text
stringlengths
33
722k
CHAPTER 19747CHEST WALL, LUNG, MEDIASTINUM, AND PLEURAthoracic paravertebral and epidural infusion of 0.2% ropi-vacaine after lung resection surgery. Eur J Anaesthesiol. 2006;23(12):999-1004. 86. Inderbitzi RG, Leiser A, Furrer M, Althaus U. Three years’ experience in video-assisted thoracic surgery (VATS) for spontaneous pneumothorax. J Thorac Cardiovasc Surg. 1994;107(6):1410-1415. 87. Warner BW, Bailey WW, Shipley RT. Value of computed tomography of the lung in the management of primary spon-taneous pneumothorax. Am J Surg. 1991;162(1):39-42. 88. Mansharamani N, Balachandran D, Delaney D, Zibrak JD, Silvestri RC, Koziel H. Lung abscess in adults: clinical com-parison of immunocompromised to non-immunocompromised patients. Respir Med. 2002;96(3):178-185. 89. Laheij RJ, Sturkenboom MC, Hassing RJ, Dieleman J, Stricker BH, Jansen JB. Risk of community-acquired pneu-monia and use of gastric acid-suppressive drugs. JAMA. 2004;292(16):1955-1960. 90. Conant EF, Wechsler RJ. Actinomycosis and nocardiosis of the lung. J Thorac Imaging. 1992;7(4):75-84. 91. Thomson RM, Armstrong JG, Looke DF. Gastroesopha-geal reflux disease, acid suppression, and Mycobacterium avium complex pulmonary disease. Chest. 2007;131(4): 1166-1172. 92. Koh WJ, Lee JH, Kwon YS, et al. Prevalence of gastroesopha-geal reflux disease in patients with nontuberculous mycobac-terial lung disease. Chest. 2007;131(6):1825-1830. 93. Angrill J, Agusti C, de Celis R, et al. Bacterial colonisation in patients with bronchiectasis: microbiological pattern and risk factors. Thorax. 2002;57(1):15-19. 94. Barker AF. Bronchiectasis. N Engl J Med. 2002;346(18):1383-1393. 95. Ilowite J, Spiegler P, Chawla S. Bronchiectasis: new find-ings in the pathogenesis and treatment of this disease. Curr Opin Infect Dis. 2008;21(2):163-167. 96. Xu L, Zhang F, Du S, et al. Inhaled antibiotics in non-cystic fibrosis bronchiectasis: a meta-analysis. Pharmazie. 2016;71:491-498. 97. Steinfort DP, Steinfort C. Effect of long-term nebulized colis-tin on lung function and quality of life in patients with chronic bronchial sepsis. Intern Med J. 2007;37(7):495-498. 98. Kellett F, Robert NM. Nebulised 7% hypertonic saline improves lung function and quality of life in bronchiectasis. Respir Med. 2011;105:1831-1835. 99. Frieden TR, Sterling TR, Munsiff SS, Watt CJ, Dye C. Tuber-culosis. Lancet. 2003;362(9387):887-899. 100. Haque AK. The pathology and pathophysiology of mycobac-teria infections. J Thorac Imaging. 1990;5:8-16. 101. Iseman MD. Treatment of multidrug-resistant tuberculosis. N Engl J Med. 1993;329(19):784-791. 102. Kubak BM. Fungal infection in lung transplantation. Transpl Infect Dis. 2002;4(suppl 3):24-31. 103. Wheat LJ, Goldman M, Sarosi G. State-of-the-art review of pulmonary fungal infections. Semin Respir Infect. 2002;17(2):158-181. 104. Marr KA, Patterson T, Denning D. Aspergillosis. Pathogen-esis, clinical manifestations, and therapy. Infect Dis Clin North Am. 2002;16(4):875-894. 105. Chun JY, Belli AM. Immediate and long-term outcomes of bronchial and non-bronchial systemic artery emboli-sation for the management of haemoptysis. Eur Radiol. 2010;20:558-565. 106. Corr P. Management of severe hemoptysis from pulmonary aspergilloma using endovascular embolization. Cardiovasc Intervent Radiol. 2006;29(5):807-810. 107. Pappas PG, Kauffman CA, Andes DR, et al. Clinical practice guideline for the management of candidiasis: 2016 update by the Infectious Diseases Society of America. Clin Infect Dis. 2016;62:e1-50. 108. Ostrosky-Zeichner L, Rex JH, Bennett J, Kullberg BJ. Deeply invasive candidiasis. Infect Dis Clin North Am. 2002;16(4):821-835. 109. Gonzalez CE, Rinaldi MG, Sugar AM. Zygomycosis. Infect Dis Clin North Am. 2002;16(4):895-914. 110. Wheat LJ, Kauffman CA. Histoplasmosis. Infect Dis Clin North Am. 2003;17(1):1-19. 111. Hage CA, Wheat LJ, Loyd J, Allen SD, Blue D, Knox KS. Pulmonary histoplasmosis. Semin Respir Crit Care Med. 2008;29(2):151-165. 112. Assi MA, Sandid MS, Baddour LM, Roberts GD, Walker RC. Systemic histoplasmosis: a 15-year retrospective insti-tutional review of 111 patients. Medicine (Baltimore). 2007;86(3):162-169. 113. Spinello IM, Munoz A, Johnson RH. Pulmonary coccidioido-mycosis. Semin Respir Crit Care Med. 2008;29(2):166-173. 114. Pappas PG. Blastomycosis. Semin Respir Crit Care Med. 2004;25(2):113-121. 115. Bradsher RW, Chapman SW, Pappas PG. Blastomycosis. Infect Dis Clin North Am. 2003;17(1):21-40. 116. Corder R. Hemoptysis. Emerg Med Clin North Am. 2003;21(2):421-435. 117. Conlan AA. Massive hemoptysis—diagnostic and therapeutic implications. Surg Annu. 1985;17:337-354. 118. Cahill BC, Ingbar DH. Massive hemoptysis. Assessment and management. Clin Chest Med. 1994;15(1):147-167. 119. Noe GD, Jaffe SM, Molan MP. CT and CT angiography in massive haemoptysis with emphasis on pre-embolization assessment. Clin Radiol. 2011;66:869-875. 120. Poyanli A, Acunas B, Rozanes I, et al. Endovascular therapy in the management of moderate and massive haemoptysis. Br J Radiol. 2007;80:331-336. 121. Conlan AA, Hurwitz SS. Management of massive haemoptysis with the rigid bronchoscope and cold saline lavage. Thorax. 1980;35(12):901-904. 122. Russi EW, Bloch KE, Weder W. Lung volume reduction sur-gery: what can we learn from the National Emphysema Treat-ment Trial? Eur Respir J. 2003;22(4):571-573. 123. Bhorade SM, Vigneswaran W, McCabe MA, Garrity ER. Lib-eralization of donor criteria may expand the donor pool with-out adverse consequence in lung transplantation. J Heart Lung Transplant. 2000;19(12):1199-1204. 124. Pierre AF, Sekine Y, Hutcheon MA, Waddell TK, Keshavjee SH. Marginal donor lungs: a reassessment. J Thorac Cardio-vasc Surg. 2002;123(3):421-427; discussion 427. 125. Palmer SM, Miralles AP, Howell DN, Brazer SR, Tapson VF, Davis RD. Gastroesophageal reflux as a reversible cause of allograft dysfunction after lung transplantation. Chest. 2000;118(4):1214-1217. 126. Dahlberg PS, Prekker ME, Hertz M, Thompson DJ, Park SJ. Recent trends in lung transplantation: the University of Min-nesota experience. Clin Transpl. 2002;243-251. 127. Somers J, Faber LP. Chondroma and chondrosarcoma. Semin Thorac Cardiovasc Surg. 1999;11(3):270-277. 128. Andino L, Cagle PT, Murer B, et al. Pleuropulmonary des-moid tumors: immunohistochemical comparison with solitary fibrous tumors and assessment of beta-catenin and cyclin D1 expression. Arch Pathol Lab Med. 2006;130(10):1503-1509. 129. Baliski CR, Temple WJ, Arthur K, Schachar NS. Desmoid tumors: a novel approach for local control. J Surg Oncol. 2002;80(2):96-99. 130. Abbas AE, Deschamps C, Cassivi SD, et al. Chest-wall des-moid tumors: results of surgical intervention. Ann Thorac Surg. 2004;78(4):1219-1223; discussion 1219-1223. 131. Gutierrez JC, Perez EA, Franceschi D, Moffat FL Jr, Livingstone AS, Koniaris LG. Outcomes for soft-tissue sarcoma in 8249 cases from a large state cancer registry. J Surg Res. 2007;141(1):105-114.Brunicardi_Ch19_p0661-p0750.indd 74701/03/19 7:02 PM 748SPECIFIC CONSIDERATIONSPART II 132. Walsh GL, Davis BM, Swisher SG, et al. A single-institutional, multidisciplinary approach to primary sarcomas involving the chest wall requiring full-thickness resections. J Thorac Car-diovasc Surg. 2001;121(1):48-60. 133. Liptay MJ, Fry WA. Malignant bone tumors of the chest wall. Semin Thorac Cardiovasc Surg. 1999;11(3):278-284. 134. Shah AA, D’Amico TA. Primary chest wall tumors. J Am Coll Surg. 2010;210:360-366. 135. Incarbone M, Pastorino U. Surgical treatment of chest wall tumors. World J Surg. 2001;25(2):218-230. 136. Deschamps C, Tirnaksiz BM, Darbandi R, et al. Early and long-term results of prosthetic chest wall reconstruction. J Thorac Cardiovasc Surg. 1999;117(3):588-591; discussion 591-592. 137. Graeber GM. Chest wall resection and reconstruction. Semin Thorac Cardiovasc Surg. 1999;11(3):251-263. 138. Kirschner PA. Anatomy and surgical access of the mediasti-num. In: Pearson FG, ed. Thoracic Surgery. 2nd ed. New York: Churchill Livingstone; 2002:1563. 139. Strollo DC, Rosado-de-Christenson ML, Jett JR. Primary mediastinal tumors. Part II: tumors of the middle and posterior mediastinum. Chest. 1997;112:1344-1357. 140. Takahashi K, Al-Janabi NJ. Computed tomography and mag-netic resonance imaging of mediastinal tumors. J Magn Reson Imaging. 2010;32:1325-1339. 141. Storch I, Shah M, Thurer R, Donna E, Ribeiro A. Endoscopic ultrasound-guided fine-needle aspiration and Tru-Cut biopsy in thoracic lesions: when tissue is the issue. Surg Endosc J. 2008;22(1):86-90. 142. Herman SJ, Holub RV, Weisbrod GL, Chamberlain DW. Ante-rior mediastinal masses: utility of transthoracic needle biopsy. Radiology. 1991;180(1):167-170. 143. Assaad MW, Pantanowitz L. Diagnostic accuracy of image-guided percutaneous fine needle aspiration biopsy of the medi-astinum. Diagn Cytopathol. 2007;35:705-709. 144. Pedote P, Gaudio F, Moschetta M, et al. CT-guided needle biopsy performed with modified coaxial technique in the diagnosis of malignant lymphomas. Radiol Med. 2010;115: 1292-1303. 145. Demmy TL, Krasna MJ. Multicenter VATS experience with mediastinal tumors. Ann Thorac Surg. 1998;66:187-192. 146. Bodner J, Wykypiel H, Greiner A, et al. Early experience with robot-assisted surgery for mediastinal masses. Ann Thorac Surg. 2004;78:259-265. 147. Yim AP. Video-assisted thoracoscopic resection of anterior mediastinal masses. Int Surg. 1996;81(4):350-353. 148. Weksler B, Tavares J. Robot-assisted thymectomy is superior to transsternal thymectomy. Surg Endosc. 2012;26:261-266. 149. Chang PC, Chou SH, Kao EL, et al. Bilateral video-assisted thoracoscopic thymectomy vs. extended transsternal thymec-tomy in myasthenia gravis: a prospective study. Eur Surg Res. 2005;37:199-203. 150. Meyers BF, Cooper JD. Transcervical thymectomy for myas-thenia gravis. Chest Surg Clin N Am. 2001;11(2):363-368. 151. Small EJ, Venook AP, Damon LE. Gallium-avid thymic hyper-plasia in an adult after chemotherapy for Hodgkin disease. Cancer. 1993;72(3):905-908. 152. Smith CS, Schoder H. Thymic extension in the superior medi-astinum in patients with thymic hyperplasia: potential cause of false-positive findings on 18F-FDG PET/CT. AJR Am J Roent-genol. 2007;188:1716-1721. 153. Quint LE. PET: other thoracic malignancies. Cancer Imaging. 2006;6:S82-S88. 154. Luzzi L, Campione A, Gorla A, et al. Role of fluorinefluo-rodeoxyglucose positron emission tomography/computed tomography in preoperative assessment of anterior mediastinal masses. Eur J Cardiothorac Surg. 2009;36:475-479. 155. Masaoka A, Monden Y, Nakahara K, Tanioka T. Follow-up study of thymomas with special reference to their clinical stages. Cancer. 1981;48(11):2485-2492. 156. Pennathur A, Qureshi I, Schuchert T, et al. Comparison of surgical techniques for early-stage thymoma: feasibility of minimally invasive thymectomy and comparison with open resection. J Thorac Cardiovasc Surg. 2011;141(3):694-701. 157. Chahinian AP. Chemotherapy of thymomas and thymic carci-nomas. Chest Surg Clin N Am. 2001;11(2):447-456. 158. Blumberg D, Port JL, Weksler B, et al. Thymoma: a multivari-ate analysis of factors predicting survival. Ann Thorac Surg. 1995;60(4):908-913; discussion 914. 159. Weksler B, Shende M. The role of adjuvant radiation therapy for resected stage III thymoma: a population-based study. Ann Thorac Surg. 2012;93:1822-1828; discussion 1828-1829. 160. Suster S, Rosai J. Thymic carcinoma. A clinicopathologic study of 60 cases. Cancer. 1991;67(4):1025-1032. 161. Bousamra M. Neurogenic tumors of the mediastinum. In: Pearson FG, ed. Thoracic Surgery. 2nd ed. New York: Churchill Liv-ingstone; 2002:1732. 162. Venissac N, Leo F, Hofman P, Paquis P, Mouroux J. Medi-astinal neurogenic tumors and video-assisted thoracoscopy: always the right choice? Surg Laparosc Endosc Percutan Tech. 2004;14(1):20-22. 163. Coleman BG, Arger PH, Dalinka MK, Obringer AC, Raney BR, Meadows AT. CT of sarcomatous degeneration in neurofibro-matosis. AJR Am J Roentgenol. 1983;140(2):383-387. 164. Ducatman BS, Scheithauer BW, Piepgras DG, Reiman HM, Ilstrup DM. Malignant peripheral nerve sheath tumors. A clinicopathologic study of 120 cases. Cancer. 1986;57(10):2006-2021. 165. Nichols CR, Saxman S, Williams SD, et al. Primary medi-astinal nonseminomatous germ cell tumors. A modern single institution experience. Cancer. 1990;65(7):1641-1646. 166. Kesler KA, Rieger KM, Hammoud Z, et al. A 25-year sin-gle institution experience with surgery for primary medias-tinal nonseminomatous germ cell tumors. Ann Thorac Surg. 2008;85:371-378. 167. Rice TW. Benign neoplasms and cysts of the mediastinum. Semin Thorac Cardiovasc Surg. 1992;4(1):25-33. 168. Di Lorenzo M, Collin PP, Vaillancourt R, Duranceau A. Bron-chogenic cysts. J Pediatr Surg. 1989;24(10):988-991. 169. Ribet ME, Copin MC, Gosselin B. Bronchogenic cysts of the mediastinum. J Thorac Cardiovasc Surg. 1995;109(5):1003-1010. 170. St-Georges R, Deslauriers J, Duranceau A, et al. Clinical spec-trum of bronchogenic cysts of the mediastinum and lung in the adult. Ann Thorac Surg. 1991;52(1):6-13. 171. Agostoni E. Mechanics of the pleural space. In: Fisherman AP, Macklem PT, Mead J, et al, eds. Mechanics of Breathing: Handbook of Physiology. Vol 3. Bethesda, MD: American Physiological Society; 1986. 172. Lawrence GH. Considerations of the anatomy and physiology of the pleural space. In: Lawrence GH, ed. Problems of the Pleural Space. Philadelphia: WB Saunders; 1983. 173. Rusch VW. Pleural effusion: benign and malignant. In: Pear-son FG, ed. Thoracic Surgery. 2nd ed. New York: Churchill Livingstone; 2002:1157. 174. Gammie JS, Banks MC, Fuhrman CR, et al. The pigtail cath-eter for pleural drainage: a less invasive alternative to tube thoracostomy. JSLS. 1999;3(1):57-61. 175. Luketich JD, Kiss M, Hershey J, et al. Chest tube insertion: a prospective evaluation of pain management. Clin J Pain. 1998;14(2):152-154. 176. Johnston WW. The malignant pleural effusion. A review of cytopathologic diagnoses of 584 specimens from 472 consecu-tive patients. Cancer. 1985;56(4):905-909.Brunicardi_Ch19_p0661-p0750.indd 74801/03/19 7:02 PM
CHAPTER 19749CHEST WALL, LUNG, MEDIASTINUM, AND PLEURA 177. Ocaña I, Martinez-Vazquez JM, Segura RM, et al. Adenosine deaminase in pleural fluids. Test for diagnosis of tuberculous pleural effusion. Chest. 1983;84(1):51-53. 178. Lee YC, Rogers JT, Rodriguez RM, Miller KD, Light RW. Adenosine deaminase levels in nontuberculous lymphocytic pleural effusions. Chest. 2001;120(2):356-361. 179. Tremblay A, Michaud G. Single-center experience with 250 tunneled pleural catheter insertions for malignant pleural effu-sion. Chest. 2006;129(2):362-368. 180. Light RW. Parapneumonic effusions and empyema. Clin Chest Med. 1985;6(1):55-62. 181. Rahman NM, Maskell NA, West A, et al. Intrapleural use of tissue plasminogen activator and DNase in pleural infection. N Engl J Med. 2011;365:518-526. 182. Miller JI Jr. The history of surgery of empyema, thoracoplasty, Eloesser flap, and muscle flap transposition. Chest Surg Clin N Am. 2000;10(1):45-53. 183. Miller JI Jr. Diagnosis and management of chylothorax. Chest Surg Clin N Am. 1996;6(1):139-148. 184. Malthaner RA, Inculet RI. The thoracic duct and chylotho-rax. In: Pearson FG, ed. Thoracic Surgery. 2nd ed. New York: Churchill Livingstone; 2002:1228. 185. Rusch VW. A proposed new international TNM staging system for malignant pleural mesothelioma. From the International Mesothelioma Interest Group. Chest. 1995;108(4):1122-1128. 186. Khalil MY, Mapa M, Shin HJ, Shin DM. Advances in the management of malignant mesothelioma. Curr Oncol Rep. 2003;5(4):334-341. 187. Fletcher CDM, Unni KK, Mertens F. World Health Organization Classification of Tumours. Pathology and Genetics of Tumours of Soft Tissue and Bone. Lyon, France: IARC Press; 2002. 188. England DM, Hochholzer L, McCarthy MJ. Localized benign and malignant fibrous tumors of the pleura. A clinicopathologic review of 223 cases. Am J Surg Pathol. 1989;13(8):640-658.Brunicardi_Ch19_p0661-p0750.indd 74901/03/19 7:02 PM
Brunicardi_Ch19_p0661-p0750.indd 75001/03/19 7:02 PMThis page intentionally left blankCongenital Heart DiseaseRaghav Murthy, Tabitha G. Moe, Glen S. Van Arsdell, John J. Nigro, and Tara Karamlou20chapterINTRODUCTIONCongenital heart surgery is a dynamic and evolving field. The last 20 years have brought about rapid developments in technol-ogy, emphasis on a multidisciplinary approach to treatment, and a more thorough understanding of both the anatomy and patho-physiology of congenital heart disease, leading to the improved care of these challenging patients.These advancements have created a sustained paradigm shift in the field of congenital heart surgery. The traditional strategy of initial palliation followed by definitive correction at a later age, which had pervaded the thinking of most surgeons, began to evolve into emphasizing early repair. Defects such as hypoplastic left heart syndrome (HLHS) are now successfully managed with staged palliation, resulting in excellent survival outcomes for these children.The goal in most cases of congenital heart disease (CHD) is appropriate timing of complete repair. Rather than subdivid-ing lesions into cyanotic or noncyanotic lesions, a more appro-priate classification divides defects into three categories based on the feasibility of achieving complete repair: (a) defects that have no reasonable palliation and for which repair is the only option; (b) defects for which repair is not possible and for which palliation is the only option; and (c) defects that can either be repaired or palliated in infancy. It bears mentioning that all defects in the second category are those in which the appropriate anatomic components either are not present, as in hypoplastic left heart syndrome, or cannot be created from existing structures, i.e., unguarded tricuspid orifice.1Eight out of every 1000 live births will have some form of CHD, most of which, however, are mild.1 In the United States nearly 40,000 infants are affected each year.2 As of 2010, it is estimated that there are about 2 million people living with CHD in the United States, and as of 2011 there are more adults (>18) than children.2 CHD is the most common birth defect and the most common cause of infant death related to birth defects, accounting for 28% of deaths due to birth defects in the first month of life. There are currently 127 centers in North America that perform congenital heart surgery. The Society for Thoracic Surgeons (STS) reports an overall national mortality of 3.1%.3DEFECTS AMENABLE TO COMPLETE REPAIRAtrial Septal DefectAn atrial septal defect (ASD) is defined as discontinuity of the interatrial septum that permits direct mixing of blood between the systemic venous and pulmonary venous circulations.Embryology. The atrial and ventricular septa form between the third and sixth weeks of fetal development. After the paired heart tubes fuse into a single tube folded onto itself, the distal por-tion of the tube indents to form the roof of the common atrium. Near this portion of the roof, the septum primum originates and descends in a crescentic formation toward the atrioventricular (AV) junction. The ostium primum is situated superiorly to the crux of the heart at the atrioventricular junction. Prior to completion of endocardial cushion fusion with the septum pri-mum, a sequence of fenestrations appear that coalesce into the Introduction 751Defects Amenable to  Complete Repair 751Atrial Septal Defect / 751Aortic Stenosis / 755Patent Ductus Arteriosus / 759Aortic Coarctation / 761Truncus Arteriosus / 764Total Anomalous Pulmonary Venous Connection / 765Cor Triatriatum / 768Aortopulmonary Window / 769Vascular Rings and Pulmonary Artery Slings / 769Defects Requiring Palliation 770Tricuspid Atresia / 770Hypoplastic Left Heart Syndrome / 773Defects That May be Palliated  or Repaired 777Ebstein’s Anomaly / 777Transposition of the Great Arteries / 780Double-Outlet Right Ventricle / 783Double-Outlet Right Ventricle With Noncommitted Ventricular Septal Defect / 783Double-Outlet Right Ventricle With Subaortic or Doubly Committed Ventricular Septal Defect Without Pulmonary Stenosis / 784Double-Outlet Right Ventricle With Subaortic or Doubly Committed Ventricular Septal Defect With Pulmonary Stenosis / 784Taussig–Bing Syndrome Without Pulmonary Stenosis / 784Taussig–Bing Syndrome With Pulmonary Stenosis / 784Tetralogy of Fallot / 784Ventricular Septal Defect / 786Atrioventricular Canal Defects / 789Interrupted Aortic Arch / 790Pediatric Mechanical Circulatory Support / 790Pediatric Heart Transplantation / 791Public Reporting and the STS Database in Congenital Heart Surgery / 792Future Directions / 793Brunicardi_Ch20_p0751-p0800.indd 75122/02/19 2:54 PM 752ostium secundum. During this coalescence, the septum secun-dum grows downward from the roof of the atrium, parallel to and to the right of the septum primum. The septum primum does not fuse, but creates an oblique pathway, called the foramen ovale, within the interatrial septum. After birth, the increase in left atrial pressure associated with an increase in SVR relative to PVR typically closes this pathway in approximately 80% of the population, obliterating the interatrial communication.Anatomy. ASDs can be classified into three different types (Fig. 20-1): (a) ostium secundum type defect (Fig. 20-1B,C) (deficiency of septum primum), which are the most prevalent subtype, comprising 80% of all ASDs; (b) ostium primum defects (Fig. 20-1A), which may also be described as partial or transitional AV canal defect; and (c) sinus venosus type defects, comprising approximately 5% to 10% of all ASDs.4Pathophysiology. ASDs result in an increase in pulmonary blood flow secondary to primarily left-to-right shunting through the defect. The direction of the intracardiac shunt is predomi-nantly determined by the compliance of the respective ventri-cles. In utero, the distensibility, or compliance, of the right and left ventricles is equal, but postnatally the left ventricle (LV) becomes less compliant than the right ventricle (RV). This shift occurs because the resistance of the downstream vascular beds changes after birth. The pulmonary vascular resistance falls with the infant’s first breath, decreasing RV pressure, whereas the systemic vascular resistance rises dramatically, increasing LV pressure. The increase in LV pressure promotes hypertrophy with a thicker muscle mass, which offers a greater resistance to diastolic filling than does the RV; thus, the majority of flow through the ASD occurs from left to right. The greater volume of blood returning to the right atrium causes volume overload in the RV, but because of its lower muscle mass and low-resistance output, it easily distends to accommodate the increased volume.The long-term consequences of RV volume overload include hypertrophy with elevated RV end-diastolic pressure and a relative pulmonary stenosis across the pulmonary valve because it cannot accommodate the increased RV flow. Com-pliance gradually decreases as the right ventricular pressure approaches systemic pressure, and the size of the left-to-right shunt decreases. Patients at this stage have a balanced circula-tion and may deceptively appear less symptomatic.Key Points1 Congenital heart disease comprises a wide morphologic spec-trum. In general, lesions can be conceptualized as those that can be completely repaired, those that should be palliated, and those that can be either repaired or palliated depending on particular patient and institutional characteristics.2 Percutaneous therapies for congenital heart disease are quickly becoming important adjuncts, and in some cases, alternatives, to standard surgical therapy. Important exam-ples include percutaneous closure of atrial and ventricular septal defects, the hybrid approach to hypoplastic left heart syndrome, radiofrequency perforation of the pulmonary valve, and percutaneous pulmonary valve placement. Further studies are necessary to establish criteria and current bench-marks for the safe integration of these novel approaches into the care of patients with congenital heart surgery.3 Patients with critical left ventricular outflow tract obstruc-tion, such as neonatal critical aortic stenosis, represent a challenging population. It is critical that the correct decision (whether to pursue univentricular or biventricular repair) be made prior to the initial operation, as attrition when the incorrect decision is made is high. There are several pub-lished criteria (Congenital Heart Surgeons’ Society critical stenosis calculator) to help surgeons decide which strategy to pursue.4 Optimum strategy for repair of total anomalous pulmonary venous connection (TAPVC) remains a topic of some con-tention. Sutureless repair, formerly reserved for initial reste-nosis after conventional repair, has evolved in many centers to be the primary approach for high-risk patients. Defining whether sutureless repair should be considered in all patients with TAPVC will require further study.5 Vascular rings and pulmonary artery slings often require multidisciplinary approaches for management. They can be associated with complete tracheal rings and tracheobronchomalacia.6 A recent prospective, randomized, multi-institutional trial sponsored by the National Institutes of Health, the Systemic Ventricle Reconstruction (SVR) trial, compared the out-comes of neonates with hypoplastic left heart syndrome hav-ing either a modified Blalock–Taussig shunt (MBTS) versus a right ventricle-to-pulmonary artery (RV-PA) shunt. The SVR trial demonstrated that transplantation-free survival 12 months after randomization was higher with the RV-PA shunt than with the MBTS. However, data collected over a mean follow-up period of 32 ± 11 months showed a nonsig-nificant difference in transplantation-free survival between the two groups.7 Outcomes have improved substantially over time in congeni-tal heart surgery, and most complex lesions can be operated in early infancy. Neurologic protection, however, remains a key issue in the care of neonates undergoing surgery with cardiopulmonary bypass and deep hypothermic circulatory arrest. New monitoring devices and perioperative strategies are currently under investigation. Attention in the field has shifted from analyses of perioperative mortality, which for most lesions is under 10%, to longer-term outcomes, includ-ing quality of life and neurologic function.8 Pediatric mechanical circulatory support and heart transplan-tation is an upcoming and rapidly evolving component of congenital heart surgery. These are offering options for res-cue, palliation, and treatment of complex defects or children who were palliated and failing.9 Public reporting has become an integral part of this subspe-cialty. The Society of Thoracic Surgeons Congenital Heart Surgery Database (STS CHSD) remains the largest database in the world for congenital and pediatric heart surgery. Transparency in overall outcomes, mortality, and morbidity is allowing patients and their families an insight into the complexity of their diagnoses as well as the level of perfor-mance of different centers.Brunicardi_Ch20_p0751-p0800.indd 75222/02/19 2:54 PM 753CONGENITAL HEART DISEASECHAPTER 20ABCFigure 20-1. A. Echocardiogram of a patient with primum type artial septal defect (‘*’ points to the atrial septal defect). B. Echocardiogram of a large secundum type ASD (‘*’ points to the defect). C. Intra-operative picture during repair of atrial septal defect. A large fenestrated atrial septum is seen. Bicaval venous cannulation has been performed and a right atriotomy provides exposure to the atrial septum.Patients with large ASDs gradually develop progressive pulmonary vascular changes as a result of chronic overcircu-lation. The increased pulmonary vascular resistance in these patients leads to an equalization of left and right ventricular pressures, and their ratio of pulmonary (Qp) to systemic flow (Qs), Qp to Qs, will approach 1.5 This does not mean, however, that there is no intracardiac shunting, only that the ratio between the left-to-right component and the right-to-left component is equal.The ability of the RV to recover normal function is related to the duration of chronic overload because those undergoing ASD closure before age 10 years have a better likelihood of achieving normal RV volumes and function in the postopera-tive period.6The physiology of sinus venosus ASDs is similar to that discussed earlier, except that these are frequently accompanied by anomalous pulmonary venous drainage. This often results in significant hemodynamic derangements that accelerate the clinical course of these infants.The same increase in symptoms is true for those with ostium primum defects because the associated mitral insuffi-ciency from the “cleft” mitral valve can lead to more atrial vol-ume load and increased atrial level shunting.Diagnosis. Patients with ASDs upon auscultation may reveal prominence of the first heart sound with fixed splitting of the second heart sound. This results from the relatively fixed left-to-right shunt throughout all phases of the cardiac cycle. A diastolic flow murmur indicating increased flow across the tricuspid valve may be discerned, and frequently, an ejection flow mur-mur can be heard across the pulmonary valve. A right ventricu-lar heave and increased intensity of the pulmonary component of the second heart sound indicates pulmonary hypertension.Chest radiographs in the patient with an ASD demonstrate increased pulmonary vascularity, with prominent hilar mark-ings and cardiomegaly. The electrocardiogram shows right axis deviation with an incomplete bundle-branch block. When right bundle-branch block is associated with a leftward or superior axis, an AV canal defect should be strongly suspected.Diagnosis is clarified by two-dimensional echocardiogra-phy (Fig. 20-1A,C), and use of color-flow mapping facilitates an understanding of the physiologic derangements created by the defects. Older children and adults with unrepaired ASDs may present with stroke or systemic embolism from paradoxical embolism or atrial arrhythmias from dilation of the right atrium.Echocardiography also enables the clinician to estimate the amount of intracardiac shunting, and it can demonstrate the degree of mitral regurgitation in patients with ostium primum defects. With the addition of an agitated saline injection (bubble study), it can also assist in the detection of sinus venosus defects.The advent of two-dimensional echocardiography with color-flow Doppler has largely superseded the use of cardiac catheterization because the ASD can be well defined by echo-cardiography alone. However, in cases where the right ventric-ular systolic pressure is elevated, or patient is older than age 40 years, catheterization can quantify the degree of pulmonary hypertension because those with a fixed pulmonary vascular resistance greater than 12 U/mL may be considered inoperable.7 Cardiac catheterization also can be useful in that it provides data that enable the calculation of Qp and Qs so that the magnitude of the intracardiac shunt can be determined. The ratio (Qp to Qs) can then be used to determine whether closure is indicated in equivocal cases, because a ratio of Qp to Qs greater than 1.5:1 Brunicardi_Ch20_p0751-p0800.indd 75322/02/19 2:54 PM 754SPECIFIC CONSIDERATIONSPART IIis generally accepted as the threshold for surgical intervention. Finally, in patients older than age 40 years, cardiac catheteriza-tion can be important to evaluate for the presence of coronary artery disease.In general, ASDs are closed when patients are between 4 and 5 years of age. Children of this size can usually be oper-ated on without the use of blood transfusion and have excellent outcomes. Patients who are symptomatic may require repair earlier, even in infancy. Some surgeons advocate routine repair in infants and children especially in cases where prematurity-related lung disease may accelerate damage to the pulmonary vascular bed, though this philosophy may not be widespread. In a review by Reddy and colleagues, 116 neonates weighing less than 2500 g who underwent repair of simple and complex cardiac defects with the use of cardiopulmonary bypass were found to have no intracerebral hemorrhages, no long-term neu-rologic sequelae, and a low operative mortality rate (10%). These results correlated with the length of cardiopulmonary bypass and the complexity of repair.8 These investigators also found an 80% actuarial survival at 1 year and, more importantly, that growth following complete repair was equivalent to weight-matched neonates free from cardiac defects.8Treatment. Simple secundum type ASDs can frequently be repaired via a transcatheter technique, and assessment for trans-catheter closure with TTE assessment is generally indicated prior to consideration of a surgical repair. The most common surgical approach requires standard cardiopulmonary bypass (CPB) tech-nique through a midline sternotomy approach. The details of the repair itself are generally straightforward. An oblique atriotomy is made, the position of the coronary sinus and all systemic and pulmonary veins are determined, and the rim of the defect is completely visualized. Closure of an ostium secundum defect is accomplished either by primary repair or by insertion of a patch that is sutured to the rim of the defect. The decision of whether patch closure is necessary can be determined by the size and shape of the defect as well as by the quality of the edges.The type of repair used for sinus venosus ASDs associated with partial anomalous pulmonary venous connection is dictated by the location of the anomalous pulmonary vein. If the anoma-lous veins connect to the atria or to the superior vena cava cau-dal to where the cava is crossed by the right pulmonary artery, the ASD can be repaired by inserting a patch, with redirection of the pulmonary veins behind the patch to the left atrium. Care must be taken with this approach to avoid obstruction of the pulmonary veins or the superior vena cava, although usually the superior vena cava is dilated and provides ample room for patch insertion. If the anomalous vein connects to the superior vena cava cranial to the right pulmonary artery, an alternative technique, the Warden procedure, may be necessary. In this operation, the superior vena cava is transected cranial to the connection of the anomalous vein (usually the right superior pulmonary vein). The caudal end of the transected cava is over-sewn. The cranial end of the transected cava is anastomosed to the auricle of the right atrium. Inside the atrium, a patch is used to redirect pulmonary venous blood flow to the left atrium. In contrast to the repair for a defect where the pulmonary veins enter the right atrium or the superior vena cava below the right pulmonary artery, the patch covers the superior vena caval right atrial junction so that blood from the anomalous pulmonary vein that enters the cava is directed to the left atrium. Blood returning from the upper body enters the right atrium via the anastomosis between the superior vena cava and the right atrial appendage.Results and Complications of Surgical ASD Closure. Tra-ditional operative strategies, such as pericardial or synthetic patch closure, have been well established, with a low complica-tion rate and a mortality rate of zero among patients without pulmonary hypertension.9 The most frequently reported imme-diate complications include postpericardiotomy syndrome and atrial arrhythmias. Beyond immediate postoperative outcomes, long-term outcomes following surgical closure (up to 20 years) document the low mortality rates and durability of functional status benefit. Importantly, however, atrial arrhythmias, par-ticularly atrial fibrillation, are not completely mitigated by closure and can occur in 10% to 40% of patients, especially in older patients (>40 years) or those with preexisting arrhyth-mias.10 Kutty and colleagues11 followed 300 patients from their institution, 152 of whom had surgical closure. Late mortality at 10 years was 3%, and functional health status had declined in only 15 patients during follow-up. Recently, there have been an increasing number of reports regarding the results follow-ing surgical closure among elderly patients (>60 years of age), which demonstrate equivalent survival to younger patients, albeit with slightly higher complication rates.11-13 Hanninen and colleagues14 studied 68 patients between 68 and 86 years at their institution undergoing either surgical (n = 13) or device (n = 54) closure. Although the 23% incidence of major complications (including pneumothorax, heart failure, and pneumonia) was higher than that recently reported by Mascio et al15 using the Society of Thoracic Surgeons’ Congenital Database (20%) or a single-institution review by Hopkins et al16 (12%), there were no operative deaths among the elderly cohort. Moreover, after ASD closure, echocardiographic indices of right ventricular size and function were significantly improved from preoperative val-ues, and functional capacity as measured by standardized survey instruments was also significantly improved.New and Future Approaches to Traditional Surgical ASD Closure. Because of the uniformly excellent outcomes with traditional surgery, attention has shifted to improving the cos-metic result and minimizing hospital stay and convalescence. Multiple strategies have been described to achieve these aims, including the right submammary incision with anterior thora-cotomy, limited bilateral submammary incision with partial sternal split, and limited midline incision with partial sternal split. Some surgeons use either video-assisted thoracic surgery (VATS) in conjunction with the submammary and transxiphoid approaches to facilitate closure within a constricted operative field or totally endoscopic repair in selected patients.17-20 Use of robotics has also been reported in a small series of 12 adult patients by Argenziano and colleagues.18 The morbidity and mortality of all of these approaches are comparable to those of the traditional median sternotomy; however, each has technical drawbacks. Operative precision must be maintained with limited exposure in any minimally invasive technique. Extended CPB and aortic cross-clamp times, coupled with increased cost, may limit the utility of totally endoscopic or robotic-assisted ASD closure except at specific centers. Moreover, certain approaches have a specific patient population in whom they are most appli-cable. For example, the anterolateral thoracotomy should not be employed in prepubescent girls because it will interfere with breast development. Most totally endoscopic approaches are not feasible in very young patients because of the size of the tho-racoscopic ports. Despite these potential drawbacks, however, in carefully selected patients, minimally invasive techniques have demonstrated benefits. Luo and associates performed Brunicardi_Ch20_p0751-p0800.indd 75422/02/19 2:54 PM 755CONGENITAL HEART DISEASECHAPTER 20ABFigure 20-2. A. Picture of the Amplatzr device after open retrieval from the heart (dislodged during percutaenous catheter placement). B. Echocardiographic view of the septum after transcatheter closure of the atrial septal defect with an Amplatzar device.a prospective randomized study comparing ministernotomy (division of the upper sternum for aortic and pulmonary lesions and the lower sternum for septal lesions) to full sternotomy in 100 consecutive patients undergoing repair of septal lesions.19 The patients in the ministernotomy group had longer procedure times (by 15 to 20 minutes) but had less bleeding and shorter hospital stays. Consistent with these initiatives, conversion of “low-risk” patients undergoing minimally invasive ASD closure to an ambulatory population (discharge from hospital within 24 hours) has recently been described.21First performed in 1976, transcatheter closure of ASDs with the use of various occlusion devices is gaining widespread accep-tance.22 Certain types of ASDs, including patent foramen ovale, secundum defects, and some fenestrated secundum defects, are amenable to device closure, as long as particular ana-tomic criteria (e.g., an adequate superior and inferior rim for device seating and distance from the AV valve) are met. Since the introduction of percutaneous closure (Fig. 20-2A,B), there has been a dramatic rise in device closure prevalence to the point where device closure has supplanted surgical therapy as the domi-nant treatment modality for secundum ASD.23 A study from Karamlou et al23 found that ASD and patent foramen ovale clo-sures per capita increased dramatically from 1.08 per 100,000 population in 1988 to 2.59 per 100,000 population in 2005, an increase of 139%. When analyzed by closure type, surgical clo-sure increased by only 24% (from 0.86 per 100,000 population in 1988 to 1.07 per 100,000 in 2005), whereas transcatheter closure increased by 3475% (from 0.04 per 100,000 population in 1988 to 1.43 per 100,000 in 2005). Importantly, this study determined that the paradigm shift favoring transcatheter closure has occurred mainly due to increased prevalence of closure in adults over age 40 years rather than an increase in closure in infants or children.Despite the simplicity of ASD repair, there are a myriad of options for patients and physicians who care for patients with CHD. The patient population that might benefit from closure (whether device or surgical) is likely to increase, challenging current ideas and treatment algorithms that optimize outcomes.2Aortic StenosisAnatomy and Classification. The spectrum of aortic valve abnormality represents the most common form of CHD, with the great majority of patients being asymptomatic until midlife. Obstruction of the left ventricular outflow tract (LVOT) occurs at multiple levels: subvalvular, valvular, and supravalvular (Fig. 20-3A-D). The critically stenotic aortic valve in the neo-nate or infant is commonly unicommissural or bicommissural, with thickened, dysmorphic, and myxomatous leaflet tissue and a reduced cross-sectional area at the valve level. Associ-ated left-sided lesions are often present. In a review of 32 cases from the Children’s Hospital in Boston, 59% had unicommis-sural valves, and 40% had bicommissural valves.24 Associated lesions were frequent, occurring in 88% of patients, most com-monly patent ductus arteriosus, mitral regurgitation, and hypo-plastic LV. Endocardial fibroelastosis (EFE) also is common among infants with critical aortic stenosis (AS). In this condi-tion, the LV is usually prohibitively hypoplastic and noncom-pliant, rendering these patients poor candidates for recruitment of the LV into the systemic circulation with techniques that can be utilized in those with more normal sized LVs. In some neonates with critical AS, a dilated LV with poor diastolic com-pliance rather than a hypertrophied LV is encountered.24Neonates with critical AS are a challenging population because one must make a decision about the suitability of the left-sided structures to support a biventricular circulation. There are recent approaches that include techniques, such as aortic valvotomy coupled with EFE resection and mitral valve inter-vention, that are directed at LV rehabilitation. The advent of fetal valvotomy for critical AS may also increase the number of infants who are candidates for biventricular repair.Pathophysiology. The unique intracardiac and extracardiac shunts present in fetal life allow even neonates with critical AS to survive. In utero, left ventricular hypertrophy and ischemia cause left atrial hypertension, which reduces the right-to-left flow across the foramen ovale. In severe cases, a reversal of Brunicardi_Ch20_p0751-p0800.indd 75522/02/19 2:54 PM 756SPECIFIC CONSIDERATIONSPART IIFigure 20-3. A. Congenital aortic valve stenosis, en fosse echocardiographic view of the stenotic bicuspid aortic valve. Parasternal long axis view of the same valve with a gradient of 60 mm of Hg (‘*’ points to the valve). B. Parasternal long axis ecocardiographic view of a patient with discrete subaortic membrane (‘*’ points to the membrane). C. Parasternal long axis ecocardiographic view of a patient with diffuse tunnel like subvalvar aortic stenosis with membrane. Doppler revealed a gradient of 81 mm of hg (‘*’ represents the area of diffuse narrowing). D. Appearance of supravalvar aortic stenosis on an aortogram performed in the cardiac catheterization lab (‘*’ points to the stenosis). E. Appearance after four patch reconstruction of the same patient shown in Figure 20.3 d. (Re-formatted images obtained from a CT angiogram).ABCDEBrunicardi_Ch20_p0751-p0800.indd 75622/02/19 2:54 PM 757CONGENITAL HEART DISEASECHAPTER 20flow may occur, causing right ventricular volume loading. The RV then provides the entire systemic output via the patent duc-tus arteriosus (ductal-dependent systemic blood flow). Although cardiac output is maintained, the LV suffers continued damage as the intracavitary pressure precludes adequate coronary perfu-sion, resulting in LV infarction and subendocardial fibroelas-tosis. The presentation of the neonate with critical AS is then determined by the morphology of the LV and other left-sided heart structures, the degree of left ventricular dysfunction, and the completeness of the transition from a parallel circulation to an in-series circulation (i.e., on closure of the foramen ovale and the ductus arteriosus). Those infants with mild-to-moderate AS in whom LV function is preserved are asymptomatic at birth. The only abnormalities may be a systolic ejection murmur and electrocardiogram (ECG) evidence of left ventricular hypertro-phy. However, those neonates with severe AS and compromised LV function are unable to provide adequate cardiac output at birth and will present in circulatory collapse once the ductus closes, with dyspnea, tachypnea, irritability, narrowed pulse pressure, oliguria, and profound metabolic acidosis.24 If ductal patency is maintained, systemic perfusion will be provided by the RV via ductal flow, and cyanosis may be the only finding.Diagnosis. Neonates and infants with severe valvular AS may have a relatively nonspecific history of irritability and failure to thrive. Angina, if present, is usually manifested by episodic, inconsolable crying that coincides with feeding. As discussed previously, evidence of poor peripheral perfusion, such as extreme pallor, indicates severe LVOT obstruction. Differen-tial cyanosis is an uncommon finding, but it is present when enough antegrade flow occurs only to maintain normal upper body perfusion, while a large patent ductus arteriosus produces blue discoloration of the abdomen and legs.Physical findings include a systolic ejection murmur, although a quiet murmur may paradoxically indicate a more severe condition with reduced cardiac output. A systolic click correlates with a valvular etiology of obstruction. As LV dys-function progresses, evidence of congestive heart failure occurs.The chest radiograph is variable but may show dilatation of the aortic root, and the ECG often demonstrates LV hypertro-phy. Echocardiography with Doppler flow is extremely useful in establishing the diagnosis, as well as quantifying the transvalvular gradient. Furthermore, echocardiography can facilitate evaluation for the several associated defects that can be present in critical neonatal AS, including mitral stenosis, LV hypoplasia, LV endo-cardial fibroelastosis, subaortic stenosis, VSD, or coarctation. The presence of any or several of these defects has important impli-cations related to treatment options for these patients. Although cardiac catheterization is not routinely performed for diagnostic purposes, it can be invaluable as part of the treatment algorithm if the lesion is amenable to balloon valvotomy. Magnetic resonance imaging (MRI) is another very useful technique for assessing the adequacy of the left-sided structures and is increasingly utilized to determine candidacy for biventricular repairs.Treatment. As alluded to previously, the first decision that must be made in the neonate with critical LVOT obstruction is whether the patient is a candidate for biventricular or univen-tricular repair. Central to this decision is assessment of the degree of hypoplasia of the LV and other left-sided structures. Alsoufi and colleagues25 have described a rational approach to the neonate with critical LVOT obstruction. The options vary depending on whether the infant follows a single or a 3biventricular pathway. The options for a single ventricle include the Norwood operation, a hybrid strategy (initial ductal stent and bilateral pulmonary artery bands followed by later completion of the Norwood operation) or heart transplantation. The options for a biventricular heart include balloon valvuloplasty, surgical val-votomy, neonatal Ross operation, or a Yasui operation. Often valvotomy is accompanied by LV rehabilitation techniques, including EFE resection and mitral valve interventions. Fetal aortic valvotomy, which is now offered at specialized centers, is another promising strategy to decompress the LV in fetal life and potentially allow growth of the left-sided structures sufficient to permit a biventricular circulation. Regardless of whether the baby is triaged to a single or biventricular strategy, any infant with severe AS requires urgent intervention. Preoperative stabi-lization, however, has dramatically altered the clinical algorithm and outcomes for this patient population.25 The preoperative strategy begins with endotracheal intubation and inotropic sup-port. Prostaglandin infusion is initiated to maintain ductal patency, and confirmatory studies are performed prior to opera-tive intervention. Therapy is generally indicated in the presence of a transvalvular gradient of 50 mmHg with associated symp-toms including syncope, CHF, or angina, or if a gradient of 50 to 75 mmHg exists with concomitant ECG evidence of LV strain or ischemia. In the critically ill neonate, a gradient across the aortic valve may not be present because of poor LV function. However, the decision regarding treatment options must be based on a complete understanding of associated defects. For example, in the presence of a hypoplastic LV (left ventricular end-diastolic volume <20 mL/m2) or a markedly abnormal mitral valve, iso-lated aortic valvotomy should not be performed because studies have demonstrated high mortality in this population following isolated valvotomy.26Patients who have an LV capable of providing systemic output are candidates for intervention to relieve AS, generally through balloon valvotomy. Occasionally, if catheter-based therapy is not an option, relief of valvular AS in infants and children can be accomplished with surgical valvotomy using standard techniques of CPB and direct exposure to the aortic valve. A transverse incision is made in the ascending aorta above the sinus of Valsalva, extending close to, but not into, the noncoronary sinus. Exposure is attained with placement of a retractor into the right coronary sinus. After inspection of the valve, the chosen commissure is incised to within 1 to 2 mm of the aortic wall (Fig. 20-4A,B).Balloon valvotomy performed in the catheterization lab is generally the procedure of choice for reduction of transvalvular gradients in symptomatic infants and children without signifi-cant aortic insufficiency. Balloon valvotomy provides relief of the valvular gradient and allows future surgical intervention (which is generally required in most patients when a larger prosthesis can be implanted) to be performed on an unscarred chest. An important issue when planning aortic valvotomy, whether percutaneously or via open surgical technique, is the risk of inducing hemodynamically significant aortic regurgita-tion. Induction of more than moderate aortic regurgitation is poorly tolerated in the infant with critical AS and may require an urgent procedure to replace or repair the aortic valve. Most often in these patients, a Ross procedure represents the only real option as mechanical valve replacement in a neonate has exceptionally poor outcome.In general, catheter-based balloon valvotomy has supplanted open surgical valvotomy. The decision regarding Brunicardi_Ch20_p0751-p0800.indd 75722/02/19 2:54 PM 758SPECIFIC CONSIDERATIONSPART IIFigure 20-4. A. Intra-operative picture of a stenotic bicuspid aortic valve (as seen through an aortotomy). B. Intra-operative picture of the valve after a controlled valvotomy if performed. Note the forceps is across the opening of the aortic valve (‘*’ points to the valvotomy).the most appropriate method to use depends on several factors, including the available medical expertise, the patient’s overall status and hemodynamics, and the presence of associated cardiac defects requiring repair.25 Although evidence is emerging to the contrary, simple valvotomy, whether performed using percutaneous or open technique, is generally considered a palliative procedure. The goal is to relieve LVOT obstruction without producing clinically significant regurgitation, in order to allow sufficient annular growth for eventual aortic valve replacement. The reintervention rate is higher if balloon valvuloplasty is performed as the initial palliation (54%) compared to a surgical valvolomy (23%) as the latter is a more controlled division of the aortic commissure25 (Fig. 20-4C). The majority of infants who undergo aortic valvotomy will require further intervention on the aortic valve within 10 years following initial intervention.26Neonates with severely hypoplastic LVs or significant LV endocardial fibroelastosis may not be candidates for biventricu-lar repair and are treated the same as infants with the hypoplas-tic left heart syndrome (HLHS), which is discussed later (see “Hypoplastic Left Heart Syndrome”).As mentioned previously, fetal intervention for the aortic valve has been described with the goal being to improve the growth of the left ventricle. The group at Boston Children’s Hospital have reported fairly favorable results in a small cohort.34Many surgeons previously avoided aortic valve replace-ment for AS in early childhood because the more commonly used mechanical valves would be outgrown and require replace-ment later and the obligatory anticoagulation for mechanical valves resulted in a substantial risk for complications. In addi-tion, prosthetic valves have an incidence of bacterial endocardi-tis or perivalvular leak requiring reintervention.The use of allografts and the advent of the Ross procedure have largely obviated these issues and made early definitive cor-rection of critical AS a viable option.23,27,28 Donald Ross first described transposition of the pulmonary valve into the aortic position with allograft reconstruction of the pulmonary outflow tract in 1967.27 The result of this operation is a normal trileaf-let semilunar valve made of a patient’s native tissue with the potential for growth to adult size in the aortic position in place of the damaged aortic valve (Fig. 20-5). The Ross procedure has become a useful option for aortic valve replacement in children because it has improved durability and can be performed with acceptable morbidity and mortality rates. The placement of a pulmonary conduit, which does not grow and becomes calci-fied and stenotic over time, does obligate the patient to rein-tervention (either surgically or using transcatheter techniques) to replace the RV-to-pulmonary artery conduit. Karamlou and colleagues29 have reviewed the outcomes and associated risk factors for aortic valve replacement in 160 children from the Hospital for Sick Children in Toronto. They found that younger age, lower operative weight, concomitant performance of aortic root replacement or reconstruction, and use of prosthesis type other than a pulmonary autograft were significant predictors of death, whereas the use of a bioprosthetic or allograft valve type and earlier year of operation were identified as significant risk factors for repeated aortic valve replacement. Autograft use was associated with a blunted progression of the peak prosthetic valve gradient and a rapid decrease in the left ventricular end-diastolic dimension. In agreement with these findings, Lupinetti and Jones28 compared allograft aortic valve replacement with the Ross procedure and found a more significant transvalvular gradient reduction and regression of left ventricular hypertro-phy in those patients who underwent the Ross procedure. In some cases, the pulmonary valve may not be usable because of associated defects or congenital absence. These children are not candidates for the Ross procedure and can be treated with cryopreserved allografts (cadaveric human aortic valves) or prosthetic aortic valve replacement. At times, there may be a size discrepancy between the right ventricular outflow tract (RVOT) and the LVOT, especially in cases of severe critical AS in infancy. For these cases, the pulmonary autograft is placed in a manner that also provides enlargement of the aortic annulus (Ross/Konno).Subvalvular AS occurs beneath the aortic valve and may be classified as discrete or tunnel-like (diffuse). A thin, ABBrunicardi_Ch20_p0751-p0800.indd 75822/02/19 2:54 PM 759CONGENITAL HEART DISEASECHAPTER 20fibromuscular diaphragm immediately proximal to the aortic valve characterizes discrete subaortic stenosis. This diaphragm typically extends for 180o or more in a crescentic or circular fash-ion, often attaching to the mitral valve as well as the interven-tricular septum. The aortic valve itself is usually normal in this condition, although the turbulence imparted by the subvalvular stenosis may affect leaflet morphology and valve competence.Diffuse subvalvular AS results in a long, tunnel-like obstruction that may extend to the left ventricular apex. In some individuals, there may be difficulty in distinguishing between hypertrophic cardiomyopathy and diffuse subaortic steno-sis. Operation for subvalvular AS is indicated with a gradient exceeding 30 mmHg, in the presence of aortic valve insuffi-ciency, or when symptoms indicating LVOT obstruction are present.30 Given that repair of isolated discrete subaortic ste-nosis can be done with low rates of morbidity and mortality, some surgeons advocate repair in all cases of discrete AS to avoid progression of the stenosis and the development of aortic insufficiency, although more recent data demonstrate that sub-aortic resection should be delayed until the LV gradient exceeds 30 mmHg because most children with an initial LV gradient less than 30 mmHg have quiescent disease.31 Diffuse AS is a more complex lesion and often requires aortoventriculoplasty. Results are generally excellent, with operative mortality less than 5%.32Supravalvular AS occurs more rarely and also can be clas-sified into a discrete type, which produces an hourglass defor-mity of the aorta, and a diffuse form that can involve the entire arch and brachiocephalic arteries. The aortic valve leaflets are usually normal, but in some cases, the leaflets may adhere to the supravalvular stenosis, thereby narrowing the sinuses of Valsalva in diastole and restricting coronary artery perfusion. In addition, accelerated intimal hyperplastic changes in the coronary arteries can be demonstrated in these patients because the proximal position of the coronary arteries subjects them to abnormally high perfusion pressures.The signs and symptoms of supravalvular AS are similar to other forms of LVOT obstruction. An asymptomatic murmur is the presenting manifestation in approximately half of these patients. Syncope, poor exercise tolerance, and angina may all occur with nearly equal frequency. Supravalvar AS is associated with Williams’ syndrome, a constellation of elfin facies, mental retardation, and hypercalcemia.33 Following routine evaluation, cardiac catheterization should be performed in order to delin-eate coronary anatomy, as well as to delineate the degree of obstruction. A gradient of 50 mmHg or greater is an indication for operation. However, the clinician must be cognizant of any coexistent lesions, most commonly pulmonic stenosis, which may add complexity to the repair.The localized form of supravalvular AS can be treated by creating an inverted Y-shaped aortotomy across the area of ste-nosis, straddling the right coronary artery. The obstructing shelf is then excised, and a pantaloon-shaped patch (Doty technique) or individual sinus patch enlargement (Brom technique) is used (Fig. 20-3E).The diffuse form of supravalvular stenosis is more vari-able (Fig. 20-6), and the particular operative approach must be tailored to each specific patient’s anatomy. In general, either an aortic endarterectomy with patch augmentation can be per-formed or if the narrowing extends past the aorta arch, a pros-thetic graft can be placed between the ascending and descending aorta. Operative results for discrete supravalvular AS are gen-erally good, with a hospital mortality of less than 1% and an actuarial survival rate exceeding 90% at 20 years.35 In contrast, however, the diffuse form is more hazardous to repair and car-ried a mortality of 15% in a recent series.35,36Patent Ductus ArteriosusAnatomy. The ductus arteriosus is derived from the sixth aor-tic arch and normally extends from the main or left pulmonary artery to the upper descending thoracic aorta, distal to the left subclavian artery. In the normal fetal cardiovascular system, ductal flow is considerable (approximately 60% of the com-bined ventricular output) and is directed exclusively from the pulmonary artery to the aorta. In infancy, the length of the duc-tus may vary from 2 to 8 mm, with a diameter of 4 to 12 mm.Locally produced and circulating prostaglandin E2 (PGE2) and prostaglandin I2 (PGI2) induce active relaxation of the duc-tal musculature, maintaining maximal patency during the fetal period.38 At birth, increased pulmonary blood flow metabo-lizes these prostaglandin products, and absence of the placenta removes an important source of them, resulting in a marked decrease in these ductal-relaxing substances. In addition, release of histamines, catecholamines, bradykinin, and acetylcholine all promote ductal contraction. Despite all of these complex Figure 20-5. Appearance of the stenotic aortic valve during aortography performed in the cardiac catheterization lab. (left). Balloon valvuloplasty being performed. (right). The ‘*’ points to the the “waist” created by the stenotic valve during dilation. (Used with permission from Kelly Rosso MD.)Brunicardi_Ch20_p0751-p0800.indd 75922/02/19 2:54 PM 760SPECIFIC CONSIDERATIONSPART IIFigure 20-6. Reformatted image obtained after CT angiography of a child with diffuse supravalvar aortic stenosis (‘*’ points to the transverse aortic arch).interactions, the rising oxygen tension in the fetal blood is the main stimulus causing smooth muscle contraction and ductal closure within 10 to 15 hours postnatally.39 Anatomic closure by fibrosis produces the ligamentum arteriosum connecting the pulmonary artery to the aorta.Delayed closure of the ductus is termed prolonged patency, whereas failure of closure causes persistent patency, which may occur as an isolated lesion or in association with more complex congenital heart defects. In many of these infants with more complex congenital heart defects, either pulmonary or systemic perfusion may depend on ductal flow, and these infants may decompensate if exogenous PGE is not administered to maintain ductal patency.Natural History. The incidence of patent ductus arteriosus (PDA) is approximately 1 in every 2000 births; however, it increases dramatically with increasing prematurity.39 In some series, PDAs have been noted in 75% of infants of 28 to 30 weeks gestation. Persistent patency occurs more commonly in females, with a 2:1 ratio.40PDA is not a benign entity, although prolonged survival has been reported. The estimated death rate for infants with iso-lated, untreated PDA is approximately 30%.41 The leading cause of death is congestive heart failure, with respiratory infection as a secondary cause. Endocarditis is more likely to occur with a small ductus and is rarely fatal if aggressive antibiotic therapy is initiated early.Clinical Manifestations and Diagnosis. After birth, in an otherwise normal cardiovascular system, a PDA results in a left-to-right shunt that depends on both the size of the ductal lumen and its total length. As the pulmonary vascular resistance falls 8 to 10 weeks postnatally, the shunt will increase, and its flow will ultimately be determined by the relative resistances of the pulmonary and systemic circulations.The hemodynamic consequences of an unrestrictive duc-tal shunt are left ventricular volume overload with increased left atrial and pulmonary artery pressures and right ventricular strain from the augmented afterload. These changes result in increased sympathetic discharge, tachycardia, tachypnea, and ventricular hypertrophy. The diastolic shunt results in lower aortic diastolic pressure and increases the potential for myo-cardial ischemia and underperfusion of other systemic organs, while the increased pulmonary flow leads to increased work of breathing and decreased gas exchange. Unrestrictive ductal flow may lead to pulmonary hypertension within the first year of life. These changes will be significantly attenuated if the size of the ductus is only moderate, and they will be completely absent if the ductus is small.Physical examination of the afflicted infant will reveal evi-dence of a hyperdynamic circulation with a widened pulse pres-sure and a hyperactive precordium. Auscultation demonstrates a systolic or continuous murmur, often termed a machinery mur-mur. Cyanosis is not present in uncomplicated isolated PDA.The chest radiograph may reveal increased pulmonary vascularity or cardiomegaly, and the ECG may show LV strain, left atrial enlargement, and possibly RV hypertrophy. Echocar-diogram with color mapping reliably demonstrates the patency of the ductus as well as estimates the shunt size. Cardiac cath-eterization is necessary only when pulmonary hypertension is suspected.Therapy. The presence of a persistent PDA is sufficient indica-tion for closure because of the increased mortality and risk of endocarditis.40 In older patients with pulmonary hypertension, closure may not improve symptoms and is associated with much higher mortality.In premature infants, aggressive intervention with indometh-acin or ibuprofen to achieve early closure of the PDA is beneficial unless contraindications such as necrotizing enterocolitis or renal insufficiency are present.41 Term infants, however, are gener-ally unresponsive to pharmacologic therapy with indomethacin, so mechanical closure must be undertaken once the diagnosis is established. This can be accomplished either surgically (Fig. 20-7) or with catheter-based therapy.15,42,43 Currently, transluminal placement of various occlusive devices, such as the Rashkind double-umbrella device or embolization with Gianturco coils, is in widespread use.42 However, there are a number of complications inherent with the use of percutaneous devices, such as thromboem-bolism, endocarditis, incomplete occlusion, vascular injury, and hemorrhage secondary to perforation.43 In addition, these tech-niques may not be applicable in very young infants because the peripheral vessels do not provide adequate access for the delivery devices. Attempts are being made to develop such devices for pre-mature infants with early successful results in study populations.44Surgical closure can be achieved via either open or video-assisted approaches. The open approach employs a muscle-sparing posterior lateral thoracotomy in the third or fourth intercostal space on the side of the aorta (generally the left). The lung is then retracted anteriorly. In the neonate, the PDA is singly ligated with a surgical clip or permanent suture. Care must be taken to avoid the recurrent laryngeal nerve, which courses around the PDA. The PDA can also be ligated via a median sternotomy; however, this approach is generally reserved for patients who have additional cardiac or great vessel lesions requiring repair. Occasionally, a short, broad ductus, in which the dimension of Brunicardi_Ch20_p0751-p0800.indd 76022/02/19 2:54 PM 761CONGENITAL HEART DISEASECHAPTER 20its width approaches that of its length, will be encountered. In this case, division between vascular clamps with oversewing of both ends is advisable (Fig. 20-8). In extreme cases, the use of CPB to decompress the large ductus during ligation is an option.Video-assisted thoracoscopic occlusion, using metal clips, also has been described, although it offers few advantages over the standard surgical approach. Preterm newborns and children may do well with a surgical technique, while older patients (older than age 5 years) and those with smaller ducts (<3 mm) do well with coil occlusion. In fact, Moore and colleagues recently concluded from their series that coil occlusion is the procedure Figure 20-7. Chest x-ray before and after PDA ligation showing the dramatic improvement in the lung fields after ligation (arrow points to the clip used for PDA ligation).Figure 20-8. Surgical PDA ligation. A clip has been applied to occlude the ductus arteriosus. Note the relationship of the recurrent laryngeal nerve to the ductus arteriosus. (Used with permission from Kelly Rosso MD.)of choice for ducts smaller than 4 mm.45 Complete closure rates using catheter-based techniques have steadily improved.Outcomes. In premature infants, the surgical mortality is very low, although the overall hospital death rate is significant as a consequence of other complications of prematurity. In older infants and children, mortality is less than 1%. Bleeding, chylo-thorax, vocal cord paralysis, and the need for reoperation occur infrequently. With the advent of muscle-sparing thoracotomy, the risk of subsequent arm dysfunction or breast abnormalities is virtually eliminated.46Aortic CoarctationAnatomy. Coarctation of the aorta (COA) is defined as a lumi-nal narrowing in the aorta that causes an obstruction to blood flow. This narrowing is most commonly located distal to the left subclavian artery. The embryologic origin of COA is a sub-ject of some controversy. One theory holds that the obstructing shelf, which is largely composed of tissue found within the duc-tus, forms as the ductus involutes.47 The other theory holds that a diminished aortic isthmus develops secondary to decreased aortic flow in infants with enhanced ductal circulation.Extensive collateral circulation develops, predominantly involving the intercostals and mammary arteries as a direct result of aortic flow obstruction. This translates into the well-known finding of “rib-notching” on chest radiograph, as well as a prominent pulsation underneath the ribs.Other associated anomalies, such as ventricular septal defect, PDA, and ASD, may be seen with COA, but the most common is that of a bicuspid aortic valve, which can be demon-strated in 25% to 42% of cases.48Pathophysiology. Infants with COA develop symptoms con-sistent with left ventricular outflow obstruction, including pulmo-nary overcirculation and, later, biventricular failure. In addition, proximal systemic hypertension develops as a result of mechanical obstruction to ventricular ejection, as well as hypoperfusion-induced activation of the renin-angiotensin-aldosterone system. PAAoBrunicardi_Ch20_p0751-p0800.indd 76122/02/19 2:54 PM 762SPECIFIC CONSIDERATIONSPART IIFigure 20-9. Reformatted images obtained from CT angiography of a baby showing a descrete coarctation of the aorta (‘*’ points to the coarctation).ABFigure 20-10. A. Reformatted images obtained from a CT angio-gram of a child with discrete coarctation of the aorta (‘*’ points to the coarctation). B. Aortogram performed in the cardiac catheteriza-tion lab after stenting the coarctation (‘*’ points to the stent).Interestingly, hypertension is often persistent after surgical correction despite complete amelioration of the mechanical obstruction and pressure gradient.49 It has been shown that early surgical correction may prevent the development of long-term hypertension, which undoubtedly contributes to many of the adverse sequelae of COA, including the development of circle of Willis aneurysms, aortic dissection and rupture, and an increased incidence of coronary arteriopathy with resulting myocardial infarction.50Diagnosis. COA is likely to become symptomatic either in the newborn period if other anomalies are present or in the late ado-lescent period with the onset of left ventricular failure.Physical examination will demonstrate a hyperdynamic precordium with a harsh murmur localized to the left chest and back. Femoral pulses will be dramatically decreased when com-pared to upper extremity pulses, and differential cyanosis may be apparent until ductal closure.Echocardiography will reliably demonstrate the narrowed aortic segment, as well as define the pressure gradient across the stenotic segment. In addition, detailed information regarding other associated anomalies can be gleaned. Aortography (Fig. 20-9) is reserved for those cases in which the echocardiographic findings are equivocal. Cross-sectional imaging with computed tomogra-phy (CT) scan or MRI is also increasing to facilitate definition of arch anatomy (i.e., transverse arch hypoplasia), assess intracardiac volumes, and associated defects.Therapy. The routine management of hemodynamically sig-nificant COA in all age groups has traditionally been surgical. Transcatheter repairs (Fig. 20-10) are used with increasing frequency in older patients and those with recoarctation fol-lowing surgical repair. Balloon dilatation of native coarctation in neonates generally is avoided because of the high recoarc-tation rate. However, in infants who present with severely depressed LV function and a closed ductus arteriosus, initial decompression with balloon dilation of the COA followed by later surgical intervention may be useful. The most common surgical techniques in current use are resection with end-to-end anastomosis or extended end-to-end anastomosis, taking care to remove all residual ductal tissue.51,52 Extended end-to-end anastomosis (Fig. 20-11) may also allow the surgeon to treat transverse arch hypoplasia, which is commonly encoun-tered in infants with aortic coarctation.53,54 The subclavian flap Brunicardi_Ch20_p0751-p0800.indd 76222/02/19 2:55 PM 763CONGENITAL HEART DISEASECHAPTER 20aortoplasty is another repair, although it is used less frequently in the modern era because of the risk of late aneurysm formation and possible underdevelopment of the left upper extremity isch-emia.52 In this method, the left subclavian artery is transected and brought down over the coarcted segment as a vascular-ized patch. The main benefit of these techniques is that they do not involve the use of prosthetic materials, and evidence sug-gests that extended end-to-end anastomosis may promote arch growth, especially in infants with the smallest initial aortic arch diameters.53Despite the benefits, however, extended end-to-end anas-tomosis may not be feasible when there is a long segment of coarctation or in the presence of previous surgery because suf-ficient mobilization of the aorta above and below the lesion may not be possible. In this instance, prosthetic materials, such as a patch aortoplasty, in which a prosthetic patch is used to enlarge the coarcted segment, or an interposition tube graft must be employed. One of the most important decisions in infants and neonates with COA and some degree of transverse arch hypoplasia is whether the lesion should be approached with a sternotomy or a thoracotomy. Cross-sectional imaging with CT scan can be extremely helpful in assessing the adequacy of the transverse arch and any associated abnormalities with branching that may complicate repair from the side.The most common complications after COA repair are late restenosis (Fig. 20-12) and aneurysm formation at the repair site.55-57 Aneurysm formation is particularly common after patch aortoplasty when using Dacron material. In a large series of 891 patients, aneurysms occurred in 5.4% of the total, with 89% occurring in the group who received Dacron-patch aortoplasty and only 8% occurring in those who received resection with primary end-to-end anastomosis.55 A further complication, although uncommon, is lower-body paralysis resulting from ischemic spinal cord injury during the repair. This dreaded outcome complicates 0.5% of all surgical repairs, but its incidence can be lessened with the use of some form of distal perfusion, preferably left heart bypass with the use of femoral arterial or distal thoracic aorta for arterial inflow and Figure 20-11. Appearance of the aorta after resection of the seg-ment of coarctation and reconstruction with an extended end-to-end anastomosis. (Used with permission from Kelly Rosso MD.)Figure 20-12. Reformatted images obtained from a CT angiogram after recurrent coarctation repaired by an extra anatomic bypass (‘*’ points to the bypass graft).the femoral vein or left atrium for venous return.51 These tech-niques are generally reserved for older patients with complex coarctations that may need prolonged aortic cross clamp times for repair, often in the setting of large collateral vessels and/or previous surgery.58Hypertension is also well recognized following repair of COA. Bouchart and colleagues reported that in a cohort of 35 hypertensive adults (mean age, 28 years) undergoing repair, despite a satisfactory anatomic outcome, only 23 patients were normotensive at a mean follow-up period of 165 months.56 Like-wise, Bhat and associates reported that in a series of 84 patients (mean age at repair, 29 years), 31% remained hypertensive at a mean follow-up of 5 years following surgery.57Although operative repair is still the gold standard, treat-ment of COA by catheter-based intervention has become more widespread for older children and adults. Both balloon dilata-tion and primary stent implantation have been used successfully. The most extensive study of the results of balloon angioplasty reported on 970 procedures: 422 native and 548 recurrent COAs. Mean gradient reduction was 74% ± 24% for native and 70% ± 31% for recurrent COA.59 This demonstrated that catheter-based therapy could produce equally effective results both in recurrent and in primary COA, a finding with far-reaching implications in the new paradigm of multidisciplinary treatment algorithms for CHD. In the Valvuloplasty and Angioplasty of Congeni-tal Anomalies (VACA) report, higher preangioplasty gradient, earlier procedure date, older patient age, and the presence of recurrent COA were independent risk factors for suboptimal procedural outcome.5The gradient after balloon dilatation in most series is gen-erally acceptable. However, there is a significant minority of patients (0%–26%) for whom the procedural outcome is sub-optimal, with a postprocedure gradient of 20 mmHg or greater. These patients may be ideal candidates for primary stent place-ment. Deaths from the procedure also are infrequent (<1% of cases), and the main major complication is aneurysm formation, PAAoBrunicardi_Ch20_p0751-p0800.indd 76322/02/19 2:55 PM 764SPECIFIC CONSIDERATIONSPART IIwhich occurs in 7% of patients.51 With stent implantation, many authors have demonstrated improved resolution of stenosis compared with balloon dilatation alone, yet the long-term com-plications on vessel wall compliance remain largely unknown because only mid-term data are widely available.In summary, children younger than age 6 months with native COA should be treated with surgical repair, while those requiring intervention at later ages may be ideal candidates for balloon dilatation or primary stent implantation.51 Additionally, catheter-based therapy should be employed for those cases of restenosis following either surgical or primary endovascular management.Truncus ArteriosusAnatomy. Truncus arteriosus is a rare anomaly, compris-ing between 1% and 2% of all live born cases of CHD.60 It is characterized by a single great artery that arises from the heart, overrides the ventricular septum, and supplies the pulmonary, systemic, and coronary circulations.The two major classification systems are those of Collett and Edwards, described in 1949, and Van Praagh, described in 1965 (Fig. 20-13).61,62 The Collett and Edwards classification focuses mainly on the origin of the pulmonary arteries from the common arterial trunk, whereas the Van Praagh system is based on the presence or absence of a VSD, the degree of formation of the aorticopulmonary septum, and the status of the aortic arch.During embryonic life, the truncus arteriosus normally begins to separate and spiral into a distinguishable anterior pul-monary artery and posterior aorta. Persistent truncus, therefore, represents an arrest in embryologic development at this stage.63 Other implicated events include twisting of the dividing trun-cus because of ventricular looping, subinfundibular atresia, and abnormal location of the semilunar valve anlages.64The neural crest may also play a crucial role in the normal formation of the great vessels, as experimental studies in chick embryos have shown that ablation of the neural crest results in persistent truncus arteriosus.65 The neural crest also develops into the pharyngeal pouches that give rise to the thymus and parathyroids, which likely explains the prevalent association of truncus arteriosus and DiGeorge’s syndrome.66The annulus of the truncal valve usually straddles the ventricular septum in a “balanced” fashion; however, it is not unusual for it to be positioned predominantly over the RV, which increases the potential for LVOT obstruction following surgical repair. In the great majority of cases, the leaflets are thickened and deformed, which leads to valvular insufficiency. There are usually three leaflets (60%), but occasionally a bicus-pid (5%) or even a quadricuspid valve (25%) is present.61In truncus arteriosus, the pulmonary trunk bifurcates, with the left and right pulmonary arteries forming posteriorly and to the left in most cases. The caliber of the pulmonary arterial branches is usually normal, with stenosis or diffuse hypoplasia occurring in rare instances.The coronary arteries may be normal; however, anomalies are not unusual and occur in 50% of cases.67 Many of these are relatively minor, although two variations are of particular importance because they have implications in the conduct of operative repair. The first is that the left coronary ostium may arise high in the sinus of Valsalva or even from the truncal tis-sue at the margin of the pulmonary artery tissue. This coronary artery can be injured during repair when the pulmonary arteries are removed from the trunk or when the resulting truncal defect is closed. The second is that the right coronary artery can give rise to an important accessory anterior descending artery, which often passes across the RV in the exact location where the right ventriculotomy is commonly performed during repair.68Physiology and Diagnosis. The main pathophysiologic con-sequences of truncus arteriosus are (a) the obligatory mixing of systemic and pulmonary venous blood at the level of the ven-tricular septal defect (VSD) and truncal valve, which leads to arterial saturations near 85% and (b) the presence of a nonre-strictive left-to-right shunt, which occurs during both systole and diastole, the volume of which is determined by the relative resistances of the pulmonary and systemic circulations. Addi-tionally, truncal valve stenosis or regurgitation, the presence of important LVOT obstruction, and stenosis of pulmonary artery branches can further contribute to both pressure and volume-loading of the ventricles. The presence of these lesions often results in severe heart failure and cardiovascular instability early in life. Pulmonary vascular resistance may develop as early as 6 months of age, leading to poor results with late surgical correction.Patients with truncus arteriosus usually present in the neo-natal period, with signs and symptoms of congestive heart fail-ure and mild to moderate cyanosis. A pansystolic murmur may be noted at the left sternal border, and occasionally a diastolic murmur may be heard in the presence of truncal regurgitation.Chest radiography will be consistent with pulmonary over-circulation, and a right aortic arch can be appreciated 35% of the time. The thymus is prominent by its absence if associated with DiGeorge syndrome (Fig. 20-14). The ECG is usually non-specific, demonstrating normal sinus rhythm with biventricular hypertrophy.Echocardiography with Doppler color-flow or pulsed Doppler is diagnostic and usually provides sufficient informa-tion to determine the type of truncus arteriosus, the origin of the Figure 20-13. Collett & Edwards classification for Truncus arteriosus. (Used with permission from Kelly Rosso MD.)RPARPARPAType 1Type 2Type 3LPALPALPABrunicardi_Ch20_p0751-p0800.indd 76422/02/19 2:55 PM 765CONGENITAL HEART DISEASECHAPTER 20coronary arteries and their proximity to the pulmonary trunk, the character of the truncal valves, and the extent of truncal insuffi-ciency (Fig. 20-15). CT scan helps define the pulmonary arteries and the coronary anatomy (Fig. 20-16). Cardiac catheterization can be helpful in cases where pulmonary hypertension is sus-pected or to further delineate coronary artery anomalies prior to repair.The presence of truncus is an indication for surgery. Repair should be undertaken in the neonatal period or as soon as the diagnosis is established.Repair. Truncus arteriosus was first managed with pulmonary artery banding as described by Armer and colleagues in 1961.69 However, this technique led to only marginal improvements in 1-year survival rates because ventricular failure inevitably occurred. In 1967, however, complete repair was accomplished by McGoon and his associates based on the experimental work of Rastelli, who introduced the idea that an extracardiac valved conduit could be used to restore ventricular-to-pulmonary artery continuity.70 Over the next 20 years, improved survival rates led to uniform adoption of complete repair even in the youngest and smallest infants.71Surgical correction entails the use of CPB. Repair is completed by separation of the pulmonary arteries from the aorta, closure of the aortic defect (occasionally with a patch) to minimize coronary flow complications, placement of a valved cryopreserved allograft or jugular venous valved conduit (Con-tegra) to reconstruct the RVOT, and VSD closure. Important branch pulmonary arterial stenosis should be repaired at the time of complete repair and can usually be accomplished with longitudinal allograft patch arterioplasty. Severe truncal valve insufficiency occasionally requires truncal valve repair or even replacement, which can be accomplished with a cryopreserved allograft.72Results. The results of complete repair of truncus have steadily improved. Ebert reported a 91% survival rate in his series of 77 patients who were younger than 6 months of age; later reports by others confirmed these findings and demonstrated that excel-lent results could be achieved in even smaller infants with com-plex-associated defects.71Newer extracardiac conduits also have been developed and used with success, which has widened the repertoire of the modern congenital heart surgeon and improved outcomes.72,73 Severe truncal regurgitation, interrupted aortic arch, coexistent coronary anomalies, chromosomal or genetic anomalies, and age younger than 100 days are risk factors associated with peri-operative death and poor outcome.Total Anomalous Pulmonary Venous ConnectionTotal anomalous pulmonary venous connection (TAPVC) occurs in 1% to 2% of all cardiac malformations and is char-acterized by abnormal drainage of the pulmonary veins into the right heart, whether through connections into the right atrium or into its tributaries.74 Accordingly, the only mechanism by which oxygenated blood can return to the left heart is through an ASD, which is almost uniformly present with TAPVC.Figure 20-14. Chest x-ray of a baby with DiGeorge syndrome and truncus arteriosus. Note the absence of the thymic shadow in the superior mediastinum (‘*’).Figure 20-15. Echo appearance of a baby with Truncus Ateriosus. The ‘*’ represents the VSD, and the arrow points to the truncal valve.Figure 20-16. CT scan of a baby with Truncus Arteriosus Type 2. The ‘*’ mark the RPA and the LPA. Note the stenosis at the origin of the LPA.Brunicardi_Ch20_p0751-p0800.indd 76522/02/19 2:55 PM 766SPECIFIC CONSIDERATIONSPART IIUnique to this lesion is the absence of a definitive form of palliation. Thus, TAPVC with concomitant obstruction (Fig. 20-17) represents one of the only true surgical emergen-cies across the entire spectrum of congenital heart surgery.Anatomy and Embryology. The lungs develop from an out-pouching of the foregut, and their venous plexus arises as part of the splanchnic venous system. TAPVC arises when the pul-monary vein evagination from the posterior surface of the left atrium fails to fuse with the pulmonary venous plexus surround-ing the lung buds. In place of the usual connection to the left atrium, at least one connection of the pulmonary plexus to the splanchnic plexus persists. Accordingly, the pulmonary veins drain to the heart through a systemic vein.Darling and colleagues classified TAPVC (Fig. 20-18) according to the site or level of connection of the pulmonary veins to the systemic venous system75: type I (45%), anomalous connection at the supracardiac level; type II (25%), anomalous connection at the cardiac level; type III (25%), anomalous con-nection at the infracardiac level; and type IV (5%), anomalous connection at multiple levels.76 Within each category, further subdivisions can be implemented, depending on whether pul-monary venous obstruction exists. Obstruction to pulmonary venous drainage is a powerful predictor of adverse natural out-come and occurs most frequently with the infracardiac type, especially when the pattern of infracardiac connection prevents the ductus venosus from bypassing the liver.77Pathophysiology and Diagnosis. Because both pulmonary and systemic venous blood returns to the right atrium in all forms of TAPVC, a right-to-left intracardiac shunt must be present in order for the afflicted infant to survive. This invariably occurs via a nonrestrictive patent foramen ovale. Because of this obliga-tory mixing, cyanosis is usually present, and its degree depends on the ratio of pulmonary to systemic blood flow. Decreased Figure 20-17. Infracardiac type of TAPVR. Note the stenosis (‘*’) of the descending vertical vein as it drains into the portal system.Figure 20-18. The various types of TAPVC as described by Darling and colleagues. (Used with permission from Nicholas Clarke MD.)pulmonary blood flow is a consequence of pulmonary venous obstruction, the presence of which is unlikely if the right ven-tricular pressure is less than 85% of systemic pressure.78The child with TAPVC may present with severe cyanosis and respiratory distress, necessitating urgent surgical interven-tion if a severe degree of pulmonary venous obstruction is pres-ent. However, in cases where there is no obstructive component, the clinical picture is usually one of pulmonary overcircula-tion, hepatomegaly, tachycardia, and tachypnea with feeding. In a child with serious obstruction, arterial blood gas analysis reveals severe hypoxemia (partial pressure of oxygen [Po2] < 20 mmHg), with metabolic acidosis.79Chest radiography (Fig. 20-19) will show normal heart size with generalized pulmonary edema. Two-dimensional echocardiography is very useful in establishing the diagnosis and also can assess ventricular septal position, which may be leftward secondary to small left ventricular volumes, as well as estimate the right ventricular pressure based on the height of the tricuspid regurgitant jet. Echocardiography can usually identify the pulmonary venous connections (types I to IV), and it is rarely necessary to perform other diagnostic tests.Cardiac catheterization is not recommended in these patients because the osmotic load from the intravenous contrast can exacerbate the degree of pulmonary edema.80 When cardiac catheterization is performed, equalization of oxygen saturations in all four heart chambers is a hallmark finding in this disease because the mixed blood returned to the right atrium gets dis-tributed throughout the heart.Therapy. Operative correction of TAPVC requires anastomo-sis of the common pulmonary venous channel to the left atrium, obliteration of the anomalous venous connection, and closure of the ASD.79,81IIIAIVCIVCSVCLPVLARARPVIVCRVLVRARVDVVVPVLVLASVCCPVIVCIIBIIISVCVVLPVCPVSVCRPRALARVLVCPVLALVRARVBrunicardi_Ch20_p0751-p0800.indd 76622/02/19 2:55 PM 767CONGENITAL HEART DISEASECHAPTER 20All types of TAPVC are approached through a median ster-notomy, and many surgeons use deep hypothermic circulatory arrest in order to achieve an accurate and widely patent anastomo-sis. The technique for supracardiac TAPVC includes early division of the vertical vein, retraction of the aorta and the superior vena cava laterally to expose the posterior aspect of the left atrium and the pulmonary venous confluence, and a side-to-side anastomosis between a long, horizontal biatrial incision and a longitudinal inci-sion within the pulmonary venous confluence. The ASD can then be closed with an autologous pericardial or synthetic patch.In patients with TAPVC to the coronary sinus without obstruction, a simple unroofing of the coronary sinus can be performed through a single right atriotomy with concomitant closure of the ASD. If pulmonary venous obstruction is pres-ent, the repair should include generous resection of roof of the coronary sinus.79Repair of infracardiac TAPVC entails ligation of the verti-cal vein at the diaphragm, followed by construction of a proximal, patulous longitudinal venotomy. This repair is usually performed by “rolling” the heart toward the left, thus exposing the left atrium where it usually overlies the descending vertical vein.As originally described by Lacour-Gayet and colleagues at the Marie-Lannelongue Hospital, Paris, and Coles and col-leagues at The Hospital for Sick Children, Toronto, the suture-less technique was developed for patients with anastomotic stenosis occurring after TAPVC repair.80,81 After determining that favorable outcomes were possible using this technique, it is currently used in selected patients upon initial presentation of TAPVC.81 Incisions are made in the venous confluence. Based on the surgeon’s discretion, the incisions are extended into both upper and lower pulmonary veins separately if judged to be important for an unobstructed pathway. An atriopericardial anastomosis is created using the pericardium adjacent to where the pulmonary veins enter the pericardium (Fig. 20-20). This anastomosis avoids direct contact with the incision site in the wall of the pulmonary veins and allows the free egress of blood from the lungs to the left atrium.The perioperative care of these infants is crucial because episodes of pulmonary hypertension can occur within the first 48 hours, which contribute significantly to mortality following repair. Muscle relaxants and narcotics should be administered during this period to maintain a constant state of anesthesia. Arterial partial pressure of carbon dioxide (Pco2) should be maintained at 30 mmHg with use of a volume ventilator, and the fraction of inspired oxygen (Fio2) should be increased to keep the pulmonary arterial pressure at less than two-thirds of the systemic pressure.Results. Results of TAPVC in infancy have markedly improved in recent years, with an operative mortality of 5% or less in some series.79-82 This improvement is probably multifac-torial, mainly as a consequence of early noninvasive diagnosis and aggressive perioperative management. The routine use of echocardiography; improvements in myocardial protection with specific attention to the RV; creation of a large, tension-free anastomosis with maximal use of the venous confluence and atrial tissue; use of a sutureless technique in selected cases; and prevention of pulmonary hypertensive events have likely played a major role in reducing operative mortality. The importance of risk factors for early mortality, such as venous obstruction at presentation, urgency of operative repair, and infradiaphrag-matic anatomic type, has been debated.81,83Bando and colleagues84 made the controversial statement that both preoperative pulmonary venous obstruction and ana-tomic type had been neutralized as potential risk factors beyond calendar year 1991. Hyde et al82 similarly reported that connec-tion type was not related to outcome. However, a large single-institution report of 377 children with TAPVC by the author from the Hospital for Sick Children in Toronto85 found that, although outcomes had improved over time, patient anatomic factors were still important determinants of both survival and the need for subsequent reoperation. Risk factors for postrepair death were earlier operation year, younger age at repair, cardiac connection type, and postoperative pulmonary venous obstruc-tion. Risk-adjusted estimated 1-year survival for a patient repaired at birth with unfavorable morphology in 2006 was 37% (95% confidence interval [CI], 8%–80%) compared with 96% (95% CI, 91%–99%) for a patient with favorable morphology repaired at age 1 year. Freedom from reoperation was 82% ± 6% 4Figure 20-19. Chest x-ray of a newborn with obstructed infracar-diac type of TAPVR rescued by ECMO. Note the ECMO cannulas in the right neck (‘*’).InfracardiacTAPVCConventionalRepairSuturelessRepairFigure 20-20. Differences between conventional repair of total anomalous pulmonary venous connection (TAPVC) and sutureless repair of TAPVC. In the sutureless techniques, there are no sutures placed in the fragile veins themselves. Rather, the pericardial flaps are used to create a “well” for the pulmonary venous return (bottom inset). Early and late extrinsic stenosis are thought to be reduced using this latter technique.Brunicardi_Ch20_p0751-p0800.indd 76722/02/19 2:55 PM 768SPECIFIC CONSIDERATIONSPART IIat 11 years after repair, with increased risk associated with mixed connection and postoperative pulmonary venous obstruction. A study from the Hospital for Sick Children, Toronto, showed a lower incidence of reoperation in the sutureless technique com-pared to conventional pulmonary venous confluence–left atrial anastomosis.86 However, there was no statistically significant difference suggesting similar results between the strategies. Although the sutureless technique appears to have favorable outcomes at primary repair for TAPVC, long-term follow-up is necessary to evaluate the occurrence of arrhythmias, such as complete heart block and atrial tachycardia, since an incision on the atrial septum and atrial wall is more invasive compared to the conventional technique.The most significant postoperative complication of TAPVC repair is pulmonary venous obstruction (Figure 20-21), which occurs 9% to 11% of the time, regardless of the surgi-cal technique employed. Mortality varies between 30% and 45%, and alternative catheter interventions do not offer defini-tive solutions.80 Recurrent pulmonary venous obstruction can be localized at the site of the pulmonary venous anastomosis (extrinsic), which usually can be cured with patch enlargement or balloon dilatation, or it may be secondary to endocardial thickening of the pulmonary venous ostia frequently resulting in diffuse pulmonary venous sclerosis (intrinsic), which car-ries a 66% mortality rate because few good solutions exist.77 More commonly, postrepair left ventricular dysfunction can occur as the noncompliant LV suddenly is required to handle an increased volume load from redirected pulmonary venous return. This can manifest as an increase in pulmonary artery pressure but is distinguishable from primary pulmonary hyper-tension (another possible postoperative complication following repair of TAPVC) from the elevated left atrial pressure and LV dysfunction along with echocardiographic evidence of poor LV contractility. In pulmonary hypertension, the left atrial pressure may be low, the LV may appear “underfilled” (by echocardiog-raphy), and the RV may appear dilated. In either case, postop-erative support for a few days with extracorporeal membrane oxygenation may be lifesaving, and TAPVC should be repaired in centers that have this capacity.Some investigators have speculated that preoperative pul-monary venous obstruction is associated with increased medial thickness within the pulmonary vasculature, which may predis-pose these infants to intrinsic pulmonary venous stenosis despite adequate pulmonary venous decompression.82 The majority of studies demonstrating that preoperative pulmonary venous obstruction is a predictor of subsequent need for reoperation to correct recurrent pulmonary venous obstruction lend credence to this notion.Cor TriatriatumAnatomy. Cor triatriatum is a rare congenital heart defect char-acterized by the presence of a fibromuscular diaphragm that par-titions the left atrium into two chambers: a superior chamber that receives drainage from the pulmonary veins, and an inferior chamber that communicates with the mitral valve and the LV (Fig. 20-22). An ASD frequently exists between the superior chamber and the right atrium, or, more rarely, between the right atrium and the inferior chamber.Pathophysiology and Diagnosis. Cor triatriatum results in obstruction of pulmonary venous return to the left atrium. The degree of obstruction is variable and depends on the size of fen-estrations present in the left atrial membrane, the size of the ASD, and the existence of other associated anomalies. If the communication between the superior and inferior chambers is <3 mm, patients usually are symptomatic during the first year of life. The afflicted infant will present with the stigmata of low cardiac output and pulmonary venous hypertension, as well as congestive heart failure and poor feeding.Physical examination may demonstrate a loud pulmonary S2 sound and a right ventricular heave, as well as jugular venous distention and hepatomegaly. Chest radiography will show car-diomegaly and pulmonary vascular prominence, and the ECG will suggest right ventricular hypertrophy. Two-dimensional echocardiography provides a definitive diagnosis in most cases, with catheterization necessary only when echocardiographic evaluation is equivocal.Therapy. Operative treatment for cor triatriatum is fairly simple. CPB and cardioplegic arrest are used. A right atriotomy usually Figure 20-21. Angiogram showing the discrete stenosis (‘*’) of the right-sided pulmonary veins after conventional repair for supra-cardiac type TAPVC.Figure 20-22. Echocardiogram (apical 4 chamber view) showing the discrete membrane (‘*’) in a patient with Cor triatritum.Brunicardi_Ch20_p0751-p0800.indd 76822/02/19 2:55 PM 769CONGENITAL HEART DISEASECHAPTER 20allows access to the left atrial membrane through the existing ASD because it is dilated secondary to communication with the pulmonary venous chamber. The membrane is then excised, tak-ing care not to injure the mitral valve or the interatrial septum, and the ASD is closed with a patch. Alternatively, if the right atrium is small, the membrane can be exposed through an inci-sion directly into the superior left atrial chamber, just anterior to the right pulmonary veins. Surgical results are uniformly excel-lent for this defect, with survival approaching 100%.The utility of catheter-based intervention for this diagnosis remains controversial, although there have been some reports of successful balloon dilatation.87Aortopulmonary WindowEmbryology and Anatomy. Aortopulmonary window (APW) is a rare congenital lesion, occurring in about 0.2% of patients, characterized by incomplete development of the septum that normally divides the truncus into the aorta and the pulmonary artery88In the vast majority of cases, APW occurs as a single defect of minimal length, which begins a few millimeters above the semilunar valves on the left lateral wall of the aorta (Fig. 20-23). Coronary artery anomalies, such as aberrant origin of the right or left coronary artery from the main pulmonary artery, are occa-sionally present.Pathophysiology and Diagnosis. The dominant pathophysi-ology of APW is that of a large left-to-right shunt with increased pulmonary flow and the early development of congestive heart failure. Like other lesions with left-to-right flow, the magnitude of the shunt is determined by both the size of the defect and the pulmonary vascular resistance.Infants with APW present with frequent respiratory tract infections, tachypnea with feeding, and failure to thrive. Cya-nosis usually is absent because these infants deteriorate prior to the onset of significant pulmonary hypertension. The rapid decline with this defect occurs because shunt flow continues during both phases of the cardiac cycle, which limits systemic perfusion and increases ventricular work.89The diagnosis of APW begins with the physical exami-nation, which may demonstrate a systolic flow murmur, a hyperdynamic precordium, and bounding peripheral pulses. The chest radiograph will show pulmonary overcirculation and cardiomegaly, and the ECG will usually demonstrate either left ventricular hypertrophy or biventricular hypertrophy. Echocar-diography (Fig. 20-24) can detect the defect and also provide information about associated anomalies. Retrograde aortogra-phy will confirm the diagnosis but is rarely necessary.Therapy. All infants with APW require surgical correction once the diagnosis is made. Repair is undertaken through a median sternotomy and the use of CPB. The pulmonary arteries are occluded once the distal aorta is cannulated, and a transaor-tic repair using a prosthetic patch for pulmonary artery closure is then carried out. The coronary ostia must be carefully visual-ized and included on the aortic side of the patch. Alternatively, a two-patch technique can be used, which may eliminate recurrent fistulas from suture line leaks that occasionally occur with the single-patch method.90Results. Results are generally excellent, with an operative mortality in most large series of less than 5%.Vascular Rings and Pulmonary Artery SlingsVascular rings constitute a group of disorders derived from anomalies that result from abnormal development of the aortic arches resulting in compression of the trachea or esophagus. The surgical management of vascular rings dates back to 1945 when Dr. Gross described the surgical management of a kid with double aortic arch.91 Most children present with symptoms during the first few months of life. Vascular rings can be com-plete (e.g., double aortic arch, right aortic arch with left liga-ment) or partial (e.g., innominate artery compression syndrome, pulmonary artery sling).Anatomy. The embryologic basis of vascular rings involves the development of six pairs of aortic arches and the dorsal and ventral aortae. The development of a specific type of vascular ring depends of the deletion or preservation of a specific seg-ment of these structures. The persistence of the right and left fourth arches leads to the development of double aortic arch. Persistence of the fourth right aortic arch and the involution of the left fourth arch leads to the development of a right aor-tic arch system with various combinations of mirror imaging Figure 20-23. Cartoon depicting the various types of aortopulmonary window. (Used with permission from Nicholas Clarke MD.)Figure 20-24. Echo demonstrating an aortopulmonary window (‘*’).Type IType IIType IIIBrunicardi_Ch20_p0751-p0800.indd 76922/02/19 2:55 PM 770SPECIFIC CONSIDERATIONSPART IIbranching, aberrant subclavian arteries or with a left-sided liga-mentum arterisum. When the developing left lung captures its blood supply from the right sixth arch caudad to the tracheo-bronchial tree, it leads to the development of a pulmonary artery sling. The left pulmonary artery arises from the right pulmonary artery and then wraps around the trachea and esophagus forming a “sling.”92 The pathophysiology of innominate artery compres-sion syndrome is not very well understood.Pathophysiology and Diagnosis. The symptoms associated with vascular rings include respiratory distress, barking cough, stridor, apnea, dysphagia, and recurrent respiratory tract infec-tions. The diagnosis often requires a high index of suspicion. Minor respiratory tract infections may precipitate serious respi-ratory distress. The work up includes chest X-rays, echocardiog-raphy, bronchoscopy, CT scan (Fig. 20-25), MRI (Fig. 20-26), and, rarely, cardiac catheterization. Chest X-rays show the rela-tionship of the aortic arch to the trachea. Tracheal compression can be better evaluated using lateral films. Unilateral hyperinfla-tion of the lung is sometimes seen and is often associated with a pulmonary artery sling (Fig. 20-27). PA slings (Fig. 20-28) are often associated with complete tracheal rings necessitating a bronchoscopy when this diagnosis is made (Fig. 20-29). Patients with dysphagia require a barium esophagogram as a part of their work-up (Fig. 20-30).Treatment. All symptomatic patients should undergo surgery. On close questioning nearly all patients are symptomatic.93 The treatment varies depending on the type of vascular ring. A left posterolateral thoracotomy provides good exposure to most types. A right thoracotomy is often used for innominate artery compression syndrome, and a median sternotomy often with cardiopulmonary bypass is used to treat pulmonary artery slings with or without associated complete tracheal rings. The out-comes and results for vascular rings are excellent (Fig. 20-31). Video-assisted thoracoscopic approaches have been developed for the management of these conditions.94-96 The criticism often stated involves retraction of vascular structures into the medias-tinum and losing control of the stumps prior to definitve control leading to exsanguination.96DEFECTS REQUIRING PALLIATIONTricuspid AtresiaTricuspid atresia occurs in 2% to 3% of patients with CHD and is characterized by atresia of the tricuspid valve. This results in discontinuity between the right atrium and RV. The RV is generally hypoplastic, and left-heart filling is dependent on an ASD. Tricuspid atresia is the most common form of the single-ventricle complex, indicating that there is functionally only one ventricular chamber.Anatomy. As mentioned, tricuspid atresia results in a lack of communication between the right atrium and the RV, and in the 5Figure 20-25. CT angiogram showing the four artery sign classic of double aortic arch.Figure 20-26. MRI showing a double aortic arch.Figure 20-27. Unilateral hyperinflation of the left lung associ-ated with a rare vascular ring: left ascending aorta and right sided descending aorta.Figure 20-28. CT angiogram showing a PA sling. Note the LPA wrapping around behind the trachea.Brunicardi_Ch20_p0751-p0800.indd 77022/02/19 2:55 PM 771CONGENITAL HEART DISEASECHAPTER 20majority of patients there is no identifiable valve tissue or rem-nant.98 The right atrium is generally enlarged and muscular, with a fibrofatty floor. An unrestrictive ASD is usually present. The LV is often enlarged as it receives both systemic and pulmonary blood flow, but the left AV valve is usually normal.The RV, however, is usually severely hypoplastic, and there is sometimes a VSD in its trabeculated or infundibular portion. In many cases, the interventricular communication is a site of obstruction to pulmonary blood flow, but obstruction may also occur at the level of the outlet valve or in the subval-vular infundibulum.99 In most cases, pulmonary blood flow is dependent on the presence of a PDA, and there may be no flow into the pulmonary circulation except for this PDA.Tricuspid atresia is classified according to the relationship of the great vessels and by the degree of obstruction to pulmo-nary blood flow. Because of the rarity of tricuspid atresia with transposed great arteries, we will restrict our discussion to tri-cuspid atresia with normally related great vessels.Pathophysiology. The main pathophysiology in tricuspid atresia is that of a univentricular heart of left ventricular morphology. That is, the LV must receive systemic blood via the interatrial communication and then distribute it to both the pulmonary circulation and the systemic circulation. Unless there is a VSD (as is found in some cases), pulmonary flow is dependent on the presence of a PDA. As the ductus begins to close shortly after birth, infants become intensely cyanotic. Reestablishing ductal patency (with PGE1) restores pulmonary blood flow and stabilizes patients for surgical intervention. Pulmonary hypertension is unusual in tricuspid atresia. However, occasional patients have a large VSD between the LV and the infundibular portion of the RV (just below the pulmonary valve). If there is no obstruction at the level of this VSD or at the valve, these infants may actually present with heart failure from excessive pulmonary blood flow. Regardless of whether these infants are “ductal-dependent” for pulmonary blood flow or have pulmonary blood flow provided across a VSD, they will be cyanotic since the obligatory right-to-left shunt at the atrial level will provide complete mixing of systemic and pulmonary venous return so that the LV ejects a hypoxemic mixture into the aorta.Diagnosis. The signs and symptoms of tricuspid atresia are dependent on the underlying anatomic variant, but most infants are cyanotic and hypoxic as a result of decreased pulmonary blood flow and the complete mixing at the atrial level. When pulmonary blood flow is provided through a VSD, there may be a prominent systolic murmur. Tricuspid atresia with pulmonary blood flow from a PDA may present with the soft, continuous murmur of a PDA in conjunction with cyanosis.In the minority of patients with tricuspid atresia, symp-toms of congestive heart failure will predominate. This is often related to excessive flow across a VSD. The natural history of the muscular VSDs in these infants is that they will close and the congestive heart failure will dissipate and transform into cyano-sis with reduced pulmonary blood flow. Chest radiography will show decreased pulmonary vascularity. The ECG is strongly suggestive because uncharacteristic left axis deviation will be present, due to underdevelopment of the RV. Two-dimensional echocardiography readily confirms the diagnosis and the ana-tomic subtype. (Fig 20-32)Treatment. The treatment for tricuspid atresia in the earlier era of palliation was aimed at correcting the defect in the pul-monary circulation. That is, patients with too much pulmonary flow received a pulmonary band, and those with insufficient flow received a systemic-to-pulmonary artery shunt. Systemic-to-pulmonary artery shunts, or Blalock–Taussig (BT) shunts, were first applied to patients with tricuspid atresia in the 1940s and 1950s.98 Likewise pulmonary artery banding was applied Figure 20-29. Rigid bronchoscopy showing complete tracheal rings in a the patient with pulmonary artery sling.Figure 20-30. Barium esophagogram showing posterior indenta-tion of the esophagus caused by a vascular ring (right aortic arch, aberrant left subclavian artery and left ligamentum).Brunicardi_Ch20_p0751-p0800.indd 77122/02/19 2:55 PM 772SPECIFIC CONSIDERATIONSPART IIto patients with tricuspid atresia and congestive failure in 1957. However, despite the initial relief of either cyanosis or conges-tive heart failure, long-term mortality was high, as the single ventricle was left unprotected from either volume or pressure overload.99Recognizing the inadequacies of the initial repairs, Glenn described the first successful cavopulmonary anastomosis, an end-to-side right pulmonary artery-to-superior vena cava shunt in 1958, and later modified this to allow flow to both pulmonary arteries.100 This end-to-side right pulmonary artery-to-superior vena cava anastomosis was known as the bidirectional Glenn, and it is the first stage to final Fontan repair in widespread use today (Fig. 20-33). The Fontan repair was a major advancement in the treatment of CHD, as it essentially bypassed the right heart and allowed separation of the pulmonary and systemic circulations. It was first performed by Fontan in 1971 and con-sisted of a classic Glenn anastomosis, ASD closure, and direct connection of the right atrium to the proximal end of the left pulmonary artery using an aortic homograft.101 The main pul-monary artery was ligated, and a homograft valve was inserted into the orifice of the inferior vena cava.Figure 20-32. Echo showing tricuspid atresia. The ‘*’ demonstrates the membranous tissue instead of the presence of a tricuspid valve.Figure 20-33. Angiogram showing a widely patent Glenn. The SVC (‘*’) is seen draining into the central pulmonary artery.Figure 20-31. Bronchoscopy before and after repair of a vascular ring: right arch, left descending aorta, and left ligament.Multiple modifications of this initial repair were per-formed over the next 20 years. One of the most important was the description by deLeval and colleagues of the creation of an interatrial lateral tunnel that allowed the inferior vena caval blood to be channeled exclusively to the superior vena cava.102 A total cavopulmonary connection could then be accomplished by dividing the superior vena cava and suturing the superior portion to the upper side of the right pulmonary artery and the inferior end to the augmented undersurface of the right pulmonary artery. Pulmonary flow then occurs passively, in a laminar fashion, driven by the central venous pressure. This repair became known as the modified Fontan operation.Another important modification, the fenestrated Fontan repair, was introduced in 1988.103 In this procedure, a residual 20% to 30% right-to-left shunt is either created or left unre-paired at the time of cavopulmonary connection to help sustain systemic output in the face of transient elevations in the pulmo-nary vascular resistance postoperatively.103Brunicardi_Ch20_p0751-p0800.indd 77222/02/19 2:55 PM 773CONGENITAL HEART DISEASECHAPTER 20The last notable variation on the original Fontan repair uses an extracardiac prosthetic tube graft (Fig. 20-34), usually 18 to 20 mm in diameter, as the conduit directing inferior vena cava blood to the pulmonary arteries.105 This technique has the advantages of decreasing atrial geometric alterations by avoid-ing intra-atrial suture lines and improving flow dynamics in the systemic venous pathway by maximizing laminar flow. Several investigators have shown a decrease in supraventricular arrhyth-mias, as well as an improvement in ventricular function, which may be secondary to decreased atrial tension and alleviation of chronic elevations in coronary sinus pressure.102,103One potential disadvantage of the extracardiac Fontan is that it delays performance of the Fontan in order to allow placement of a conduit of sufficient size. Despite these innova-tive approaches, the current strategy for operative management still relies on the idea of palliation. Patients are approached in a staged manner, to maximize their physiologic state so that they will survive to undergo a Fontan operation. The therapeu-tic strategy must begin in the neonatal period and should be directed toward reducing the patient’s subsequent risk factors for a Fontan procedure. Accordingly, small systemic pulmonary shunts, which are usually performed through a median sternot-omy, should be constructed for palliation of ductus-dependent univentricular physiology. This can easily be replaced with a bidirectional Glenn shunt or hemi-Fontan operation at 6 months of life. In non–ductus-dependent univentricular physiology, the infant can be managed medically until primary construction of a bidirectional cavopulmonary anastomosis becomes feasible. This is possible in the majority of cases because the physiologi-cally elevated pulmonary vascular resistance prevents pulmo-nary overcirculation during the neonatal period.The Fontan is usually performed when the child is between 2 and 4 years of age, and it is generally successful if the infant was staged properly, with a protected single ventricle, and there is adequate pulmonary artery growth. The pulmonary vascular resistance should be below 4 Wood units, and the ejection frac-tion should be more than 45% to ensure success.106 In patients with high pulmonary artery pressure, fenestration of the atrial baffle may be helpful because their pulmonary vascular resis-tance may preclude adequate cardiac output postoperatively.99,103Results. Recent reports of the Fontan procedure for tricuspid atresia have been encouraging, with an overall survival of 86% and an operative mortality of 2%.107 The main complications following repair are atrial arrhythmias, particularly atrial flutter; conduit obstruction requiring reoperation; protein-losing enter-opathy; and decreased exercise tolerance.A prospective multi-institutional study from the Congeni-tal Heart Surgeons Society reported the outcomes of 150 neo-nates with tricuspid atresia and normally related great vessels.107 Five-year survival was 86%, and by the age of 2 years, 89% had undergone cavopulmonary anastomosis, and 75% of those surviving cavopulmonary anastomosis underwent Fontan opera-tion within 3 years. Competing risks methodology was used in this study to determine the rates of transition to end-states and their associated determinants (Fig. 20-35). Risk factors for death without cavopulmonary anastomosis in this study included the presence of mitral regurgitation and palliation with systemic-to-pulmonary artery shunts not originating from the innominate artery. Factors associated with decreased transition rate to cavo-pulmonary anastomosis included patient variables (younger age at admission to a participating institution and noncardiac anom-alies) and procedural variables (larger systemic-to-pulmonary arterial shunt diameter and previous palliation).9Hypoplastic Left Heart SyndromeHLHS comprises a wide spectrum of cardiac malformations, including hypoplasia or atresia of the aortic and mitral valves and hypoplasia of the LV and ascending aorta.108 HLHS has a reported prevalence of 0.2 per 1000 live births and occurs twice as often in boys as in girls. Left untreated, HLHS is invari-ably fatal and is responsible for 25% of early cardiac deaths in neonates.109 However, the recent evolution of palliative surgical procedures has dramatically improved the outlook for patients with HLHS, and an improved understanding of anatomic and physiologic alterations has spurred advances in parallel arenas such as intrauterine diagnosis and fetal intervention, echocardio-graphic imaging, and neonatal critical care.Anatomy. As implied by its name, HLHS involves varying degrees of underdevelopment of left-sided structures (Fig. 20-36), including the LV and the aortic and mitral valves. Thus, HLHS can be classified into four anatomic subtypes based on the val-vular morphology: (a) aortic and mitral stenosis; (b) aortic and mitral atresia; (c) aortic atresia and mitral stenosis; and (d) AS and mitral atresia. Aortic atresia tends to be associated with more severe degrees of hypoplasia of the ascending aorta than does AS.Even in cases without frank aortic atresia, however, the aortic arch is generally hypoplastic and, in severe cases, may even be interrupted. There is an associated coarctation shelf in 80% of patients with HLHS, and the ductus itself is usually quite large, as is the main pulmonary artery.7The segmental pulmonary arteries, however, are small, secondary to reduced intrauterine pulmonary blood flow, which is itself a consequence of the left-sided outflow obstruction (Fig. 20-36). The left atrial cavity is generally smaller than nor-mal and is accentuated because of the leftward displacement of the septum primum. There is almost always an interatrial com-munication via the foramen ovale, which can be large, but more Figure 20-34. Angiogram in a patient with a fenestrated extra-cardiac fontan constructed with a 20 mm Gore-tex tube graft (‘*’).Brunicardi_Ch20_p0751-p0800.indd 77322/02/19 2:55 PM 774SPECIFIC CONSIDERATIONSPART IIcommonly restricts right-to-left flow. In rare cases, there is no atrial-level communication, which can be lethal for these infants because there is no way for pulmonary venous return to cross over to the RV.Associated defects can occur with HLHS, and many of them have importance with respect to operative repair. For example, if a VSD is present, the LV can retain its normal size during development even in the presence of mitral atresia. This is because a right-to-left shunt through the defect impels growth of the LV.110 This introduces the feasibility of biventricular repair for this subset of patients.Although HLHS undoubtedly results from a complex interplay of developmental errors in the early stages of cardio-genesis, many investigators have hypothesized that the altered blood flow is responsible for the structural underdevelopment that characterizes HLHS. In other words, if the stimulus for nor-mal development of the ascending aorta from the primordial aortic sac is high-pressure systemic blood flow from the LV through the aortic valve, then an atretic or stenotic aortic valve, which impedes flow and leads to only low-pressure diastolic retrograde flow via the ductus, will change the developmental signals and result in hypoplasia of the downstream structures (Fig. 20-37). Normal growth and development of the LV and mitral valve can be secondarily affected, resulting in hypoplasia or atresia of these structures.108Pathophysiology and Diagnosis. In HLHS, pulmonary venous blood enters the left atrium, but atrial systole cannot propel blood across the stenotic or atretic mitral valve into the LV. Thus, the blood is shunted across the foramen ovale into the right atrium, where it contributes to volume loading of the RV. The end result is pulmonary venous hypertension from outflow obstruction at the level of the left atrium, as well as pulmonary overcirculation and right ventricular failure. As the pulmonary vascular resistance falls postnatally, the condition is exacerbated because right ventricular output is preferentially directed away from the systemic circulation, resulting in profound underperfu-sion of the coronary arteries and the vital organs. Closure of the ductus is incompatible with life in these neonates.Neonates with severe HLHS receive all pulmonary, sys-temic, and coronary blood flow from the RV. Generally, a child with HLHS will present with respiratory distress within the first day of life, and mild cyanosis may be noted. These infants must be rapidly triaged to a tertiary center, and echocardiography should be performed to confirm the diagnosis. Prostaglandin E1 must be administered to maintain ductal patency, and the Figure 20-36. Echo In a patient with HLHS. Note the extremely hypoplastic left ventricle (‘*’).0200.00.40.81.2Years from diagnosis1.62.0406080100Proportion (%) of patients in each stateBDCPA (2 year prevalence = 90%)Dead without BDCPA(2 year prevalence = 5%)Single-stage Fontan(2 year prevalence = 1%)Alive without BDCPA(2 year prevalence = 4%)Figure 20-35. Competing risks depiction of events after diagnosis in 150 patients with tricuspid atresia. All patients began alive and thereafter migrated to one of four mutually exclusive end states (death, bidirectional cavopulmonary anastomosis [BDCPA], single-stage Fontan completion, or remaining alive without BDCPA) at time-dependent rates defined by the underlying hazard functions. At any point in time, the sum of propor-tions of children in each state is 100%. For example, estimated prevalences after 2 years from diagnosis are as follows: 89% BDCPA, 6% dead without BDCPA, 4% alive without BDCPA, and 1% single-stage Fontan completion. Solid lines represent parametric point estimates; dashed lines enclose 70% confidence intervals; circles with error bars represent nonparametric estimates; numbers in parentheses indicate the estimated propor-tion of patients in each state at 2 years from diagnosis. (Reproduced with permission from Karamlou T, Ashburn DA, Caldarone CA, et al: Matching procedure to morphology improves outcomes in neonates with tricuspid atresia, J Thorac Cardiovasc Surg. 2005 Dec;130(6):1503-1510.) Brunicardi_Ch20_p0751-p0800.indd 77422/02/19 2:55 PM 775CONGENITAL HEART DISEASECHAPTER 20ventilatory settings must be adjusted to avoid excessive oxygen-ation and increase carbon dioxide tension. These maneuvers will maintain pulmonary vascular resistance and promote improved systemic perfusion.5,7,108 Cardiac catheterization should gener-ally be avoided because it is not usually helpful and might result in injury to the ductus and compromised renal function second-ary to the osmotic dye load.Treatment. In 1983, Norwood and colleagues described a two-stage palliative surgical procedure for relief of HLHS111 that was later modified to the currently used three-stage method of palliation.109 Stage 1 palliation, also known as the modified Norwood procedure (Fig. 20-38), bypasses the LV by creating a single outflow vessel, the neoaorta, which arises from the RV.The current technique of arch reconstruction involves completion of a connection between the pulmonary root, the native ascending aorta, and a piece of pulmonary homograft used to augment the diminutive native aorta. There are several modifications of this anastomosis, most notably the Damus-Kaye-Stansel (DKS) anastomosis, which involves dividing both the aorta and the pulmonary artery at the sinotubular junction. The proximal aorta is anastomosed to the proximal pulmonary artery, creating a “double-barreled” outlet from the heart. This outlet is anastomosed to the distal aorta, which can be augmented with homograft material if there is an associated coarctation. At the completion of arch reconstruction, a 3.5or 4-mm shunt is placed from the innominate artery to the right pulmonary artery. The interatrial septum is then widely excised, thereby creating a large interatrial communication and prevent-ing pulmonary venous hypertension.The DKS connection, as described earlier, might avoid postoperative distortion of the tripartite connection in the neo-aorta, and thus decrease the risk of coronary insufficiency.112 It can be used when the aorta is 4 mm or larger. Unfortunately, in many infants with HLHS, especially if there is aortic atresia, the aorta is diminutive and often less than 2 mm in diameter. The alternate technique available to provide pulmonary blood flow instead of a shunt is a RV-PA conduit often referred to as a “Sano.” It is usually a 5 or 6 mm ribbed Gore-tex graft.113The postoperative management of infants following stage 1 palliation is complex because favorable outcomes depend on establishing a delicate balance between pulmonary and systemic perfusion. Recent literature suggests that these infants require adequate postoperative cardiac output in order to supply both the pulmonary and the systemic circulations and that the use of oxi-metric catheters to monitor mixed venous oxygen saturation (Svo2) aids clinicians in both the selection of inotropic agents and in ventilatory management.114 Introduction of a shunt between the RV and the pulmonary artery (Sano shunt) dimin-ishes the diastolic flow created by the modified BT shunt and may augment coronary perfusion, resulting in improved postop-erative cardiac function.113 A recent prospective, randomized, multi-institutional trial sponsored by the National Institutes of Health, the Systemic Ventricle Reconstruction (SVR) trial, com-pared the outcomes of neonates having either a modified Blalock–Taussig shunt (MBTS) or a Sano shunt.115 The SVR trial demonstrated that transplantation-free survival 12 months after randomization was higher with the Sano shunt than with the MBTS (74% vs. 64%, P = .01). However, the Sano shunt group had more unintended interventions (P = .003) and complications (P = .002). Right ventricular size and function at the age of 14 months and the rate of nonfatal serious adverse events at the age of 12 months were similar in the two groups. Data collected over a mean (± standard deviation) follow-up period of 32 ± 11 months showed a nonsignificant difference in transplanta-tion-free survival between the two groups (P = .06).115Since the initial SVR publications in 2010, the 3-year and 6-year results have been analyzed. At 3 years, the com-bined death and cardiac transplantation rates for the RVPAS vs. MBTS groups were 33% vs. 39% (P = 0.14). When all available data were examined by Kaplan-Meier analysis (mean follow-up 4.4 ± 1.0 years), there was also no difference between groups (log rank P = 0.11). Overall, there were 100 deaths and 10 trans-plantations in the MBTS cohort and 86 deaths and 11 transplan-tations in the RVPAS group.116 At 6 years, although the point averages continued to reflect a difference favoring the RVPAS (combined death/transplantation rate, 36%) in comparison with the MBTS (41%), the number of subjects was not sufficient to 6Figure 20-37. Angiogram obtained in a patient with HLSH (AS/MS). Note the extremely diminutive ascending aorta (‘*’).PatchmBTSRPALPAFigure 20-38. Cartoon depicting the Norwood procedure. The anas-tomosis of the aortic and pulmonary valve annulus is not shown. The ascending aorta and hyplastic arch are reconstructed by patch augmentation. The pulmonary blood flow has been provided in this case by a mBTS. (Used with permission from Kelly Rosso MD.)Brunicardi_Ch20_p0751-p0800.indd 77522/02/19 2:55 PM 776SPECIFIC CONSIDERATIONSPART IIdemonstrate a statistically significant difference between the two groups (log rank P = 0.13). Similar to the 3-year results, RVPAS subjects had a higher incidence of any catheter inter-vention (0.38 vs. 0.23 interventions/patient-year, P <0.001), including balloon angioplasty (P = 0.014), stent (P = 0.009), and coiling (P <0.001).113,114 Currently, there remains an ongoing controversy regarding MBTS vs. RV-PA conduit as the source of pulmonary blood flow after the Norwood operation.119,120Although surgical palliation with the Norwood procedure is still the mainstay of therapy for infants with HLHS, a combined surgical and percutaneous option (hybrid procedure), which con-sists of bilateral pulmonary artery banding and placement of a ductal stent, has emerged as a promising alternative that obviates the need for CPB in the fragile neonatal period.121,122 The hybrid procedure is performed in a “hybrid suite,” incorporating both advanced fluoroscopic imaging facilities combined with com-plete operating room capabilities. A 3or 3.5-mm PTFE tube graft is cut to a width of 3 to 4 mm and used as the bands on the branch pulmonary arteries, placed just distal to the main pulmo-nary artery. The ductal stent is then positioned in order to cover all ductal tissue and is deployed through a purse-string suture in the main pulmonary artery. A reverse systemic-to-pulmonary shunt is considered in patients with aortic atresia and preductal coarctation to improve coronary perfusion; however, a recent study demonstrated no difference in survival between those with and without the shunt.123 The hybrid procedure can also be used as a bridge to heart transplantation in those infants with severe AV valve regurgitation or otherwise unsuitable single-ventricle anatomy.124Following stage 1 palliation, the second surgical proce-dure is the creation of a bidirectional cavopulmonary shunt (Fig. 20-39) or hemi-Fontan, generally at 3 to 6 months of life when the pulmonary vascular resistance has decreased to nor-mal levels. This is the first step in separating the pulmonary and systemic circulations, and it decreases the volume load on the single ventricle. The existing innominate artery-to-pulmonary shunt (or RV-to-pulmonary shunt) or MBTS is eliminated dur-ing the same operation.The third stage of surgical palliation, known as the modi-fied Fontan procedure, completes the separation of the sys-temic and pulmonary circulations and is performed between 18 months and 3 years of age, or when the patient experiences increased cyanosis (i.e., has outgrown the capacity to perfuse the systemic circulation with adequately oxygenated blood). This has traditionally required a lateral tunnel within the right atrium to direct blood from the inferior vena cava to the pulmo-nary artery, allowing further relief of the volume load on the RV and providing increased pulmonary blood flow to alleviate cyanosis. More recently, many favor using an extracardiac con-duit (e.g., 18to 20-mm tube graft) to connect the inferior vena cava to the pulmonary artery (Fig. 20-40).Not all patients with HLHS require this three-stage pallia-tive repair. Some infants afflicted with a milder form of HLHS, recently described as hypoplastic left heart complex (HLHC), have aortic or mitral hypoplasia without intrinsic valve stenosis and antegrade flow in the ascending aorta. In this group, a two-ventricle repair can be achieved with reasonable outcome. Tch-ervenkov has published the results with 12 patients with HLHC who underwent biventricular repair at a mean age of 7 days.114 The operative technique consisted of a pulmonary homograft patch aortoplasty of the aortic arch and ascending aorta and closure of the interatrial and interventricular communications. The left heart was capable of sustaining systemic perfusion in 92% of patients, and early mortality was 15.4%. Four patients required reoperations to relieve LVOT obstruction, most com-monly between 12 and 39 months following repair. The group from Boston Children’s Hospital has been very aggressive in left ventricular recruitment. These operations still carry a high burden of late death and several reoperations.Although the Norwood procedure is the most widely per-formed initial operation for HLHS, transplantation can be used as a first-line therapy and may be preferred when anatomic or physiologic considerations exist that preclude a favorable out-come with palliative repair. Significant tricuspid regurgitation, intractable pulmonary artery hypertension, or progressive right ventricular failure are cases where cardiac replacement may be advantageous. Widespread adaptation of transplantation as SVCLPAAtriumFigure 20-39. Cartoon depicting a bidirectional Glenn. (Used with permission from Kelly Rosso MD.)SVCGore-textube graftAtriumIVCFigure 20-40. Extra cardiac fenestrated Fontan. ‘*’ shows the fen-estration. (Used with permission from Kelly Rosso MD.)Brunicardi_Ch20_p0751-p0800.indd 77622/02/19 2:55 PM 777CONGENITAL HEART DISEASECHAPTER 20first-line treatment for HLHS has been limited by improved Norwood survival rates as the operation and preand postop-erative management of the patient have evolved and by lim-ited organ availability. Organ availability should be considered prior to electing transplantation, as 24% of infants died awaiting transplantation in the largest series to date.126,127Results. Outcomes for HLHS are still significantly worse than those for other complex cardiac defects. However, with improvements in perioperative care and modifications in surgical technique, the survival following the Norwood proce-dure now exceeds 90% in experienced centers.115-120 The out-come for low-birth-weight infants has improved, but low weight still remains a major predictor of adverse survival, especially when accompanied by significant tricuspid valve insufficiency, a restructive interatrial communication, poor RV function, or extracardiac or chromosomal anomalies.DEFECTS THAT MAY BE PALLIATED OR REPAIREDEbstein’s AnomalyAnatomy. This is a rare defect, occurring in less than 1% of CHD patients. The predominant maldevelopment in this lesion is the inferior displacement of the tricuspid valve into the RV, although Bove128 and others have emphasized the fact that Ebstein’s anomaly is primarily a defect in right ventricular morphology rather than an isolated defect in the tricuspid valve. The anterior leaflet is usually attached in its normal position to the annulus, but the septal and posterior leaflets are displaced toward the ventricle. This effectively divides the RV into two parts: the inlet portion (atrialized RV) and the outlet portion (true or trabeculated RV) (Fig. 20-41). The atrialized RV is usu-ally thin and dilated. Similarly, the tricuspid annulus and the right atrium are extremely dilated, and the tricuspid valve is usually regurgitant with a “sail-like” leaflet (Fig. 20-42). There is commonly an ASD present, which results in a right-to-left shunt at the atrial level. Occasionally, there is true anatomic pulmonary atresia or milder forms of RVOT obstruction.A Wolff-Parkinson-White (WPW) syndrome (Fig. 20-43) type of accessory pathway with associated preexcitation is pres-ent in 15% of patients.128Pathophysiology. Right ventricular dysfunction occurs in patients with Ebstein’s anomaly because of two basic mecha-nisms: the inflow obstruction at the level of the atrialized ven-tricle, which produces ineffective RV filling and contractile dysfunction. Inflow obstruction and tricuspid regurgitation, which is exacerbated by progressive annular dilatation, both produce ineffective RV filling. Contractile dysfunction of the RV is a result of a decrease in the number of myocardial fibers, as well as the discordant contraction of the large atrialized portion.The lack of forward flow at the right ventricular level may lead to physiologic or functional pulmonary atresia, and the infant is dependent on ductal patency for survival. All sys-temic venous return must be directed through an ASD to the left atrium, where it can be shunted through the ductus for gas exchange. However, the left ventricular function is usually compromised in infants with severe Ebstein’s anomaly as well because the enormous RV and the to-and-fro flow within the atrialized RV prevent adequate intracardiac mixing. Left ven-tricular function may also be severely compromised in Ebstein’s anomaly because the large RV causes left ventricular compres-sion (Fig. 20-44A,B).Diagnosis. There is a spectrum of clinical presentation in infants with Ebstein’s anomaly that mirrors the anatomic spec-trum of this anomaly. Some infants with less severe forms may present with a mild degree of cyanosis, whereas the onset of clinical symptoms in patients surviving childhood is gradual, with the average age of diagnosis in the mid-teens.However, the infant with severe atrialization and pulmo-nary stenosis will be both cyanotic and acidotic at birth. The chest radiograph may demonstrate the classic appearance, which 7Figure 20-41. Echo showing a patient with Ebsteins anomaly. Note the inferiorly displaced tricuspid valve (‘*’) and the atrialized por-tion of the RV (arrow).Figure 20-42. Echo in a patient with severe Ebsteins anomaly showing the large ‘sail like’ anterior leaflet (‘*’).Brunicardi_Ch20_p0751-p0800.indd 77722/02/19 2:56 PM 778SPECIFIC CONSIDERATIONSPART IIconsists of a globular “wall-to-wall” heart (Fig. 20-45), similar to that seen with pericardial effusion. The ECG may show right bundle-branch block and right axis deviation. WPW syndrome, as mentioned earlier, is a common finding in these patients. Echocardiography will confirm the diagnosis and provide criti-cal information including tricuspid valvular function, size of the atrialized portion of the RV, degree of pulmonary stenosis, and the atrial size.128The Great Ormond Street Score (GOSE) (Table 20-1),129 which consists of the area of the right atrium plus the area of the atrialized portion of the RV divided by the diastolic area of the remaining cardiac chambers, has been proposed as a useful prognostic tool to stratify neonates with Ebstein’s anomaly. A score of greater than 2 translates into uniformly fatal outcome. Electrophysiology study with radiofrequency ablation is indi-cated in patients with evidence of WPW syndrome or in children Figure 20-43. EKG of a newborn with Ebsteins anomaly and WPW syndrome. Note the pre-excitation (arrow).ABFigure 20-44. A. Echo (short axis view) of a patient with severe Ebsteins anomaly showing the large RV (‘*’) and small LV (arrow) in diastole. B. Echo (short axis view) of a patient with severe Ebsteins anomaly showing the large RV (‘*’) and small ‘pancaked’ LV (arrow) in systole.Brunicardi_Ch20_p0751-p0800.indd 77822/02/19 2:56 PM 779CONGENITAL HEART DISEASECHAPTER 20with a history of supraventricular tachycardia, undefined wide-complex tachycardia, or syncope.Treatment. Surgery is indicated for symptomatic infants and for older children and adults with arrhythmias, progressive cya-nosis, or New York Heart Association class III or IV. How-ever, the operative repair may be different, depending on the patient’s age, because older children usually are candidates for a biventricular or one-and-a-half ventricle repair, whereas moder-ate survival has been reported for neonates, using a procedure that converts the anatomy to a single-ventricle physiology, as described by Starnes and coworkers.130The surgical approach in widespread use today for patients surviving infancy was described by Danielson and colleagues in 1992.128,131 This procedure entails excision of redundant right atrial tissue and patch closure of any associated ASD, plication of the atrialized portion of the ventricle with obliteration of the aneurysmal cavity, posterior tricuspid annuloplasty to narrow the tricuspid annulus, reconstruction of the tricuspid valve if the anterior leaflet is satisfactory, or replacement of the tricuspid valve if necessary.131 If the tricuspid valve is not amenable to reconstruction, valve replacement should be considered. Care must be taken when performing the posterior annuloplasty, or during the conduct of tricuspid valve replacement, to avoid the conduction system, because complete heart block can compli-cate this procedure. In addition, patients who demonstrated preoperative evidence of preexcitation should undergo electro-physiologic mapping and ablation.Neonatal Ebstein’s anomaly is a separate entity. Results with surgical correction have been poor, and many neonates are not candidates for operative repair as previously described. Surgical options for the symptomatic neonate include palliative procedures, the one-and-a-half ventricle repair, or conversion to single-ventricle physiology.132 Arguably, the most favorable out-comes in symptomatic neonatal Ebstein’s anomaly or repair in slightly older infants have been achieved using the right ventric-ular exclusion premise. This technique, known as the “Starnes” procedure (Fig. 20-46),130 uses a fenestrated patch to close the tricuspid valve orifice coupled with systemic-to-pulmonary artery shunt. The patch must be fenestrated to allow decom-pression of the RV in instances of anatomic pulmonary atresia. Although Knott-Craig and colleagues132 have described tricus-pid valve repair for the full spectrum of neonates and infants with excellent shortand mid-term results, these results have not been reproduced in other institutions.133 The one-and-a-half ventricle repair was first described by Billingsly and cowork-ers as an attempt to achieve a more physiologic “pulsatile” pul-monary circulation in patients with a hypoplastic or dysplastic RV.134 This is accomplished by diverting the superior vena caval blood directly into the pulmonary arterial system by a bidirec-tional cavopulmonary shunt while recruiting the RV to propel the inferior vena caval blood directly to the pulmonary arteries via the RVOT. Thus, the hemodynamics of the one-and-a-half ventricle repair are characterized by separate systemic and pul-monary circulations in series. The systemic circulation is fully supported by a systemic ventricle, and the pulmonary circula-tion is supported by both the bidirectional Glenn shunt and the hypoplastic (pulmonary) ventricle. Proponents of this approach report a decreased right atrial pressure and a decrease in inferior vena cava hypertension, which is theorized to be responsible for many of the dreaded complications of the Fontan circulation, including protein-losing encephalopathy, hepatic congestion, atrial arrhythmias, and systemic ventricular failure. In addition, the maintenance of pulsatile pulmonary blood flow, as opposed to continuous laminar flow as in the Fontan circulation, may be advantageous to the pulmonary microcirculation, although it has not been proven in any studies thus far.134,135 Certain criteria, most notably an adequate tricuspid valve Z score, as well as Figure 20-45. CXR in a newborn with severe Ebsteins anomaly showing a ‘wall-to-wall’ heart.Table 20-1The Great Ormond Street Score (GOSE)GOSE Score: Area of RA + aRA/Area of RV + LA + LVGOSE ScoreRatioMortality (%)1<0.5820.5–1.0831.1–1.41004>1.5100Figure 20-46. Echo appearance after a Starnes operation. Note the jet of flow across the fenestration In the patch.Brunicardi_Ch20_p0751-p0800.indd 77922/02/19 2:56 PM 780SPECIFIC CONSIDERATIONSPART IIthe absence of severe pulmonary hypertension or concomitant defects requiring intricate intracardiac repair, should be satis-fied prior to electing the one-and-a-half ventricle approach.136 Patients who do not fulfill these criteria may be approached with a two-ventricle repair and atrial fenestration or a Fontan repair.In the infant with severe Ebstein’s anomaly, initial stabili-zation with prostaglandin to maintain ductal patency, mechanical ventilation, and correction of cyanosis is mandatory. Metabolic acidosis, if present from compromised systemic perfusion, must be aggressively treated with afterload reduction. Many of these infants will improve over 1 to 2 weeks as pulmonary vascu-lar resistance falls and they are able to improve antegrade flow into the pulmonary circulation through their abnormal RV and tricuspid valve. When stabilization and medical palliation fail, surgical management remains an option, although its success depends on numerous anatomic factors (e.g., adequacy of the tricuspid valve, RV, and pulmonary outflow tract), and surgery for symptomatic neonates with Ebstein’s anomaly carries a high risk. Knott-Craig and associates reported three cases where two-ventricle repair was undertaken by subtotal closure of the ASD, extensive resection of the right atrium, and vertical plication of the atrialized chamber.132 Five-year follow-up revealed all patients to be asymptomatic and in sinus rhythm without medi-cations. Recently, they have reported on their 20-year experi-ence with treating 32 such neonates with an overall mortality of 40%. Surgical management of neonates with Ebstein’s anom-aly remains challenging. For neonates with Ebstein’s anomaly and anatomical pulmonary atresia, single-ventricle palliation is associated with lower early mortality compared with two-ventricle repair.132Results. In the neonatal period, the most common postopera-tive problem, whether after a simple palliative procedure such as a BT shunt or following a more extensive procedure such as attempted exclusion of the RV, has been low cardiac out-put. Supraventricular tachycardia also has been problematic postoperatively. Complete heart block necessitating pacemaker implantation should be uncommon if the techniques described to avoid suturing between the coronary sinus and the tricuspid annulus are used.There are few published reports of outcomes, due to the rarity of this defect. However, based on the natural history of this condition, which is remarkably benign for the majority of older patients, the outlook should be excellent for patients who have survived the neonatal period.127,131,132,137Transposition of the Great ArteriesAnatomy. Complete transposition is characterized by connec-tion of the atria to their appropriate ventricles with inappropriate ventriculoarterial connections. Thus, the aorta arises anteriorly from the RV, while the pulmonary artery arises posteriorly from the LV. Van Praagh and coworkers introduced the term dextro-transposition of the great arteries (D-TGA) to describe this defect, whereas levo-transposition of the great arteries (L-TGA) describes a form of corrected transposition where there is concomitant AV discordance.138,139D-TGA requires an obligatory intracardiac mixing of blood, which usually occurs at both the atrial and the ventricu-lar levels or via a patent ductus. Significant coronary anomalies occur frequently in patients with D-TGA. The most common pattern, occurring in 68% of cases, is characterized by the left main coronary artery arising from the leftward coronary sinus, giving rise to the left anterior descending and circumflex arteries. The most common variant is for the circumflex coro-nary artery to arise as a branch from the right coronary artery instead of from the left coronary artery.Pathophysiology. D-TGA results in parallel pulmonary and systemic circulations, with patient survival dependent on intracardiac mixing of blood. After birth, both ventricles are relatively noncompliant, and thus, infants initially have higher pulmonary flow due to the decreased downstream resistance. This causes left atrial enlargement and a left-to-right shunt via the patent foramen ovale.Postnatally, the LV does not hypertrophy because it is not subjected to systemic afterload. The lack of normal extrauter-ine left ventricular maturation has important implications for the timing of surgical repair because the LV must be converted to the systemic ventricle and be able to function against sys-temic vascular resistance. If complete repair is done within the first few weeks of life, the LV usually adapts easily to systemic resistance since it is conditioned to high intrauterine pulmonary vascular resistance. After a few weeks of life, the LV that is conditioned to the decrease in pulmonary resistance that occurs when the lungs inflate after birth may have difficulty adapting to systemic vascular resistance without preoperative preparation or postoperative support. Novel techniques of LV “preparation” using a pulmonary arterial band have been used in cases where complete repair has been delayed (Fig. 20-47A,B).Clinical Manifestations and Diagnosis. Infants with D-TGA and an intact ventricular septum are usually cyanotic at birth, with an arterial Po2 between 25 and 40 mmHg. If duc-tal patency is not maintained, deterioration will be rapid with ensuing metabolic acidosis and death. Conversely, those infants with a coexisting VSD may be only mildly hypoxemic and may come to medical attention after 2 to 3 weeks, when the falling pulmonary vascular resistance leads to symptoms of congestive heart failure.The ECG will reveal right ventricular hypertrophy, and the chest radiograph will reveal the classic egg-shaped con-figuration. Definitive diagnosis is made by echocardiography, which reliably demonstrates ventriculoarterial discordance and any associated lesions. Cardiac catheterization is rarely nec-essary, except in infants requiring surgery after the neonatal period, to assess the suitability of the LV to support the sys-temic circulation. Limited catheterization, however, is useful for performance of atrial septostomy in neonates with inadequate intracardiac mixing.Surgical Repair. Blalock and Hanlon introduced the first operative intervention for D-TGA with the creation of an atrial septectomy to enhance intracardiac mixing.140 This initial proce-dure was feasible in the pre-CPB era, but carried a high mortal-ity rate. Later, Rashkind and Causo developed a catheter-based balloon septostomy, which largely obviated the need for open septectomy.42These early palliative maneuvers, however, met with lim-ited success, and it was not until the late 1950s, when Senning and Mustard developed the first “atrial repair,” that outcomes improved. The Senning operation consisted of rerouting venous flow at the atrial level by incising and realigning the atrial sep-tum over the pulmonary veins and using the right atrial free wall to create a pulmonary venous baffle (Fig. 20-48).141Although the Mustard repair (Fig. 20-49) was similar, it made use of either autologous pericardium or synthetic material to create the interatrial baffle.142 These atrial switch procedures Brunicardi_Ch20_p0751-p0800.indd 78022/02/19 2:56 PM 781CONGENITAL HEART DISEASECHAPTER 20ABFigure 20-47. A. Echocardiographic appearance of the LV (‘*’) prior to “LV training”. B. Echocardiographic appearance of the LV (‘*’) after “LV training” achieved by the application of a tight PA band and a mBTS.ACBDFigure 20-48. The Senning operation. A. The atrial septum is cut near the tricuspid valve, creating a flap attached posteriorly between the caval veins. B. The flap of atrial septum is sutured to the anterior lip of the orifices of the left pulmonary veins, effectively separating the pulmonary and systemic venous channels. C. The posterior edge of the right atrial incision is sutured to the remnant of the atrial septum, diverting the systemic venous channel to the mitral valve. D. The anterior edge of the right atrial incision (lengthened by short incisions at each corner) is sutured around the cava above and below to the lateral edge of the LA incision, completing the pulmonary channel and diversion of pulmonary venous blood to the tricuspid valve area. (Reproduced with permission from Mavroudis C, Backer CL: Pediatric Cardiac Surgery, 2nd ed. St. Louis, MO: Mosby; 1994.) Figure 20-49. Angiographic appearance of a Mustard type baffle repair for dTGA.resulted in a physiologic correction, but not an anatomic one, as the systemic circulation is still based on the RV. Still, survival rose to 95% in most centers by using an early balloon septostomy fol-lowed by an atrial switch procedure at 3 to 8 months of age.141,142Despite the improved early survival rates, long-term problems, such as superior vena cava or pulmonary venous obstruction, baffle leak, arrhythmias, tricuspid valve regurgita-tion, and right ventricular failure, prompted the development of the arterial switch procedure by Jatene in 1975.143 The arterial switch procedure involves the division of the aorta and the pul-monary artery, posterior translocation of the aorta (LeCompte maneuver), mobilization of the coronary arteries, placement of a pantaloon-shaped pericardial patch, and proper alignment of the coronary arteries on the neoaorta (Fig. 20-50).The most important consideration is the timing of surgical repair because arterial switch should be performed within 2 weeks after birth, before the LV loses its ability to pump against sys-temic afterload. In patients presenting later than 2 weeks, the LV can be retrained with preliminary pulmonary artery banding Brunicardi_Ch20_p0751-p0800.indd 78122/02/19 2:56 PM 782SPECIFIC CONSIDERATIONSPART IIFigure 20-50. The Arterial Switch Operation. A. The maneuver of Lecompte (positioning the pulmo-nary artery anterior to the aorta) is shown with aortic cross-clamp repositioning to retract the pulmonary artery during the neoaortic reconstruction. A and B. After the coronary patches are rotated for an optimal lie, they are sutured to the linearly incised sinuses of Valsalva at the old pulmonary artery (neoaorta) (C). (Reproduced with permission from Mavroudis C, Backer CL: Arterial Switch. Cardiac Surgery: State of the Art Review. Vol. 5, no. 1. Philadelphia, PA: Hanley & Belfus; 1991.) Figure 20-51. Angiographic appearance of the pulmonary arteries before and after balloon dilation. The RV pressures dropped from “systemic” to “1/2 systemic” after dilation.and aortopulmonary shunt followed by definitive repair. Alter-natively, the unprepared LV can be supported following arterial switch with a mechanical assist device for a few days while it recovers ability to manage systemic pressures. Echocardiogra-phy can be used to assess left ventricular performance and guide operative planning in these circumstances.The subset of patients who present with D-TGA compli-cated by LVOT obstruction and VSD may not be suitable for an arterial switch operation. The Rastelli operation, first performed in 1968, uses placement of an intracardiac baffle to direct left ventricular blood to the aorta and an extracardiac valved conduit to establish continuity between the RV and the pulmonary artery, which has led to successful outcomes in these complex patients.144Results. For patients with D-TGA, intact ventricular septum, and VSD, the arterial switch operation provides excellent long-term results with a mortality rate of less than 5%. Operative risk is increased when unfavorable coronary anatomic configu-rations are present or when augmentation of the aortic arch is required. The most common complication is supravalvular pul-monary stenosis, occurring 10% of the time, which may require ballooning or reoperation (Fig. 20-51).145Results of the Rastelli operation have improved substan-tially, with an early mortality rate of 5%.146 Late mortality rate results were less favorable because conduit failure requiring reoperation, pacemaker insertion, or relief of LVOT obstruc-tion was frequent.Brunicardi_Ch20_p0751-p0800.indd 78222/02/19 2:56 PM 783CONGENITAL HEART DISEASECHAPTER 20Double-Outlet Right VentricleAnatomy. Double-outlet RV (DORV) accounts for 5% of CHD and exists when both the aorta and pulmonary artery arise wholly, or in large part, from the RV (Fig. 20-52). DORV encompasses a spectrum of malformations because the incom-plete shift of the aorta toward the LV is often associated with other abnormalities of cardiac development, such as ventricular looping and infundibular-truncal spiraling.147 The vast majority of hearts exhibiting DORV have a concomitant VSD, which varies in its size and spatial association with the great vessels. The VSD is usually nonrestrictive and represents the only out-flow for the LV; its location relative to the great vessels dictates the dominant physiology of DORV, which can be analogous to that of a large isolated VSD, tetralogy of Fallot, or D-TGA. In 1972, Lev et al148 suggested considering DORV as a spectrum of hearts that “pass imperceptibly from tetralogy with VSD with overriding aorta into double-outlet right ventricle with subaor-tic VSD.” Thus, Lev and colleagues described a classification scheme for DORV based on the “commitment” of the VSD to either or both great arteries.148 The VSD can be subaortic, dou-bly committed, noncommitted, or subpulmonic.The subaortic type is the most common (47%) and occurs when the VSD is located directly beneath the aortic annulus. Doubly committed VSD (4%) is present when the VSD lies beneath both the aorta and the pulmonary artery, which are usually side-by-side in this lesion. The noncommitted VSD (26%) exists when the VSD is remote from the great vessels. The subset of DORV hearts with the VSD located beneath the pulmonary valve also are classified as the Taussig–Bing syn-drome (Fig. 20-53).149 This occurs in 23% of cases of DORV with VSD, and it occurs when the aorta rotates more anteriorly, with the pulmonary artery rotated more posteriorly.150Clinical Manifestations and Diagnosis. Patients with DORV typically present with one of the following three scenar-ios: (a) those with doubly committed or subaortic VSD present with congestive heart failure and a high propensity for pulmo-nary hypertension, much like infants with a large single VSD; (b) those with a subaortic VSD and pulmonary stenosis present with cyanosis and hypoxia, much like infants with tetralogy of Fallot; and (c) those with subpulmonic VSD present with cya-nosis, much like those with D-TGA, because streaming directs desaturated systemic venous blood to the aorta and oxygenated blood to the pulmonary artery.140 Thus, the three critical factors influencing the clinical presentation and subsequent manage-ment of infants with DORV are the size and location of the VSD, the presence or absence of important RVOT obstruc-tion, and the presence of other anomalies (especially associ-ated hypoplasia of left-sided structures sometimes seen with subpulmonary VSD).Echocardiography is the mainstay of diagnosis and can also provide valuable information regarding the feasibility of biventricular repair. Specific anatomic questions that should be resolved to assist in surgical planning in addition to those mentioned earlier include the coronary anatomy (presence of a conal branch or left anterior descending from the right coronary coursing across the conus), the presence of additional muscular VSDs remote from either great vessel, and the distance between the tricuspid and pulmonary valve. Cardiac catheterization is rarely necessary in neonates or infants, except to determine the degree of pulmonary hypertension and to determine the effects of previous palliative procedures on the pulmonary arterial anatomy.Therapy. The goals of corrective surgery are to relieve pul-monary stenosis, to provide separate and unobstructed outflow pathways from each ventricle to the correct great vessel, and to achieve separation of the systemic and pulmonary circulations.Double-Outlet Right Ventricle With Noncommitted Ventricular Septal DefectThe repair of hearts with DORV and noncommitted VSD can be accomplished by constructing an intraventricular tunnel con-necting the VSD to the aorta, closing the pulmonary artery, and placing a valved extracardiac conduit from the RV to the pulmonary artery. In patients without pulmonary stenosis who have intractable congestive failure, a pulmonary artery band can be placed in the first 6 months to control pulmonary artery Figure 20-53. Angiographic appearance of the aorta in a patient with Taussig-Bing anomaly. Note the hypoplastic arch (‘*’).Figure 20-52. DORV, aortomitral discontinuity (‘*’), aorta mostly arising from RV (arrow).Brunicardi_Ch20_p0751-p0800.indd 78322/02/19 2:56 PM 784SPECIFIC CONSIDERATIONSPART IIovercirculation and prevent the development of pulmonary hypertension.Infants with pulmonary stenosis can be managed with a systemic-to-pulmonary shunt followed by biventricular repair as described by Belli and colleagues in 1999, or with a modi-fied Fontan.151 There is no consensus on the timing of repair, but recent literature suggests that repair within the first 6 months is associated with better outcome. However, in cases where an extracardiac-valved conduit is necessary, it is better to delay definitive repair until the child is 2 to 3 years of age because this allows placement of a larger conduit and possibly reduces the number of future obligatory conduit replacements.147Double-Outlet Right Ventricle With Subaortic or Doubly Committed Ventricular Septal Defect Without Pulmonary StenosisThis group of patients can be treated by creating an intracardiac baffle that directs blood from the LV into the aorta. Enlargement of the VSD may be necessary to allow ample room for the baf-fle; this should be done anterosuperiorly to avoid injury to the conduction system that normally lies inferoposteriorly along the border of the VSD. In addition, other important considerations in constructing the LV outflow tunnel include the prominence of the conal septum, the attachments of the tricuspid valve to the conal septum, and the distance between the tricuspid and pulmonary valves. In some instances, unfavorable anatomy may preclude placement of an adequate intracardiac baffle, neces-sitating single ventricle repair.Double-Outlet Right Ventricle With Subaortic or Doubly Committed Ventricular Septal Defect With Pulmonary StenosisRepair of this defect is similar to the above except that concomi-tant RVOT reconstruction must be performed in addition to the intracardiac tunnel. The RVOT augmentation can be accom-plished with the placement of a transannular patch or with place-ment of an extracardiac-valved conduit when an anomalous left anterior descending artery precludes use of a patch.Taussig–Bing Syndrome Without Pulmonary StenosisThese infants are best treated with a balloon septostomy dur-ing the neonatal period to improve mixing, followed by VSD closure baffling LV egress to the pulmonary artery and an arte-rial switch operation. The Kawashima procedure,152 in which an intraventricular tunnel is used to baffle LV egress directly to the aorta, may alternatively be used when the aorta is more posterior or when there is associated pulmonary stenosis.Taussig–Bing Syndrome With Pulmonary StenosisThis defect may be treated with a variety of techniques, depend-ing on the specific anatomic details and the expertise of the treat-ment team. A Rastelli-type repair, which involves construction of an intraventricular tunnel through the existing VSD that con-nects the LV to both great vessels, followed by division of the pulmonary artery at its origin and insertion of a valved conduit from the RV to the distal pulmonary artery, can be performed.153 Alternatively, a Yasui procedure, which involves baffling the VSD to the pulmonary artery and creation of a DKS anastomo-sis between the pulmonary artery and the aorta with patch aug-mentation, can be accomplished concomitant with placement of an RV pulmonary artery conduit.154Results. The results of DORV repairs are generally favor-able, especially for the tetralogy-type DORV with subaortic VSD.150,155 However, more complex types of DORV, including noncommitted VSD and Taussig–Bing type, still carry impor-tant morbidity and mortality.150,151,155 Furthermore, repeated interventions for RVOT reconstruction or staged operations for patients triaged to single-ventricle pathways pose late hazards for patients surviving initial repair. A single-institution series evaluated 393 patients with DORV.150 The authors found that the need for reintervention approached 37% at 15 years follow-ing repair. Arterial switch operation, as opposed to Rastelli-type repair, was associated with an increased risk of early postrepair mortality, but mitigated against the risk of late death. Patients with hypoplastic left-sided structures and a nonsubaortic VSD may fare better with a single-ventricle repair.Tetralogy of FallotAnatomy. The original description of tetralogy of Fallot (TOF) by Ettienne Louis Fallot,156 as the name implies, included four abnormalities: a large perimembranous VSD adjacent to the tri-cuspid valve; an overriding aorta; a variable degree of RVOT obstruction, which might include hypoplasia and dysplasia of the pulmonary valve as well as obstruction at the subvalvar and pulmonary artery level; and right ventricular hypertrophy. More recently, the Van Praagh et al157 pointed out that TOF could be more correctly termed monology of Fallot, since the four com-ponents are explained by the malposition of the infundibular sep-tum. When the infundibular septum is displaced anteriorly and leftward, the RVOT is narrowed and its anterior displacement results in failure of fusion of the ventricular septum between the arms of the trabeculo-septo-marginalis (Fig. 20-54).The morphology of TOF is markedly heterogeneous and includes an absent pulmonary valve, concomitant AV septal defects, and pulmonary atresia with major aortopulmonary collaterals. The present discussion will focus only on the so-called classic presentation of TOF without coexisting intracardiac defects.Anomalous coronary artery patterns, related to either ori-gin or distribution, have been described in TOF.158 However, the most surgically important coronary anomaly occurs when AortaMPAVSDMultilevelpulmonary stenosisRVHFigure 20-54. Tetrology of Fallot. (Used with permission from Kelly Rosso MD.)Brunicardi_Ch20_p0751-p0800.indd 78422/02/19 2:56 PM 785CONGENITAL HEART DISEASECHAPTER 20the left anterior descending artery arises as a branch of the right coronary artery. This occurs in approximately 3% of cases of TOF and may preclude placement of a transannular patch, as the left anterior descending coronary artery crosses the RVOT at varying distances from the pulmonary valve annulus.159Pathophysiology and Clinical Presentation. The initial presentation of a child afflicted with TOF depends on the degree of RVOT obstruction. Children with cyanosis at birth usually have severe pulmonary annular hypoplasia with concomitant hypoplasia of the peripheral pulmonary arteries. Most children, however, present with mild cyanosis at birth, which then pro-gresses as the right ventricular hypertrophy further compromises the RVOT. Cyanosis usually becomes significant within the first 6 to 12 months of life, and the child may develop characteristic “tet” spells, which are periods of extreme hypoxemia. These spells are characterized by decreased pulmonary blood flow and an increase in systemic blood flow. They can be triggered by any stimulus that decreases systemic vascular resistance, such as fever, agitation, or vigorous physical activity. Cyanotic spells increase in severity and frequency as the child grows, and older patients with uncorrected TOF may often squat, which increases peripheral vascular resistance and relieves the cyanosis.Evaluation in the older patient with TOF may demonstrate clubbing, polycythemia, hemoptysis, or brain abscesses. Chest radiography will demonstrate a boot-shaped heart (Fig. 20-55), and EKG will show the normal pattern of right ventricular hypertrophy. Echocardiography confirms the diagnosis because it demonstrates the position and nature of the VSD, defines the character of the RVOT obstruction, and often visualizes the branch pulmonary arteries and the proximal coronary arteries. Cardiac catheterization is rarely necessary and is actually risky in TOF since it can create spasm of the RVOT muscle and result in a hypercyanotic episode (tet spell). Occasionally, aortogra-phy (Fig. 20-56) is necessary to delineate the coronary artery anatomy.Treatment. John Deanfield160 stated “…long follow-up inevi-tably means surgery in an earlier era: More recent surgery, at a younger age, with better preoperative, operative, and post-operative care, will improve long-term results. Data from the former (earlier) era will be overly pessimistic.” This statement is particularly pertinent as surgical correction of TOF has evolved from a staged approach of antecedent palliation in infancy fol-lowed by intracardiac repair to primary repair during the first few months of life without prior palliative surgery.However, systemic-to-pulmonary shunts, generally an MBTS, may still be preferred with an unstable neonate younger than 3 months of age, when an extracardiac conduit is required because of an anomalous left anterior descending coronary artery, or when pulmonary atresia, significant branch pulmo-nary artery hypoplasia, or severe noncardiac anomalies coexist with TOF.Traditionally, TOF was repaired through a right ventricu-lotomy, providing excellent exposure for closure of the VSD and relief of the RVOT obstruction, but concerns that the resul-tant scar would significantly impair right ventricular function or lead to lethal arrhythmias led to the development of a transatrial approach. Transatrial repair, except in cases when the presence of diffuse RVOT hypoplasia requires insertion of a transannular patch, is now being increasingly advocated by many, although its superiority has not been conclusively demonstrated.161The operative technique involves the use of CPB. All existing systemic-to-pulmonary arterial shunts, as well as the ductus arteriosus, are ligated. A right atriotomy is then made, and the anatomy of the VSD and the RVOT are assessed by retracting the tricuspid valve. The outflow tract obstruction is relieved by resecting the offending portion of the infundibular septum as well as any muscle trabeculations. If necessary, a pul-monary valvotomy or, alternatively, a longitudinal incision in the main pulmonary artery can be performed to improve expo-sure. The diameter of the pulmonary valve annulus is assessed by inserting Hegar dilators across the outflow tract; if the pul-monary artery/aorta diameter is less than 0.5, or the estimated RV/LV pressure is greater than 0.7, or the size of the pulmo-nary valve is less than a Z score of −2.5, a transannular patch is inserted. Patch closure of the VSD is then accomplished, taking Figure 20-56. CT aortogram showing the large aorta often associated with conotruncal anomalies, rotated coronaries, and extremely hypoplastic main and branch pulmonary arteries in a patient with TOF.Figure 20-55. Chest x-ray showing a boot shaped heart in an infant with tetralogy of Fallot.Brunicardi_Ch20_p0751-p0800.indd 78522/02/19 2:56 PM 786SPECIFIC CONSIDERATIONSPART IIcare when placing sutures along the posteroinferior portion to avoid the conduction system.Results. Operative mortality for primary repair of TOF in infancy is less than 5% in most series.161 Previously reported risk factors such as transannular patch insertion or younger age at time of repair have been eliminated secondary to improved intraoperative and postoperative care. According to the Society of Thoracic Surgeons Congenital Heart Surgery Database, dis-charge mortality from 3059 operations from 2002 to 2007 was 7.5% for initial palliation, 1.3% for primary repair, and 0.9% for staged repair, indicating similar outcomes for patients get-ting primary repair compared to staged repair.162 Nevertheless, for neonatal repair, discharge mortality increased to 6.2% with palliation and 7.8% with primary repair. This may be partly explained by a higher chance of postoperative complications in neonates.A major complication of repaired TOF is the develop-ment of pulmonary insufficiency, which subjects the RV to the adverse effects of acute and chronic volume overload. This is especially problematic if residual lesions such as a VSD or peripheral pulmonary stenosis exist. Pulmonary valve regurgita-tion after repair of TOF is relatively well tolerated in the short term, partly because the hypertrophied RV usually adapts to the altered hemodynamic load.163 The detrimental effects of chronic pulmonary valve regurgitation are, however, numerous, and include progressive right ventricular dilatation and failure, tri-cuspid valve regurgitation, exercise intolerance, arrhythmia, and sudden death. Mechanoelectrical interaction, by which a dila-tated RV provides the substrate for electrical instability, might underlie the propensity toward ventricular arrhythmia.164 In sup-port of this contention, Gatzoulis and colleagues163,164 found that the risk of symptomatic arrhythmia was high in patients with marked right ventricular enlargement and QRS prolongation on resting ECG of more than 180 ms. Karamlou et al have shown that similar structural and hemodynamic abnormalities, including a larger right atrial volume and right ventricular chamber size, are also related to atrial arrhythmias in patients following TOF repair.165 We found that prolongation of the QRS duration beyond a threshold of 160 ms increased the risk of atrial arrhythmias.165 Together, these data show that a similar mechanism could be responsible for both atrial and ventricular arrhythmias after repair in TOF patients.When significant deterioration of ventricular func-tion occurs, insertion of a pulmonary valve may be required, although this is rarely necessary in infants. Unfortunately, there are no universal criteria establishing the timing of pulmonary valve replacement. The current criteria for pulmonary valve replacement are the presence of two of the following criteria: RVEDD index >160 ml/m2, RVEDI >70 ml/m2, LVEDV index >65 ml/m2, RVEF <45%, RVOT aneurysm, and clinical symp-toms or signs, including syncope or VT.166 PVR can be achieved with minimal morbidity and mortality.167The alternative to surgical PVR is percutaneous pulmo-nary valve implantation. The Melody valve system (Fig. 20-57) is the most popular of such systems. Following risk adjustment, no significant differences were observed between surgical or transcatheter PVR. However, transcatheter PVR was associated with a shorter hospitalization. Hospitalization costs are similar for both procedures.168Arrhythmias are potentially the most serious late complication following TOF repair. In a multicenter cohort of 793 patients studied by Gatzoulis et al,164 a steady increase was documented in the prevalence of ventricular and atrial tachyarrhythmia and sudden cardiac death in the first 5 to 10 years after intracardiac repair. Clinical events were reported in 12% of patients at 35 years after repair. Prevalence of atrial arrhythmias from other studies, however, ranges from 1% to 11%,163,164 which is a reflection of the strong time dependence of arrhythmia onset.Underlying causes of arrhythmia following repair are complex and multifactorial, resulting in poorly defined opti-mum screening and treatment algorithms. Older repair age has been associated with an increased frequency of both atrial and ventricular arrhythmias. Impaired ventricular function second-ary to a protracted period of cyanosis before repair might con-tribute to the propensity for arrhythmia in older patients.Ventricular Septal DefectAnatomy. VSD refers to a hole between the LV and RV. These defects are common, comprising 20% to 30% of all cases of CHD, and may occur as an isolated lesion or as part of a more Figure 20-57. The Melody valve.Brunicardi_Ch20_p0751-p0800.indd 78622/02/19 2:56 PM 787CONGENITAL HEART DISEASECHAPTER 20complex malformation.169 VSDs vary in size from 3 to 4 mm to more than 3 cm and are classified into four types based on their location in the ventricular septum: perimembranous (or paramembranous, conoventricular), AV canal (inlet), outlet or supracristal, and muscular (Fig. 20-58).Perimembranous VSDs are the most common type requir-ing surgical intervention, comprising approximately 80% of cases.169 These defects involve the membranous septum and include the malalignment defects seen in tetralogy of Fallot. In rare instances, the anterior and septal leaflets of the tricus-pid valve adhere to the edges of the perimembranous defect, forming a channel between the LV and the right atrium. These defects result in a large left-to-right shunt due to the large pres-sure differential between the two chambers.AV canal defects, also known as inlet defects, occur when part or all of the septum of the AV canal is absent. The VSD lies beneath the tricuspid valve and is limited upstream by the tricuspid annulus, without intervening muscle.The supracristal or outlet VSD results from a defect within the conal septum. Characteristically, these defects are limited upstream by the pulmonary valve and are otherwise surrounded by the muscle of the infundibular septum.Muscular VSDs are the most common type and may lie in four locations: anterior, midventricular, posterior, or apical. These are surrounded by muscle and can occur anywhere along the trabecular portion of the septum. The rare “Swiss-cheese” type of muscular VSD consists of multiple communications between the RV and LV, complicating operative repair.Pathophysiology and Clinical Presentation. The size of the VSD determines the initial pathophysiology of the disease. Large VSDs are classified as nonrestrictive and are at least equal in diameter to the aortic annulus. These defects allow free flow of blood from the LV to the RV, elevating right ventricular pres-sures to the same level as systemic pressure.Consequently, the pulmonary-to-systemic flow ratio (Qp to Qs) is inversely dependent on the ratio of pulmonary vas-cular resistance to systemic vascular resistance. Nonrestrictive VSDs produce a large increase in pulmonary blood flow, and the afflicted infant will present with symptoms of congestive heart failure. However, if untreated, these defects will cause pulmonary hypertension with a corresponding increase in pulmonary vascular resistance. This will lead to a reversal of flow (a right-to-left shunt), which is known as Eisenmenger’s syndrome.Small restrictive VSDs offer significant resistance to the passage of blood across the defect, and therefore right ventricu-lar pressure is either normal or only minimally elevated and the ratio of Qp to Qs rarely exceeds 1.5. These defects are generally asymptomatic because there are few physiologic consequences. However, there is a long-term risk of endocarditis because endo-cardial damage from the jet of blood through the defect may serve as a possible nidus for colonization (Fig. 20-59A,B).Diagnosis. The child with a large VSD will present with severe congestive heart failure and frequent respiratory tract infections. Children with Eisenmenger’s syndrome may be deceptively asymptomatic until frank cyanosis develops.The chest radiograph will show cardiomegaly and pulmo-nary overcirculation, and the ECG will show signs of left ven-tricular or biventricular hypertrophy. Echocardiography provides definitive diagnosis and can estimate the degree of shunting as well as pulmonary arterial pressures. Cardiac catheterization has MembranousMuscularInletSupracristalTVFigure 20-58. Types of VSD. (Used with permission from Kelly Rosso MD.)ABFigure 20-59. A. Severe TV and VSD endocarditis (‘*’) in a 4 yo untreated patient. B. Echocardiographic appearance of the same patient after patch repair(‘*’) of the VSD and complete exci-sion of the tricuspid valve.Brunicardi_Ch20_p0751-p0800.indd 78722/02/19 2:56 PM 788SPECIFIC CONSIDERATIONSPART IIlargely been supplanted by echocardiography, except in older children where measurement of pulmonary resistance is neces-sary prior to recommending closure of the defect.Treatment. VSDs may close or narrow spontaneously, and the probability of closure is inversely related to the age at which the defect is observed. Thus, infants at 1 month of age have an 80% incidence of spontaneous closure, whereas a child at 12 months of age has only a 25% chance of closure.170 This has an important impact on operative decision-making because a small or moder-ate-size VSD may be observed for a period of time in the absence of symptoms. Large defects and those in severely symptomatic neonates should be repaired during infancy to relieve symptoms and because irreversible changes in pulmonary vascular resis-tance may develop during the first year of life.Repair of isolated VSDs requires the use of CPB with moderate hypothermia and cardioplegic arrest. The right atrial approach (Fig. 20-60) is preferable for most defects, except apical muscular defects, which often require a right ventricu-lotomy for adequate exposure. Supracristal defects may alter-natively be exposed via a pulmonary arteriotomy or through an incision in the RV immediately beneath the pulmonary valve (Fig. 20-61). Regardless of the type of defect present, a right atrial approach can be used initially to inspect the anatomy, as this may be abandoned should it offer inadequate exposure for repair. After careful inspection of the heart for any associated malformations, a patch repair is employed, taking care to avoid the conduction system. Routine use of intraoperative trans-esophageal echocardiography should be used to assess for any residual defect.Successful percutaneous device closure of VSDs using the Amplatzer device has been described.152 The device has demon-strated a 100% closure rate in a small series of patients with iso-lated or residual VSDs, or as a collaborative treatment strategy for the VSD component in more complex congenital lesions. Proponents of device closure argue that its use can decrease the complexity of surgical repair, avoid reoperation for a small residual lesion, or avoid the need for a ventriculotomy. The use of devices to close paramembranous defects can cause heart block because the defect is in close association to the conduction system (Fig 20-62).171 The procedure can be performed percuta-neously or through the per ventricular approach. Embolization of the device is an added risk.Multiple or “Swiss-cheese” VSDs represent a special case, and many cannot be repaired during infancy. In patients in whom definitive VSD closure cannot be accomplished, tem-porary placement of a pulmonary artery band can be employed to control pulmonary flow. This allows time for spontaneous closure of many of the smaller defects, thus simplifying surgi-cal repair.172Some centers, however, have advocated early definitive repair of the Swiss-cheese septum, by using oversize patches, fibrin glue, and combined intraoperative device closure, as well as techniques to complete the repair transatrially.173Results. Even in very small infants, closure of VSDs can be safely performed with hospital mortality near 0%. The main risk factor remains the presence of other associated lesions, espe-cially when present in symptomatic neonates with large VSDs.Figure 20-60. Intra-op picture during a VSD closure performed by interrupted suture technique with patch closure.Figure 20-61. Echocardiographic appearance of a supracristal VSD (arrow). Note its location just beneath the pulmonary valve (‘*’).Brunicardi_Ch20_p0751-p0800.indd 78822/02/19 2:56 PM 789CONGENITAL HEART DISEASECHAPTER 20Atrioventricular Canal DefectsAnatomy. AV canal defects result from failure of fusion of the endocardial cushions in the central portion of the heart, caus-ing a lesion that involves the atrial and the ventricular septum, as well as the anterior mitral and septal tricuspid valve leaf-lets. Defects involving primarily the atrial septum are known as partial AV canal defects and frequently occur in conjunction with a cleft anterior mitral leaflet. Complete AV canal defects have a combined deficiency of the atrial and ventricular sep-tum associated with a common AV orifice rather than separate tricuspid and mitral valves. The common AV valve generally has five leaflets, three lateral (free wall) and two bridging (septal) leaflets. The defect in the ventricular septum can lie either between the two bridging leaflets or beneath them. The relationship between the septal defect and the anterior bridging leaflet forms the basis of the Rastelli classification for complete AV canal defects (Fig. 20-63).174,175Pathophysiology and Diagnosis. Partial AV canal defects, in the absence of AV valvular regurgitation, frequently resemble isolated ASDs. Left-to-right shunting predominates as long as pulmonary vascular resistance remains low. However, 40% of patients with partial AV canal defects have moderate-to-severe valve incompetence, and progressive heart failure occurs early in this patient population.175 Complete AV canal defects produce more severe pathophysiologic changes because the large intra-cardiac communication and significant AV valve regurgitation contribute to ventricular volume loading and pulmonary hyper-tension. Children with complete AV canal defects develop signs of congestive heart failure within the first few months of life.Physical examination may reveal a right ventricular heave and a systolic murmur. Children may also present with endo-carditis or paradoxical emboli as a result of the intracardiac communication. Chest radiography will be consistent with con-gestive heart failure, and the EKG demonstrates right ventricu-lar hypertrophy with a prolonged PR interval and is classically associated with left axis deviation.Two-dimensional echocardiography (Fig. 20-64) with color-flow mapping is confirmatory, but cardiac catheterization can be employed to define the status of the pulmonary vascula-ture, with a pulmonary vascular resistance greater than 12 Wood units indicating inoperability.Treatment. The management of patients with AV canal defects can be especially challenging. Timing of operation is individualized. Patients with partial defects can be electively repaired between 2 and 5 years of age, whereas complete AV canal defects should be repaired within the first year of life to prevent irreversible changes in the pulmonary circulation. Complete repair in infancy should be accomplished, with palliative procedures such as pulmonary artery banding reserved for only those infants with other complex lesions or who are too ill to tolerate CPB.The operative technique requires the use of either continu-ous hypothermic CPB or, for small infants, deep hypothermic circulatory arrest. The heart is initially approached through an oblique right atriotomy, and the anatomy is carefully observed. In the case of a partial AV canal, the cleft in the mitral valve is repaired with interrupted sutures and the ASD is closed with a pericardial patch. Complete AV canal defects are repaired by patch closure of the VSD, separating the common AV valve into tricuspid and mitral components and suspending the neovalves from the top of the VSD patch and closing the ASD.Results. Partial AV canal defects have an excellent outcome, with a mortality rate of 0% to 2% in most series.175 Complete AV canal defects are associated with anoperative mortality of 3% to 4%.176The most frequently encountered postoperative problems are complete heart block (1%–2%), right bundle-branch block (22%), arrhythmias (11%), RVOT obstruction (11%), and severe mitral regurgitation (13%–24%).175 The increasing use of intraoperative transesophageal echocardiography may positively Figure 20-62. Intraoperative picture at the time of removal of a percutaneously placed VSD device causing severe TR and complete heart block. Note the close association of the device to the tricuspid valve leaflet (arrow) and cordae.Type AType BType CFigure 20-63. Rastelli classification of complete AVSD. (Used with permission from Kelly Rosso MD.)Figure 20-64. Echo of an infant with complete AVSD. Note the prominent absence of the ‘crux’ (‘*’) of the heart in this defect.Brunicardi_Ch20_p0751-p0800.indd 78922/02/19 2:56 PM 790SPECIFIC CONSIDERATIONSPART IIinfluence outcomes, as the adequacy of repair can be assessed and treated without need for subsequent reoperation.174-175Interrupted Aortic ArchAnatomy. Interrupted aortic arch (IAA) is a rare defect, com-prising approximately 1% of all cases of CHD.177 It is defined as an absence of luminal continuity between the ascending and descending aorta and does not occur as an isolated defect in most cases because a VSD or PDA is usually present. IAA is classified based on the location of the interruption (Fig. 20-65 to Fig. 20-67).Clinical Manifestations and Diagnosis. Infants with IAA have ductal-dependent systemic blood flow and will develop profound metabolic acidosis and hemodynamic collapse upon ductal closure. In the rare instance of failed ductal closure, the diagnosis may be missed during infancy, and the child will pres-ent with symptoms of congestive heart failure from a persistent left-to-right shunt.Once definitive diagnosis is made in infants, usually with echocardiography, preparations are made for operative interven-tion, and prostaglandin E1 is infused to maintain ductal patency and correct acidosis. The infant’s hemodynamic status should Figure 20-66. CT angiogram of a Type A IAA.AoAoPAType AType BType CPAPAAoFigure 20-65. Types of IAA. (Used with permission from Nicholas Clarke MD.)Figure 20-67. MRI reconstruction of a Type B IAA.be optimized with mechanical ventilation and inotropic support. An effort should be made to increase pulmonary vascular resis-tance by decreasing the fractional inspired oxygen and avoiding hyperventilation because this will preferentially direct blood into the systemic circulation.Treatment. Initial strategies for the management of IAA involved palliation though a left thoracotomy by using one of the arch vessels as a conduit to restore aortic continuity. Pulmo-nary artery banding can be simultaneously performed to limit left-to-right shunting because it is not feasible to repair the VSD or other intracardiac communications with this approach.However, complete one stage surgical repair in infants with IAA is now preferable. The operative technique involves use of a median sternotomy and CPB with short periods of cir-culatory arrest. Aortic arch reconstruction can be accomplished with either direct anastomosis or patch aortoplasty followed by closure of the VSD.178In certain cases, the defect will involve hypoplasia of the left heart, precluding attempts at definitive repair. These infants should be managed with a Norwood procedure followed by a Fontan repair.Results. Outcomes in infants with IAA have improved sub-stantially over the last decades as a result of improved periop-erative care. Operative mortality is now less than 10% in most series.177,179 Some authors advocate the use of patch augmenta-tion of the aorta to ensure adequate relief of LVOT obstruction and to diminish anastomotic tension, thus reducing the subse-quent risk of restenosis and tracheobronchial compression.178Pediatric Mechanical Circulatory SupportMechanical circulatory support has become standard therapy for adults with end stage heart failure. There has been a sig-nificant lag with development of similar devices for the pediatric population. This is probably related to the smaller mar-ket for these devices and the technical challenges associated with the anatomical constraints secondary to anatomy and size of the patients. Extracorporeal membrane oxygenation (ECMO) 8Brunicardi_Ch20_p0751-p0800.indd 79022/02/19 2:56 PM 791CONGENITAL HEART DISEASECHAPTER 20has been the mainstay of mechanical support in many centers for the pediatric population. The adaptation of other adult devices to the pediatric population las led to the slow but steady devel-opment of pediatric durable mechanical devices. The Berlin Heart EXCOR (Berlin Heart AG, Berlin, Germany) device was approved by the FDA in 2011 in the United States as a paracor-poreal device that can be used as a bridge to transplantation. This device has a 73% overall survival post implant at 12 months.97 Infection, stroke and bleeding remain significant morbidities associated with it. Young age and small body surface area still remain poor prognostic factors. In 2010, the National Heart, Lung, and Blood Institute launched the Pumps for Kids, Infants, and Neonates (PumpKIN) program to promote development of new devices with the goal of clinical use.ECMO remains the most commonly used form of mechan-ical support in the pediatric population in the United States. Per the ECLS Registry report released by the Extracorporeal Life Support Organization, as of January 2017, there were a total of 16,531 ECMO runs performed for cardiac causes, internation-ally.180 The survival to discharge is about 40% in the neona-tal population as opposed to 50% in the pediatric population. ECMO remains the only means of salvage for newborns and infants in many institutions. The biggest limitation remains the short duration it can be used. It is often used as a bridge to recovery and sometimes as a bridge to transplantation. The abil-ity to place small infants on ECMO with peripheral cannulation continues to make it a very attractive first line option.Ventricular assist devices can be either of the pulsatile or continuous types. The Berlin Heart EXCOR (Berlin Heart AG, Berlin, Germany) remains a classic example of a pulsa-tile device. The Impella 2.5 (Abiomed) (Fig. 20-68) has been used in the pediatric population as a temporary support device for recovering myocarditis, during treatment of acute rejection after heart transplantation and high-risk interventions in frag-ile patients with marginal function.181,182 Other continuous flow devices available for the pediatric patient include the Heartmate II Figure 20-68. Impella 2.5 (Abiomed). (Reproduced with permis-sion from Abiomed. Danvers, MA.)Figure 20-69. Heartware HVAD. (HeartWare® HVAD (Heart-Ware Inc., Miami Lakes, FL.)and Heartmate III devices (Thoratec, Pleasanton, CA), DeBakey VAD Child (MicroMed Technology, Houston, TX), PediMag (Thoratec, Pleasanton, CA), Jarvik2015 and HeartWare HVAD (Fig 20-69) (HeartWare international Inc, Framingham, MA).183 The total artificial heart (SynCardia Systems Inc, Tuscon, Az, USA) is an implantable biventricular device that replaces both ventricles. With the new introduction of the 50 ml pump, its popularity in the pediatric population has risen.Posttransplant survival of patients bridged with and with-out mechanical circulatory support (ventricular assist device or total artificial heart) at 5 years post transplant remains the same. However, patients bridged to transplant with ECMO have a sig-nificantly worse survival.184 All in all, the field of pediatric heart surgery is very exciting and rapidly expanding.Pediatric Heart TransplantationHeart transplantation is currently an accepted mode of therapy in infants and children. Annually, about 600 pediatric heart transplants are performed worldwide,184 about 400 of which are performed in the United States.185 The common indications for heart transplant in the pediatric population are congenital heart disease, dilated cardiomyopathy, retransplantation, and other rare indications (e.g., arrhythmogenic right ventricular dysplasia, cancer, muscular dystrophy, and restrictive cardio-myopathy). The most common congenital heart defect requir-ing transplantation remains hypoplastic left heart syndrome. Although in the past some centers have advocated primary heart transplantation for this lesion, the improved outcomes with surgical palliation have eliminated this as an option. The first year post transplant remains the greatest risk for mortality. The overall median survival is 20.7 years for infants, 18.2 years for children age 1 to 5 years, 14 years for age 6 to 10 years, and 12.7 years for those age 11 to 17 years.184 Males seem to have a modestly superior overall survival compared with females. The causes of mortality include cardiac allograft vasculopathy, acute Brunicardi_Ch20_p0751-p0800.indd 79122/02/19 2:57 PM 792SPECIFIC CONSIDERATIONSPART IIrejection, infections, and graft failures. In the current era, the expected 1-year survival rate is 80% to 90%, the 2-year survival rate is 80% to 85%, and the 5-year survival rate is approximately 70% to 80% in experienced centers.186 Interestingly, infants who undergo transplantation in the first month of life appear to have a survival advantage over infants who undergo transplantation during the remainder of the first year of life.The two main techniques for performing the implant of the heart are the right atrial technique developed by Lower and Shumway and the bicaval-left atrial technique described by Sievers and associates.187 In the latter technique, implantation consists of five anastamoses performed using a running prolene suture. These include the left atrial cuff, aorta, pulmonary artery, and the superior and inferior vena cave. One of the cornerstones of postoperative management remains immunosuppression. The triple drug regimen remains popular, corticosteroids, calcineurin inhibitor (cyclosporine or tacrolimus), and an antiproliferative agent (azathioprine or mycophenolate mofetil). Endomyocardial biopsy and coronary angiography are performed at regular inter-vals to monitor rejection. The field of pediatric heart transplan-tation has made huge strides since the days of “Baby Fae.”188,189Public Reporting and the STS Database in Congenital Heart SurgeryThere has been a recent impetus in the filed of congenital and pediatric cardiac surgery toward public reporting of out-comes. The advantages of this include promoting patient autonomy, shows a commitment to quality improvement, and also serves as a free marketing tool. The Society of Thoracic Surgeons Congenital Heart Surgery Database (STS-CHSD), is the largest clinical database in the world for congenital and pedi-atric cardiac surgery. It was founded in 1994. It contains data of about 394,980 operations as of September 9, 2016.192 These data are the foundation for assessment of performance by benchmark and comparison of individual programmatic outcomes to national aggregate data, development and subsequent applica-tion of sophisticated risk adjustment models, quality improve-ment initiatives, research, voluntary public reporting, development of reimbursement strategies, and governmental and regulatory collaborations.190 The database is currently in its 25th overall data harvest and records and represents data from 120 participants and 392 surgeons. Thus, this database has greater than 95% penetrance. STS CHSD public reporting started in January 2015, and participation is voluntary. Report-ing is restricted to the hospital level and involves a rolling 4-year analytic window of data. Public reporting is based on the STS CHSD Operative Mortality Risk Model. Developed in 2014, this risk model calculates the operative mortality rate of hospitals performing such surgery, adjusting for procedural and patient level factors. The overall mortality rate over a 4-year period and the operative mortality rate for each of the five STAT (Society of Thoracic Surgeons—European Association for Cardio-Thoracic Surgery) categories is reported. The STAT categories are a multi-institutional, validated complexity stratification tool. They range from a score of 1 to 5, and the risk of mortality increases with each category.190 In addition, the STS star rating system was introduced, and every institution is rated as one, two, or three stars. This system is based on the confidence limits of the O/E (observed to expected) overall mortality for the institu-tion (Fig. 20-70). One star equals higher than expected operative 9Rady Children’s Hospital San DiegoRady Children’s Hospital San Diego SurgeonsEnc Devaney, MDDaniel DiBardino, MDJohn Lambert, MDPeter Pastuszko, MDOverall Star RatingPopulation: Neonates,Infants, Children & AdultsOvarallSTAT Mortality Category 1STAT Mortality Category 2STAT Mortality Category 3STAT Mortality Category 4STAT Mortality Category 5#/Eligible28/11650/3067/3991/12817/2953/37Observed2.4%0.0%1.8%0.8%5.8%8.1%Expected3.0%0.6%1.5%2.1%6.7%14.7%OE (95% CI)0.79 (0.53, 1.14)0.00 (0.00, 2.16)1.20 (0.48, 2.45)0.37 (0.01, 2.05)0.87 (0.51, 1.36)0.55 (0.12, 1.49)Adj. Rate (95% CI)2.5 (1.6, 3.5)0.0 (0.0, 1.1)2.0 (0.8, 4.1)1.0 (0.0, 5.3)6.0 (3.5, 9.4)8.7 (1.8, 23.6)San DiegoCAWebsite: http://www.rchsd.org/programs-services/cardiologyOperative and Adjusted Operative Mortality, Last 4 Years (January 2012–December 2015)Figure 20-70. Program performance as currently reported by the STS-CHSD.Brunicardi_Ch20_p0751-p0800.indd 79222/02/19 2:57 PM 793CONGENITAL HEART DISEASECHAPTER 20mortality (the 95% confidence interval for their risk-adjusted O/E mortality ratio was entirely above the number 1), two stars equals the same as expected operative mortality (the 95% con-fidence interval for their risk-adjusted O/E mortality ratio over-lapped with the number 1), and three stars equals lower than expected operative mortality (the 95% confidence interval for their risk-adjusted O/E mortality ratio was entirely below the number 1). The Spring 2016 STS CHSD Feedback Report includes data from 117 participants in the STS-CHSD, including 14 one-star programs, 83 two-star programs, and 8 three-star programs. Twelve participants did not receive a star rating due to incomplete data.191 Public reporting increased from 23% to 57.6% (all three-star programs, 50 two-star and three one-star programs). The online public reporting portal can be accessed at www.sts.org/congenital-public-reporting-module-search.There are several criticisms to the current methodology used for reporting. Important limitations of current publicly reported data (including the STS star rating system) will need to be addressed in future initiatives in order to completely engage parents of children with CHD and reassure providers that risk-adjustment models are optimized. There are four spe-cific areas that should be considered when making decisions how to improve this methodology: (a) While the mortality risk-adjustment model on which the star rating system is based is mature now, there are not comparable models that provide risk-adjusted morbidity (complication) rates. The assessment of the quality of congenital heart disease care at different centers should include complication metrics and incorporate failure-to-rescue as an important discriminator; (b) the star rating system does not provide risk-adjusted outcomes for specific procedures or, more importantly, for specific diagnoses. This is mainly because of the exceptionally wide spectrum of diagnoses and procedures in pediatric cardiac surgery that preclude sufficiently large numbers in most procedure-specific categories; (c) the star rating system, although the “best” we have at present, may not be understood equally by all families. It will be critical to provide equivalent information to the large numbers of under-resourced and non–English-speaking families; (d) finally, the current adjusted mortality rate reported by the STS is calculated from a statistical formula and refers to what the hospital’s mor-tality rate would be if the measured performance (in this case the mortality rate) were extrapolated to the overall case-mix or make-up of patients within the entire STS database. This is a critical point because a hospital’s case-mix is highly variable, and discrimination based on mortality is mostly related to out-comes of more complex procedures. In other words, if hospital A has excellent survival for less complex procedures and therefore performs very few highly complex procedures (i.e., choosing a case-mix consistent with its expertise), the application of an extrapolated mortality rate may not reflect the actual quality of care for that particular hospital. This issue is evident because the majority of experienced centers with arguably the highest complexity received a “middle star” rating of 2. This rating may reflect calibration issues with the current rating system, whereby centers are potentially penalized for high-complexity predominance.Fortunately, there are efforts to correct these deficien-cies. In 2016, the STS CHSD Task Force and STS Quality Measurement Task Force began to collaborate on an initiative to refine risk adjustment for chromosomal abnormalities, syn-dromes, and noncardiac congenital anatomic abnormalities and to then enhance the STS CHSD Mortality Risk Model with this additional information. Upon completion of this project, STS CHSD Task Force plans to collaborate with the STS Quality Measurement Task Force to study the relationship between vol-ume (programmatic volume and surgeon volume) and outcome using this enhanced STS CHSD Mortality Risk Model.192 Also, currently under development is a multidomain quality metric that incorporates mortality, morbidity, postoperative length of stay, and the occurrence of complications. As the largest con-genital and pediatric cardiac surgical clinical data registry in the world, containing data about nearly all pediatric cardiac operations performed in the United States, STS CHSD contains a truly representative sample of national aggregate data that is useful for multiple purposes.192Future DirectionsThe future of congenital heart surgery remains very bright and exciting. The development of novel technologies such as four-dimensional MRI flow studies (Fig. 20-71) and three-dimen-sional printing have offered this field several new tools to help understand complex anatomy and pathophysiology. Three-dimensional printing of complex congenital heart defects has helped surgeons in preoperative planning by allowing transla-tion of two-dimensional cross-sectional imaging studies into a tangible and easily visualized model.193 The hollow nature of the human heart and the direct correlation of structure to disease in the congenital population allows this technology to be used in abundance in this field. Its utilization to train young surgeons is very appealing (Figs. 20-72 and 20-73).194,196 Current research in the field of genetics, device bioengineering and miniaturization, stem cell therapy, and fusion imaging technology is expected to further improve patient outcome.195,198 The improved outcomes and survival of these young and fragile patients with congeni-tal heart disease has led to the development of a complex new field termed adult congenital heart disease. The field of con-genital heart surgery is young and offers brilliant, motivated, and upcoming surgeons a very daunting challenge to better the future of these babies.Figure 20-71. 4D MRI flow study obtained in a complex single ventricle patient for the evaluation of persistent hypoxia.Brunicardi_Ch20_p0751-p0800.indd 79322/02/19 2:57 PM 794SPECIFIC CONSIDERATIONSPART IIFigure 20-72. 3D printed models of complex heart defects which were very helpful for preoperative surgical planning and patient education.ADEFBCMAPCAPulmonaryArteryAortaFigure 20-73. Example of Pre-Interventional Planning Using 3D Printed Models. Transthoracic echocardiogram (A) confirms tetralogy of Fallot/pulmonary atresia/multiple aortopulmonary collateral arteries (MAPCAs) diagnosis. Three-dimensional (3D) reconstruction (B and C) illustrates spatial relationship of patient-specific geometry such as true pulmonary arteries (blue), aorta (red), and MAPCAs (green and yellow) for central aortopulmonary shunt placement and coil planning. Three-dimensional printing (D) provides absolute scaling for planning purposes, as well as patient/family education. Angiography (E and F) captured after central shunt and prior to placement of MAPCA embolization coils. (Reproduced with permission from Ryan JR, Moe TG, Richardson R, et al: A novel approach to neonatal management of tetralogy of Fallot, with pulmonary atresia, and multiple aortopulmonary collaterals, JACC Cardiovasc Imaging. 2015 Jan;8(1):103-104.)Brunicardi_Ch20_p0751-p0800.indd 79422/02/19 2:57 PM 795CONGENITAL HEART DISEASECHAPTER 20REFERENCESEntries highlighted in bright blue are key references. 1. American Heart Association. About congenital heart defects. Available at: http://www.heart.org/HEARTORG/Conditions/CongenitalHeartDefects/Congenital-Heart-Defects_UCM_001090_SubHomePage.jsp. Accessed May 18, 2018. 2. Congenital Heart Public Health Consortium. FAQ fact sheet. Available at: https://www.aap.org/en-us/Documents/chphc/chd_fact_sheet_long.pdf. Accessed May 18, 2018. 3. Society for Thoracic Surgeons. Congenital heart surgery pub-lic reporting. Available at: https://www.sts.org/congenital-public-reporting-module-search. Accessed May 18, 2018. 4. Kouchoukos NT, Blackstone EH, Doty DB, et al. Atrial septal defect and partial anomalous pulmonary venous connection. In: Kouchoukos NT, Blackstone EH, Doty DB, et al, eds. Kirklin/Barrat-Boyes Cardiac Surgery. 3rd ed. Philadelphia: Churchill Livingstone; 2003:716. 5. Kirklin JW, Pacifico AD, Kirklin JK. The surgical treat-ment of atrioventricular canal defects. In: Arciniegas E, ed. Pediatric Cardiac Surgery. Chicago: Yearbook Medical; 1985:2398. 6. Peterson GE, Brickner ME, Reimold SC. Transesophageal echocardiography: clinical indications and applications. Circulation. 2003;107:2398-2402. 7. Kouchoukos NT, Blackstone EH, Doty DB, et al. Atrial septal defect and partial anomalous pulmonary venous connection. In: Kouchoukos NT, Blackstone EH, Doty DB, et al, eds. Kirklin/Barrat-Boyes Cardiac Surgery. 3rd ed. Philadelphia: Churchill Livingstone; 2003:740. 8. Reddy VM. Cardiac surgery for premature and low birth weight neonates. Semin Thorac Cardiovasc Surg Pediatr Card Surg Annu. 2001;4:271-276. Congenital heart defects in low-birth-weight infants are typically managed with sup-portive therapy or palliative surgery, and definitive repair is delayed. This paper describes the outcomes in 116 neonates and infants under 2500 g who underwent complete repair of simple and complex cardiac defects using cardiopulmo-nary bypass. 9. Thompson JD, Abuwari EH, Watterson KG, et al. Surgi-cal and transcatheter (Amplatzer) closure of atrial septal defect: a prospective comparison of results and cost. Heart. 2002;87:466-469. 10. Du ZD, Hijazi ZM, Kleinman CS, et al. Comparison between transcatheter and surgical closure of secundum atrial septal defect in children and adults: results of a multicenter nonran-domized trial. J Am Coll Cardiol. 2002;39:1836-1844. 11. Kutty S, Hazeem AA, Brown K, et al. Long-term (5-to 20-year) outcomes after transcatheter or surgical treatment of hemodynamically significant isolated secundum atrial septal defect. Am J Cardiol. 2012;109:1348-1352. 12. Highes ML, Maskell G, Goh TH, Wilkinson JL. Prospective comparison of costs and short term health outcomes of surgi-cal versus device closure of atrial septal defect in children. Heart. 2002;88:67-70. 13. Murphy JG, Gersh BJ, McGoon MD, et al. Long-term out-come after surgical repair of isolated atrial septal defect. N Engl J Med. 1990;323:1645-1650. 14. Hanninen M, Kmet A, Taylor DA, et al. Atrial septal defect closure in the elderly is associated with excellent quality of life, functional improvement, and ventricular remodeling. Can J Cardiol. 2011;27:698-704. 15. Mascio CE, Pasquali SK, Jacobs JP, et al. Outcomes in adult congenital heart surgery: analysis of the Society of Tho-racic Surgeons (STS) Database. J Thorac Cardiovasc Surg. 2011;142:1090-1097. 16. Hopkins RA, Bert AA, Buchholz B, et al. Surgical patch closure of atrial septal defects. Ann Thorac Surg. 2004;77:2144-2150. 17. Liu G, Qiao Y, Zou C, et al. Totally thoracoscopic surgical treatment for atrial septal defect: mid-term follow-up results in 45 consecutive patients. Heart Lung Circ. 2012;S1443-S9506. 18. Argenziano M, Oz M, Kohmoto T, et al. Totally endoscopic atrial septal defect repair with robotic assistance. Circulation. 2003;108(suppl II):II-191-II-194. 19. Luo W, Chang C, Chen S. Ministernotomy vs. full sternotomy in congenital heart defects: a prospective randomized study. Ann Thorac Surg. 2001;71(2):473-475. 20. Sebastian VA, Guleserian KJ, Leonard SR, Forbess JM. Min-isternotomy for repair of congenital cardiac disease. Interact Cardiovasc Thorac Surg. 2009;9(5):819-821. 21. Srivastava AR, Banerjee A, Tempe DK, et al. A comprehen-sive approach to fast tracking in cardiac surgery: ambula-tory low-risk open-heart surgery. Eur J Cardiothorac Surg. 2008;33:955-960. 22. King TD, Thompson SL, Steiner C, Mills NL. Secundum atrial septal defects: nonoperative closure during cardiac cath-eterization. JAMA. 1976;235(23):2506-2509. 23. Karamlou T, Diggs BS, McCrindle BW, Ungerleider RM, Welke KF. The rush to atrial septal defect closure: is the introduction of percutaneous closure driving utilization? Ann Thorac Surg. 2008;86:1584-1590. 24. Zeevi B, Keane JF, Castaneda AR, Perry SB, Lock JE. Neonatal critical valvular aortic stenosis. A comparison of surgical and balloon dilatation therapy. Circulation. 1989;80(4):831-839. 25. Alsoufi B, Karamlou T, McCrindle BW, Caldarone CA. Man-agement options in neonates and infants with critical left ven-tricular outflow tract obstruction. Eur J Cardiothorac Surg. 2007;31(6):1013-1021. 26. Hammon JW Jr, Lupinetti FM, Maples MD, et al. Predictors of operative mortality in critical aortic stenosis presenting in infancy. Ann Thorac Surg. 1988;45(5):537-540. 25. Hill GD, Ginde S, Rios R, Frommelt PC, Hill KD. Surgical valvotomy versus balloon valvuloplasty for congenital aor-tic valve stenosis: a systematic review and meta-analysis. J Am Heart Assoc. 2016;5(8):e003931. A review article and a meta-analysis comparing balloon valvuloplasty to surgi-cal aortic valvotomy. This article describes the outcomes and reintervention rates in both the groups. 26. Moore P, Egito E, Mowrey H, Perry SB, Lock JE, Keane JF. Midterm results of balloon dilatation of congenital aortic stenosis: predictors of success. J Am Coll Cardiol. 1996;27(5):1257-1263. 27. Ross DN. Replacement of aortic and mitral valves with a pul-monary autograft. Lancet. 1967;57(7523):956-958. 28. Jones TK, Lupinetti FM. Comparison of Ross procedures and aortic valve allografts in children. Ann Thorac Surg. 1998;66(6 suppl):S170-S173. 29. Karamlou T, Jang K, Williams WG, et al. Outcomes and associated risk factors for aortic valve replacement in 160 children: a competing risks analysis. Circulation. 2005;29(22):3462-3469. 30. Marasini M, Zannini L, Ussia GP, et al. Discrete subaor-tic stenosis: incidence, morphology, and surgical impact of associated subaortic anomalies. Ann Thorac Surg. 2003;75(6):1763-1768. 31. Karamlou T, Gurofsky R, Bojcevski A, et al. Prevalence and associated risk factors for intervention in 313 children with subaortic stenosis. Ann Thorac Surg. 2007;84:900-906. 32. Somerville J, Stone S, Ross D. Fate of patients with fixed subaortic stenosis after surgical removal. Br Heart J. 1980; 43(6):629-647. 33. Williams JCP, Barratt-Boyes BG, Lowe JB. Supravalvular aortic stenosis. Circulation. 1961;24:1311-1318.Brunicardi_Ch20_p0751-p0800.indd 79522/02/19 2:57 PM 796SPECIFIC CONSIDERATIONSPART II 34. Tworetzky W, Wilkins-Haug L, Jennings RW, et al. Balloon dilation of severe aortic stenosis in the fetus: potential for pre-vention of hypoplastic left heart syndrome: candidate selection, technique, and results of successful intervention. Circulation. 2004;110(15):2125-2131. 35. van Son JM, Danielson GK, Puga FJ, et al. Supravalvular aor-tic stenosis: long-term results of surgical treatment. J Thorac Cardiovasc Surg. 1994;107(1):103-114. 36. Sharma BK, Fujiwara H, Hallman GL, et al. Supravalvular aortic stenosis: a 29-year review of surgical experience. Ann Thorac Surg. 1991;51:1031-1039. 37. McElhinney DB, Petrossian E, Tworetzky W, Silverman NH, Hanley FL. Issues and outcomes in the management of supravalvular aortic stenosis. Ann Thorac Surg. 2000;69(2): 562-567. 38. Clyman RI, Mauray F, Roman C, Rudolph AM, Heymann MA. Circulating PGE2 concentration and patent ductus arteriosus in fetal and neonatal lambs. J Pediatr. 1982;97(3):455-463. 39. McMurphy DM, Heymann MA, Rudolph AM, Melmon KL. Developmental change in constriction of the ductus arteriosus: response to oxygen and vasoactive substances in the isolated duc-tus arteriosus of the fetal lamb. Pediatr Res. 1972;6(4):231-238. 40. Mitchell SC, Korones SB, Berendes HW. Congenital heart disease in 56,109 births. Incidence and natural history. Circu-lation. 1971;43(3):323-332. 40. Campbell M. Natural history of persistent ductus arteriosus. Br Heart J. 1968;30(1):4-13. 41. Itabashi K, Ohno T, Nishida H. Indomethacin responsive-ness of patent ductus arteriosus and renal abnormalities in preterm infants treated with indomethacin. J Pediatr. 2003;143(2):203-207. 42. Rashkind WJ, Cuaso CC. Transcatheter closure of patent duc-tus arteriosus. Pediatr Cardiol. 1979;1(1):3-7. 43. Moore JW, Schneider DJ, Dimeglio D. The duct-occlud device: design, clinical results, and future directions. J Interv Cardiol. 2001;14(2):231-237. 44. Zahn EM, Peck D, Phillips A, et al. Transcatheter closure of patent ductus arteriosus in extremely premature newborns: early results and midterm follow-up. JACC Cardiovasc Interv. 2016;9(23):2429-2437. This article shows that percutaneous closure of PDAs even in extremely small babies is possible. 45. Moore P, Egito E, Mowrey H, Perry SB, Lock JE, Keane JF. Midterm results of balloon dilation of congenital aor-tic stenosis: predictors of success. J Am Coll Cardiol. 1996;27(5):1257-1263. 46. Mavroudis C, Backer CL, Gevitz M. Forty-six years of pat-ent ductus arteriosus division at Children’s Memorial Hospital of Chicago. Standards for comparison. Ann Thorac Surg. 1994;220(3):402-409. 47. Elzenga NJ, Gittenberger-de Groot AC, Oppenheimer-Dekker A. Coarctation and other obstructive arch anoma-lies: their relationship to the ductus arteriosus. Int J Cardiol. 1986;13(3):289-308. 48. Locher JP, Kron IL. Coarctation of the aorta. In: Mavroudis C, Backer CL, eds. Pediatric Cardiac Surgery. St. Louis: Mosby; 1994:167. 49. Presbitero P, Demaie D, Villani M, et al. Long-term results (15–30 years) of surgical repair of coarctation. Br Heart J. 1987;57(5):462-467. 50. Cohen M, Fuster V, Steele PM, Driscoll D, McGoon DC. Coarctation of the aorta: long-term follow-up and predic-tion of outcome after surgical correction. Circulation. 1989;80(4):840-845. 51. Hornung TS, Benson LN, McLaughlin PR. Interventions for aortic coarctation. Cardiol Rev. 2002;10(3):139-148. 52. Waldhausen JA, Nahrwold DL. Repair of coarctation of the aorta with a subclavian flap. J Thorac Cardiovasc Surg. 1966;51(4):532-533. 53. Karamlou T, Bernasconi A, Jaeggi E, et al. Factors associated with arch reintervention and growth of the aortic arch after coarctation repair in neonates weighing less than 2.5 kg. J Thorac Cardiovasc Surg. 2009;137:1163-1167. 54. van Heum LW, Wong CM, Speigelhalter DJ, et al. Surgi-cal treatment of aortic coarctation in infants younger than 3 months: 1985-1990. Success of extended end-to-end arch aor-toplasty. J Thorac Cardiovasc Surg. 1994;107:74-85. 55. Knyshov GV, Sitar LL, Glagola MD, Atamanyuk MY. Aortic aneurysms at the site of the repair of coarctation of the aorta: a review of 48 patients. Ann Thorac Surg. 1996;61(3):935-939. 56. Bouchart F, Dubar A, Tabley A, et al. Coarctation of the aorta in adults: surgical results and long-term follow-up. Ann Thorac Surg. 2000;70(5):1483-1489. 57. Bhat MA, Neelakhandran KS, Unnikriahnan M, Rathore RS, Mohan Singh MP, Lone GN. Fate of hypertension after repair of coarctation of the aorta in adults. Br J Surg. 2001;88(4):536-538. 58. Acher C, Wynn M. Paraplegia after thoracoabdominal aortic surgery: not just assisted circulation, hypothermic arrest, clamp and sew, or TEVAR. Ann Cardiothorac Surg. 2012;1(3):365-372. 59. McCrindle BW, Jones TK, Morrow WR, et al. Acute results of balloon angioplasty of native coarctation versus recurrent aor-tic obstruction are equivalent. Valvuloplasty and Angioplasty of Congenital Anomalies (VACA) Registry Investigators. J Am Coll Cardiol. 1996;28(7):1810-1817. 60. Egbe A, Uppu S, Lee S, Ho D, Srivastava S. Changing preva-lence of severe congenital heart disease: a population-based study. Pediatr Cardiol. 2014;35(7):1232-1238. 61. Collett RW, Edwards JE. Persistent truncus arteriosus: a clas-sification according to anatomic subtypes. Surg Clin North Am. 1949;29(4):1245-1270. 62. Van Praagh R, Van Praagh S. The anatomy of common aor-ticopulmonary trunk (truncus arteriosus communis) and its embryologic implications: a study of 57 necroscopy cases. Am J Cardiol. 1965;16(3):406-425. 63. De la Cruz MV, Pio da Rocha J. An ontogenic theory for the explanation of congenital malformations involving the truncus and conus. Am Heart J. 1976;51(5):782-805. 64. Manner J. Cardiac looping in the chick embryo: a morpho-logic review with special reference to terminological and biomechanical aspects of the looping process. Anat Rec. 2000;259(3):242-262. 65. Hutson MR, Kirby ML. Neural crest and cardiovascular development: a 20-year perspective. Birth Defects Res Part C Embryo Today. 2003;69(1):2-13. 66. Ziolkowska L, Kawalec W, Turska-Kmiec A, et al. Chromo-some 22q11.2 microdeletion in children with conotruncal heart defects: frequency, associated cardiovascular anoma-lies, and outcome following cardiac surgery. Eur J Pediatr. 2008;167(10):1135-1140. 67. Anderson KR, McGoon DC, Lie JT. Surgical significance of the coronary arterial anatomy in truncus arteriosus communis. Am J Cardiol. 1978;41(1):76-81. 68. Chiu IS, Wu SJ, Chen MR, Chen SJ, Wang JK. Anatomic rela-tionship of the coronary orifice and truncal valve in truncus arteriosus and their surgical implication. J Thorac Cardiovasc Surg. 2002;123(2):350-352. 69. Armer RM, De Oliveira PF, Lurie PR. True truncus arteriosus. Review of 17 cases and report of surgery in 7 patients. Circu-lation. 1961;24:878-890. 70. McGoon DC, Rastelli GC, Ongley PA. An operation for the correction of truncus arteriosus. JAMA. 1968;205(2): 69-73. 71. Ebert PA. Truncus arteriosus. In: Glenn WWL, Baue AE, Geha AS, eds. Thoracic and Cardiovascular Surgery. 4th ed. Norwalk: Appleton-Century-Crofts; 1983:731.Brunicardi_Ch20_p0751-p0800.indd 79622/02/19 2:57 PM 797CONGENITAL HEART DISEASECHAPTER 20 72. Forbess JM, Shah AS, St Louis JD, Jaggers JJ, Ungerleider RM. Cryopreserved homografts in the pulmonary position: determinants of durability. Ann Thorac Surg. 2001;71:54-59. 73. Aupecle B, Serraf A, Belli E, et al. Intermediate follow-up of a composite stentless porcine valved conduit of bovine pericardium in the pulmonary circulation. Ann Thorac Surg. 2002;74(1):127-132. 74. Correa-Villaseñor A, Ferencz C, Boughman JA, Neill CA. Total anomalous pulmonary venous return: familial and envi-ronmental factors. The Baltimore-Washington Infant Study Group. Teratology. 1991;44(4):415-428. 75. Darling RC, Rothney WB, Craij JM. Total pulmonary venous drainage into the right side of the heart. Lab Invest. 1957;6(1):44-64. 76. Delisle G, Ando M, Calder AL, et al. Total anomalous pul-monary venous connection: report of 93 autopsied cases with emphasis on diagnostic and surgical considerations. Am Heart J. 1976;91(1):99-122. 77. Michielon G, Di Donato RM, Pasquini L, et al. Total anoma-lous pulmonary venous connection: long-term appraisal with evolving technical solutions. Eur J Cardiothorac Surg. 2002;22(2):184-191. 78. Jonas RA, Smolinsky A, Mayer JE, Castaneda AR. Obstructed pulmonary venous drainage with total anomalous pulmo-nary venous connection to the coronary sinus. Am J Cardiol. 1987;59(5):431-435. 79. Austin EH. Disorders of pulmonary venous return. In: Sabis-ton DC, Lyerly HK, eds. Textbook of Surgery: The Biologi-cal Basis of Modern Surgical Practice. 15th ed. Philadelphia: W.B. Saunders; 1997:2001. 80. Lacour-Gayet F, Rey C, Planche C. Pulmonary vein steno-sis. Description of a sutureless surgical procedure using the pericardium in situ (in French). Arch Mal Coeur Vaiss. 1996;89(5):633-636. 81. Najm HK, Caldarone CA, Smallhorn J, Coles JG. A suture-less technique for the relief of pulmonary vein stenosis with the use of in situ pericardium. J Thorac Cardiovasc Surg. 1998;115(2):468-470. 82. Hyde JAJ, Stumper O, Barth MJ, et al. Total anomalous pul-monary venous connection: outcome of surgical correction and management of recurrent venous obstruction. Eur J Car-diothorac Surg. 1999;15(6):735-740. 83. Korbmacher B, Buttgen S, Schulte HD, et al. Long-term results after repair of total anomalous pulmonary venous con-nection. Thorac Cardiovasc Surg. 2001;49(2):101-106. 84. Bando K, Turrentine MW, Ensing GJ, et al. Surgical man-agement of total anomalous pulmonary venous connection. Thirty-year trends. Circulation. 1996;95(9 suppl):II12-II26. 85. Karamlou T, Gurofsky R, Al Sukhni E, et al. Factors associated with mortality and reoperation in 377 children with total anomalous pulmonary venous connection. Circulation. 2007;115(12):1591-1598. This article describes the era-specific changes in the incidence of mortality and reoperation in children with total anomalous pulmonary venous connection and describes the unfavorable anatomic characteristics that determine postrepair survival. 86. Salomone G, Tiraboschi R, Bianchi T, Ferri F, Crippa M, Parenzan L. Cor triatriatum: clinical presentation and operative results. J Thorac Cardiovasc Surg. 1991;101(6):1088-1092. 87. Huang TC, Lee CL, Lin CC, Tseng CJ, Hsieh KS. Use of an Inoue balloon dilatation method for treatment of cor triatriatum stenosis in a child. Catheter Cardiovasc Interv. 2002;57(2):252-256. 88. Cooley DA, McNamara DG, Latson JR. Aorticopulmonary septal defect: diagnosis and surgical treatment. Surgery. 1957;42(1):101-120. 89. Scalia D, Russo P, Anderson RH, et al. The surgical anatomy of hearts with no direct communication between the right atrium and the ventricular mass—so-called tricuspid atresia. J Thorac Cardiovasc Surg. 1984;87(5):743-755. 90. Cheung HC, Lincoln C, Anderson RH, et al. Options for surgical repair in hearts with univentricular atrioventricular connection and subaortic stenosis. J Thorac Cardiovasc Surg. 1990;100(5):672-681. 91. Gross RE. Surgical relief for tracheal obstruction from a vas-cular ring. N Engl J Med. 1945;233:586-590. 92. Sade RM, Rosenthal A, Fellows K, Castaneda AR. Pulmonary artery sling. J Thorac Cardiovasc Surg. 1975;69(3):333-346. 93. Clarke NS, Murthy R, Hernandez J, Megison S, Guleserian KJ. Aortoesophageal fistula in a child with undiagnosed vascular ring: life-threatening or lethal? Ann Thorac Surg. 2016;102(4):e325-e327. 94. Laborde F, Noirhomme P, Karam J, Batisse A, Bourel P, Saint Maurice O. A new video-assisted thoracoscopic surgi-cal technique for interruption of patient ductus arteriosus in infants and children. J Thorac Cardiovasc Surg. 1993;105(2): 278-280. 95. Burke RP, Wernovsky G, van der Velde M, Hansen D, Castaneda AR. Video-assisted thoracoscopic surgery for congenital heart disease. J Thorac Cardiovasc Surg. 1995;109(3):499-507; discussion 508. 96. Kogon BE, Forbess JM, Wulkan ML, Kirshbom PM, Kanter KR. Video-assisted thoracoscopic surgery: is it a superior technique for the division of vascular rings in children? Congenit Heart Dis. 2007;2(2):130-133. 97. Berlin Heart. EXCOR pediatric update. Available at: http://www.berlinheart.de/UserFiles/ClinicalUpdateEXCORPedi-atricMai2016.pdf. Accessed May 19, 2018. 98. Trusler GA, Williams WG. Long-term results of shunt procedures for tricuspid atresia. Ann Thorac Surg. 1980; 29(4):312-316. 99. Dick M, Gyler DC, Nadas AS. Tricuspid atresia: clinical course in 101 patients. Am J Cardiol. 1975;36(3):327-337. 100. Glenn WWL, Patino JF. Circulatory by-pass of the right heart. Preliminary observations on the direct delivery of vena caval blood into the pulmonary arterial circulation. Azygous vein-pulmonary artery shunt. Yale J Biol Med. 1954;27(3): 147-151. 101. Fontan F, Baudet E. Surgical repair of tricuspid atresia. Thorax. 1971;26(3):240-248. 102. deLeval MR, Kilner P, Gerwillig M, Bull C. Total cavopulmo-nary connection: a logical alternative to atriopulmonary con-nection for complex Fontan operations. J Thorac Cardiovasc Surg. 1988;96(5):682-695. 103. Laks H, Haas GS, Pearl JM, et al. The use of an adjust-able interatrial communication in patients undergoing the Fontan and definitive heart procedures. Ann Thorac Surg. 1991;52(5):1084-1094. 105. Haas GS, Hess H, Black M, Onnasch J, Mohr FW, van Son JA. Extracardiac conduit Fontan procedure: early and intermedi-ate results. Eur J Cardiothorac Surg. 2000;17(6):648-654. 106. Tokunaga S, Kado H, Imoto Y, et al. Total cavopulmonary connection with an extracardiac conduit: experience with 100 patients. Ann Thorac Surg. 2002;73(1):76-80. 107. Karamlou T, Ashburn DA, Caldarone CA, Blackstone EH. Matching procedure to morphology improves outcome in neonates with tricuspid atresia. J Thorac Cardiovasc Surg. 2005;130:1503-1510. 108. Bardo DME, Frankel DG, Applegate KE, Murphy DJ, Saneto RP. Hypoplastic left heart syndrome. Radiographics. 2001;21(3): 706-717. 109. Norwood WI Jr. Hypoplastic left heart syndrome. Ann Thorac Surg. 1991;52(3):688-695. 110. Bronshtein M, Zimmer EZ. Early sonographic diagnosis of fetal small left heart ventricle with a normal proximal outlet tract: a medical dilemma. Prenat Diagn. 1997;17(3):249-253.Brunicardi_Ch20_p0751-p0800.indd 79722/02/19 2:57 PM 798SPECIFIC CONSIDERATIONSPART II 111. Norwood WI, Lang P, Hansen DD. Physiologic repair of aor-tic atresia-hypoplastic left heart syndrome. N Engl J Med. 1983;308(1):23-26. 112. Tweddell JS, Hoffman GM, Ghanayem NS, et al. Ventilatory control of pulmonary vascular resistance is not necessary to achieve a balanced circulation in the postoperative Norwood patient. Circulation. 1999;100(18 suppl):I-671. 113. Sano S, Ishino K, Kawada M. Right ventricle-pulmonary artery shunt in first-stage palliation of hypoplastic left heart syndrome. J Thorac Cardiovasc Surg. 2003;126(2):504-509; discussion 1609-1610. 114. Tchervenkov CI. Two-ventricle repair for hypoplastic left heart syndrome. Semin Thorac Cardiovasc Surg Pediatr Card Surg Annu. 2001;4:83-93. 115. Ohye RG, Sleeper la, Mahony L, et al. Comparison of shunt types in the Norwood procedure for single ventricle lesions. N Engl J Med. 2010;362:1980-1992. 116. Newburger JW, Sleeper LA, Frommelt PC, et al; Pediatric Heart Network Investigators. Transplantation-free sur-vival and interventions at 3 years in the single ventricle reconstruction trial. Circulation. 2014;129:2013-2020. This article discusses the long-term outcomes of the Norwood procedure for patients with the Sano or BT shunt. This is a landmark article in the field. 117. Pasquali SK, Ohye RG, Lu M, et al; Pediatric Heart Network Investigators. Variation in perioperative care across centers for infants undergoing the Norwood procedure. J Thorac Cardio-vasc Surg. 2012;144:915-144. 118. Ohye RG, Schranz D, D’Udekem Y. Current therapy for hypo-plastic left heart syndrome and related single ventricle lesions. Circulation. 2016 Oct;134(17):1265-1279. 119. Murthy R, Sebastian VA, Huang R, Guleserian KJ, Forbess JM. Selective use of the Blalock–Taussig shunt and right ventricle-to-pulmonary artery conduit dur-ing the Norwood procedure. World J Pediatr Congenit Heart Surg. 2016;7(3):329-333. This article elucidates the extensive debate that determines the source of pulmonary blood flow after the Norwood operation. The selective use of mBTS can be beneficial. 120. Wilder TJ, McCrindle BW, Phillips AB, et al. Survival and right ventricular performance for matched children after stage-1 Norwood: modified Blalock–Taussig shunt versus right-ventricle-to-pulmonary-artery conduit. J Thorac Cardio-vasc Surg. 2015;150(6):1440-1450; discussion 1450-1452. 121. Akintuerk H, Michel-Behnke I, Valeske K, et al. Stenting of the arterial duct and banding of the pulmonary arteries: basis for combined Norwood Stage I and II repair in hypoplastic left heart. Circulation. 2002;105:1099-1103. 122. Caldarone CA, Benson L, Holtby H, Li J, Redington AN, VanArsdell GS. Initial experience with hybrid palliation for neonates with single ventricle physiology. Ann Thorac Surg. 2007;84:1294-1300. 123. Baba K, Honjo O, Chaturvedi R, et al. “Reverse Blalock–Taussig shunt”: application in single ventricle hybrid pallia-tion. J Thorac Cardiovasc Surg. 2013;146(2):352-357. 124. Guleserian KJ, Barker GM, Sharma MS, et al. Bilateral pul-monary artery banding for resuscitation in high-risk, single-ventricle neonates and infants: a single-center experience. J Thorac Cardiovasc Surg. 2013;145(1):206-213; discussion 213-214. 125. Myers PO, Baird CW, Del Nido PJ, et al. Neonatal mitral valve repair in biventricular repair, single ventricle palliation, and secondary left ventricular recruitment: indications, tech-niques, and mid-term outcomes. Front Surg. 2015;2:59. 126. Bailey LL, Gundry SR, Razzouk AJ, et al. Bless the babies: 115 late survivors of heart transplantation during the first year of life. The Loma Linda University Pediatric Heart Transplant Group. J Thorac Cardiovas Surg. 1993;105:805-814. 127. Gaynor JW, Mahle WT, Cohen MI, et al. Risk factors for mor-tality after the Norwood procedure. Eur J Cardiothorac Surg. 2002;22:82-89. 128. Bove EL. Ebstein’s anomaly in the neonate. Rev Port Cardiol. 2001;20(9):865-873. 129. Celermajer DS, Cullen S, Sullivan ID, et al. Outcome in neonates with Ebstein’s anomaly. J Am Coll Cardiol. 1992;19:1041-1046. 130. Starnes VA, Pitlick PT, Bernstein D, Griffin ML, Choy M, Shumway NE. Ebstein’s anomaly appearing in the neonate. J Thorac Cardiovasc Surg. 1991;101(6):1082-1087. 131. Danielson GK, Driscoll DJ, Mair DD, Warnes CA, Oliver WC Jr. Operative treatment of Ebstein’s anomaly. J Thorac Cardiovasc Surg. 1992;104:1195-1202. 132. Knott-Craig CJ, Overholt ED, Ward KE, Razook JD. Neo-natal repair of Ebstein’s anomaly: indications, surgical technique, and medium-term follow-up. Ann Thorac Surg. 2000;69(5):1505-1510. 133. Yetman AT, Freedom RM, McCrindle BW. Outcome in cyanotic neonates with Ebstein’s anomaly. Am J Cardiol. 1998;81(6):749-754. 134. Billingsly AM, Laks H, Boyce SW, George B, Santulli T, Williams RG. Definitive repair in patients with pulmonary atresia and intact ventricular septum. J Thorac Cardiovasc Surg. 1989;97(5):746-754. 135. Stellin G, Vida VL, Milanesi O, et al. Surgical treatment of complex cardiac anomalies: the “one and one half ventricle repair.” Eur J Cardiothorac Surg. 2002;22(3):435-437. 136. Chowdhury UK, Airan B, Sharma R, et al. One and a half ventricle repair with pulsatile Glenn: results and guidelines for patient selection. Ann Thorac Surg. 2001;71(6):2000-2002. 137. Knott-Craig CJ, Kumar TK, Arevalo AR, Joshi VM. Surgical management of symptomatic neonates with Ebstein’s anomaly: choice of operation. Cardiol Young. 2015;25(6):1119-1123. 138. Van Praagh R, Van Praagh S, Vlad P, Keith JC. Anatomic sub-types of congenital dextrocardia: diagnostic and embryologic implications. Am J Cardiol. 1964;13:510-531. 139. Van Praagh R, Van Praagh S. Isolated ventricular inversion: a consideration of the morphogenesis, definition, and diagnosis of nontransposed and transposed great arteries. Am J Cardiol. 1966;17:395-406. 140. Blalock A, Hanlon CR. The surgical treatment of complete transposition of the aorta and the pulmonary artery. Surg Gynecol Obstet. 1950;90(1):1-15. 141. Senning A. Surgical correction of transposition of the great vessel. Surgery. 1959;45(6):966-980. 142. Mustard WT, Chute AL, Keith JD, Sirek A, Rowe RD, Vlad P. A surgical approach to transposition of the great vessels with extracorporeal circuit. Surgery. 1954;36:31-59. 143. Jatene AD, Fontes VF, Paulista PP, et al. Successful anatomic correction of transposition of the great vessels: a preliminary report. Arq Bras Cardiol. 1975;28(4):461-464. 144. Rastelli GC. A new approach to the “anatomic” repair of transposition of the great arteries. Mayo Clin Proc. 1969; 44(1):1-12. 145. Culbert EL, Ashburn DA, Cullen-Dean G, et al. Quality of life after repair of transposition of the great arteries. Circulation. 2003;108:857-862. 146. Dearani JA, Danielson GK, Puga FJ, Mair DD, Schleck CD. Late results of the Rastelli operation for transposition of the great arteries. Semin Thorac Cardiovasc Surg Pediatr Card Surg Annu. 2001;4:3-15. 147. Freedom RM, Yoo SJ. Double-outlet right ventricle: pathol-ogy and angiocardiography. Semin Thorac Cardiovasc Surg Pediatr Card Surg Annu. 2000;3:3-19. 148. Lev M, Bharati S, Meng CCL, et al. A concept of double outlet right ventricle. J Thorac Cardiovasc Surg. 1972; 64(2):271-281.Brunicardi_Ch20_p0751-p0800.indd 79822/02/19 2:57 PM 799CONGENITAL HEART DISEASECHAPTER 20 149. Taussig HB, Bing RJ. Complete transposition of the aorta and a levoposition of the pulmonary artery. Am Heart J. 1949;37(4):551-559. 150. Bradley TJ, Karamlou T, Kulik A, et al. Determinants of repair type, reintervention, and mortality in 393 children with double-outlet right ventricle. J Thorac Cardiovasc Surg. 2007;134(4):967-973.e6. 151. Belli E, Serraf A, Lacour-Gayet F, et al. Double-outlet right ventricle with non-committed ventricular septal defect. Eur J Cardiothorac Surg. 1999;15(6):747-752. 152. Kawashima Y, Matsuda H, Yagihara T, et al. Intraventricular repair for Taussig–Bing anomaly. J Thorac Cardiovasc Surg. 1993;105:591-596. 153. Rastelli GC, McGoon DC, Wallace RB. Anatomic correction of transposition of the great arteries with ventricular septal defect and subpulmonic stenosis. J Thorac Cardiovasc Surg. 1969;58(4):545-552. 154. Yasui H, Kado H, Nakano E, et al. Primary repair of inter-rupted aortic arch with severe stenosis in neonates. J Thorac Cardiovasc Surg. 1987;93:539-545. 155. Brown JW, Ruzmetov M, Okada Y, Vijay P, Turrentine MW. Surgical results in patients with double outlet right ventricle: a 20-year experience. Ann Thorac Surg. 2001;72(5):1630-1635. 156. Fallot A. Contribution a l’anatomie pathologique de la mal-adie bleue (cyanose cardiaque) (French). Marseille Med. 1888;25:77-403. 157. Van Praagh R, Van Praagh S, Nebesar RA, et al. Tetralogy of Fallot: underdevelopment of the pulmonary infundibulum and its sequelae. Am J Cardiol. 1970;26:25-53. 158. Need LR, Powell AJ, del Nido P, Geva T. Coronary echocar-diography in tetralogy of Fallot: diagnostic accuracy, resource utilization, and surgical implications over 13 years. J Am Coll Cardiol. 2000;36(4):1371-1377. 159. Mahle WT, McBride MG, Paridon SM. Exercise performance in tetralogy of Fallot: the impact of primary complete repair in infancy. Pediatr Cardiol. 2002;23(2):224-229. 160. Deanfield JE. Adult congenital heart disease with special refernce to the data on long-term follow-up of patients sur-viving to adulthood with or without surgical correction. Eur Heart J. 1992;13(suppl H):111-116. 161. Alexiou C, Chen Q, Galogavrou M, et al. Repair of tetral-ogy of Fallot in infancy with a transventricular or a transatrial approach. Eur J Cardiothorac Surg. 2002;22(2):174-183. 162. Al Habib HF, Jacobs JP, Mavroudis C, et al. Contemporary patterns of management of tetralogy of Fallot: data from the Society of Thoracic Surgeons database. Ann Thorac Surg. 2010;90(3):813-819; discussion 819-820. 163. Karamlou T, McCrindle BW, Williams WG. Surgery insight: late complications following repair of tetralogy of Fallot and related surgical strategies for management. Nature Cardiovasc Med. 2006;3:611-622. 164. Gatzoulis MA, Till JA, Somerville J, et al. Mechanoelectrical interaction in tetralogy of Fallot. QRS prolongation relates to right ventricular size and predicts malignant ventricular arrhythmias and sudden death. Circulation. 1995;92:231-237. 165. Karamlou T, Silber I, Lao R, et al. Outcomes after late reop-eration in patients with repaired tetralogy of Fallot: the impact of arrhythmia and arrhythmia surgery. Ann Thorac Surg. 2006;81:1786-1793. 166. Geva T. Indications and timing of pulmonary valve replace-ment after tetralogy of Fallot repair. Semin Thorac Cardiovasc Surg Pediatr Card Surg Annu. 2006:11-22. Review. 167. Khanna AD, Hill KD, Pasquali SK, et al. Benchmark out-comes for pulmonary valve replacement using the Soci-ety of Thoracic Surgeons databases. Ann Thorac Surg. 2015;100(1):138-145; discussion 145-6. doi: 10.1016/j.atho-racsur.2015.03.025. With the increasing number of adults with congenital heart disease, this article describes the benchmark outcomes for one of the most commonly per-formed operations in this population. 168. Steinberg ZL, Jones TK, Verrier E, Stout KK, Krieger EV, Karamlou T. Early outcomes in patients undergoing trans-catheter versus surgical pulmonary valve replacement. Heart. 2017 Mar 28. doi: 10.1136/heartjnl-2016-310776. 169. Turner SW, Hornung T, Hunter S. Closure of ventricular septal defects: a study of factors influencing spontaneous and surgi-cal closure. Cardiol Young. 2002;12(4):357-363. 170. Waight DJ, Bacha EA, Khahana M, Cao QL, Heitschmidt M, Hijazi ZM. Catheter therapy of Swiss cheese ventricular septal defects using the Amplatzer muscular VSD occluder. Catheter Cardiovasc Interv. 2002;55(3):360-361. 171. Predescu D, Chaturvedi RR, Friedberg MK, Benson LN, Ozawa A, Lee KJ. Complete heart block associated with device closure of perimembranous ventricular septaldefects. J Thorac Cardiovasc Surg. 2008;136(5):1223-1228. 172. Seddio F, Reddy VM, McElhinney DB, Tworetzky W, Silverman NH, Hanley FL. Multiple ventricular septal defects: how and when should they be repaired? J Thorac Cardiovasc Surg. 1999;117(1):134-139. 173. Tsang VT, Hsia TY, Yates RW, Anderson RH. Surgical repair of supposedly multiple defects within the apical part of the muscular ventricular septum. Ann Thorac Surg. 2002;73(1):58-62. 174. Rastelli G, Kirklin JW, Titus JL. Anatomic observations on complete form of persistent common atrioventricular canal with special reference to atrioventricular valves. Mayo Clin Proc. 1966;41(5):296-308. 175. Ungerleider RM. Atrial septal defects, ostium primum defects, and atrioventricular canals. In: Sabiston DC, Lyerly HK, eds. Textbook of Surgery: The Biologic Basis of Modern Surgical Practice. Philadelphia: W.B. Saunders; 1997:1993. 176. Fortuna RS, Ashburn DA, Carias De Oliveira N, Burkhart HM, Konstantinov IE, Coles JG, Smallhorn JF, Williams WG, Van Arsdell GS. Atrioventricular septal defects: effect of bridging leaflet division on early valve function. Ann Thorac Surg. 2004;77(3):895-902; discussion 902. 177. Kouchoukos NT, Blackstone EH, Doty DB, et al. Coarcta-tion of the aorta and interrupted aortic arch. In: Kouchoukos NT, Blackstone EH, Doty DB, et al, eds. Kirklin/Barrat-Boyes Cardiac Surgery. 3rd ed. Philadelphia: Churchill Livingstone; 2003:1353. 178. Roussin R, Belli E, Lacour-Gayet F, et al. Aortic arch recon-struction with pulmonary autograft patch aortoplasty. J Tho-rac Cardiovasc Surg. 2002;123(3):443-448. 179. Brown JW, Ruzmetov M, Okada Y, Vijay P, Rodefeld MD, Turrentine MW. Outcomes in patients with interrupted aortic arch and associated anomalies: a 20-year experience. Eur J Cardiothorac Surg. 2006;29(5):666-673; discussion 673-674. 180. Extracorporeal Life Support Organization. ECLS registry report. Available at: https://www.elso.org/Registry/Statistics.aspx. Accessed May 19, 2018. 181. Murthy R, Brenes J, Dimas VV, Guleserian KJ. Ringed polytetrafluoroethylene (Gore-Tex) tunneled “chimney” graft for pediatric use of Impella 2.5 axial flow pump. J Thorac Cardiovasc Surg. 2014;147(4):1421-1422. 182. Dimas VV, Murthy R, Guleserian KJ. Utilization of the Impella 2.5 micro-axial pump in children for acute circulatory support. Catheter Cardiovasc Interv. 2014;83(2):261-262. 183. Ferro G, Murthy R, Williams D, Sebastian VA, Forbess JM, Guleserian KJ. Early outcomes with HeartWare HVAD as bridge to transplant in children: a single institution expe-rience. Artif Organs. 2016;40(1):85-89. A contemporary article describing the use of left ventricular assist devices in the pediatric population. 184. Rossano JW, Dipchand AI, Edwards LB, et al; International Society for Heart and Lung Transplantation. The Registry of Brunicardi_Ch20_p0751-p0800.indd 79922/02/19 2:57 PM 800SPECIFIC CONSIDERATIONSPART IIthe International Society for Heart and Lung Transplantation: nineteenth pediatric heart transplantation report, 2016; focus theme: primary diagnostic indications for transplant. J Heart Lung Transplant. 2016;35(10):1185-1195. 185. Organ Procurement and Transplantation Network. National data. Available at: https://optn.transplant.hrsa.gov/data/view-data-reports/national-data/#. Accessed May 18, 2018. 186. Reinhartz O, Maeda K, Reitz BA, et al. Changes in risk pro-file over time in the population of a pediatric heart transplant program. Ann Thorac Surg. 2015;100(3):989-994; discussion 995. 187. Sievers HH, Leyh R, Jahnke A, et al. Bicaval versus atrial anastomoses in cardiac transplantation. Right atrial dimension and tricuspid valve function at rest and during exercise up to thirty-six months after transplantation. J Thorac Cardiovasc Surg. 1994;108(4):780-784. 188. Bailey LL, Nehlsen-Cannarella SL, Concepcion W, Jolley WB. Baboon-to-human cardiac xenotransplantation in a neo-nate. JAMA. 1985;254(23):3321-3329. 189. Murthy R, Bajona P, Bhama JK, Cooper DK. Heart xenotrans-plantation: historical background, experimental progress, and clinical prospects. Ann Thorac Surg. 2016;101(4):1605-1613. 190. O’Brien SM, Clarke DR, Jacobs JP, et al. An empirically based tool for analyzing mortality associated with congenital heart surgery. J Thorac Cardiovasc Surg. 2009;138:1139-1153. 191. https://www.sts.org/congenital-public-reporting-module-search. March 2017. 192. Jacobs JP, Mayer JE Jr, Mavroudis C, et al. The Society of Thoracic Surgeons Congenital Heart Surgery Database: 2017 Update on Outcomes and Quality. Ann Thorac Surg. 2017;103(3):699-709. An important article to understand the STS database, outcomes reporting, and where the future of the filed of public reporting is headed. 193. Bramlet M, Olivieri L, Farooqi K, Ripley B, Coakley M. Impact of three-dimensional printing on the study and treatment of congenital heart disease. Circ Res. 2017;120(6): 904-907. This article describes the new and innovative tech-nology of three-dimensional printing and its impact on the field of pediatric and congenital cardiac surgery. 194. Yoo SJ, Spray T, Austin EH 3rd, Yun TJ, van Arsdell GS. Hands-on surgical training of congenital heart surgery using 3-dimensional print models. J Thorac Cardiovasc Surg. 2017 Feb 9. 195. Seghaye MC. Management of children with congenital heart defect: state of the art and future prospects. Future Cardiol. 2017;13(1):65-79. doi:10.2217/fca-2016-0039. 196. Ryan JR, Moe TG, Richardson R, Frakes DH, Nigro JJ, Pophal S. A novel approach to neonatal management of tetralogy of Fallot, with pulmonary atresia, and multiple aortopulmonary collaterals. JACC Cardiovasc Imaging. 2015;8(1):103-104. 197. Ferro G, Murthy R, Sebastian VA, Guleserian KJ, Forbess JM. Single-center experience with the Senning Proce-dure in the Current Era. Semin Thorac Cardiovasc Surg. 2016;28(2):514-520. 198. Zuluaga MA, Burgos N, Mendelson AF, Taylor AM, Ourselin S. Voxelwise atlas rating for computer assisted diagnosis: Application to congenital heart diseases of the great arteries. Med Image Anal. 2015;26(1):185-194.Brunicardi_Ch20_p0751-p0800.indd 80022/02/19 2:57 PM
Acquired Heart DiseaseMatthew R. Schill, Ali J. Khiabani, Puja Kachroo, and Ralph J. Damiano Jr 21chapterCardiac Assessment 801Clinical Evaluation / 801History / 801Physical Examination / 803Cardiac Risk Assessment in Noncardiac Surgery Patients / 804Diagnostic Studies / 804Extracorporeal Perfusion 807History / 807Technique / 807Adverse Effects / 808Myocardial Protection / 808Coronary Artery Disease 808History / 808Etiology and Pathogenesis / 809Risk Factors and Prevention / 809Clinical Manifestations / 809Preoperative Evaluation / 809Coronary Artery Bypass Grafting 809Indications / 809Percutaneous Coronary Intervention vs. Coronary Artery Bypass Grafting / 810Summary / 811Operative Techniques and Results / 811New Developments / 814Valvular Heart Disease 814General Principles / 814Surgical Options / 815Mitral Valve Disease 817Mitral Stenosis / 817Mitral Regurgitation / 819Mitral Valve Operative Techniques and Results / 821Aortic Valve Disease 823Aortic Stenosis / 823Aortic Insufficiency / 825Aortic Valve Operative Techniques and Results / 828Tricuspid Valve Disease 829Tricuspid Stenosis and Insufficiency / 829Multivalve Disease / 831Surgical Therapy for  the Failing Heart 831Epidemiology of Heart Failure / 831Etiology and Pathophysiology / 831CABG for Ischemic Cardiomyopathy / 831Secondary Mitral Regurgitation / 832Left Ventricular Aneurysmorrhaphy and Surgical Ventricular Restoration / 833Mechanical Circulatory Support / 835Right Ventricular Assist Devices and Biventricular Assist Devices / 837Total Artificial Heart / 837Surgery For Arrhythmias 837Atrial Fibrillation / 838Surgery for Pericardial Disease 839Acute Pericarditis / 839Relapsing Pericarditis / 840Chronic Constrictive Pericarditis / 840Cardiac Neoplasms 841Overview and General Clinical Features / 841Myxoma / 842Other Benign Cardiac Tumors / 843Malignant Cardiac Tumors / 843Metastatic Cardiac Tumors / 843CARDIAC ASSESSMENTClinical EvaluationAs with any other field in medicine, the history and physical examination form the foundation for the evaluation of a patient with acquired heart disease requiring surgical intervention. Obtaining a complete history identifies comorbid conditions and assists in delineating the operative risks and prognosis after sur-gery. Physical examination reveals factors that may increase the complexity of surgery, such as previous surgery or the presence of peripheral arterial or cerebrovascular disease. These may influence the operative approach, but they also help guide the choice and sequence of diagnostic studies. A complete assess-ment of the patient allows the surgeon to make educated deci-sions regarding the optimal treatment strategy for the patient.HistorySymptoms suggestive of heart disease include: chest discomfort, fatigue, edema, dyspnea, palpitations, and syncope. Adequate definition of these symptoms calls for detailed history-taking, paying particular attention to onset, intensity, radiation, dura-tion, and exacerbating or alleviating factors. The demands on the heart are determined by its loading conditions and the metabolic state of the patient. Cardiac symptoms are commonly accentuated with physical exertion or postural changes.Angina pectoris is the hallmark of coronary artery disease (CAD), but may occur with other cardiac pathologies that result in ischemia from a mismatch between the supply of oxygen by the coronary circulation and the metabolic demand of the myo-cardium. Typically, angina is described as tightness, heaviness, or dull pain, frequently substernal, that lasts for a few minutes. This discomfort may radiate to the left arm, neck, mandible, or epigastrium. Angina is most often provoked by activities that increase metabolic demand on the heart such as exercise, eating, and states of intense emotion, and it is typically alleviated by rest or use of nitroglycerin. It is important to note that a signifi-cant number of patients with myocardial ischemia, particularly diabetics, females, and the elderly, may have “silent” angina or angina equivalents (dyspnea, diaphoresis, nausea, or fatigue). The overlap of these features with those of noncardiac etiologies Brunicardi_Ch21_p0801-p0852.indd 80101/03/19 5:32 PM 802such as costochondritis, biliary colic, gastroesophageal reflux disease, diffuse esophageal spasm, and peptic ulcer disease, to name a few, can sometimes lead to misdiagnosis.Heart failure can occur from either left and/or right heart dysfunction, and respective symptoms arise from congestion of blood flow owing to an inadequate cardiac output. Left heart failure manifests as dyspnea, usually with exertion. Orthopnea, defined as dyspnea while lying flat, suggests worsened pulmo-nary congestion with increased venous return. Ascites, periph-eral edema, and hepatomegaly reflect congestion in the systemic venous circulation and are prominent features of right heart failure. Peripheral edema can occur in right heart failure second-ary to systemic venous congestion or in left heart failure due to salt and fluid retention as a result of impaired renal perfusion. Patients with chronic suboptimal perfusion and oxygenation can also have digital clubbing and cyanosis.It is difficult to implicate cardiac disease based solely on the presence of fatigue, which is a very nonspecific symptom. However, most cardiac pathologies do result in fatigue or exer-cise intolerance to some degree. It is important to differenti-ate fatigue from exertional dyspnea which some patients may describe as “fatigue.”Dyspnea is another common symptom. Although gen-erally a late symptom in patients with valvular heart disease or cardiomyopathy, it may be a relatively early complaint in some patients, particularly those with mitral stenosis. As stated previously, dyspnea is also an anginal equivalent and may sig-nal a myocardial ischemic episode. Many primary pulmonary disorders feature dyspnea as their cardinal symptom and should be evaluated simultaneously as the physiology of the heart and lungs are intimately related and can have dramatic influences on one another.Patients typically describe palpitations as a “skipped beat” or “racing heart.” Depending on the clinical context, such as occasional premature atrial or ventricular beats in otherwise healthy individuals, these may be benign. Clinically significant arrhythmias, however, require thorough investigation. Atrial fibrillation is the most common arrhythmia and can occur alone or with other cardiac pathologies. It results in an irregular, and at times, rapid heartbeat. Concurrent symptoms such as angina, lightheadedness, or syncope are particularly worrisome for life-threatening arrhythmias such as ventricular tachycardia or ventricular fibrillation, particularly in patients with preexisting heart failure.Syncope associated with heart disease results from an abrupt reduction in cerebral perfusion. Many of the potential cardiac etiologies are serious, including sinus node dysfunction, atrioventricular conduction abnormalities, malignant arrhyth-mias, aortic stenosis, and hypertrophic obstructive cardiomy-opathy. Noncardiac causes of syncope includes, but are not limited to, neurologic causes (e.g., transient ischemic attacks [TIAs]), orthostatic hypotension, vasavagal events, and carotid sinus hypersensitivity. Any episode of syncope warrants a thor-ough evaluation and search for the root cause.1,2 In addition to a thorough inquiry regarding the aforementioned symptoms, it is important to obtain details about the patient’s medical and Key Points1 Although advances have been made in percutaneous coro-nary intervention techniques for coronary artery disease, survival is superior with coronary artery bypass grafting in patients with left main disease, multivessel disease, and in diabetic patients.2 Despite the theoretical advantages, the superiority of off-pump coronary artery bypass to conventional coronary artery bypass grafting has not been clearly established, and other factors likely dominate the overall outcome for either technique.3 Although mechanical valves offer enhanced durability over tissue valve prosthesis, they require permanent systemic anticoagulation therapy to mitigate the risk of valve throm-bosis and thromboembolic sequelae and thus are associated with an increased risk of hemorrhagic complications.4 Mitral valve repair is recommended over mitral valve replacement in the majority of patients with severe chronic mitral regurgitation. The decision to proceed with mitral valve repair is based on the skill and experience of the sur-geon in performing the repair and on the pathology of mitral valve disease encountered at the time of operation. Trans-catheter mitral valve therapies are also becoming increas-ingly available as options to offer patients who are deemed high risk for surgical intervention for their mitral valve disease.5 Although open aortic valve replacement has traditionally been the only effective treatment in patients with severe cal-cific aortic stenosis, transcatheter aortic valve replacement is a developing technology that has proven beneficial for the treatment of aortic stenosis in seriously ill patients that had previously been deemed high risk or inoperable. It has also recently been approved for us in patients at moderate risk for surgical aortic valve replacement and is in clinical trials for low-risk patients.6 Mechanical circulatory support with newer generation con-tinuous flow left ventricular assist devices has proven to be durable and effective both as a bridge to transplant and as a means of destination therapy for patients who are not trans-plant candidates.7 Performing a biatrial Cox-Maze lesion set results in freedom from atrial fibrillation in approximately 90% of patients and is superior to both catheter-ablation and more limited lesion sets for patients with persistent atrial fibrillation or enlarged left atria. Surgical ablation of atrial fibrillation is recom-mended for patients referred with concomitant valvular dis-ease and those who have previously failed or are poor candidates for catheter-based approaches.8 The preferred treatment for pericarditis depends on the underlying cause, although the disease typically follows a self-limited course and is best managed medically. Surgical pericardiectomy may have a role in treating relapsing peri-carditis and, more commonly, chronic constrictive pericarditis.9 Myxomas are the most common cardiac tumors, and, while benign, they should be promptly excised after diagnosis due to the risk of embolization, obstructive complications, and arrhythmias.Brunicardi_Ch21_p0801-p0852.indd 80201/03/19 5:32 PM 803ACQUIRED HEART DISEASECHAPTER 21Table 21-1New York Heart Association (NYHA) functional classificationCLASSDESCRIPTIONIPhysical activity not limited by symptoms: fatigue, palpitations, or dyspnea.IIComfortable at rest. Slight limitation of physical activity. Fatigue, palpitations, or dyspnea with ordinary physical activity.IIIComfortable at rest. Marked limitation of physical activity. Fatigue, palpitations, or dyspnea with less than ordinary physical activity.IVInability to carry out any physical activity. Symptoms may be present at rest and increase with activity.Table 21-2Canadian Cardiovascular Society (CCS) angina classificationCLASSDESCRIPTIONIOrdinary physical activity (walking, climbing stairs) does not cause angina. Angina occurs with strenuous, rapid, or prolonged exertion during work or recreation.IISlight limitation of ordinary activity. Angina occurs with climbing stairs rapidly, walking uphill in the wind, under emotional stress, in the cold, or after meals. Walking more than 2 blocks or climbing one flight of stairs causes angina.IIIMarked limitation of ordinary physical activity (climbing a flight of stairs or walking 1 to 2 blocks at a normal pace).IVInability to carry out any physical activity without discomfort. Angina may be present at rest.surgical history, family history, social habits (including alcohol and tobacco use), current medications, focused review of sys-tems, as well as an assessment of the patient’s functional status and frailty. Frailty is often defined as a state of increased vul-nerability to adverse health outcomes. Clinicians can use frailty index calculators to assess a patient’s risk for adverse outcomes following cardiac intervention. Specific attention should also be directed to the patient’s comorbidities which not only sheds light on their general health but also helps delineate expected risks from surgery. A strong family history of coronary artery disease, myocardial infarction, hypertension, or diabetes is of particular importance as they increase the individual’s risk for having an adverse cardiac event.Functional Disability and Angina. With regard to heart failure, functional capacity is strongly correlated with mortality. The New York Heart Association (NYHA) functional class is a widely used classification system in categorizing patients based on their functional status (Table 21-1).3 The NYHA clas-sification has become one basis by which to compare patient populations in many studies. Although less commonly used, the Canadian Cardiovascular Society (CCS) angina classification is also used to incorporate anginal symptoms into the functional assessment for prognostic value (Table 21-2).Physical ExaminationThe physical examination is an invaluable tool in directing further diagnostic studies in the management of a patient with suspected heart disease. The astute clinician may be able to detect subtle signs that may further characterize the underlying pathology.The general appearance of a patient is important in the clinical assessment. A pale, diaphoretic, and obviously uncom-fortable patient is more likely to be in a clinically critical condition than one who is conversing comfortably with an unre-markable demeanor. In addition to basic vital signs, particular attention should be directed to the patient’s mental status as well as the color and temperature of the skin, as these may be reflec-tive of the general adequacy of perfusion. Overall frailty and dementia have also been shown to be predictors of operative and late mortality.4Palpation of the precordium may demonstrate devia-tion in the point of maximal impulse, indicative of ventricular hypertrophy, or parasternal heaves, seen in right ventricular overload. Auscultation should be performed in a quiet envi-ronment as critical murmurs, rubs, or gallops may be subtle. Murmurs are characterized by their location, timing, quality, and radiation. They are typically secondary to valvular or other structural pathology, and new findings require further investi-gation. A rub due to pericardial friction is indicative of pericar-ditis. A third heart sound (S3) is generated by the rapid filling of a stiff ventricle and can be normal in young patients, but when present in older adults, is indicative of diastolic dysfunction and is pathologic. Increased contribution of the atrial pump function to ventricular filling may manifest as a fourth heart sound (S4) and is also suggestive of ventricular dysfunction.Palpation of peripheral pulses is important not only to assess the adequacy of perfusion, but also the burden of coro-nary artery disease often correlates with the degree of peripheral arterial disease. The presence of a carotid bruit may indicate clinically significant stenosis and may alter the course and tim-ing of treatment, especially if symptomatic.Heart failure will frequently have extracardiac manifesta-tions and examination of the other organ systems should not be neglected. For example, auscultation of the lung fields may reveal rales in patients with pulmonary edema. The use of acces-sory muscles of breathing may be present in patients with sig-nificant pleural effusions and volume overload. The presence of jugular venous distention and hepatosplenomegaly may signal right heart failure.Additionally, clinicians should know the manifestation of other cardiac pathologies including endocarditis and rheu-matic heart disease, although less commonly seen. Endocarditis is an inflammation of the endocardium, usually on the heart valves. A cardiac murmur is a common physical exam finding. Relatively uncommon but more specific clinical manifestations for infectious endocarditis are: Janeway lesions, which are nontender erythematous macules on the palms and soles; Osler nodes, which are described as tender subctanous nodules mostly on the pads of the fingers and toes; and Roth spots, which are exudative hemorrhagic lesions of the retina with pale centers.Brunicardi_Ch21_p0801-p0852.indd 80301/03/19 5:32 PM 804SPECIFIC CONSIDERATIONSPART IICardiac Risk Assessment in Noncardiac Surgery PatientsCardiovascular complications occur in approximately 3% of patients undergoing inpatient noncardiac surgery.5 The American College of Cardiology (ACC) and American Heart Association (AHA) have formed a joint task force to publish a consensus statement, with periodic focused updates, on guide-lines and recommendations that were revised in 2017.6 The aim of these guidelines is to incorporate surgery-specific risks and patient characteristics to guide perioperative decision-making in the management of patient with valvular heart disease.Surgical procedures have been categorized based on cardiovascular risk into low risk, moderate risk, and vascu-lar procedures. Vascular procedures, likely due to both the nature of the procedures themselves as well as the associated cardiovascular pathology in many of these patients, carry the highest reported risk of cardiac events at more than 7%.5 Low risk procedures, including endoscopic procedures, superficial operations, cataract surgery, breast surgery, and ambulatory surgeries, have a risk generally less than 1%. Intermediate risk procedures include intraperitoneal and intrathoracic surgery, head and neck surgery, orthopedic procedures, and prostate surgery.5Patient characteristics can be classified by the status of the patient’s cardiac disease, comorbid conditions, and functional capacity. Patients are considered to be at major perioperative clinical risk if they have one or more of the following active car-diac conditions: acute coronary syndrome, decompensated heart failure, significant arrhythmias, or severe valvular heart disease. In these patients, intensive evaluation and treatment prior to sur-gery (unless emergent) is warranted, prior to proceeding with the noncardiac surgery.If the patient does not have any of the previously men-tioned active cardiac conditions, the perioperative risk of major adverse cardiac events (MACE) should be estimated. Both the operation performed and the patient’s risk factors are predictive of MACE, and the ACC/AHA guidelines recommend the use of either the American College of Surgeons’ NSQIP risk calculator or the Revised Cardiac Risk Index for the estimation of patient-specific risk. Patients at low (<1%) risk or patients at elevated risk with functional capacity greater than or equal to 4 metabolic equivalents (METs), should proceed to surgery without further testing. It is reasonable to perform pharmacologic stress testing in patients with poor or unknown functional capacity if this test-ing will impact decision making or perioperative care. Patients with abnormal stress test results should undergo confirmatory test such as coronary angiography, if indicated, before an elec-tive noncardiac surgery. The previous guidelines included inter-mediate and low cardiovascular risk profiles, but this has been replaced by cardiovascular risk factors in the update. These risk factors are: history of ischemic heart disease, history of prior or compensated heart failure, history of cerebrovascular dis-ease, diabetes mellitus, and renal insufficiency. Based on the number of present risk factors and the surgery-specific risk, the guidelines recommend pathways for further evaluation and risk management. The most recent guidelines from ACC/AHA were published in 2014 (Fig. 21-1).7 One important subgroup of patients at elevated risk are those who have recently undergone percutaneous coronary intervention. In these patients, elective noncardiac surgery should be delayed until the risk of stent thrombosis decreases (30 days for bare metal stents and 180 to 365 days for drug-eluting stents), and dual antiplatelet therapy should be continued unless the risk of bleeding exceeds the risk of stent thrombosis.5Diagnostic StudiesElectrocardiogram and Chest X-ray. Electrocardiograms (ECGs) and chest X-rays are noninvasive diagnostic studies that provide invaluable information in the preoperative assess-ment of patients with cardiac pathology. ECGs can be useful in detecting old myocardial infarction, dilation or hypertrophy of the cardiac chambers, arrhythmias, and conduction abnormali-ties. A stress ECG requires a patient to exercise to a target heart rate and is used to help diagnose ischemic pathologies that may not be evident at rest.A plain film of the chest can detect pulmonary pathol-ogy, sequelae of heart failure (e.g., pulmonary edema, cardiac enlargement, pleural effusions), as well as presence of hardware (e.g., prosthetic heart valves, sternal wires, pacemakers, and defibrillators).Echocardiography. Echocardiography utilizes reflected sound waves to image the heart. Transthoracic echocardiography (TTE) is used widely due to its noninvasive nature. It is the pri-mary diagnostic tool used to evaluate structural diseases of the heart, including valvular pathology, septal defects, cardiomyop-athies, and cardiac masses. Although more invasive, transesoph-ageal echocardiography (TEE) can provide more information and better definition of some valvular and structural abnormali-ties. It is particularly useful in identifying left atrial thrombi in patients with atrial fibrillation. Echocardiography is indispens-able in assessing surgical prostheses such as valves, leads, or mechanical circulatory support devices. These examinations can be performed with M-mode imaging (motion along a single line) as well as two-dimensional (2D) and three-dimensional (3D) imaging depending on the information required.Doppler technology has become a standard addition to assess changes in flow patterns across dysfunctional valves. Velocity measurements can be obtained to estimate pres-sure gradients across structures using the continuity equation. A common example would be the estimation of pulmonary arterial systolic pressure calculated from the regurgitant tricuspid jet profile during right ventricular systole.Transthoracic echocardiography requires no sedation and is generally performed with the patient in a slight left lateral decubitus position. Standardized views are obtained with the ultrasound probe placed in the apical, parasternal, subcostal, and suprasternal positions. The apical four-chamber view is a use-ful window for visualizing all four cardiac chambers simultane-ously as well as the tricuspid and mitral valves. Other windows can be obtained to assess specific structures such as the individ-ual valve anatomy or myocardial wall segments. Dobutamine-stress echocardiography is a study similar in idea to the stress ECG that utilizes a pharmacologic agent to assess the patient for ischemia or stress-induced valvular abnormalities.Transesophageal echocardiography, on the other hand, is performed using a special endoscope with an ultrasound probe mounted on its end that is introduced orally into the esophagus under sedation. Posterior structures such as the mitral valve and left atrium are particularly well visualized. TEEs are frequently used intraoperatively during cardiothoracic surgery to assess global cardiac function, integrity of valve repairs and replace-ments, intracavitary thrombus and/or air, and aortic athero-sclerosis or dissections that can have significant influences on operative strategy.Brunicardi_Ch21_p0801-p0852.indd 80401/03/19 5:32 PM 805ACQUIRED HEART DISEASECHAPTER 21Figure 21-1. Stepwise approach to perioperative cardiac assessment for coronary artery disease. (Reproduced with permission from Fleisher LA, Fleischmann KE, Auerbach AD, et al: 2014 ACC/AHA guideline on perioperative cardiovascular evaluation and management of patients undergoing noncardiac surgery: executive summary: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines, Circulation. 2014 Dec 9;130(24):2215-2245.)EmergencyACS†(Step 2)YesYesNoNoModerate or greater(˜4 METs) functionalcapacityPoor OR unknownfunctional capacity(<4 METs):Will further testing impactdecision making ORperioperative care?(Step 6)No orunknownPatient scheduled for surgery withknown or risk factors for CAD*(Step 1)Clinical risk stratiÿcationand proceed to surgeryEvaluate and treataccording to GDMT†Estimated perioperative risk of MACEbased on combined clinical/surgical risk(Step 3)Low risk (<1%)(Step 4)Proceed tosurgeryElevated risk(Step 5)No furthertesting(Class III:NB)Proceed to surgeryaccording to GDMT ORalternate strategies(noninvasive treatment,palliation)(Step 7)No furthertesting(Class lIa)No furthertesting(Class IIb)Pharmacologicstress testing(Class lIa)Coronaryrevascularizationaccording toexisting CPGs(Class I)Proceed tosurgeryYesIfnormalIfabnormalNoExcellent(>10 METs)Moderate/Good(˜4–10 METs)Brunicardi_Ch21_p0801-p0852.indd 80501/03/19 5:32 PM 806SPECIFIC CONSIDERATIONSPART IIThere are some more recent additions to the echocardio-graphic armamentarium that capitalize on the strengths of ultra-sound imaging. Three-dimensional TEE is playing an increasing role in the preoperative and intraoperative evaluation of patients with valvular heart disease and is especially helpful in percuta-neous mitral intervention. Tissue Doppler imaging is based on principles akin to conventional Doppler echocardiography, but attention is directed to the myocardium itself as opposed to the motion of blood to quantify abnormalities in wall motion. Strain imaging with speckle-tracking echocardiography measures the actual deformation of the myocardium by following inhomoge-neities inherent to the myocardium and is a useful measure of myocardial function.Radionuclide Studies. Although ECGs are useful, inexpen-sive, and safe, baseline abnormalities in the ECG may limit its diagnostic capacity. In particular, ventricular rhythms, bundle-branch blocks, left ventricular hypertrophy, drug effects, and baseline ST-segment depressions can make stress ECGs dif-ficult to interpret for the presence of myocardial ischemia. In this setting, myocardial perfusion imaging (MPI) using radionu-clides can be utilized. Thallium 201 (201Tl) was the initial radio-nuclide used for MPI, but due to its long half-life and relatively low photopeak, it has largely been replaced by technetium-99m (sestamibi and tetrofosmin) because of its more favorable char-acteristics. In the past, planar imaging with three separate 2D views of the heart were obtained. Currently, it is more common to have the images acquired by single-photon emission com-puted tomography (SPECT) technology, which detects emit-ted photons from 180° to 360° around the patient. The signals are then processed to reconstruct multiple slices that together provide a 3D image. The distribution of radionuclides depends on perfusion, and therefore areas that show uptake at rest, but not during stress, are concerning for ischemia. The amount of uptake at both rest and stressed states is compared to assess ischemia and viability of the myocardium. Territories that do not show uptake at rest or during stress are likely to be nonvi-able scar. The sensitivity and specificity of exercise SPECT are 87% and 73%, respectively.8,9The image acquisition may also be gated to a simultane-ously obtained ECG to assess global ventricular function. The endocardial and epicardial borders (as delineated by radionu-clide uptake) are detected throughout the cardiac cycle and the ejection fraction, along with end-systolic and end-diastolic vol-umes, can be calculated. This study is also useful in revealing hypokinetic segments of the myocardium.One significant drawback of SPECT imaging is that it shows regional ischemia well, but it does not adequately detect global or “balanced” ischemia that can occur with diffuse CAD. Positron emission tomography (PET) has been used due to its ability to obtain absolute quantitative data on both myocardial perfusion and metabolism. Tracers used in PET scans can be divided into those that assess perfusion (oxygen-15, nitrogen-13, and rubidiuim-82) and those that assess metabolism (carbon-11 and fluorine-18). The specificity of PET in detecting CAD is better than SPECT at 86% due to its superior spatial resolution.10Magnetic Resonance Imaging. Magnetic resonance imaging (MRI) has a wide variety of uses in cardiac imaging depending on the pulse sequence and signal weighting. Cine-loop imaging of the heart throughout the cardiac cycle can yield information on global chamber function, geometry, and valvular pathologies. The differential response of normal and ischemic myocardium to certain pulse sequences allows imaging of myocardial per-fusion using MRI. Use of contrast agents such as gadolinium can enhance scar tissue and are very useful in viability assess-ment. Myocardial strain imaging can also be performed taking advantage of radio-frequency tagging of the myocardium, which deforms with the tissue and can be followed throughout the car-diac cycle.Cardiac Catheterization. Cardiac catheterization involves access to the cardiac chambers, coronary arteries, and great vessels with a peripherally inserted catheter under fluoroscopic guidance. It is a versatile tool used to investigate cardiac cham-ber pressures, valvular abnormalities, wall motion, and coronary artery anatomy. While some of these roles are being replaced by less invasive techniques mentioned previously, cardiac cath-eterization continues to be widely performed and is the gold standard for the assessment of coronary artery disease.11Left heart catheterization is performed by percutaneous access of the femoral, or radial, artery. Under fluoroscopic guid-ance, the catheter is threaded into the ascending aorta where a contrast aortogram may be performed. Coronary angiography requires manipulation of this catheter into the coronary ostia where contrast is directly injected. With advancement of the catheter retrograde through the aortic valve, left ventricular pressures can be obtained. This measurement is used to calcu-late direct pressure gradients across the aortic valve, in con-trast to echocardiography that indirectly measures pressure, and can be used to confirm severe aortic stenosis. Again, contrast injection into the left ventricle can be used to estimate ejection fraction and visualize hypokinetic segments of the myocardium. Inappropriate retrograde leakage of contrast may indicate insuf-ficiency of the aortic and/or mitral valves.Coronary angiography provides information on hemody-namically significant stenoses in the coronary circulation as well as an anatomical roadmap for surgeons to plan revascularization (Fig. 21-2A,B). A stenosis is considered to be significant if it narrows the lumen of the artery by 70% (or 50% in the case of left main coronary artery). Borderline lesions or complex lesions may be assessed by fractional flow reserve (FFR) or instant wave-free radio (iFR), which obviates the need of adenosine.12 This has been shown to very helpful in guiding revasculariza-tion strategies in recent clinical trials.13 Additional assessment can also be done using intravascular ultrasound (IVUS) inside the coronary circulation. There is some variability in the coro-nary arterial anatomy with the posterior descending artery being supplied by the right coronary artery in approximately 80% of patients (right dominant) or the left coronary artery in approxi-mately 15% of patients (left dominant). The remaining patients have a codominant circulation where the posterior descending artery is supplied by both the right and left coronaries.Right heart catheterization is performed by the introduc-tion of catheter through a peripheral vein that is advanced into the right side of the heart.14 Right-sided pressures and structures are assessed in a similar fashion as in the left heart. Extension of the catheter into the pulmonary artery allows measurement of pulmonary artery pressures as well as pulmonary capillary wedge pressure (reflecting left ventricular end diastolic pres-sure) with an occlusive balloon. In addition to these measure-ments, cardiac output can be measured using thermodilution or by the Fick method using oxygen saturations of blood sampled from the various locations during the procedure.Brunicardi_Ch21_p0801-p0852.indd 80601/03/19 5:32 PM 807ACQUIRED HEART DISEASECHAPTER 21Figure 21-2. Cardiac catheterization angiography. A. Stenosis of right coronary artery indicated by the arrow. B. Still image of a normal left ventriculogram.ABAn advantage of cardiac catheterization is that it offers an opportunity for interventional therapy of coronary artery disease, arrhythmias, valvular abnormalities, and other struc-tural defects of the heart. Cardiac catheterization is generally safe, but being an invasive procedure, it is associated with rare complications. The overall mortality is 0.11%, and total rate of major complications, including MI, stroke, arrhythmia, vascular injury, contrast reaction including allergic reaction and contrast-induced nephropathy, hemodynamic instability, and cardiac per-foration is usually <2%.15Cardiac Computed Tomography. Multislice computed tomography (CT) imaging can be used to assess the coronary vasculature. The coronary calcium score is an index devel-oped to quantify the degree of coronary atherosclerotic burden by measuring Hounsfield units in a noncontrast cardiac CT. Although this technique is quite sensitive for angiographic stenoses (>50%) it remains fairly nonspecific as calcification often precedes significant luminal narrowing.16 CT coronary angiography using intravenous contrast is also utilized clini-cally to assess coronary pathology and is particularly useful in the emergency room to perform a “triple rule-out” for acute coronary events, pulmonary embolism, and aortic dissection in patients who present with undifferentiated chest pain. LV ejec-tion fraction may be measured by this technique, and, together with the degree of coronary stenosis, it has been shown to have incremental prognostic value for the presence of coronary artery disease and in the prediction of adverse coronary events.17EXTRACORPOREAL PERFUSIONHistoryPrior to the development of extracorporeal perfusion, heart sur-gery was rarely performed and was limited to brief periods of asystole and/or hypothermia. The need for obtaining a bloodless operating field, while maintaining perfusion of heart and other organs, was evident.John Gibbon’s motivation to develop a means for extra-corporeal perfusion came from a desire to safely open the pulmonary artery in a patient who suffered from a pulmonary embolus following a cholecystectomy. After numerous experi-mental iterations, Gibbon’s cardiopulmonary bypass machine was first used clinically in 1953 to repair an atrial septal defect in an 18-year-old woman.18 Although Gibbon is credited for its invention, the development of modern cardiopulmonary bypass (CPB) is a culmination of the work of many investi-gators throughout the world. The early bubble oxygenators have evolved into the currently used membrane oxygenators. The search for an ideal biocompatible material that minimizes the inflammatory cascade initiated by the contact of blood with the circuit components continues to this day.TechniqueThe basic CPB circuit consists of the venous cannulae, a venous reservoir, pump, oxygenator, filter, and the arterial cannula.Anticoagulation is required during CPB, and 300 to 400 units/kg of heparin are given to increase the activated clotting time (ACT) to greater than 450 seconds. Once an ade-quate level of anticoagulation is achieved, arterial cannulation is performed through a purse-string suture or through a side graft sewn onto the native artery. The distal ascending thoracic aorta is the most common site of cannulation. Other routinely utilized sites of cannulation include the femoral artery, the axillary artery, the innominate artery, or the distal aortic arch, and they are altered based on the indicated surgical repair and the pres-ence of native arterial disease. Venous cannulation is performed through purse-string sutures placed on the right atrium either for a single cannula or for two separate cannulae placed into the superior and inferior vena cava, respectively. Alternatively, the venous cannula may be inserted from the femoral vein and advanced into the right atrium and superior vena cava using TEE guidance. This technique is frequently used in minimally invasive cardiac surgery.Effective communication between the surgeon, the anes-thesiologist, and the perfusionist is mandatory for effective Brunicardi_Ch21_p0801-p0852.indd 80701/03/19 5:32 PM 808SPECIFIC CONSIDERATIONSPART IIcardiopulmonary bypass. Once the appropriate cannulations and connections are complete, CPB is commenced. Venous return is initiated followed by arterial flow while monitoring systemic blood pressure. At normothermia, the flow required is approxi-mately 2.4 L/min/m2, but with hypothermia, oxygen consump-tion is reduced by 50% for every 10°C drop in temperature, and a flow of only 1 L/min/m2 is required at 18°C. Once the heart is decompressed and hemodynamics are acceptable, ventilation is stopped. The oxygenator is adjusted to maintain a Pao2 of 150 mmHg and normocarbia. Blood can also be filtered and returned through vents that are placed in chambers of the heart (such as the left ventricle or pulmonary artery) or through the cardiotomy suction used to aspirate blood from the surgical field. When the cardiac procedure is complete, the patient is rewarmed, the lungs ventilated, and the heart defibrillated, if needed. The venous return to the CPB machine is gradually reduced allowing the heart to fill. The pump is also slowed while hemodynamics and global cardiac function are assessed with a TEE probe. Ino-tropic and vasopressor support may be used to augment cardiac function and treat hypotension. Once CPB has been weaned and stable hemodynamics achieved, the cannulae are removed. The heparin anticoagulation is reversed with 1 mg protamine per 100 units of heparin and hemostasis is achieved.19Adverse EffectsCardiopulmonary bypass has a number of deleterious effects as various intertwining processes result in derangements in hemo-stasis, an enhanced systemic inflammatory response, and end-organ function.Anticoagulation prior to the commencement of CPB is required as contact of blood with the artificial surfaces of the cir-cuit can initiate a thrombogenic cascade. Generation of thrombin plays a major role in both thrombotic and bleeding phenomena during CPB. The endothelium that normally regulates the fine balance between procoagulant and anticoagulant pathways is perturbed. Fibrinogen is consumed rapidly as thrombin converts fibrinogen to fibrin while fibrinolytic mechanisms (initiated by the activated endothelium) degrade the fibrin macromolecules. Platelets are activated by the converging hemostatic pathways and are consumed.The response of the humoral and cellular immune systems partly overlap with the hemostatic pathways. The classic and alternative complement pathways are activated by CPB gen-erating powerful chemotaxic molecules and anaphylatoxins.20 Monocytes, platelets, and neutrophils are activated releasing acute inflammatory mediators and cytokines that persist even after conclusion of CPB.21 These inflammatory cells also pro-duce reactive oxidants that may have cytotoxic and cardiovas-cular effects such as vasodilation and hypotension.The large quantity of unfractionated heparin used during cardiac surgery predisposes patients to developing heparin-induced thrombocytopenia (HIT) with an incidence of 1% to 5%.22 Platelet factor-4 (PF4) is produced by platelets and avidly binds to heparin to form a heparin-PF4 complex that can be antigenic in some patients binding IgG. The IgG-heparin-PF4 complex can bind to platelets, which causes release of more PF4, perpetuating the process. The earliest sign is a sudden drop of more than 50% in the platelet count, usually seen from sev-eral hours to days after surgery. HIT can be confirmed with an enzyme-linked immunosorbent assay (ELISA) or serotonin release assay (SRA). Of the patients with HIT, 20% to 50% of patients develop thromboses in arterial or venous beds, designated as heparin-induced thrombocytopenia and thrombo-sis (HITT), which can be life-threatening.23 Treatment is anti-coagulation with nonheparin anticoagulant (e.g., argatroban, bivalirudin).The etiology of end-organ dysfunction resulting from extracorporeal circulation can mostly be categorized into one of three mechanisms: hypoperfusion, embolization, and whole-body inflammatory response. Although cardiac output and blood pressure are monitored carefully during CPB, they are surrogates for regional perfusion and cannot detect end-organ hypoperfusion directly. This can be a problem particularly with the cerebral, renal, and mesenteric circulations. With manip-ulation of diseased vessels and dysregulation of the native coagulation system, macroscopic and microscopic emboli are a concern. Activated cells and circulating cytotoxic products of the immune response may cause microvascular injury and edema of other organs manifesting as neurocognitive deficits, respiratory failure, and renal injury.24Myocardial ProtectionDuring CPB, pharmacologic agents in cardioplegic solutions may be delivered into the coronary circulation to arrest the heart, allowing for a still operating target and improved myocardial protection. The most common cardioplegia consists of potas-sium-rich solutions that can be mixed with autologous blood and are delivered into the coronary circulation.25 Antegrade cardioplegia is delivered into the root of a cross-clamped aorta or directly into the individual coronary ostial using specialized catheters. A retrograde cardioplegia catheter is a balloon-cuffed catheter that is placed through the right atrium into the coro-nary sinus and is used to perfuse the coronary circulation in the opposite direction through the venous circulation. This has the advantage of more uniform distribution in patients with diffuse coronary artery disease and is not dependent on a competent aortic valve for delivery.There is continued debate regarding the best method (ante-grade vs. retrograde vs. both), type (crystalloid vs. blood), tem-perature (cold vs. warm vs. tepid), and interval (continuous vs. intermittent) of cardioplegia delivery. The optimal combination is beyond the scope of this text. However, most cardiac surgeons in the United States favor cold blood potassium cardioplegia.CORONARY ARTERY DISEASEHistoryAortocoronary bypass for myocardial ischemia was first pro-posed and performed in laboratory animals by Carrel in 1910.26 The Vineberg operation, one of the initial attempts at surgical revascularization of the myocardium, was introduced in 1951.27 This procedure involved implantation of the internal thoracic artery directly into the myocardium itself. While some patients were relieved of their anginal symptoms, this resulted in vir-tually no increase in coronary flow and was soon supplanted by methods to restore flow directly. Coronary endarterectomy was introduced by Longmire during this time period but had high rates of restenosis and occlusion.28 The use of vein patches to repair the arteriotomy sites was described by Senning in 1961.29 The first saphenous vein coronary artery bypass grafting (CABG) was performed by Sabiston in 1962,30 but was popular-ized by Favalaro and Sones in 1967.31 In 1968, the internal tho-racic artery was introduced as a bypass conduit by Green, who used it to bypass the left anterior descending coronary artery.32Brunicardi_Ch21_p0801-p0852.indd 80801/03/19 5:32 PM 809ACQUIRED HEART DISEASECHAPTER 21Etiology and PathogenesisAtherosclerotic stenoses are the primary mechanism of CAD. The pathophysiologic process is initiated with vascular endo-thelial injury and is potentiated by inflammatory mechanisms, circulating lipids, toxins, and other vasoactive agents in the blood. Macrophages and platelets are attracted to this area of endothelial dysfunction inciting a local inflammatory response. During this process, macrophages infiltrate into the intimal lay-ers and accumulate cholesterol-containing low-density lipo-proteins. The growth factors secreted promote proliferation of smooth muscle cells within the intima and media of the arteries. Together with the accumulation of the lipid-laden macrophages, the smooth muscle hyperplasia results in an atheroma and subse-quent stenosis of the vessel. These atheromas have a fibrous cap that may rupture, exposing the underlying cells and extracellular matrix, which are very prothrombotic. Acute plaque rupture and thrombus formation is thought to be the main pathophysiologic mechanism responsible for acute coronary syndromes.33-35Risk Factors and PreventionPrior to the establishment of modern management strategies, the annual mortality rate from ischemic heart disease was 482 out of 100,000 persons.36 Since the peak of coronary heart dis-ease mortality in 1968, modern primary and secondary preven-tion strategies such as risk factor modification, percutaneous and surgical revascularization, use of medications (e.g., aspirin, HMG-CoA reductase inhibitors [statins], and β-blockers), has decreased mortality from coronary artery disease by 74%.36The major risk factors for atherosclerosis include advanced age, cigarette smoking, hypertension, dyslipidemias, sedentary lifestyle, obesity, and diabetes. Likely due to increased public awareness and aggressive medical management, these risk fac-tors (with the exception of glucose intolerance and obesity) have recently been on the decline.Current guidelines outlined in the AHA/ACC consensus statement summarize the secondary prevention recommendations.37 Class I recommendations include smoking cessation and avoid-ance of environmental tobacco exposure, blood pressure con-trol to under 140/90 mmHg (under 130/80 mmHg in those with diabetes or chronic kidney disease), LDL cholesterol levels less than 100 mg/dL, aspirin therapy in all patients without contra-indications, a BMI target of less than 25 kg/m2, diabetes man-agement with target HbA1c <7%, and encouragement of daily moderate-intensity aerobic exercise. β-Blockers should be used in all patients with LV dysfunction and following MI, ACS, or revascularization, unless a specific contraindication is pres-ent. Renin-angiogensin-aldosterone system blockade in patients with hypertension, LV dysfunction, diabetes, or chronic kidney disease should also be considered.Clinical ManifestationsPatients with CAD may have a spectrum of presentations, including angina pectoris, myocardial infarction, ischemic heart failure, arrhythmias, and sudden death.Angina pectoris is the pain or discomfort caused by myo-cardial ischemia and is typically substernal and may radiate to the left upper extremity, neck, or epigastrium. The variety of presentations can make myocardial ischemia challenging to diagnose. Characteristics of chest pain that make myocardial ischemia less likely include pleuritic chest pain, pain reproduc-ible by movement or palpation, or brief episodes lasting only seconds. Typical angina is relieved by rest and/or use of sub-lingual nitroglycerin. Differential diagnoses to be considered include, but are not limited to, musculoskeletal pain, pulmonary disorders, esophageal spasm, pericarditis, aortic dissection, gas-troesophageal reflux, neuropathic pain, and anxiety.Myocardial infarction is a serious consequence of CAD occurring when ischemia results in myocardial necrosis. This may be silent and need not be preceded by angina. Necrosis may result in disruption of the myocardial integrity leading to devastating conditions such as intracardiac shunts from ventric-ular septal defects, acute valvular regurgitation from rupture of necrotic papillary muscles, and cardiac aneurysms, which have the potential for fatal rupture.Ischemic insults from CAD may lead to congestive heart failure. The initial myocardial damage sets off a cascade of both local and systemic responses. Over time, these changes can cause deleterious myocardial loading and abnormal neuro-humoral responses that result in pathologic remodeling of the heart. Heart failure should be suspected in patients who present with dyspnea, orthopnea, fatigue, and edema.Arrhythmias may also be sequelae of CAD. Ischemic etiologies should be investigated in patients who present with new arrhythmias. CAD may result in arrhythmias following an acute MI or as the result of ultrastructural and electrophysi-ologic remodeling secondary to chronic ischemic heart disease. Ischemia of the electrical conduction system may be present in the form of new onset complete or partial atrioventricular conduction blocks.Preoperative EvaluationA focused history and physical examination is essential with par-ticular attention directed to the signs, symptoms, and clinical man-ifestations mentioned previously. The patient’s functional status is of importance not only because it is a component of preoperative risk assessment, but also because quality of life improvement and symptomatic relief are both goals of surgical therapy.Coronary angiography is the primary diagnostic tool. The coronary anatomy and degrees of stenoses are delineated allow-ing for planning of surgical revascularization.Noninvasive diagnostic studies, in combination with pro-vocative maneuvers (exercise or pharmacologic agents) offer information regarding the functional significance of ischemic disease. A stress ECG is frequently used as a screening tool with 50% sensitivity and 90% specificity for coronary artery with a threshold of 1 mm of ST-segment depression.38 This test, how-ever, requires patients to achieve a certain elevation in their heart rate and is therefore not suitable for those that cannot achieve this goal. Furthermore, baseline ECG abnormalities may render it impossible to detect typical ischemic changes with stress.Echocardiography and nuclear imaging may be performed under pharmacologic stress (with dobutamine or dipyridamole) to assess reversible ischemia and myocardial viability. Technetium-99m or thallium-201 perfusion scans and stress echocardiogra-phy are more sensitive than stress ECG.39 These studies also have the ability to assess global ventricular function in terms of left ventricle ejection fraction, which can be used to determine operative risk. Please refer to the diagnostic studies section for more details.CORONARY ARTERY BYPASS GRAFTINGIndicationsA joint committee established by the ACC/AHA have pub-lished guidelines for surgical revascularization (CABG) in Brunicardi_Ch21_p0801-p0852.indd 80901/03/19 5:32 PM 810SPECIFIC CONSIDERATIONSPART IITable 21-3Algorithm set forth by ACC/AHA guidelines for preoperative cardiovascular evaluation before noncardiac surgery for patients who are scheduled for nonemergent, non-low risk surgery, no active cardiac disease, and less than 3 METsNUMBER OF RISK FACTORSaRECOMMENDATION0Proceed with planned surgery.1–2Control HR and proceed with planned surgery or pursue further testing if it will change management.3–5Pursue further testing if it will advance management.aRisk factors are history of ischemic heart disease, history of prior or compensated heart failure, history of cerebrovascular disease, diabetes mellitus, and renal insufficiency.Table 21-4Data from ACC/AHA guidelines for CABG in CAD to improve survivalANATOMYCLASS OF RECOMMENDATIONLEVEL OF EVIDENCE• LMIB• 3-vessel +/− proximal LADIB• 2-vessel + proximal LADIB• 2-vessel – proximal LADIIa – with extensive ischemiaIIb – without extensive ischemiaBC• Multivessel disease with DMIIa (CABG preferred over PCI)B• Proximal LAD onlyIIa – with LITA for long-term benefitB• 1-vessel – proximal LADIII – HarmB• LV dysfunctionIIa – LVEF 35%–50%IIb – LVEF <35% without LM diseaseBB• Survivor of ischemia-mediated VTIBDM = Diabetes mellitus; LITA = Left internal thoracic/mammary artery; LM = Left main coronary artery; LV = left ventricle; VT = ventricular tachycardia. Class of recommendation: I – Benefit far outweighs risks and procedure should be performed; IIa – Benefit outweighs risks and procedure is considered to be reasonable; IIb – Potential benefits may exceed risks and procedure may be considered; III – Procedure not helpful and may cause harm. Level of evidence: A – Strong; multiple supporting randomized controlled trials or meta-analyses, B – Limited; data based on a single randomized trial or nonrandomized trials, C – Very limited; based on expert consensus, case studies or standards of care.CAD. The indications, categorized by presentation and angio-graphic disease burden as well as by treatment intention (sur-vival improvement and symptom relief), are summarized later (Tables 21-3, 21-4, and 21-5).40,41Percutaneous Coronary Intervention vs. Coronary Artery Bypass GraftingThere have been multiple prospective, randomized, controlled trials as well as large retrospective studies looking at the com-parative effectiveness of percutaneous coronary interventions (PCI) and CABG. Some of the representative studies are sum-marized here.The New York State Study (2005). A retrospective review of 59,314 patients in a New York state registry with multivessel (two or more) coronary disease was performed. Of these, 37,212 patients received a CABG, and the remainder underwent a PCI. After adjusting by means of proportional-hazards methods, CABG was associated with higher adjusted rates of long-term survival than PCI.42Stent or Surgery Trial (2008). An international multicenter, randomized, controlled trial of 988 patients (n = 488 PCI, n = 500 CABG) with multivessel CAD was performed to compare revascularization strategies. The median follow-up was extended to 6 years, and a survival advantage persisted in the CABG group over the PCI group.43Synergy Between Percutaneous Coronary Intervention With Taxus and Cardiac Surgery (SYNTAX Trial, 2009, updated 2013). Revascularization strategies, CABG vs. PCI, were compared in a 1:1 randomized prospective trial of 1800 patients with high-risk coronary artery disease (left-main or triple-vessel disease). Rates of requirement for repeat revascu-larization and major adverse cardiac or cerebrovascular events (MACCE) at 1 year were lower in the CABG patients (5.9% and 12.4%, respectively) compared to PCI patients (13.5% and 17.8%, respectively). No difference in mortality was seen between the groups at 1 year.44 At 5 years, the estimated rate of MACCE was 26.9% in the CABG group vs. 37.3% in the PCI group. No difference in all-cause mortality was seen. The dif-ference in MACCE between PCI and CABG was confined to patients with intermediate or high SYNTAX scores.45The ACCF and STS Database Collaboration on the Com-parative Effectiveness of Revascularization Strategies (ASCERT Study, 2012). This study, performed by collabo-ration of the American College of Cardiology Foundation and the Society of Thoracic Surgeons, reviewed their respective national databases of patients over the age of 65 who had multi-vessel coronary disease (excluding those with left main disease). CABG was performed on 86,244 patients, and 103,549 under-went PCI. There was no difference in adjusted mortality at 1 year, but there was a significantly lower mortality with CABG than PCI at 4 years.46 Although CABG had higher cost, this was Brunicardi_Ch21_p0801-p0852.indd 81001/03/19 5:32 PM 811ACQUIRED HEART DISEASECHAPTER 21Table 21-5Data from ACC/AHA guidelines for CABG in CAD to improve symptomsANATOMY ASSOCIATED SYMPTOMSCLASS OF RECOMMENDATIONLEVEL OF EVIDENCE• Unacceptable angina with presence of ≥1 stenoses amenable to revascularization despite medical treatmentIA• Complex 3-vessel CAD +/− proximal LAD involvementIIa (CABG preferred over PCI)B• Unacceptable angina with presence of ≥1 stenoses amenable to revascularization but medical treatment is not possibleIIaC• Previous CABG with ≥1 stenoses associated with ischemia and angina despite medical treatmentIIbCmodest with an incremental cost-effectiveness ratio of $30,454 per quality-adjusted life year gained.47Everolimus-Eluting Stents or Bypass Surgery for Left Main Coronary Artery Disease (EXCEL Trial, 2016). This study randomized 1905 patients with left main coronary artery disease of low or intermediate complexity to PCI or CABG. At 3 years, no difference was observed in the primary endpoint of death, stroke, myocardial infarction or ischemia-driven revas-cularization. However, it should be noted that the PCI group exhibited a greater increase in these events between 30 days and three years than the CABG group (11.5% vs. 7.9%).48SummaryPCI technology has improved over time, and rates of periproce-dural adverse events have decreased significantly. Man-agement strategies must be tailored to the individual patient’s clinical status and context, but CABG maintains improved long-term outcome and remains the standard of care for patients with left-main, multivessel coronary artery disease and patients with diabetes. Recent and upcoming trials will con-tinue to clarify which patient populations benefit most from either revascularization strategy.Operative Techniques and ResultsBypass Conduit Selection. The most important criterion in conduit selection is graft patency. The conduit with the highest patency rate (98% at 5 years and 85%–90% at 10 years) is the internal thoracic artery, which is most commonly left attached proximally to the subclavian artery (although occasionally used as a free graft) and anastomosed distally to the target coronary artery.49,50 The use of both internal thoracic arteries has been shown to increase event-free survival in a number of studies.51,52The greater saphenous vein can be harvested using an open or endoscopic technique. In the open technique, the initial inci-sion is made along the course of the vein on the medial aspect of the lower extremity. The vein is harvested with meticulous attention directed towards minimizing manipulation of the vein itself. The incision may be continuous or bridged in an attempt to decrease the size of the incision, but multiple bridged inci-sions may have the potential risk of increased conduit manipula-tion during harvest. Endoscopic harvest is performed by making a small incision just above and medial to the knee where the endoscope is inserted. Side branches are cauterized under endo-scopic visualization using bipolar electrocautery until dissec-tion is carried proximally until the required length of vein is mobilized. A proximal counterincision is then made to extract the venous conduit, which is prepared in the standard fashion.1The radial artery is another frequently used conduit. After confirmation of ulnar collateral flow to the hand by the clinical Allen’s test or a duplex ultrasound study, an incision is made from a point just proximal to the radial styloid process and end-ing just medial and distal to the biceps tendon on the nondomi-nant hand. With lateral retraction of the brachioradialis muscle, the radial artery is dissected sharply with care to avoid injury to the cutaneous nerves in this area and minimize manipulation of the artery itself. This artery can also be harvested using an endoscopic technique.Many studies have looked at the patency rates of the radial artery graft in comparison to the saphenous vein graft. Although some studies have resulted in equivocal data, general consen-sus favors the use of radial arterial grafts over vein grafts with 5-year patency rates of 98% and 86%, respectively.53,54From a historical perspective, the anterior circulation (left anterior descending artery) is generally bypassed using the internal thoracic artery, and the lateral (circumflex artery) or inferior (right coronary artery) territories are bypassed using a saphenous vein or radial artery graft. These conduits may be combined to form a composite Tor Y-graft, or sewn to multiple targets as sequential grafts. Since patency is best with arterial grafts, recent data have suggested that the best long-term results are achieved using a multiple or all-arterial revascularization strategy, particularly in patients >70 years of age and patients with diabetes.55-57 Other conduits such as the gastroepiploic arteries, lesser saphenous veins, and cephalic veins have been described, but these are not widely used and will not be dis-cussed here.Conventional Coronary Artery Bypass Grafting. Tradi-tionally, CABGs are performed with the patient lying supine through a median sternotomy. Left internal thoracic artery and other conduit harvests are performed. After the patient is heparinized, cardiopulmonary bypass is initiated. The aorta is cross-clamped, and cardioplegia is delivered. Once adequate myocardial protection has been achieved, coronary arterioto-mies are made, and distal anastomoses are performed using polypropylene suture (Fig. 21-3A,B). The proximal anastomo-ses are then performed directly onto the ascending aorta or onto preexisting grafts. It is important to note that significant coro-nary stenoses can cause differential distribution of cardioplegia and myocardial protection. It is therefore recommended to use retrograde cardioplegia or to revascularize the area with the most concern for ischemia first and give cardioplegia down the completed graft. The left internal thoracic artery to left anterior descending (LAD) graft is frequently performed last to avoid kinking or disruption of this important conduit. Once all grafts Brunicardi_Ch21_p0801-p0852.indd 81101/03/19 5:32 PM 812SPECIFIC CONSIDERATIONSPART IIFigure 21-3. Coronary artery bypass grafting. A. Intraoperative photograph of the distal anastomoses performed between the left internal thoracic artery and left anterior descending coronary artery with a continuous 8-0 suture. B. Fifteen-year follow-up coronary angiogram of a left internal thoracic artery to left anterior descend-ing coronary artery bypass demonstrating a widely patent free of any significant atherosclerotic stenosis. Anastomotic site is shown by the arrow.Figure 21-4. Epicardial stabilizing device used during off-pump coronary anastomosis.ABare in place, the patient is weaned from bypass. During this time, the heart is monitored closely by direct visual inspection, transesophageal echocardiography. It is recommended that bypass graft patency be assessed with ultrasonic flow probes or Doppler to confirm flow and determine the pulsatility index (PI). These tools are utilized to detect abnormalities that may signify inadequate revascularization or technical problems with the bypass grafts. Upon confirmation of hemostasis, chest tubes are placed, the sternum is approximated with sternal wires, and the incisions are closed.Conventional CABG Results. Several early randomized trials showed improved survival in patients who received a CABG as opposed to medical therapy.58-60 A propensity-matched study identified that CABG greatly benefited patients with LV dysfunction and left main stenosis >50% compared to medi-cal management.61 The Bypass Angioplasty Revascularization Investigation (BARI) trial demonstrated impressively superior results with CABG compared to PCI in terms of 5-year cardiac mortality (5.8% vs. 20.6%) in patients with diabetes in addi-tion to CAD.62 In a study examining the benefits of CABG over medical management for specific CAD distributions, survival was better in patients with proximal LAD stenoses, regardless of the number of diseased vessels.63 In general, these studies show survival rates of over 90% at 5 years and approximately 75% at 10 years following CABG.The mortality and morbidity of the procedure itself has changed over time. Data from the Society of Thoracic Surgeons (STS) database accounts for 1,497,254 patients who under-went solitary CABG from 2000 to 2009. The mortality rate of CABGs has improved significantly from 2.4% in 2000 to 1.9% in 2009, despite the relatively constant predicted mortality rate of around 2.3%. In parallel with this, postoperative complication rates have also decreased: stroke (1.6%–1.2%), bleeding requir-ing reoperation (2.4%–2.2%), and deep sternal wound infection (0.59%–0.37%).64Off-pump Coronary Artery Bypass. To avoid the adverse consequences of cardiopulmonary bypass, off-pump coronary artery bypass (OPCAB) was developed and has been adopted in some centers over the past two decades.With OPCAB, the heart is left beating. Performing anas-tomoses on the beating heart requires the use of myocardial sta-bilization devices, which help portions of the epicardial surface to remain relatively immobile while the anastomoses are being performed (Fig. 21-4).Apical suction devices are used to aid in exposure, particu-larly of the lateral and inferior vessels. Many creative maneu-vers have been developed, including patient repositioning, opening the right pleural space to allow for cardiac displace-ment, and creation of a pericardial cradle to minimize compro-mise of cardiac function while exposing the various surfaces of the heart. Temporary proximal occlusion of the target coronary artery, or the use of an intracoronary shunt, are necessary to Brunicardi_Ch21_p0801-p0852.indd 81201/03/19 5:32 PM 813ACQUIRED HEART DISEASECHAPTER 21provide adequate exposure of the anastomosis. Occlusion causes temporary ischemia, and if not tolerated during a test occlusion, coronary shunts can be employed.OPCAB Results. The superiority of OPCAB over on-pump CABG remains a controversy despite the large body of literature on this topic. A pooled analysis of two random-ized trials, the Beating Heart Against Cardioplegic Arrest Studies (BHACAS 1 & 2), is one of several studies that have touted lower short-term mortality rates with the off-pump com-pared to the on-pump technique.65-67 Other studies, however, have demonstrated equivocal or contrary results.68-70 Further-more, the prospective and much larger ROOBY (Randomized On/Off Bypass) trial showed increased rates of adverse cardiac events with OPCAB compared to conventional CABG.71 Despite the initial enthusiasm for the theoretical advantages of avoiding cardiopulmonary bypass, consistent benefits in clinical outcome have not been observed. There does seem to be a more or less uniform trend towards decreased perioperative blood product transfusions with OPCAB compared to on-pump CABG. In terms of other measures of early outcome, postoperative renal failure, stroke, and acute MI, the superiority of OPCAB has been unclear.69,72,73 A more recent Cochrane review by Moller et al did not demonstrate any significant benefit of off-pump compared with on-pump CABG regarding mortality, stroke, or myocardial infarction. In contrast, better long-term survival in the group of patients undergoing on-pump CABG with the use of cardiopul-monary bypass and cardioplegic arrest was observed.74The higher cardiac morbidity in the ROOBY trial was associated with decreased 1-year angiographic patency rates.71 However, studies with contrasting findings exist, quoting equiv-alent rates of graft patency for OPCAB usage.75,76 The broad variety in results may be suggestive that other factors (e.g., surgeon skill, technical difficulty, patient factors) may be dom-inating the outcome rather than the use or avoidance of cardio-pulmonary bypass.77 After almost two decades, OPCAB has not been widely adopted and remains less than 20% of all CABG procedures in the United States.Minimally Invasive Direct Coronary Artery Bypass. As an extension of the off-pump coronary revascularization technique, minimally invasive direct coronary artery bypass (MIDCAB) has been described. MIDCAB is performed using a left ante-rior mini-thoracotomy through which mobilization of the left internal thoracic and direct in situ anastomosis to the left ante-rior descending artery (or its diagonal branches) is performed. This technique is primarily applicable to single-vessel disease, although reports of multivessel revascularizations do exist.MIDCAB Results. A review of 411 patients undergoing MID-CAB quotes an operative mortality >1%. In this study, all patients received revascularization of the LAD only, regard-less of the number of diseased vessels. The 3-year mortality in patients with single-vessel disease following a MIDCAB was 3.1%, which was, not surprisingly, lower than those with multi-vessel disease (8.7%).78There is an inherent selection bias in retrospective reviews comparing MIDCAB to OPCAB or conventional CABG as MIDCAB patients tend to have less extensive disease. Because of this, there have been multiple randomized controlled trials looking at the efficacy of MIDCAB compared to PCI. A meta-analysis of 12 randomized prospective trials comparing PCI to MIDCAB revascularization of isolated proximal left anterior descending artery demonstrated comparable results in terms of 2mortality and MI but a lower revascularization requirement in the MIDCAB group.79A recent meta-analysis by Lee et al revealed CABG, as compared with PCI with DES, reduced long-term rates of the composite of all-cause death, myocardial infarction, or stroke in patients with left main or multivessel CAD. Compared to PCI with DES, CABG was found to be superior in patients with multivessel CAD (P = 0.001), but no between-group differences in those with left main CAD (P = 0.427).80 Similar conclusions have been made by multiple other studies.Total Endoscopic Coronary Artery Bypass. With the advent of robotic surgical technology allowing stereoscopic visual-ization and increased instrument dexterity, total endoscopic coronary artery bypass (TECAB) has become possible. In July of 2004, the da Vinci robotic surgical system received FDA approval for use in coronary anastomoses. Extracorporeal cir-culation with peripheral cannulation has been used in earlier reports, but the development of mechanical stabilizers has pro-vided the ability to perform the internal thoracic artery harvest and coronary anastomosis off-pump with use of the robotic arms only. Several studies have looked at the feasibility of TECAB and have shown acceptable results, but this procedure has not been adopted by most surgeons because of its steep learning curve, longer operative times, and lack of demonstrable clinical benefit.81-83 Although the volume of robotic-assisted CABG is increasing, such procedures constituted <1% of all CABG pro-cedures performed in the United States in 2012.84Hybrid Coronary Revascularization. With the increasing collaboration between cardiothoracic surgeons and interven-tional cardiologists, hybrid coronary revascularization (HCR) combining a minimally invasive surgical technique (MIDCAB or TECAB) with PCI has become a reality. This capitalizes on a major advantage of both treatments, utilizing the durable left internal thoracic artery to left anterior descending coronary artery bypass graft while treating other stenoses with PCI, obvi-ating the need for a large surgical incision or cardiopulmonary bypass. HCR is not without its downsides as there are some concerns with this approach because aggressive anti-platelet therapy is required with PCI and may increase the hemorrhagic complications of surgical revascularization. A small study com-paring HCR to OPCAB showed comparable graft patency and decreased hospital stay with HCR without an increase in com-plication rates.85 There are, however, some studies that have reported increased rates of requirement for reintervention in patients undergoing HCR, and this requires further study.86,87 A recent multicenter prospective observational study showed equivalent outcomes between HCR and multivessel PCI.88 HCR has not gained widespread acceptance, and its clinical value remains a matter of debate.Transmyocardial Laser Revascularization. Despite the advancement of technology and revascularization strategies, patients with end-stage coronary artery disease may not be amenable to complete revascularization. Transmyocardial laser revascularization (TMR) relies on a CO2 or holmium:yttrium-aluminum-garnet (Ho:YAG) laser to create multiple transmu-ral channels (1 mm in diameter) through the myocardium. The initial concept was that these channels would serve as conduits for direct perfusion from the ventricle, but evidence suggests that the resultant angiogenesis is primarily responsible for the improved perfusion. A meta-analysis of seven randomized con-trolled trials comparing TMR to medical therapy for chronic Brunicardi_Ch21_p0801-p0852.indd 81301/03/19 5:32 PM 814SPECIFIC CONSIDERATIONSPART IITable 21-6Classification of cardiac murmursMURMURCONDITIONMECHANISM/ETIOLOGYSYSTOLIC MURMURSHolosystolic (pansystolic)VSDFlow between chambers that have widely different pressures throughout systoleMid-systolic (systolic ejection)High flow rate, MS, MR, TS, TIOften crescendo-decrescendo in configuration; occur as blood is ejected into the left and right ventricular outflow tractsEarly systolicEarly TI, acute MRLess commonMid to late systolicMR, MVPSoft to moderate high-pitched murmurs at the LV apex; often due to apical tethering and malcoaptation of MV leaflets; an associated click indicates prolapse of the MV leafletsDIASTOLIC MURMURSEarly high-pitchedAI, PRGenerally decrescendo in configuration; occur when the associated ventricular pressure drops sufficiently below that of the outflow tractMid-diastolicMS, TS, PDA*, VSD*, ASD*Due to a relative disproportion between valve orifice size and diastolic blood flow volume; seen in normal MV and TV with increased diastolic blood flow associated with these conditions*PresystolicMS, TSOccur during the period of ventricular filling that follows atrial contraction (i.e., only occur in sinus rhythm)CONTINUOUS MURMURSPDAUncommon, due to shunts that persist through the end of systole and the some or all of diastoleAI = aortic insufficiency; ASD = atrial septal defect; MR = mitral regurgitation; MS = mitral stenosis; MVP = mitral valve prolapse; PDA = patent ductus arteriosus; PR = pulmonic regurgitation; TI = tricuspid insufficiency; TS = tricuspid stenosis; VSD = ventricular septal defect.angina has shown higher rates of angina improvement in the TMR but was not able to show a difference in mortality between the two groups.89TMR is also being used as an adjunct to CABG in the treatment of extensive CAD that is not amenable to surgical revascularization alone. In a study looking at the benefits of TMR in addition to CABG, Allen et al concluded that TMR decreases angina burden when added to CABG in patients who cannot be revascularized by CABG alone.90 The current STS guidelines support the consideration of TMR in patients with ischemic myocardial territories that cannot be revascularized by PCI or CABG.91 Because of equivocal late results at most centers, this therapeutic strategy has not gained widespread acceptance, and ACC/AHA guidelines give TMR a class IIb recommendation for treatment of refractory angina.39New DevelopmentsRegenerative Medicine and Tissue Engineering. Provoca-tive investigations are being performed on the level of signaling molecules, gene therapy, stem cells, and tissue engineering to regenerate or replace damaged tissue in patients with ischemic heart disease. Growth factors, such as fibroblast growth fac-tor (FGF) and vascular endothelial growth factor (VEGF), are receiving attention due to their ability to induce growth of new vessels. Although concerns regarding systemic administration of these pleiotropic signaling molecules exist, early placebo-controlled clinical trials have shown some promising results with administration of these agents.92,93 Adenoviral transfection of diseased tissue with transgenes for growth factors and tran-scription factors has been attempted with variable results.Research in tissue engineering has been directed at cre-ation of vascular conduits that are resistant to atherosclerosis. Stem cells have also been infused directly into the site of injury or in the generation of new tissue around a biodegradable scaffold.94 Despite their potential, these technologies are still in their infancy, and significant progress will be needed before more widespread clinical adoption.VALVULAR HEART DISEASEGeneral PrinciplesThe number of patients undergoing surgical management of valvular heart disease has increased over the last decade, from a total of 26,547 isolated aortic or mitral valve procedures reported to the STS Adult Cardiac Surgery Database in 2006 to 45,253 such procedures in 2015.95 In 2016, valve procedures represented over 50% of the cases performed at our institution. Although congenital and inherited etiologies represent impor-tant clinical entities, age-associated and acquired conditions still represent the primary causes of valvular heart disease and are the focus of this section.The most common screening method for valvular heart disease is cardiac auscultation, with murmurs classified based primarily on their timing in the cardiac cycle, but also on their configuration, location and radiation, pitch, intensity, and dura-tion (Table 21-6).96 Although some systolic murmurs are related to normal physiologic increases in blood flow, some may indi-cate cardiac disease, such as valvular aortic stenosis (AS), that are important to diagnose, even when asymptomatic. Diastolic and continuous murmurs, on the other hand, are frequently Brunicardi_Ch21_p0801-p0852.indd 81401/03/19 5:32 PM 815ACQUIRED HEART DISEASECHAPTER 21Table 21-7Hemodynamic alterations in cardiac murmur intensityINTERVENTIONEFFECTRespirationRight-sided murmurs increase with inspiration. Left-sided murmurs increase with expiration.Valsalva maneuverMost murmurs decrease in length and intensity. The murmur of HCM becomes louder, and the murmur of MVP becomes louder and longer.ExerciseBenign flow murmurs and murmurs caused by stenotic valves become louder with isotonic and isometric exercise. The murmurs of MR, VSD, and AI also increase with isometric exercise.Positional changesMost murmurs decrease with standing; the murmur of HCM becomes louder, and the murmur of MVP becomes louder and longer. Brisk squatting and passive leg raising increases most murmurs; the murmurs of HCM and MVP diminish.Postventricular premature beat or atrial fibrillationBenign flow murmurs and stenosis at the semilunar valves increase in intensity following a ventricular premature beat or a long cycle length in atrial fibrillation. Systolic murmurs of atrioventricular valve regurgitation do not change.Pharmacologic interventionsThe initial hypotensive phase following inhalation of amyl nitrate decreases the murmurs of MR, VSD, and AI, and increases the murmur of AS. The later tachycardic phase following inhalation of amyl nitrate increases right-sided murmurs and the murmur of MS. The response in MVP is biphasic (softer then louder than control).Transient arterial occlusionTransient external compression of the upper extremity increases the murmurs of MR, VSD, and AI.AI = aortic insufficiency; AS = aortic stenosis; HCM = hypertrophic cardiomyopathy; MR = mitral regurgitation; MS = mitral stenosis; MVP = mitral valve prolapse; VSD = ventricular septal defect.pathologic in nature. Dynamic cardiac auscultation provides further evidence as to the significance and origin of many mur-murs (Table 21-7).96Although auscultation may provide initial evidence to the existence of valvular disease, associated signs and symptoms may help narrow the diagnosis. Abnormalities in the splitting of the heart sounds and additional heart sounds should be noted, as should the presence of pulmonary rales. Peripheral pulses should be checked for abnormal intensity or timing, and the presence of a jugular venous wave should be documented. Addi-tionally, symptoms of syncope, angina pectoris, heart failure, and peripheral thromboembolism are important and may help guide diagnosis and management.Several imaging examinations are also available to aid in the diagnosis and classification of various valvular disorders. Electrocardiograms may provide information regarding ven-tricular hypertrophy, atrial enlargement, arrhythmias, conduc-tion abnormalities, prior myocardial infarction, and evidence of active ischemia that would prompt further workup. Posteroan-terior and lateral chest X-rays are also easy to obtain and may yield information regarding cardiac chamber size, pulmonary blood flow, pulmonary and systemic venous pressure, and cardiac calcifications. The gold standard for the evaluation of valvular heart disease is transthoracic echocardiography (TTE), which is helpful in the noninvasive evaluation of valve mor-phology and function, chamber size, wall thickness, ventricu-lar function, pulmonary and hepatic vein flow, and pulmonary artery pressures. Specialized examinations based on the specific findings of TTE examinations are discussed in the following sections.Regardless of the etiology, valvular heart disease can pro-duce a myriad of hemodynamic derangements. Left untreated, valvular stenosis and insufficiency can produce significant pressure and volume overload on the affected cardiac chamber, respectively, with mixed disease consequently causing mixed pathology. Although the heart can initially compensate for alter-ations in cardiac physiology, cardiac function eventually dete-riorates, leading to heart failure, decreased patient functional status, ventricular dysfunction, and eventually death. In order to optimize long-term survival, surgery or transcatheter therapeu-tics are recommended in various forms of valvular heart disease and in an increasing number of elderly and high-risk patients.Surgical OptionsAlthough valve repair is increasingly indicated, especially in patients with aortic, mitral or tricuspid insufficiency, valve replacement is appropriate in certain patient populations. Valve replacement can be accomplished with either mechanical or bio-logical prostheses, and the choice of valve depends on many patient-specific factors such as age, health status, and desire for future pregnancy. Preexisting indications or contraindications to anticoagulation therapy also influence the choice of mechanical versus tissue valve prosthesis.Current options for mechanical valve replacement include either tilting disc valves or bileaflet valves. Although mechanical valves are highly durable, they require perma-nent anticoagulation to mitigate the risk of valve thrombosis and thromboembolic sequelae.97 Due to the concordant risk of hem-orrhagic complications, patient characteristics such as debility, lifestyle, and contraindications to systemic anticoagulation therapy may preclude mechanical valve replacement. Moreover, young women who are planning future pregnancies cannot take warfarin due to its teratogenic potential. Conversely, patients with other indications for systemic anticoagulation, such as other risk factors for thromboembolism (i.e., atrial fibrillation), or the presence of a mechanical prosthetic valve in place in another position, may benefit from mechanical valve replace-ment. Current ACC/AHA guidelines recommend a shared-decision-making process between patient and physician when determining the choice of valve prosthesis, with the use of 3Brunicardi_Ch21_p0801-p0852.indd 81501/03/19 5:32 PM 816SPECIFIC CONSIDERATIONSPART IIFigure 21-5. SJM Regent mechanical heart valve. (SJM Regent and St. Jude Medical are trademarks of St. Jude Medical, LLC or its related companies. Reproduced with permission of St. Jude Medical, ©2017. All rights reserved.)bioprosthetic valves in all patients who have a contraindication to lifelong anticoagulation or who are unwilling to receive it.98The potential to avoid the hazards of serious bleeding com-plications spurred the development of valve prostheses using biological materials, which obviate the need for systemic anti-coagulation therapy. As tissue valves are naturally less throm-bogenic, the attendant yearly risks of both thromboembolic and anticoagulation-related complications are considerably less than with mechanical valves.99 Consequently, tissue valve replace-ment is generally recommended for patients averse to systemic anticoagulation therapy, with potential concerns regarding com-pliance or follow-up while taking anticoagulant medications, and in the case of reoperation for a thrombosed mechanical valve. However, biological valves are more prone to degenera-tion, especially when implanted in the mitral position, and in younger patients, and those in renal failure, on hemodialysis, or with hypercalcemia.99 Improved manufacturing methods have made currently available tissue valves more durable than previ-ous versions, and valve replacement with a biological prosthesis is generally preferred in patients without other indications for anticoagulation therapy who are >60 years of age for the aortic position and >70 years of age for the mitral position. The avail-ability of transcatheter aortic valves for re-replacement, has resulted in patients and surgeons preferring bioprosthetic aortic valves in patients even <60 years of age in many centers.Mechanical Valves. The first bileaflet mechanical valve was introduced in 1977. Bileaflet valves are comprised of two semi-circular leaflets that open and close, creating one central and two peripheral orifices (Fig. 21-5). Bileaflet mechanical valves have demonstrated excellent flow characteristics, low risk of late valve-related complications, including valve failure, and are currently the most commonly implanted type of mechanical valve prosthesis in the world.100Although mechanical valves necessitate systemic antico-agulation, careful monitoring of the International Normalized Ratio (INR) reduces the risk of thromboembolic events and hemorrhagic complications and improves overall survival.101 Patients undergoing mechanical aortic valve replacement gen-erally have a target INR of 2 to 3 times normal; however, after a randomized study, one of the mechanical aortic valves has been improved for an INR range of 1.5 to 2.0.102 Patients undergoing mechanical mitral valve replacement frequently have increased left atrial size, concomitant atrial fibrillation, and are at higher risk for thromboembolism that those undergoing aortic valve replacement and are thus recommended to have a target INR 2.5 to 3.5 times normal. When managed appropriately, the yearly risk of major bleeding is <1.4%. Patients with mechanical mitral valve prostheses have nearly twice the thromboembolic risk of those with mechanical aortic valve prostheses (1.3% vs. 0.8% per year).103Tissue Valves. A xenograft valve is one implanted from another species, such as porcine xenograft valves, or manufac-tured from tissue such as bovine pericardium. A variety of xeno-graft tissue valves exist and are primarily differentiated by the presence or absence of a mounting stent. Stented valves are the most commonly implanted, and the most popular valve in the United States is a stented bovine pericardial valve.104The more traditional stented valves are attached to a sew-ing ring, which decreases the technical complexity of valve replacement compared with stentless valves (Fig. 21-6). The chief disadvantage of stented tissue valves is a smaller effective orifice area, which increases the transvalvular gradient. This phenomenon is referred to as patient prosthetic mismatch. This effect is most pronounced in patients with small prosthetic valve areas, specifically <0.85 cm2 valve area per square meter body surface area and may affect survival, symptomatic improve-ment, and the hemodynamic response to exercise following surgery.105Stentless porcine xenograft valves were developed in order to minimize the limitations in flow characteristics seen in patients with small prosthetic valve areas and have demon-strated an increase in effective valve area of approximately 10% over stented xenografts of equivalent size.100 They can result in improved hemodynamics, both at rest and with exercise.106 The absence of a stent and sewing ring both increases the techni-cal complexity of valve replacement and takes advantage of the biologic mobility of the aortic valve apparatus. Though results with stentless valves seem promising, some stentless valves have been shown to have poor durability,107 and stentless valves have not been widely adopted due to the technical complexity of implantation.Recently, rapid deployment valves have been introduced to further decrease the complexity and time required for aortic valve replacement. Two of these valves are on the market in the United States. The Perceval valve by LivaNova is the only sutureless, stentless valve available.108 These rapid deployment valves have shown improved hemodynamics, particularly in patients with small annuli, and shorter implantation times. In some series, these benefits have been shown to reduce early morbidity.108Homografts. Homograft valves from human cadavers, also known as allografts, have been used for aortic valve replace-ment since the technique was originally described over 50 years ago.109 Since that time, homografts have typically been used for aortic and pulmonary valve replacements and have been successfully harvested from brain dead organ donors and the Brunicardi_Ch21_p0801-p0852.indd 81601/03/19 5:32 PM 817ACQUIRED HEART DISEASECHAPTER 21Figure 21-6. Carpentier-Edwards PERIMOUNT Magna Ease stented porcine bioprosthesis. (Edwards Lifesciences LLC, Irvine, CA. Additionally, it should be noted that Edwards, Edwards Lifesciences, the stylized E logo, Carpentier-Edwards, Carpentier-Edwards Classic, Magna, Magna Ease, Magna Mitral Ease are trademarks of Edwards Lifesciences Corporation.)explanted hearts of heart transplant recipients. Following har-vest, these valves are sterilized using an antibiotic solution and subsequently stored in fixative or cryopreservation solution.Like other types of tissue valves, the risk of thrombo-embolic complications with homograft valves is low, and sys-temic anticoagulation therapy is not required. Additionally, the structure of homograft valves is naturally low-profile, allow-ing for larger effective valve orifices and lower postoperative transvalvular gradients compared with stented xenograft valves. Additionally, they have been shown to have some advantages in patients with endocarditis.110The major shortcoming of homograft valves is their lim-ited long-term durability due to tissue degeneration. Within one year of implantation, these valves undergo substantial loss of cellular components and subsequent structural compro-mise, which may ultimately lead to valve failure.111 Although enhanced preservation techniques has improved cellular viabil-ity, which approaches the 15-year viability of xenograft valves, the limited availability of these valves and techniques has lim-ited the use of homograft tissue valves.Autografts. In 1967, Donald Ross described a procedure in which the diseased aortic valve was replaced using the patient’s native pulmonary valve as an autograft, which was in turn replaced with a homograft in the pulmonic position.112 The pro-cedure resulted in minimal transvalvular gradients and favor-able left ventricular mechanics, both at rest and during exercise. Known as the Ross procedure, this operation has been shown to be particularly beneficial in children, as the pulmonary trunk grows with the child and long-term anticoagulation is not required.113The late results of the Ross procedure are discussed later in this chapter. In addition to potential concerns with durability, performance of the Ross procedure has also been limited by its technical complexity and the increased surgical risk associated with double valve replacement.Valve Repair. Valve repair offers a number of advantages over valve replacement, due in large part to the preservation of the patient’s native valvular and subvalvular apparatus. In mitral valve (MV) surgery, preservation of the mitral apparatus has been shown to lead to better postoperative left ventricular func-tion and survival.114,115 Additionally, as there is no implanted prosthesis, the patient avoids the risks of chronic anticoagula-tion, infection, thromboembolic complications, and prosthetic valve failure after surgery.In the case of MV repair, freedom from reoperation and valve-related complications has been excellent in certain patient populations, even at 20-year follow-up.116 It has also been dem-onstrated that patients undergoing MV surgery with moder-ate functional tricuspid regurgitation (TR) do not experience increased perioperative complication rates when a concomitant tricuspid valve (TV) repair is performed.117 Midterm results in this group are encouraging, with greater than 98% freedom from reoperation reported by some groups at 5 years, suggesting fur-ther indications for valve repair.Despite its advantages for the patient, valve repair is gen-erally more technically demanding than valve replacement and may occasionally fail. Both the suitability of the patient for valve repair and the skill and expertise of the surgeon perform-ing the operation are important when considering valve repair in the individual patient.MITRAL VALVE DISEASEMitral StenosisEtiology. Acquired mitral stenosis (MS) is most often caused by rheumatic fever, with approximately 60% of patients with pure MS presenting with a clinical history of rheumatic heart disease.96 Rarely, other conditions can cause obstruction to fill-ing of the left ventricle (LV), mimicking MS. Acquired causes of MV stenosis include left atrial myxoma, prosthetic valve thrombosis, mucopolysaccharidosis, previous chest radiation, and severe annular calcification.Pathology. Although rheumatic heart disease is associated with a transmural pancarditis, pathological fibrosis of the valves Brunicardi_Ch21_p0801-p0852.indd 81701/03/19 5:32 PM 818SPECIFIC CONSIDERATIONSPART IIFigure 21-7. Mitral stenosis. The thickened, fused leaflets of the diseased mitral valve are viewed through a left atriotomy. (Reproduced with permission from Centers for Disease Control and Prevention, Edwin P. Ewing, Jr.)Table 21-8Data from ACC/AHA guidelines for the classification of the severity of mitral valve disease in adultsMITRAL STENOSISINDICATORMILDMODERATESEVEREMean gradient (mmHg)a< 55–10>10Pulmonary artery systolic pressure (mmHg)< 3030–50> 50Valve area (cm2)>1.51.0–1.5< 1.0MITRAL REGURGITATIONQUALITATIVEMILDMODERATESEVEREAngiographic grade1+2+3+Color Doppler jet areaSmall, central jet (< 4 cm2 or <  20% left atrial area)More than mild criteria, but no severe criteria presentVena contracta width > 0.7 cm with large central jet (area > 40% of left atrial area) or with a wall-impinging jet of any size, swirling in left atriumDoppler vena contracta width (cm)< 0.30.3–0.69≥ 0.7QUANTITATIVE (CATH OR ECHO)Regurgitant volume (ml per beat)< 3030–59≥ 60Regurgitant fraction (%)< 3030–49≥ 50Regurgitant orifice area (cm2)0.20.2–0.39≥ 0.4ADDITIONAL ESSENTIAL CRITERIALeft atrial size  EnlargedLeft ventricular size  EnlargedaValve gradients are flow dependent and when used as estimates of severity of valve stenosis should be assessed with knowledge of cardiac output or forward flow across the valve.results primarily from the endocarditic process. The damage caused by endocardial inflammation and fibrosis is progressive, causing commissural fusion, subvalvular shortening of the chor-dae tendineae, and calcification of the valvular and subvalvu-lar apparatus.118 The resulting stenotic MV has a funnel shape, with doming of the leaflets, and a significantly narrowed orifice caused by interchordal and commissural fusion (Fig. 21-7). The degree of mitral stenosis should be determined preoperatively, as these pathological features may help determine the timing and type of intervention to perform.96Pathophysiology. As the normal MV area of 4.0 to 5.0 cm2 is reduced by the rheumatic process, blood can flow from the left atrium to the left ventricle only if it is propelled by an ever-increasing pressure gradient. This increased left atrial pressure causes left atrial enlargement and eventually pulmonary hyper-tension and decreased exercise tolerance. Patients with diastolic valve doming, usually accompanied by a history of rheumatic fever, are defined as having stage A MS, even with normal trans-mitral flow velocities. Stage B MS is defined by an increased transmitral flow velocity with mitral valve area greater than 1.5 cm2. This condition is associated with mild to moderate left atrial enlargement but normal pulmonary arterial pressure. Stage C MS consists of a severely stenotic valve (mitral valve area ≤1.5 cm2) without symptoms. This is frequently associated with commissural fusion and diastolic doming of the leaflets as well as a pulmonary arterial pressure of >30 mmHg. Stage D MS is defined as the aforementioned criteria with the onset of decreased exercise tolerance and/or dyspnea on exertion (Table 21-8).98The onset of symptoms is due to the evolution of patho-physiological processes, beginning with an elevation in left atrial pressure. The increased left atrial pressure is subsequently transmitted to the pulmonary venous system, causing pulmo-nary edema as the hydrostatic pressure in the vessels exceeds the plasma oncotic pressure. Decreased pulmonary venous compli-ance exacerbates the pulmonary venous hypertension, though a concomitant decrease in microvascular permeability may Brunicardi_Ch21_p0801-p0852.indd 81801/03/19 5:32 PM 819ACQUIRED HEART DISEASECHAPTER 21preclude pulmonary edema in the chronic setting.119 Patients may also develop pulmonary arterial hypertension, owing to vasoconstriction, intimal hyperplasia, and medial hypertrophy of the pulmonary arterioles in response to the increased pul-monary venous pressure. The secondary obstruction to flow caused by reactive pulmonary arterial hypertension may serve to protect against pulmonary edema, but it also exacerbates the intractable decrease in cardiac output that develops as stenosis worsens.120Throughout the process, the left atrium becomes dilated and hypertrophied due to increased work in filling the ventricle against a fixed obstruction. Atrial fibrillation (AF) may develop, exacerbating the patient’s symptoms and increasing the risk of left atrial thrombus and subsequent embolization. Left ventricu-lar structure and function are typically preserved owing to the protective effect of the stenotic valve.Clinical Manifestations. The sudden opening of the thick-ened, nonpliable valve with left atrial contraction produces an opening snap, followed by a diastolic rumble caused by rapid entry of blood into the left ventricle. When diastole is complete, the MV subsequently closes very rapidly, causing an increased first heart sound. The murmur, classically known as the aus-cultatory triad, is best heard at the apex. Associated mitral and tricuspid insufficiencies are heard as a pansystolic murmur radi-ating to the axilla and a systolic murmur at the xiphoid process, respectively.The first clinical signs of MS are those associated with pulmonary venous congestion, namely exertional dyspnea, decreased exercise capacity, orthopnea, and paroxysmal noctur-nal dyspnea. Hemoptysis and pulmonary edema may develop as the venous hypertension worsens. Advanced MS can also cause pulmonary arterial hypertension and subsequent right heart fail-ure, manifested as jugular venous distention, hepatomegaly, ascites, and lower extremity edema.2As mentioned previously, atrial fibrillation may develop as left atrial pathology worsens, causing atrial stasis and subse-quent thromboembolism. Patients with MS may initially present with signs of arterial embolization, even rarely with angina from coronary occlusion.2Diagnostic Studies. All patients with a clinical history and physical exam suggestive of MS should have an electrocardio-gram (ECG) and chest X-ray. Abnormalities in the ECG may include atrial fibrillation, left atrial enlargement, or right axis deviation. Chest X-ray findings may include enlargement of the left atrium and pulmonary artery, creating a double contour behind the right atrial shadow and obliterating the normal con-cavity between the aorta and left ventricle. Findings consistent with pulmonary congestion may also be present.2The diagnostic tool of choice is TTE, which not only con-firms the diagnosis of MS, but also rules out other concomi-tant myocardial or valvular heart disease.121 Two-dimensional TTE can be used to calculate the MV area and to determine the morphology of the MV apparatus, including leaflet mobility and flexibility, leaflet thickness and calcification, subvalvular fusion, and the appearance of the commissures. Doppler TTE can also be used in combination with various equations to esti-mate the hemodynamic severity of MS in terms of the mean transmitral pressure gradient, the MV area, and the pulmonary artery systolic pressure.In most cases, further examinations are not necessary. A preoperative TEE may be utilized to rule out left atrial appendage thrombus, when the patient is being considered for percutane-ous balloon mitral commissurotomy, or if the preoperative TTE is insufficient for diagnosis. Exercise TTE is indicated when resting TTE parameters are discordant with symptom sever-ity.122 Routine coronary angiography is usually performed prior to valve surgery,98 except in young patients (≤30 years of age) with no risk factor for coronary artery disease.Indications for Operation. Depending on the severity and the morphology of the diseased MV (see Table 21-8), balloon commissurotomy, surgical repair, or MV replacement may be indicated for the treatment of MS (Table 21-9).98Mitral RegurgitationEtiology. The most important cause of MR in the United States is myxomatous degenerative disease of the MV, which occurs in 2% to 3% of the population.123 Other important causes of MR include rheumatic heart disease, infective endocarditis, ischemic heart disease, and dilated cardiomyopathies. Less frequently, MR can be caused by collagen vascular diseases, trauma, pre-vious chest radiation, hypereosinophilic syndrome, carcinoid disease, and exposure to certain drugs.96Pathology. The MV apparatus consists of the mitral leaflets, chordae tendineae, papillary muscles, and mitral annulus, and abnormalities in any one of these components has the potential to cause MR.124 The system for classifying MR proposed by Carpentier focuses on the functional and anatomic characteris-tics of the MV pathology and proposes three basic types of dis-eased valves based on the motion of the free edge of the leaflet relative to the plane of the mitral annulus.125In Type I MR, valvular insufficiency occurs secondary to annular dilatation or leaflet perforation, and normal leaflet motion is maintained. Type II MR is seen in patients with mitral valve prolapse and is due to prolapse of often thickened exces-sive leaflet tissue that gives the valve a “billowing” appearance, in addition to ruptured or elongated chordae tendineae caus-ing increased leaflet motion. Type III insufficiency, as seen in patients with rheumatic and ischemic heart disease, occurs from restricted leaflet motion, either during systole and diastole (Type IIIA) or during systole alone (Type IIIB).Pathophysiology. The basic pathophysiologic abnormality of MR is the retrograde flow of a portion of the LV stroke volume into the left atrium during systole due to an incompetent MV or dilated MV annulus.Acute severe MR can result from ruptured chordae ten-dineae, a ruptured papillary muscle, or infective endocarditis and causes a sudden volume overload of both the left atrium and ventricle.96 Although an acute increase in preload provides a modest increase in overall stroke volume, the left atrium and ventricle are unable to fully accommodate the regurgitant vol-ume or maintain forward stroke volume in the acute setting due to a lack of remodeling.Chronic MR generally has a more indolent course, with increasing volume overload of the left atrium and ventricle as the effective regurgitant orifice size becomes larger. The result-ing increase in left atrial and ventricular volume initially allows for an increase in the total stroke volume by Starling’s law and accommodation of the regurgitant volume, thus maintaining forward cardiac output and alleviating pulmonary congestion during the compensatory phase of chronic MR.126 However, as the left atrium becomes more dilated, the development of AF becomes more likely, disrupting atrioventricular synchrony and Brunicardi_Ch21_p0801-p0852.indd 81901/03/19 5:32 PM 820SPECIFIC CONSIDERATIONSPART IITable 21-9Data from ACC/AHA guidelines for MV surgery in specific clinical contextsCLINICAL SETTINGCLASS OF RECOMMENDATIONLEVEL OF EVIDENCEBalloon Valvotomy for Mitral Stenosis• Symptomatic patients (NYHA II, III, IV) with moderate or severe MS and favorable valve morphology, without left atrial thrombus or moderate to severe MR• Asymptomatic patients with moderate or severe MS, favorable valve morphology, and pulmonary hypertension (PASP > 50 mmHg at rest, > 60 mmHg with exercise), without left atrial thrombus or moderate to severe MR• Symptomatic patients (NYHA III, IV) with moderate or severe MS and favorable valve morphology, who are high risk or not candidates for surgery• Asymptomatic patients with moderate or severe MS, favorable valve morphology, and new onset atrial fibrillation, without left atrial thrombus or moderate to severe MR• Symptomatic patients (NYHA II, III, IV) with MV area > 1.5 cm2 if there is evidence of hemodynamically significant MS (PASP > 60 mmHg, PAWP ≥ 25 mmHg, mean MV gradient >15 mmHg during exercise)• Symptomatic patients (NYHA III, IV) with moderate or severe MS and favorable valve morphology, as an alternative to surgery• Patients with mild MS• Patients with moderate to severe MR or left atrial thrombusIIIIaIIbIIbIIbIII – HarmIII – HarmACCCCCCCSurgery for Mitral Stenosisa• Symptomatic patients (NYHA III, IV) with moderate or severe MS when:Balloon valvotomy is unavailableBalloon valvotomy is contraindicated due to thrombus or MRValve morphology is not favorable for balloon valvotomy• Symptomatic patients with moderate to severe MS who also have moderate to severe MR• Mildly symptomatic patients (NYHA I, II) with severe MS and severe pulmonary hypertension (PASP > 60 mmHg)• Asymptomatic patients with moderate or severe MS and recurrent embolic events while receiving adequate anticoagulation, when the likelihood of successful MVr is high• MVr in the setting of mild MS• Closured commissurotomy in the setting of MVr; open commissurotomy should be performedIIIIaIIbIII – HarmIII – HarmBCCCCCSurgery for Mitral Regurgitationa• Symptomatic patients with acute severe MR• Symptomatic patients (NYHA II, III, IV) with chronic severe MR without LV dysfunction (LVEF < 0.30) and/or end-systolic dimension > 55 mm• Asymptomatic patients with chronic severe MR and mild to moderate LV dysfunction (LVEF 0.30–0.60) and/or end-systolic dimension ≥ 40 mm• Asymptomatic patients with chronic severe MR and preserved LV function (LVEF > 0.60, end-systolic dimension < 40 mm), when the likelihood of successful MVr is > 90%• Asymptomatic patients with chronic severe MR, preserved LV function, and 1) New onset atrial fibrillation, 2) Pulmonary hypertension (PASP > 50 mmHg at rest, > 60 mmHg with exercise)• Symptomatic patients (NYHA III, IV) with chronic severe MR due to a primary abnormality of the mitral apparatus and severe LV dysfunction (LVEF < 0.30, end-systolic dimension > 55 mm), when the likelihood of successful MVr is high• Symptomatic patients (NYHA III, IV) with chronic severe MR secondary to severe LV dys-function (LVEF < 0.30) who remain symptomatic despite optimal medical management for heart failure, including biventricular pacing• Asymptomatic patients with MR and preserved LV function (LVEF > 0.60, end-systolic dimension < 40 mm), when the likelihood of successful repair is low• Isolated MV surgery in the setting of mild or moderate MRIIIIIaIIaIIaIIbIII – HarmIII – HarmBBBBCCCCCLV = left ventricular; LVEF = left ventricular ejection fraction; MR = mitral regurgitation; MS = mitral stenosis; MV = mitral valve; MVr = mitral valve repair; MVR = mitral valve replacement; NYHA = New York Heart Association; PASP = pulmonary artery systolic pressure; PAWP = pulmonary artery wedge pressure; a = mitral valve repair should be performed when possible in this population.Brunicardi_Ch21_p0801-p0852.indd 82001/03/19 5:32 PM 821ACQUIRED HEART DISEASECHAPTER 21predisposing to thrombus formation. Additionally, chronic vol-ume overload may lead to LV contractile dysfunction, result-ing in impaired ejection and end-systolic volume increases. LV dilatation and elevated LV end-diastolic pressures may also worsen throughout the progression of MR, reducing cardiac output and causing congestion of the pulmonary vasculature. These changes herald LV decompensation and heart failure and often indicate irreversible myocardial injury.Clinical Manifestations. In cases of acute severe MR, patients are often symptomatic and present with pulmonary congestion and reduced forward stroke volume. In severe cases, patients may present with cardiogenic shock.2 Because the LV has not remodeled in the acute setting, a hyperdynamic apical impulse may not be present in the precordium. The typical sys-tolic murmur of MR may be holosystolic or absent, with a third heart sound and/or diastolic flow murmur being the only aus-cultatory findings.In cases of chronic MR, patients may remain asymptom-atic for long periods of time due to the compensatory mecha-nisms of the remodeled LV. However, once the LV begins to fail, patients become increasingly symptomatic from exertional dyspnea, decreased exercise capacity, orthopnea, and eventu-ally pulmonary hypertension and right heart failure.2 Physical examination may demonstrate displacement of the LV apical impulse due to cardiac enlargement from chronic volume over-load, a third heart sound, or an early diastolic flow rumble. The characteristic auscultatory findings also include an apical sys-tolic murmur, which is variably transmitted to the axilla or the left sternal border, depending on the location of the pathology. As mentioned previously, patients may present with AF due to dilatation of the left atrium. Findings consistent with pulmonary hypertension frequently indicate late-stage disease.Diagnostic Studies. In the setting of acute heart failure, TTE should be performed and may demonstrate the anatomical loca-tion and severity of the MV pathology. However, TTE may underestimate lesion severity due to inadequate views of the color flow jet. In this case, severe MR should be suspected if hyperdy-namic systolic function of the LV is visualized, and TEE may be used to confirm the diagnosis and direct repair strategies.127In cases of chronic MR, ECG and chest X-ray are per-formed to assess rhythm status and the degree of pulmonary vascular congestion.96,98 An initial 2D and Doppler TTE should be performed for a baseline estimation of LV and left atrial size, LV systolic function, pulmonary artery pressure, MV morphol-ogy, and MR severity.128 A central color flow jet in the setting of a structurally normal MV on TTE suggests functional MR, which may be due to LV dilatation or tethering of the posterior leaflet in patients with ischemic heart disease. In the setting of organic MR (i.e., rheumatic and degenerative MR), which is suggested by the presence of an eccentric color flow jet and morphological abnormalities in the MV apparatus on TTE, the presence of calcium in the annulus or leaflets, the redundancy of the leaflets, and the anatomy of the MV pathology should be assessed. Follow-up TTE is indicated on an annual or semian-nual basis in patients with asymptomatic moderate to severe MR in order to assess changes from baseline parameters and direct the timing of surgery. Any abrupt change in signs or symp-toms in a patient with chronic MR is also an indication for TTE examination.98Additional preoperative studies are variably indicated in certain patient populations. Preoperative TEE is indicated in patients with indications for surgery or poor windows on TTE in order to determine the severity and anatomic basis of MR and to evaluate LV systolic function.96 Preoperative TEE is also indicated in cases when a discrepancy exists between a patient’s functional status and the severity of MR on TTE. It is helpful for preoperative planning when assessing the feasibility of repair in the individual patient. Exercise stress-echocardiography may also be useful to detect LV systolic dysfunction in well-compensated patients, who may not demonstrate a rise in the end-systolic dimension of the heart or a drop in ejection fraction on routine TTE.129 Coronary angiography should be performed prior to valve surgery in patients with evidence of ischemia, decreased LV systolic function, a history of coronary artery dis-ease or coronary risk factors, including postmenopausal status and age ≥40 in men and premenopausal women.98Indications for Operation. Based on the etiology, morphol-ogy, and severity of MR (see Table 21-8), MV repair, MV replacement with preservation of part or all of the mitral apparatus may be variably performed for the treatment of MR. As the intraoperative findings may dictate MV replacement whenever a MV repair is planned, current recommendations are for MV surgery in general (see Table 21-9).98Mitral Valve Operative Techniques and ResultsMitral valve surgery is performed on the arrested heart with the assistance of cardiopulmonary bypass. Traditionally, a median sternotomy incision has been used; however, the left atrium can also be approached via minimally invasive incisions, such as a right thoracotomy, or a fully endoscopic approach. The MV is commonly exposed through a left atrial incision placed poste-rior and parallel to the intra-atrial groove or via a transseptal approach through the right atrium.Commissurotomy. Upon opening the left atrium, the MV is visualized and the left atrium is examined for thrombus. A nerve hook or right-angle clamp is subsequently introduced beneath the commissures and used to evaluate the MV apparatus for leaflet mobility, commissural fusion, and subvalvular chordal abnormalities. The commissure is then carefully incised in a slightly anterior direction 2 to 3 mm at a time, making sure with each extension of the incision that the chordae tendineae remain attached to the commissural leaflets. The commissurotomy is generally stopped 1 to 2 mm from the annulus where the leaf-let tissue thins, indicating the transition to normal commissural tissue. The papillary muscles are subsequently examined and incised as necessary in order to maximize the mobility of the leaflets.After the commissurotomy is complete and the associated chordae tendineae and papillary muscles are mobilized, leaflet mobility is assessed. The anterior leaflet is grasped with forceps and brought through its complete range of motion. If subvalvu-lar restriction or leaflet rigidity is identified, further division or excision of fused chordae and debridement of calcium may be necessary. Occasionally, the leaflets can be debrided carefully to increase mobility. In rheumatic patients, the thickened leaf-lets can be thinned by careful dissection.130 Valve replacement may be more appropriate if extensive secondary mobilization is required. At the end of the procedure, competence of the valve is assessed with injection of cold saline into the ventricle.Open surgical commissurotomy has an operative risk of <1%, and has been shown to have good long-term results, with freedom from reoperation as high as 88.5%, 80.3%, and 78.7% at 10, 20, and 30 years, respectively.131 The incidence of 4Brunicardi_Ch21_p0801-p0852.indd 82101/03/19 5:32 PM 822SPECIFIC CONSIDERATIONSPART IIFigure 21-8. Mitral valve replacement. A St. Jude bileaflet mechanical valve is viewed through a left atriotomy.postoperative thromboembolic complications is generally <1% per patient-year, and the lack of required systemic anticoagula-tion precludes the development of hemorrhagic complications long term.132 In some institutions, balloon valvuloplasty has replaced commissurotomy.Mitral Valve Replacement. After exposing the valve, an inci-sion is made in the anterior mitral leaflet, in the midline. The chordal attachments are preserved if possible, with leaflet tis-sue being excised as needed. Attempts are made to preserve the annular and subvalvular apparatus when possible. If it is necessary to excise the anterior leaflet and chordae, the papil-lary muscles can be reattached to the annulus with PTFE suture. If possible, the posterior leaflet along with its associated sub-valvular structures are preserved. The annulus is subsequently sized, and an appropriate mitral prosthesis is implanted using pledgeted horizontal mattress sutures. The annular sutures may be placed from the atrial to the ventricular side, seating the valve intra-annularly, or from the ventricular to the atrial side, seating the valve in a supra-annular position. When placing the mattress sutures, care must be taken to stay within the annular tissue, as excessively deep bites may cause injury to critical structures such as the circumflex coronary artery posterolaterally, the atrioventricular node anteromedially, or the aortic valve antero-laterally. The sutures are subsequently placed through the sew-ing ring, and the valve prosthesis is lowered onto the annulus, where it is secured (Fig. 21-8).The factors associated with increased operative risk for MV replacement include age, left ventricular systolic dys-function, emergent procedure status, NYHA functional status, previous cardiac surgery, associated coronary artery disease, and concomitant disease in another valve. However, for most patients, MV replacement is associated with an operative mor-tality between 2% to 6%, and 65% to 70% 5-year survival.133,134 Although preservation of the mitral apparatus during MV replacement is important for subsequent left ventricular func-tion, there was no difference between complete and partial preservation with respect to 30-day and 5-year mortality.133 Mechanical valves are associated with increased durability compared to bioprosthetic valves, and they have demonstrated a freedom from reoperation of 98% vs. 79% at 15 years, respectively.135 Despite these findings, the choice of prosthetic valve depends on many factors and should be decided on a patient-by-patient basis.Mitral Valve Repair. There are many techniques available for MV repair that are variably used depending on the preoperative and intraoperative assessment of valvular pathology. On open-ing the atrium, the endocardium is examined for a jet lesion, a roughened area caused by a regurgitant jet striking the wall, in order to better localize the area of valvular insufficiency. The commissures are examined for evidence of prolapse, fusion, and malformation. The subvalvular apparatus and individual leaflets are subsequently examined, and areas of prolapse, restriction, fibrosis, and calcification are identified. Leaflet perforations are generally repaired primarily, or with a pericardial patch. The degree of annular dilation is also noted. The basic components of MV repair based on this assessment may include resection of the posterior and/or anterior leaflet, chordal shortening, chordal transposition, artificial chordal replacement, and annuloplasty. Recent trends have been toward leaflet preservation.One of the mainstays of MV repair is triangular resection of the posterior leaflet. Excision of the diseased leaflet tissue extends down towards but generally not to the mitral annulus. After repair has been completed, valvular competency is evalu-ated by injecting saline into the ventricle with a bulb syringe and assessing leaflet mobility and apposition. If focal insufficiency is identified in other areas, additional procedures are performed.The anterior leaflet may be repaired via chordal shorten-ing, chordal transposition, artificial chordal replacement, and triangular resection of the anterior leaflet. Chordal shortening has generally been abandoned in favor of chordal replacement. During chordal transposition, a resected portion of the posterior leaflet with attached chordae is transposed onto the prolapsed portion of the anterior leaflet to provide structural support, and this is followed by posterior leaflet repair, as described pre-viously. The procedure of artificial chordal replacement uses polytetrafluoroethylene sutures to attach the papillary muscle to the free edge of the prolapsing anterior leaflet. Triangular resection with primary repair of the anterior leaflet removes the prolapsing segment of the anterior MV leaflet, while preserv-ing adjacent chordal tissue, and may be especially helpful in patients with a ruptured chord or large amount of redundant anterior leaflet tissue.Annular dilation is generally corrected using a MV annu-loplasty device, such as a ring or partial band. Annuloplasty is known to improve the durability of all types of MV repair (Fig. 21-9).136 A number of devices are available and include rigid or semirigid rings that geometrically remodel the annulus, flexible rings or bands that restrict annular dilation while main-taining the physiologic sphincter motion of the annulus, and semirigid bands that provide a combination of annular remodel-ing and support of physiologic motion.Another technique known as the “double-orifice” or “edge-to-edge” repair was introduced by Alfieri in 1995, and it involves tacking the free edge of the anterior leaflet to the opposing free edge of the posterior leaflet.137 This procedure effectively gives the valve a double-orifice “bow tie” configura-tion, and it has been used as both a primary repair technique and an adjunct to other repair techniques, usually in cases of anterior leaflet pathology or Barlow’s disease. While some groups report excellent late results, its use remains controversial, and it is used mainly as a bail-out procedure of last resort in many centers.Brunicardi_Ch21_p0801-p0852.indd 82201/03/19 5:32 PM 823ACQUIRED HEART DISEASECHAPTER 21Figure 21-9. Mitral valve repair. The narrow arrow indicates the posterior leaflet repair, and the wide arrow indicates the ring annu-loplasty as viewed through a left atriotomy.Figure 21-10. Aortic stenosis. The aorta has been removed to demonstrate the thickened, fused aortic valve leaflets associated with rheumatic heart disease. (Reproduced with permission from Centers for Disease Control and Prevention, Edwin P. Ewing, Jr.)Due to the variety in operations and etiologies of MV dis-ease, there is heterogeneity in outcomes following MV repair. In general, the operative risk for elective, younger patients undergoing MV repair is <1%, and late results across a broad range of patients have demonstrated benefits in survival and valve-related complications, such as thromboembolic events, infective endocarditis, and anticoagulation-related hemorrhage, compared to MV replacement.116,138 Patients with MR due to degenerative disease have especially encouraging outcomes, demonstrating rates of survival and freedom from reoperation of >50% and >94% at 20 years, respectively.116 Historically, isolated anterior leaflet prolapse increased the risk of reopera-tion fivefold in this population. However, increasing experi-ence and the expanded use of chordal replacement has greatly improved these results in recent series.139 Independent predic-tors of mortality have included higher NYHA class, lower left ventricular ejection fraction, renal dysfunction, and age. Older patients have demonstrated slightly worse outcomes overall, with an operative mortality of approximately 4%, and a 10-year survival of 54% in patients ≥65 years of age. However, the superiority of repair over replacement persists even for patients >80 years of age.134Patients with rheumatic disease have demonstrated slightly worse outcomes, with one study showing significantly better freedom from operation at 10 years in patients with non-rheumatic MV disease (88% vs. 73%, P <0.005).140 Similarly, in patients with MR secondary to myocardial ischemia, there is growing recent evidence that mitral valve replacement may be significantly more durable than repair.141,142 Despite these differ-ences in outcomes, MV repair remains the procedure of choice for the majority of patients with amenable MV disease.Transcatheter Mitral Valve Repair and Replace-ment. Since the successful introduction of transcatheter aortic valve replacement, efforts have been made to translate the les-sons learned to treatment of the mitral valve. The first device to receive FDA approval for repair of severe mitral regurgitation due to degenerative mitral disease was the MitraClip (Abbott, Abbott Park, IL), introduced in 2003. This device allows a sur-geon or cardiologist to grasp the anterior and posterior leaflets of the mitral valve together, approximating the Alfieri double-orifice repair technique.143 Transcatheter mitral valve repair is now in clinical use in patients with chronic severe primary MR in whom surgery would be too great a risk, as judged by a heart team approach including a cardiologist skilled in structural heart intervention and an experienced mitral valve surgeon (see Table 21-9). In a recent randomized controlled trial comparing trans-catheter mitral valve repair to open surgical mitral valve repair, 20.1% (n = 37) of patients who received transcatheter mitral valve repair (n = 184) underwent second intervention with sur-gical mitral valve repair or replacement within 12 months com-pared with 2% (n = 2) of patients who underwent surgical repair (n = 95) (P <0.001).143,144 Surgical repair was associated with higher rates of blood transfusion and mechanical ventilation >48 hours but had otherwise equivalent safety. Other transcatheter techniques, including transcatheter mitral valve replacement, have begun clinical trials. This is an area of active research; however, at present, open surgical repair or replacement remains the standard of care for most patients.AORTIC VALVE DISEASEAortic StenosisEtiology. The most common cause of adult aortic stenosis (AS) is calcification of a normal trileaflet or congenital bicuspid aortic valve, particularly in patients >70 years of age. Another important cause of AS is rheumatic heart disease, which is par-ticularly common in developing countries (Fig. 21-10).Pathology. Calcific aortic valve disease, also known as senile or degenerative disease, is an age-related disorder characterized by lipid accumulation, proliferative and inflammatory changes, upregulation of angiotensin-converting enzyme activity, oxidative stress, and infiltration of macrophages and T lymphocytes.145 This process, which closely resembles atherosclerotic vascular calcification, initially results in bone formation within the base of the cusps, reducing leaflet motion. Calcification progresses to involve the leaflets, and eventually results in obstructive Brunicardi_Ch21_p0801-p0852.indd 82301/03/19 5:32 PM 824SPECIFIC CONSIDERATIONSPART IITable 21-10Data from ACC/AHA guidelines for the classification of the severity of aortic valve disease in adultsAORTIC STENOSISINDICATORMILDMODERATESEVEREJet velocity (m per s)< 303.0–4.0> 40Mean gradient (mmHg)a< 2525–40> 4.0Valve area (cm2)> 1.51.0–1.5< 1.0Valve area index (cm2 per m2)  < 0.6AORTIC REGURGITATIONQUALITATIVEMILDMODERATESEVEREAngiographic grade1+2+3–4+Color Doppler jet widthCentral jet, width < 25% of left ventricular outflow tractGreater than mild, but no signs of severe regurgitationCentral jet, width >65% of left ventricular outflow tractDoppler vena contracta width (cm)< 0.30.3–0.6> 0.6QUANTITATIVE (CATH OR ECHO)Regurgitant volume (ml per beat)< 3030–59≥ 60Regurgitant fraction (%)< 3030–49≥ 50Regurgitant orifice area (cm2)< 0.10.1–0.29≥ 0.3ADDITIONAL ESSENTIAL CRITERIALeft ventricular size  EnlargedaValve gradients are flow dependent and when used as estimates of severity of valve stenosis should be assessed with knowledge of cardiac output or forward flow across the valve.disease, with a reduced effective valve area without signs of leaflet fusion.Pathophysiology. In general, once moderate AS is present, the average rate of progression includes an increase in jet velocity of 0.3 m/s per year, an increase in mean pressure gradient of 7 mmHg per year, and a decrease in valve area of 0.1 cm2 per year (Table 21-10).96 In most adult patients with AS, obstruction develops gradually and includes a long latent period free from symptoms. During this time, the LV typically hypertrophies in response to systolic pressure overload, and normal intracavi-tary volume is maintained.146 Afterload, which is defined as left ventricular systolic wall stress, and thus ejection fraction remain normal early in this process as the increase in myocardial thickness is usually enough to counter the increased intracavi-tary systolic pressures. Patients without a typical hypertrophic response to systolic pressure overload or with a depressed con-tractile state of the myocardium do not follow the common clini-cal course, but they experience an early decrease in ejection fraction due to excessively increased afterload without a com-pensatory response.147Concentric LV hypertrophy without chamber dilatation eventually leads to increased end-diastolic pressures and dia-stolic dysfunction. Forceful atrial contraction in the face of elevated end-diastolic pressures becomes an important compo-nent of ventricular filling, even as mean left atrial and pulmo-nary venous pressures remain in the normal range. Disorders such as atrial fibrillation that disrupt atrial contraction can lead to clinical deterioration. Although systolic function is gener-ally preserved long into the natural history of the disease, left ventricular decompensation eventually occurs in the setting of longstanding increased afterload and is an indication for surgery even in the absence of other symptoms.Although concentric hypertrophy is a compensatory mech-anism to maintain ejection fraction in the face of high intracavi-tary pressures, the hypertrophied heart becomes increasingly vulnerable to ischemic injury. Coronary blood flow may become inadequate, despite the absence of epicardial coronary artery disease.148 Coronary vasodilation is mitigated by the hypertro-phied myocardium, and the hemodynamic stress of exercise or tachyarrhythmias can lead to subendocardial ischemia and further systolic or diastolic dysfunction. When ischemic insults occur, patients with ventricular hypertrophy experience larger infarcts and higher mortality rates than those without hypertrophy.149 In some patients, ventricular hypertrophy occurs in excess of what is needed to compensate for increased intra-cavitary pressures, creating a high-output state that is also asso-ciated with increased perioperative morbidity and mortality.150Clinical Manifestations. The characteristic auscultatory findings of AS include a harsh, crescendo-decrescendo systolic murmur at the right second or third intercostal space, often with radiation to the carotid arteries.2 As the disease progresses, aor-tic valve closure may follow pulmonic valve closure, causing paradoxical splitting of the second heart sound. Other physical findings associated with AS include an apical impulse com-monly described as a “prolonged heave,” and the presence of a narrow and sustained peripheral pulse, known as pulsus parvus et tardus.The classic symptoms of AS are exertional dyspnea, angina, and syncope.2 Although many patients are diagnosed prior to the onset of symptoms, the most common clinical Brunicardi_Ch21_p0801-p0852.indd 82401/03/19 5:32 PM 825ACQUIRED HEART DISEASECHAPTER 21presentation in patients with a known diagnosis of AS is wors-ening exertional dyspnea. Angina occurs in over half of patients with AS and is due to the increased oxygen demand of the hypertrophied myocardium in the setting of reduced oxygen supply secondary to coronary compression. Although some patients may have concomitant coronary disease, angina occurs without significant epicardial coronary artery disease in half of all patients with AS.151 Syncope is most common during exer-tion, as systemic vasodilation in the setting of a fixed cardiac output causes decreased cerebral perfusion. However, at times, it may occur at rest secondary to paroxysmal atrial fibrillation and subsequent loss of atrial booster pump function. Late find-ings of AS include atrial fibrillation, pulmonary hypertension, systemic venous hypertension, and, rarely, sudden death.Diagnostic Studies. Evidence of LV hypertrophy is found in approximately 85% of patients with AS on routine ECG, though the correlation between the absolute electrocardiographic volt-ages in precordial leads and the severity of AS is poor.2 ECG also may demonstrate signs of left atrial enlargement and vari-ous forms and degrees of atrioventricular or intraventricular block due to calcific infiltration of the conduction system. Rou-tine chest X-ray usually demonstrates a normal heart size, with rounding of the left ventricular border and apex. A late finding on chest X-ray is cardiac enlargement, or cardiomegaly, a sign of LV failure.Transthoracic echocardiography is indicated in all patients with a systolic murmur graded ≥2/6, a single second heart sound, or symptoms characteristic of AS.98 Initial TTE examinations are often diagnostic and provide an assessment of left ventricular size and function, the degree of left ventricular hypertrophy, the degree of valvular calcification, and the pres-ence of other associated valvular disease. Doppler evaluation should be performed to define the maximum jet velocity, which is a useful measure for following disease severity and predict-ing clinical outcome.2 Additionally, color flow Doppler assesses the severity of the stenotic lesion by allowing calculation of the mean transvalvular pressure gradient and effective valve orifice area (see Table 21-10).98 Follow-up TTE is indicated depending on the severity of AS in order to assess changes from baseline parameters and direct the timing of surgery: yearly for severe AS; every 1 to 2 years for moderate AS; and every 3 to 5 years for mild AS. Any abrupt change in signs or symptoms in a patient with AS is an indication for TTE examination.Additional preoperative studies may be necessary in some patients. Rarely, when TTE images are suboptimal, TEE or fluo-roscopy may be indicated to assess the degree of valve calcifica-tion and effective valve orifice area. As in other patients with valvular heart disease, coronary angiography should be per-formed prior to aortic valve surgery in most patients.98 Since the symptoms of AS often mimic those of ischemic heart disease, left heart catheterization and coronary angiography may be nec-essary at the initial evaluation in patients with AS. Stress echo-cardiography may also be useful in the asymptomatic patient with AS in order to elicit exercise-induced symptoms or abnor-mal blood pressure responses during exertion. It is also useful in the evaluation of low-gradient AS in patients with depressed LV function.98 However, exercise stress-echocardiography is con-traindicated in patients with ischemic heart disease.98 In patients with evidence of aortic root disease by TTE, chest computed tomography is useful in evaluating aortic dilatation at several anatomic levels and is necessary for clinical decision making and surgical planning.2Indications for Operation. Based on the severity of AS (see Table 21-10) and the predicted risk with surgical aortic valve replacement (SAVR) determined using the STS risk calculator, SAVR or transcatheter aortic valve replacement (TAVR) may be recommended for the treatment of AS (Table 21-11).98,152 As this field is rapidly evolving, attention to guideline updates and a multidisciplinary heart team approach to risk stratification and treatment selection are mandatory. In patients with severe calcific AS, AVR via either approach is the only effective treat-ment, though controversy exists as to the timing of intervention in asymptomatic patients. Balloon aortic valvuloplasty creates a modest hemodynamic effect and temporary symptom improve-ment in patients with calcific AS. However, the procedure has not been shown to affect long-term outcomes and is often used in hemodynamically unstable patients as a bridge to AVR.98Aortic InsufficiencyEtiology. The most common cause of isolated aortic insuffi-ciency (AI) in patients undergoing AVR is aortic root disease, and it represents over 50% of such patients in some studies.2 Other common causes of AI include congenital abnormalities of the aortic valve such as bicuspid aortic valve, calcific degenera-tion, rheumatic disease, infective endocarditis, systemic hyper-tension, myxomatous degeneration, dissection of the ascending aorta, and Marfan syndrome. Less common causes of AI include traumatic injuries to the aortic valve, ankylosing spondylitis, syphilitic aortitis, rheumatoid arthritis, osteogenesis imperfecta, giant cell aortitis, Ehlers-Danlos syndrome, Reiter’s syndrome, discrete subaortic stenosis, and ventricular septal defects with prolapse of an aortic cusp.96 Although most of these lesions produce chronic aortic insufficiency, rarely acute severe aortic regurgitation can result, often with devastating consequences.Pathology. Regardless of its cause, AI produces volume over-load with dilation and hypertrophy of the left ventricle and sub-sequent dilation of the MV annulus. Depending on the severity of AI, the left atrium may undergo dilation and hypertrophy as well. Frequently, the regurgitant jet causes endocardial lesions at the site of impact on the left ventricular wall.Diseases causing AI can be classified as primary disorders of the aortic valve leaflets and/or disorders involving the wall of the aortic root. Diseases causing dilation of the ascending aorta are a more common indication for AVR due to isolated AI, and they include disorders such as age-related (degenera-tive) aortic dilation, cystic medial necrosis of the aorta as is seen in Marfan syndrome, aortic dilation secondary to bicuspid valves, and aortic dissection, to name a few.153 In these disor-ders, the aortic annulus becomes dilated, causing separation of the valve leaflets and subsequent AI. The diseased aortic wall may dissect secondarily and further escalate regurgitation across the valve, and secondary thickening and shortening of the valve cusps may occur due to undue tension placed on the valvular apparatus by the dilated aortic root. As the disease progresses, the valve leaflets become too small to close the aortic orifice, causing further aortic insufficiency and exacerbating dilation of the ascending aorta.There are also many primary valvular diseases that cause AI, generally in association with AS. One such disorder is age-related calcific AS, which causes some degree of AI in up to 75% of patients.154 Infective endocarditis may involve the aortic valve apparatus and cause AI through direct destruction of the valve leaflets, perforation of a leaflet, or formation of vegetations that interfere with proper coaptation of the valve Brunicardi_Ch21_p0801-p0852.indd 82501/03/19 5:32 PM 826SPECIFIC CONSIDERATIONSPART IITable 21-11Data from ACC/AHA guidelines for AV surgery in specific clinical contextsCLINICAL SETTINGCLASS OF RECOMMENDATIONLEVEL OF EVIDENCEBalloon Valvotomy for Aortic Stenosis• Bridge to surgery in hemodynamically unstable patients with AS at high risk for AVRIIbC• Palliation in adult patients with AS, who are not candidates for AVRIIbC• Alternative to AVR in adult patients with ASIII – HarmBSurgery for Aortic Stenosis• Symptomatic patients with severe ASIB• Severe AS in the setting of1) Concomitant CABG2) Concomitant valvular or aortic surgery3) LV systolic dysfunction (LVEF <0.50)IC• Moderate AS in the setting of1) Concomitant CABG2) Concomitant valvular or aortic surgeryIIaB• Asymptomatic patients with severe AS and• Abnormal response to exercise• High likelihood of rapid progression• High likelihood of delay if surgery is withheld until time of symptom onset• Expected operative mortality ≤1.0%IIbC• Mild AS in patients undergoing CABG, when there is high likelihood of rapid progressionIIbC• AVR for prevention of sudden death in asymptomatic patients with AS without any of the findings aboveIII – HarmBSurgery for Aortic Insufficiency• Symptomatic patients with severe AIIB• Asymptomatic patients with chronic severe AI in the setting of1) Concomitant CABG2) Concomitant valvular or aortic surgery3) LV systolic dysfunction (LVEF ≤0.50)ICCB• Asymptomatic patients with severe AI, normal LV systolic function (LVEF >0.50), but severe LV dilatation (end-diastolic dimension >75 mm, end-systolic dimension >55 mm)IIaB• Moderate AI in the setting of1) Concomitant CABG2) Concomitant surgery on the ascending aortaIIbC• Asymptomatic patients with severe AI, normal LV systolic function at rest (LVEF >0.50), and LV dilatation (end-diastolic dimension ≥70 mm, end-systolic dimension ≥50 mm) in the setting of1) Progressive LV dilatation2) Declining exercise tolerance3) Abnormal hemodynamic responses to exerciseIIbC• Asymptomatic patients with mild, moderate, or severe AI and normal LV systolic function (LVEF >0.50), when the degree of LV dilatation is not moderate or severe (end-diastolic dimension <70 mm, end-systolic dimension <50 mm)III – HarmBAS = aortic stenosis; AVR = aortic valve replacement; CABG = coronary artery bypass grafting; LV = left ventricular; LVEF = left ventricular ejection fraction; NYHA = New York Heart Association.cusps. Rheumatic disease causes fibrous infiltration of the valve cusps and subsequent retraction of the valve leaflets, inhibiting apposition of the cusps during diastole and producing a central regurgitant jet. Patients with large ventricular septal defects or membranous subaortic stenosis may develop progressive AI, owing to a Venturi effect that results in prolapse of the aortic valve leaflets.Pathophysiology. The basic pathophysiologic abnormality of AI is the retrograde flow of a portion of the LV stroke volume into the LV during diastole, producing volume overload.Acute severe AI results most commonly from infective endocarditis, acute aortic dissection, or trauma, and it causes a sudden volume overload of the left ventricle.54 Although an acute increase in preload provides a small increase in overall Brunicardi_Ch21_p0801-p0852.indd 82601/03/19 5:32 PM 827ACQUIRED HEART DISEASECHAPTER 21stroke volume due to the Starling mechanism, the left ventricle often is unable to accommodate the large regurgitant volume and maintain forward stroke volume in the acute setting due to a lack of remodeling. Left ventricular end-diastolic and left atrial pressures increase dramatically as the LV is unable to develop compensatory chamber dilation. Although tachycardia develops as a compensatory mechanism to maintain forward flow, this attempt is often inadequate, and patients frequently present in heart failure and even cardiogenic shock. Moreover, subendo-cardial myocardial ischemia frequently develops as a result of decreased coronary diastolic perfusion pressures and increased LV end-diastolic pressure, as well as increased myocardial oxy-gen demand due to acute dilation. In the setting of a chronic ventricular hypertrophy and preexisting diastolic dysfunction, the pressure-volume relationship is even more extreme, exacer-bating the hemodynamic derangements seen in acute AI.Chronic AI generally has a more indolent course, with vol-ume overload of the LV causing compensatory increases in left ventricular end-diastolic volume and chamber compliance as well as a combination of eccentric and concentric hypertrophy.155 Compensatory remodeling of the LV allows for accommodation of the regurgitant volume without a significant increase in fill-ing pressures and maintains the preload reserve of the cham-ber. Eccentric left ventricular hypertrophy develops, permitting normal contractile performance across the enlarged chamber circumference and subsequent ejection of a larger total stroke volume in order to maintain forward flow, despite the regurgi-tant fraction.155,156 However, the enlarged chamber size results in an increase in systolic myocardial wall stress and causes further ventricular hypertrophy. As the disease progresses, recruitment of preload reserve and compensatory hypertrophy maintains ejection fraction within the normal range despite elevated after-load, causing many patients to remain asymptomatic throughout the compensatory phase.155,157Eventually, left ventricular compensatory mechanisms fail, and systolic dysfunction ensues. As the disease progresses, preload reserve may become exhausted, the hypertrophic response may become inadequate, and impaired myocardial contractility may develop so that ejection fraction begins to decline.158 Although left ventricular systolic dysfunction related to excessive afterload is reversible early in the course, irrevers-ible damage occurs once chamber enlargement predominates as the primary cause of diminished myocardial contractility.Clinical Manifestations. In cases of acute severe AI, patients are symptomatic and invariably present with compensatory tachycardia, often associated with acute pulmonary congestion and cardiogenic shock.2 Because the left ventricular and aortic pressures often equalize before the end of diastole, the diastolic murmur of AI may be short and/or soft. The reduced systolic pressure may attenuate the increase in peripheral pulse pressure seen in chronic AI, and early closing of the mitral valve due to elevated left ventricular end-diastolic pressures may diminish the intensity of the first heart sound in the acute setting.In patients with chronic AI, symptoms of heart fail-ure and myocardial ischemia develop after the compensatory phase.2 Patients gradually begin to complain of exertional dys-pnea, fatigue, orthopnea, and paroxysmal nocturnal dyspnea, often after significant myocardial dysfunction has developed. Angina is a common complaint late in the course, especially during sleep when heart rate slows and arterial diastolic pres-sure falls. Patients also may experience exertional angina secondary to diminished coronary perfusion in the setting of myocardial hypertrophy. Occasionally, the compensatory tachy-cardia that develops with chronic AI will cause palpitations, and the increased pulse pressure will cause a sensation of pound-ing in the patient’s head. Peripherally, the widened pulse pres-sure causes a forceful, bounding, and quickly collapsing pulse known as Corrigan’s water-hammer pulse. Premature ventricu-lar contractions have been reported to cause particularly trou-bling symptoms, owing to the heave of the volume-loaded left ventricle during the postextrasystolic beat. The classic ausculta-tory finding associated with AI is a high-pitched decrescendo diastolic murmur heard best in the left third intercostal space; an associated S3 gallop is often indicative of late disease. The Austin Flint murmur has also been described, and it is heard as a middiastolic rumble at the apex that simulates mitral stenosis and occurs in severe AI when the regurgitant jet impedes mitral valve leaflet opening.Diagnostic Studies. In the acute setting, TTE should be per-formed to confirm the presence and severity of aortic regurgita-tion, the degree of pulmonary hypertension, and the cause of valvular dysfunction.98 When aortic dissection is suspected as the cause of acute AI, TEE or chest CT angiography may be substituted if more readily available.159,160 In these patients with confirmed aortic dissection, cardiac catheterization and coro-nary angiography are rarely indicated and can delay life-saving urgent surgical intervention.In cases of chronic AI, the ECG frequently demonstrates left axis deviation and, late in the course, intraventricular con-duction defects associated with left ventricular dysfunction. On chest X-ray, the left ventricle enlarges predominantly in an infe-rior and leftward direction, causing marked increase in the long axis diameter of the heart, frequently with little or no change in the transverse diameter. The chest X-ray should be examined for aneurysmal dilation of the aorta.2 An initial TTE should be performed to confirm the diagnosis and severity of AI, assess the cause of AI (including valve morphology and aortic root size and morphology), and assess the degree of left ventricular hypertrophy, volume, and systolic function.98 Follow-up TTE is indicated on an annual or semiannual basis in patients with asymptomatic moderate to severe AI in order to assess changes from baseline parameters and direct the timing of surgery. Any abrupt change in signs or symptoms in a patient with chronic AI is an indication for TTE examination.Additional preoperative studies are indicated in certain patient populations.98 In patients with poor windows on TTE, TEE or MRI is indicated for initial and serial assessment of AI severity and left ventricular volume and function at rest. In symptomatic patients with chronic AI, it is reasonable to pro-ceed directly to TEE or cardiac catheterization if TTE examina-tions are inadequate. Exercise stress testing may be helpful for an assessment of functional capacity and symptomatic responses in patients with equivocal symptoms. Coronary angiography should be performed prior to valve surgery in most patients.98Indications for Operation. Based on the morphology and severity of valve dysfunction (see Table 21-10), AV repair or replacement may be performed for the treatment of AI (see Table 21-11).96 Although the indications for AV repair and AV replacement do not differ, it is recommended that AV repair be performed only in those surgical centers that have developed the appropriate technical expertise, gained experience in patient selection, and which have demonstrated outcomes equivalent to those of valve replacement.Brunicardi_Ch21_p0801-p0852.indd 82701/03/19 5:32 PM 828SPECIFIC CONSIDERATIONSPART IIAortic Valve Operative Techniques and ResultsAortic valve surgery has traditionally been performed through a median sternotomy with the assistance of cardiopulmonary bypass. However, minimally invasive incisions for aortic valve surgery have been introduced, including mini-sternotomy and mini-thoracotomy approaches. After the aorta is cross-clamped, cold blood cardioplegia is delivered antegrade through the aortic root and/or retrograde through the coronary sinus.Aortic Valve Replacement. During aortic valve replacement, an aortotomy is performed, extending medially from approxi-mately 1 to 2 cm above the right coronary artery and inferiorly into the noncoronary sinus. The valve is completely excised. The annulus is thoroughly debrided of calcium deposits. At this point, the annulus is sized and an appropriate prosthesis is selected. Pledgeted horizontal mattress sutures are then placed into the aortic valve annulus and subsequently through the sew-ing ring of the prosthetic valve, taking care to avoid damage to the coronary ostia, the conduction system, and the MV appara-tus. The annular sutures may be placed from below the annulus, seating the valve supra-annularly, or from above the annulus for intra-annular placement (Fig. 21-11).The major components to increased operative risk associ-ated with surgical AVR include age, body surface area, diabetes, renal failure, hypertension, chronic lung disease, peripheral vas-cular disease, neurologic events, infectious endocarditis, previ-ous cardiac surgery, myocardial infarction, cardiogenic shock, NYHA functional status, and pulmonary hypertension. For most patients, the risk of operative mortality associated with AVR is 1% to 5%, and 5-year survival has been reported to be >80%, even in patients >70 years of age.138-161 The choice of valve is dependent on many patient-related factors, and it is accompa-nied by the attendant postoperative risks of decreased durability and thromboembolic vs. hemorrhagic complications for biologi-cal and mechanical valves, respectively.Aortic Valve Repair. Although aortic valve replacement is performed more commonly, AV repair may be recommended at centers of excellence.96For patients with aortoannular ectasia, AI is due to annular dilatation and distortion of the sinotubular junction. For these Figure 21-11. Aortic valve replacement. The stented porcine bio-prosthesis as viewed through an aortotomy.patients, competence of the aortic valve can be achieved by functionally repairing the annulus in a method analogous to homograft implantation. The aneurysmal portion of the aor-tic root is excised, and the aortic valve is reimplanted inside a tubular Dacron graft, with concomitant reimplantation of the coronary arteries. Alternatively, the aneurysmal tissue and supravalvular tissue can be excised in their entirety, with subse-quent implantation of the Dacron graft onto the superior aspect of the annulus and reimplantation of the coronary arteries.Valve-sparing root replacement for root and annular sta-bilization in patients with AI due to aortoannular ectasia has led to a more durable outcome than is seen with subcommis-sural annuloplasty or leaflet-related procedures alone. One study demonstrated equivalent overall survival between patients undergoing subcommissural annuloplasty or aortic valve repair without annuloplasty and patients undergoing valve-sparing root replacement at 6 years.162 However, patients who under-went valve-sparing root replacement had higher freedom from reoperation and aortic insufficiency >2+ (100% vs. 90%, P = 0.03; and 100% vs. 77%, P = 0.002, respectively) at midterm follow-up.162For patients with AI associated with redundant leaflet tis-sue, aortic valve repair may be accomplished with free margin plication or resuspension of the valve cusps, with or without triangular resection of the redundant segment. Excision of the diseased portion of the involved valve cusp improves symme-try of the valve leaflets, and annular plication of one or both commissures helps to ensure adequate coaptation. Generally, the free margins of the excised leaflets are reapproximated pri-marily, but in the absence of adequate cusp tissue, a triangular autologous or bovine pericardial patch may be used for cusp restoration.AV cusp repair with a free margin plication or resuspen-sion technique has demonstrated encouraging results in expert centers, both in patients with tricuspid and bicuspid aortic valves. Freedom from AV reoperation in patients with a tricus-pid AV has been reported to be 89% to 92% at 10 years, with a freedom from recurrent AI >2+ of 80% to 86% at the same time point. In patients with bicuspid aortic valves, who gener-ally represent a younger cohort of patients, 10-year survival has been reported at 94% following AV repair, with a freedom from AV reoperation of 81% at the same time point.163Ross Procedure. As mentioned previously, the Ross procedure involves replacing the diseased AV with the patient’s native pulmonary valve as an autograft, which is in turn replaced with a homograft in the pulmonic position.112 The autograft may be implanted in the aortic position directly with resuspension of the valve commissures, or in association with a root replacement, which requires reimplantation of the coronary ostia.The cylinder root replacement technique is most reproduc-ible and involves transecting the native aorta approximately 5 mm above the sinotubular ridge, with subsequent excision of the aortic valve leaflets and supra-annular tissue. The main pulmonary artery is transected at the bifurcation, and the right ventricular outflow tract is incised, allowing the pulmonary valve and artery to be removed en bloc from the outflow tract. The annulus of the pulmonary autograft is sewn to the native aortic annulus with continuous or interrupted sutures, and the coronary ostia are reimplanted into the pulmonary artery graft. The pulmonary valve and right ventricular outflow tract are subsequently reconstructed using an aortic homograft.Brunicardi_Ch21_p0801-p0852.indd 82801/03/19 5:32 PM 829ACQUIRED HEART DISEASECHAPTER 21The primary benefit of the Ross procedure compared to traditional AV surgery is a low risk of thromboembolism with-out the need for systemic anticoagulation. Although patients undergoing the Ross procedure are generally younger, periop-erative mortality has been reported to be as low as 2.5% in this group, with an overall survival of 90% at 18-year follow-up.164 However, the long-term durability of the procedure is somewhat questionable. Although Ross reported a freedom from autograft replacement of 75% at 20 years, other groups have reported freedom from autograft reoperation and allograft reinterven-tion of 51% and 82%, respectively, at 18-year follow-up.164,165 Progressive aortic insufficiency has been described as a cause of late failure in these patients, as well as calcification of the pulmonary homograft and pulmonary stenosis.Transcatheter Aortic Valve Replacement. Transcatheter aortic valve replacement (TAVR) has proven beneficial for the treatment of AS in patients who are either moderate or high-risk candidates for conventional surgery. TAVR is now indicated for patients with severe AS with a STS score predicted risk of mortality of greater than or equal to 3%.152 Clinical trials in the low-risk population are currently underway.There are two types of transcatheter valves that are approved for commercial use: a balloon-expandable valve (Edwards) and a self-expandable valve (CoreValve). A trans-catheter valve may be inserted via the femoral artery, the left subclavian artery, the ascending thoracic aorta via an upper mini-sternotomy, or LV apex via a small left anterior thoracot-omy. By far the most common route is transfemoral, making up the majority of TAVR in most centers. The principle of valves placed via these routes are to place the aortic prosthesis inside the patient’s native aortic valve. Rigorous preoperative plan-ning is needed to ensure adequate sizing of the valve as well as placement to ensure there is no risk of coronary occlusion or malalignment of the valve.A series of large, multicenter clinical trials have been per-formed investigating the role and safety of TAVR in patients with severe aortic stenosis requiring surgical treatment. The PARTNER I trial looked at mortality rate as the primary endpoint in patients with severe aortic stenosis who were not suitable can-didates for surgery (high-risk patients).166 TAVR, as compared with standard surgical treatment (SAVR), significantly reduced the rates of death from any cause (30.7% vs. 50.7%, at 1 year, P <0.001), the composite endpoint of death from any cause or repeat hospitalization (42.5% vs. 71.6%, P <0.001), and cardiac symptoms (25.2% vs. 58.0%, P <0.001), despite the higher inci-dence of major strokes (5.0% vs. 1.1%, P = 0.06) and major vas-cular events (16.2% vs. 1.1%, P <0.001).166 In the PARTNER II trial, 2032 intermediate-risk patients with severe aortic stenosis were randomly assigned to undergo either TAVR or SAVR.167 It was found that in intermediate-risk patients, TAVR was simi-lar to SAVR with respect to the primary end point of death or disabling stroke (P = 0.001 for noninferiority). TAVR resulted in larger aortic valve areas than did surgery and also resulted in lower rates of acute kidney injury, severe bleeding, and new-onset atrial fibrillation; surgery resulted in fewer major vascu-lar complications and less paravalvular aortic regurgitation.167 Similarly, the Surgical or Transcatheter Aortic-Valve Replace-ment in Intermediate-Risk patients trial (SURTAVI) evaluated the clinical outcomes in intermediate-risk patients with severe, symptomatic aortic stenosis in a randomized trial comparing TAVR (performed with the use of a self-expanding prosthesis) 5with surgical aortic-valve replacement.168 TAVR was found to be a noninferior (i.e., similar composite endpoint of death from any cause or disabling stroke at 24 months) alternative to surgery in patients with severe aortic stenosis at intermediate surgical risk, with a different pattern of adverse events associ-ated with each procedure. Surgery was associated with higher rates of acute kidney injury, atrial fibrillation, and transfusion requirements, whereas TAVR had higher rates of residual aor-tic regurgitation and need for pacemaker implantation.168 The PARTNER III trial, currently under investigation, is designed to establish the safety and effectiveness of TAVR in patients with severe, calcific aortic stenosis who are at low operative risk for standard surgical aortic valve replacement (SAVR). Ongoing trials will continue to define the roles for SAVR and TAVR in the future.TRICUSPID VALVE DISEASETricuspid Stenosis and InsufficiencyEtiology. Acquired tricuspid valve (TV) disease can be clas-sified as either organic or functional and affects approximately 0.8% of the general population.169 Tricuspid stenosis (TS) is almost always a result of rheumatic heart disease or rarely endo-carditis. In the case of rheumatic disease, tricuspid stenosis with or without associated insufficiency is invariably associated with mitral valve disease. Other less common causes of obstruction to right atrial emptying include congenital tricuspid atresia, right atrial tumors, and endomyocardial fibrosis.Tricuspid insufficiency (TR), on the other hand, is most often a functional disease caused by secondary dilation of the tricuspid annulus due to pulmonary hypertension and/or right heart failure. This is most commonly caused by MV disease. Conditions such as right ventricular infarction and pulmonic stenosis can also lead to increased right ventricular pressures and functional TR. The less common causes of organic TR, with or without associated stenosis, include endocarditis, carcinoid syndrome, radiation therapy, trauma such as repeated endomyo-cardial biopsy, and Marfan syndrome.Pathology. The changes associated with TS closely resemble those associated with MS, including fusion of the commissures.169 In the case of rheumatic disease, mixed TS and TR may result from fusion and shortening of the chordae tendineae, and fusion of the commissures, causing retraction of the valve leaflets. The right atrium is frequently dilated and thickened in chronic TS, and chronic obstruction to right ventricular filling often produces signs of systemic venous congestion such as hepatomegaly and splenomegaly.2In most cases of TR, dilation and deformation of the tri-cuspid annulus is the most prominent feature; the valve leaflets oftentimes appear stretched but are otherwise pliable and nor-mal in appearance.2 When TR is caused by carcinoid syndrome, white fibrous carcinoid plaques are found on the ventricular sur-faces of the TV, causing the cusps to adhere to the underlying right ventricular wall and stenting the valve open.2Pathophysiology. The basic pathophysiologic abnormality of both TS and severe TR is elevated right atrial pressure, produc-ing systemic congestion and right heart failure. Severe TS is marked by a valve area <1.0 cm2, and severe TR is defined as a vena contracta width of >0.7 cm in combination with sys-tolic flow reversal in the hepatic veins.98 However, in patients with TS, a diastolic pressure gradient of only 5 mmHg, or a TV Brunicardi_Ch21_p0801-p0852.indd 82901/03/19 5:32 PM 830SPECIFIC CONSIDERATIONSPART IITable 21-12Data from ACC/AHA guidelines for TV surgery in specific clinical contextsCLINICAL SETTINGCLASS OF RECOMMENDATIONLEVEL OF EVIDENCESurgery for Tricuspid Valve Disease• TVr for severe TI in patients with MV disease requiring MV surgeryIB• TVR or annuloplasty for severe symptomatic primary TIIIaC• TVR for severe TI secondary to diseased/abnormal TV leaflets not amenable to annuloplasty or TVrIIaC• Annuloplasty for less than severe TI in patients undergoing MV surgery in the setting of1) Pulmonary hypertension2) Tricuspid annular dilatationIIbC• TVR or annuloplasty is not indicated in asymptomatic patients with TI, a normal MV, and a PASP <60 mmHgIII – HarmC• TVR or annuloplasty is not indicated in patients with mild primary TIIII – HarmCMV = mitral valve; PASP = pulmonary artery systolic pressure; TI = tricuspid insufficiency; TV = tricuspid valve; TVr = tricuspid valve repair; TVR = tricuspid valve replacement.orifice <1.5 cm2, is frequently enough to cause jugular venous distention, organomegaly, and peripheral edema. In severe cases, cardiac output is compromised, especially during exercise when the fixed obstruction prevents an increase in forward flow. Patients with severe insufficiency and pulmonary hypertension experience similar hemodynamic derangements.Clinical Manifestations. Patients with TS and severe TR develop symptoms of right heart failure associated with chroni-cally elevated right atrial pressures.2 The classic clinical signs and symptoms of TS and severe TR are jugular venous disten-tion, hepatomegaly, splenomegaly, ascites, and lower extremity edema. Uncomfortable fluttering in the neck has been reported in patients with TV disease, and sensations of throbbing in the eyeballs and pulsatile varicose veins have been reported to occur, especially in patients with severe TR.The low cardiac output syndrome occasionally associated with TS and severe TR can cause fatigue, weakness, and exer-cise intolerance in these patients. In the absence of pulmonary hypertension, dyspnea is not a prominent feature of tricuspid disease. The auscultatory findings associated with TS include a presystolic and middiastolic murmur characterized by a tri-cuspid opening snap that increases on inspiration. The lower left parasternal murmur of TR may be holosystolic or less than holosystolic, depending on the degree of regurgitation, may be associated with a middiastolic murmur in severe cases, and may increase on inspiration.Diagnostic Studies. In patients with TV disease, chest X-ray frequently demonstrates enlargement of the right atrium and ventricle. Patients with TS demonstrate an exaggerated a wave and a diminished rate of y descent in the jugular venous pulse, while patients with TR have abnormal systolic c and v waves.2 TTE examination should be performed in patients with TV disease in order to characterize the structure and motion of the TV, the size of the tricuspid annulus, and other cardiac abnormalities that may affect TV function.98 In patients with a pulmonary artery systolic pressure >55 mmHg, TI commonly occurs in the setting of structurally normal valves; however, structural derangement of the TV apparatus is frequently present if TR is documented with a pulmonary artery systolic pressure <40 mmHg. Doppler TTE allows estimations of the severity of TR, the right ventricular systolic pressure, and the TV diastolic gradient.Indications for Operation. As an isolated lesion, mild or moderate TV disease does not require surgical correction. How-ever, patients with severe TV disease should be considered for surgical intervention, especially in the setting of right ventricu-lar enlargement and impaired systolic function, as this improves life expectancy and the development of sequelae such as heart failure and atrial fibrillation.169 Depending on the patient’s clini-cal status and the cause of TV dysfunction, TV repair and TV replacement be variably recommended for the treatment of TV dysfunction (Table 21-12).98 In patients with TR, the valve can usually be repaired with modern techniques.Operative Techniques and Results. The TV can be approached through a median sternotomy, a right thoracotomy, or port-based techniques. Surgery is performed with the assis-tance of cardiopulmonary bypass and, though TV surgery is usually performed on the beating heart, a brief period of car-dioplegic arrest may be rarely needed to allow for complete inspection of the interatrial septum and to close any defects that may be present.TV repair may include a suture or ring annuloplasty as well as valvuloplasty, and multiple methods have been described.169 Historically, bicuspidization of the TV was accomplished by a figure-of-eight suture plication of the annulus of the posterior leaflet; however, this technique has been essentially replaced by suture or ring annuloplasty. Suture annuloplasty is gener-ally performed by placing pledgeted sutures along the base of the anterior and posterior leaflets, partially encircling the annulus. Ring annuloplasty can be accomplished by suturing the TV annulus to a variety of rigid or semirigid annuloplasty rings, which generally have an opening at the level of the anterosep-tal commissure to avoid passing the anchoring sutures near to the conduction system. Most surgeons favor ring over suture annuloplasty. In severe annular dilatation, augmentation of the anterior leaflet with autologous pericardium has been used with some success. Tricuspid valvuloplasty is infrequently performed and may include commissurotomy, triangular leaflet resection, Brunicardi_Ch21_p0801-p0852.indd 83001/03/19 5:32 PM 831ACQUIRED HEART DISEASECHAPTER 21primary perforation repair, and traditional leaflet repair tech-niques such as chordal transfer, shortening, and replacement, papillary muscle plication, tricuspid leaflet augmentation, and the edge-to-edge repair technique used in MV prolapse.For patients with functional TV disease, TV repair is gen-erally preferred to replacement due to favorable results without the associated risks of thrombosis and the need for anticoagu-lation. In the setting of concomitant mitral valve surgery, TV repair has not been associated with additional perioperative complications, and 5-year freedom from reoperation has been impressive at 98%. However, a subgroup of patients report late failure following TV repair, and this may be worse following suture annuloplasty compared with ring annuloplasty.117Prosthetic valve replacement may be necessary due to extensive leaflet destruction, as may be seen in patients with endocarditis, or marked annular dilatation not amenable to repair. In some cases, the valve prosthesis may be anchored directly to the leaflet tissue instead of the valve annulus, reduc-ing the risk of injury to the conduction system.169 If this tech-nique is used, it should be confirmed that the residual tissue does not interfere with the movement of the prosthetic leaflets after implantation. Pledgeted sutures should be used and may be placed on the ventricular or atrial side of the annulus.Outcomes data following TV replacement are difficult to interpret, as most reports are in patients with previous TV surgery and/or signs of severe right heart failure. Operative mortality has been >20% in some studies.169 One study of 87 patients undergoing TV replacement between 1994 and 2007 showed an in-hospital mortality of only 1.4%. The choice of prosthetic valve is also somewhat controversial. Though bio-prosthetic valves are more durable in the tricuspid than mitral or aortic positions, valve degeneration is an important cause of bioprosthetic valve dysfunction at reoperation. The ability to replace a degenerated tricuspid valve bioprosthesis with a trans-catheter valve has led some surgeons to favor biological valves in this position. This is particularly true since the increased risk of valve thrombosis seen with mechanical valves mandates rig-orous systemic anticoagulation. Even with these precautions, mechanical tricuspid valves are associated with an increased risk of hemorrhagic and thrombotic complications. The choice of valve is usually decided on a case-by-case basis, and late out-comes have been similar with biological and mechanical valves in this position. In general, TV replacement may be a reasonable choice in select patients, though more data are needed regarding long-term outcomes in the modern era.Multivalve DiseasePathology involving multiple valves is relatively common and may result from diseases such as rheumatic fever, calcific dis-ease, Marfan syndrome, and other connective tissue disorders. However, multivalve disease may also be caused by secondary valvular dysfunction due to a distal valvular lesion, as in the case of myxomatous degeneration of the mitral valve, resulting in pulmonary hypertension, dilation of the tricuspid annulus, and functional TR. If the primary pathology is corrected early in the disease course, these secondary functional changes may resolve without the need for intervention.In patients with multivalve disease, the clinical manifesta-tions may be dependent on the severity of each individual valve lesion, but this is not always the case.2 In patients with con-comitant mitral and tricuspid dysfunction, the prominent symp-toms of dyspnea, paroxysmal nocturnal dyspnea, and orthopnea commonly associated with MV dysfunction are sometimes diminished by associated TV dysfunction. Symptoms of multi-valve disease are most commonly masked when valvular abnor-malities are of approximately equal severity, highlighting the importance of careful examination of each valve both preopera-tively and in the operating room.Surgery for multivalve disease is associated with a higher perioperative mortality than single-valve procedures, and this risk is exacerbated by factors such as pulmonary artery hyper-tension, age, triple-valve procedures, concomitant coronary artery bypass grafting, previous heart surgery, renal insuffi-ciency, and diabetes.170 Failing to recognize significant con-comitant valvular dysfunction at the time of surgery is also associated with higher perioperative mortality. For this reason, patients suspected of having multivalve involvement should undergo full preoperative Doppler TTE or TEE evaluation and heart catheterization.98 In selected patients, procedures correcting multivalve disease demonstrate significant clinical improvement in symptoms and quality of life, as well as accept-able mortality and survival rates.170SURGICAL THERAPY FOR THE FAILING HEARTEpidemiology of Heart FailureHeart failure affects approximately 5 million patients in the United States, with >550,000 new cases diagnosed annually.171 The disorder is the primary reason for 12 to 15 million office visits and >1 million hospitalizations each year. Overall 1-year mortality is estimated to be around 25%, but this can increase to as high as 75% for patients with more advanced heart failure (NYHA class IV).172 While heart transplantation remains the gold standard for the treatment of end stage disease, an increas-ing number of patients deteriorate while on the waiting list, and up to 30% die before transplantation.173 The total direct and indirect costs associated with the treatment of heart failure are estimated to be $32 billion, and this is projected to increase to $70 billion by 2030.174 Advances in the surgical management of heart failure over the two decades have pushed surgery for CHF into the mainstream. As a result, there is an increasing number of patients with lateor end-stage disease who are being consid-ered for surgical therapies.Etiology and PathophysiologyHeart failure can be classified as acute or chronic, genetic or acquired, left-sided and/or right-sided, and systolic and/or diastolic dysfunction. The underlying causes and treatments for each of these vary considerably. In the Framingham Heart Study, coronary artery disease accounted for 67% of heart fail-ure cases, valvular heart disease accounted for 10%, and 20% of cases were attributable to primary myocardial diseases, of which dilated cardiomyopathy predominated.175 In all cases, heart failure is a progressive disorder that through complex mechanisms of ventricular remodeling, altered hemodynamics, neurohumoral activation, cytokine overexpression, and vascu-lar and endothelial dysfunction either disrupts the ability of the myocardium to generate force or results in a loss of function-ing cardiac myocytes, thereby preventing normal myocardial contraction.CABG for Ischemic CardiomyopathySurgical coronary revascularization is among the most com-monly performed procedures for CHF. CABG is beneficial as it protects from further myocardial infarction and/or malignant Brunicardi_Ch21_p0801-p0852.indd 83101/03/19 5:32 PM 832SPECIFIC CONSIDERATIONSPART IIventricular arrhythmias. It is most successful when treating hibernating as opposed to infarcted myocardium.While the majority of evidence supporting CABG for patients with ischemic cardiomyopathy comes from nonran-domized, retrospective studies, the prospective, randomized, multicenter international Surgical Treatment of Ischemic Heart Failure (STICH) trial compared CABG with medical therapy to medical therapy alone. Entry criteria included an EF ≤35% with CAD and anatomy suitable for CABG. No significant difference was seen in overall mortality by study completion, but patients who underwent CABG did have fewer deaths or hospitalizations from cardiovascular causes (58% vs. 68%, P <0.001).176,177Myocardial viability testing has been shown by multiple studies to be pivotal in identifying patients that will have improved outcomes following CABG for ischemic cardiomyopathy.178,179 A meta-analysis performed by Allman et al demonstrated an 80% reduction in mortality in patients who underwent revas-cularization with viable myocardium compared to patients who received medical therapy alone (3.2% vs. 16%, P <0.0001). Most importantly, in this analysis, CABG had no benefit over medical therapy for patients without viable myocardium. A more recent study by Gerber et al prospectively compared CABG and medical therapy to medical therapy alone in 114 patients with CAD and low EF (24% ± 8%) who underwent viability testing using delayed-enhancement cardiac MRI.180 This study demon-strated worse 3-year survival in medically treated patients with dysfunctional but viable myocardium than in medically treated patients with nonviable myocardium (48% vs. 77%, P = 0.02). This corresponded with a 4.56 times increased hazard of death when medical treatment was selected over full revasculariza-tion. In contrast, survival after CABG was not significantly different whether myocardium was viable or not (88% vs. 71%, P = NS). These studies underscore both the importance of viable myocardium as well as the adverse consequences of not offering a patient with viability surgical intervention.Patients with ischemic cardiomyopathy are a heterogeneous group, and, as with any surgery, appropriate patient selection is central to success. In one retrospective study of 96 patients with ischemic cardiomyopathy (EF ≤25%), age and poor distal vessel quality were predictors of poor outcomes.181 Mortality in patients with poor vessel quality was 100%, compared with 90% when vessel quality was fair and 10% when it was good. Therefore, poor vessel quality should be considered a contraindication to surgical revascularization even in the presence of angina.LV size and LV dyssynchrony are also risk factors for adverse shortand intermediate-term outcomes. A LV end-diastolic dimension of >100 mL/m2 is associated with a signifi-cantly reduced 5-year survival following CABG (85% vs. 53%, P <0.05), as well as worse 5-year freedom from recurrent CHF (85% vs. 31%).182 Moreover, LV dyssynchrony has been shown to have a significant impact on mortality in patients undergo-ing moderateto high-risk revascularization and may compound risk in patients with nonviable myocardium.183 In patients with severe preoperative LV dyssynchrony, the 30-day mortality was 27% vs. 3% in patients without significant dyssynchrony (P <0.001). Similar differences were seen with the presence of postoperative LV dyssynchrony, and outcomes were worse when patients also had fewer segments of viable myocardium.Secondary Mitral RegurgitationSecondary mitral regurgitation describes MR that results from damage to the left ventricle as a result of either ischemia or dilated cardiomyopathy rather than from a problem with the valve itself.184 Ischemic MR (IMR) typically results from sys-tolic restriction of the mitral leaflets due to tethering of the subvalvular apparatus. This occurs mainly from regional wall motion abnormalities in areas of the LV adjacent to papillary muscle attachments. Alterations in the size and shape of the mitral annulus and posterior displacement of the posteromedial papillary muscle, which occurs primarily after an inferoposterior MI, may also contribute. Additionally, functional MR (FMR) is caused by LV dilatation and increased sphericity, which displace the papillary muscles apically and radially, creating lateral forces on the valve that lead to increased retraction of the mitral leaflets by the chordae tendineae. LV dyssynchrony may also contribute to FMR through poor coordination of the contraction of the septum and lateral walls, producing MR that may vary in intensity during the cardiac cycle. Functional MR is usually referred to as a Carpentier class I/IIIb lesion due to the presence of both annular dilatation (Carpentier type I) and systolic restriction of the mitral leaflets due to LV dysfunction (Carpentier type IIIb). Ultimately, increased regurgitation leads to increased preload, LV wall tension, and LV work load, all of which contribute to progressive dysfunction of the LV and worsening heart failure.Several observational and population-based studies have demonstrated a significant impact of secondary MR on long-term survival. Following MI, the 5-year survival rate dropped significantly from 61% in patients who did not have MR to 47% and 29% in patients with mild and moderate to severe MR, respectively.185 Similarly, in a series of 2057 patients with symptomatic heart failure and an LVEF <40%, the 5-year sur-vival rate for patients without MR was 54%, and it decreased to 40% in patients with moderate to severe secondary MR.186 Moreover, medical therapy and PCI have not reduced the impact of IMR on late mortality.187Although specific recommendations to intervene for secondary MR are controversial and have not been rigorously defined, guidelines are available (Table 21-13).96,188 Some sur-geons initially advocated performing only revascularization in cases of moderate ischemic MR with the idea that revasculariz-ing viable myocardium would lead to improvements in LV func-tion and effect reverse remodeling, ultimately contributing to a decrease in MR. While several studies, including a recent large, multicenter, randomized, controlled trial, have shown that MR often persists following revascularization alone, the addition of a mitral valve annuloplasty in those studies did not improve long-term functional status or survival in patients with isch-emic MR.189-192 Nevertheless, other studies have shown that the persistence of MR after CABG is associated with a decreased survival rate and that CABG alone only has modest effects on reducing MR at 1 month follow-up.184 As a result, some centers continue to repair moderate MR in this patient population. Indi-cations for surgery in ischemic MR patients in the absence of revascularization options are even less well defined.For patients with functional MR, the goal of mitral valve surgery is to avoid or postpone transplantation in eligible patients. Mitral valve repair has been considered the procedure of choice when surgery is indicated for secondary MR. How-ever, in patients with severe ischemic MR, a recent randomized, multicenter trial showed improved late freedom from moderate or severe recurrent MR with mitral valve replacement compared to repair (2.3% vs. 32.6%, P <0.001).141 There was not a signifi-cantly higher mortality in the replacement group in this study.141 Brunicardi_Ch21_p0801-p0852.indd 83201/03/19 5:32 PM 833ACQUIRED HEART DISEASECHAPTER 21Table 21-13Data guidelines for surgical intervention for secondary mitral regurgitationCLINICAL SETTINGCLASS OF RECOMMENDATIONLEVEL OF EVIDENCEChronic Ischemic MR (ESC Guidelines)• Severe MR, LVEF >30%, undergoing CABGIC• Moderate MR, undergoing CABG, if mitral repair is feasibleIIaC• Severe MR, symptomatic patients, LVEF <30%, candidate for revascularizationIIaC• Severe MR, LVEF >30%, no option for revascularization, refractory to optimal medical therapy, low comorbidityIIbCChronic Functional MR (ESC and ACC/AHA Guidelines)• Chronic severe MR due to LV dysfunction, EF <30%, persistent NYHA class III-IV, symptoms despite optimal medical therapyIIbCMR = mitral regurgitation; ESC = European Society of Cardiology; CABG = coronary artery bypass grafting; LVEF = left ventricular ejection fraction; LV = left ventricle; ACC = American College of Cardiology; AHA = American Heart Association; NYHA = New York Heart Association.In patients with poor LV function, dilated LV, and severe MR with significant leaflet tethering, we favor MV replacement with preservation of the subvalvular apparatus. Bioprosthetic valve is usually used due to the poor late survival in this group of patients. Currently, for patients undergoing repair recom-mendations are to use a semirigid or rigid annuloplasty ring to downsize the mitral annulus.184 There have also been various techniques proposed to correct the papillary muscle displace-ment, but most reports are single center, retrospective, and small. Mitral valve replacement with preservation of the sub-valvular apparatus is indicated when repair is not feasible due to severe tethering of the leaflets or massive LV dilation.Outcomes from surgery vary among centers and among patients in this heterogeneous group. Operative mortality ranges between 0% and 9% in most modern series.184 Generally speak-ing, mortality and recurrence rates are higher and long-term prognosis is worse compared to outcomes for primary MR. Recurrent MR is as high as 15% to 30% in some series, and 5-year mortality is between 44% and 48%.184,193,194 Some reduc-tions in left atrial dimension and LV reverse remodeling may be achieved.195Left Ventricular Aneurysmorrhaphy and Surgical Ventricular RestorationPathophysiology of Ventricular Aneurysms. A transmural infarction of approximately 5% to 10% of the myocardium may result in formation of an LV aneurysm as necrotic myocardium is replaced by fibrous tissue. This usually occurs 4 to 8 weeks following the infarct. In the last decade, prompt revasculariza-tion of the culprit artery by either surgical or interventional tech-niques generally results in sparing of the subepicardial muscle while the subendocardial muscle remains necrotic.196 There-fore, it is not uncommon for the LV wall to show both living myocardium during thallium testing and an akinetic zone on echocardiogram or angiogram. It has been demonstrated that once more than 20% of the myocardium is necrosed there is irreversible progression to ventricular dilation and failure.197 Once heart failure develops after postinfarction remodeling, the 1-year mortality reaches 32% despite current therapies.198 The classic aneurysm is a 4 to 6 mm thick scar, which bulges out-ward in paradoxical motion as the LV contracts during systole. More than 80% develop in the anteroseptal and apical portions of the left ventricle as a result of left anterior descending artery occlusion. The rest are inferior in location and the result of cir-cumflex or right coronary occlusion.This patient population typically suffers from associated ventricular arrhythmias for several reasons. First, electrical dys-synchrony results from postinfarction remodeling, and triggers for ventricular arrhythmias typically occur in the scar border zone in patients with ischemic cardiomyopathy.199,200 Second, increased ventricular volume causes high wall stress and stretch, and stretch has been shown to be arrhythmogenic.201 Third, LV aneurysms represent an independent risk factor for SCD after MI.202 Surgical ventricular restoration (SVR) addresses each of these issues by removing the anatomic substrate during resection of the postinfarct scar and/or aneurysm, accomplishing volume reduction and mechanical resynchronization and relieving ischemia through complete revascularization and reduction in myocardial wall tension and oxygen demand.Clinical Presentation and Diagnosis. Symptoms of LV aneurysms include angina, CHF, ventricular arrhythmias, and, rarely, embolic phenomenon. Rupture is extremely uncommon. Patients generally present for coronary artery bypass or during evaluation of CHF or arrhythmias. While transthoracic echo-cardiography gives pertinent information regarding LV func-tion, size, mitral valve function, and the presence of thrombus, it is generally accepted that cardiac MRI is the best diagnostic modality to accurately identify areas of scar and viable tissue and to best define ventricular geometry.197Surgical Treatment and Results. In 1985, Vincent Dor described a surgical technique called the endoventricular cir-cular patch plasty that was intended to improve geometric reconstruction compared with the standard linear repair in LV aneurysm surgery. SVR is a somewhat broader term that arose from surgical repair of ventricular aneurysms and has now come to be applied to a group of surgical procedures designed to correct the effects of postinfarction ventricular remodeling. It is also sometimes referred to as surgical ventricular remodel-ing or reconstruction, surgical anterior ventricular endocardial reconstruction (SAVER), or the Dor procedure. SVR is specifi-cally intended to reduce the size and sphericity of the LV by Brunicardi_Ch21_p0801-p0852.indd 83301/03/19 5:32 PM 834SPECIFIC CONSIDERATIONSPART IIexcluding akinetic and dyskinetic areas, most often by using a circular patch inserted inside the ventricle on contractile myo-cardium (Fig. 21-12A,B).Candidates for SVR are typically patients who have had a remote anterior or anteroseptal myocardial infarction, signifi-cant ventricular enlargement with a significant area of akinetic or dyskinetic myocardium, a discrete aneurysm, a clinical pic-ture consistent with heart failure (LVEF <40%), retained func-tion of the basilar and lateral portions of the heart, and good right ventricular function. These patients should also be candi-dates for repair of any other concomitant cardiac disease. Dor currently emphasizes the importance of complete revasculariza-tion and repair of any mitral pathology at the time of operative SVR. In patients with spontaneous (13%) or inducible (25%) ventricular tachycardia (VT), it is additionally necessary to per-form nonguided endocardial resection and cryoablation encir-cling the resected area.197Results with this approach have been good in treating both heart failure and its sequelae, such as VT. In Dor’s series of 1150 patients, the operative mortality varied based on the LVEF, ranging from 1% (patients with EF >40%) to 13% (patients with EF <30%), and the 5-year survival approached 85%.197 Overall, more than 80% of survivors either stabilized or improved, and the quality of life was shown to improve significantly by 6 months after the Dor procedure.203 This is likely due in part to the fact that the Dor procedure restores LV geometry, resulting in a mean ejection fraction increase between 10% and 15%, with significant alleviation of symptoms.197,204-206 These data are rein-forced by the international RESTORE group, which examined SVR in a registry of 1198 postinfarction patients between 1998 and 2003.207 They found that 5-year overall freedom from hos-pital readmission for CHF was 78%. Moreover, 67% of patients had preoperative NYHA class III or IV symptoms, whereas 85% of patients were NYHA functional class I or II postoperatively.With respect to VT, Dor et al reported on 106 patients with ischemic ventricular arrhythmias that underwent recon-struction for postinfarction LV aneurysm and visually directed endocardiectomy plus or minus cryoablation and coronary revascularization.208 At a mean follow-up of 21.3 months, only 10.8% of patients had inducible VT, and no spontaneous VT was documented. Results from similar series have also been excellent,197,206,209 but the efficacy of left ventricular restoration alone has been controversial.210,211 Inferior results seen in some Figure 21-12. Surgical ventricular restoration of a ventricular aneurysm using the Dor procedure. A. The size and sphericity of the left ventricle are reduced by excluding akinetic and dyskinetic areas. B. Most often this is completed using a circular patch inserted inside the ventricle on contractile myocardium.series have been attributed to failure to perform endocardial resection and/or cryoablation at the border of the transitional zone, as well as differences in stimulation protocols and pos-sible inadequate volume reduction of the ventricle.A large, randomized, multicenter study, the STICH trial, concluded that adding SVR to reduce ventricular volume to CABG does not improve symptoms or exercise tolerance and fails to lower death rate or cardiac rehospitalization compared to CABG alone.176 While this trial has some shortcomings, it has resulted in a marked decrease in referrals for this procedure. The main problem is that the LV volume was reduced by only 19% in the STICH trial, reflecting an inadequate repair as determined by the Surgery Therapy Committee, whose “acceptable STICH procedure” guideline required a 30% reduction at the 4-month postoperative cardiac MRI.212 Previous studies have reported an average reduction of end-systolic volume index (ESVI) of 40% with a range between 30% and 58%, suggesting that the STICH SVR procedure may have involved an inadequately small LV plication or limited intracavitary reconstruction.212 Moreover, this trial enrolled 13% of patients who had never had an MI and changed criteria such that enrollment required documented LV anterior wall dysfunction rather than demonstration of scar. This could have captured patients with hibernating myocardium that would recover following CABG alone. Dor subsequently pub-lished the results of 117 patients who would have been eligible for the STICH trial and demonstrated durable improvement in left ventricular function.213 However, this was a single-center, retrospective experience. Caution should be exercised so as not to broadly extrapolate the results of the STICH trial and inap-propriately deny appropriate patients effective treatment. This remains an area of controversy.With the recent advances in percutaneous interventions, the Parachute device has been trialed in human subjects. It is composed of a self-expanding nitinol frame covered with an impermeable fluoropolymer that is deployed into the LV apex walling off akinetic or dyskinetic segments of the LV. The PARACHUTE trial reported 3-year echocardiographic and clinical outcomes of patients with ischemic heart failure who underwent placement of the Parachute device as a feasibility and safety study. They demonstrated that of the 31 patients who received the device, there was improvement or maintenance of NYHA functional class in 85% as well as significant reduction of the LV EDV index.198Brunicardi_Ch21_p0801-p0852.indd 83401/03/19 5:32 PM 835ACQUIRED HEART DISEASECHAPTER 21Mechanical Circulatory SupportIntra-Aortic Balloon Pump. The intra-aortic balloon pump (IABP) is a commonly used device for mechanical circulatory support and has been in use since 1968. The device is inserted percutaneously through a peripheral artery into the thoracic aorta. The balloon is synchronized so that it inflates during dias-tole and deflates during systole, resulting in augmentation of diastolic perfusion of the coronary arteries and decreased after-load. Typically, this improves cardiac index and decreases both preload and myocardial oxygen consumption.Common indications for use of an IABP is cardiogenic shock during or following cardiac catheterization or cardiac sur-gery. It also is utilized for preoperative stabilization of high-risk patients with either severe coronary artery disease, LV dysfunc-tion, or refractory, unstable angina. Kang et al have reported that risk-adjusted mortality was significantly lower for selected high-risk patients undergoing open heart surgery when a pre-operative IABP was used.214 In 2012, Thiele et al reported their data following a randomized, prospective, multicenter clinical trial looking at the outcome of using intra-aortic balloon pump in the treatment of cardiogenic shock complicating acute myo-cardial infarction in patients who underwent early revasculariza-tion (by means of percutaneous coronary intervention or bypass surgery) (IABP-SHOCK II trial).215 IABP did not significantly reduce 30-day mortality in this group of patients. Addition-ally, they reported no significant differences in secondary end points, including the time to hemodynamic stabilization, the length of stay in the intensive care unit, serum lactate levels, the dose and duration of catecholamine therapy, renal function, and major complications including major bleeding and peripheral ischemia.215Generally, an IABP is used for a few days and the amount of support is weaned as the patient’s condition improves. Mor-bidity associated with device use is typically minimal; however, in one series of 911 patients undergoing CABG who received an IABP, there was a 12% incidence of minor or major vascu-lar complications, including an approximately 3% incidence of limb ischemia requiring thromboembolectomy. This is the most serious complication of IABP placement. To prevent this prob-lem, frequent lower extremity neurovascular checks are neces-sary while an IABP is in place.216Ventricular Assist Device Indications and Cannulation.  Patients in need of ventricular assist devices (VADs) may have preexisting chronic heart failure, refractory ventricular arrhythmias, or acute heart failure following an MI, cardiopul-monary arrest, viral illness, pregnancy, or cardiotomy. Device therapy is intended to preserve end-organ perfusion and func-tion and may be categorized as shortor long-term support for the left heart, the right heart, or both. In general, VADs may be used rarely for support while the heart recovers (bridge to recovery, BTR), while the patient waits for a heart transplant (bridge to transplant, BTT) or increasingly more commonly to treat a chronic heart failure patient who is not a transplant candidate (destination therapy, DT). The Interagency Registry for Mechanically Assisted Circulatory Support (INTERMACS) database, a joint effort by the NHLBI, FDA, CMS, academia, and industry to prospectively track patient outcomes, reported that in 2015 and 2016 indications for device implantation were BTR (0.2%), BTT listed (26.4%), BTT likely (15.5%), BTT moderate (7.7%), BTT unlikely (2.5%), DT (49.2%), and res-cue therapy (0.5%).217 The percentage of patients receiving a VAD as destination therapy has markedly increased over the last decade as results and devices improved.Left ventricular assist devices (LVADs) provide support for the failing heart by unloading blood from the left ventricle and pumping it into the aorta. Cannulas may be inserted into the LV apex or the left atrium for inflow into the pump, and return is through an arterial cannula or graft sewn to either the ascending or descending aorta. For right-sided devices, inflow drainage is most often from a cannula in the right atrium, and blood is returned through a graft sewn to the pulmonary artery or right ventricular outflow tract.Left Ventricular Assist Devices. The first generation LVADs were pulsatile devices. They provided adequate support for the heart but were limited by their large size and durabil-ity.218 More recently, continuous-flow LVADs based on rotary pump technology have been introduced. These devices are smaller, quieter, and durable enough for long term support. The two most commonly used devices today are the HeartMate II (Thoratec, Pleasanton, CA) and the HeartWare HVAD (Heart-Ware, Inc., Framingham, MA) (Figs. 21-13A,B and 21-14A,B). These devices differ in that the HeartMate II is implanted sub-diaphragmatically, whereas the smaller HeartWare HVAD is implanted within the pericardium. Frequently used short-term support devices include the Abiomed BVS 5000 (Abiomed, Inc., Danvers, MA) and the CentriMag (Thoratec), which are both extracorporeal pumps, as well as the Impella (Abiomed), which may be inserted percutaneously. These devices are com-monly used in either post-MI or postcardiotomy heart failure. They have the benefit of faster and easier insertion, making them ideal rescue devices and allowing time for patient transfer to a tertiary referral center, device weaning, transplantation, or transition to a permanent VAD as DT or BTT.Bridge to Recovery. The ideal clinical situation would be for all LVADs to be temporary with the goal of myocardial recov-ery. However, as noted previously, this is rare with only 0.2% of devices in the most recent INTERMACS data placed with intent for bridge to recovery.217 The LVAD Working Group Recovery Study, a prospective multicenter trial investigating myocardial recovery in BTT patients, has shown significant improvements in left ventricular ejection fraction and significant reductions in left ventricular end-diastolic diameter following support with continuous flow pumps, but myocardial recovery resulting in device explantation was still only seen in six patients (9%).219 Current data suggest that significant reverse remodeling is more likely to occur in the young and those with myocarditis.220Nevertheless, some encouraging results have been reported using a combination of treatment modalities. In a few small studies of patients with LVADs inserted for nonischemic cardiomyopathy, deliberate and aggressive medical therapy, including the β2-agonist clenbuterol, resulted in successful LVAD explantation in 69% to 73% of patients,221,222 but these results have been difficult to replicate. Moreover, early results from clinical trials using stem cell therapy to treat patients with ischemic cardiomyopathy suggest that stem cells may be another adjuvant treatment with potential to aid in myocardial recovery.223,224Bridge to Transplant. LVADs are used as a bridge to trans-plant in patients who are candidates for heart transplantation but are not predicted to survive the waiting list period due to sequelae of cardiac failure, including end-organ dysfunc-tion, rising pulmonary artery pressures, escalating inotrope Brunicardi_Ch21_p0801-p0852.indd 83501/03/19 5:32 PM 836SPECIFIC CONSIDERATIONSPART IIABFigure 21-13. The HeartMate II LVAD viewed from the (A) outside and (B) inside. The device is an axial flow, rotary pump that produces no pulsatile action. The pump contains a magnet, and the rotor assembly functions by the electromotive force generated by the motor. The result is that blood is propelled from the inflow cannula to systemic circulation at flows up to 10 L/min. (HeartMate, HeartMate II and St. Jude Medical are trademarks of St. Jude Medical, LLC or its related companies. Reproduced with permission of St. Jude Medical, ©2017. All rights reserved.)ABFigure 21-14. The HeartWare HVAD system. A. Both the device controller and batteries are held in a wearable carrying case and con-nected to the ventricular assist device through the driveline. B. The main component is a centrifugal blood pump, called the HVAD, which is implanted within the pericardium. The only moving part in the device, the impeller, is suspended within the pump using magnets and thrust bearings. Similar to the HeartMate II, it can deliver a flow rate of up to 10 L/min. (Reproduced with permission of Medtronic, Inc.)requirements, malignant ventricular arrhythmias, and risk for sudden death. Due to the scarcity of donor organs, the improved survival seen with LVAD usage has resulted in more patients remaining alive while on the transplantation waiting list. It is currently estimated that 35% of patients who go on to receive a heart transplant have had a previous LVAD implantation, although at more aggressive tertiary care facilities this number may be as high as 75% to 90%.172The HeartMate II pump was evaluated as a BTT in an observational, prospective multicenter trial of 133 patients with persistent NYHA class IV heart failure despite optimal medical management who were status 1A or 1B on the transplant list.225 At 6 months, 100 patients (75%) had undergone transplantation, had cardiac recovery, or continued on mechanical support while remaining eligible for transplantation. There were significant improvements in both quality of life and functional status with device therapy. At 3 months, 81% of patients were in class I or II heart failure. Moreover, complications, including bleeding requir-ing reoperation, stroke, drive-line infection, and need for right ventricular assist device support, were significantly less frequent than with the previous generation HeartMate XVE.226 These data led to FDA approval of the HeartMate II as a BTT LVAD in 2008, and clinical use of the device increased dramatically. More recently, a multicenter, prospective trial compared the Heart-Ware HVAD to contemporaneously inserted devices for use as a BTT.227 This trial demonstrated noninferiority of the HeartWare HVAD, but in contrast to the 2007 trial, approximately 90% of patients in both groups were transplanted, explanted for recovery, or remained alive and eligible for transplant with LVAD support at 6 months. Most important, data suggest that patients bridged to transplant with an LVAD in the current era experience similar shortand long-term posttransplant survival and complications and do not have a higher incidence of allosensitization compared to standard cardiac transplant patients.228,229Brunicardi_Ch21_p0801-p0852.indd 83601/03/19 5:32 PM 837ACQUIRED HEART DISEASECHAPTER 21Most recently, in 2017, Mehra et al reported their multi-center outcome (Mechanical Circulatory Support Therapy with HeartMate 3 trial—MOMENTUM 3) comparing the safety and effectiveness of centrifugal-flow pump (HeatMate 3) to the axial-flow pump (HeatMate II).230 Implantation of a fully mag-netically levitated centrifugal-flow pump (HeartMate 3) was associated with better outcomes at 6 months than was implanta-tion of an axial-flow pump (HeartMate II). The improved out-comes were primarily due to the lower rate of reoperation for pump malfunction. Additionally, no patients in the HeartMate 3 group were suspected or found to have pump thrombosis.230Destination Therapy. The Randomized Evaluation of Mechan-ical Assistance for Treatment of Congestive Heart Failure (REMATCH) trial was conducted to compare the efficacy of LVAD insertion against optimal medical management in patients with NYHA class IV heart failure. While the pulsatile devices used in this trial had high failure rates, poor durability, and high associated mortality, there was still a clear survival ben-efit in patients treated with LVADs. This led to the FDA approval of the first LVADs for destination therapy in 2002.218Subsequent trials have proven the increased efficacy of second-generation devices for DT. In one such landmark trial, patients with advanced heart failure who were ineligible for transplantation were randomized in a 2:1 ratio to either a Heart-Mate II or HeartMate XVE.231 While both groups showed sig-nificant improvements in functional capacity and quality of life, actuarial survival at 2 years was superior for HeartMate II patients (58% vs. 24%, P = 0.008) and adverse event rates were signifi-cantly lower. These data established the benefit of continuous flow LVADs over optimal medical management for end-stage heart failure, and led to FDA approval of the HeartMate II for DT in 2010. In certain populations, 2-year survival with the HeartMate II is now 80%.232 Several smaller third generation devices are in various stages of development or clinical trials. Some of these devices eliminate the drive line by using alter-native energy sources, thereby removing a significant nidus for device infections. Long-term outcomes with these devices are expected to continue to improve, approaching that of cardiac transplantation and providing a viable solution to organ short-age for many patients.232 In 2013, Slaughter et al reported their multicenter clinical trial outcome to evaluate the HeartWare Ventricular Assist Device (HVAD) system for BTT in patients with advance heart failure in the United States (ADVANCE BTT trial).233 The use of the HeartWare pump as a BTT continued to demonstrate a high 180-day survival rate (91%) despite a low rate of transplant. Adverse event rates were similar or better than those observed in historical BTT trials, despite longer exposure times due to longer survival and lower transplant rates.233Current eligibility criteria for mechanical support as des-tination therapy include (a) NYHA class III or IV heart failure despite guideline-directed medical therapy including cardiac resynchronization therapy if indicated; (b) peak oxygen con-sumption <12 mL/kg per min or failure to wean from continuous IV inotropes; (c) left ventricular ejection fraction <25%; and (d) presence of a contraindication for heart transplantation (i.e., age >65 years, irreversible pulmonary hypertension, chronic renal failure, insulin-dependent diabetes with end-organ dam-age, or other clinically significant comorbidities).172,234 Once a patient has an LVAD inserted as DT, close and intensive follow-up by a multidisciplinary heart failure team is required in order to optimize medical therapy, reduce device-related morbidity, and improve survival.6It is also important to keep in mind that while some con-traindications to transplantation are irreversible, others can be modified. As such, approximately 10% of patients implanted with an initial strategy of destination therapy become BTT patients,172 and in some patients, the LVAD itself facilitates this transition. For example, an improvement in mean pulmonary vascular resistance was reported following implantation of the HeartMate II in patients with end-stage heart failure (2.1 vs. 3.6 Woods units, P <0.001).235 These data are also relevant to patients that receive LVADs as a bridge to decision.Right Ventricular Assist Devices and Biventricular Assist DevicesMost patients who present with advanced heart failure and a failing left ventricle also have some degree of right ventricu-lar dysfunction, but the majority of these patients do well with only an LVAD. However, implantation of an LVAD may cause acute worsening of tricuspid regurgitation and exacerbations of right heart failure through leftward deviation of the intraven-tricular septum and as a result of the significant volume-loading and transfusion requirement that is often necessary to achieve adequate flows postoperatively. Overall, approximately 20% of HeartMate II BTT patients had persistent right ventricular failure (RVF) requiring either a subsequent RVAD (6%) or intravenous inotropic support for >14 days (14%), and these patients had significantly worse 6-month survival compared to those without RVF (71% vs. 89%, P <0.001).236 Typically, mechanical right-ventricular support is temporary with intent to wean the device, and isolated right-ventricular assist devices are unusual.Biventricular support is most commonly indicated for acute cardiogenic shock after an MI or postcardiotomy heart failure. Biventricular support is temporary, although some patients may be successfully bridged to transplant or perma-nent left-sided assist devices. There is currently no destination therapy device for biventricular failure.Total Artificial HeartThe total artificial heart (TAH, SynCardia Systems, Tucson, AZ) is currently indicated as a bridge to transplant for patients in biventricular failure, particularly for those who are critically ill and too large for extracorporeal BiVAD support. Unlike ven-tricular assist devices, the TAH replaces the entire heart. The ven-tricles of the TAH are implanted orthotopically to the atrial cuffs on the ventricular side of the AV groove, and the outflow conduits are attached to the great vessels. This approach has the benefit of obviating the hemodynamic influence of pulmonary hyperten-sion, right heart failure, myocardial or valvular problems, cardiac arrhythmias, and inotropic agents.237 While this device has failed to reach its potential as a replacement for cardiac transplantation, the TAH has achieved favorable results as a BTT with a >70% survival in selected centers.238-240 However, at most centers results with the TAH have been suboptimal, and it is not frequently used. A total of 226 TAH implants between 2013 and 2016 were reported to INTERMACS database. One-year and 2-year sur-vival was reported at 52% and 37%, respectively. Compare to the previously reported survival (2006 through 2012), no significant improvement in survival was noted with time.217SURGERY FOR ARRHYTHMIASThe success of catheter-based ablation and implantable cardio-verter defibrillators (ICDs) has significantly diminished refer-rals for the surgical treatment of arrhythmias such as ventricular Brunicardi_Ch21_p0801-p0852.indd 83701/03/19 5:32 PM 838SPECIFIC CONSIDERATIONSPART IItachycardia, Wolff-Parkinson-White syndrome, atrial flutter, and atrioventricular nodal reentry. On the other hand, the intro-duction of surgical ablation modalities such as radiofrequency and cryothermal energy, has simplified the surgical treatment of atrial fibrillation and has led to an increase in the number of surgical procedures performed annually for AF, although this has plateaued in recent years.241,242Atrial FibrillationEpidemiology of Atrial Fibrillation.  AF remains the most common arrhythmia in the world with an overall prevalence of 0.4% to 1% that increases to 8% in those older than 80 years old.243 The most serious complication of AF is thromboembo-lism with resultant stroke,244 but serious morbidity and mortality may also result from hemodynamic compromise due to loss of atrial contraction and exacerbations of CHF from atrioventricu-lar asynchrony and tachycardia-induced cardiomyopathy.Medical Management. Most patients are treated medically, but the shortcomings of pharmacological management have left an important role for interventional therapies. Antiarrhythmic medications have been limited by modest efficacy and sig-nificant proarrhythmic and systemic toxicities.245 Conversely, rate control strategies leave the patient in AF, do not address the impaired hemodynamics or symptoms associated with this arrhythmia, and may render subsequent attempts at rhythm con-trol therapies less effective for younger patients who may suf-fer irreversible cardiac remodeling due to the prolonged period of time in AF. Additionally, AF is associated with a fivefold greater risk of ischemic stroke or systemic embolism compared with normal sinus rhythm. Annual risk of major bleeding in those on anticoagulation is estimated at 1.2%.246Restoration of normal sinus rhythm has several potential benefits over other strategies.247-249 These include improvement in atrial systolic function, which improves cardiac output and often symptoms of CHF; lowered risks of stroke; potential free-dom from anticoagulation; and likely reversal of atrial structural and/or electrical remodeling.Indications for Surgical Management. Consensus guide-lines published by the Heart Rhythm Society state that surgical ablation for atrial fibrillation is indicated for (a) all symptom-atic AF patients undergoing other cardiac surgery; (b) selected asymptomatic AF patients undergoing cardiac surgery in which the ablation can be performed with minimal additional risk; and (c) symptomatic patients with lone AF who have failed medi-cal therapy and prefer a surgical approach, have failed one or more attempts at catheter ablation, or are poor candidates for catheter ablation.243 At our institution, relative indications for surgical ablation in patients with permanent AF that were not included in the consensus statement are (a) a contraindica-tion to long term anticoagulation for patients at high risk for stroke (CHADS2 score ≥2) and (b) a history of stroke while on therapeutic anticoagulation. Since the consensus statement was released, a multicenter, randomized, controlled trial of surgical ablation in patients undergoing mitral valve surgery showed a significant improvement in freedom from atrial fibrillation in patients receiving surgical ablation (63% vs. 29%, P <0.001).250 Controversially, this trial did not show a difference between left atrial and biatrial ablation; this may have been due to techni-cal issues with the operations.251 The STS has recently released guidelines for surgical ablation that give a Class I Level A rec-ommendation for concomitant surgical ablation at the time of mitral valve surgery and a Class I Level B-NR recommendation for concomitant surgical ablation at the time of AVR, CABG, or AVR-CABG.252The Cox-Maze IV Procedure. The first successful operation for atrial fibrillation, the Cox-Maze procedure, was introduced clinically in 1987 by James Cox. The procedure involved the completion of a maze-like pattern of surgical incisions across both the right and left atrial that were designed to interrupt the multiple macroreentrant circuits thought to be responsible for AF, while still allowing propagation of the sinus impulse, restoring atrioventricular synchrony, and preserving atrial trans-port function. While effective at eliminating AF and reducing the risk of thromboembolism, it was not widely performed because it was technically difficult and significantly prolonged time on cardiopulmonary bypass. In 2002, the Cox-Maze IV, was introduced. The Cox-Maze IV uses a combination of bipo-lar radiofrequency (RF) ablation and cryoablation to effectively replace the majority of incisions that comprise the Cox-Maze III while significantly shortening cross-clamp time and reducing operative complexity.The Cox-Maze IV is performed on cardiopulmonary bypass through either a median sternotomy, often in combina-tion with other cardiac surgery or a right minithoracotomy.253,254 In most cases, the right atrial lesion set performed on the beat-ing heart, whereas the left atrial lesions are performed during cardioplegic arrest (Fig. 21-15).Results from the Cox-Maze IV procedure have been excellent. The Washington University group reported a series of 576 consecutive patients in 2015, demonstrating free-dom from atrial tachyarrhythmias in 92% of patients at 1 year and 73% of patients at 5 years postoperatively.255 Additionally, freedom from atrial tachyarrhythmias and antiarrhythmic drugs was 81% at 1 year and 61% at 5 years. A recent propensity-matched analysis showed that the addition of the Cox-Maze IV procedure to a routine cardiac surgery did not significantly increase postoperative morbidity or mortality and was associ-ated with improved late survival compared with patients with untreated AF and a similar survival to patients without a his-tory of AF.256 A propensity analysis has shown that results are similar between the traditional “cut-and-sew” maze (Cox-Maze III) and the Cox-Maze IV.257 This procedure is often successful in patients who are poor candidates for catheter-based ablation, such as those with large left atria and patients with long-standing persistent AF.The combination of surgical management of the left atrial appendage (LAA) and restoration of normal sinus rhythm after the Cox-Maze procedure significantly reduces stroke risk. It is our practice to stop warfarin at 3 months postoperatively in patients who are in normal sinus rhythm and without another indication for anticoagulation, regardless of CHA2DS2-VASc score. With this approach, the stroke rate following the Cox-Maze procedure off anticoagulation has been remarkably low (annual risk = 0.2%).258 In contrast, in one report the annual rate of intracranial hemorrhage in anticoagulated patients with AF was 0.9% per year, and the overall rate of major bleeding complications was 2.3% per year.259Left Atrial Lesion Sets. Some surgeons perform more lim-ited ablation procedures, such as isolated pulmonary vein isola-tion or lesion sets that are limited to the left side of the heart. This is done in order to further reduce the complexity of the pro-cedure and takes advantage of the fact that in most patients AF 7Brunicardi_Ch21_p0801-p0852.indd 83801/03/19 5:32 PM 839ACQUIRED HEART DISEASECHAPTER 21Figure 21-15. The Cox-Maze IV Lesion Set. A. The left atrial lesion set is comprised of right and left pulmonary vein isolation, connecting lesions between the left and right superior and inferior pulmonary veins, a lesion from the left atrial appendage excision site to the pulmonary vein, and a lesion to the mitral valve annulus. B. The right atrial lesion set consists of lines of ablation along the superior and inferior vena cavae, the free wall of the right atrium, and down to the tricuspid valve annulus. (Reproduced with permission from Weimar T, Bailey MS, Watanabe Y, et al: The Cox-maze IV procedure for lone atrial fibrillation: a single center experience in 100 consecutive patients, J Interv Card Electrophysiol. 2011 Jun;31(1):47-54.)ABoriginates from the pulmonary veins and posterior left atrium. However, there is seldom justification for limited lesion sets in experienced hands.While there is a high degree of variability in both the techniques and energy sources that have been attempted for left-sided atrial lesion sets, these procedures have all incorpo-rated some subset of the left atrial lesion set of the Cox-Maze procedure. Pulmonary vein isolation is ubiquitously performed, and the LAA is often excised. Results differ greatly between series, including the recent CTSNet multicenter trial,250 but a meta-analysis of the published literature by Ad and colleagues revealed that a biatrial lesion set resulted in a significantly higher late freedom from AF compared with a left atrial lesion set alone (87% vs. 73%, P = 0.05).260 These results are not sur-prising, as our intraoperative mapping experience with such patients showed a distinct region of stable dominant frequency in the left atrium only 30% of the time.261 The dominant fre-quency was located in the right atrium 12% of the time and moved during the recording period in almost half of all patients. It must also be kept in mind that recurrent right atrial flutter is a known complication of performing only the left atrial lesions. When it does occur, atrial flutter can be treated with catheter-based ablation; however, recurrent left atrial flutter can be very difficult to ablate.Pulmonary Vein Isolation. Pulmonary vein isolation (PVI) is an attractive therapeutic option because it can be performed off of cardiopulmonary bypass (CPB) through small or thora-coscopic incisions. The results of PVI have been variable and highly dependent on patient selection since outcomes are con-sistently worse in patients with longstanding persistent AF. In a study from Edgerton et al, only 56% of patients were free from AF at 6 months (35% off antiarrhythmic drugs), and with concomitant procedures, the success rate of PVI has been even lower.262 Several devices are available to close the LAA at the time of PVI. These include staplers and epicardial clips that can be placed without the need for CPB.263While surgical PVI has had poorer results than a Cox-Maze procedure, it has had superior results to catheter-based PVI. The Atrial Fibrillation Catheter Ablation Versus Surgi-cal Ablation Treatment (FAST) Trial, which was a two cen-ter, randomized clinical trial, compared catheter-based ablation to thoracoscopic PVI in patients with antiarrhythmic drug-refractory AF and either left atrial dilatation and hypertension or failed prior catheter-ablation.264 This study demonstrated that the 12-month freedom from AF and antiarrhythmic drugs was 37% for the catheter ablation group and 66% for the PVI group (P = 0.002).264SURGERY FOR PERICARDIAL DISEASEAcute PericarditisPericarditis is characterized by infiltration of the cellular and fibrous pericardium by inflammatory cells. The exact incidence and prevalence of pericarditis is unknown, but it is estimated that pericarditis is found in approximately 1% of autopsies and accounts for up to 5% of presentations of nonischemic chest pain.265,266 The etiologies of acute pericarditis are diverse and may result from primary pericardial disorders or occur sec-ondary to a systemic illness.267 In developed countries, 80% to 90% of cases are now considered idiopathic or related to a viral pathogen, but nonviral infection, autoimmune diseases, myocardial infarction, radiation, malignancy, endocrinopathy, myocarditis, aortic dissection, uremia, trauma, pharmacologi-cal side effects, and previous cardiothoracic surgery must be included in the differential diagnosis. The relative incidences of peri-infarction pericarditis, which was once common, and post-cardiac injury syndrome have been dramatically reduced with the advent of thrombolytics and coronary angioplasty.267Clinical Presentation and Diagnosis. Diagnosis of acute pericarditis typically requires the identification of at least two of four cardinal features (Table 21-14). The presentation may be confused with several more common cardiopulmonary condi-tions, particularly myocardial infarction, making a careful his-tory and physical critical. Patients with pericarditis classically complain of sudden onset, retrosternal pain that may be pleuritic in nature. The pain may also be positional, with alleviation of pain when the patient is upright and leaning forward. Pain from pericarditis is typically sharp or stabbing, as opposed to the dull pain or pressure that is common with angina, and it typically does not crescendo. While both conditions cause pain that often radiates to the neck, arms, and shoulders, pericarditis pain may Brunicardi_Ch21_p0801-p0852.indd 83901/03/19 5:32 PM 840SPECIFIC CONSIDERATIONSPART IIuniquely radiate to the trapezius ridge due to innervation from the phrenic nerve.268-269The presence of a pericardial friction rub is pathogno-monic for pericarditis, but it tends to vary in intensity over time and may be absent in 15% to 65% of patients.265,268 As such, the sensitivity of this physical finding is dependent on the fre-quency and quality of auscultation. A pericardial friction rub is best heard at the left lower sternal border and is typically described as a high-pitched scratchy or squeaky sound with a triphasic cadence corresponding to the movement of the heart during atrial systole, ventricular systole, and early ventricular diastole. However, it may be monophasic or biphasic in up to 50% of patients.Electrocardiogram changes typically progress through four stages representing global subepicardial myocarditis and subsequent recovery. Pericarditis patients may have concave ST deflections with diffuse changes, spanning the leads of multiple coronary artery distributions, but ST segment abnormalities are absent in 20% to 40% of patients.270,271 Acute pericarditis should not result in the development of infarct patterns, such as Q waves or loss of R waves, and T-wave inversions from pericarditis tend to result later in the disease process after the ST segment has returned to baseline.Echocardiography is routinely performed in the evaluation of acute pericarditis. Its role is primarily to assess for a pericar-dial effusion. However, in a patient who can be demonstrated to have previously had normal cardiac function, it may be used to exclude segmental wall motion abnormalities that may suggest ischemia.The remaining workup should attempt to determine the underlying cause of the pericarditis and should be directed by the history and physical. Most inflammatory markers and labo-ratory tests are nonspecific, but C-reactive protein may be useful in predicting recurrence risks and in guiding the duration of anti-inflammatory medications.272 Rarely, other imaging modalities, such as CT scanning, pericardial biopsies, or pericardiocentesis may aid in diagnosis.Treatment. The preferred treatment depends on the underly-ing cause of the pericarditis. The disease usually follows a self-limited and benign course and can be successfully treated with a short course of nonsteroidal anti-inflammatory agents (NSAIDs). The addition of colchicine may be beneficial.273 Some patients may require judicious use of steroids or IV anti-biotics. In cases of purulent pyogenic pericarditis, surgical exploration and drainage are occasionally necessary. Rarely, accumulation of fluid in the pericardium may lead to tampon-ade, requiring prompt evacuation of the pericardial space. While pericardiocentesis will typically suffice, surgical drain-age may be required for thick, viscous, or clotted fluid or in patients with significant scarring from previous operations. More commonly, surgical intervention is required to manage recurrent disease.8Table 21-14Features of acute pericarditis• Pleuritic and positional, retrosternal chest pain• Pericardial friction rub• EKG changes: diffuse ST elevation and PR depression• Pericardial effusionEKG = Electrocardiogram.Relapsing PericarditisAs many as one-third of patients with acute pericarditis will develop at least one episode of relapse.267 While many of these patients can be treated medically during their initial relapse and do not experience further episodes, a subset of patients experi-ence chronic relapsing pericarditis that can significantly impact their quality of life. Recurrence may develop either from the original etiology or from an autoimmune process that occurs as a consequence of damage from the initial episode. Relapsing pericarditis normally responds to a longer course of NSAIDS ± colchicine. While steroids may induce rapid symptomatic response, their use should be limited to patients who have mul-tiple relapses and are unresponsive to first-line agents, as several studies have suggested that steroid administration may favor relapse.273,274Pericardiectomy may be considered a last resort treatment in patients with relapsing pericarditis who are severely symp-tomatic despite optimal medical management, are unable to tol-erate steroids, or have recurrence with tamponade. Evidence for this approach is lacking, as few studies have described pericar-diectomy in this population.275-277 The largest study and the only one to compare surgical treatment with medical management for patients with persistent relapsing pericarditis was a report of 184 patients from the Mayo Clinic.276 About 58 patients were identi-fied as having undergone a pericardiectomy after failed medi-cal treatment, whereas the remainder were treated with medical management only. Compared to medical treatment only, peri-cardiectomy resulted in significantly fewer relapses (8.6% vs. 28.6%, P = 0.009) at long term follow-up, as well as a nonsig-nificant trend towards less medication and corticosteroid usage. Of note, 80% of patients in the pericardiectomy group who had relapses reported significant improvements in their symptoms and had fewer relapses than before pericardiectomy. No periop-erative deaths were observed, and only two patients (3%) had major complications. Hence, at experienced centers pericardi-ectomy may be a safe and viable option in select patients with relapsing pericarditis.Chronic Constrictive PericarditisEtiology, Pathology, and Pathophysiology. Constrictive pericarditis can occur after any pericardial disease process but remains a rare outcome of recurrent pericarditis. It results when chronic pericardial scarring and fibrosis cause adhesion of the visceral and parietal layers and resultant obliteration of the pericardial space. While the pericardium is often grossly thickened with either focal or diffuse calcification in chronic disease, constriction may occur with normal pericardial thick-ness in approximately 20% of cases.267,278 In developed nations, idiopathic causes and cardiac surgery (accounting for almost 40% of cases in some series) are the predominant underlying eti-ologies, followed by mediastinal radiation, pyogenic infections (i.e., Staphylococcus), and other miscellaneous causes. Tuber-culosis is an additional common cause in immunosuppressed patients and in developing or underdeveloped countries.Clinically, pericardial constriction limits diastolic filling of the ventricles and mimics right heart failure since the right-sided chambers are more affected by a rise in filling pressures. Subsequent increases in central venous pressure result in the progressive development of hepatomegaly, ascites, peripheral edema, abdominal pain, dyspnea on exertion, anorexia, and nausea (in part due to hepatic and bowel congestion). In many patients, these symptoms develop insidiously over a course Brunicardi_Ch21_p0801-p0852.indd 84001/03/19 5:32 PM 841ACQUIRED HEART DISEASECHAPTER 21of years. Since many of these symptoms are similar to those seen in patients with restrictive cardiomyopathy, the distinc-tion between the two entities is difficult, but it remains critical because the treatment is completely different for restriction. The primary difference is that restrictive cardiomyopathy is defined by a nondilated ventricle with a rigid myocardium that causes a significant decrease in myocardial compliance, which is not seen in constrictive pericarditis.Clinical and Diagnostic Findings. Classic physical exam findings include jugular venous distention with Kussmaul’s sign, diminished cardiac apical impulses, peripheral edema, ascites, pulsatile liver, a pericardial knock, and, in advanced disease, signs of liver dysfunction, such as jaundice or cachexia. The “pericardial knock” is an early diastolic sound that reflects a sudden impediment to ventricular filling, similar to an S3 but of higher pitch.Several findings are characteristic on noninvasive and invasive testing. CVP is often elevated 15 to 20 mmHg or higher. ECG commonly demonstrates nonspecific low voltage QRS complexes and isolated repolarization abnormalities. Chest X-ray may demonstrate calcification of the pericardium, which is highly suggestive of constrictive pericarditis in patients with heart failure, but this is present in only 25% of cases.274 Cardiac CT or MRI (cMRI) typically demonstrate increased pericardial thickness (>4 mm) and calcification, dilation of the inferior vena cava, deformed ventricular contours, and flattening or leftward shift of the ventricular septum. Pericardial adhesions may also be seen on tagged cine MRI studies.As discussed, it is most important to distinguish peri-cardial constriction from restrictive cardiomyopathy, which is best done with either echocardiography or right heart catheter-ization. Findings favoring constriction on echocardiography include respiratory variation of ventricular septal motion and mitral inflow velocity, preserved or increased mitral annulus early diastolic filling velocity, and increased hepatic vein flow reversal with expiration.267,274 Cardiac catheterization will show increased atrial pressures, equalization of end-diastolic pressure and early ventricular diastolic filling with a subsequent plateau, called the “square-root sign.” Additional findings upon cath-eterization that would favor constriction include respiratory variation in ventricular filling and increased ventricular inter-dependence, manifest as a discordant change in the total area of the LV and RV systolic pressure curve with respiration.Surgical Treatment. Transient constrictive pericarditis may occur weeks to months after an initial injury and follows a self-limiting course of weeks to a few months. These patients are best treated with medical therapy alone. They often lack calci-fication of their pericardium, and the degree of late gadolinium enhancement of the pericardium on cardiac MRI has shown promise in predicting which patients may have resolution of the process.279 Still, there is no ideal way to distinguish these patients from those who will develop chronic constrictive peri-carditis, which is permanent. Therefore, if a newly diagnosed patient is hemodynamically stable, it is recommended that con-servative management is attempted for 2 to 3 months prior to performing a pericardiectomy.278 Surgical therapy should not be delayed indefinitely, however, as results are improved when the operation is performed earlier in the course of the disease. A series of 938 patients undergoing pericardiectomy reported by the Mayo Clinic, 355 of whom underwent pericardiec-tomy for constrictive pericarditis, showed significantly lower survival in patients with constrictive pericarditis compared with patients with effusive/relapsing pericarditis.280 Patients with left ventricular systolic dysfunction or right ventricular dilata-tion are at increased risk of early mortality.281 Additional fac-tors that predict adverse long-term outcomes include older age and prior ionizing radiation, as well as cardiopulmonary and renal dysfunction.274,281 Surgery should therefore be approached cautiously in patients with advanced, “end-stage” constrictive pericarditis, mixed constrictive-restrictive disease (often from radiation), and significant myocardial or renal dysfunction, as those patients are at increased risk from surgery and may not experience improvement of symptoms.In order to minimize recurrence following pericardiec-tomy, complete pericardial resection is desirable. This is typi-cally performed through either a median sternotomy or left anterolateral thoracotomy while on cardiopulmonary bypass. Radical pericardiectomy involves wide resection of the con-stricting pericardium from the anterior surface of the heart between the phrenic nerves and the diaphragmatic surface. Decortication of the right atrium and vena cavae is not univer-sally performed, but doing so improves the risk of persistent disease or relapse.282,283The extent of myocardial involvement may also affect long-term outcomes, and, thus, the depth of decortication is an important consideration.282 Even when an adequate pericardi-ectomy is performed, epicardial sclerosis can cause persistent hemodynamic instability or a delayed response to surgery. Scle-rotic epicardium is often thin and nearly transparent, but in cases of severe chronic constrictive pericarditis it can be difficult to remove it without injury to the heart.Surgical Results. While most patients experience significant improvement in their symptoms following pericardiectomy, symptomatic relief may take several months. Since there is a significant perioperative morbidity and mortality, pericardiec-tomy is best performed by experienced surgeons at high-volume centers. Between 1970 and 1985, the operative mortality was reported to be 12%, but a lower mortality of approximately 4% to 8% was noted between 1977 and 2006 at several experienced centers.278,283-287Long-term survival is in part determined by etiology of the disease. In a report from the Cleveland Clinic, 7-year survival rates following pericardiectomy for idiopathic, postsurgical, and radiation-induced constrictive pericarditis were 88%, 66%, and 27%, respectively.284 Results are worst for radiation-induced disease because ionizing radiation is often associated with myo-cardial injury as well as pericardial disease.Despite the risks, many patients experience significant benefits from surgical treatment. In one large series, 83% of patients were reported to be free of symptoms at last follow-up.287 This is in agreement with other studies that have shown a signif-icant improvement in NYHA functional status from class III/IV preoperatively to class I/II following pericardiectomy in >95% of patients.283,285-287CARDIAC NEOPLASMSOverview and General Clinical FeaturesCardiac neoplasms are rare, with an incidence ranging from 0.001% to 0.3% in autopsy studies and a 0.15% incidence in major echocardiographic series.288,289 In one large autopsy series, 99.2% of cardiac tumors were metastatic in origin; however, Brunicardi_Ch21_p0801-p0852.indd 84101/03/19 5:32 PM 842SPECIFIC CONSIDERATIONSPART IIthese patients almost never present for surgical management as they usually have fatal diffuse metastatic disease.290 As a result, a majority of surgical series describe management of primary cardiac neoplasms. Benign cardiac tumors are most common and account for 75% of primary neoplasms. Approximately 50% of benign cardiac tumors are myxomas, with the remainder being papillary fibroelastomas, lipomas, rhabdomyomas, fibro-mas, hemangiomas, teratomas, lymphangiomas, and others, in order of decreasing frequency. Most malignant primary cardiac tumors are sarcomas (angiosarcoma, rhabdomyosarcoma, fibro-sarcoma, leiomyosarcoma, and liposarcoma), with a small inci-dence of malignant lymphomas.Clinical Presentation. The clinical presentation of cardiac neoplasms varies greatly depending on the location of the tumor, as well as its size, rate of growth, invasiveness, and fri-ability. While as many as 10% of patients are asymptomatic, most manifest some combination of symptoms from the classic triad resulting from blood flow obstruction, tumor embolization, and constitutional symptoms.291,292 Systemic manifestations of disease include fever, myalgias, chills, night sweats, weight loss, and fatigue and occur in up to one-third of patients.Obstruction of cardiac blood flow accounts for the major-ity of presenting symptoms.292 When the tumor is located in the left atrium, symptoms tend to mimic mitral valve disease with dyspnea and pulmonary edema; although more severe presenta-tions with syncopal episodes, hypotension, and sudden cardiac death have been reported from temporary valve orifice occlu-sion. When the tumor is located in the right atrium, symptoms may mimic right heart failure and include hepatomegaly, asci-tes, and peripheral edema. Outflow tract obstruction is rare but may be caused by large ventricular tumors.293Tumor lysis and embolization may also lead to neurologic presentations such as stroke, retinal artery occlusion, or cere-bral aneurysms, particularly in the case of pedunculated tumors and those with frond-like projections.294 Embolic tumor cells are able to lodge and penetrate distant vessel walls via subintimal growth, which leads to weakening of the arterial wall and sub-sequent aneurysm formation. This has been documented as late as 5 years after successful primary myxoma resection.295 Alter-natively, embolic implants may metastasize and create space occupying lesions. While rare, myxomatous tumor emboli have also been identified in the coronary arteries, common iliac and femoral arteries, kidney, spleen, pancreas, and liver.294Certain clinical features may be helpful in distinguishing benign from malignant primary cardiac tumors.292 Malignant tumors, primarily sarcomas, do not demonstrate a gender pref-erence and tend to present after the fourth decade of life. They are often multifocal within the right atrium, and intramyocardial invasion can lead to refractory congestive heart failure, arrhyth-mias, hemopericardium, and ischemia. Conversely, benign tumors, primarily myxomas, are typically unifocal in the left atrium, have a 3:1 female preference, and occur in younger patients. Arrhythmias and pericardial effusions are very rare in this population.Diagnosis and Characterization of Cardiac Masses. Trans-thoracic echocardiography is the mainstay imaging technique for the detection of cardiac tumors.292 However, echocardiogra-phy is limited by dependence on an acoustic window, subopti-mal visualization of extracardiac extension, and poor soft-tissue visualization. TEE is generally only beneficial for small local-ized tumors due to its limited field of view. cMRI is therefore the current standard for delineating the anatomical extent of the tumor and assessing the paracardiac space and great vessels. Advantages of cMRI over CT scans include better soft-tissue evaluation without the need for iodinated contrast and no expo-sure to ionizing radiation.It is important in the initial workup to distinguish a cardiac tumor from an intracardiac thrombus, which may be common in the atria of patients with AF and can mimic echocardiographic features of atrial myxomas. This determination is critical, as an atrial thrombus may be expected to resolve with anticoagula-tion, whereas a tumor requires surgical intervention. Moreover, anticoagulation can potentially increase the risk of peripheral embolization in patients with cardiac tumors. Delayed enhance-ment cMRI is the best modality to separate these two entities. cMRI may show vascularization, areas of necrosis, hemorrhage, or calcification in cardiac tumors that are not present in thrombi.MyxomaPathology and Genetics. Cardiac myxomas are the most common cardiac tumor and are characterized by several distinguishing features. About 75% of the time, they arise from the interatrial septum near the fossa ovalis in the left atrium.296 Most others will develop in the right atrium, but, less commonly, they can arise from valvular surfaces and the walls of other cardiac chambers. Macroscopically, these tumors are pedunculated with a gelatinous consistency, and the surface may be smooth (65%), villous, or friable.291 Size varies greatly with these tumors and ranges from 1 to 15 cm in diameter. Internally, myxomas are heterogeneous and often contain hemorrhage, cysts, necrosis, or calcification. Histologically, these tumors contain cells that arise from a multipotent mesenchyme and are contained within a mucopolysaccharide stroma.297While the majority of myxomas occur spontaneously with the highest incidence in women aged 40 to 60 years old, approx-imately 7% of cases are familial as part of Carney complex.291 Carney complex is an autosomal dominant disorder character-ized by two or more of the following conditions: atrial and extra-cardiac myxomas, schwannomas, cutaneous lentiginosis, spotty pigmentation, myxoid fibroadenomas of the breast, endocrine overactivity (pituitary adenomas or primary adrenal hyperplasia with Cushing’s syndrome), and testicular tumors. Compared to sporadic myxomas, those that occur as part of Carney complex are more commonly found in the right atrium (37% vs. 18%) or one of the ventricles (25% vs. 0%), more often multicentric (33% vs. 6%) and more likely to recur (20% vs. 3%).296 They also present earlier at an average age of 24 years old (range 4–48 years).Pathophysiology. Larger tumors are more likely to be asso-ciated with cardiovascular symptoms from obstruction, and embolic symptoms tend to occur from organized thrombi pres-ent on friable or villous tumors (Fig. 21-16). The relative fre-quencies of symptoms was illustrated by a series of 112 patients who reported cardiovascular symptoms (67%), most commonly resembling mitral valve obstruction; systemic embolization (29%); neurologic deficits (20%); and constitutional symptoms (34%).291 Similar incidences of symptoms have been reported in other large studies.Treatment. Cardiac myxomas should be promptly excised after diagnosis due to the significant risk of embolization and cardiovascular complications, including sudden death. Resec-tion may be performed through either a median sternotomy or 9Brunicardi_Ch21_p0801-p0852.indd 84201/03/19 5:32 PM 843ACQUIRED HEART DISEASECHAPTER 21Figure 21-16. Massive left atrial myxoma. A. Intraoperative echocardiogram of a large left atrial mass, diagnosed preoperatively as a left atrial myxoma. The mass can be seen prolapsing through the mitral valve orifice causing intermittent symptoms of mitral stenosis. B. The resected specimen. The neck of the mass that was obstructing the mitral orifice is clearly delineated.a minimally invasive right thoracotomy while on cardiopulmo-nary bypass. Care is taken not to manipulate the tumor before cross clamping of the aorta in order to avoid embolization. Left atrial tumors may be approached through a standard left atriotomy.298 Exposure of large tumors attached to the interatrial septum may be facilitated by an additional parallel incision in the right atrium, but this is rarely necessary. An ideal resection encompasses both the tumor and a portion of the cardiac wall or interatrial septum to which it is attached. In order to prevent recurrence, a full thickness excision of the attachment site is preferred, but partial thickness excisions and cryoablation of the base have been performed with good late results.298 The defect created in the atrial septum can either be repaired primarily or with a small patch. Finally, patients with valvular involvement may require additional valvular reconstruction or replacement, and rare cases of cardiac autotransplantation (with atrial recon-struction) or transplantation have been reported as strategies for complex cases of recurrent atrial myxoma.299,300Shortand long-term results following excision are excellent for benign cardiac myxomas. Operative mortality is low, and the probability of disease-free survival at 20 years has been reported to be as high as 92% for benign, sporadic myxomas.291,298 Risk of recurrence is significantly higher for familial cases. Other risk factors for recurrence include younger age, smaller tumor mass, and ventricular tumor location.301Other Benign Cardiac TumorsThere are several benign cardiac tumors apart from myxomas that are infrequent but have distinct pathophysiologic features.292 Papillary fibroelastomas are the second most common primary cardiac tumor, representing approximately 8% of all cases. These tumors typically occur in more elderly patients; are small (<1 cm in diameter) sessile, pedunculated masses that arise from the mitral or aortic valves; and frequently result in embo-lization. Fibroelastomas can almost always be resected with preservation of the native valve leaflets, and cryoablation of the valve leaflet after resection can help prevent recurrence. Lipomas are encapsulated tumors that usually arise from the epicardium and remain asymptomatic in most patients. Heman-giomas, which may arise from any cardiac structure, including the pericardium, account for 2% of benign cardiac tumors, and atrioventricular node tumors, which often lead to sudden cardiac death from heart block and ventricular fibrillation, are exceedingly rare.In children, rhabdomyomas are the most common pri-mary cardiac tumor, whereas fibromas are the most commonly resected cardiac tumor. Rhabdomyomas are myocardial hamar-tomas that are often multicentric in the ventricles. About 50% of cases are associated with tuberous sclerosis, and while resection is occasionally necessary, most disappear spontaneously. Fibro-mas are congenital lesions that one-third of the time are found in children younger than 1-year old. These tumors, conversely, are ordinarily solitary lesions found in the inner interventricu-lar septum, and they may present with heart failure, cyanosis, arrhythmias, syncopal episodes, chest pain, or sudden cardiac death.Malignant Cardiac TumorsPrimary cardiac malignancies are very rare, but when they occur they tend to have a right-sided predominance and frequently demonstrate extracardiac extension and involvement.292,302 Malignant cardiac tumors include intimal sarcoma, angiosar-coma, osteosarcoma, leiomyosarcoma, rhabdomyosarcoma, liposarcoma, and primary cardiac lymphomas. Intimal sarcoma is the most common subtype.303 Angiosarcomas are aggressive, rapidly invading adjacent structures, and 47% to 89% of patients present with lung, liver, or brain metastases by the time of diag-nosis. Leiomyosarcomas are sessile masses with a mucous appearance that are typically found in the posterior wall of the left atrium. Rhabdomyosarcomas are bulky (>10 cm in diam-eter) tumors that usually occur in children and do not have a predilection for any particular chamber. They frequently invade nearby cardiac structures and are multicentric in 60% of cases. Finally, while not as frequent as secondary cardiac lymphomas, primary cardiac lymphomas are increasing in frequency due to lymphoproliferative disorders caused by Epstein-Barr virus in immunosuppressed patients. The absence of necrotic foci in lymphomas can be used to differentiate these tumors from car-diac sarcomas.Metastatic Cardiac TumorsCardiac metastases have been found in approximately 10% of autopsies performed for malignant disease.292 Secondary cardiac tumors, unlike primary tumors, are therefore relatively common. They may arise from direct extension of mediastinal tumors, hematological spread, intracavitary extension from the inferior vena cava or lymphatic extension, although the latter is the most common mechanism.While they can occur with most any primary tumor, they are generally observed late in the course of disease. Malignant melanomas have a high potential for cardiac involvement, but Brunicardi_Ch21_p0801-p0852.indd 84301/03/19 5:32 PM 844SPECIFIC CONSIDERATIONSPART IIother soft tissue tumors such as lung cancer, breast cancer, sarcomas, renal carcinoma, esophageal cancer, hepatocellu-lar carcinoma, and thyroid cancer may all progress to cardiac involvement. Cardiac metastases may also develop from leuke-mia and lymphoma in 25% to 40% of cases.304Metastatic cardiac tumors are typically found in random locations, excluding the valvular tissue where lymphatics are absent, and they may be multifocal or diffusely extend along the epicardial surface. Signs of malignant cardiac involvement in cancer patients include pericardial effusion or tamponade, tachyarrhythmias, and heart failure symptoms. Workup is simi-lar to other cardiac tumors. Treatment is generally with com-bined chemotherapy and radiation and is rarely effective.REFERENCESEntries highlighted in bright blue are key references. 1. Task Force for the Diagnosis and Management of Syncope; European Society of Cardiology (ESC); European Heart Rhythm Association (EHRA); et al. Guidelines for the diag-nosis and management of syncope (version 2009). Eur Heart J. 2009;30(21):2631-2671. 2. Braunwald E, Bonow RO. Braunwald’s Heart Disease: A Textbook of Cardiovascular Medicine, 9th ed. Philadel-phia: Saunders; 2012. 3. New York Heart Association. Diseases of the Heart and Blood Vessels: Nomenclature and Criteria for Diagnosis, 6th ed. Boston: Little, Brown; 1964. 4. Lee DH, Buth KJ, Martin BJ, Yip AM, Hirsch GM. Frail patients are at increased risk for mortality and pro-longed institutional care after cardiac surgery. Circulation. 2010;121(8):973-978. 5. Smilowitz NR, Gupta N, Ramakrishna H, Guo Y, Berger JS, Bangalore S. Perioperative major adverse cardiovascular and cerebrovascular events associated with noncardiac surgery. JAMA Cardiol. 2017;2(2):181-187. 6. Nishimura RA, Otto CM, Bonow RO, et al. 2017 AHA/ACC focused update of the 2014 AHA/ACC guideline for the man-agement of patients with valvular heart disease: a report of the American College of Cardiology/American Heart Association Task Force on clinical practice guidelines. J Am Coll Cardiol. 2017;70(2):252-289. 7. Fleisher LA, Fleischmann KE, Auerbach AD, et al. 2014 ACC/AHA guideline on perioperative cardiovascular eval-uation and management of patients undergoing noncardiac surgery: a report of the American College of Cardiology/American Heart Association Task Force on practice guide-lines. J Am Coll Cardiol. 2014;64(22):e77-e137. 8. Klocke FJ, Baird MG, Lorell BH, et al. ACC/AHA/ASNC guide-lines for the clinical use of cardiac radionuclide imaging— executive summary: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (ACC/AHA/ASNC Committee to Revise the 1995 Guidelines for the Clinical Use of Cardiac Radionuclide Imaging). Circulation. 2003;108(11):1404-1418. 9. Badheka AO, Hendel RC. Radionuclide cardiac stress testing. Curr Opin Cardiol. 2011;26(5):370-378. 10. Bax JJ, Boogers MM, Schuijf JD. Nuclear imaging in heart failure. Cardiology clinics. 2009;27(2):265-276. 11. Proudfit WL, Shirey EK, Sones FM, Jr. Selective cine coro-nary arteriography. Correlation with clinical findings in 1,000 patients. Circulation. 1966;33(6):901-910. 12. Shuttleworth K, Smith K, Watt J, Smith JAL, Leslie SJ. Hybrid instantaneous wave-free ratio-fractional flow reserve versus fractional flow reserve in the real world. Front Cardiovasc Med. 2017:435. 13. Gotberg M, Cook CM, Sen S, Nijjer S, Escaned J, Davies JE. The evolving future of instantaneous wave-free ratio and frac-tional flow reserve. J Am Coll Cardiol. 2017;70(11):1379-1402. 14. Forssmann W. Die sondierung des rechten herzens. Klinische Wochenschrift. 1929;8(45):3. 15. Scanlon PJ, Faxon DP, Audet AM, et al. ACC/AHA guide-lines for coronary angiography. A report of the American College of Cardiology/American Heart Association Task Force on practice guidelines (Committee on Coronary Angiography). Developed in collaboration with the Society for Cardiac Angiography and Interventions. J Am Coll Cardiol. 1999;33(6):1756-824. 16. Berman DS, Hachamovitch R, Shaw LJ, et al. Roles of nuclear cardiology, cardiac computed tomography, and cardiac mag-netic resonance: assessment of patients with suspected coro-nary artery disease. J Nucl Med. 2006;47(1):74-82. 17. Chow BJ, Small G, Yam Y, et al. Incremental prognostic value of cardiac computed tomography in coronary artery disease using CONFIRM: COroNary computed tomography angiogra-phy evaluation for clinical outcomes: an InteRnational Multi-center registry. Circ Cardiovasc Imaging. 2011;4(5):463-472. 18. Edmunds LH, Jr. The evolution of cardiopulmonary bypass: lessons to be learned. Perfusion. 2002;17(4):243-251. 19. Cohn LH. Cardiac Surgery in the Adult, 4th ed. New York: McGraw-Hill; 2012. 20. Kirklin JK, Westaby S, Blackstone EH, Kirklin JW, Chenoweth DE, Pacifico AD. Complement and the damaging effects of cardiopulmonary bypass. J Thorac Cardiovasc Surg. 1983;86(6):845-857. 21. Asimakopoulos G. Systemic inflammation and cardiac surgery: an update. Perfusion. 2001;16(5):353-360. 22. Salter BS, Weiner MM, Trinh MA, et al. Heparin-induced thrombocytopenia: a comprehensive clinical review. J Am Coll Cardiol. 2016;67(21):2519-2532. 23. Greinacher A. Heparin-induced thrombocytopenia. N Engl J Med. 2015;373(19):1883-1884. 24. Murphy GJ, Angelini GD. Side effects of cardiopulmonary bypass: what is the reality? J Cardiac Surg. 2004;19(6):481-488. 25. Gay WA, Jr, Ebert PA. Functional, metabolic, and morpho-logic effects of potassium-induced cardioplegia. Surgery. 1973;74(2):284-290. 26. Carrel A. VIII. On the experimental surgery of the thoracic aorta and heart. Ann Surg. 1910;52(1):83-95. 27. Vineberg A, Miller G. Internal mammary coronary anastomo-sis in the surgical treatment of coronary artery insufficiency. Can Med Assoc J. 1951;64(3):204-210. 28. Longmire WP, Jr, Cannon JA, Kattus AA. Direct-vision coronary endarterectomy for angina pectoris. N Engl J Med. 1958;259(21):993-999. 29. Senning A. Strip grafting in coronary arteries. Report of a case. J Thorac Cardiovasc Surg. 1961;41:542-549. 30. Sabiston DC, Jr. The William F. Rienhoff, Jr. lecture. The coro-nary circulation. Johns Hopkins Med J. 1974;134(6):314-329. 31. Favaloro RG, Effler DB, Groves LK, Sones FM, Jr, Fergusson DJ. Myocardial revascularization by internal mammary artery implant procedures. Clinical experience. J Thorac Cardiovasc Surg. 1967;54(3):359-370. 32. Greason KL, Schaff HV. Myocardial revascularization by coronary arterial bypass graft: past, present, and future. Curr Prob Cardiol. 2011;36(9):325-368. 33. Crea F, Liuzzo G. Pathogenesis of acute coronary syndromes. J Am Coll Cardiol. 2012;8;61(1):1-11. 34. Fuster V, Badimon L, Badimon JJ, Chesebro JH. The patho-genesis of coronary artery disease and the acute coronary syn-dromes (1). N Engl J Med. 1992;326(4):242-250. 35. Libby P. Mechanisms of acute coronary syndromes and their implications for therapy. N Engl J Med. 2013;368(21): 2004-2013.Brunicardi_Ch21_p0801-p0852.indd 84401/03/19 5:32 PM 845ACQUIRED HEART DISEASECHAPTER 21 36. National Heart, Lung, and Blood Institute, National Institutes of Health. Morbidity and mortality: 2012 chart book on car-diovascular, lung, and blood diseases. 2012. 37. Smith SC, Jr, Benjamin EJ, Bonow Row, et al. AHA/ACCF secondary prevention and risk reduction therapy for patients with coronary and other atherosclerotic vascular disease: 2011 update: a guideline from the American Heart Association and American College of Cardiology Foundation. Circulation. 2011;124(22):2458-2473. 38. Gibbons RJ, Balady GJ, Bricker Jt, et al. ACC/AHA 2002 guideline update for exercise testing: summary article: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Committee to Update the 1997 Exercise Testing Guidelines). Circulation. 2002;106(14):1883-1892. 39. Fihn SD, Gardin JM, Abrams J, et al. 2012 ACCF/AHA/ACP/AATS/PCNA/SCAI/STS guideline for the diagnosis and management of patients with stable ischemic heart disease: a report of the American College of Cardiology Foundation/American Heart Association task force on practice guidelines, and the American College of Physicians, American Associa-tion for Thoracic Surgery, Preventive Cardiovascular Nurses Association, Society for Cardiovascular Angiography and Interventions, and Society of Thoracic Surgeons. Circulation. 2012;126(25):e354-e471. 40. Fihn SD, Blankenship JC, Alexander KP, et al. 2014 ACC/AHA/AATS/PCNA/SCAI/STS focused update of the guide-line for the diagnosis and management of patients with stable ischemic heart disease: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines, and the American Association for Thoracic Surgery, Preventive Cardiovascular Nurses Association, Society for Cardiovascular Angiography and Interventions, and Society of Thoracic Surgeons. Circulation. 2014;130(19):1749-1767. 41. Hillis LD, Smith PK, Anderson JL, et al. 2011 ACCF/AHA guideline for coronary artery bypass graft surgery: a report of the American College of Cardiology Foundation/American Heart Association Task Force on Practice Guidelines. Circula-tion. 2011;124(23):e652-e735. 42. Hannan EL, Racz MJ, Walford G, et al. Long-term outcomes of coronary-artery bypass grafting versus stent implantation. N Engl J Med. 2005;352(21):2174-2183. 43. Booth J, Clayton T, Pepper J, et al. Randomized, controlled trial of coronary artery bypass surgery versus percutaneous coronary intervention in patients with multivessel coronary artery disease: six-year follow-up from the Stent or Surgery Trial (SoS). Circulation. 2008;118(4):381-388. 44. Serruys PW, Morice MC, Kappetein AP, et al. Percutane-ous coronary intervention versus coronary-artery bypass grafting for severe coronary artery disease. N Engl J Med. 2009;360(10):961-972. 45. Mohr FW, Morice MC, Kappetein AP, et al. Coronary artery bypass graft surgery versus percutaneous coronary interven-tion in patients with three-vessel disease and left main cor-onary disease: 5-year follow-up of the randomised, clinical SYNTAX trial. Lancet. 2013;381(9867):629-638. 46. Weintraub WS, Grau-Sepulveda MV, Weiss JM, et al. Com-parative effectiveness of revascularization strategies. N Engl J Med. 2012;366(16):1467-1476. 47. Zhang Z, Kolm P, Grau-Sepulveda MV, et al. Cost-effective-ness of revascularization strategies: the ASCERT study. J Am Coll Cardiol. 2015;65(1):1-11. 48. Stone GW, Sabik JF, Serruys PW, et al. Everolimus-eluting stents or bypass surgery for left main coronary artery disease. N Engl J Med. 2016;375(23):2223-2235. 49. Tatoulis J, Buxton BF, Fuller JA. Patencies of 2127 arterial to coronary conduits over 15 years. Ann Thorac Surg. 2004;77(1): 93-101. 50. Goldman S, Zadina K, Moritz T, et al. Long-term patency of saphenous vein and left internal mammary artery grafts after coronary artery bypass surgery: results from a Department of Veterans Affairs Cooperative Study. J Am Coll Cardiol. 2004;44(11):2149-2156. 51. Dorman MJ, Kurlansky PA, Traad EA, Galbut DL, Zucker M, Ebra G. Bilateral internal mammary artery grafting enhances survival in diabetic patients: a 30-year follow-up of pro-pensity score-matched cohorts. Circulation. 2012;126(25): 2935-2942. 52. Kelly R, Buth KJ, Legare JF. Bilateral internal thoracic artery grafting is superior to other forms of multiple arterial grafting in providing survival benefit after coronary bypass surgery. J Thorac Cardiovasc Surg. 2012;144(6):1408-1415. 53. Athanasiou T, Saso S, Rao C, et al. Radial artery versus saphe-nous vein conduits for coronary artery bypass surgery: forty years of competition—which conduit offers better patency? A systematic review and meta-analysis. Eur J Cardiothorac Surg. 2011;40(1):208-220. 54. Collins P, Webb CM, Chong CF, et al. Radial artery versus saphenous vein patency randomized trial: five-year angio-graphic follow-up. Circulation. 2008;117(22):2859-2864. 55. Zacharias A, Schwann TA, Riordan CJ, Durham SJ, Shah AS, Habib RH. Late results of conventional versus all-arterial revascularization based on internal thoracic and radial artery grafting. Ann Thorac Surg. 2009;87(1):19-26e2. 56. Zacharias A, Habib RH, Schwann TA, Riordan CJ, Durham SJ, Shah A. Improved survival with radial artery versus vein con-duits in coronary bypass surgery with left internal thoracic artery to left anterior descending artery grafting. Circulation. 2004;109(12):1489-1496. 57. Tatoulis J, Wynne R, Skillington PD, Buxton BF. Total arte-rial revascularization: a superior strategy for diabetic patients who require coronary surgery. Ann Thorac Surg. 2016;102(6): 1948-1955. 58. Caracciolo EA, Davis KB, Sopko G, et al. Comparison of sur-gical and medical group survival in patients with left main equivalent coronary artery disease. Long-term CASS experi-ence. Circulation. 1995;91(9):2335-2344. 59. Grover FL, Hammermeister KE, Burchfiel C. Initial report of the Veterans Administration Preoperative Risk Assessment Study for Cardiac Surgery. Ann Thorac Surg. 1990;50(1): 12-26; discussion 27-28. 60. Yusuf S, Zucker D, Peduzzi P, et al. Effect of coronary artery bypass graft surgery on survival: overview of 10-year results from randomised trials by the Coronary Artery Bypass Graft Surgery Trialists Collaboration. Lancet. 1994;344(8922): 563-570. 61. De Lorenzo A, Tura B, Bassan F, Pittella F, Rocha AS. Out-comes of patients with left main coronary artery disease under-going medical or surgical treatment: a propensity-matched analysis. Cor Artery Dis. 2011;22(8):585-589. 62. Influence of diabetes on 5-year mortality and morbidity in a randomized trial comparing CABG and PTCA in patients with multivessel disease: the Bypass Angioplasty Revascularization Investigation (BARI). Circulation. 1997;96(6):1761-1769. 63. Jones RH, Kesler K, Phillips HR 3rd, et al. Long-term survival benefits of coronary artery bypass grafting and percutaneous transluminal angioplasty in patients with coronary artery dis-ease. J Thorac Cardiovasc Surg. 1996;111(5):1013-1025. 64. ElBardissi AW, Aranki SF, Sheng S, O’Brien SM, Greenberg CC, Gammie JS. Trends in isolated coronary artery bypass grafting: an analysis of the Society of Thoracic Surgeons adult cardiac surgery database. J Thorac Cardiovasc Surg. 2012;143(2):273-281. 65. Angelini GD, Taylor FC, Reeves BC, Ascione R. Early and midterm outcome after off-pump and on-pump surgery in Beating Heart Against Cardioplegic Arrest Studies (BHACAS Brunicardi_Ch21_p0801-p0852.indd 84501/03/19 5:32 PM 846SPECIFIC CONSIDERATIONSPART II1 and 2): a pooled analysis of two randomised controlled trials. Lancet. 2002;359(9313):1194-1199. 66. Lemma MG, Coscioni E, Tritto FP, et al. On-pump versus off-pump coronary artery bypass surgery in high-risk patients: operative results of a prospective randomized trial (on-off study). J Thorac Cardiovasc Surg. 2012;143(3):625-631. 67. Mack MJ, Brown P, Houser F, et al. On-pump versus off-pump coronary artery bypass surgery in a matched sample of women: a comparison of outcomes. Circulation. 2004; 110(11 suppl 1):II1-II6. 68. Hu S, Zeng Z, Yuan X, et al. Increasing long-term major vas-cular events and resource consumption in patients receiving off-pump coronary artery bypass: a single-center prospective observational study. Circulation. 2010;121(16):1800-1808. 69. Lamy A, Devereaux PJ, Prabhakaran D, et al. Off-pump or on-pump coronary-artery bypass grafting at 30 days. N Engl J Med. 2012;366(16):1489-1497. 70. Diegeler A, Börgermann J, Kappert U, et al. Off-pump versus on-pump coronary-artery bypass grafting in elderly patients. N Engl J Med. 2013;368(13):1189-1198. 71. Hattler B, Messenger JC, Shroyer Al, et al. Off-Pump coronary artery bypass surgery is associated with worse arterial and saphenous vein graft patency and less effec-tive revascularization: results from the Veterans Affairs Randomized On/Off Bypass (ROOBY) trial. Circulation. 2012;125(23):2827-2835. 72. Hannan EL, Wu C, Smith CR, et al. Off-pump versus on-pump coronary artery bypass graft surgery: differences in short-term outcomes and in long-term mortality and need for subsequent revascularization. Circulation. 2007;116(10):1145-1152. 73. Hueb W, Lopes NH, Pereira AC, et al. Five-year follow-up of a randomized comparison between off-pump and on-pump stable multivessel coronary artery bypass grafting. The MASS III Trial. Circulation. 2010;122(11 suppl):S48-S52. 74. Moller CH, Penninga L, Wetterslev J, Steinbrüchel DA, Gluud C. Off-pump versus on-pump coronary artery bypass grafting for ischaemic heart disease. Cochrane Database Syst Rev. 2012(3):CD007224. 75. Widimsky P, Straka Z, Stros P, et al. One-year coronary bypass graft patency: a randomized comparison between off-pump and on-pump surgery angiographic results of the PRAGUE-4 trial. Circulation. 2004;110(22):3418-3423. 76. Puskas JD, Williams WH, O’Donnell R, et al. Off-pump and on-pump coronary artery bypass grafting are associated with similar graft patency, myocardial ischemia, and freedom from reintervention: long-term follow-up of a randomized trial. Ann Thorac Surg. 2011;91(6):1836-1842; discussion 1842-1843. 77. Sellke FW, Di Maio JM, Caplan LR, et al. Comparing on-pump and off-pump coronary artery bypass grafting: numer-ous studies but few conclusions: a scientific statement from the American Heart Association council on cardiovascular surgery and anesthesia in collaboration with the interdisciplin-ary working group on quality of care and outcomes research. Circulation. 2005;111(21):2858-2864. 78. Lichtenberg A, Kilma U, Paeschke H, et al. Impact of multi-vessel coronary artery disease on outcome after isolated mini-mally invasive bypass grafting of the left anterior descending artery. Ann Thorac Surg. 2004;78(2):487-491. 79. Deppe AC, Liakopoulos OJ, Kuhn EW, et al. Minimally inva-sive direct coronary bypass grafting versus percutaneous coro-nary intervention for single-vessel disease: a meta-analysis of 2885 patients. Eur J Cardiothorac Surg. 2015;47(3):397-406; discussion 406. 80. Lee CW, Ahn JM, Cavalcante R, et al. Coronary artery bypass surgery versus drug-eluting stent implantation for left main or multivessel coronary artery disease: a meta-analysis of individual patient data. JACC Cardiovasc Interv. 2016;9(24): 2481-2489. 81. Acharya MN, Ashrafian H, Athanasiou T, Casula R. Is totally endoscopic coronary artery bypass safe, feasible and effective? Int Cardiovasc Thoracic Surg. 2012;15(6):1040-1046. 82. Bonatti J, Schachner T, Bonaros N, et al. Effectiveness and safety of total endoscopic left internal mammary artery bypass graft to the left anterior descending artery. Am J Cardiol. 2009;104(12):1684-1688. 83. Srivastava S, Gadasalli S, Agusala M, et al. Beating heart totally endoscopic coronary artery bypass. Ann Thorac Surg. 2010;89(6):1873-1879; discussion 1879-1880. 84. Whellan DJ, McCarey MM, Taylor BS, et al. Trends in robotic-assisted coronary artery bypass grafts: a study of the Society of Thoracic Surgeons Adult Cardiac Surgery Database, 2006 to 2012. Ann Thorac Surg. 2016;102(1):140-146. 85. Reicher B, Poston RS, Mehra MR, et al. Simultaneous “hybrid” percutaneous coronary intervention and minimally invasive surgical bypass grafting: feasibility, safety, and clini-cal outcomes. Am Heart J. 2008;155(4):661-667. 86. Holzhey DM, Jacobs S, Mochalski M, et al. Minimally inva-sive hybrid coronary artery revascularization. Ann Thorac Surg. 2008;86(6):1856-1860. 87. Katz MR, Van Praet F, de Canniere D, et al. Integrated coro-nary revascularization: percutaneous coronary intervention plus robotic totally endoscopic coronary artery bypass. Circu-lation. 2006;114(1 suppl):I473-I476. 88. Puskas JD, Halkos ME, DeRose JJ, et al. Hybrid coronary revascularization for the treatment of multivessel coronary artery disease: a multicenter observational study. J Am Coll Cardiol. 2016;68(4):356-365. 89. Briones E, Lacalle JR, Marin I. Transmyocardial laser revas-cularization versus medical therapy for refractory angina. Cochrane Database Syst Rev. 2009(1):CD003712. 90. Allen KB, Dowling RD, Schuch DR, et al. Adjunctive trans-myocardial revascularization: five-year follow-up of a prospec-tive, randomized trial. Ann Thorac Surg. 2004;78(2):458-465; discussion 458-465. 91. Bridges CR, Horvath KA, Nugent WC, et al. The Society of Thoracic Surgeons practice guideline series: transmyocar-dial laser revascularization. Ann Thorac Surg. 2004;77(4): 1494-14502. 92. Henry TD, Annex BH, McKendall GR, et al. The VIVA trial: Vascular endothelial growth factor in Ischemia for Vascular Angiogenesis. Circulation. 2003;107(10):1359-1365. 93. Simons M, Annex BH, Laham RJ, et al. Pharmacological treat-ment of coronary artery disease with recombinant fibroblast growth factor-2: double-blind, randomized, controlled clinical trial. Circulation. 2002;105(7):788-793. 94. Kumar VA, Brewster LP, Caves JM, Chaikof EL. Tis-sue engineering of blood vessels: functional requirements, progress, and future challenges. Cardiovasc Eng Technol. 2011;2(3):137-148. 95. D’Agostino RS, Jacobs JP, Badwar V, et al. The Society of Tho-racic Surgeons adult cardiac surgery database: 2017 update on outcomes and quality. Ann Thorac Surg. 2017;103(1):18-24. 96. Bonow RO, Carabello BA, Chatterjee K, et al. 2008 focused update incorporated into the ACC/AHA 2006 guidelines for the management of patients with valvular heart disease: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Writing Com-mittee to revise the 1998 guidelines for the management of patients with valvular heart disease). Endorsed by the Society of Cardiovascular Anesthesiologists, Society for Cardiovascu-lar Angiography and Interventions, and Society of Thoracic Surgeons. J Am Coll Cardiol. 2008;52(13):e1-142. 97. Rosendaal FR. The Scylla and Charybdis of oral anticoagulant treatment. N Engl J Med. 1996;335(8):587-589. 98. Nishimura RA, et al. 2014 AHA/ACC guideline for the man-agement of patients with valvular heart disease: a report Brunicardi_Ch21_p0801-p0852.indd 84601/03/19 5:32 PM 847ACQUIRED HEART DISEASECHAPTER 21of the American College of Cardiology/American Heart Association Task Force on practice guidelines. Circulation. 2014;129(23):e521-e643. 99. Hammermeister K. Outcomes 15 years after valve replacement with a mechanical versus a bioprosthetic valve: final report of the Veterans Affairs randomized trial. J Am Coll Cardiol. 2000;36(4):1152-1158. 100. Bloomfield P. Choice of heart valve prosthesis. Heart. 2002;87(6):583-589. 101. Butchart EG, et al. Better anticoagulation control improves survival after valve replacement. J Thorac Cardiovasc Surg. 2002;123(4):715-723. 102. Puskas J, Gerdisch M, Nichols D, et al. Reduced anticoagula-tion after mechanical aortic valve replacement: interim results from the prospective randomized on X-valve anticoagulation clinical trial randomized Food and Drug Administration inves-tigational device exemption trial. J Thorac Cardiovasc Surg. 2014;147(4):1202-1210; discussion 1210-1211. 103. Cannegieter SC, Rosendaal FR, Briet E. Thromboembolic and bleeding complications in patients with mechanical heart valve prostheses. Circulation. 1994;89(2):635-641. 104. Hoffmann G, Lutter G, Cremer J. Durability of bioprosthetic cardiac valves. Dtsch Arztebl Int. 2008;105(8):143-148. 105. Pibarot P, Dumesnil JG, Jobin J, Cartier P, Honos G, Durand LG. Hemodynamic and physical performance during maximal exercise in patients with an aortic bioprosthetic valve: com-parison of stentless versus stented bioprostheses. J Am Coll Cardiol. 1999;34(5):1609-1617. 106. Fries R, Wendler O, Schieffer H, Schäfers HJ. Comparative rest and exercise hemodynamics of 23-mm stentless versus 23-mm stented aortic bioprostheses. Ann Thorac Surg. 2000;69(3): 817-22. 107. Pavoni D, Badano LP, Ius F, et al. Limited long-term durabil-ity of the Cryolife O’Brien stentless porcine xenograft valve. Circulation. 2007;116(11 suppl): I307-I313. 108. Powell R, Pelletier MP, Chu MWA, Bouchard D, Melvin KN, Adams C. The perceval sutureless aortic valve: review of outcomes, complications, and future direction. Innovations (Phila). 2017;12(3):155-173. 109. Ross DN. Homograft replacement of the aortic valve. Lancet. 1962;2(7254):487. 110. Anguera I, Miro JM, San Roman JA, et al. Periannular com-plications in infective endocarditis involving prosthetic aortic valves. Am J Cardiol. 2006;98(9):1261-1268. 111. Vogt F, et al. Pulmonary homografts for aortic valve replace-ment: long-term comparison with aortic grafts. Heart Surg Forum. 2011;14(4):E237-E241. 112. Ross DN. Replacement of aortic and mitral valves with a pul-monary autograft. Lancet. 1967;2(7523):956-958. 113. Gerosa G, McKay R, Davies J, Ross DN. Comparison of the aortic homograft and the pulmonary autograft for aortic valve or root replacement in children. J Thorac Cardiovasc Surg. 1991;102(1):51-60; discussion 60-61. 114. David TE, Uden DE, Strauss HD. The importance of the mitral apparatus in left ventricular function after correction of mitral regurgitation. Circulation. 1983;68(3 pt 2):II76-II82. 115. Enriquez-Sarano M, Schaff HV, Orszulak TA, Tajik AJ, Bailey KR, Frye RL. Valve repair improves the outcome of surgery for mitral regurgitation. A multivariate analysis. Circulation. 1995;91(4):1022-1028. 116. David TE, Armstrong S, McCrindle BW, Manlhiot C. Late outcomes of mitral valve repair for mitral regurgitation due to degenerative disease. Circulation. 2013;127(14): 1485-1492. 117. Pfannmueller B, Verevkin A, Borger Ma, et al. Role of tricus-pid valve repair for moderate tricuspid regurgitation during minimally invasive mitral valve surgery. Thorac Cardiovasc Surg. 2013;61(5):386-391. 118. Roberts WC, Perloff JK. Mitral valvular disease. A clinico-pathologic survey of the conditions causing the mitral valve to function abnormally. Ann Intern Med. 1972;77(6):939-975. 119. Snopek G, Pogorzelska H, Rywik TM, Browarek A, Janas J, Korewicki J. Usefulness of endothelin-1 concentration in capillary blood in patients with mitral stenosis as a predic-tor of regression of pulmonary hypertension after mitral valve replacement or valvuloplasty. Am J Cardiol. 2002;90(2): 188-189. 120. Gorlin R. The mechanism of the signs and symptoms of mitral valve disease. Br Heart J. 1954;16(4):375-380. 121. Martin RP, Rakowski H, Kleiman JH, Beaver W, London E, Popp RL. Reliability and reproducibility of two dimensional echocardiograph measurement of the stenotic mitral valve ori-fice area. Am J Cardiol. 1979;43(3):560-568. 122. Cheriex EC, Pieters FA, Janssen JH, de Swart H, Palmans-Meulemans A. Value of exercise Doppler-echocardiography in patients with mitral stenosis. Int J Cardiol. 1994;45(3):219-226. 123. Delling FN, Vasan RS. Epidemiology and pathophysiology of mitral valve prolapse: new insights into disease progression, genetics, and molecular basis. Circulation. 2014;129(21): 2158-2170. 124. Enriquez-Sarano M, Akins CW, Vahanian A. Mitral regurgita-tion. Lancet. 2009;373(9672):1382-1394. 125. Carpentier A. Cardiac valve surgery—the “French correction.” J Thorac Cardiovasc Surg. 1983;86(3):323-337. 126. Zile MR, Gaasch WH, Carroll JD, Levine HJ. Chronic mitral regurgitation: predictive value of preoperative echocardio-graphic indexes of left ventricular function and wall stress. J Am Coll Cardiol. 1984;3(2 pt 1):235-242. 127. Castello R, Fagan L, Jr, Lenzen P, Pearson AC, Labovitz AJ. Comparison of transthoracic and transesophageal echocar-diography for assessment of left-sided valvular regurgitation. Am J Cardiol. 1991;68(17):1677-1680. 128. Enriquez-Sarano M. Quantitative determinants of the out-come of asymptomatic mitral regurgitation. N Engl J Med. 2005;352(9):875-883. 129. Picano E, Pibarot P, Lancellotti P, Monin JL, Bonow RO. The emerging role of exercise testing and stress echocardiography in valvular heart disease. J Am Coll Cardiol. 2009;54(24): 2251-2560. 130. Kitamura N, Uemura S, Kunitomo R, Utoh J, Noji S. A new technique for debridement in rheumatic valvular disease: the rasping procedure. Ann Thorac Surg. 2000;69(1):121-125. 131. Reichart DT, Sodian R, Zenker R, Klinner W, Schmitz C, Reichart B. Long-term (</= 50 years) results of patients after mitral valve commissurotomy—a single-center experience. J Thorac Cardiovasc Surg. 2012;143(4 suppl):S96-S98. 132. Choudhary SK, Dhareshwar J, Govil A, Airan B, Kumar AS. Open mitral commissurotomy in the current era: indications, technique, and results. Ann Thorac Surg. 2003;75(1):41-46. 133. Mohty D, Orszulak TA, Schaff HV, et al. Very long-term sur-vival and durability of mitral valve repair for mitral valve prolapse. Circulation. 2001;104(12 suppl 1):I1-I7. 134. Vassileva CM, Mishkel G, McNeely C, et al. Long-term sur-vival of patients undergoing mitral valve repair and replace-ment: a longitudinal analysis of medicare fee-for-service beneficiaries. Circulation. 2013;127(18):1870-1876. 135. Khan SS, Trento A, DeRobertis M, et al. Twenty-year com-parison of tissue and mechanical valve replacement. J Thorac Cardiovasc Surg. 2001;122(2):257-269. 136. Gillinov AM, Cosgrove DM. Mitral valve repair for degenera-tive disease. J Heart Valve Dis. 2002;11(suppl 1):S15-S20. 137. Fucci C. Improved results with mitral valve repair using new surgical techniques. Eur J Cardiothorac Surg. 1995;9(11): 621-626. 138. O’Brien SM, Shahian DM, Filardo G, et al. The Society of Thoracic Surgeons 2008 cardiac surgery risk models: part Brunicardi_Ch21_p0801-p0852.indd 84701/03/19 5:32 PM 848SPECIFIC CONSIDERATIONSPART II2—isolated valve surgery. Ann Thorac Surg. 2009;88(1 suppl): S23-S42. 139. Castillo JG, Anyanwu AC, El-Eshmawi A, Adams DH. All anterior and bileaflet mitral valve prolapses are repairable in the modern era of reconstructive surgery. Eur J Cardiothorac Surg. 2014;45(1):139-145. 140. Braunberger E, Deloche A, Berrebi A, et al. Very long-term results (more than 20 years) of valve repair with carpentier’s techniques in nonrheumatic mitral valve insufficiency. Circu-lation. 2001;104(12 suppl 1):I8-I11. 141. Acker MA, Parides MK, Perrault LP, et al. Mitral-valve repair versus replacement for severe ischemic mitral regurgitation. N Engl J Med. 2014;370(1):23-32. 142. Goldstein D, Moskowitz AJ, Geljins AC, et al. Two-year out-comes of surgical treatment of severe ischemic mitral regurgi-tation. N Engl J Med. 2016;374(4):344-353. 143. Feldman T, Wasserman HS, Herrmann HC, et al. Percutane-ous mitral valve repair using the edge-to-edge technique: six-month results of the EVEREST Phase I Clinical Trial. J Am Coll Cardiol. 2005;46(11):2134-2140. 144. Feldman T, Foster E, Glower DD, et al. Percutaneous repair or surgery for mitral regurgitation. N Engl J Med. 2011;364(15): 1395-1406. 145. O’Brien KD. Pathogenesis of calcific aortic valve disease: a disease process comes of age (and a good deal more). Arterio-scler Thromb Vasc Biol. 2006;26(8):1721-1728. 146. Murakami T, Hess OM, Gage JE, Grimm J, Krayenbuehl HP. Diastolic filling dynamics in patients with aortic stenosis. Cir-culation. 1986;73(6):1162-1174. 147. Gunther S, Grossman W. Determinants of ventricular func-tion in pressure-overload hypertrophy in man. Circulation. 1979;59(4):679-688. 148. Marcus ML, Doty DB, Hiratzka LF, Wright CB, Eastham CL. Decreased coronary reserve: a mechanism for angina pectoris in patients with aortic stenosis and normal coronary arteries. N Engl J Med. 1982;307(22):1362-1366. 149. Gaasch WH, Zile MR, Hoshino PK, Weinberg EO, Rhodes DR, Apstein CS. Tolerance of the hypertrophic heart to ischemia. Studies in compensated and failing dog hearts with pressure overload hypertrophy. Circulation. 1990;81(5):1644-1653. 150. Orsinelli DA, Aurigemma GP, Battista S, Krendel S, Gaasch WH. Left ventricular hypertrophy and mortality after aortic valve replacement for aortic stenosis. A high risk sub-group identified by preoperative relative wall thickness. J Am Coll Cardiol. 1993;22(6):1679-1683. 151. Lumley M, Williams R, Asrress KN, et al. Coronary physiol-ogy during exercise and vasodilation in the healthy heart and in severe aortic stenosis. J Am Coll Cardiol. 2016;68(7):688-697. 152. Nishimura RA, Otto CM, Bonow RO, et al. 2017 AHA/ACC focused update of the 2014 aha/acc guideline for the man-agement of patients with valvular heart disease: a report of the American College of Cardiology/American Heart Asso-ciation task force on clinical practice guidelines. Circulation. 2017;135(25):e1159-e1195. 153. Roberts WC, JO JM, Moore TR, Jones WH. Causes of pure aortic regurgitation in patients having isolated aortic valve replacement at a single US tertiary hospital (1993 to 2005). Circulation. 2006;114(5):422-429. 154. Roberts WC, Ko JM. Frequency by decades of unicuspid, bicus-pid, and tricuspid aortic valves in adults having isolated aortic valve replacement for aortic stenosis, with or without associ-ated aortic regurgitation. Circulation. 2005;111(7):920-925. 155. Grossman W, Jones D, McLaurin LP. Wall stress and pat-terns of hypertrophy in the human left ventricle. J Clin Invest. 1975;56(1):56-64. 156. Ross J, Jr, McCullagh WH. Nature of enhanced performance of the dilated left ventricle in the dog during chronic volume overloading. Circ Res. 1972;30(5):549-556. 157. Wisenbaugh T, Spann SF, Carabello BA. Differences in myo-cardial performance and load between patients with similar amounts of chronic aortic versus chronic mitral regurgitation. J Am Coll Cardiol. 1984;3(4):916-923. 158. Ross J, Jr. Afterload mismatch in aortic and mitral valve dis-ease: implications for surgical therapy. J Am Coll Cardiol. 1985;5(4):811-826. 159. Nienaber CA, von Kodolitsch Y, Nicolas V, et al. The diagnosis of thoracic aortic dissection by noninvasive imaging proce-dures. N Engl J Med. 1993;328(1):1-9. 160. Smith DC, Bansal RC. Transesophageal echocardiography in the diagnosis of traumatic rupture of the aorta. N Engl J Med. 1995;332(6):356-362. 161. Sasaki Hirai H, Hosono M, et al. Adding coronary artery bypass grafting to aortic valve replacement increases opera-tive mortality for elderly (70 years and older) patients with aortic stenosis. Gen Thorac Cardiovasc Surg. 2013;61(11): 626-631. 162. de Kerchove L, Boodhwani M, Glineur D, et al. Valve sparing-root replacement with the reimplantation technique to increase the durability of bicuspid aortic valve repair. J Thorac Cardio-vasc Surg. 2011 Dec;142(6):1430-8. 163. El Khoury G, de Kerchove L. Principles of aortic valve repair. J Thorac Cardiovasc Surg. 2013;145(3 suppl):S26-S29. 164. Mokhles MM, Rizopoulos D, Andrinopoulou ER, et al. Autograft and pulmonary allograft performance in the sec-ond post-operative decade after the Ross procedure: insights from the Rotterdam Prospective Cohort Study. Eur Heart J. 2012;33(17):2213-2224. 165. Chambers JC, Somerville J, Stone S, Ross DN. Pulmonary autograft procedure for aortic valve disease: long-term results of the pioneer series. Circulation. 1997;96(7):2206-2214. 166. Leon MB, Smith CR, Mack M, et al. Transcatheter aortic-valve implantation for aortic stenosis in patients who cannot undergo surgery. N Engl J Med. 2010;363(17):1597-1607. 167. Leon MB, Smith CR, Mack MJ, et al. Transcatheter or surgical aortic-valve replacement in intermediate-risk patients. N Engl J Med. 2016;374(17):1609-1620. 168. Reardon MJ, Van Mieghem NM, Popma JJ, et al. Surgical or transcatheter aortic-valve replacement in intermediate-risk patients. N Engl J Med. 2017;376(14):1321-1331. 169. Shinn SH, Schaff HV. Evidence-based surgical management of acquired tricuspid valve disease. Nature reviews. Cardiology. 2013;10(4):190-203. 170. Galloway AC, Grossi EA, Baumann FG. Multiple valve operation for advanced valvular heart disease: results and risk factors in 513 patients. J Am Coll Cardiol. 1992;19(4): 725-732. 171. Hunt SA, Abraham WT, Chin MH, et al. 2009 focused update incorporated into the ACC/AHA 2005 guidelines for the diag-nosis and management of heart failure in adults: a report of the American College of Cardiology Foundation/American Heart Association task force on practice guidelines: developed in collaboration with the International Society for Heart and Lung Transplantation. Circulation. 2009;119(14):e391-e479. 172. Kilic A, Ailawadi G. Left ventricular assist devices in heart failure. Expert Rev Cardiovasc Ther. 2012;10(5):649-656. 173. Harper AM, Rosendale JD. The UNOS OPTN waiting list and donor registry: 1988-1996. Clin Transpl. 1996:69-90. 174. Go AS, Mozaffarian D, Roger VL, et al. Heart disease and stroke statistics—2013 update a report from the American Heart Association. Circulation. 2013;127(1):143-152. 175. Levy D, Kenchaiah S, Larson MG, et al. Long-term trends in the incidence of and survival with heart failure. N Engl J Med. 2002;347(18):1397-1402. 176. Jones RH, Velazquez EJ, Michler RE, et al. Coronary bypass surgery with or without surgical ventricular reconstruction. N Engl J Med. 2009;360(17):1705-1717.Brunicardi_Ch21_p0801-p0852.indd 84801/03/19 5:32 PM 849ACQUIRED HEART DISEASECHAPTER 21 177. McGee EC, Jr, McCarthy PM. Do patients with heart failure benefit from coronary artery bypass grafting? Curr Opin Cardiol. 2012;27(6):629-633. 178. Allman KC, Shaw LJ, Hachamovitch R, Udelson JE. Myo-cardial viability testing and impact of revascularization on prognosis in patients with coronary artery disease and left ventricular dysfunction: a meta-analysis. J Am Coll Cardiol. 2002;39(7):1151-1158. 179. Chareonthaitawee P, Gersh BJ, Araoz PA, Gibbons RJ. Revas-cularization in severe left ventricular dysfunction: the role of viability testing. J Am Coll Cardiol. 2005;46(4):567-574. 180. Gerber BL, Rousseau MF, Ahn SA, et al. Prognostic value of myocardial viability by delayed-enhanced magnetic resonance in patients with coronary artery disease and low ejection frac-tion: impact of revascularization therapy. J Am Coll Cardiol. 2012;59(9):825-835. 181. Langenburg SE, Buchanan SA, Blackbourne LH, et al. Pre-dicting survival after coronary revascularization for ischemic cardiomyopathy. Ann Thorac Surg. 1995;60(5):1193-1196; discussion 1196-1197. 182. Yamaguchi A, Ino T, Adachi H, et al. Left ventricular volume predicts postoperative course in patients with ischemic cardio-myopathy. Ann Thorac Surg. 1998;65(2):434-438. 183. Penicka M, Bartunek J, Lang O, et al. Severe left ventricular dyssynchrony is associated with poor prognosis in patients with moderate systolic heart failure undergoing coronary artery bypass grafting. J Am Coll Cardiol. 2007;50(14):1315-1323. 184. Ciarka A, Van de Veire N. Secondary mitral regurgita-tion: pathophysiology, diagnosis, and treatment. Heart. 2011;97(12):1012-1023. 185. Grigioni F, Enriquez-Sarano M, Zehr KJ, Bailey KR, Tajik AJ. Ischemic mitral regurgitation: long-term outcome and prog-nostic implications with quantitative Doppler assessment. Cir-culation. 2001;103(13):1759-1764. 186. Trichon BH, Felker GM, Shaw LK, Cabell CH, O’Connor CM. Relation of frequency and severity of mitral regurgitation to survival among patients with left ventricular systolic dysfunction and heart failure. Am J Cardiol. 2003;91(5): 538-543. 187. Ellis SG, Whitlow PL, Raymond RE, Schneider JP. Impact of mitral regurgitation on long-term survival after percutaneous coronary intervention. Am J Cardiol. 2002;89(3):315-318. 188. Vahanian A, Alfieri O, Andreotti F, et al. Guidelines on the management of valvular heart disease: the task force on the management of valvular heart disease of the European Society of Cardiology. Eur Heart J. 2007;28(2):230-268. 189. DiDonato M, Sabatier M, Dor V, Buckberg G; RESTORE Group. Ventricular arrhythmias after LV remodelling: surgi-cal ventricular restoration or ICD? Heart Fail Rev. 2004;9(4): 299-306; discussion 347-351. 190. Mihaljevic T, Lam BK, Rajeswaran J, et al. Impact of mitral valve annuloplasty combined with revascularization in patients with functional ischemic mitral regurgitation. J Am Coll Cardiol. 2007;49(22):2191-2201. 191. Wu AH, Aaronson KD, Bolling SF, Pagani FD, Welch K, Koelling TM. Impact of mitral valve annuloplasty on mortality risk in patients with mitral regurgitation and left ventricular systolic dysfunction. J Am Coll Cardiol. 2005;45(3):381-387. 192. Michler RE, Smith PK, Parides MK, et al. Two-year outcomes of surgical treatment of moderate ischemic mitral regurgita-tion. N Engl J Med. 2016;374(20):1932-1941. 193. Acker MA, Bolling S, Shemin R, et al. Mitral valve surgery in heart failure: insights from the Acorn Clinical Trial. J Thorac Cardiovasc Surg. 2006;132(3):568-577, 577 e1-e4. 194. McGee EC, Gillinov AM, Blackstone EH, et al. Recur-rent mitral regurgitation after annuloplasty for functional ischemic mitral regurgitation. J Thorac Cardiovasc Surg. 2004;128(6):916-924. 195. Bax JJ, Braun J, Somer ST, et al. Restrictive annuloplasty and coronary revascularization in ischemic mitral regurgita-tion results in reverse left ventricular remodeling. Circulation. 2004;110(11 suppl 1):II103-II108. 196. Bogaert J, Maes A, Van de Werf F, et al. Functional recovery of subepicardial myocardial tissue in transmural myocardial infarction after successful reperfusion: an important contribu-tion to the improvement of regional and global left ventricular function. Circulation. 1999;99(1):36-43. 197. Dor V, Sabatier M, Montiglio F, Civaia F, DiDonato M. Endoventricular patch reconstruction of ischemic failing ven-tricle. A single center with 20 years experience. Advantages of magnetic resonance imaging assessment. Heart Fail Rev. 2004;9(4):269-286. 198. Costa MA, Mazzaferri EL, Jr, Sievert H, Abraham WT. Per-cutaneous ventricular restoration using the parachute device in patients with ischemic heart failure: three-year outcomes of the PARACHUTE first-in-human study. Circ Heart Fail. 2014;7(5):752-758. 199. Fenoglio JJ, Jr, Pham TD, Harken AH, Horowitz LN, Josephson ME, Wit AL. Recurrent sustained ventricular tachy-cardia: structure and ultrastructure of subendocardial regions in which tachycardia originates. Circulation. 1983;68(3): 518-533. 200. Scherlag BJ, el-Sherif N, Hope R, Lazzara R. Characteriza-tion and localization of ventricular arrhythmias resulting from myocardial ischemia and infarction. Circulation Res. 1974;35(3):372-383. 201. Koilpillai C, Quiñones MA, Greenberg B, et al. Rela-tion of ventricular size and function to heart failure sta-tus and ventricular dysrhythmia in patients with severe left ventricular dysfunction. Am J Cardiol. 1996;77(8): 606-611. 202. Hassapoyannes CA, Stuck LM, Hornung CA, Berbin MC, Flowers NC. Effect of left ventricular aneurysm on risk of sud-den and nonsudden cardiac death. Am J Cardiol. 1991;67(6): 454-459. 203. Sartipy U, Albage A, Lindblom D. Improved health-related quality of life and functional status after surgical ventricular restoration. Ann Thorac Surg. 2007;83(4):1381-1387. 204. Isomura T. Surgical left ventricular reconstruction. Gen Tho-rac Cardiovasc Surg. 2011;59(5):315-325. 205. Maxey TS, Reece TB, Ellman PI, et al. Coronary artery bypass with ventricular restoration is superior to coronary artery bypass alone in patients with ischemic cardiomyopathy. J Thorac Cardiovasc Surg. 2004;127(2):428-434. 206. Mickleborough LL, Merchant N, Ivanov J, Rao V, Carson S. Left ventricular reconstruction: early and late results. J Thorac Cardiovasc Surg. 2004;128(1):27-37. 207. Athanasuleas CL, Buckberg GD, Stanley AW, et al. Surgi-cal ventricular restoration: the RESTORE Group experience. Heart Fail Rev. 2004;9(4):287-297. 208. Dor V, Sabatier M, Montiglio F, Rossi P, Toso A, Di Donato M. Results of nonguided subtotal endocardiectomy asso-ciated with left ventricular reconstruction in patients with ischemic ventricular arrhythmias. J Thorac Cardiovasc Surg. 1994;107(5):1301-1307; discussion 1307-1308. 209. Sartipy U, Albåge A, Strååt E, Insulander P, Lindblom D. Sur-gery for ventricular tachycardia in patients undergoing left ventricular reconstruction by the Dor procedure. Ann Thorac Surg. 2006;81(1):65-71. 210. Matthias Bechtel JF, Tölg R, Graf B, et al. High incidence of sudden death late after anterior LV-aneurysm repair. Eur J Cardiothorac Surg. 2004;25(5):807-811. 211. O’Neill JO, Starling RC, Khaykin Y, et al. Residual high inci-dence of ventricular arrhythmias after left ventricular recon-structive surgery. J Thorac Cardiovasc Surg. 2005;130(5): 1250-1256.Brunicardi_Ch21_p0801-p0852.indd 84901/03/19 5:32 PM 850SPECIFIC CONSIDERATIONSPART II 212. Buckberg GD, Athanasuleas CL. The STICH trial: misguided conclusions. J Thorac Cardiovasc Surg. 2009;138(5): 1060-1064 e2. 213. Dor V, Civaia F, Alexandrescu C, Sabatier M, Montiglio F. Favorable effects of left ventricular reconstruction in patients excluded from the Surgical Treatments for Isch-emic Heart Failure (STICH) trial. J Thorac Cardiovasc Surg. 2011;141(4):905-916, 916 e1-e4. 214. Kang N, Edwards M, Larbalestier R. Preoperative intraaor-tic balloon pumps in high-risk patients undergoing open heart surgery. Ann Thorac Surg. 2001;72(1):54-57. 215. Thiele H, Zeymer U, Neumann FJ, et al. Intraaortic balloon support for myocardial infarction with cardiogenic shock. N Engl J Med. 2012;367(14):1287-1296. 216. Meharwal ZS, Trehan N. Vascular complications of intra-aortic balloon insertion in patients undergoing coronary reavs-cularization: analysis of 911 cases. Eur J Cardiovasc Surg. 2002;21(4):741-747. 217. Kirklin JK, Pagani FD, Kormos RL, et al. Eighth annual INTERMACS report: special focus on framing the impact of adverse events. J Heart Lung Transplant. 2017; 36(10): 1080-1086. 218. Rose EA, Gelijns AC, Moskowitz AJ, et al. Long-term use of a left ventricular assist device for end-stage heart failure. N Engl J Med. 2001;345(20):1435-1443. 219. Maybaum S, Mancini D, Xydas S, et al. Cardiac improve-ment during mechanical circulatory support: a prospective multicenter study of the LVAD Working Group. Circulation. 2007;115(19):2497-2505. 220. Lamarche Y, Kearns M, Josan K, et al. Successful weaning and explantation of the Heartmate II left ventricular assist device. Can J Cardiol. 2011;27(3):358-362. 221. Birks EJ, George RS, Hedger M, et al. Reversal of severe heart failure with a continuous-flow left ventricular assist device and pharmacological therapy: a prospective study. Circulation. 2011;123(4):381-390. 222. Birks EJ, Tansley PD, Hardy J, et al. Left ventricular assist device and drug therapy for the reversal of heart failure. N Engl J Med. 2006;355(18):1873-1884. 223. Chugh AR, Beache GM, Loughran JH, et al. Administra-tion of cardiac stem cells in patients with ischemic cardio-myopathy: the SCIPIO trial: surgical aspects and interim analysis of myocardial function and viability by magnetic resonance. Circulation. 2012;126(11 suppl 1):S54-S64. 224. Hare JM, Fishman JE, Gerstenblith G, et al. Comparison of allogeneic vs autologous bone marrow-derived mesenchymal stem cells delivered by transendocardial injection in patients with ischemic cardiomyopathy: the POSEIDON randomized trial. JAMA. 2012;308(22):2369-2379. 225. Miller LW, Pagani FD, Russell SD, et al. Use of a continuous-flow device in patients awaiting heart transplantation. N Engl J Med. 2007;357(9):885-896. 226. Frazier OH, Rose EA, Oz MC, et al. Multicenter clinical eval-uation of the HeartMate vented electric left ventricular assist system in patients awaiting heart transplantation. J Thorac Cardiovasc Surg. 2001;122(6):1186-1195. 227. Aaronson KD, Slaughter MS, Miller LW, et al. Use of an intrapericardial, continuous-flow, centrifugal pump in patients awaiting heart transplantation. Circulation. 2012;125(25): 3191-3200. 228. John R, Pagani FD, Naka Y, et al. Post-cardiac transplant survival after support with a continuous-flow left ventricu-lar assist device: impact of duration of left ventricular assist device support and other variables. J Thorac Cardiovasc Surg. 2010;140(1):174-181. 229. Pal JD, Piacentino V, Cuevas AD, et al. Impact of left ven-tricular assist device bridging on posttransplant outcomes. Ann Thorac Surg. 2009;88(5):1457-1461; discussion 1461. 230. Mehra MR, Naka Y, Uriel N, et al. A fully magnetically levi-tated circulatory pump for advanced heart failure. N Engl J Med. 2017;376(5):440-450. 231. Slaughter MS, Rogers JG, Milano CA, et al. Advanced heart failure treated with continuous-flow left ventricular assist device. N Engl J Med. 2009;361(23):2241-2251. 232. Kirklin JK, Naftel DC, Pagani FD, et al. Long-term mechani-cal circulatory support (destination therapy): on track to com-pete with heart transplantation? J Thorac Cardiovasc Surg. 2012;144(3):584-603; discussion 597-598. 233. Slaughter MS, Pagani FD, McGee EC, et al. HeartWare ven-tricular assist system for bridge to transplant: combined results of the bridge to transplant and continued access protocol trial. J Heart Lung Transplant. 2013;32(7):675-683. 234. Yancy CW, Jessup M, Bozkurt B, et al. 2013 ACCF/AHA guideline for the management of heart failure: a report of the American College of Cardiology Foundation/American Heart Association task force on practice guidelines. J Am Coll Cardiol. 2013;62(16):e147-e239. 235. John R, Liao K, Kamdar F, Eckman P, Boyle A, Colvin-Adams M. Effects on preand posttransplant pulmonary hemody-namics in patients with continuous-flow left ventricular assist devices. J Thorac Cardiovasc Surg. 2010;140(2):447-452. 236. Kormos RL, Teuteberg JJ, Pagani FD, et al. Right ventricu-lar failure in patients with the HeartMate II continuous-flow left ventricular assist device: incidence, risk factors, and effect on outcomes. J Thorac Cardiovasc Surg. 2010;139(5): 1316-1324. 237. Neragi-Miandoab S. A ventricular assist device as a bridge to recovery, decision making, or transplantation in patients with advanced cardiac failure. Surg Today. 2012;42(10):917-926. 238. Copeland JG, Smith RG, Arabia FA, et al. Cardiac replace-ment with a total artificial heart as a bridge to transplantation. N Engl J Med. 2004;351(9):859-867. 239. El-Hamamsy I, Jacques F, Perrault LP, et al. Results follow-ing implantation of mechanical circulatory support systems: the Montreal Heart Institute experience. Can J Cardiol. 2009;25(2):107-110. 240. Meyer A, Slaughter M. The total artificial heart. Panminerva Med. 2011;53(3):141-154. 241. Gammie JS, Haddad M, Milford Beland S, et al. Atrial fibril-lation correction surgery: lessons from the Society of Tho-racic Surgeons national cardiac database. Ann Thorac Surg. 2008;85(3):909-914. 242. Ad N, Suri RM, Gammie JS, Sheng S, O’Brien SM, Henry L. Surgical ablation of atrial fibrillation trends and outcomes in North America. J Thorac Cardiovasc Surg. 2012;144(5): 1051-1060. 243. Calkins H, Kuck KH, Cappato R, et al. 2012 HRS/EHRA/ECAS expert consensus statement on catheter and surgical ablation of atrial fibrillation: recommendations for patient selection, procedural techniques, patient management and follow-up, definitions, endpoints, and research trial design: a report of the Heart Rhythm Society (HRS) Task Force on Catheter and Surgical Ablation of Atrial Fibrillation. Devel-oped in partnership with the European Heart Rhythm Associa-tion (EHRA), a registered branch of the European Society of Cardiology (ESC) and the European Cardiac Arrhythmia Soci-ety (ECAS); and in collaboration with the American College of Cardiology (ACC), American Heart Association (AHA), the Asia Pacific Heart Rhythm Society (APHRS), and the Society of Thoracic Surgeons (STS). Endorsed by the governing bod-ies of the American College of Cardiology Foundation, the American Heart Association, the European Cardiac Arrhythmia Society, the European Heart Rhythm Association, the Society of Thoracic Surgeons, the Asia Pacific Heart Rhythm Soci-ety, and the Heart Rhythm Society. Heart Rhythm. 2012;9(4): 632-696 e21.Brunicardi_Ch21_p0801-p0852.indd 85001/03/19 5:32 PM 851ACQUIRED HEART DISEASECHAPTER 21 244. Hart RG, Halperin JL. Atrial fibrillation and thromboembo-lism: a decade of progress in stroke prevention. Ann Intern Med. 1999;131(9):688-695. 245. Zimetbaum P. Antiarrhythmic drug therapy for atrial fibrilla-tion. Circulation. 2012;125(2):381-389. 246. Potpara TS, Lip GY. Oral anticoagulant therapy in atrial fibril-lation patients at high stroke and bleeding risk. Prog Cardio-vasc Dis. 2015;58(2):177-194. 247. Corley SD, Epstein AE, Di Marco JP, et al. Relationships between sinus rhythm, treatment, and survival in the Atrial Fibrillation Follow-Up Investigation of Rhythm Management (AFFIRM) study. Circulation. 2004;109(12):1509-1513. 248. Cox JL, Ad N, Palazzo T. Impact of the maze procedure on the stroke rate in patients with atrial fibrillation. J Thorac Cardio-vasc Surg. 1999;118(5):833-840. 249. Feinberg MS, Waggoner AD, Kater KM, Cox JL, Lindsay BD, Pérez JE. Restoration of atrial function after the maze proce-dure for patients with atrial fibrillation. Assessment by Doppler echocardiography. Circulation. 1994;90(5 pt 2):II285-II292. 250. Gillinov AM, Geljins AC, Parides MK, et al. Surgical ablation of atrial fibrillation during mitral-valve surgery. N Engl J Med. 2015;372(15):1399-1409. 251. Cox JL. Surgical ablation for atrial fibrillation. N Engl J Med. 2015;373(5):483. 252. Badhwar V, Rankin JS, Damiano RE, Jr, et al. The Society of Thoracic Surgeons 2017 clinical practice guidelines for the surgical treatment of atrial fibrillation. Ann Thorac Surg. 2017;103(1):329-341. 253. Weimar T, Schena S, Bailey MS, et al. The Cox-maze IV pro-cedure for lone atrial fibrillation: a single center experience in 100 consecutive patients. J Interv Card Electrophysiol. 2011;31(1):47-54. 254. Robertson JO, Saint LL, Leidenfrost JE, Damiano RJ, Jr. Illus-trated techniques for performing the Cox-Maze IV procedure through a right mini-thoracotomy. Ann Cardiothorac Surg. 2014;3(1):105-116. 255. Henn MC, Lancaster TS, Miller JR, et al. Late outcomes after the Cox maze IV procedure for atrial fibrillation. J Thorac Cardiovasc Surg. 2015;150(5):1168-1176, 1178 e1-e2. 256. Musharbash FN, Schill MR, Sinn LA, et al. Performance of the Cox-maze IV procedure is associated with improved long-term survival in patients with atrial fibrillation undergo-ing cardiac surgery. J Thorac Cardiovasc Surg. 2018;155(1): 159-170. 257. Lall SC, Melby SJ, Voeller RK, et al. The effect of ablation technology on surgical outcomes after the Cox-maze pro-cedure: a propensity analysis J Thorac Cardiovasc Surg. 2007;133(2):389-396. 258. Pet M, Robertson JO, Bailey M, et al. The impact of CHADS(2) score on late stroke after the Cox maze procedure. J Thorac Cardiovasc Surg. 2013;146(1):85-89. 259. Bleeding during antithrombotic therapy in patients with atrial fibrillation. The Stroke Prevention in Atrial Fibrillation Inves-tigators. Arch Intern Med. 1996;156(4):409-416. 260. Barnett SD, Ad N. Surgical ablation as treatment for the elimi-nation of atrial fibrillation: a meta-analysis. J Thorac Cardio-vasc Surg. 2006;131(5):1029-1035. 261. Schuessler RB, Kay MW, Melby SJ, Branham BH, Boineau JP, Damiano RJ, Jr. Spatial and temporal stability of the domi-nant frequency of activation in human atrial fibrillation. J Electrocardiol. 2006;39(4 suppl):S7-S12. 262. Edgerton JR, Edgerton ZJ, Weaver T, et al. Minimally invasive pulmonary vein isolation and partial autonomic denervation for surgical treatment of atrial fibrillation. Ann Thorac Surg. 2008;86(1):35-38; discussion 39. 263. Jazayeri MA, Vuddanda, Turagam MK, et al. Safety profiles of percutaneous left atrial appendage closure devices: an analysis of the Food and Drug Administration manufacturer and user facility device experience (MAUDE) database from 2009-2016. J Cardiovasc Electrophysiol. 2018;29(1):5-13. 264. Boersma LV, Castella M, van Boven W, et al. Atrial fibril-lation catheter ablation versus surgical ablation treatment (FAST): a 2-center randomized clinical trial. Circulation. 2012;125(1):23-30. 265. Imazio M, Demichelis B, Parrini I, et al. Day-hospital treat-ment of acute pericarditis: a management program for outpa-tient therapy. J Am Coll Cardiol. 2004;43(6):1042-1046. 266. Launbjerg J, Fruergaard P, Hesse B, Jørgensen F, Elsborg L, Petri A. Long-term risk of death, cardiac events and recurrent chest pain in patients with acute chest pain of different origin. Cardiology. 1996;87(1):60-66. 267. Dudzinski DM, Mak GS, Hung JW. Pericardial diseases. Curr Probl Cardiol. 2012;37(3):75-118. 268. Lange RA, Hillis LD. Clinical practice. Acute pericarditis. N Engl J Med. 2004;351(21):2195-2202. 269. Spodick DH. Acute pericarditis: current concepts and practice. JAMA. 2003;289(9):1150-1153. 270. Bruce MA, Spodick DH. Atypical electrocardiogram in acute pericarditis: characteristics and prevalence. J Electrocardiol. 1980;13(1):61-66. 271. Salisbury AC, Olalla-Gómez C, Rihal CS, et al. Frequency and predictors of urgent coronary angiography in patients with acute pericarditis. Mayo Clin Proc. 2009. 84(1):11-15. 272. Imazio M, Brucato A, Maestroni S, et al. Prevalence of C-reactive protein elevation and time course of normalization in acute pericarditis: implications for the diagnosis, therapy, and prog-nosis of pericarditis. Circulation. 2011;123(10):1092-1097. 273. Imazio M, Bobbio M, Cecchi E, et al. Colchicine in addition to conventional therapy for acute pericarditis: results of the COlchicine for acute PEricarditis (COPE) trial. Circulation. 2005;112(13):2012-2016. 274. Khandaker MH, Espinosa RE, Nishimura R, et al. Pericar-dial disease: diagnosis and management. Mayo Clin Proc. 2010;85(6):572-593. 275. Fowler NO. Recurrent pericarditis. Cardiol Clin. 1990;8(4): 621-626. 276. Khandaker MH, Schaff HV, Greason KL, et al. Pericardiec-tomy vs medical management in patients with relapsing peri-carditis. Mayo Clin Proc. 2012;87(11):1062-1070. 277. Tuna IC, Danielson GK. Surgical management of pericardial diseases. Cardiol Clin. 1990;8(4):683-696. 278. Azam S, Hoit BD. Treatment of pericardial disease. Cardio-vasc Ther. 2011;29(5):308-314. 279. Feng D, Glockner J, Kim K, et al. Cardiac magnetic resonance imaging pericardial late gadolinium enhancement and elevated inflammatory markers can predict the reversibility of constric-tive pericarditis after antiinflammatory medical therapy: a pilot study. Circulation. 2011;124(17):1830-1837. 280. Gillaspie EA, Stulak JM, Daly RC, et al. A 20-year experi-ence with isolated pericardiectomy: analysis of indications and outcomes. J Thorac Cardiovasc Surg. 2016;152(2): 448-458. 281. Busch C, Penov K, Amorim PA, et al. Risk factors for mor-tality after pericardiectomy for chronic constrictive pericardi-tis in a large single-centre cohort. Eur J Cardiothorac Surg. 2015;48(6):e110-e116. 282. Ariyoshi T, Hashizume K, Taniguchi S, et al. Surgical experi-ence with chronic constrictive pericarditis. Gen Thorac Car-diovasc Surg. 2012;60 (12):796-802. 283. Chowdhury UK, Subramaniam GK, Kumar AS, et al. Peri-cardiectomy for constrictive pericarditis: a clinical, echo-cardiographic, and hemodynamic evaluation of two surgical techniques. Ann Thorac Surg. 2006;81(2):522-529. 284. Bertog SC, Thambidorai SK, Parakh K, et al. Constrictive pericarditis: etiology and cause-specific survival after pericar-diectomy. J Am Coll Cardiol. 2004;43(8):1445-1452.Brunicardi_Ch21_p0801-p0852.indd 85101/03/19 5:32 PM 852SPECIFIC CONSIDERATIONSPART II 285. DeValeria PA, Baumgartner WA, Casale AS, et al. Current indications, risks, and outcome after pericardiectomy. Ann Thorac Surg. 1991;52(2): 219-224. 286. Ghavidel AA, Gholampour, Kyavar M, et al. Constrictive pericarditis treated by surgery. Tex Heart Inst J. 2012;39(2): 199-205. 287. Ling LH, et al. Constrictive pericarditis in the modern era: evolving clinical spectrum and impact on outcome after peri-cardiectomy. Circulation. 1999;100(13):1380-1386. 288. Abushaban L, Denham B, Duff D. 10 year review of cardiac tumours in childhood. Br Heart J. 1993;70(2):166-169. 289. Reynen K. Frequency of primary tumors of the heart. Am J Cardiol. 1996;77(1):107. 290. Butany J, Leong SW, Carmichael K, Komeda M. A 30-year analysis of cardiac neoplasms at autopsy. Can J Cardiol. 2005;21(8):675-680. 291. Pinede L, Duhaut P, Loire R. Clinical presentation of left atrial cardiac myxoma. A series of 112 consecutive cases. Medicine (Baltimore). 2001;80(3):159-172. 292. Castillo JG, Silvay GG. Characterization and management of car-diac tumors. Semin Cardiothorac Vasc Anesth. 2010;14(1): 6-20. 293. Kusano KF, Ohe T. Cardiac tumors that cause arrhythmias. Cardiac Electrophysiol Rev. 2002;6(1-2):174-177. 294. Lee VH, Connolly HM, Brown RD, Jr. Central nervous system manifestations of cardiac myxoma. Arch Neurol. 2007;64(8): 1115-1120. 295. Jean WC, Walski-Easton SM, Nussbaum ES. Multiple intra-cranial aneurysms as delayed complications of an atrial myxoma: case report. Neurosurgery. 2001;49(1):200-202; discussion 202-203. 296. Jain D, Maleszewski JJ, Halushka MK. Benign cardiac tumors and tumorlike conditions. Ann Diagn Pathol. 2010;14(3):215-230. 297. Pucci A, Gagliardotto P, Zanini C, Pansini S, di Summa M, Mollo F. Histopathologic and clinical characterization of car-diac myxoma: review of 53 cases from a single institution. Am Heart J. 2000;140(1):134-138. 298. Bakaeen FG, Reardon MJ, Coselli JS, et al. Surgical out-come in 85 patients with primary cardiac tumors. Am J Surg. 2003;186(6):641-647; discussion 647. 299. Gammie JS, Abrishamchian AR, Griffith BP. Cardiac autotransplantation and radical bi-atrial resection for recurrent atrial myxoma. Ann Thorac Surg. 2007;83(4): 1545-1547. 300. Goldstein DJ, Oz MC, Michler RE. Radical excisional therapy and total cardiac transplantation for recurrent atrial myxoma. Ann Thorac Surg. 1995;60(4):1105-1107. 301. Shah IK, Dearani JA, Daly RC, et al. Cardiac myxomas: a 50-year experience with resection and analysis of risk factors for recurrence. Ann Thorac Surg. 2015;100(2):495-500. 302. Putnam JB, Jr, Sweeney MS, Colon R, Lanza LA, Frazier OH, Cooley DA. Primary cardiac sarcomas. Ann Thorac Surg. 1991;51(6):906-910. 303. Neuville A, Collin F, Bruneval P, et al. Intimal sarcoma is the most frequent primary cardiac sarcoma: clinicopathologic and molecular retrospective analysis of 100 primary cardiac sarco-mas. Am J Surg Pathol. 2014;38(4):461-469. 304. Neragi-Miandoab S, Kim J, Vlahakes GJ. Malignant tumours of the heart: a review of tumour type, diagnosis and therapy. Clin Oncol (R Coll Radiol). 2007;19(10):748-756.Brunicardi_Ch21_p0801-p0852.indd 85201/03/19 5:32 PM
Thoracic Aneurysms and Aortic DissectionScott A. LeMaire, Ourania Preventza, and Joseph S. Coselli 22chapterANATOMY OF THE AORTAThe aorta consists of two major segments—the proximal aorta and the distal aorta—whose anatomic characteristics affect both the clinical manifestations of disease in these segments and the selection of treatment strategies for such disease (Fig. 22-1). The proximal aortic segment includes the ascending aorta and the transverse aortic arch. The ascending aorta begins at the aortic valve and ends at the origin of the innominate artery. The first portion of the ascending aorta is the aortic root, which includes the aortic valve annulus and the three sinuses of Valsalva; the coronary arteries originate from two of these sinuses. The aortic root joins the tubular portion of the ascending aorta at the sinotubular ridge. The transverse aortic arch is the area from which the brachio-cephalic branches arise. The distal aortic segment includes the descending thoracic aorta and the abdominal aorta. The descending thoracic aorta begins distal to the origin of the left subclavian artery and extends to the diaphragmatic hia-tus, where it joins the abdominal aorta. The descending tho-racic aorta gives rise to multiple bronchial and esophageal branches, as well as to the segmental intercostal arteries, which provide circulation to the spinal cord.The volume of blood that flows through the thoracic aorta at high pressure is far greater than that found in any other vascular structure. For this reason, any condition that disrupts the integrity of the thoracic aorta, such as aortic dissection, aneurysm rupture, or traumatic injury, can have catastrophic consequences.Historically, open surgical repair of such conditions has been an intimidating undertaking associated with significant morbidity and mortality. Strategies for protecting the brain and spinal cord during such repairs have become critical in preventing devastating complications. Endovascular therapy for such conditions in selected patients has become accepted practice, producing fewer adverse outcomes than traditional approaches.THORACIC AORTIC ANEURYSMSAortic aneurysm is defined as a permanent, localized dilatation of the aorta to a diameter that is at least 50% greater than is normal at that anatomic level.1 The annual incidence of thoracic aortic aneurysms is estimated to be 5.9 per 100,000 persons.2 The clinical manifestations, methods of treatment, and treatment results in patients with aortic aneurysms vary according to the cause and the aortic segment involved. Causes of thoracic aortic aneurysms include degenerative disease of the aortic wall, aor-tic dissection, aortitis, infection, and trauma. Aneurysms can be localized to a single aortic segment, or they can involve multiple segments. Thoracoabdominal aortic aneurysms, for example, involve both the descending thoracic aorta and the abdominal aorta. In the most extreme cases, the entire aorta is aneurysmal; this condition is often called mega-aorta.Aortic aneurysms can be either “true” or “false.” True aneurysms can take two forms: fusiform and saccular. Fusiform aneurysms are more common and can be described as sym-metrical dilatations of the aorta. Saccular aneurysms are local-ized outpouchings of the aorta. False aneurysms, also called pseudoaneurysms, are leaks in the aortic wall that are contained by the outer layer of the aorta and/or the periaortic tissue; they are caused by disruption of the aortic wall and lead blood to collect in pouches of fibrotic tissue.Aneurysms of the thoracic aorta consistently increase in size and eventually progress to cause serious complications. These include rupture, which usually is a fatal event. Therefore, aggressive treatment is indicated in all but the poorest surgical candidates. Small, asymptomatic thoracic aortic aneurysms can be followed, especially in high-surgical-risk patients, and can be treated surgically later if symptoms or complications develop, or if progressive enlargement occurs. Meticulous control of hyper-tension is the primary medical treatment for patients with small, asymptomatic aneurysms.Elective resection with graft replacement is indicated in asymptomatic patients with an aortic diameter of at least twice Anatomy of the Aorta853Thoracic Aortic Aneurysms853Causes and Pathogenesis / 854Clinical History / 857Clinical Manifestations / 857Diagnostic Evaluation / 858Treatment / 860Aortic Dissection876Pathology and Classification / 876Causes and Clinical History / 879Clinical Manifestations / 879Diagnostic Evaluation / 880Treatment / 881Outcomes885Repair of Proximal Aortic Aneurysms / 885Treatment of Acute Ascending Aortic Dissection / 888Repair of Distal Aortic Aneurysms / 888Treatment of Descending Thoracic Aortic Dissection / 888Conclusions889Acknowledgments889Brunicardi_Ch22_p0853-p0896.indd 85301/03/19 5:40 PM 854Figure 22-1. Illustration of normal thoracic aortic anatomy. The brachiocephalic vessels arise from the transverse aortic arch and are used as anatomic landmarks to define the aortic regions. The ascending aorta is proximal to the innominate artery, whereas the descending aorta is distal to the left subclavian artery.normal in the involved segment (5 to 6 cm in most thoracic segments). Elective repair is contraindicated by extreme opera-tive risk due to severe coexisting cardiac or pulmonary dis-ease and by other conditions that limit life expectancy, such as malignancy. An emergency operation is performed for any patient in whom a ruptured aneurysm is suspected.Patients with thoracic aortic aneurysm often have coexisting aneurysms of other aortic segments. A common cause of death after repair of a thoracic aortic aneurysm is rupture of a different aortic aneurysm. Therefore, staged repair of multiple aortic seg-ments often is necessary. As with any major operation, careful pre-operative evaluation for coexisting disease and subsequent medical optimization are important for successful surgical treatment.An alternative to traditional open repair of a descending thoracic aortic aneurysm is endovascular stent grafting. Certain anatomic criteria for use—such as a landing zone that includes at least 2 cm of landing zone of healthy aortic tissue proximal and distal to the targeted aneurysm—are preferable, but not absolutely necessary. Although few data on long-term outcomes have recently been published, endovascular repair of descending thoracic aortic aneurysm has become an accepted practice that produces excellent midterm results.Causes and PathogenesisGeneral Considerations. The normal aorta derives its elastic-ity and tensile strength from the medial layer, which contains approximately 45 to 55 lamellae of elastin, collagen, smooth muscle cells, and ground substance. Elastin content is highest within the ascending aorta, as would be expected because of its compliant nature, and decreases distally into the descending and abdominal aorta. Maintenance of the aortic matrix involves complex interactions among smooth muscle cells, macrophages, proteases, and protease inhibitors. Any alteration in this delicate balance can lead to aortic disease.Thoracic aortic aneurysms have a variety of causes (Table 22-1). Although these disparate pathologic processes differ in biochemical and histologic terms, they share the final common pathway of progressive aortic expansion and eventual rupture.Hemodynamic factors clearly contribute to the process of aortic dilatation. The vicious cycle of increasing diameter and increasing wall tension, as characterized by Laplace’s law (tension = pressure × radius), is well established. Turbulent Key Points1 Assessing urgency of repair is essential to developing the appropriate management plan. Although emergent repair carries greater operative risk than does elective repair, any inappropriate delay of repair risks death.2 The clinical progression of an aortic aneurysm is continued expansion and eventual dissection or rupture. Hence, regular noninvasive imaging studies, as part of a lifelong surveil-lance plan, are necessary to ensure long-term patient health. Even small asymptomatic aneurysms should be routinely imaged to assess overall size and yearly rate of expansion.3 Endovascular repair devices are approved for the treatment of descending thoracic aortic aneurysms, descending thoracic aortic dissections, aortic trauma, and penetrating aortic ulcer.4 Practice guidelines have been published to help standardize the decision-making process and select an appropriate surgi-cal intervention, as well as to standardize the use of imaging studies for patients with thoracic aortic disease.5 Ascending aortic aneurysms that are symptomatic or ≥5.5 cm in diameter should be repaired regardless of whether the patient has a bicuspid or tricuspid aortic valve. This threshold is lowered for patients with certain heritable disor-ders affecting the aorta and for patients with additional risk factors, such as rapid aortic expansion (≥0.5 cm per year) or a family history of dissection.6 Surgical repair involves the development of a patienttailored plan based on careful preoperative medical evalua-tion. When appropriate, optimizing a patient’s health status—to mitigate existing comorbidities—is important before surgical intervention.7 The development and use of surgical adjuncts like antegrade selective cerebral perfusion and cerebrospinal fluid drainage have significantly reduced the morbidity rates traditionally associated with complex aortic repair.8 Proximal aortic dissection is a life-threatening condition, and immediate operative repair is generally indicated, although definitive aortic repair may be delayed until after severe mal-perfusion has been treated.Brunicardi_Ch22_p0853-p0896.indd 85401/03/19 5:40 PM 855THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22Table 22-1Causes of thoracic aortic aneurysmNonspecific medial degenerationAortic dissectionHeritable conditions Marfan syndrome Loeys-Dietz syndrome Ehlers-Danlos syndrome Turner syndrome Familial thoracic aortic aneurysm Aneurysms-osteoarthritis syndrome Congenital bicuspid aortic valve Bovine aortic archPoststenotic dilatationInfectionAortitis Takayasu arteritis Giant cell arteritis Rheumatoid aortitisTrauma (pseudoaneurysm)blood flow also is recognized as a factor. Poststenotic aortic dilatation, for example, occurs in some patients with aortic valve stenosis or coarctation of the descending thoracic aorta. Hemodynamic derangements, however, are only one piece of a complex puzzle.Atherosclerosis is commonly cited as a cause of thoracic aortic aneurysms. However, although atherosclerotic disease often is found in conjunction with aortic aneurysms, the notion that atherosclerosis is a distinct cause of aneurysm formation has been challenged. In most thoracic aortic aneurysms, ath-erosclerosis appears to be a coexisting process, rather than the underlying cause.Research into the pathogenesis of abdominal aortic aneurysms has focused on the molecular mechanisms of aortic wall degeneration and dilatation.3 For example, imbalances between proteolytic enzymes (e.g., matrix metalloproteinases) and their inhibitors contribute to abdominal aortic aneurysm formation. Building on these advances, current investigations are attempting to determine whether similar inflammatory and proteolytic mechanisms are involved in thoracic aortic disease, in hope of identifying potential molecular targets for pharmacologic therapy.Nonspecific Medial Degeneration. Nonspecific medial degeneration is the most common cause of thoracic aortic dis-ease. Histologic findings of mild medial degeneration, includ-ing fragmentation of elastic fibers and loss of smooth muscle cells, are expected in the aging aorta. However, an advanced, accelerated form of medial degeneration leads to progressive weakening of the aortic wall, aneurysm formation, and eventual dissection, rupture, or both. The underlying causes of medial degenerative disease remain poorly understood.Aortic Dissection. An aortic dissection usually begins as a tear in the inner aortic wall, which initiates a progressive sepa-ration of the medial layers and creates two channels within the aorta. This event profoundly weakens the outer wall. As the most common catastrophe involving the aorta, dissection repre-sents a major, distinct cause of thoracic aortic aneurysms and is discussed in detail in the second half of this chapter.Heritable Conditions. Several heritable conditions cause thoracic aortic aneurysms. To better characterize these disorders, the National Institutes of Health (NIH) sponsored a longitudinal registry for individuals affected by genetically triggered thoracic aortic aneurysms and cardiovascular conditions (GenTAC) more than a decade ago.4 The registry enrollment includes adults and children in 13 clinical categories, including Marfan syndrome, Ehlers-Danlos syndrome, Loeys-Dietz syndrome, familial tho-racic aortic aneurysms and dissections, aneurysms-osteoarthritis syndrome, and congenital bicuspid aortic valve.Marfan Syndrome Marfan syndrome is an autosomal domi-nant genetic disorder characterized by a specific connective tissue defect that leads to aneurysm formation. The phenotype of patients with Marfan syndrome typically includes a tall stat-ure, high palate, joint hypermobility, eye lens disorders, mitral valve prolapse, and aortic aneurysms. The aortic wall is weak-ened by fragmentation of elastic fibers and deposition of exten-sive amounts of mucopolysaccharides (a process previously called cystic medial degeneration or cystic medial necrosis). Patients with Marfan syndrome have a mutation in the fibrillin gene located on the long arm of chromosome 15. The tradi-tional view has been that abnormal fibrillin in the extracellular matrix decreases connective tissue strength in the aortic wall and produces abnormal elasticity, which predisposes the aorta to dilatation from wall tension caused by left ventricular ejec-tion impulses.5 More recent evidence, however, shows that the abnormal fibrillin causes degeneration of the aortic wall matrix by increasing the activity of transforming growth factor beta (TGF-β).6 Between 75% and 85% of patients with Marfan syn-drome have dilatation of the ascending aorta and annuloaortic ectasia (dilatation of the aortic sinuses and annulus).7 Marfan syndrome also is frequently associated with aortic dissection, and aortic complications are the most common cause of death among patients with Marfan syndrome.8Loeys-Dietz Syndrome Loeys-Dietz syndrome is phenotypi-cally distinct from Marfan syndrome. It is characterized as an aneurysmal syndrome with widespread systemic involvement. Loeys-Dietz syndrome is an aggressive, autosomal dominant condition that is distinguished by the triad of arterial tortuosity and aneurysms, hypertelorism (widely spaced eyes), and bifid uvula or cleft palate. It is caused by heterozygous mutations in the genes encoding TGF-β receptors.9,10 Patients with Loeys-Dietz syndrome—including young children—are at increased risk of aortic rupture and aortic dissection; diameter-based thresholds of repair tend to be lower for patients with this syndrome than for patients with other heritable disorders.Ehlers-Danlos Syndrome Ehlers-Danlos syndrome includes a spectrum of inherited disorders of collagen synthesis. The sub-types represent differing defective steps of collagen production. Vascular type Ehlers-Danlos syndrome is characterized by an autosomal dominant defect in type III collagen synthesis, which can have life-threatening cardiovascular manifestations. Sponta-neous arterial rupture, usually involving the mesenteric vessels, is the most common cause of death in these patients. Thoracic aortic aneurysms and dissections are less commonly associated with Ehlers-Danlos syndrome, but when they do occur, they pose a particularly challenging surgical problem because of the reduced integrity of the aortic tissue.11 An Ehlers-Danlos variant of periventricular heterotopia associated with joint and skin hyperextensibility and aortic dilation has been described as being caused by mutations in the gene encoding filamin A Brunicardi_Ch22_p0853-p0896.indd 85501/03/19 5:40 PM 856SPECIFIC CONSIDERATIONSPART II(FLNA), an actin-binding protein that links the smooth muscle cell contractile unit to the cell surface.12Familial Thoracic Aortic Aneurysm and Dissection Fami-lies without the heritable syndromes described earlier also can be affected by genetic conditions that cause thoracic aortic aneurysm. In fact, it is estimated that at least 20% of patients with thoracic aortic aneurysms and dissections have a genetic predisposition to them. The involved mutations are characterized by autosomal dominant inheritance with decreased penetrance and variable expression. The number of genes for which mutations have been identified as causes of familial thoracic aortic aneurysm and dissection is expanding rapidly; involved genes include those related to TGF-β receptors (TGFBR1 and TGFBR2), TGF-β ligands (TGFB2 and TGFB3), myosin (MYH11 and MYLK), elastin (ELN), elastin microfibril interfacer 1 (EMLIN1), microfibril-associated glycoprotein 2 (MFAP5), fibrillin-2 (FBN2), fibulin-4 (FBLN4), lysyl oxidase (LOX), and α-smooth muscle cell actin (ACTA2).3,13-16 ACTA2 mutations are present in approximately 14% of families with familial thoracic aortic aneurysms and dissections.Aneurysms-Osteoarthritis Syndrome Aneurysmsosteoarthritis syndrome is an autosomal dominant disorder char-acterized by aortic and arterial aneurysms, arterial tortuosity, aor-tic dissection, mild craniofacial abnormalities, and early-onset osteoarthritis. Aneurysms-osteoarthritis syndrome is caused by mutations in the gene encoding SMAD3, a transcription factor for TGF-β. Affected patients have a high incidence of aortic dissection, which often occurs in a mildly dilated aorta and causes sudden death.17Congenital Bicuspid Aortic Valve Bicuspid aortic valve is the most common congenital malformation of the heart or great vessels, affecting up to 2% of Americans.18 Compared to patients with a normal, trileaflet aortic valve, patients with bicuspid aortic valve have an increased incidence of ascending aortic aneurysm formation and, often, a more rapid rate of aortic enlargement.19 The location of the fused leaflet, or raphe, may be predictive of aortic dilation and other abnormalities.20 Fifty to 70% of adults with bicuspid aortic valve, but without significant valve dysfunction, have echocardiographically detectable aortic dilatation.21,22 This dilatation usually is limited to the ascending aorta and root.23 Dilation occasionally is found in the arch and only rarely in the descending or abdominal aorta. In addition, aortic dissection occurs 10 times more often in patients with bicuspid valves than in the general population.24 Recent findings suggest that aneurysms associated with bicuspid aortic valve have a fundamentally different pathobiologic cause than aneu-rysms that occur in patients with trileaflet valves.25Although the exact mechanism responsible for aneu-rysm formation in patients with bicuspid aortic valve remains unclear, evidence suggests that these patients have a congeni-tal connective tissue abnormality that predisposes the aorta to medial degeneration.25-31 For example, fibrillin-1 content is sig-nificantly lower and matrix metalloproteinase activity is signifi-cantly higher in the aortic media in patients with bicuspid aortic valve than in persons with a normal, tricuspid aortic valve.25-27 Further, the process of medial degeneration in patients with bicuspid aortic valve may be exacerbated by the presence of chronic turbulent flow through the deformed valve.Bovine Aortic Arch Bovine aortic arch—a common origin of the innominate and left common carotid arteries—has been con-sidered a normal anatomic variant. Studies from Yale University have identified a higher prevalence of bovine aortic arch in patients with thoracic aortic disease; an association was found between this anomaly and a generalized increase in aortic aneu-rysmal disease (without any predisposition to a particular aortic region). However, bovine aortic arch was not associated dis-tinctly with bicuspid aortic valve or aortic dissection, but with a higher mean aortic growth rate: 0.29 cm per year in patients with bovine aortic arch, compared with 0.09 cm per year in controls. Therefore, bovine aortic arch may be better character-ized as a precursor of aortic aneurysm than as a simple normal anatomic variant.32 Further studies are needed to delineate the underlying mechanism for this association.Infection. Primary infection of the aortic wall resulting in aneurysm formation is rare. Although these lesions are termed mycotic aneurysms, the responsible pathogens usually are bac-teria rather than fungi. Bacterial invasion of the aortic wall may result from bacterial endocarditis, endothelial trauma caused by an aortic jet lesion, or extension from an infected laminar clot within a preexisting aneurysm. The most common causative organisms are Staphylococcus aureus, Staphylococcus epider-midis, Salmonella, and Streptococcus.33,34 Unlike most other causes of thoracic aortic aneurysms, which generally produce fusiform aneurysms, infection often produces saccular aneu-rysms located in areas of aortic tissue destroyed by the infec-tious process.Although syphilis was once the most common cause of ascending aortic aneurysms, the advent of effective antibiotic therapy has made syphilitic aneurysms a rarity in developed nations. In other parts of the world, however, syphilitic aneu-rysms remain a major cause of morbidity and mortality. The spi-rochete Treponema pallidum causes an obliterative endarteritis of the vasa vasorum that results in medial ischemia and loss of the elastic and muscular elements of the aortic wall. The ascend-ing aorta and arch are the most commonly involved areas. The emergence of HIV infection in the 1980s was associated with a substantial increase in the incidence of syphilis in both HIV-positive and HIV-negative patients. Because syphilitic aortitis often presents 10 to 30 years after the primary infection, the inci-dence of associated aneurysms may increase in the near future.Aortitis. In patients with preexisting degenerative thoracic aortic aneurysms, localized transmural inflammation and subse-quent fibrosis can develop. The dense aortic infiltrate responsible for the fibrosis consists of lymphocytes, plasma cells, and giant cells. The cause of the intense inflammatory reaction is unknown. Although the severe inflammation is a superimposed problem rather than a primary cause, its onset within an aneurysm can further weaken the aortic wall and precipitate expansion.Systemic autoimmune disorders also cause thoracic aor-titis. Aortic Takayasu arteritis generally produces obstructive lesions related to severe intimal thickening, but associated medial necrosis can lead to aneurysm formation. In patients with giant cell arteritis (temporal arteritis), granulomatous inflam-mation may develop that involves the entire thickness of the aortic wall, causing intimal thickening and medial destruction. Rheumatoid aortitis is an uncommon systemic disease that is associated with rheumatoid arthritis and ankylosing spondylitis. The resulting medial inflammation and fibrosis can affect the aortic root, causing annular dilatation, aortic valve regurgitation, and ascending aortic aneurysm formation.Pseudoaneurysms. Pseudoaneurysms of the thoracic aorta usually represent chronic leaks that are contained by surrounding Brunicardi_Ch22_p0853-p0896.indd 85601/03/19 5:40 PM 857THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22tissue and fibrosis. By definition, the wall of a pseudoaneurysm is not formed by intact aortic tissue; rather, the wall devel-ops from organized thrombus and associated fibrosis. Pseu-doaneurysms can arise from primary defects in the aortic wall (e.g., after trauma or contained aneurysm rupture) or from anas-tomotic or cannulation site leaks that occur after cardiovascular surgery. Anastomotic pseudoaneurysms can be caused by tech-nical problems or by deterioration of the native aortic tissue, graft material, or suture. Commonly, they occur in patients with Marfan syndrome, Loeys-Dietz syndrome, or other heritable conditions that markedly weaken the vessel wall.35 Tissue dete-rioration usually is related to either progressive degenerative disease or infection. Improvements in sutures, graft materials, and surgical techniques have decreased the incidence of tho-racic aortic pseudoaneurysm. Should thoracic aortic pseudoan-eurysms occur, they typically require expeditious open surgical or catheter-based repair because they are associated with a high incidence of morbidity and rupture.Clinical HistoryTreatment decisions in cases of thoracic aortic aneurysm are guided by our current understanding of the clinical history of these aneurysms, which classically is characterized as progres-sive aortic dilatation and eventual dissection, rupture, or both. An analysis by Elefteriades of data from 1600 patients with thoracic aortic disease has helped quantify these well-recognized risks.36 Average expansion rates were 0.07 cm per year in ascending aortic aneurysms and 0.19 cm per year in descending thoracic aortic aneurysms. As expected, aortic diam-eter was a strong predictor of rupture, dissection, and mortality. For thoracic aortic aneurysms >6 cm in diameter, annual rates of catastrophic complications were 3.6% for rupture, 3.7% for dissection, and 10.8% for death. Critical “hinge-point” diame-ters, at which the incidence of expected complications signifi-cantly increased, were 6.0 cm for aneurysms of the ascending aorta and 7.0 cm for aneurysms of the descending thoracic aorta; the corresponding risks of rupture after reaching these diameters were 31% and 43%, respectively.37Certain types of aneurysms have an elevated propensity for expansion and rupture. For example, aneurysms in patients with Marfan or Loeys-Dietz syndrome tend to dilate at an accelerated rate and rupture or dissect at smaller diameters than sporadic, nonheritable aneurysms. Before the era of surgical treatment for aortic aneurysms, the aggressive form of aortic disease in Marfan patients resulted in an average life expectancy of 32 years, with aortic root complications causing the majority of deaths.38 Saccular aneurysms, which commonly are associated with aortic infection and typically affect only a discrete small section of the aorta, tend to grow more rapidly than fusiform aneurysms, which are associated with more widespread degen-erative changes and generally affect a larger section of the aorta.One common clinical scenario deserves special attention. A moderately dilated ascending aorta (i.e., 4 to 5 cm) often is encountered during aortic valve replacement or coronary artery bypass operations. The clinical history of these ectatic ascend-ing aortas has been defined by several studies. Michel and colleagues39 studied patients whose ascending aortic diameters were >4 cm at the time of aortic valve replacement; 25% of these patients required reoperation for ascending aortic replacement. Prenger and colleagues40 reported that aortic dissection occurred in 27% of patients who had aortic diameters of >5 cm at the time of aortic valve replacement. Attention has been directed toward whether or not a mildly dilated aortic root should be replaced in patients with bicuspid aortic valve who are undergoing iso-lated valve replacement, and at what threshold to intervene. Although this is a controversial issue, many surgeons believe that the tendency toward late aortic dilatation in these patients war-rants aggressive treatment.41,42 According to a recent guidelines clarification,43 in patients with bicuspid aortic valve who are undergoing aortic valve replacement or repair, replacing the ascending aorta is reasonable when the diameter of the ascending aorta is greater than 4.5 cm (Class IIa, Level C recommendation).Clinical ManifestationsIn many patients with thoracic aortic aneurysms, the aneurysm is discovered incidentally when imaging studies are performed for unrelated reasons. Therefore, patients often are asymptom-atic at the time of diagnosis. However, thoracic aortic aneurysms that initially go undetected eventually create symptoms and signs that correspond with the segment of aorta that is involved. These aneurysms have a wide variety of manifestations, includ-ing compression or erosion of adjacent structures, aortic valve regurgitation, distal embolism, and rupture.Local Compression and Erosion. Initially, aneurysmal expan-sion and impingement on adjacent structures causes mild, chronic pain. The most common symptom in patients with ascending aor-tic aneurysms is anterior chest discomfort; the pain is frequently precordial in location but may radiate to the neck and jaw, mim-icking angina. Aneurysms of the ascending aorta and transverse aortic arch can cause symptoms related to compression of the superior vena cava, the pulmonary artery, the airway, or the ster-num. Rarely, these aneurysms erode into the superior vena cava or right atrium, causing acute high-output failure. Expansion of the distal aortic arch can stretch the recurrent laryngeal nerve, which results in left vocal cord paralysis and hoarseness. Descending thoracic and thoracoabdominal aneurysms frequently cause back pain localized between the scapulae. When the aneurysm is larg-est in the region of the aortic hiatus, it may cause middle back and epigastric pain. Thoracic or lumbar vertebral body erosion typically causes severe, chronic back pain; extreme cases can present with spinal instability and neurologic deficits from spinal cord compression. Although mycotic aneurysms have a peculiar propensity to destroy vertebral bodies, spinal erosion also occurs with degenerative aneurysms. Descending thoracic aortic aneu-rysms may cause varying degrees of airway obstruction, mani-festing as cough, wheezing, stridor, or pneumonitis. Pulmonary or airway erosion presents as hemoptysis. Compression and ero-sion of the esophagus cause dysphagia and hematemesis, respec-tively. Thoracoabdominal aortic aneurysms can cause duodenal obstruction or, if they erode through the bowel wall, gastrointes-tinal bleeding. Jaundice due to compression of the liver or porta hepatis is uncommon. Erosion into the inferior vena cava or iliac vein presents with an abdominal bruit, widened pulse pressure, edema, and heart failure.Aortic Valve Regurgitation. Ascending aortic aneurysms can cause displacement of the aortic valve commissures and annular dilatation. The resulting deformation of the aortic valve leads to progressively worsening aortic valve regurgitation. In response to the volume overload, the heart remodels and becomes increasingly dilated. Patients with this condition may present with progressive heart failure, a widened pulse pressure, and a diastolic murmur.Distal Embolization. Thoracic aortic aneurysms—particularly those involving the descending and thoracoabdominal aorta—are commonly lined with friable, atheromatous plaque and 1Brunicardi_Ch22_p0853-p0896.indd 85701/03/19 5:40 PM 858SPECIFIC CONSIDERATIONSPART IIFigure 22-2. Chest radiographs showing a calcified rim (arrows) in the aortic wall of a thoracoabdominal aortic aneurysm. A. Anteroposterior view. B. Lateral view.mural thrombus. This debris may embolize distally, caus-ing occlusion and thrombosis of the visceral, renal, or lower-extremity branches.Rupture. Patients with ruptured thoracic aortic aneurysms often experience sudden, severe pain in the anterior chest (ascending aorta), upper back or left chest (descending thoracic aorta), or left flank or abdomen (thoracoabdominal aorta). When ascending aortic aneurysms rupture, they usually bleed into the pericardial space, producing acute cardiac tamponade and death. Descending thoracic aortic aneurysms rupture into the pleural cavity, producing a combination of severe hemorrhagic shock and respiratory compromise. External rupture is extremely rare; saccular syphilitic aneurysms have been observed to rupture externally after eroding through the sternum.Diagnostic EvaluationDiagnosis and characterization of thoracic aneurysms require imaging studies, which also provide critical information that guides the selection of treatment options. Although the best choice of imaging technique for the thoracic and thoracoab-dominal aorta is somewhat institution-specific, varying with the availability of imaging equipment and expertise, efforts have been made to standardize key elements of image acquisition and reporting. Recent practice guidelines44 recommend that aortic imaging reports plainly state the location of aortic abnormalities (including calcification and the extent to which abnormalities extend into branch vessels), the maximum external aortic diam-eters (rather than internal, lumen-based diameters), internal fill-ing defects, and any evidence of rupture. Whenever possible, all results should be compared with those of prior imaging studies.Plain Radiography. Plain radiographs of the chest, abdomen, or spine often provide enough information to support the initial diag-nosis of thoracic aortic aneurysm. Ascending aortic aneurysms produce a convex shadow to the right of the cardiac silhouette. The anterior projection of an ascending aneurysm results in the loss of the retrosternal space in the lateral view. An aneurysm may be indistinguishable from elongation and tortuosity.45 Impor-tantly, chest radiographs (CXRs) may appear normal in patients with thoracic aortic disease and thus cannot exclude the diagnosis of aortic aneurysm. Aortic root aneurysms, for example, often are hidden within the cardiac silhouette. Plain CXRs may reveal convexity in the right superior mediastinum, loss of the retroster-nal space, or widening of the descending thoracic aortic shadow, which may be highlighted by a rim of calcification outlining the dilated aneurysmal aortic wall. Aortic calcification also may be seen in the upper abdomen on a standard radiograph made in the anteroposterior or lateral projection (Fig. 22-2). Once a thoracic aortic aneurysm is detected on plain radiographs, additional stud-ies are required to define the extent of aortic involvement.Echocardiography and Abdominal Ultrasonography.  Ascending aortic aneurysms are commonly discovered during echocardiography in patients presenting with symptoms or signs of aortic valve regurgitation. Both transthoracic and transesophageal echocardiography provide excellent visualization of the ascending aorta, including the aortic root.46 Transesophageal echocardiography also allows visualization of the descending thoracic aorta but is not ideal for evaluating the transverse aortic arch (which is obscured by air in the tracheobronchial tree) or the upper abdominal aorta. Effective echocardiography requires considerable technical skill, both in obtaining adequate images and in interpreting them. This imaging modality has the added Brunicardi_Ch22_p0853-p0896.indd 85801/03/19 5:40 PM 859THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22Figure 22-3. Current practice guidelines44 seek to standardize the reporting of aortic diameters by indicating key locations of mea-surement. These include (1) the sinuses of Valsalva, (2) the sinotu-bular junction, (3) the mid-ascending aorta, (4) the proximal aortic arch at the origins of the innominate artery, (5) the mid-aortic arch, which is between the left common carotid and left subclavian arter-ies, (6) the proximal descending thoracic aorta, which begins at the isthmus (approximately 2 cm distal to the origins of the left subcla-vian artery), (7) the mid-descending thoracic artery, (8) the aorta at the diaphragm, and (9) the abdominal aorta at the origins of the celiac axis. (Used with permission of Baylor College of Medicine.)benefit of assessing cardiac function and revealing any other abnormalities that may be present. During ultrasound evaluation of a suspected infrarenal abdominal aortic aneurysm, if a definitive neck cannot be identified at the level of the renal arteries, the possibility of thoracoabdominal aortic involvement should be suspected and investigated by using other imaging modalities. Caution should be exercised while interpreting aneurysm dimensions from ultrasound imaging because intraluminal measurements are often reported, whereas external measurements are usually used in other imaging modalities.Computed Tomography. Computed tomographic (CT) scan-ning is widely available, provides visualization of the entire thoracic and abdominal aorta, and permits multiplanar and 3-dimensional aortic reconstructions. Consequently, CT is the most common—and arguably the most useful—imaging modal-ity for evaluating thoracic aortic aneurysms.47 In addition to establishing the diagnosis, CT provides information about an aneurysm’s location, extent, anatomic anomalies, and relation-ship to major branch vessels. CT is particularly useful in deter-mining the absolute diameter of the aorta, especially in the presence of laminated clot, and also detects aortic calcification. Contrast-enhanced CT provides information about the aortic lumen and can detect mural thrombus, aortic dissection, inflam-matory periaortic fibrosis, and mediastinal or retroperitoneal hematoma due to contained aortic rupture. To increase consis-tency and ensure uniform reporting, current practice guidelines suggest that measurements be taken perpendicular to blood flow and at standard anatomic locations44 (Fig. 22-3); this should reduce the likelihood of erroneous measurements, espe-cially during serial imaging surveillance .The major disadvantage of contrast-enhanced CT scanning is the possibility of contrast-induced acute renal failure in patients who are at risk (e.g., patients with preexisting renal disease or diabetes) even though the risk is smaller than was assumed in the past.48,49 If possible, surgery is performed at least 1 day after contrast administration to allow time to observe renal function and to permit diuresis. If renal insufficiency occurs or is worsened, elective surgery is postponed until renal function returns to normal or stabilizes.Magnetic Resonance Angiography. Magnetic resonance angiography (MRA) is becoming widely available and can facilitate visualization of the entire aorta. This modality pro-duces aortic images comparable to those produced by contrast-enhanced CT but does not necessitate exposure to ionizing radiation.50 In addition, MRA offers excellent visualization of branch-vessel details, and it is useful in detecting branch-vessel stenosis.51 However, MRA is limited by high expense and a sus-ceptibility to artifacts created by ferromagnetic materials, and gadolinium—the contrast agent for MRA—may be linked to nephrogenic systemic fibrosis and acute renal failure in patients with advanced renal insufficiency.52 Furthermore, the MRA environment is not appropriate for many critically ill patients, and unlike CT imaging, MRA imaging is suboptimal in patients with extensive aortic calcification.Invasive Aortography and Cardiac Catheterization.  Although catheter-based contrast aortography was previously considered the gold standard for evaluating thoracic aortic dis-ease, cross-sectional imaging (i.e., CT and MRA) has largely replaced this modality. Technologic improvements have enabled CT and MRA to provide excellent aortic imaging while causing less morbidity than catheter-based studies do, so CT and 2MRA are now the primary modes for evaluating thoracic aortic disease. Today, the use of invasive aortography in patients with thoracic aortic disease is generally limited to those undergoing endovascular therapies or when other types of studies are con-traindicated or have not provided satisfactory results.Unlike standard aortography, cardiac catheterization con-tinues to play an important role in diagnosis and preoperative planning, especially in patients with ascending aortic involve-ment. Proximal aortography can reveal not only the status of the coronary arteries and left ventricular function but also the degree of aortic valve regurgitation, the extent of aortic root involvement, coronary ostial displacement, and the relationship of the aneurysm to the arch vessels.The value of the information one can obtain from catheter-based diagnostic studies should be weighed against Brunicardi_Ch22_p0853-p0896.indd 85901/03/19 5:40 PM 860SPECIFIC CONSIDERATIONSPART IIthe established limitations and potential complications of such studies. A key limitation of aortography is that it images only the lumen and may therefore underrepresent the size of large aneurysms that contain laminated thrombus. Manipulation of intraluminal catheters can result in embolization of laminated thrombus or atheromatous debris. Proximal aortography carries a 0.6% to 1.2% risk of stroke. Other risks include allergic reac-tion to the contrast agent, iatrogenic aortic dissection, and bleed-ing at the arterial access site. In addition, the volumes of contrast agent required to adequately fill large aneurysms can cause sig-nificant renal toxicity. To minimize the risk of contrast nephrop-athy, patients receive periprocedural intravenous (IV) fluids for hydration, mannitol for diuresis, and acetylcysteine.53,54 As with contrast-enhanced CT, surgery is performed ≥1 day after angiography whenever possible to ensure that renal func-tion has stabilized or returned to baseline.TreatmentSelecting the Appropriate Treatment. Once a thoracic aor-tic aneurysm is detected, management begins with patient edu-cation, particularly if the patient is asymptomatic, because aortic disease may progress rapidly and unexpectedly in some patients. A detailed medical history is collected, a physical examination is performed, and a systematic review of medical records is car-ried out to clearly assess the presence or absence of pertinent symptoms and signs, despite any initial denial of symptoms by the patient. Signs of heritable conditions such as Marfan syn-drome or Loeys-Dietz syndrome are thoroughly reviewed. If clinical criteria are met for a heritable condition, confirmatory laboratory tests are conducted. Patients with heritable disorders are best treated in a dedicated aortic clinic where they can be appropriately followed up. Surveillance imaging and aggressive blood pressure control are the mainstays of initial management for asymptomatic patients. When patients become symptomatic or their aneurysms grow to meet certain size criteria, the patients become surgical candidates.Endovascular therapy has become an accepted treatment for descending thoracic aortic aneurysm.55,56 Its role in treating proximal aortic disease and thoracoabdominal aortic aneurysm remains experimental;55 nonetheless, endoluminal stenting is approved by the U.S. Food and Drug Administration for the treatment of isolated descending thoracic aortic aneurysm, and several different devices have been approved for the treatment of blunt aortic injury and penetrating aortic ulcer. In practice, however, the off-label application of aortic stent grafts is widespread and accounts for well over half their use57; endovascular approaches may be helpful in emergent aneurysm repair, such as for patients with aortic rupture.58 Endovascular therapy has evolved to include hybrid repairs, which combine open “debranching” techniques (to reroute branching vessels) with endovascular aortic repair.59,60 Despite these advances, for the repair of aneurysms with proximal aortic involvement and of thoracoabdominal aortic aneurysms, open procedures remain the gold standard and preferred approach.Determination of the Extent and Severity of Disease.  Cross-sectional imaging with reconstruction is critical when one is evaluating a thoracic aneurysm, determining treatment strategy, and planning necessary procedures. Note that patients with a thoracic aortic aneurysm may also have a second, remote aneurysm.2 In such cases, the more threatening lesion usually is addressed first. In many patients, staged operative procedures are necessary for complete repair of extensive aneurysms involving the ascending aorta, transverse arch, and descending thoracic or thoracoabdominal aorta.61 When the descending segment is not disproportionately large (compared with the proximal aorta) and is not causing symptoms, the proximal aortic repair is carried out first. An important benefit of this approach is that it allows treatment of valvular and coronary artery occlusive disease at the first operation.Proximal aneurysms (proximal to the left subclavian artery) usually are addressed via a sternotomy approach. Aneu-rysms involving the descending thoracic aorta are evaluated in terms of criteria (described in the following section) for poten-tial endovascular repair; those unsuitable for an endovascular approach are repaired with open techniques through a left thora-cotomy. A CT scan can reveal detailed information about aortic calcification and luminal thrombus. These details are important in preventing embolization during surgical manipulation.Indications for Operation Thoracic aortic aneurysms are repaired to prevent fatal rupture. Therefore, on the basis of clini-cal history studies and other data, practice guidelines for tho-racic aortic disease43,44,62 recommend elective operation in asymptomatic patients when the diameter of an ascending aortic aneurysm is >5.5 cm, when the diameter of a descending thoracic aortic aneurysm is >6.0 cm, or when the rate of dilata-tion is >0.5 cm per year. In patients with heritable disorders such as Marfan and Loeys-Dietz syndromes, the threshold for opera-tion is based on a smaller aortic diameter (5.0 cm for the ascend-ing aorta in patients with Marfan syndrome, 4.4 to 4.6 cm for the ascending aorta in patients with Loeys-Dietz syndrome, and <6.0 cm for the descending thoracic aorta in patients with either disorder). For women with heritable disorders who are consider-ing pregnancy, prophylactic aortic root replacement is considered because the risk of aortic dissection or rupture increases at an aortic diameter of 4.0 cm and greater. For patients with ascending aortic aneurysm and bicuspid aortic valve, repair is recommended if aortic diameter is 5.0 cm or greater and additional risk factors are present (e.g., family his-tory of dissection, expansion rate exceeding 0.5 cm per year), if aortic diameter is 5.5 cm or larger and no additional risk factors are present, or if aortic diameter exceeds 4.5 cm and the patient is undergoing aortic valve replacement or repair.43 For low-risk patients with chronic aortic dissection, descending thoracic repair is recommended at an aortic diameter of 5.5 cm or greater.The acuity of presentation is a major factor in decisions about the timing of surgical intervention. Many patients are asymptomatic at the time of presentation, so there is time for thorough preoperative evaluation and improvement of their cur-rent health status, such as through smoking cessation and other optimization programs. In contrast, patients who present with symptoms may need urgent operation. Symptomatic patients are at increased risk of rupture and warrant expe-ditious evaluation. The onset of new pain in patients with known aneurysms is especially concerning because it may herald sig-nificant expansion, leakage, or impending rupture. Emergent intervention is reserved for patients who present with aneurysm rupture or superimposed acute dissection.63Open Repair vs. Endovascular Repair As noted earlier, endo-vascular repair has become the standard approach for patients with isolated degenerative descending thoracic aortic aneurysm; in fact, practice guidelines recommend that endovascular repair be strongly considered for patients with descending thoracic aneurysm at an aortic diameter of 5.5 cm (which is slightly below the 6.0-cm threshold for open repair).44 For endovascular 3456Brunicardi_Ch22_p0853-p0896.indd 86001/03/19 5:40 PM 861THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22repairs to produce optimal outcomes, several anatomic criteria must be met. For one, the proximal and distal neck diameters should fall within a range that will allow proper sealing. Also, the proximal and distal landing zones should ideally be at least 20 mm long so that an appropriate seal can be made. Note that the limiting structures proximally and distally are the brachio-cephalic vessels and celiac axis, respectively. Vascular access continues to be one of the most important determinants of suc-cessful deployment of the current endovascular devices. The femoral and iliac arteries have to be wide enough to accommo-date the sheaths used to deploy the stent grafts. As endovascular technology evolves, newer devices are using smaller sheaths (or are “sheathless” self-deployed stent grafts) to accommodate smaller arteries. Tortuosity of the iliac vessels and abdominal aorta can make these procedures technically challenging. Occa-sionally, an 8or 10-mm polyester “side graft” is anastomosed to the iliac artery through a retroperitoneal incision if the femo-ral vessels are too small to access easily.Of note, attempts have been made to extend the use of endovascular therapy to aortic arch aneurysms and thoracoab-dominal aortic aneurysms. Although reports of purely endovas-cular repair of the aortic arch remain limited, Greenberg and colleagues64 have reported their experience with a large series of purely endovascular thoracoabdominal aortic repairs. Addition-ally, there have been numerous reports of small series of off-label, experimental hybrid procedures that involve debranching the aortic arch or the visceral vessels of the abdominal aorta, fol-lowed by endovascular exclusion of the aneurysm. The majority of hybrid approaches involve repairing the aortic arch.59,60 In its simplest form, hybrid arch repair involves an open bypass from the left subclavian to the left common carotid artery, which is followed by deliberate coverage of the origins of the left subcla-vian artery by the stent graft. In its most complex form, hybrid arch repair involves rerouting all of the brachiocephalic vessels, followed by proximal placement of the stent graft in the ascend-ing aorta and extending repair distally into the aortic arch and descending thoracic aorta.The patients who theoretically benefit the most from an endovascular approach are those who are of advanced age or have significant comorbidities, as many of these patients face substantial risks when undergoing traditional open repair.65 For example, with regard to open repair of a descending thoracic aortic aneurysm, significant pulmonary morbidity can occur postoperatively; therefore, patients with borderline pulmonary reserve may better tolerate an endovascular procedure than a standard open repair. Patients with heritable syndromic condi-tions generally are not considered candidates for elective endo-vascular repair except in specific circumstances.66 Endovascular repair in patients with heritable syndromic conditions have pro-duced poor results, which are mainly due to progressive dilata-tion, stent graft migration, and endoleak.67,68Preoperative Assessment and Preparation. Given the impact of comorbid conditions on perioperative complications, a careful preoperative assessment of physiologic reserve is criti-cal in assessing operative risk. Therefore, most patients undergo a thorough evaluation—with emphasis on cardiac, pulmonary, and renal function—before undergoing elective surgery.69,70Cardiac Evaluation Coronary artery disease is common in patients with thoracic aortic aneurysm and is responsible for a substantial proportion of early and late postoperative deaths in such patients. Similarly, valvular disease and myocardial dysfunction have important implications when one is planning anesthetic management and surgical approaches for aortic repair. Transthoracic echocardiography is a satisfactory noninvasive method for evaluating both valvular and biventricular function. Dipyridamole-thallium myocardial scanning identifies regions of myocardium that have reversible ischemia, and this test is more practical than exercise testing in older patients with concomitant lower-extremity peripheral vascular disease. Cardiac catheteriza-tion and coronary arteriography are performed in patients who have evidence of coronary disease—as indicated by either the patient’s history or the results of noninvasive studies—or who have a left ventricular ejection fraction of ≤30%. If significant valvular or coronary artery disease is identified before a proxi-mal aortic operation, the disease can be addressed directly dur-ing the procedure. Patients who have asymptomatic distal aortic aneurysms and severe coronary occlusive disease undergo per-cutaneous transluminal angioplasty or surgical revascularization before the aneurysmal aortic segment is replaced.Pulmonary Evaluation Pulmonary function screening with arterial blood gas measurement and spirometry is routinely per-formed before thoracic aortic operations. Patients with a forced expiratory volume in 1 second of >1.0 L and a partial pressure of carbon dioxide of <45 mmHg are considered appropriate can-didates for open surgical repair. In suitable patients, borderline pulmonary function can be improved by implementing a regi-men that includes smoking cessation, weight loss, exercise, and treatment of bronchitis for a period of 1 to 3 months before surgery. Although surgery is not withheld from patients with symptomatic aortic aneurysms and poor pulmonary function, adjustments in operative technique should be made to maximize these patients’ chances of recovery. In such patients, preserving the left recurrent laryngeal nerve, the phrenic nerves, and dia-phragmatic function is particularly important.Renal Evaluation Renal function is assessed preoperatively by measuring serum electrolyte, blood urea nitrogen, and cre-atinine levels. Information about kidney size and perfusion can be obtained from the imaging studies used to evaluate the aorta.Obtaining accurate information about baseline renal function has important therapeutic and prognostic implications. For exam-ple, perfusion strategies and perioperative medications are adjusted according to renal function. Patients with severely impaired renal function frequently require at least temporary hemodialysis after surgery. These patients also have a mortality rate that is signifi-cantly higher than normal. Patients with thoracoabdominal aortic aneurysms and poor renal function secondary to severe proximal renal occlusive disease undergo renal artery endarterectomy, stent-ing, or bypass grafting during the aortic repair.Operative Repair Proximal Thoracic Aortic Aneurysms Open Repair Traditional open operations to repair proximal aortic aneurysms—which involve the ascending aorta, trans-verse aortic arch, or both—are performed through a midsternal incision and require cardiopulmonary bypass. The best choice of aortic replacement technique depends on the extent of the aneurysm and the condition of the aortic valve.71 The spectrum of operations (Fig. 22-4) ranges from simple graft replacement of the tubular portion of the ascending aorta only (Fig. 22-4A) to replacement of the ascending aorta and the proximal aortic arch (Fig. 22-4B) to graft replacement of the entire proximal aorta, including the aortic root, and reattachment of the coronary Brunicardi_Ch22_p0853-p0896.indd 86101/03/19 5:40 PM 862SPECIFIC CONSIDERATIONSPART IIABCEFGHIJDKFigure 22-4. Illustrations of proximal aortic repairs in which the native aortic root is left intact. A. Graft replacement of the tubular portion of the ascending aorta with the aortic arch left intact. B. Hemiarch beveled graft replacement, in which the ascending aorta and a portion of the lesser curvature of the aortic arch are replaced. C. A modified arch with additional graft replacement of the innominate artery. D. Patch repair of the aortic arch. E. Traditional total arch replacement using an island approach to reattach the brachiocephalic vessels. F. The branched graft approach, which replaces the brachiocephalic vessels by following their original anatomic location. G. The elephant trunk approach with a concomitant island brachiocephalic artery reattachment. Contemporary Y-graft arch repairs include (H) the single Y-graft approach, (I) the double Y-graft approach, (J) the elephant trunk approach with a single Y-graft, and (K) the elephant trunk approach with a double Y-graft.Brunicardi_Ch22_p0853-p0896.indd 86201/03/19 5:40 PM 863THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22arteries and brachiocephalic branches. The options for treating aortic valve disease, repairing aortic aneurysms, and maintain-ing perfusion during repair procedures each deserve detailed consideration (Table 22-2).Aortic Valve Disease and Root Aneurysms Many patients undergoing proximal aortic operations have aortic valve dis-ease that requires concomitant surgical correction. When such disease is present and the sinus segment is normal, separate repair or replacement of the aortic valve and graft replacement of the tubular segment of the ascending aorta are carried out. In such cases, mild to moderate valve regurgitation with annular dilatation can be addressed by plicating the annulus with mat-tress sutures placed below each commissure, thereby preserving the native valve. In patients with more severe valvular regur-gitation or with valvular stenosis, the valve is replaced with a stented biologic or mechanical prosthesis; mechanical prosthe-ses necessitate following a lifelong anticoagulation regimen. Separate replacement of the aortic valve and ascending aorta is Table 22-2Options for open surgical repair of proximal aortic aneurysmsOptions for treating aortic valve disease Aortic valve annuloplasty (annular plication) Aortic valve replacement (with mechanical or biologic prosthesis) Aortic root replacement  Composite valve graft (with mechanical or biologic valve)  Aortic homograft  Stentless porcine root  Pulmonary autograft (Ross procedure)  Valve-sparing techniquesOptions for graft repair of the aortic aneurysm Patch aortoplasty Ascending replacement only Beveled hemiarch replacement Total arch replacement with reattachment of brachiocephalic branches (island technique)  Elephant trunk technique with island reattachment Total arch replacement with bypass grafts to the brachiocephalic branches (including Y-graft approaches)  Elephant trunk technique with Y-graft approach Hybrid aortic arch repairs (including “frozen elephant trunk technique”)Perfusion options Standard cardiopulmonary bypass Profound hypothermic circulatory arrest without adjuncts Hypothermic circulatory arrest with adjuncts  Retrograde cerebral perfusion  Antegrade cerebral perfusion   Balloon perfusion catheters   Right axillary artery cannulation   Innominate artery cannulationnot performed in patients with Marfan syndrome or Loeys-Dietz syndrome, because progressive dilatation of the remaining sinus segment eventually leads to complications that necessitate reop-eration. Therefore, patients with Marfan syndrome, Loeys-Dietz syndrome, or annuloaortic ectasia require some form of aortic root replacement.72In many cases, the aortic root is replaced with a mechani-cal or biologic graft that has both a valve and an aortic conduit. Currently, the following graft options are commercially avail-able: composite valve grafts with a mechanical valve, which consist of a bileaflet mechanical valve attached to a polyester tube graft; composite valve grafts with a biological valve (avail-able in Europe only at this point); aortic root homografts, which are harvested from cadavers and cryopreserved73; and stentless porcine aortic root grafts.74,75 In the United States, because no biologic composite valve grafts are commercially available, another option for surgeons is to construct a bioprosthetic com-posite valve graft during the operation by suturing a stented tis-sue valve to a polyester tube graft.Although select patients may be offered the Ross procedure—in which the patient’s pulmonary artery root is excised and placed in the aortic position and then the right ven-tricular outflow tract is reconstructed by using a cryopreserved pulmonary homograft—this option is rarely used. This is largely because it is a technically demanding procedure, and there are concerns about the potential for autograft dilatation in patients with heritable conditions.76An additional option is valve-sparing aortic root replace-ment, which has evolved substantially during the past decade.77,78 The valve-sparing technique that is currently favored is called aortic root reimplantation and involves excising the aortic sinuses, attaching a prosthetic graft to the patient’s annulus (Fig. 22-5), and resuspending the native aortic valve inside the graft. The superior hemodynamics of the native valve and the avoidance of anticoagulation are major advantages of the valve-sparing approach. Long-term results in carefully selected patients have been excellent.79 Although the durability of this procedure in patients with Marfan syndrome has been satisfac-tory in some centers, it remains uncertain whether long-term durability can be reliably achieved with this approach.78 Further, acceptable mid-term outcomes have been reported for patients with bicuspid aortic valve.80 Patients who have structural leaf-let deterioration or excessive annular dilatation are typically deemed unsuitable for valve-sparing repair.Regardless of the type of conduit used, aortic root replace-ment requires reattaching the coronary arteries to openings in the graft. In the original procedure described by Bentall and De Bono,81 this was accomplished by suturing the intact aortic wall surrounding each coronary artery to the openings in the graft. The aortic wall was then wrapped around the graft to establish hemostasis. However, this technique frequently pro-duced leaks at the coronary reattachment sites that eventually led to pseudoaneurysm formation. Cabrol’s modification, in which a separate, small tube graft is sutured to the coronary ostia and the main aortic graft, achieves tension-free coronary anas-tomoses, and reduces the risk of pseudoaneurysm formation.82 Kouchoukos’s button modification of the Bentall procedure is currently the most widely used technique.83 The aneurysmal aorta is excised, and buttons of aortic wall are left surrounding both coronary arteries, which are then mobilized and sutured to the aortic graft (Fig. 22-6). The coronary suture lines may be reinforced with polytetrafluoroethylene felt or pericardium Brunicardi_Ch22_p0853-p0896.indd 86301/03/19 5:40 PM 864SPECIFIC CONSIDERATIONSPART IIAEIJKLFGHBCDFigure 22-5. Illustration of our current valve-sparing procedure for replacing the aortic root and ascending aorta for treatment of (A) aortic root aneurysm. B. The ascending aorta is opened after cardiopulmonary bypass and cardioplegic arrest are established and the distal ascending aorta is clamped. The diseased aortic tissue (including the sinuses of Valsalva) is excised. Buttons of surrounding tissue are used to mobi-lize the origins of the coronary arteries. C. A synthetic graft is sewn to the distal ascending aorta with continuous suture. D. After the distal anastomosis is completed, six sutures reinforced with Teflon pledgets are placed in the plane immediately below the aortic valve annulus. E. The subannular sutures are placed through the base of a synthetic aortic root graft, which is then is parachuted down around the valve. F. After the root graft is cut to an appropriate length, the valve commissures and leaflets are positioned within the graft. The annular sutures are then tied. G. Each of the three commissures is then secured near the top of the graft. H. The supra-annular aortic tissue is sewn to the graft in continuous fashion. I. The button surrounding the origin of the left main coronary artery is sewn to an opening cut in the root graft. J. The two aortic grafts are sewn together with continuous suture. K. The button surrounding the origin of the right coronary artery is sewn to an opening cut in the root graft. L. The completed valve-sparing aortic root replacement and graft repair of the ascending aorta are shown. (Used with permission of Baylor College of Medicine.)to enhance hemostasis. When the coronary arteries cannot be mobilized adequately because of extremely large aneurysms or scarring from previous surgery, the Cabrol technique or a related modification can be used. Another option, originally described by Zubiate and Kay,84 is the construction of bypass grafts by using interposition saphenous vein or synthetic grafts.Aortic Arch Aneurysms Several options are also available for handling aneurysms that extend into the transverse aortic arch Brunicardi_Ch22_p0853-p0896.indd 86401/03/19 5:40 PM 865THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22Figure 22-6. Illustration of the modified Bentall procedure for replacing the aortic root and ascending aorta. Commonly, the ascending aorta is replaced by a straight “tube” graft, and the aortic root, including the valve apparatus and the sinuses of Valsalva, is replaced by a mechanical composite valve graft with neosinuses to better mimic its native shape. The coronary arteries with buttons of surrounding aortic tissue have been mobilized and are being reat-tached to openings in the aortic graft. Shown at the proximal aspect of the innominate artery, the ligated remnant of an 8-mm graft was used to ease cannulation of the artery, which was used as inflow during cardiopulmonary bypass. (Used with permission of Baylor College of Medicine.)(see Fig. 22-4C-K).65 The surgical approach depends on the extent of involvement and the need for cardiac and cerebral pro-tection. Saccular aneurysms that arise from the lesser curvature of the distal transverse arch and that encompass <50% of the aortic circumference can be treated by patch graft aortoplasty; such aneurysms are particularly well suited for hybrid repair with arch debranching followed by exclusion of the aneurysm with an endovascular graft.85 For fusiform aneurysms, when the distal portion of the arch is a reasonable size, a single, beveled replacement of the lower curvature (hemiarch) is performed. More extensive arch aneurysms require total replacement involving a distal anastomosis to the proximal descending tho-racic aorta and separate reattachment of the brachiocephalic branches. The brachiocephalic vessels can be reattached to one or more openings made in the graft, or if these vessels are aneurysmal, they can be replaced with separate, smaller grafts. Alternatively, a Y-graft approach86,87 can be used to debranch the brachiocephalic vessels and move them forward, thereby permitting the distal anastomosis to be brought forward, which aids in hemostasis. When the aneurysm involves the entire arch and extends into the descending thoracic aorta, it is approached by using Borst’s elephant trunk technique of staged total arch replacement.88 The distal anastomosis is performed such that a portion of the graft is left suspended within the proximal descending thoracic aorta (Fig. 22-7). A collared graft can be used to accommodate any discrepancy in aortic diameter.86 During a subsequent operation, the suspended “trunk” is used to facilitate repair of the remaining descending thoracic or tho-racoabdominal aortic aneurysm by an endovascular technique or by open repair through a thoracotomy incision, depending on the extent of disease and other factors. The elephant trunk technique permits access to the distal portion of the graft during the second operation without the need for dissection around the distal transverse aortic arch; this reduces the risk of injuring the left recurrent laryngeal nerve, esophagus, and pulmonary artery if an open approach is used at the second stage. As described in the section on hybrid repair of arch aneurysms (see later), the elephant trunk can be completed by using a hybrid endovascular approach (Fig. 22-8) in certain settings. A newer technique that is currently under investigation involves using a graft compris-ing a conventional polyester proximal portion and a stent graft distal elephant trunk portion. This “frozen elephant trunk” tech-nique can enable treatment of the entire aortic pathology during a single procedure or can facilitate a subsequent endovascular procedure (Fig. 22-9).89-91Cardiopulmonary Bypass Perfusion Strategies Like the opera-tions themselves, perfusion strategies used during proximal aor-tic surgery depend on the extent of the repair. Aneurysms that are isolated to the ascending segment can be replaced by using standard cardiopulmonary bypass and distal ascending aortic clamping. This provides constant perfusion of the brain and other vital organs during the repair. Aneurysms involving the transverse aortic arch, however, cannot be clamped during the repair, which necessitates the temporary withdrawal of cardio-pulmonary bypass support; this is called circulatory arrest. To protect the brain and other vital organs during the circulatory arrest period, hypothermia must be initiated before pump flow is stopped. However, the deep levels of hypothermia (below 20°C) that have been traditionally used in open arch repair are not without risk, and pure hypothermic circulatory arrest contin-ues to have substantial limitations. Importantly, although brief periods of total circulatory arrest generally are well tolerated at cold temperatures, as the duration of circulatory arrest increases, the well-recognized risks of brain injury and death increase dra-matically. Additionally, deep levels of hypothermia are associ-ated with coagulopathy.Because of the inherent complexity of aortic arch repairs and their general tendency to require longer periods Brunicardi_Ch22_p0853-p0896.indd 86501/03/19 5:41 PM 866SPECIFIC CONSIDERATIONSPART IIADFGECBFigure 22-7. Illustration of a contemporary Y-graft approach to total arch replacement for aortic arch aneurysm. A. The proximal portions of the brachiocephalic arteries are exposed. B. The first two branches of the graft are sewn end-to-end to the transected left subclavian and left common carotid arteries. The proximal ends of the transected brachiocephalic arteries are ligated. C. A balloon-tipped perfusion cannula is placed inside the double Y-graft and used to deliver antegrade cerebral perfusion. After systemic circulatory arrest is initiated, the innominate artery is clamped, transected, and sewn to the distal end of the main graft. D. The proximal aspect of the Y-graft is clamped. This directs flow from the axillary artery to all three brachiocephalic arteries. The arch is then replaced with a collared elephant trunk graft. E. The distal anastomosis between the elephant trunk graft and the aorta is created between the innominate and left common carotid arteries. The collared graft accommodates any discrepancy in aortic diameter. F. The aortic graft is clamped, and a second limb from the arterial inflow tubing of the cardiopulmonary bypass circuit is used to deliver systemic perfusion through a side-branch of the arch graft while the proximal por-tion of the ascending aorta is replaced. Once the proximal aortic anastomosis is completed, the main trunk of the double Y-graft is cut to an appropriate length, and the beveled end is then sewn to an oval opening created in the right anterolateral aspect of the ascending aortic graft, which completes the repair (G). (Modified with permission from LeMaire SA, Price MD, Parenti JL, et al. Early outcomes after aortic arch replacement by using the Y-graft technique, Ann Thorac Surg. 2011 Mar;91(3):700-707.)of hypothermic circulatory arrest, two cerebral perfusion strategies—retrograde cerebral perfusion (RCP) and antegrade cerebral perfusion (ACP)—were developed to supplement this process by delivering cold, oxygenated blood to the brain and further reduce the risks associated with repair. Retrograde cerebral perfusion involves directing blood from the cardio-pulmonary bypass circuit into the brain through the superior vena cava.92 However, RCP is thought to be less beneficial than ACP,93 and although it may be helpful in the retrograde flush-ing of air and debris from the arch, many centers have stopped using RCP.In contrast, ACP delivers blood directly into the brachio-cephalic arteries to maintain cerebral flow. Although its use was cumbersome in the past, contemporary ACP techniques (Fig. 22-10) have been simplified and commonly involve can-nulating either the right axillary artery or the innominate artery and subsequent connection to the cardiopulmonary bypass circuit.94-96 Often, a small section of graft is used as a conduit to ease cannulation, but there remains a small procedure-related risk of brachial plexus or vascular injury. Upon initiation, cold blood is delivered into the brain via the right common carotid artery and, if bilateral ACP is desired, the left common carotid artery. Note that, with the unilateral ACP technique, blood flow to the left side of the brain requires collateral circulation, ideally through an intact circle of Willis.Methods to help determine the adequacy of unilateral ACP to deliver cerebral cross-circulation include preoperative imag-ing and intraoperative monitoring. A commonly used method Brunicardi_Ch22_p0853-p0896.indd 86601/03/19 5:41 PM 867THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22ABCFigure 22-8. Illustration of Borst’s elephant trunk technique using a contemporary Y-graft approach. A. Stage 1: The proximal repair includes replacing the ascending aorta and entire arch, with Y-graft reattachment of the brachiocephalic vessels. The distal anastomosis is facilitated by using a collared elephant trunk graft to accommodate the larger diameter of the distal aorta. A section of the graft is left sus-pended within the proximal descending thoracic aorta. B. Stage 2: The distal repair uses the floating “trunk” for the proximal anastomosis. C. An alternate “hybrid” approach may be used in patients with less extensive distal aortic disease. Endovascular stent grafts are placed within the elephant trunk to complete the repair. (Used with permission of Baylor College of Medicine.)ABFigure 22-9. Illustration of a frozen elephant trunk repair, which is a hybrid approach to repair that combines open aortic replacement with endovascular aortic repair. A. Extensive aortic disease affects the proximal and distal aorta. B. Aortic repair is extended into the proximal por-tion of the descending thoracic aorta after the transverse aortic arch is fully replaced. (Used with permission of Baylor College of Medicine.)Brunicardi_Ch22_p0853-p0896.indd 86701/03/19 5:41 PM 868SPECIFIC CONSIDERATIONSPART IIFigure 22-10. Illustration of a contemporary technique for deliv-ering antegrade cerebral perfusion during aortic arch repair. A. A graft sewn to the right axillary artery or to the innominate artery (inset) is used to return oxygenated blood from the cardiopulmo-nary bypass circuit. B. After adequate hypothermia is established, the innominate artery is occluded with a tourniquet (inset) so that flow is diverted to the right common carotid artery, which maintains cerebral circulation. (Used with permission from Baylor College of Medicine.)of intraoperative monitoring is brain near-infrared spectroscopy (NIRS), which measures cerebral oxygenation. If NIRS moni-toring indicates inadequate perfusion, an additional perfusion catheter can be inserted into the left common carotid artery to provide blood flow to the left side of the brain.Because ACP provides excellent brain protection, many surgeons now use more moderate levels of hypothermia (often between 22°C and 24°C) to decrease the risks associated with deep hypothermia.97 However, some authors have raised the ABconcern that reducing the degree of hypothermia increases the risk of ischemic complications involving the spinal cord, kid-neys, and other organs that are ischemic (without the benefit of deep hypothermia) during the systemic circulatory arrest period.98 Consequently, some groups supplement ACP with additional perfusion strategies that provide flow to the descend-ing aorta during arch repair.99,100Endovascular Repair Experience with purely endovascular treatment of proximal aortic disease remains limited and only investigational.101 The unique anatomy of the aortic arch and the need for uninterrupted cerebral perfusion pose difficult chal-lenges. There are reports of the use of “homemade” grafts to exclude arch aneurysms; however, these grafts are experimen-tal at this time. For example, in 1999, Inoue and colleagues102 reported placing a triple-branched stent graft in a patient with an aneurysm of the aortic arch. The three brachiocephalic branches were positioned by placing percutaneous wires in the right brachial, left carotid, and left brachial arteries. The patient underwent two subsequent procedures: surgical repair of a right brachial pseudoaneurysm and placement of a distal stent graft extension to control a major perigraft leak. Since then, efforts to employ endovascular techniques in the treatment of the proxi-mal aorta have been essentially limited to the use of approved devices for off-label indications, such as the exclusion of pseu-doaneurysms in the ascending aorta.Hybrid Repair In June 1991, the Ukrainian surgeon Nikolay Volodos and his colleagues performed the first hybrid aortic arch repair103,104; 22 years later, Volodos reported that the patient was still alive.105 Unlike purely endovascular approaches, hybrid repairs of the aortic arch have entered the mainstream clinical arena, although they remain controversial. Hybrid arch repairs involve some form of “debranching” of the brachiocephalic vessels (which are not unlike Y-graft approaches), followed by endovascular exclusion of some or all of the aortic arch (Fig. 22-11). Although this technique has many variants, they often involve sewing a branched graft to the proximal ascend-ing aorta with the use of a partial aortic clamp. The branches of the graft are then sewn to the arch vessels. Once the arch is “debranched,” the arch aneurysm can be excluded with an endograft. Commonly, a zone 0 approach (Fig. 22-12) is under-taken in which the proximal end of the endograft is secured within the ascending aorta. Other hybrid approaches aim to extend repair into the distal arch and descending thoracic aorta (see the following section). The arguments for using a hybrid approach to treat aortic arch aneurysm include the potential to avoid using cardiopulmonary bypass, circulatory arrest, and car-diac ischemia.59,60It is not yet clear whether hybrid repairs are as durable as traditional ones because little midor long-term data have been published, and there are very few comparative studies.65 Procedure-related risks include the risk of embolization and stroke due to wire and device manipulation within the aortic arch (this risk appears to be greatest in zone 0 repairs106), retrograde acute aortic dissection,107 type I endoleak,108 and paraplegia.27 Because iatrogenic retrograde dissection of the ascending aorta is a particularly lethal complication, special considerations, including careful blood pressure management and wire manipulation, are recommended to avoid this problem in patients who are undergoing hybrid arch zone 0 stent deployment.109 Notably, patients with an ascending aortic diameter greater than 4.2 cm may be more susceptible to retrograde dissection. In an effort to Brunicardi_Ch22_p0853-p0896.indd 86801/03/19 5:41 PM 869THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22Figure 22-11. Illustration of a “Zone 0” hybrid arch repair. A. A distal arch aneurysm is shown that extends into the proximal aspect of the descending thoracic aorta. B. The brachiocephalic vessels are debranched onto a Y-graft, and a separate graft is used as a conduit for ante-grade endovascular deployment of the stent graft. C. In the completed repair, the proximal landing zone of the endograft is within zone 0. (Used with permission from Baylor College of Medicine.)reduce the risk of iatrogenic dissection, some centers have begun to replace a small section of the ascending aorta with a standard polyester graft such that the endograft’s proximal landing zone comprises prosthetic material rather than native aortic tissue.107Distal Thoracic Aortic Aneurysms Open Repair In patients with descending thoracic or thoracoab-dominal aortic aneurysms, several aspects of treatment—includ-ing preoperative risk assessment, anesthetic management, choice of incision, and use of protective adjuncts—are dictated by the overall extent of aortic involvement. By definition, descend-ing thoracic aortic aneurysms involve the portion of the aorta between the left subclavian artery and the diaphragm. Thora-coabdominal aneurysms can involve the entire thoracoabdominal aorta, from the origin of the left subclavian artery to the aortic bifurcation. Surgical repair of thoracoabdominal aortic aneu-rysms is categorized by the extent of aortic replacement accord-ing to the Crawford classification scheme (Fig. 22-13). Extent I thoracoabdominal aortic aneurysm repairs involve most of the descending thoracic aorta, usually beginning near the left sub-clavian artery, and extend down into the suprarenal abdominal aorta. Extent II repairs also begin near the left subclavian artery but extend distally into the infrarenal abdominal aorta, and they often reach the aortic bifurcation. Extent III repairs extend from the lower descending thoracic aorta (below the sixth rib) and into the abdomen. Extent IV repairs begin at the diaphragmatic hiatus and often involve the entire abdominal aorta.Descending thoracic aortic aneurysms not amenable to endovascular therapy are currently repaired through a left thoracotomy. In patients with thoracoabdominal aortic aneu-rysm, the thoracotomy is extended across the costal margin and into the abdomen.110 Using a double-lumen endobronchial tube allows selective ventilation of the right lung and deflation of the left lung. Transperitoneal exposure of the thoracoabdominal aorta is achieved by performing medial visceral rotation and circumferential division of the diaphragm. During a period of aortic clamping, the diseased segment is replaced with a polyes-ter tube graft. Important branch arteries—including intercostal arteries and the celiac, superior mesenteric, and renal arteries—are reattached to openings made in the side of the graft. In patients with Marfan syndrome and other heritable conditions, separate (8and 10-mm) grafts to the visceral branches are often used to prevent subsequent “patch aneurysms” that can develop in residual aortic tissue.111 Visceral and renal artery occlusive dis-ease is commonly encountered during aneurysm repair; options for correcting branch-vessel stenosis include endarterectomy, direct arterial stenting, and bypass grafting.Clamping the descending thoracic aorta causes ischemia of the spinal cord and abdominal viscera. Clinically significant manifestations of hepatic, pancreatic, and bowel ischemia are relatively uncommon. However, both acute renal failure and spinal cord injury resulting in paraplegia or paraparesis remain major causes of morbidity and mortality after these operations. Therefore, several aspects of the operation are devoted to minimizing spinal and renal ischemia (Table 22-3). Our multimodal approach to spinal cord protection includes expeditious repair to minimize aortic clamping time, moderate systemic heparinization (1.0 mg/kg) to prevent small-vessel AB5-FrenchsheathMarked pigtailcatheterDeliverysheathStiffguidewireUndeployedendograftCBrunicardi_Ch22_p0853-p0896.indd 86901/03/19 5:41 PM 870SPECIFIC CONSIDERATIONSPART IIFigure 22-13. Illustration of the Crawford classification of thora-coabdominal aortic aneurysm repair, based on the extent of aortic replacement. (Used with permission from Baylor College of Medicine.)Right commoncarotid arteryInnominatearteryLeft commoncarotid arteryLeft subclavianarteryLanding Zone ClassificationsFigure 22-12. Illustration of the Criado landing zones, which are used to describe aortic anatomy during thoracic endovascular repair. The arch is the short segment that includes the origins of the three brachiocephalic arteries—the innominate artery, the left com-mon carotid artery, and the left subclavian artery. Zone 0 includes the ascending aorta and the origin of the innominate artery. Zone 1 includes the origin of the left common carotid artery. Zone 2 includes the left subclavian artery origin. Zone 3 is a short section of the aorta that comprises the 2 cm immediately distal to the origin of the left subclavian artery, and zone 4 begins where zone 3 ends. (Used with permission from Baylor College of Medicine.)Table 22-3Current strategy for spinal cord and visceral protection during repair of distal thoracic aortic aneurysmsAll extents• Permissive mild hypothermia (32°C–34°C, nasopharyngeal)• Moderate heparinization (1 mg/kg)• Aggressive reattachment of segmental arteries, especially between T8 and L1• Sequential aortic clamping when possible• Perfusion of renal arteries with 4°C crystalloid solution when possibleCrawford extent I and II thoracoabdominal repairs• Cerebrospinal fluid drainage• Left heart bypass during proximal anastomosis• Selective perfusion of celiac axis and superior mesenteric artery during intercostal and visceral anastomosesthrombosis, mild permissive hypothermia (32°C to 34°C [89.6°F to 93.2°F] nasopharyngeal temperature), and reattachment of segmental intercostal and lumbar arteries. As the aorta is replaced from proximal to distal, the aortic clamp is moved sequentially to lower positions along the graft to restore perfusion to newly reattached branch vessels. During extensive thoracoabdominal aortic repairs (i.e., Crawford extent I and II repairs), cerebrospinal fluid drainage is used to improve spinal perfusion by reducing cerebrospinal fluid pressure. Because the benefits of this adjunct have been confirmed in a randomized clinical trial,112 its use is recommended in current guidelines (Class I, Level B recommendation).44 During cerebral spinal fluid drainage, the cerebral spinal fluid pressure is closely monitored, and the amount of fluid that is removed is carefully limited to avoid the devastating complication of intracranial hemorrhage.113 Motor evoked potentials are used by some groups to monitor the spinal cord throughout the operation.114,115 Left heart bypass, which provides perfusion of the distal aorta and its branches during the clamping period, is also used during extensive thoracoabdominal aortic repairs.116-118 Because left heart bypass unloads the heart, it is also useful in patients with poor cardiac reserve. Balloon perfusion cannulas connected to the left heart bypass circuit can be used to deliver blood directly to the celiac axis and superior mesenteric artery during their reattachment. The potential benefits of reducing hepatic and bowel ischemia include reduced risks of postoperative coagulopathy and bacterial translocation, respectively. Whenever possible, renal protection is achieved by perfusing the kidneys with cold (4°C [39.2°F]) crystalloid. In a randomized clinical trial, reduced kidney temperature was found to be associated with renal protection, and the use of cold crystalloid independently predicted preserved renal function.119Hypothermic circulatory arrest can also be used dur-ing descending thoracic or thoracoabdominal aortic repairs.120 At our center, the primary indication for this approach is the inability to clamp the aorta because of rupture, extremely large aneurysm size, or extension of the aneurysm into the distal transverse aortic arch, or because a prior endovascular repair hinders clamping.67As discussed previously, complete repair of extensive aneurysm involving the ascending aorta, transverse arch, and descending thoracic aorta generally requires staged open 7Brunicardi_Ch22_p0853-p0896.indd 87001/03/19 5:41 PM 871THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22Figure 22-14. Illustration of the reversed elephant trunk technique using a traditional “island” approach to total aortic arch replacement. A. Stage 1: The distal aorta is repaired through a left thoracoabdominal approach. The aneurysm is opened after the aorta is clamped between the left common carotid artery and the left subclavian artery, which is also clamped. Before the proximal anastomosis is performed, the end of the graft is partly invaginated to leave a “trunk” for the subsequent repair. Proximal intercostal arteries are oversewn. B. After the proximal suture line is completed, the clamps are repositioned to restore blood flow to the left subclavian artery. The repair is completed by reattaching patent intercostal arteries to an opening in the side of the graft and creating a beveled distal anastomosis at the level of the visceral branches. C. Stage 2: The proximal aorta is repaired through a median sternotomy. The aortic arch is opened under hypothermic circulatory arrest. The “trunk” is pulled out and used to replace the aortic arch and ascending aorta. This eliminates the need for a new distal anastomosis and sim-plifies the procedure. Circulatory arrest and operative time, along with their attendant risks, are reduced. D. The completed two-stage repair of the entire thoracic aorta. (Modified with permission from Coselli JS, LeMaire SA, Carter SA, et al: The reversed elephant trunk technique used for treatment of complex aneurysms of the entire thoracic aorta, Ann Thorac Surg. 2005 Dec;80(6):2166-2172.)operations or a hybrid approach. In such procedures, when the descending or thoracoabdominal component is symptomatic (e.g., causes back pain or has ruptured) or is disproportionately large (compared with the ascending aorta), the distal segment is treated during the initial operation, and repair of the ascend-ing aorta and transverse aortic arch is performed as a second procedure. A reversed elephant trunk repair, in which a portion of the proximal end of the aortic graft is inverted down into the lumen, can be performed during the first operation; this tech-nique facilitates the second-stage repair of the ascending aorta and transverse aortic arch (Fig. 22-14).121Although spinal cord ischemia and renal failure receive the most attention, several other complications warrant consid-eration. The most common complication of extensive repairs is pulmonary dysfunction. With aneurysms adjacent to the left subclavian artery, the vagus and left recurrent laryngeal nerves are often adherent to the aortic wall and thus are susceptible to injury. Vocal cord paralysis should be suspected in patients who have postoperative hoarseness, and the presence of nerve damage should be confirmed by endoscopic examination. Vocal cord paralysis can be treated effectively by direct cord medial-ization (type 1 thyroplasty).122 Injury to the esophagus during Brunicardi_Ch22_p0853-p0896.indd 87101/03/19 5:41 PM 872SPECIFIC CONSIDERATIONSPART IIFigure 22-15. Illustration of a thoracoabdominal aortic aneurysm repair in a patient with a patent left internal thoracic artery-to-left anterior descending coronary artery graft. The proximal anastomosis is being performed while the aorta is clamped between the left common carotid and subclavian arteries. Myo-cardial perfusion is maintained through the carotid-subclavian bypass graft. (Modifed with permission from Jones MM, Akay M, Murariu D, et al: Safe aortic arch clamping in patients with patent inter-nal thoracic artery grafts. Ann Thorac Surg. 2010 Apr;89(4):e31-e32.)the proximal anastomosis can have catastrophic consequences. Carefully separating the proximal descending thoracic aorta from the underlying esophagus before performing the proximal anastomosis minimizes the risk of a secondary aortoesophageal fistula. In patients who have previously undergone coronary artery bypass with a left internal thoracic artery graft, clamp-ing proximal to the left subclavian artery can precipitate severe myocardial ischemia and cardiac arrest. When the need to clamp at this location is anticipated in these patients, a left common carotid-to-subclavian bypass is performed to prevent cardiac complications (Fig. 22-15).123Endovascular Repair Descending Thoracic Aortic Aneurysms Stent graft repair has become the standard treatment for patients with descending thoracic aortic aneurysm.55,56,124 Although aortic repair with a self-fixing endoprosthesis was reported by Volodos103,104 in the mid 1980s, it was the report by Parodi and associates125 of using endovascular stent grafting to repair abdominal aortic aneurysm that launched widespread interest in developing this approach. Only 3 years after this seminal report was published, Dake and colleagues126 reported performing endovascular descending tho-racic aortic repair with “homemade” stent grafts in 13 patients.Guidelines for the use of endovascular repair in thoracic aortic disease have been published,44 and reporting standards to uniformly describe the endovascular repair process have been established.127 Although endografting was initially approved to treat degenerative descending thoracic aortic aneurysm, newer devices have been approved for use in treating various descending thoracic aortic pathologies, including blunt aortic injury, penetrating aortic ulcer (see following section), coarcta-tion, and dissection. Although the use of stent grafts in cases of aortic infection is not ideal, patients with a fistula or mycotic aneurysm are sometimes treated with endovascular devices as a bridge to open repair.In elderly patients with severe comorbidity and patients who have undergone previous complex thoracic aortic procedures, endovascular repair is a particularly attractive alternative to stan-dard open surgical procedures.128 Patients who undergo endo-vascular repair tend to have a lower incidence of intraoperative complications, a shorter length of stay, and a higher likelihood of being discharged to home than those who undergo open repair.129 As mentioned previously, appropriate patient selection depends on specific measurements taken from preoperative CT angiograms.To protect patients against spinal cord ischemia during endovascular repair of the descending thoracic aorta, the most important maneuver is to keep the mean arterial perfusion pres-sure between 90 and 110 mmHg after the endograft is deployed. In patients who have had previous open or endovascular abdom-inal aortic aneurysm repair, cerebrospinal fluid drainage is rec-ommended.130 The first step in the repair procedure is to obtain appropriate vascular access for the insertion of the thoracic stent graft. If the femoral artery will not accommodate the necessary Brunicardi_Ch22_p0853-p0896.indd 87201/03/19 5:41 PM 873THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22sheath, then an iliac artery is exposed. If necessary, a graft can be sewn to the iliac artery in an end-to-side fashion to facilitate the deployment of the endograft. After 5,000 to 10,000 units of heparin are administered, a guidewire and the delivery sheath are typically inserted into the access artery under fluoroscopic guidance; depending on which endovascular device is used, the stent graft can be advanced through a sheath or with no sheath. The endograft is then advanced into the aorta and suitably posi-tioned. Note that the best view of the distal arch and descending thoracic aorta is usually in the left anterior oblique position at an angle of approximately 40° to 50°. The device is then deployed, and the proximal and distal ends can be ballooned for better apposition of the stent graft to the aortic wall. An aortogram is then performed to rule out any endoleak, and protamine is administered. As an alternative to aortography, intravascular ultrasonography (IVUS) can be used to identify the proximal and distal landing zones, and the entire procedure can be per-formed with minimal or no contrast.Although it is not uncommon to cover the left subcla-vian artery with the endograft to lengthen the proximal landing zone,131 findings suggest that the risk of spinal cord complica-tions is heightened when the subclavian artery is covered and not revascularized, presumably because of a loss of collateral circulation to the spinal cord.132 To prevent this complication, a carotid-to-subclavian bypass can be easily constructed to main-tain vertebral artery blood flow and minimize neurologic injury (Fig. 22-16).133,134 In addition, recent studies suggest that revas-cularization of the left subclavian artery is associated with lower stroke risk in patients in whom an endograft was deployed in Zone 2 and covered the left subclavian artery.135 In addition, new generations of stent grafts are being designed with side branches that can be placed within the left subclavian artery. This feature is particularly attractive if the proximal neck is short or if the patient has a patent left internal thoracic artery-to-left anterior descending coronary artery bypass. Indications for left subclavian artery revascularization include previous coro-nary artery bypass with patent internal thoracic artery, dominant left vertebral artery, aneurysm arising from the left subclavian artery, left arm arterio-venous fistula, and coverage of a long segment of the descending thoracic aorta.Elephant Trunk Completion In select patients, elephant trunk completion repairs can be done with an endovascular approach (see Fig. 22-8C), rather than by the traditional open operation through a thoracotomy.136 Recall that an elephant trunk is used when an aortic aneurysm extends from the distal arch to the descending thoracic aorta. An endograft can be deployed at the time of elephant trunk construction or during a separate, subse-quent procedure.97,107,137 When the stent is deployed in a retro-grade manner during a second-stage procedure, the procedure is facilitated by placing radiopaque markers at the end of the elephant trunk during the first-stage procedure. This allows the distal end of the trunk to be identified via fluoroscopy. A guide-wire can then be manipulated into the trunk and advanced into the ascending aorta to stabilize it during stent deployment. Note that advancing a wire in retrograde fashion from the femoral artery into the elephant trunk can be challenging. Occasionally, the wire must be advanced in an antegrade fashion from a bra-chial artery. The frozen elephant trunk technique—in which a short stent graft is delivered antegrade inside the trunk—can be used to perform the entire repair in one stage or to facilitate the second stage.89,90Thoracoabdominal Aortic Aneurysms Although endovascular thoracoabdominal aortic aneurysm repair remains experimental, it has been shown to be feasible in a handful of specialized cen-ters. Endovascular thoracoabdominal aortic aneurysm repairs are quite complex, because at least one of the visceral arteries is incorporated into the repair. The number of visceral branches that need to be addressed varies with the extent of aortic coverage.138 The types of stent grafts used include fenestrated grafts, reinforced fenestrated grafts, branched or cuffed grafts, modular combinations of grafts, and multilayer stents.139 Graft fenestrations and branch vessels are typically aligned by using inflatable angioplasty balloons. Procedure time is not insignifi-cant, nor is the amount of contrast medium required to obtain the highly detailed images needed to plan these procedures. In addi-tion, some of the stent grafts used in endovascular thoracoab-dominal aortic aneurysm repair are custom-made in advance and thus may take several weeks to obtain; therefore, their use is limited to cases of elective repair.107 In efforts to hasten repair and utilize off-the-shelf devices, parallel graft approaches, which use a combination of largeand small-diameter stents, have been reported.140 And, although some centers now propose distal coverage of the celiac axis141 for extent I thoracoabdomi-nal aortic aneurysm repairs, this potentially risky approach is not widely used.It should be noted that, like open thoracoabdominal aortic aneurysm repair, endovascular repair carries risks of paraplegia, renal failure, stroke, and death, despite the apparent benefits of its being a less invasive procedure. Notably, reports from centers experienced in endovascular thoracoabdominal aortic repair primarily describe limited extent IV repairs.64 Although the technology is progressing rapidly, at present endovascular thoracoabdominal aortic aneurysm repair should be considered investigational.Hybrid Repair Extensive hybrid thoracoabdominal aortic aneurysm repair142,143 can be a life-saving option in patients at high surgical risk, such as those who have limited physiologic reserve, are of advanced age, or have significant comorbidities. Hybrid procedures use open surgical techniques to reroute blood supply to the visceral arteries so that their aortic origins can be covered by stent grafts without causing visceral ischemia (Fig. 22-17). Endovascular methods are then used (either as part of the same procedure or at a later stage) to repair the aor-tic aneurysm, often with simple tube stent grafts; such devices are more readily available than the customized, modular stent grafts deployed in strictly endovascular repairs. Overall, results for hybrid thoracoabdominal aortic aneurysm repair have been somewhat disappointing.144 However, a handful of centers report acceptable outcomes in high-risk patients, particularly when a staged hybrid approach is used.145Postoperative Considerations Open Procedures Aortic anastomoses are often extremely fragile during the early postoperative period. Even brief episodes of postoperative hypertension can disrupt suture lines and precipitate severe bleeding or pseudoaneurysm formation. Therefore, during the initial 24 to 48 hours, meticulous blood pressure control is maintained to protect the integrity of the anastomoses. Generally, we liberally use IV vasoactive agents to keep the mean arterial blood pressure between 80 and 90 mmHg. In patients with extremely friable aortic tissue, such as those with Marfan syndrome, we lower the target range to 70 to 80 mmHg. It is a delicate balancing act because one must be Brunicardi_Ch22_p0853-p0896.indd 87301/03/19 5:41 PM 874SPECIFIC CONSIDERATIONSPART IIFigure 22-16. Illustration of a “Zone 2” hybrid repair of the proximal descending thoracic aorta. A. The preoperative representation of the aneurysm shows that establishing a 2-cm proximal landing zone for a stent graft will require covering the origin of the left subclavian artery. B. Through a supraclavicular approach, a bypass from the left common carotid artery to the left subclavian artery is performed to reroute circulation and create a landing zone for the stent graft. After the bypass is completed, the left subclavian artery is ligated proximal to the graft. C. In the completed hybrid repair, the aneurysm has been excluded successfully by a stent graft that covers the origin of the left subclavian artery, and the proximal landing zone of the endograft is within zone 2. Importantly, blood flow to the left vertebral artery and arm is preserved by the bypass graft. (Reproduced with permission from Bozinovski J, LeMaire SA, Weldon SA: Hybrid Repairs of the Distal Aortic Arch and Proximal Descending Thoracic Aorta, Oper Tech Thorac Cardiovasc Surg 2007;12(3):167-177.)VertebralarterySubclavianarteryPhrenicnerveAnterior scalenemuscle (divided)Internal thoracicarterySternocleidomastoidmuscle (divided)Commoncarotid arteryVagusnerveABCBrunicardi_Ch22_p0853-p0896.indd 87401/03/19 5:41 PM 875THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22Figure 22-17. Illustration of a “Zone 0” hybrid approach—which combines open and endovascular techniques—for repair of an extensive aortic aneurysm. Debranching the arch and thoracoab-dominal segments allows the use of a series of endovascular stent grafts to exclude the entire aneurysm. Note that the arterial inflow for the debranched visceral arteries comes from the left common iliac artery.Table 22-4Classification of and common treatment strategies for endoleakType I• Incomplete seal between stent graft and aorta at the proximal landing site (Type Ia), the distal landing site (Type Ib), or branch module, fenestration, or plug (Type Ic)• Early reintervention to improve seal or conversion to open surgeryType II• Retrograde perfusion of sac from excluded collateral arteries• Surveillance; as-needed occlusion with percutaneous or other interventionsType III• Incomplete seal between overlapping stent graft or module (Type IIIa), or tear in graft fabric (Type IIIb)• Early reintervention to cover or conversion to open surgeryType IV• Perfusion of sac due to porosity of material• Surveillance; as-needed reintervention to reline stent graftType V• Expansion of sac with no identifiable source• Surveillance; as-needed reintervention to reline stent graftmindful of spinal cord perfusion and avoid periods of relative hypotension while maintaining these low pressures.Endovascular Procedures Many of the complications are directly related to manipulation of the delivery system within the iliac arteries and aorta.146 Patients with small, calcified, tor-tuous iliofemoral arteries are at particularly high risk for life-threatening iliac artery rupture. Although relatively uncommon, acute iatrogenic retrograde dissection into the aortic arch and ascending aorta is a life-threatening complication that neces-sitates emergency repair of the ascending aorta and aortic arch via sternotomy and cardiopulmonary bypass.109 The most important risk factors for this complication include incautious wire and catheter manipulation, aggressive proximal ballooning (especially in cases of acute descending thoracic aortic dissection), and hybrid arch repair in which the native ascending aorta is dilated (more than 4 cm). Retrograde proximal dissection con-verts a localized descending thoracic aortic aneurysm into an acute problem involving the entire thoracic aorta. Of note, ret-rograde aortic dissection may also occur several months after initial repair.147Another significant complication of descending thoracic aortic stent grafting is endoleak. An endoleak occurs when there is a persistent flow of blood (visible on radiologic imaging) into the aneurysm sac, and it may occur during the initial proce-dure or develop over time. Although endoleaks are a relatively common complication,148,149 they are not benign because they lead to continual pressurization of the sac, which can cause expansion or even rupture. These complications are categorized (Table 22-4) according to the site of the leak.127 Although all endoleaks may progress such that they can be considered life-threatening, type I and type III endoleaks generally necessitate early and aggressive intervention. Recently published reporting guidelines aid standardized reporting.127Other complications include stent graft misdeployment, device migration, endograft kinking or infolding, and stent graft infection, including fistula. Although not all complications related to stent grafts are fatal, endovascular repairs should be performed by expert teams qualified to address the variety of problems that may arise; some patients may need to have these devices removed and replaced with polyester grafts.67,68,150,151 Complications of endovascular repair are relatively common, so regularly scheduled radiologic imaging surveillance is of the utmost importance.Brunicardi_Ch22_p0853-p0896.indd 87501/03/19 5:41 PM 876SPECIFIC CONSIDERATIONSPART IIAORTIC DISSECTIONPathology and ClassificationAortic dissection, the most common catastrophic event involving the aorta, is a progressive separation of the aortic wall layers that usually occurs after a tear forms in the intima and inner media. As the separation of the layers of the media propagates, two channels are typically formed (Fig. 22-18): the original lumen, which remains lined by the intima and which is called the true lumen, and the newly formed channel within the layers of the media, which is called the false lumen. The dissecting membrane separates the true and false lumens. Additional tears in the dis-secting membrane that allow communication between the two channels are called reentry sites. Although the separation of lay-ers primarily progresses distally along the length of the aorta, it can also proceed in a proximal direction; this process often is referred to as proximal extension or retrograde dissection.The extensive disruption of the aortic wall has severe anatomic consequences (Fig. 22-19). First, the outer wall of the false lumen is extremely thin, inflamed, and fragile, which makes it prone to expansion or rupture in the face of ongoing hemodynamic stress. Second, the expanding false lumen can compress the true lumen and cause malperfusion syndrome by interfering with blood flow in the aorta or any of its branch vessels, including the coronary, carotid, inter-costal, visceral, renal, and iliac arteries. Finally, when the separation of layers occurs within the aortic root, the aortic valve commissures can become unhinged, which results in acute valvular regurgitation. The clinical consequences of each of these sequelae are addressed in detail in the section on clinical manifestations.Dissection vs. Aneurysm. The relationship between dissec-tion and aneurysmal disease requires clarification. Dissection and aneurysm are separate entities, although they often coexist and are mutual risk factors. In some cases, dissection occurs in patients without aneurysms, and the subsequent progressive dilatation of the weakened outer aortic wall ultimately results in an aneurysm. On the other hand, in patients with degenera-tive aneurysms, the ongoing deterioration of the aortic wall can lead to a superimposed dissection. The overused term dissecting aneurysm should be reserved for this specific situation.Classification. For management purposes, aortic dissec-tions are classified according to their location and chronicity. Improvements in imaging have increasingly revealed variants of aortic dissection that probably represent different forms along the spectrum of this condition.Location To guide treatment, dissections are categorized according to their anatomic location and extent. The two tra-ditional classification schemes that remain in common use are the DeBakey and the Stanford classification systems (Fig. 22-20).152,153 In their current forms, both of these schemes describe the segments of aorta that are involved in the dissec-tion, rather than the site of the initial intimal tear. The main drawback of the Stanford classification system is that it does not distinguish between patients with isolated ascending aor-tic dissection and patients with dissection involving the entire aorta. Both types of patients would be classified as having type A dissections, despite the fact that their treatment, follow-up, and prognosis are substantially different.Additional classification schemas include that by Borst and associates,154 in which the ascending and descending aorta are considered independently; the recent modification of the DeBakey classification by Tsagakis et al,155 which extends type II dissection into the aortic arch; and the Penn modification of the Stanford classification,156,157 which expands the classification to include the presence of tissue and global malperfusion. These modifications may help to better streamline the primary surgical intervention.Normal aortaAortic dissectionIntramural hematomaPenetrating aortic ulcerFigure 22-18. Illustration of longitudinal sections of the aortic wall and lumen. Blood flows freely downstream in normal aortic tissue. In classic aortic dissection, blood entering the media through a tear creates a false channel in the wall. Intramural hematomas arise when hemor-rhage from the vasa vasorum causes blood to collect within the media; the intima is intact. Penetrating aortic ulcers are deep atherosclerotic lesions that burrow into the aortic wall and allow blood to enter the media. In each of these conditions, the outer aortic wall is severely weakened and prone to rupture.Brunicardi_Ch22_p0853-p0896.indd 87601/03/19 5:42 PM 877THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22Figure 22-19. Illustration of the potential anatomic consequences of aortic dissection, with a mapped diagram of affected regions (inset). A. Ascending aortic rupture and cardiac tamponade. B. Disruption of coronary blood flow. C. Injury to the aortic valve causing regurgitation. D, E, and F. Compromised blood flow to branch vessels, causing ischemic complications. (Adapted with permission from Creager MA, Dzau VS, Loscalzo J: Vascular Medicine, 7th ed. Philadelphia, PA: Elsevier/Saunders; 2006.)Figure 22-20. Illustration of the classification schemes for aortic dissection based on which portions of the aorta are involved. Dissection can be confined to the ascending aorta (left) or the descending aorta (middle), or it can involve the entire aorta (right). (Used with permission from Baylor College of Medicine.)ABCDEFBrunicardi_Ch22_p0853-p0896.indd 87701/03/19 5:42 PM 878SPECIFIC CONSIDERATIONSPART IIContrast-enhanced CT scanTransfer to operatingroom, intubation,diagnostic TEESuspected acutedissectionAortic dissection?Ascending aorticdissection (Stanford A orDeBakey I or II)?Secondary diagnosticstudy (MRA, TEE, oraortography)Emergency operationEmergency operationTransfer to intensive carefor further stabilizationand diagnostic work-upTransfer to intensive care unitfor blood pressure control,anti-impulse therapy Emergency endovascular(fenestration, stent) oropen interventionYesYesYesYesYesYesNoNoNoNoNoNoFurther diagnosticwork-upHemodynamicallystable?Anti-impulse therapy(beta blockers),blood pressure controlAortic dissection?Complicated descendingaortic dissection (malperfusion, rupture)?Management of acute aortic dissectionAscending aorticdissection (Stanford A orDeBakey I or II)?Figure 22-21. Algorithm used to facilitate decisions regarding treatment of acute aortic dissection. CT = computed tomography; MRA = magnetic resonance angiography; TEE = transesophageal echocardiography.Regardless of which system is used, patients with isolated ascending aortic dissection usually undergo emergent opera-tion, as do patients with dissection involving both the ascend-ing and descending thoracic segments. Patients with isolated descending thoracic and abdominal aortic dissection are typi-cally treated medically, unless complications requiring surgery develop. Understanding the precise extent of dissection has become increasingly important as some aortic centers consider augmenting traditional ascending aortic repairs with endovascu-lar techniques to treat dissected distal aortic segments.158Chronicity Aortic dissection also is categorized according to the time elapsed since the initial tear. Dissection is considered acute within the first 14 days after the initial tear; after 14 days, the dissection is considered chronic. Although arbitrary, the dis-tinction between acute and chronic dissections has important implications, not only for decision making about perioperative management strategies and operative techniques, but also for evaluating surgical results. Figure 22-21 provides an algorithm for the management of acute aortic dissection. In light of the importance of acuity, Borst and associates154 have proposed a third phase—termed subacute—to describe the transition between the acute and chronic phases. The subacute period encompasses days 15 through 60 after the initial tear. Although this is past the traditional 14-day acute phase, patients with subacute dissection continue to have extremely fragile aortic Brunicardi_Ch22_p0853-p0896.indd 87801/03/19 5:42 PM 879THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22tissue, which may complicate operative treatment and increase the risks associated with surgery. Recently, the International Registry of Acute Aortic Dissections (IRAD) investigators pro-posed a new classification system for characterizing the phases of aortic dissection: The period within 24 hours from the onset of symptoms was defined as hyperacute, the period between 2 and 7 days was defined as acute, the period between 8 and 30 days was defined as subacute, and the period beyond 30 days was defined as chronic.159Variants As noted earlier, advancements in noninvasive imag-ing of the aorta have revealed variants of aortic dissection (see Fig. 22-18). The recently introduced term acute aortic syn-drome encompasses classic aortic dissection and its variants. Other aortic syndromes, which were once thought to be rare, include intramural hematoma (IMH) and penetrating aortic ulcer (PAU). Although the issue is somewhat controversial, the current consensus is that, in most cases, these variants of dissec-tion should be treated identically to classic dissection.An IMH is a collection of blood within the aortic wall, without an intimal tear, that is believed to be due to rupture of the vasa vasorum within the media. The accumulation of blood can result in a secondary intimal tear that ultimately leads to a dissection.160 Because IMH and aortic dissection represent a continuum, it is possible that IMH is seen less frequently than aortic dissection because IMH rapidly progresses to true dissec-tion. The prevalence of IMH among patients with acute aortic syndromes is approximately 6%, and 16% progress to full dis-section.161 An IMH can be classified according to its location (i.e., ascending or descending) and should be treated analo-gously to classic dissection.162A PAU is essentially a disrupted atherosclerotic plaque that projects into the aortic wall and is associated with surround-ing hematoma. Eventually, the ulcer can penetrate the aortic wall, which leads to dissection or rupture. The rate of disease progression is higher than that of IMH alone.163Causes and Clinical HistoryAortic dissection is a lethal condition with a reported incidence of 3.5 per 100,000 in the United States.164 Without appropriate mod-ern medical or surgical treatment, most patients (approximately 90%) die within 3 months of dissection, mostly from rupture.165,166Although several risk factors for aortic dissection have been identified, the specific causes remain unknown. Ultimately, any condition that weakens the aortic wall increases the risk of aortic dissection. Common general cardiovascular risk factors, such as smoking, hypertension, atherosclerosis, and hypercholesterolemia, are associated with aortic dissection. Patients with heritable forms of aortopathy, aortitis, bicuspid aortic valve, or preexisting medial degenerative disease are at risk for dissection, especially if they already have a thoracic aortic aneurysm.24 Aortic injury during cardiac catheterization, surgery, or endovascular aortic repair is a common cause of iatrogenic dissection. Other conditions that are associated with aortic dissection include cocaine and amphetamine abuse,167 as well as severe emotional stress or extreme physical exertion such as during weightlifting.168 Advances in the understanding of the molecular mechanisms behind abdominal aortic aneu-rysms have prompted similar investigations of thoracic aortic dissection.169-171Clinical ManifestationsThe onset of dissection often is associated with severe chest or back pain, classically described as “tearing,” that migrates Table 22-5Anatomic complications of aortic dissection and their associated symptoms and signsANATOMIC MANIFESTATIONSYMPTOMS AND SIGNSAortic valve insufficiencyDyspneaMurmurPulmonary ralesShockCoronary malperfusionChest pain with characteristics of anginaNausea/vomitingShockIschemic changes on electrocardiogramElevated cardiac enzymesPericardial tamponadeDyspneaJugular venous distensionPulsus paradoxusMuffled cardiac tonesShockLow-voltage electrocardiogramSubclavian or iliofemoral artery malperfusionCold, painful extremityExtremity sensory and motor deficitsPeripheral pulse deficitCarotid artery malperfusionSyncopeFocal neurologic deficit (transient or persistent)Carotid pulse deficitComaSpinal malperfusionParaplegiaIncontinenceMesenteric malperfusionNausea/vomitingAbdominal painRenal malperfusionOliguria or anuriaHematuriadistally as the dissection progresses along the length of the aorta. The location of the pain often indicates which aortic segments are involved. Pain in the anterior chest suggests involvement of the ascending aorta, whereas pain in the back and abdomen generally indicates involvement of the descending and thora-coabdominal aorta. Additional clinical sequelae of acute aortic dissection vary substantially and are best considered in terms of the dissection’s potential anatomic manifestations at each level of the aorta (see Fig. 22-19 and Table 22-5). Thus, potential complications of dissection of the aorta (and involved second-ary arteries) may include cardiac ischemia (coronary artery) or tamponade, stroke (brachiocephalic arteries), paraplegia or paraparesis (intercostal arteries), mesenteric ischemia (superior mesenteric artery), kidney failure (renal arteries), and limb isch-emia or loss of motor function (brachial or femoral arteries).Ascending aortic dissection can directly injure the aortic valve, causing regurgitation. The severity of the regurgitation varies with the degree of commissural disruption, which ranges from partial separation of only one commissure, producing mild Brunicardi_Ch22_p0853-p0896.indd 87901/03/19 5:42 PM 880SPECIFIC CONSIDERATIONSPART IIvalvular regurgitation, to full separation of all three commis-sures and complete prolapse of the valve into the left ventricle, producing severe acute heart failure. Patients with acute aortic valve regurgitation may report rapidly worsening dyspnea.Ascending dissections also can extend into the coronary arteries or shear the coronary ostia off of the true lumen, caus-ing acute coronary occlusion; when this occurs, it most often involves the right coronary artery. The sudden disruption of coronary blood flow can cause a myocardial infarction. This presentation of acute myocardial ischemia can mask the pres-ence of aortic dissection, which results in delayed diagnosis and treatment.172The thin and inflamed outer wall of a dissected ascend-ing aorta often produces a serosanguineous pericardial effusion that can accumulate and cause tamponade. Suggestive signs include jugular venous distention, muffled heart tones, pulsus paradoxus, and low-voltage electrocardiogram (ECG) tracings. Free rupture into the pericardial space produces rapid tampon-ade and is generally fatal.As the dissection progresses, any branch vessel from the aorta can become involved, which results in compromised blood flow and ischemic complications (i.e., malperfusion). Therefore, depending on which arteries are involved, the dissection can produce acute stroke, paraplegia, hepatic failure, bowel infarc-tion, renal failure, or a threatened ischemic limb.Diagnostic EvaluationBecause of the variations in severity and the wide variety of potential clinical manifestations, the diagnosis of acute aortic dissection can be challenging.173-175 Only 3 out of every 100,000 patients who present to an emergency department with acute chest, back, or abdominal pain are eventually diagnosed with aortic dissection. Not surprisingly, diagnostic delays are com-mon; delays beyond 24 hours after hospitalization occur in up to 39% of cases. Unfortunately, delays in diagnosis lead to delays in treatment, which can have disastrous consequences. The European Society of Cardiology Task Force on Aortic Dis-section stated, “The main challenge in managing acute aortic dissection is to suspect and thus diagnose the disease as early as possible.”173 A recent study by the IRAD investigators exam-ined the reasons for delayed diagnosis and found that diagnosis lagged in women, as well as in patients with atypical symptoms, such as fever or mild pain (rather than severe pain).172 A high index of suspicion is critical, particularly in younger, atypical patients, who may have heritable disorders or other, less com-mon risk factors.Most patients with acute aortic dissection (80% to 90%) experience severe pain in the chest, back, or abdomen.173-175 The pain usually occurs suddenly, has a sharp or tearing quality, and often migrates distally as the dissection progresses along the aorta. For classification purposes (acute vs. subacute vs. chronic), the onset of pain is generally considered to represent the beginning of the dissection process. Most of the other com-mon symptoms either are nonspecific or are caused by the sec-ondary manifestations of dissection.A discrepancy between the extremities in pulse, blood pressure, or both is the classic physical finding in patients with aortic dissection. It often occurs because of changes in flow in the true and false lumens, and it does not necessarily indi-cate extension into an extremity branch vessel. Involvement of the aortic arch often creates differences between the right and left arms, whereas descending aortic dissection often causes differences between the upper and lower extremities. Like symptoms, most of the physical signs after dissection are related to the secondary manifestations and therefore vary considerably (see Table 22-5). For example, signs of stroke or a threatened ischemic limb may dominate the physical findings in patients with carotid or iliac malperfusion, respectively.Unfortunately, laboratory studies are of little help in diag-nosing acute aortic dissection. There has been continued inter-est in using D-dimer level to aid in making this diagnosis.176 Several reports indicate that D-dimer is an extremely sensitive indicator of acute aortic dissection; elevated levels are found in approximately 97% of affected patients.177 Tests that are com-monly used to detect acute coronary events—including ECG and tests for serum markers of myocardial injury—deserve spe-cial consideration and need to be interpreted carefully. Normal ECGs and serum marker levels in patients with acute chest pain should raise suspicion about the possibility of aortic dissection. It is important to remember that ECG changes and elevated serum marker levels associated with myocardial infarction do not exclude the diagnosis of aortic dissection because dissection can cause coronary malperfusion. Of note, abnormal ECGs have recently been shown to delay the diagnosis of aortic dissection, and the possibility of aortic dissection should not be prema-turely ruled out.172,178 Similarly, although CXRs may show a widened mediastinum or abnormal aortic contour, up to 16% of patients with dissection have a normal-appearing CXR.174 The value of the CXR for detecting aortic dissection is limited, with a sensitivity of 67% and a specificity of 86%.179Once the diagnosis of dissection is considered, the tho-racic aorta should be imaged with CT, MRA, or echocardiogra-phy. The accuracy of these noninvasive imaging tests has all but eliminated the need for diagnostic aortography in most patients with suspected aortic dissection. Currently, the diagnosis of aor-tic dissection is usually established with contrast-enhanced CT, which has a sensitivity of 98% and a specificity of 87%, and, most importantly, acquires images swiftly.180 The classic diag-nostic feature is a double-lumen aorta (Fig. 22-22). In addition, CT scans provide essential information about the segments of the aorta involved; the acuity of the dissection; aortic dilata-tion, including the presence of preexisting degenerative aneu-rysms; and the development of threatening sequelae, including pericardial effusion, early aortic rupture, and branch-vessel compromise. Although MRA also provides excellent imaging (with both a sensitivity and specificity of 98%), the MR suite is not well suited for critically ill patients. In patients who cannot undergo contrast-enhanced CT or MRA, transthoracic echocar-diography can be used to establish the diagnosis.Transesophageal echocardiography (TEE) is excellent for detecting dissection, aneurysm, and IMH in the ascending aorta. In appropriate hands, TEE has a demonstrated sensitivity and specificity as high as 98% and 95%, respectively.181 Further-more, TEE offers important information about ventricular func-tion and aortic valve competency. Finally, TEE is the diagnostic modality of choice for hemodynamically unstable patients in whom the diagnosis of ascending dissection is suspected; ide-ally, these patients should be taken to the operating room, where the TEE can be performed and, if the TEE is confirmatory, sur-gery can be started immediately.In selected patients with ascending aortic dissection (i.e., those who have evidence of preexisting coronary artery dis-ease), coronary angiography can be considered before surgery. Specific relative indications in these patients include a history Brunicardi_Ch22_p0853-p0896.indd 88001/03/19 5:42 PM 881THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22of angina or myocardial infarction, a recent myocardial per-fusion study with abnormal results, previous coronary artery bypass or angioplasty, and acute ischemic changes on ECG. Contraindications include hemodynamic instability, aortic rupture, and pericardial effusion.182 In our practice, patients with acute aortic dissections rarely undergo coronary angiog-raphy. However, all patients presenting for elective repair of chronic ascending dissections have diagnostic coronary angio-grams taken.Of note, when malperfusion of the renal, visceral, or lower extremity arteries develops, the patient is usually treated in an angiography suite or hybrid operating room.158 Although the dissection usually is diagnosed on CT scan, these patients also undergo aortography, during which the mechanism of the malperfusion is ascertained and, if possible, corrected. Hence, catheter-based aortography may be obsolete as a diagnostic test for dissection, but it remains beneficial for patients with malperfusion.TreatmentInitial Assessment and Management. Regardless of the location of the dissection, the initial treatment is the same for all patients with suspected or confirmed acute aortic dissection (see Fig. 22-21). Furthermore, because of the potential for rup-ture before the diagnosis is confirmed, aggressive pharmaco-logic management is started once there is clinical suspicion of dissection, and this treatment is continued during the diagnostic evaluation. The goals of pharmacologic treatment are to stabi-lize the dissection and prevent rupture.Patients are monitored closely in an intensive care unit. Indwelling radial arterial catheters are used to monitor blood pressure and optimize titration of antihypertensive agents. Blood pressures in a malperfused limb can underrepresent the central aortic pressure; therefore, blood pressure is measured in the arm with the better pulse. Central venous catheters assure reliable IV access for delivering vasoactive medications. Pul-monary artery catheters are reserved for patients with severe cardiopulmonary dysfunction.In addition to confirming the diagnosis of dissection and defining its acuity and extent, the initial evaluation focuses on determining whether any of several life-threatening compli-cations are present. Particular attention is paid to changes in neurologic status, peripheral pulses, and urine output. Serial laboratory studies—including arterial blood gas concentrations, complete blood cell count, prothrombin and partial thrombo-plastin times, and serum levels of electrolytes, creatinine, blood urea nitrogen, and liver enzymes—are useful for detecting organ ischemia and optimizing management.The initial management strategy, commonly described as anti-impulse therapy or blood pressure control, focuses on reducing aortic wall stress, the force of left ventricular ejection, chronotropy, and the rate of change in blood pressure (dP/dT). Reductions in dP/dT are achieved by lowering both cardiac contractility and blood pressure. The drugs initially used to accomplish these goals include IV b-adrenergic blockers, direct vasodilators, calcium channel blockers, and angiotensinconverting enzyme inhibitors. These agents are used to achieve a heart rate between 60 and 80 bpm, a systolic blood pressure between 100 and 110 mmHg, and a mean arterial blood pres-sure between 60 and 75 mmHg. These hemodynamic targets are maintained as long as urine output remains adequate and neuro-logic function is not impaired. Achieving adequate pain control with IV opiates, such as morphine and fentanyl, is important for maintaining acceptable blood pressure control.b-Antagonists are administered to all patients with acute aortic dissections unless there are strong contraindications, such as severe heart failure, bradyarrhythmia, high-grade atrioven-tricular conduction block, or bronchospastic disease. Esmolol Figure 22-22. Computed tomographic scans showing that the aorta has been separated into two channels—the true (T) and false (F) lumens—in two patients with different phases of aortic dissection. A. An acute DeBakey type I aortic dissection. The dissecting membrane appears wavy (arrows) in the early phase of dissection. Here, the true lumen of the proximal aorta can be seen to be extensively compressed. This may lead to malperfusion of the heart. B. A chronic DeBakey type III aortic dissection. In the chronic phase, the membrane appears straighter and less mobile (arrow) because it has stabilized over time. (Used with permission of Baylor College of Medicine.)Brunicardi_Ch22_p0853-p0896.indd 88101/03/19 5:42 PM 882SPECIFIC CONSIDERATIONSPART IIcan be useful in patients with bronchospastic disease because it is a cardioselective, ultra-fast-acting agent with a short half-life. Labetalol, which causes both nonselective b-blockade and postsynaptic α1-blockade, reduces systemic vascular resistance without impairing cardiac output. Doses of b-antagonists are titrated to achieve a heart rate of 60 to 80 bpm. In patients who cannot receive b-antagonists, calcium channel blockers such as diltiazem are an effective alternative. Nitroprusside, a direct vasodilator, can be administered once b-blockade is adequate. When used alone, however, nitroprusside can cause reflex increases in heart rate and contractility, elevated dP/dT, and pro-gression of aortic dissection. Enalapril and other angiotensin-converting enzyme inhibitors are useful in patients with renal malperfusion. These drugs inhibit renin release, which may improve renal blood flow.Treatment of Ascending Aortic Dissection Acute Dissection Because of the risk of aortic rupture, acute ascending aortic dissection is usually considered an absolute indication for emergency surgical repair. However, specific patient groups may benefit from nonoperative manage-ment or delayed operation.183 Delayed repair may be con-sidered for patients who (a) present with severe acute stroke or mesenteric ischemia, (b) are elderly and have substantial comor-bidity, (c) are in stable condition and may benefit from transfer to specialized centers, or (d) have undergone a cardiac operation in the remote past. Regarding the last group, it is important that the previous operation not be too recent; dissections that occur during the first 3 weeks after cardiac surgery pose a high risk of rupture and tamponade, and such dissections warrant early operation.184In the absence of the aforementioned circumstances, most patients with acute ascending aortic dissection undergo emer-gent graft replacement of the ascending aorta. Operative repair is similar to that for aneurysm of the transverse aortic arch (pre-viously described) because hypothermic circulatory arrest is commonly used regardless of the extent of repair. Immediately before the operation begins, intraoperative TEE is commonly performed to further assess baseline myocardial and valvular function and, if necessary, to confirm the diagnosis. The opera-tion is performed via a median sternotomy with cardiopulmo-nary bypass and hypothermic circulatory arrest (Fig. 22-23). In preparation for circulatory arrest, cannulas are placed in the right axillary artery (to provide arterial inflow) and in the right atrium (to provide venous drainage).94 The innominate artery is some-times used for arterial inflow if it is not dissected.185 After an appropriate level of cooling has been achieved (approximately 24°C), cardiopulmonary bypass is stopped, and the ascending aorta is opened. The innominate artery is then occluded with a clamp or snare, and flow from the axillary artery cannula is used to provide ACP.186 Currently as a default, we use bilateral ACP with a separate perfusion catheter in the left common carotid artery to ensure perfusion of the left side of the brain. This strat-egy of performing the distal anastomosis during a brief period of circulatory arrest, often termed open distal anastomosis, obvi-ates the need to place a clamp across the fragile aorta, avoiding further aortic damage. Also, it allows the surgeon to carefully inspect the aortic arch for intimal tears. Traditionally, the entire arch is replaced only if a primary intimal tear is located in the arch or if the arch is aneurysmal; most commonly, repair is lim-ited to replacement of the entire ascending aorta or to a bev-eled “hemiarch” repair.187 Conservative repair has been shown 8to increase the likelihood of early survival.188 The distal aortic cuff is prepared by tacking the inner and outer walls together and occasionally using a small amount of surgical adhesive to obliterate the false lumen and strengthen the tissue. A polyester tube graft is sutured to the distal aortic cuff. The anastomosis between the graft and the aorta is fashioned so that blood flow will be directed into the true lumen; this often alleviates distal malperfusion problems that were present preoperatively. After the distal anastomosis has been completed and adequately rein-forced, the graft is deaired and clamped, full cardiopulmonary bypass is resumed, rewarming is initiated, and the proximal por-tion of the repair is started. In the absence of conditions that generally necessitate aortic root replacement (i.e., annuloaortic ectasia or heritable disorders, particularly Marfan and Loeys-Dietz syndromes), aortic valve regurgitation can be corrected by resuspending the commissures onto the outer aortic wall.189 The proximal aortic cuff is prepared with tacking sutures and occasionally a small amount of surgical adhesive before the proximal aortic anastomosis is performed.In the majority of patients who undergo surgical repair of acute ascending dissection, the dissection persists distal to the site of the operative repair; the residually dissected aorta, which generally includes at least a portion of the transverse aortic arch as well as a large portion of the distal aorta, is susceptible to dil-atation over time. Extensive dilatation of the arch or distal aorta develops in 25% to 40% of survivors190,191 and often necessitates further aortic repair. Additionally, long-term survival after acute proximal aortic dissection is generally poor, and rupture of the dilated distal aorta is a common cause of late death in these patients.188,190-192The challenges that survivors of acute proximal aortic dissec-tion commonly face over time have led to the development of alter-nate acute dissection strategies such as total arch replacement193 and hybrid arch strategies to extend proximal aortic repair into the distal aorta. The goal of hybrid arch approaches in acute dis-section is to thrombose the residual false lumen by compressing it with the radial force that is exerted by a stent graft placed in the true lumen, thereby facilitating remodeling and prevent-ing late aneurysm formation.194,195 However, in such repairs, the compressed false lumen may continue to be perfused in a ret-rograde fashion.In Europe, Japan, and elsewhere, one-piece hybrid pros-theses are now available that incorporate a polyester graft for the proximal repair and a stent graft component for the descending aorta. The device enables single-stage “frozen elephant trunk” repair of the ascending aorta, entire aortic arch, and proximal descending thoracic aorta.196 In the United States, such devices are not currently available, so this repair is commonly done by concomitantly deploying a commercially available stent graft in an antegrade fashion after fully replacing the ascending aorta and aortic arch. In some variations of this off-label approach, the stent graft is directly sutured to the distal aspect of the proximal open repair, whereas in others, there may be a gap of native tissue between the open and endovascular repair. Although this technique appears to be extensively used outside the United States, and with early and mid-term success,194,197-199 only a few U.S. reports describe its use.200-203 Emerging reports describe an enhanced risk of spinal cord ischemia, a risk that is not usually associated with open arch repair. This is prob-ably due to the extensive coverage of the intercostal vessels by the stent graft. Uncertainties in the frozen elephant trunk procedure need to be addressed before it becomes a standard Brunicardi_Ch22_p0853-p0896.indd 88201/03/19 5:42 PM 883THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22Figure 22-23. Illustration of proximal aortic repair for acute ascending aortic dissection. A. This repair requires a median sternotomy and cardiopulmonary bypass. The ascending aorta is opened during hypothermic circulatory arrest, while antegrade cerebral perfusion is delivered via an axillary artery graft (shown) or via an innominate artery graft, provided that the innominate artery is not dissected (see Fig. 22-10). B. The dissecting membrane is removed to expose the true lumen. C. An open distal anastomosis prevents clamp injury of the friable arch tis-sue and allows inspection of the arch lumen. A balloon perfusion catheter in the left common carotid artery ensures bilateral antegrade cerebral perfusion. If the origin of the dissection (i.e., intimal tear or disruption) does not extensively involve the greater curvature of the aortic arch, and if there is no evidence of a preexisting arch aneurysm, a beveled, hemiarch repair is carried out, preserving most of the greater curvature of the arch. The aorta is transected, beginning at the greater curvature immediately proximal to the origin of the innominate artery and extending distally toward the lesser curvature to the level of the left subclavian artery. Consequently, most of the transverse aortic arch, except for the dorsal segment containing the brachiocephalic arteries, is removed. An appropriately sized, sealed (with collagen or gelatin) polyester tube graft is selected, and the beveled distal anastomosis is made with continuous 3-0 or 4-0 monofilament suture; the potential space between the true and false lumen can be obliterated with a small amount of surgical adhesive or by using a strip of Teflon felt. To improve hemostasis, the distal anastomosis can be reinforced by placing interrupted mattress sutures with felt pledgets. D. After cardiopulmonary bypass is resumed and a cross-clamp is applied to the hemiarch replacement graft, the aortic valve is assessed. Disrupted commissures are resuspended with pledgeted mattress sutures to restore valvular competence. E. The aorta is generally transected at the sinotubular junction, and a very small amount of surgical adhesive can be applied between the true and false lumens, or more commonly, the false lumen within the proximal aortic stump is obliterated by inserting a semicircle of felt within the false lumen of the noncoronary sinus. The trimmed edges are brought together by using 6-0 polypropylene sutures. F. The proximal anastomosis is carried out at the sinotubular junction, incorporating the distal margin of the commissures. G. In patients with residual distal aortic dissection (such as in DeBakey type I aortic dissection), hemiarch repair can be extended with antegrade stent delivery to the descending thoracic aorta. (Used with permission of Baylor College of Medicine.)ACFGDEBBrunicardi_Ch22_p0853-p0896.indd 88301/03/19 5:42 PM 884SPECIFIC CONSIDERATIONSPART IIrecommendation for this subset of patients.204 Another alter-native employs separate grafts: a standard polyester graft to replace the ascending aorta and proximal hemiarch, and a stent graft delivered antegrade into the descending thoracic aorta (Fig. 22-23G). Although this procedure differs from a formal “frozen elephant trunk” repair in that it does not replace the entire arch, it is meant to achieve the same goal: promoting remodeling of the dissected descending aortic segment.Chronic Dissection Occasionally, patients with ascending aor-tic dissection present for repair in the chronic phase. In most respects, the operation is similar to that for acute dissection repair. One notable difference is that the tissue is stronger in chronic dissection than in acute dissection, which makes sutur-ing safer. In addition, the false lumen is not obliterated at the distal anastomosis; instead, the dissecting membrane is fenes-trated into the arch to assure perfusion of both lumens and to prevent postoperative malperfusion complications. Unlike operations for acute dissection, operations for chronic dissec-tion are often aggressive repairs that extend into the arch and root because the tissues are much less fragile.Treatment of Descending Aortic Dissection Nonoperative Management Nonoperative, pharmacologic management of acute descending aortic dissection results in lower morbidity and mortality rates than traditional open surgi-cal treatment does.174 The most common causes of death during nonoperative treatment are aortic rupture and end-organ malp-erfusion. Therefore, patients are continually reassessed for new complications. Serial CT scans are generally obtained during the index hospitalization—usually on day 2 or 3 and on day 8 or 9 of treatment—and compared with the initial scan to rule out significant aortic expansion.Once the patient’s condition has been stabilized, phar-macologic management is gradually shifted from IV to oral medications. Oral therapy, usually including a b-antagonist, is initiated when systolic pressure is consistently between 100 and 110 mmHg and the neurologic, renal, and cardiovascular systems are stable. Many patients can be discharged after their blood pressure is well controlled with oral agents and after serial CT scans confirm the absence of aortic expansion.Long-term pharmacologic therapy is important for patients with chronic aortic dissection. b-Blockers remain the drugs of choice.205 In a 20-year follow-up study, DeBakey and col-leagues206 found that inadequate blood pressure control was associated with late aneurysm formation. Aneurysms developed in only 17% of patients with “good” blood pressure control, compared with 45% of patients with “poor” control.Aggressive imaging follow-up is recommended for all patients with chronic aortic dissection.207 Both contrast-enhanced CT and MRA scans provide excellent aortic imag-ing and facilitate serial comparisons to detect progressive aortic expansion. The first surveillance scan is obtained approximately 6 weeks after the onset of dissection. Subsequent scans are obtained at 3 to 6 months and then at 1 year after onset. If the aorta appears to be stable, imaging is obtained annually there-after. Scans are obtained more frequently in high-risk patients, such as those with Marfan or Loeys-Dietz syndrome, and in those in whom significant aortic expansion is detected. For patients who have undergone graft repair of descending aor-tic dissection, annual CT or MRA scans are also obtained to detect false aneurysm formation or dilatation of unrepaired seg-ments of aorta. Early detection of worrisome changes allows timely, elective intervention before rupture or other complica-tions develop; rupture of the distal aorta is relatively common in patients with chronic aortic dissection and often results in death.192Indications for Open Surgery In the acute phase of descend-ing aortic dissection, open surgery has been traditionally reserved for patients who experience complications.208 Compli-cated acute distal aortic dissections are those with aortic rupture, increasing periaortic or pleural fluid volume, rapidly expanding aortic diameter, uncontrolled hypertension, and persistent pain despite adequate medical therapy and malperfusion. In general terms, emergency open operations were originally intended to prevent or repair rupture and relieve life-threatening ischemic manifestations. However, open operation is associated with high morbidity in such cases; now that stent graft technology is available, endovascular surgical intervention is recommended for patients with complicated acute distal aortic dissection.Acute dissection superimposed on a preexisting aneu-rysm is considered a life-threatening condition and is therefore another indication for operation. Finally, patients who have a history of noncompliance with medical therapy may ultimately benefit more from surgical intervention if they are otherwise reasonable operative candidates.In the chronic phase, the indications for open surgical inter-vention for aortic dissection are similar to those for degenerative thoracic aortic aneurysm, although a slightly lower threshold of repair is now recommended. Guidelines for thoracic aortic disease44 recommend elective operation in otherwise healthy patients when the affected segment has reached a diameter of 5.5 cm, especially in patients with heritable disorders. Rapid aortic enlargement and other factors that increase the likelihood of aortic rupture may also be considered.Endovascular Treatment Malperfusion Syndrome Endovascular therapy is routinely used in patients with descending aortic dissection complicated by visceral malperfusion.209 Abdominal malperfusion syn-drome often is fatal; prompt identification of visceral ischemia and expedited treatment to restore hepatic, gastrointestinal, and renal perfusion are imperative for a positive outcome. As described in a later section, several open surgical techniques can be used to reestablish blood flow to compromised organs. However, in acute cases, open surgery is associated with poor outcomes. Therefore, endovascular intervention is the pre-ferred initial approach in such cases. In one endovascular tech-nique known as endovascular fenestration, a balloon is used to create a tear in the dissection flap, which allows blood to flow in both the true and false lumens. Although endovascular fen-estration was commonly used in the past, its use has declined in recent years as direct aortic and branch-vessel stenting tech-niques have evolved and gained favor. Placing a stent graft in the true lumen of the aorta can resolve a “dynamic” malperfu-sion. Occasionally, a small stent must be placed directly in the lumen of a visceral or renal artery because the dissection has propagated into the branch, resulting in “static” malperfusion at the origin.209Iliofemoral malperfusion causing limb-threatening leg ischemia also can be treated via an endovascular approach. Limb malperfusion usually resolves after the endovascular repair of acute descending thoracic aortic dissection. If the malperfusion does not resolve, then a femoral-to-femoral arterial bypass graft is an effective option.Brunicardi_Ch22_p0853-p0896.indd 88401/03/19 5:42 PM 885THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22Acute Dissection  Although surgery has been traditionally recommended for patients with complicated acute descending aortic dissection, many centers have shifted toward using endo-vascular stent grafts as the preferred approach in these cases because of the high morbidity associated with the open opera-tion. Evidence suggests that emergent endovascular repair in patients with true lumen collapse and complications such rupture or dynamic malperfusion may be lifesaving in these difficult-to-treat patients. However, these patients remain at risk of further complication or future reintervention. Although endovascular repair in patients with heritable aortic disorders is generally not recommended, this technique can be used as a bridge to later, definitive repair in such life-threatening circumstances.66Controversy exists regarding the use of endovascular stent grafts to treat uncomplicated acute descending dissection; some encouraging data have been published in the last couple of years.210 The goal of this treatment strategy is to use the stent graft to cover the intimal tear, seal the entry site of the dis-section, and eventually cause thrombosis of the false lumen to aid in aortic remodeling and reduce late aortic expansion. Such procedures take place in a hybrid operating room. After the true lumen is accessed through the femoral arteries, an aor-togram is taken, and the intimal tear is identified. Note that the diameter of the true lumen is measured on the preoperative contrast-enhanced CT scan. The use of IVUS is encouraged to help access the true lumen, verify navigation of the wire inside the true lumen, and confirm measurements. For these cases, a stent graft is selected with a diameter no more than 10% greater than that of the true lumen. Unlike stents deployed to treat most descending thoracic aortic aneurysms, stents deployed to treat descending thoracic aortic dissections must not be ballooned, because ballooning can cause a new intimal tear, retrograde dissection into the ascending aorta, or even aortic rupture. The ideal length of the descending thoracic aorta that should be cov-ered in patients with acute distal descending dissection remains unclear. Close monitoring with serial imaging is necessary after endovascular repair because the false lumen remains at risk for retrograde perfusion or pressurization.Chronic Dissection Endovascular treatment of chronic descend-ing aortic dissection is supported by the 5-year data of the INSTEAD-XL trial, which showed that endovascular repair com-bined with optimal medical treatment was associated with slower disease progression and greater aorta-specific survival than opti-mal medical treatment alone.211 Importantly, patients in the trial had dissections in the early chronic phase, many within 10 to 12 weeks of onset and all within 1 year of onset. Endovascular repair of chronic dissection is particularly challenging because the rela-tive rigidity of the dissecting membrane—which increases over time during the chronic phase—and the presence of multiple reen-try sites make it difficult to exclude the false lumen.Penetrating Aortic Ulcer Patients with PAUs appear to be good candidates for endovascular intervention. Covering the focal ulceration with a stent graft has been shown to be an effec-tive treatment.212 In a recent study by Patel and colleagues,213 endovascular repair of PAU was associated with better early outcomes than open repair. However, when PAU was associ-ated with adjacent hematoma within the aortic wall, rates of subsequent reintervention were increased.Open Repair Acute Dissection In patients with acute aortic dissection, open surgical repair of the descending thoracic or thoracoabdominal aorta has been traditionally associated with high morbidity and mortality.174 Therefore, surgery was generally only performed to prevent fatal rupture or to restore branch-vessel perfusion in patients with complicated dissection.208 With the evolution of endovascular technology, open repair has fallen out of favor in recent years.Malperfusion Syndrome In patients with malperfusion, when an endovascular approach is unavailable or unsuccessful, open surgery is necessary. Lower-extremity ischemia can be readily addressed with surgical extra-anatomic revascularization techniques, such as femoral-to-femoral bypass grafting. In patients with abdominal organ ischemia, flow to the compromised bed must be reestab-lished swiftly. Although they are considered second-line therapies, multiple techniques are available, including graft replacement of the aorta (with flow redirected into the true lumen), open aortic fenestration, and visceral or renal artery bypass.Chronic Dissection A more aggressive replacement usually is performed during elective aortic repairs in patients with chronic dissection. In many regards, the operative approach used in these patients is identical to that used for descending thoracic and tho-racoabdominal aortic aneurysms, as described in the first half of this chapter (Fig. 22-24). One key difference is the need to excise as much dissecting membrane as possible to clearly identify the true and false lumens and to locate all important branch vessels. When the dissection extends into the visceral or renal arteries, the membrane can be fenestrated, or the false lumen can be obliter-ated with sutures or intraluminal stents. Asymmetric expansion of the false lumen can create wide separation of the renal arteries. This problem is addressed by reattaching the mobilized left renal artery to a separate opening in the graft or by performing a left renal artery bypass with a side graft. Wedges of dissecting mem-brane also are excised from the aorta adjacent to the proximal and distal anastomoses, which allows blood to flow through both true and false lumens. When placing the proximal clamp is not technically feasible, hypothermic circulatory arrest can be used to facilitate the proximal portion of the repair.OUTCOMESImprovements in anesthesia, surgical techniques, and periopera-tive care have led to substantial improvements in outcome after thoracic aortic aneurysm repair. When performed in specialized centers, these operations are associated with excellent survival rates and acceptable morbidity rates. The interpretation of out-comes data is complicated by site-specific variables, such as the number of years reported and whether data are taken from single-practice centers or from pooled, multicenter, or national registries, and by patient-specific variables, such as type of enrollment, urgency and extent of repair, concomitant proce-dures performed, and the presence of preexisting risk factors such as advanced age, previous cardiovascular repair, disease of any system or organ, or heritable conditions.Repair of Proximal Aortic AneurysmsRisks associated with the open repair of the proximal aorta vary by extent of repair and are greatest for repairs involving total arch replacement.71,214 All varieties of aortic root replacement have shown acceptable early mortality rates and few complica-tions. Two groups with 20 and 27 years’ experience with com-posite valve graft replacement reported early mortality rates of 5.6% and 1.9%, respectively; the more recent repairs had better outcomes.215,216 Early mortality rates for stentless porcine Brunicardi_Ch22_p0853-p0896.indd 88501/03/19 5:42 PM 886SPECIFIC CONSIDERATIONSPART IIFigure 22-24. Illustration of distal aortic repair of a chronic dissection. A. Thoracoabdominal incision. B. Extent II thoracoabdominal aortic aneurysm resulting from chronic aortic dissection. The patient has previously undergone composite valve graft replacement of the aortic root and ascending aorta. After left heart bypass is initiated, the proximal portion of the aneurysm is isolated by placing clamps on the left sub-clavian artery, between the left common carotid and left subclavian arteries, and across the middle descending thoracic aorta. C. The isolated segment of aorta is opened by using electrocautery. D. The dissecting membrane is excised, and bleeding intercostal arteries are oversewn. The aorta is prepared for proximal anastomosis by transecting it distal to the proximal clamp and separating this portion from the esophagus (not shown). E. The proximal anastomosis between the aorta and an appropriately sized polyester graft is completed with continuous polypro-pylene suture. F. After left heart bypass has been stopped and the distal aortic cannula has been removed, the proximal clamp is repositioned onto the graft, the other two clamps are removed, and the remainder of the aneurysm is opened. G. The rest of the dissecting membrane is excised, and the openings to the celiac, superior mesenteric, and renal arteries are identified. H. Selective visceral perfusion with oxygenated blood from the bypass circuit is delivered through balloon perfusion catheters placed in the celiac and superior mesenteric arterial ostia. Cold crystalloid is delivered to the renal arteries. The critical intercostal arteries are reattached to an opening cut in the graft. I. To minimize spinal cord ischemia, the proximal clamp is repositioned distal to the intercostal reattachment site. A second oval opening is fashioned in the graft adjacent to the visceral vessels. Selective perfusion of the visceral arteries continues during their reattachment to the graft. A separate anas-tomosis is often required to reattach the left renal artery. J. After the balloon perfusion catheters are removed and the visceral anastomosis is completed, the clamp is again moved distally, restoring blood flow to the celiac, renal, and superior mesenteric arteries. The final anastomosis is created between the graft and the distal aorta. (Reproduced with permission from Creager MA, Dzau VS, Loscalzo J: Vascular Medicine, 7th ed. Philadelphia, PA: Elsevier/Saunders; 2006.)Left heartbypasscircuitCold renalperfusionsystemFalselumenABCDEtissue root replacements are also low, ranging from 3.6% to 6.0%.217-221 Early mortality rates for contemporary valve-sparing approaches to aortic root replacement are quite low (1%–2%) in experienced centers.77,78,80,222,223 Late survival rates after valve-sparing root procedures range from 97% to 99% at 5 years80,222,223 and approach 94% at 10 years.80Repairs incorporating the ascending aorta and aortic arch have acceptable outcomes; risk increases with patient-specific factors such as severe atherosclerosis224 or as larger sections of the aortic arch are incorporated into the repair.225,226 A revised surgical strategy—such as the use of hypothermic circulatory arrest—is often needed to avoid clamping atherosclerotic sections in the “porcelain” aorta. In Zingone and colleagues’ series224 of 64 patients who underwent replacement of atherosclerotic ascend-ing aorta, hypothermic circulatory arrest was used in 61 patients (95%). Even though these patients had substantial comorbidity and 83% underwent concomitant cardiac repairs, acceptable rates of early mortality (11%) and stroke (6%) were obtained. Other Brunicardi_Ch22_p0853-p0896.indd 88601/03/19 5:42 PM 887THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22Figure 22-24. (Continued)studies indicate that the enhanced risk of neurocognitive distur-bances in ascending repairs using circulatory arrest are not offset by lower rates of early mortality.227,228 Regarding extended proxi-mal repair, reported early mortality rates after traditional stage 1 elephant trunk repairs (primarily using island reattachment strate-gies) range from 2.3 to 13.9%.229-233Contemporary mortality rates for extensive proximal aortic repair have improved as new strategies and modified adjuncts have been adopted. For example, by adopting contem-porary approaches, we have reduced early mortality for stage 1 elephant trunk repairs from 12% to 2% in our patients.86,230 Similarly, in a report by Kazui and colleagues234 covering 20 years of experience and 472 consecutive patients who under-went aortic arch repair with selective ACP, operative mortality was 16.0% for early repairs and 4.1% for more recent repairs. Other contemporary reports of the use of techniques such as moderate hypothermia and Y-graft approaches235-238 indicate similarly improved outcomes; early mortality ranges from 1% to 7%, stroke rates range from 1% to 6%, and no cases of para-plegia are reported. Although paraplegia has traditionally been an unusual and infrequent complication of aortic arch repair, it has been reported as a complication of “long” elephant trunk approaches239 and frozen elephant trunk approaches.240Because of the heterogeneity of hybrid arch approaches and the tendency to use these approaches in high-risk patients, results of hybrid arch repair are difficult to interpret. In a recent report from our group,65 among 319 consecutive patients who underwent total arch replacement in the last 8.5 years, 274 patients had traditional open repair and 45 patients had hybrid zone 0 exclusion repairs. The rate of permanent adverse outcome (death, persistent neurologic deficit at dis-charge, or persistent hemodialysis at discharge) was not sig-nificantly different between the two groups. A higher overall stroke rate was noticed in the hybrid group, reinforcing the importance of catheter skills and careful wire manipulation. A meta-analysis conducted by Koullias and Wheatley241 of data from 15 studies with 463 patients found an average 30-day mortality rate of 8.3%; stroke, 4.4%; paraplegia, 3.9%; and endoleak, 9.2%. Of note, relatively few repairs (30%) were performed “off-pump,” and the majority of repairs used cardiopulmonary bypass or hypothermic circulatory arrest. Additionally, several reports of small series have documented increased risk of acute retrograde aortic dissection during hybrid arch repairs; rates range from 0% to 7.5%, and these patients face significant mortality risk (ranging from 33% to 100%) should this occur.108,109,242-244Brunicardi_Ch22_p0853-p0896.indd 88701/03/19 5:42 PM 888SPECIFIC CONSIDERATIONSPART IITreatment of Acute Ascending Aortic DissectionThe International Registry of Acute Aortic Dissection (IRAD) provides the most comprehensive data on contemporary out-comes in patients with acute aortic dissection. This registry was established in 1996 and has accumulated data from >7000 patients treated for acute aortic dissection at 51 centers in 12 countries. An IRAD analysis of data from 776 patients who underwent surgical repair of acute ascending aortic dissection revealed an in-hospital mortality rate of 23.8%.245 The investiga-tors identified several preoperative predictors of early mortality, including age >70 years, previous cardiac surgery, hypotension or shock at presentation, abrupt onset of symptoms, migrat-ing pain, cardiac tamponade, preoperative renal failure, pulse deficit, and evidence of myocardial ischemia or infarction on ECG.245,246 In a report from IRAD, in-hospital mortality after surgical treatment had decreased from 25% in 1995 to 18% in 2013.247 The German Registry for Acute Aortic Dissection (GERAADA) has collected data on more than 3300 patients from 56 centers since 2006. 248 In a report of 1436 patients with acute proximal dissection that was surgically repaired using hypothermic circulatory arrest with or without unilateral and bilateral ACP, the early mortality rates ranged from 13.9% to 19.4%; the 628 patients with unilateral ACP had the lowest rate of early death.249 Operative mortality reported by North American centers varies from 5% to 17%; improvements in out-comes may be related to the implementation of protocol-based management and the assembly of thoracic aortic teams.203Repair of Distal Aortic AneurysmsEndovascular Repair of Descending Thoracic Aortic Aneurysms. In the earliest series of endovascular repairs of descending thoracic aortic aneurysms, mortality and morbidity were difficult to assess. Most of the reported series were small and included a large proportion of high-risk patients with sub-stantial comorbidity.250,251 Subsequent evidence from pivotal, nonrandomized trials that compared patients who underwent endograft exclusion with historical or concurrent patients who underwent open repair252-254 showed that the stent graft groups had significantly less morbidity and early mortality than the open repair groups, although in two of the trials, a nonsig-nificant between-group difference was observed in the rate of stroke.252,254 Five-year comparative data show that the two groups differed significantly in their aneurysm-related mortality rates (2.8% for endovascular patients and 11.7% for open repair patients) but not in their rates of all-cause mortality (which were 32% and 31%, respectively).255 Additional pivotal trial 5-year outcomes256 indicate the growing disparity between aneurysm-related (96.1%) and all-cause survival (58.5%) in patients with endovascular repair, leading some to comment on the possible futility of repair in many patients.257 Among 8967 patients iden-tified in the National Inpatient Sample database (8255 with open repair and 712 with endovascular repair), the odds of death were 46% lower among patients who underwent endovascular repair rather than open repair.56 The endovascular repair group also had lower odds of postoperative neurologic, cardiac, and respi-ratory complications.Open Repair of Descending Thoracic and Thoracoabdominal Aortic Aneurysms. Contemporary results of open repairs of descending thoracic aortic aneurysms, including those performed in select patients with chronic dissection, indicate that early mor-tality rates range from 4.1% to 8.0%, renal failure rates range from to 4.2% to 7.5%, and paraplegia rates range from 2.3% to 5.7%; stroke rates are generally lower, ranging from 1.8% to 2.1%.258-260 In our series, although the risk of paraplegia increased with the extent of repair, the risk of mortality was greatest for those under-going repair of the proximal two thirds of the descending aorta.258 As expected, stroke rates after distal aortic repairs were highest when the clamp site was near the left subclavian artery.Contemporary series of open thoracoabdominal aortic repairs show acceptable survival. Reported outcome rates range from 5% to 12% for early mortality, 3.8% to 9.5% for paraple-gia, 1.7% to 5.2% for stroke, and 6% to 12% for renal compli-cations.261-265 Many of these series summarize 10 to 20 years of surgical experience,262-265 although some present a shorter but more contemporary experience.261 Even for complex tho-racoabdominal aortic repairs, such as stage 2 elephant trunk repairs, several centers report acceptable early mortality rates ranging from 0% to 10%.229-233 Worse outcomes are also docu-mented, as in a statewide, nonfederal analysis of data from 1010 patients whose early mortality rate was 25%. Of note, 40% of these patients were treated at centers averaging only one tho-racoabdominal aortic aneurysm repair per year.266 Cowan and colleagues,267 who examined the influence of familiarity with the procedure on rates of mortality and morbidity after tho-racoabdominal aortic aneurysm repair, reported that patients treated at low-volume centers fared less well. Replacing the entire thoracoabdominal aorta (i.e., performing an extent II repair) carries the highest risk of death, bleeding, renal failure, and paraplegia.118,262,263 Early survival has been estimated at 79% at 2 years,268 and mid-term survival has been estimated at 63% at 5 years.265 In our recent report of 3309 repairs,269 the overall mortality rate was 7.5%, and the rate of operative death was higher in extent II and III repairs than in extent I and IV. Perma-nent paraplegia and paraparesis occurred in 2.9% and 2.4% of patients, respectively, and the incidence of paraplegia in patients 50 years of age or younger was only 1.1%. Estimated survival after repair was 84% ± 1% at 1 year, 64% ± 1% at 5 years, 37% ± 1% at 10 years, and 18% ± 1% at 15 years.Treatment of Descending Thoracic Aortic DissectionNonoperative Management. The in-hospital mortality rate is 8.7% for patients with acute descending aortic dissection who receive nonoperative treatment247; however, when IRAD stratified patients according to clinical presentation, the mor-tality rate for patients with uncomplicated dissection was less than 4%, whereas the mortality rate for patients with compli-cated dissection was more than 20%.174,270 The primary causes of death during nonoperative management are rupture, malper-fusion, and cardiac failure. Risk factors associated with treat-ment failure—defined as death or need for surgery—include an enlarged aorta, persistent hypertension despite maximal treatment, oliguria, and peripheral ischemia. Among patients who receive nonoperative treatment for descending aortic dis-section and who survive the acute period, approximately 90% remain alive 1 year later, and approximately 76% are alive 3 years later.271Endovascular Treatment. For patients with complicated acute descending thoracic aortic dissection, including rupture and malperfusion of the visceral or renal arteries, an endovas-cular approach is ideal. The Stanford group reported a 93% technical success rate for endovascular reperfusion of an isch-emic bed.272 Their experience with the use of first-generation stent grafts to treat acute complicated descending dissections Brunicardi_Ch22_p0853-p0896.indd 88801/03/19 5:42 PM 889THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22was also encouraging: Complete thrombosis of the false lumen occurred in 79% of patients. The early mortality rate was 16%, comparable to that associated with open techniques.273 A meta-analysis of observational studies of endovascular repair, which included 248 patients with acute descending thoracic aortic dissection, found a 30-day mortality rate of 9.8%.274 When compared with early mortality rates obtained from IRAD data,174 this rate is substantially lower than the rate associated with open surgical treatment and is similar to the rate achieved with nonoperative management. However, patients with com-plicated acute descending dissection remain susceptible to late events; at 1 year, survival is approximately 70%, and reinterven-tion is needed in about 10% of survivors.275The ADSORB trial276 focused on patients with uncom-plicated acute descending thoracic aortic dissection. Patients were randomly assigned to optimal medical therapy alone (n = 31) or endovascular repair plus optimal medical therapy (n = 30).277 The 1-year results showed aortic remodeling with false lumen thrombosis and reduced diameter in the group treated with endovascular repair.The INSTEAD-XL trial involved 140 patients with stable, early-chronic descending thoracic aortic dissection who were randomly assigned to either endovascular repair plus opti-mal medical treatment or optimal medical therapy alone.211 The eagerly anticipated 5-year data showed that endovascular repair was associated with greater survival and slower disease progression.CONCLUSIONSAortic aneurysm may present as localized or extensive dis-ease. The availability and development of adjuncts and endo-vascular techniques have supported the constant evolution of surgical strategies to tackle these complex problems. Repair strategies range from isolated, totally endovascular aortic repair for descending thoracic aneurysms to extensive total aortic and staged replacements with a combination of both open and endovascular techniques. Regardless of the difficulty of accu-rately assessing the risks associated with aortic repair, surgical repair of the thoracoabdominal aorta clearly remains the most challenging aortic repair in terms of mortality and morbidity. Accordingly, replacing the entire thoracoabdominal aorta (i.e., performing an extent II repair) carries the highest risk of death, renal failure, and paraplegia.69,70,261,263,269ACKNOWLEDGMENTSThe authors wish to thank Susan Y. Green, MPH, and Stephen N. Palmer, PhD, ELS, for editorial assistance; Scott A. Weldon, MA, CMI, and Carol P. Larson, CMI, for creating the illus-trations; and Kapil Sharma, MD, and Raja Gopaldas, MD, for their substantial contributions to the chapters published in the 9th and 10th editions of this book, on which this updated chapter is based.REFERENCESEntries highlighted in bright blue are key references. 1. Johnston KW, Rutherford RB, Tilson MD, et al. Suggested standards for reporting on arterial aneurysms. Subcommit-tee on Reporting Standards for Arterial Aneurysms, Ad Hoc Committee on Reporting Standards, Society for Vascular Surgery and North American Chapter, International Society for Cardiovascular Surgery. J Vasc Surg. 1991;13(3):452-458. 2. Bickerstaff LK, Pairolero PC, Hollier LH, et al. Thoracic aortic aneurysms: a population-based study. Surgery. 1982;92(6):1103-1108. 3. Shen YH, LeMaire SA. Molecular pathogenesis of genetic and sporadic aortic aneurysms and dissections. Curr Probl Surg. 2017;54(3):95-155. A contemporary, comprehensive review of the pathobiology underlying aortic disease. 4. Eagle KA, GenTAC Consortium. Rationale and design of the National Registry of Genetically Triggered Thoracic Aor-tic Aneurysms and Cardiovascular Conditions (GenTAC). Am Heart J. 2009;157(2):319-326. 5. Segura AM, Luna RE, Horiba K, et al. Immunohistochemistry of matrix metalloproteinases and their inhibitors in thoracic aortic aneurysms and aortic valves of patients with Marfan’s syndrome. Circulation. 1998;98(19 suppl):II331-II337. 6. Neptune ER, Frischmeyer PA, Arking DE, et al. Dysregula-tion of TGF-β activation contributes to pathogenesis in Marfan syndrome. Nat Genet. 2003;33(3):407-411. 7. Marsalese DL, Moodie DS, Vacante M, et al. Marfan’s syndrome: natural history and long-term follow-up of cardio-vascular involvement. J Am Coll Cardiol. 1989;14(2):422-428. 8. Adams JN, Trent RJ. Aortic complications of Marfan’s syn-drome. Lancet. 1998;352(9142):1722-1723. 9. LeMaire SA, Pannu H, Tran-Fadulu V, et al. Severe aortic and arterial aneurysms associated with a TGFBR2 mutation. Nat Clin Pract Cardiovasc Med. 2007;4(3):167-171. 10. Loeys BL, Schwarze U, Holm T, et al. Aneurysm syndromes caused by mutations in the TGF-β receptor. N Engl J Med. 2006;355(8):788-798. 11. Oderich GS, Panneton JM, Bower TC, et al. The spectrum, management and clinical outcome of Ehlers-Danlos syndrome type IV: a 30-year experience. J Vasc Surg. 2005;42(1):98-106. 12. Sheen VL, Jansen A, Chen MH, et al. Filamin A mutations cause periventricular heterotopia with Ehlers-Danlos syn-drome. Neurology. 2005;64(2):254-262. 13. Boileau C, Guo DC, Hanna N, et al. TGFB2 mutations cause familial thoracic aortic aneurysms and dissections associated with mild systemic features of Marfan syndrome. Nat Genet. 2012;44(8):916-921. 14. Guo DC, Pannu H, Tran-Fadulu V, et al. Mutations in smooth muscle alpha-actin (ACTA2) lead to thoracic aortic aneurysms and dissections. Nat Genet. 2007;39(12):1488-1493. 15. Pannu H, Tran-Fadulu V, Papke CL, et al. MYH11 muta-tions result in a distinct vascular pathology driven by insu-lin-like growth factor 1 and angiotensin II. Hum Mol Genet. 2007;16(20):2453-2462. 16. Brownstein AJ, Ziganshin BA, Kuivaniemi H, et al. Genes asso-ciated with thoracic aortic aneurysm and dissection: an update and clinical implications. Aorta (Stamford). 2017;5(1):11-20. 17. van de Laar IM, Oldenburg RA, Pals G, et al. Mutations in SMAD3 cause a syndromic form of aortic aneurysms and dissections with early-onset osteoarthritis. Nat Genet. 2011;43(2):121-126. 18. Hoffman JI, Kaplan S. The incidence of congenital heart dis-ease. J Am Coll Cardiol. 2002;39(12):1890-1900. 19. Keane MG, Wiegers SE, Plappert T, et al. Bicuspid aortic valves are associated with aortic dilatation out of proportion to coexistent valvular lesions. Circulation. 2000;102(19 suppl 3):III35-III39. 20. Jassal DS, Bhagirath KM, Tam JW, et al. Association of bicus-pid aortic valve morphology and aortic root dimensions: a sub-study of the aortic stenosis progression observation measuring effects of rosuvastatin (ASTRONOMER) study. Echocardiog-raphy. 2010;27(2):174-179. 21. Cecconi M, Manfrin M, Moraca A, et al. Aortic dimensions in patients with bicuspid aortic valve without significant valve dysfunction. Am J Cardiol. 2005;95(2):292-294. 22. Nistri S, Sorbo MD, Marin M, et al. Aortic root dilatation in young men with normally functioning bicuspid aortic valves. Heart. 1999;82(1):19-22.Brunicardi_Ch22_p0853-p0896.indd 88901/03/19 5:42 PM 890SPECIFIC CONSIDERATIONSPART II 23. Sabet HY, Edwards WD, Tazelaar HD, Daly RC. Congenitally bicuspid aortic valves: a surgical pathology study of 542 cases (1991 through 1996) and a literature review of 2,715 addi-tional cases. Mayo Clin Proc. 1999;74(1):14-26. 24. Larson EW, Edwards WD. Risk factors for aortic dissection: a necropsy study of 161 cases. Am J Cardiol. 1984;53(6):849-855. 25. LeMaire SA, Wang X, Wilks JA, et al. Matrix metalloprotein-ases in ascending aortic aneurysms: bicuspid versus trileaflet aortic valves. J Surg Res. 2005;123(1):40-48. 26. Fedak PW, de Sa MP, Verma S, et al. Vascular matrix remod-eling in patients with bicuspid aortic valve malformations: implications for aortic dilatation. J Thorac Cardiovasc Surg. 2003;126(3):797-806. 27. Koullias GJ, Korkolis DP, Ravichandran P, et al. Tissue microarray detection of matrix metalloproteinases, in dis-eased tricuspid and bicuspid aortic valves with or without pathology of the ascending aorta. Eur J Cardiothorac Surg. 2004;26(6):1098-1103. 28. Martin LJ, Ramachandran V, Cripe LH, et al. Evidence in favor of linkage to human chromosomal regions 18q, 5q and 13q for bicuspid aortic valve and associated cardiovascular malformations. Hum Genet. 2007;121(2):275-284. 29. McKellar SH, Tester DJ, Yagubyan M, et al. Novel NOTCH1 mutations in patients with bicuspid aortic valve disease and thoracic aortic aneurysms. J Thorac Cardiovasc Surg. 2007;134(2):290-296. 30. Wessels MW, Berger RM, Frohn-Mulder IM, et al. Autosomal dominant inheritance of left ventricular outflow tract obstruc-tion. Am J Med Genet. 2005;134A(2):171-179. 31. Yasuda H, Nakatani S, Stugaard M, et al. Failure to prevent pro-gressive dilation of ascending aorta by aortic valve replacement in patients with bicuspid aortic valve: comparison with tricuspid aortic valve. Circulation. 2003;108(suppl 1):II291-II294. 32. Hornick M, Moomiaie R, Mojibian H, et al. ‘Bovine’ aor-tic arch – a marker for thoracic aortic disease. Cardiology. 2012;123(2):116-124. 33. Brown SL, Busuttil RW, Baker JD, et al. Bacteriologic and surgical determinants of survival in patients with mycotic aneurysms. J Vasc Surg. 1984;1(4):541-547. 34. Johnson JR, Ledgerwood AM, Lucas CE. Mycotic aneurysm: new concepts in therapy. Arch Surg. 1983;118(5):577-582. 35. Schwill S, LeMaire SA, Green SY, Bakaeen FG, Coselli JS. Endovascular repair of thoracic aortic pseudoaneurysms and patch aneurysms. J Vasc Surg. 2010;52(4):1034-1037. 36. Elefteriades JA. Natural history of thoracic aortic aneu-rysms: indications for surgery, and surgical versus non-surgical risks. Ann Thorac Surg. 2002;74(5):S1877-S1880. This classic longitudinal study identified “hinge points” for complications of ascending and descending thoracic aortic aneurysm, forming the basis for key diameter thresholds for elective repair. 37. Davies RR, Goldstein LJ, Coady MA, et al. Yearly rupture or dissection rates for thoracic aortic aneurysms: simple predic-tion based on size. Ann Thorac Surg. 2002;73(1):17-27. 38. Murdoch JL, Walker BA, Halpern BL, Kuzma JW, McKusick VA. Life expectancy and causes of death in the Marfan syn-drome. N Engl J Med. 1972;286(15):804-808. 39. Michel PL, Acar J, Chomette G, Iung B. Degenerative aortic regurgitation. Eur Heart J. 1991;12(8):875-882. 40. Prenger K, Pieters F, Cheriex E. Aortic dissection after aortic valve replacement: incidence and consequences for strategy. J Card Surg. 1994;9(5):495-498. 41. Bonow RO. Bicuspid aortic valves and dilated aortas: a criti-cal review of the ACC/AHA practice guidelines recommenda-tions. Am J Cardiol. 2008;102(1):111-114. 42. Girdauskas E, Disha K, Raisin HH, et al. Risk of late aortic events after an isolated aortic valve replacement for bicuspid aortic valve stenosis with concomitant ascending aortic dila-tion. Eur J Cardiothorac Surg. 2012;42(5):832-837. 43. Hiratzka LF, Creager MA, Isselbacher EM, et al. Sur-gery for aortic dilatation in patients with bicuspid aortic valves: a statement of clarification from the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. J Am Coll Cardiol. 2016;67(6):724-731. Important clarification of conflicting guidelines regarding indications for surgical treatment in patients with bicuspid aortic valve. 44. Hiratzka LF, Bakris GL, Beckman JA, et al. 2010 ACCF/AHA/AATS/ACR/ASA/SCA/SCAI/SIR/STS/SVM guide-lines for the diagnosis and management of patients with thoracic aortic disease: a report of the American College of Cardiology Foundation/American Heart Association Task Force on Practice Guidelines, American Associa-tion for Thoracic Surgery, American College of Radiology, American Stroke Association, Society of Cardiovascular Anesthesiologists, Society for Cardiovascular Angiogra-phy and Interventions, Society of Interventional Radiol-ogy, Society of Thoracic Surgeons, and Society for Vascular Medicine. Circulation. 2010;121(13):e266-e369. Compre-hensive guidelines regarding a broad range of diagnosis and treatment issues, based on review and ranking of the available evidence in the literature. 45. Isselbacher EM. Thoracic and abdominal aortic aneurysms. Circulation. 2005;111(6):816-828. 46. Wiet SP, Pearce WH, McCarthy WJ, et al. Utility of trans-esophageal echocardiography in the diagnosis of disease of the thoracic aorta. J Vasc Surg. 1994;20(4):613-620. 47. Fillinger MF. Imaging of the thoracic and thoracoabdominal aorta. Semin Vasc Surg. 2000;13(4):247-263. 48. McDonald JS, McDonald RJ, Lieske JC, et al. Risk of acute kidney injury, dialysis, and mortality in patients with chronic kidney disease after intravenous contrast material exposure. Mayo Clin Proc. 2015;90(8):1046-1053. 49. Meinel FG, De Cecco CN, Schoepf UJ, Katzberg R. Contrast-induced acute kidney injury: definition, epidemiology, and outcome. Biomed Res Int. 2014;2014:859328. 50. Stojanovska J, Rodriguez K, Mueller GC, Agarwal PP. MR imaging of the thoracic aorta. Magn Reson Imaging Clin N Am. 2015;23(2):273-291. 51. Danias P, Eldeman R, Manning W. Magnetic resonance angi-ography of the great vessels and the coronary arteries. In: Pohost GM, ed. Imaging in Cardiovascular Disease. Phila-delphia: Lippincott Williams & Wilkins; 2000:449. 52. Ergun I, Keven K, Uruc I, et al. The safety of gadolinium in patients with stage 3 and 4 renal failure. Nephrol Dial Trans-plant. 2006;21(3):697-700. 53. Merten GJ, Burgess WP, Gray LV, et al. Prevention of contrast-induced nephropathy with sodium bicarbonate: a randomized controlled trial. JAMA. 2004;291(19):2328-2334. 54. Tepel M, van der Giet M, Schwarzfeld C, et al. Prevention of radiographic-contrast-agent-induced reductions in renal func-tion by acetylcysteine. N Engl J Med. 2000;343(3):180-184. 55. Appoo JJ, Tse LW, Pozeg ZI, et al. Thoracic aortic fron-tier: review of current applications and directions of tho-racic endovascular aortic repair (TEVAR). Can J Cardiol. 2014;30(1):52-63. 56. Hughes K, Guerrier J, Obirieze A, et al. Open versus endo-vascular repair of thoracic aortic aneurysms: a Nationwide Inpatient Sample study. Vasc Endovascular Surg. 2014;48(5-6): 383-387. 57. Walker KL, Shuster JJ, Martin TD, et al. Practice patterns for thoracic aneurysms in the stent graft era: health care system implications. Ann Thorac Surg. 2010;90(6):1833-1839. 58. Gopaldas RR, Dao TK, LeMaire SA, Huh J, Coselli JS. Endovas-cular versus open repair of ruptured descending thoracic aortic Brunicardi_Ch22_p0853-p0896.indd 89001/03/19 5:42 PM 891THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22aneurysms: a nationwide risk-adjusted study of 923 patients. J Thorac Cardiovasc Surg. 2011;142(5):1010-1018. 59. Preventza O, Aftab M, Coselli JS. Hybrid techniques for com-plex aortic arch surgery. Tex Heart Inst J. 2013;40(5):568-571. 60. Preventza O, Bakaeen FG, Cervera RD, Coselli JS. Deploy-ment of proximal thoracic endograft in zone 0 of the ascending aorta: treatment options and early outcomes for aortic arch aneurysms in a high-risk population. Eur J Cardiothorac Surg. 2013;44(3):446-452. 61. Coselli JS, LeMaire SA, Buket S. Marfan syndrome: the vari-ability and outcome of operative management. J Vasc Surg. 1995;21(3):432-443. 62. Svensson LG, Adams DH, Bonow RO, et al. Aortic valve and ascending aorta guidelines for management and qual-ity measures. Ann Thorac Surg. 2013;95(6 suppl):S1-S66. Comprehensive guidelines regarding the treatment of ascend-ing aortic disease, based on review and ranking of the avail-able evidence in the literature. 63. LeMaire SA, Rice DC, Schmittling ZC, Coselli JS. Emergency surgery for thoracoabdominal aortic aneurysms with acute pre-sentation. J Vasc Surg. 2002;35(6):1171-1178. 64. Greenberg R, Eagleton M, Mastracci T. Branched endografts for thoracoabdominal aneurysms. J Thorac Cardiovasc Surg. 2010;140(6 suppl):S171-S178. 65. Preventza O, Garcia A, Cooley DA, et al. Total aortic arch replacement: a comparative study of zone 0 hybrid arch exclu-sion versus traditional open repair. J Thorac Cardiovasc Surg. 2015;150(6):1591-1600. 66. Preventza O, Mohammed S, Cheong BY, et al. Endovascular therapy in patients with genetically triggered thoracic aor-tic disease: applications and shortand mid-term outcomes. Eur J Cardiothorac Surg. 2014;46(2):248-253. 67. LeMaire SA, Green SY, Kim JH, et al. Thoracic or thoracoabdomi-nal approaches to endovascular device removal and open aortic repair. Ann Thorac Surg. 2012;93(3):726-732; discussion 733. 68. Coselli JS, Spiliotopoulos K, Preventza O, et al. Open aortic surgery after thoracic endovascular aortic repair. Gen Thorac Cardiovasc Surg. 2016;64(8):441-449. 69. LeMaire SA, Miller CC, III, Conklin LD, Schmittling ZC, Coselli JS. Estimating group mortality and paraplegia rates after thoracoabdominal aortic aneurysm repair. Ann Thorac Surg. 2003;75(2):508-513. 70. LeMaire SA, Miller CC, III, Conklin LD, et al. A new pre-dictive model for adverse outcomes after elective thora-coabdominal aortic aneurysm repair. Ann Thorac Surg. 2001;71(4):1233-1238. 71. Preventza O, Coselli JS, Price MD, et al. Elective primary aortic root replacement with and without hemiarch repair in patients with no previous cardiac surgery. J Thorac Cardio-vasc Surg. 2017;153(6):1402-1408. 72. Gott VL, Cameron DE, Alejo DE, et al. Aortic root replace-ment in 271 Marfan patients: a 24-year experience. Ann Tho-rac Surg. 2002;73(2):438-443. 73. Preventza O, Mohamed AS, Cooley DA, et al. Homograft use in reoperative aortic root and proximal aortic surgery for endo-carditis: a 12-year experience in high-risk patients. J Thorac Cardiovasc Surg. 2014;148(3):989-994. 74. Carrel TP, Berdat P, Englberger L, et al. Aortic root replace-ment with a new stentless aortic valve xenograft conduit: pre-liminary hemodynamic and clinical results. J Heart Valve Dis. 2003;12(6):752-757. 75. Deleuze PH, Fromes Y, Khoury W, et al. Eight-year results of Freestyle stentless bioprosthesis in the aortic position: a single-center study of 500 patients. J Heart Valve Dis. 2006;15(2):247-252. 76. Oury JH. Clinical aspects of the Ross procedure: indica-tions and contraindications. Semin Thorac Cardiovasc Surg. 1996;8(4):328-335. 77. Coselli JS, Hughes MS, Green SY, et al. Valve-sparing aortic root replacement: early and midterm outcomes in 83 patients. Ann Thorac Surg. 2014;97(4):1267-1273. 78. Coselli JS, Volguina IV, LeMaire SA, et al. Early and 1-year outcomes of aortic root surgery in patients with Marfan syndrome: a prospective, multicenter, comparative study. J Thorac Cardiovasc Surg. 2014;147(6):1758-1766, 1767.e1751-e1754. This report details the early and 1-year outcomes of an international prospective study comparing valve-sparing and valve-replacing root operations in patients with Marfan syndrome. Although patients in both groups had excellent early outcomes, those who underwent valve-sparing procedures had a higher incidence of late aortic valve regur-gitation, raising concerns about long-term durability. 79. David TE, Ivanov J, Armstrong S, Feindel CM, Webb GD. Aortic valve-sparing operations in patients with aneurysms of the aortic root or ascending aorta. Ann Thorac Surg. 2002;74(5):S1758-S1761. 80. Kvitting JP, Kari FA, Fischbein MP, et al. David valvesparing aortic root replacement: equivalent mid-term outcome for different valve types with or without connective tissue disorder. J Thorac Cardiovasc Surg. 2013;145(1):117-126, 127e111-e115. 81. Bentall H, De Bono A. A technique for complete replacement of the ascending aorta. Thorax. 1968;23(4):338-339. 82. Cabrol C, Pavie A, Gandjbakhch I, et al. Complete replace-ment of the ascending aorta with reimplantation of the coro-nary arteries: new surgical approach. J Thorac Cardiovasc Surg. 1981;81(2):309-315. 83. Kouchoukos NT, Wareing TH, Murphy SF, Perrillo JB. Sixteen-year experience with aortic root replacement: results of 172 operations. Ann Surg. 1991;214(3):308-318. 84. Zubiate P, Kay JH. Surgical treatment of aneurysm of the ascending aorta with aortic insufficiency and marked dis-placement of the coronary ostia. J Thorac Cardiovasc Surg. 1976;71(3):415-421. 85. Preventza O, Coselli JS. Saccular aneurysms of the transverse aortic arch: treatment options available in the endovascular era. Aorta (Stamford). 2015;3(2):61-66. 86. LeMaire SA, Price MD, Parenti JL, et al. Early outcomes after aortic arch replacement by using the Y-graft technique. Ann Thorac Surg. 2011;91(3):700-707. 87. Spielvogel D, Etz CD, Silovitz D, Lansman SL, Griepp RB. Aortic arch replacement with a trifurcated graft. Ann Thorac Surg. 2007;83(2):S791-S795. 88. Borst HG, Frank G, Schaps D. Treatment of extensive aortic aneurysms by a new multiple-stage approach. J Thorac Car-diovasc Surg. 1988;95(1):11-13. 89. Preventza O, Al-Najjar R, LeMaire SA, Weldon S, Coselli JS. Total arch replacement with frozen elephant trunk technique. Ann Cardiothorac Surg. 2013;2(5):649-652. 90. Shrestha M, Martens A, Kaufeld T, et al. Single-centre experi-ence with the frozen elephant trunk technique in 251 patients over 15 years. Eur J Cardiothorac Surg. 2017;52(5):858-866. 91. Preventza O, Coselli JS, Mayor J, et al. The stent is not to blame: lessons learned with a simplified US version of the frozen elephant trunk. Ann Thorac Surg. 2017;104(5): 1456-1463. 92. Ueda Y, Miki S, Kusuhara K, et al. Surgical treatment of aneu-rysm or dissection involving the ascending aorta and aortic arch, utilizing circulatory arrest and retrograde cerebral perfu-sion. J Cardiovasc Surg (Torino). 1990;31(5):553-558. 93. Sundt TM, III, Orszulak TA, Cook DJ, Schaff HV. Improv-ing results of open arch replacement. Ann Thorac Surg. 2008;86(3):787-796. 94. Wong DR, Coselli JS, Palmero L, et al. Axillary artery can-nulation in surgery for acute or subacute ascending aortic dis-sections. Ann Thorac Surg. 2010;90(3):731-737.Brunicardi_Ch22_p0853-p0896.indd 89101/03/19 5:42 PM 892SPECIFIC CONSIDERATIONSPART II 95. Preventza O, Bakaeen FG, Stephens EH, et al. Innominate artery cannulation: an alternative to femoral or axillary cannu-lation for arterial inflow in proximal aortic surgery. J Thorac Cardiovasc Surg. 2013;145(3 suppl):S191-S196. 96. Preventza O, Coselli JS, Akvan S, et al. The impact of tem-perature in aortic arch surgery patients receiving antegrade cerebral perfusion for >30 minutes: how relevant is it really? J Thorac Cardiovasc Surg. 2017;153(4):767-776. 97. Preventza O, Coselli JS, Garcia A, et al. Moderate hypother-mia at warmer temperatures is safe in elective proximal and total arch surgery: results in 665 patients. J Thorac Cardiovasc Surg. 2017;153(5):1011-1018. 98. Svensson LG. Antegrade perfusion during suspended anima-tion? J Thorac Cardiovasc Surg. 2002;124(6):1068-1070. 99. Della Corte A, Scardone M, Romano G, et al. Aortic arch sur-gery: thoracoabdominal perfusion during antegrade cerebral perfusion may reduce postoperative morbidity. Ann Thorac Surg. 2006;81(4):1358-1364. 100. Panos A, Myers PO, Kalangos A. Novel technique for aor-tic arch surgery under mild hypothermia. Ann Thorac Surg. 2008;85(1):347-348. 101. Preventza O, Henry MJ, Cheong BY, Coselli JS. Endovascular repair of the ascending aorta: when and how to implement the current technology. Ann Thorac Surg. 2014;97(5):1555-1560. 102. Inoue K, Hosokawa H, Iwase T, et al. Aortic arch reconstruc-tion by transluminally placed endovascular branched stent graft. Circulation. 1999;100(19 suppl):II316-II321. 103. Volodos NL, Karpovich IP, Troyan VI, et al. Clinical experi-ence of the use of self-fixing synthetic prostheses for remote endoprosthetics of the thoracic and the abdominal aorta and iliac arteries through the femoral artery and as intraop-erative endoprosthesis for aorta reconstruction. Vasa Suppl. 1991;33:93-95. 104. Volodos NL, Shekhanin VE, Karpovich IP, Troian VI, Gur’ev Iu A. A self-fixing synthetic blood vessel endoprosthesis [in Russian]. Vestn Khir Im I I Grek. 1986;137(11):123-125. 105. Volodos NL. Historical perspective: the first steps in endovas-cular aortic repair: how it all began. J Endovasc Ther. 2013;20 (suppl 1):I3-23. 106. Melissano G, Tshomba Y, Bertoglio L, Rinaldi E, Chiesa R. Analysis of stroke after TEVAR involving the aortic arch. Eur J Vasc Endovasc Surg. 2012;43(3):269-275. 107. Andersen ND, Williams JB, Hanna JM, et al. Results with an algorithmic approach to hybrid repair of the aortic arch. J Vasc Surg. 2013;57(3):655-667. 108. Lotfi S, Clough RE, Ali T, et al. Hybrid repair of complex thoracic aortic arch pathology: long-term outcomes of extra-anatomic bypass grafting of the supra-aortic trunk. Cardiovasc Intervent Radiol. 2013;36(1):46-55. 109. Preventza O, Garcia A, Moeller K, et al. Retrograde ascend-ing aortic dissection after thoracic endovascular aortic repair for distal aortic dissection or with zone 0 landing: asso-ciation, risk factors, and true incidence. Ann Thorac Surg. 2015;100(2):509-515. 110. Coselli JS, de la Cruz KI, Preventza O, LeMaire SA, Weldon SA. Extent II thoracoabdominal aortic aneurysm repair: how I do it. Semin Thorac Cardiovasc Surg. 2016;28(2):221-237. 111. Ghanta RK, Green SY, Price MD, et al. Midterm survival and quality of life after extent II thoracoabdominal aortic repair in Marfan syndrome. Ann Thorac Surg. 2016;101(4): 1402-1409. 112. Coselli JS, LeMaire SA, Köksoy C, Schmittling ZC, Curling PE. Cerebrospinal fluid drainage reduces paraplegia after thoracoabdominal aortic aneurysm repair: results of a ran-domized clinical trial. J Vasc Surg. 2002;35(4):631-639. This randomized clinical trial established the utility of using cerebral spinal fluid drainage to prevent spinal cord injury during exten-sive thoracoabdominal aortic aneurysm repairs. 113. Youngblood SC, Tolpin DA, LeMaire SA, et al. Complications of cerebrospinal fluid drainage after thoracic aortic surgery: a review of 504 patients over 5 years. J Thorac Cardiovasc Surg. 2013;146(1):166-171. 114. Jacobs MJ, Mess W, Mochtar B, et al. The value of motor evoked potentials in reducing paraplegia during thora-coabdominal aneurysm repair. J Vasc Surg. 2006;43(2): 239-246. 115. van Dongen EP, Schepens MA, Morshuis WJ, et al. Thoracic and thoracoabdominal aortic aneurysm repair: use of evoked potential monitoring in 118 patients. J Vasc Surg. 2001;34(6):1035-1040. 116. Coselli JS. The use of left heart bypass in the repair of thora-coabdominal aortic aneurysms: current techniques and results. Semin Thorac Cardiovasc Surg. 2003;15(4):326-332. 117. Coselli JS, LeMaire SA. Left heart bypass reduces paraplegia rates after thoracoabdominal aortic aneurysm repair. Ann Tho-rac Surg. 1999;67(6):1931-1934. 118. Safi HJ, Miller CC, III, Huynh TT, et al. Distal aortic perfu-sion and cerebrospinal fluid drainage for thoracoabdominal and descending thoracic aortic repair: ten years of organ pro-tection. Ann Surg. 2003;238(3):372-380. 119. Köksoy C, LeMaire SA, Curling PE, et al. Renal perfusion during thoracoabdominal aortic operations: cold crystal-loid is superior to normothermic blood. Ann Thorac Surg. 2002;73(3):730-738. 120. Kouchoukos NT, Masetti P, Rokkas CK, Murphy SF. Hypo-thermic cardiopulmonary bypass and circulatory arrest for operations on the descending thoracic and thoracoabdominal aorta. Ann Thorac Surg. 2002;74(5):S1885-S1887. 121. Coselli JS, Oberwalder P. Successful repair of mega aorta using reversed elephant trunk procedure. J Vasc Surg. 1998;27(1):183-188. 122. Chen DW, Price MD, LeMaire SA, et al. Early versus late inpatient awake transcervical injection laryngoplasty after thoracic aortic repair. Laryngoscope. 2018;128(1): 144-147. 123. Jones MM, Akay M, Murariu D, LeMaire SA, Coselli JS. Safe aortic arch clamping in patients with patent internal thoracic artery grafts. Ann Thorac Surg. 2010;89(4):e31-e32. 124. Svensson LG, Kouchoukos NT, Miller DC, et al. Expert con-sensus document on the treatment of descending thoracic aor-tic disease using endovascular stent-grafts. Ann Thorac Surg. 2008;85(1 suppl):S1-S41. 125. Parodi JC, Palmaz JC, Barone HD. Transfemoral intraluminal graft implantation for abdominal aortic aneurysms. Ann Vasc Surg. 1991;5(6):491-499. 126. Dake MD, Miller DC, Semba CP, et al. Transluminal placement of endovascular stent-grafts for the treatment of descending thoracic aortic aneurysms. N Engl J Med. 1994;331(26):1729-1734. 127. Fillinger MF, Greenberg RK, McKinsey JF, Chaikof EL, Society for Vascular Surgery Ad Hoc Committee on TEVAR Reporting Standards. Reporting standards for thoracic endovascular aortic repair (TEVAR). J Vasc Surg. 2010;52(4):1022-1033, 1033 e1015. Essential guidelines for writing and interpreting reports regarding endovascular repair of the thoracic aorta. 128. Preventza O, Bavaria J, Ramaiah V, et al. Thoracic endograft-ing is a viable option for the octogenarian. Ann Thorac Surg. 2010;90(1):78-82. 129. Gopaldas RR, Huh J, Dao TK, et al. Superior nationwide outcomes of endovascular versus open repair for isolated descending thoracic aortic aneurysm in 11,669 patients. J Thorac Cardiovasc Surg. 2010;140(5):1001-1010. 130. Preventza O, Wheatley GH, 3rd, Williams J, et al. Identifying paraplegia risk associated with thoracic endografting. Asian Cardiovasc Thorac Ann. 2009;17(6):568-572.Brunicardi_Ch22_p0853-p0896.indd 89201/03/19 5:42 PM 893THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22 131. Riesenman PJ, Farber MA, Mendes RR, et al. Coverage of the left subclavian artery during thoracic endovascular aortic repair. J Vasc Surg. 2007;45(1):90-94. 132. Buth J, Harris PL, Hobo R, et al. Neurologic complica-tions associated with endovascular repair of thoracic aor-tic pathology: incidence and risk factors. A study from the European Collaborators on Stent/Graft Techniques for Aor-tic Aneurysm Repair (EUROSTAR) registry. J Vasc Surg. 2007;46(6):1103-1110. 133. Bozinovski J, LeMaire SA, Weldon SA, Coselli JS. Hybrid repairs of the distal aortic arch and proximal descend-ing thoracic aorta. Op Tech Thorac Cardiovasc Surg. 2007;12(3):167-177. 134. Woo EY, Bavaria JE, Pochettino A, et al. Techniques for pre-serving vertebral artery perfusion during thoracic aortic stent grafting requiring aortic arch landing. Vasc Endovascular Surg. 2006;40(5):367-373. 135. Bradshaw RJ, Ahanchi SS, Powell O, et al. Left subclavian artery revascularization in zone 2 thoracic endovascular aortic repair is associated with lower stroke risk across all aortic dis-eases. J Vasc Surg. 2017;65(5):1270-1279. 136. Fann JI, Dake MD, Semba CP, et al. Endovascular stent-graft-ing after arch aneurysm repair using the “elephant trunk.” Ann Thorac Surg. 1995;60(4):1102-1105. 137. Lin PH, Dardik A, Coselli JS. A simple technique to facili-tate antegrade thoracic endograft deployment using a hybrid elephant trunk procedure under hypothermic circulatory arrest. J Endovasc Ther. 2007;14(5):669-671. 138. Greenberg RK, West K, Pfaff K, et al. Beyond the aortic bifur-cation: branched endovascular grafts for thoracoabdominal and aortoiliac aneurysms. J Vasc Surg. 2006;43(5):879-886. 139. Greenberg RK, Qureshi M. Fenestrated and branched devices in the pipeline. J Vasc Surg. 2010;52(4 suppl):15S-21S. 140. Moulakakis KG, Mylonas SN, Avgerinos E, et al. The chim-ney graft technique for preserving visceral vessels during endovascular treatment of aortic pathologies. J Vasc Surg. 2012;55(5):1497-1503. 141. Mehta M, Darling RC, III, Taggert JB, et al. Outcomes of planned celiac artery coverage during TEVAR. J Vasc Surg. 2010;52(5):1153-1158. 142. Black SA, Wolfe JH, Clark M, et al. Complex thoracoabdomi-nal aortic aneurysms: endovascular exclusion with visceral revascularization. J Vasc Surg. 2006;43(6):1081-1089. 143. Zhou W, Reardon M, Peden EK, Lin PH, Lumsden AB. Hybrid approach to complex thoracic aortic aneurysms in high-risk patients: surgical challenges and clinical outcomes. J Vasc Surg. 2006;44(4):688-693. 144. Patel R, Conrad MF, Paruchuri V, et al. Thoracoabdominal aneurysm repair: hybrid versus open repair. J Vasc Surg. 2009;50(1):15-22. 145. Hughes GC, Barfield ME, Shah AA, et al. Staged total abdom-inal debranching and thoracic endovascular aortic repair for thoracoabdominal aneurysm. J Vasc Surg. 2012;56(3):621-629. 146. Modine T, Lions C, Destrieux-Garnier L, et al. Iatrogenic iliac artery rupture and type A dissection after endovas-cular repair of type B aortic dissection. Ann Thorac Surg. 2004;77(1):317-319. 147. Tshomba Y, Bertoglio L, Marone EM, et al. Retrograde type A dissection after endovascular repair of a “zone 0” nondis-secting aortic arch aneurysm. Ann Vasc Surg. 2010;24(7):952 e951-957. 148. Desai ND, Pochettino A, Szeto WY, et al. Thoracic endovas-cular aortic repair: evolution of therapy, patterns of use, and results in a 10-year experience. J Thorac Cardiovasc Surg. 2011;142(3):587-594. 149. Preventza O, Wheatley GH, 3rd, Ramaiah VG, et al. Management of endoleaks associated with endovascular treatment of descending thoracic aortic diseases. J Vasc Surg. 2008;48(1):69-73. A detailed account of the develop-ment and treatment of endoleak after endovascular repair of aneurysm, dissection, injuries, and several other pathologies involving the descending thoracic aorta. 150. Dumfarth J, Michel M, Schmidli J, et al. Mechanisms of fail-ure and outcome of secondary surgical interventions after tho-racic endovascular aortic repair (TEVAR). Ann Thorac Surg. 2011;91(4):1141-1146. 151. Geisbusch P, Hoffmann S, Kotelis D, et al. Reinterventions during midterm follow-up after endovascular treatment of thoracic aortic disease. J Vasc Surg. 2011;53(6):1528-1533. 152. Daily PO, Trueblood HW, Stinson EB, Wuerflein RD, Shumway NE. Management of acute aortic dissections. Ann Thorac Surg. 1970;10(3):237-247. 153. DeBakey ME, Henly WS, Cooley DA, et al. Surgical manage-ment of dissecting aneurysms of the aorta. J Thorac Cardio-vasc Surg. 1965;49:130-149. 154. Borst HG, Heinemann MK, Stone CD. Surgical Treatment of Aortic Dissection. New York: Churchill Livingstone; 1996. 155. Tsagakis K, Tossios P, Kamler M, et al. The DeBakey classification exactly reflects late outcome and re-interven-tion probability in acute aortic dissection with a slightly mod-ified type II definition. Eur J Cardiothorac Surg. 2011;40(5): 1078-1084. 156. Augoustides JG, Geirsson A, Szeto WY, et al. Observational study of mortality risk stratification by ischemic presentation in patients with acute type A aortic dissection: the Penn classi-fication. Nat Clin Pract Cardiovasc Med. 2009;6(2):140-146. 157. Augoustides JG, Szeto WY, Woo EY, et al. The complica-tions of uncomplicated acute type-B dissection: the introduc-tion of the Penn classification. J Cardiothorac Vasc Anesth. 2012;26(6):1139-1144. 158. Tsagakis K, Konorza T, Dohle DS, et al. Hybrid operating room concept for combined diagnostics, intervention and surgery in acute type A dissection. Eur J Cardiothorac Surg. 2013;43(2):397-404. 159. Booher AM, Isselbacher EM, Nienaber CA, et al. The IRAD classification system for characterizing survival after aortic dissection. Am J Med. 2013;126(8):730 e719-e724. 160. Nienaber CA, Sievers HH. Intramural hematoma in acute aor-tic syndrome: more than one variant of dissection? Circula-tion. 2002;106(3):284-285. 161. Evangelista A, Mukherjee D, Mehta RH, et al. Acute intramu-ral hematoma of the aorta: a mystery in evolution. Circulation. 2005;111(8):1063-1070. 162. Maraj R, Rerkpattanapipat P, Jacobs LE, Makornwattana P, Kotler MN. Meta-analysis of 143 reported cases of aortic intramural hematoma. Am J Cardiol. 2000;86(6):664-668. 163. Ganaha F, Miller DC, Sugimoto K, et al. Prognosis of aortic intramural hematoma with and without penetrating atheroscle-rotic ulcer: a clinical and radiological analysis. Circulation. 2002;106(3):342-348. 164. Clouse WD, Hallett JW, Jr, Schaff HV, et al. Acute aor-tic dissection: population-based incidence compared with degenerative aortic aneurysm rupture. Mayo Clin Proc. 2004;79(2):176-180. 165. Anagnostopoulos CE, Prabhakar MJ, Kittle CF. Aor-tic dissections and dissecting aneurysms. Am J Cardiol. 1972;30(3):263-273. 166. Hirst AE, Jr, Johns VJ, Jr, Kime SW, Jr. Dissecting aneurysm of the aorta: a review of 505 cases. Medicine (Baltimore). 1958;37(3):217-279. 167. Daniel JC, Huynh TT, Zhou W, et al. Acute aortic dis-section associated with use of cocaine. J Vasc Surg. 2007;46(3):427-433. 168. Hatzaras IS, Bible JE, Koullias GJ, et al. Role of exertion or emotion as inciting events for acute aortic dissection. Am J Cardiol. 2007;100(9):1470-1472.Brunicardi_Ch22_p0853-p0896.indd 89301/03/19 5:42 PM 894SPECIFIC CONSIDERATIONSPART II 169. Wang X, LeMaire SA, Chen L, et al. Decreased expression of fibulin-5 correlates with reduced elastin in thoracic aortic dissection. Surgery. 2005;138(2):352-359. 170. Wang X, LeMaire SA, Chen L, et al. Increased collagen depo-sition and elevated expression of connective tissue growth factor in human thoracic aortic dissection. Circulation. 2006;114(1 suppl):I200-I205. 171. Shen YH, Zhang L, Ren P, et al. AKT2 confers protec-tion against aortic aneurysms and dissections. Circ Res. 2013;112(4):618-632. 172. Harris KM, Strauss CE, Eagle KA, et al. Correlates of delayed recognition and treatment of acute type A aortic dissection: the International Registry of Acute Aortic Dissection (IRAD). Circulation. 2011;124(18):1911-1918. 173. Erbel R, Alfonso F, Boileau C, et al. Diagnosis and man-agement of aortic dissection. Eur Heart J. 2001;22(18): 1642-1681. 174. Hagan PG, Nienaber CA, Isselbacher EM, et al. The Inter-national Registry of Acute Aortic Dissection (IRAD): new insights into an old disease. JAMA. 2000;283(7):897-903. 175. Klompas M. Does this patient have an acute thoracic aortic dissection? JAMA. 2002;287(17):2262-2272. 176. Shimony A, Filion KB, Mottillo S, Dourian T, Eisenberg MJ. Meta-analysis of usefulness of D-dimer to diagnose acute aor-tic dissection. Am J Cardiol. 2011;107(8):1227-1234. 177. Sodeck G, Domanovits H, Schillinger M, et al. D-dimer in ruling out acute aortic dissection: a systematic review and pro-spective cohort study. Eur Heart J. 2007;28(24):3067-3075. 178. Rapezzi C, Longhi S, Graziosi M, et al. Risk factors for diagnostic delay in acute aortic dissection. Am J Cardiol. 2008;102(10):1399-1406. 179. von Kodolitsch Y, Nienaber CA, Dieckmann C, et al. Chest radiography for the diagnosis of acute aortic syndrome. Am J Med. 2004;116(2):73-77. 180. Nienaber CA, von Kodolitsch Y, Nicolas V, et al. The diagnosis of thoracic aortic dissection by noninvasive imaging proce-dures. N Engl J Med. 1993;328(1):1-9. 181. Keren A, Kim CB, Hu BS, et al. Accuracy of biplane and multiplane transesophageal echocardiography in diagnosis of typical acute aortic dissection and intramural hematoma. J Am Coll Cardiol. 1996;28(3):627-636. 182. Miller JS, LeMaire SA, Coselli JS. Evaluating aortic dis-section: when is coronary angiography indicated? Heart. 2000;83(6):615-616. 183. Scholl FG, Coady MA, Davies R, et al. Interval or permanent nonoperative management of acute type A aortic dissection. Arch Surg. 1999;134(4):402-405. 184. Gillinov AM, Lytle BW, Kaplon RJ, et al. Dissection of the ascending aorta after previous cardiac surgery: differences in presentation and management. J Thorac Cardiovasc Surg. 1999;117(2):252-260. 185. Preventza O, Garcia A, Tuluca A, et al. Innominate artery cannulation for proximal aortic surgery: outcomes and neu-rological events in 263 patients. Eur J Cardiothorac Surg. 2015;48(6):937-942. 186. Preventza O, Simpson KH, Cooley DA, et al. Unilateral versus bilateral cerebral perfusion for acute type A aortic dissection. Ann Thorac Surg. 2015;99(1):80-87. 187. Kirsch M, Soustelle C, Houel R, Hillion ML, Loisance D. Risk factor analysis for proximal and distal reoperations after sur-gery for acute type A aortic dissection. J Thorac Cardiovasc Surg. 2002;123(2):318-325. 188. Crawford ES, Kirklin JW, Naftel DC, et al. Surgery for acute dissection of ascending aorta. Should the arch be included? J Thorac Cardiovasc Surg. 1992;104(1):46-59. 189. Westaby S, Saito S, Katsumata T. Acute type A dissection: conservative methods provide consistently low mortality. Ann Thorac Surg. 2002;73(3):707-713. 190. Geirsson A, Bavaria JE, Swarr D, et al. Fate of the residual distal and proximal aorta after acute type A dissection repair using a contemporary surgical reconstruction algorithm. Ann Thorac Surg. 2007;84(6):1955-1964. 191. Malvindi PG, van Putte BP, Sonker U, et al. Reoperation after acute type A aortic dissection repair: a series of 104 patients. Ann Thorac Surg. 2013;95(3):922-927. 192. Glower DD, Speier RH, White WD, et al. Management and long-term outcome of aortic dissection. Ann Surg. 1991;214(1):31-41. 193. Kazui T, Washiyama N, Muhammad BA, et al. Extended total arch replacement for acute type A aortic dissection: experience with seventy patients. J Thorac Cardiovasc Surg. 2000;119(3):558-565. 194. Hoffman A, Damberg AL, Schalte G, et al. Thoracic stent graft sizing for frozen elephant trunk repair in acute type A dissec-tion. J Thorac Cardiovasc Surg. 2013;145(4):964-969. 195. Preventza O, Cervera R, Cooley DA, et al. Acute type I aortic dissection: traditional versus hybrid repair with antegrade stent delivery to the descending thoracic aorta. J Thorac Cardiovasc Surg. 2014;148(1):119-125. 196. Karck M, Chavan A, Khaladj N, et al. The frozen elephant trunk technique for the treatment of extensive thoracic aortic aneurysms: operative results and follow-up. Eur J Cardiotho-rac Surg. 2005;28(2):286-290. 197. Gorlitzer M, Weiss G, Meinhart J, et al. Fate of the false lumen after combined surgical and endovascular repair treat-ing Stanford type A aortic dissections. Ann Thorac Surg. 2010;89(3):794-799. 198. Di Bartolomeo R, Di Marco L, Armaro A, et al. Treatment of complex disease of the thoracic aorta: the frozen elephant trunk technique with the E-vita open prosthesis. Eur J Cardio-thorac Surg. 2009;35(4):671-675. 199. Uchida N, Katayama A, Tamura K, et al. Long-term results of the frozen elephant trunk technique for extended aortic arch disease. Eur J Cardiothorac Surg. 2010;37(6):1338-1345. 200. Lima B, Roselli EE, Soltesz EG, et al. Modified and “reverse” frozen elephant trunk repairs for extensive disease and com-plications after stent grafting. Ann Thorac Surg. 2012;93(1): 103-109. 201. Roselli EE, Rafael A, Soltesz EG, Canale L, Lytle BW. Simplified frozen elephant trunk repair for acute DeBakey type I dissection. J Thorac Cardiovasc Surg. 2013;145 (3 suppl):S197-S201. 202. Roselli EE, Soltesz EG, Mastracci T, Svensson LG, Lytle BW. Antegrade delivery of stent grafts to treat complex thoracic aortic disease. Ann Thorac Surg. 2010;90(2):539-546. 203. Preventza O, Coselli JS. Differential aspects of ascending tho-racic aortic dissection and its treatment: the North American experience. Ann Cardiothorac Surg. 2016;5(4):352-359. 204. Kouchoukos NT. Frozen elephant trunk technique for exten-sive chronic thoracic aortic dissection: is it the final answer? Ann Thorac Surg. 2011;92(5):1557-1558. 205. Genoni M, Paul M, Jenni R, et al. Chronic beta-blocker ther-apy improves outcome and reduces treatment costs in chronic type B aortic dissection. Eur J Cardiothorac Surg. 2001;19(5): 606-610. 206. DeBakey ME, McCollum CH, Crawford ES, et al. Dissection and dissecting aneurysms of the aorta: twenty-year follow-up of five hundred twenty-seven patients treated surgically. Surgery. 1982;92(6):1118-1134. 207. Fann JI, Smith JA, Miller DC, et al. Surgical management of aortic dissection during a 30-year period. Circulation. 1995;92(9 suppl):II113-II121. 208. Elefteriades JA, Hartleroad J, Gusberg RJ, et al. Long-term experience with descending aortic dissection: the complicationspecific approach. Ann Thorac Surg. 1992;53(1):11-20. 209. Barnes DM, Williams DM, Dasika NL, et al. A single-center experience treating renal malperfusion after aortic dissection Brunicardi_Ch22_p0853-p0896.indd 89401/03/19 5:42 PM 895THORACIC ANEURYSMS AND AORTIC DISSECTIONCHAPTER 22with central aortic fenestration and renal artery stenting. J Vasc Surg. 2008;47(5):903-910. 210. Hughes GC. Management of acute type B aortic dissec-tion; ADSORB trial. J Thorac Cardiovasc Surg. 2015;149 (2 suppl):S158-S162. 211. Nienaber CA, Kische S, Rousseau H, et al. Endovascular repair of type B aortic dissection: long-term results of the randomized investigation of stent grafts in aortic dissec-tion trial. Circ Cardiovasc Interv. 2013;6(4):407-416. The eagerly anticipated report of a randomized trial comparing endovascular repair plus optimal medical treatment with opti-mal medical treatment alone for the treatment of early-chronic descending thoracic aortic dissection. 212. Demers P, Miller DC, Mitchell RS, et al. Stent-graft repair of penetrating atherosclerotic ulcers in the descending tho-racic aorta: mid-term results. Ann Thorac Surg. 2004;77(1): 81-86. 213. Patel HJ, Sood V, Williams DM, et al. Late outcomes with repair of penetrating thoracic aortic ulcers: the merits of an endovascular approach. Ann Thorac Surg. 2012;94(2): 516-522. 214. Preventza O, Coselli JS, Garcia A, et al. Aortic root surgery with circulatory arrest: predictors of prolonged postoperative hospital stay. J Thorac Cardiovasc Surg. 2017;153(3):511-518. 215. Aomi S, Nakajima M, Nonoyama M, et al. Aortic root replace-ment using composite valve graft in patients with aortic valve disease and aneurysm of the ascending aorta: twenty years’ experience of late results. Artif Organs. 2002;26(5):467-473. 216. Kindo M, Billaud P, Gerelli S, et al. Twenty-seven-year experi-ence with composite valve graft replacement of the aortic root. J Heart Valve Dis. 2007;16(4):370-377. 217. David TE, Mohr FW, Bavaria JE, et al. Initial experience with the Toronto Root bioprosthesis. J Heart Valve Dis. 2004;13(2):248-251. 218. Gleason TG, David TE, Coselli JS, Hammon JW, Jr, Bavaria JE. St. Jude Medical Toronto biologic aortic root prosthe-sis: early FDA phase II IDE study results. Ann Thorac Surg. 2004;78(3):786-793. 219. Kincaid EH, Cordell AR, Hammon JW, Adair SM, Kon ND. Coronary insufficiency after stentless aortic root replacement: risk factors and solutions. Ann Thorac Surg. 2007;83(3):964-968. 220. Kon ND, Cordell AR, Adair SM, Dobbins JE, Kitzman DW. Aortic root replacement with the freestyle stent-less porcine aortic root bioprosthesis. Ann Thorac Surg. 1999;67(6):1609-1615. 221. Melina G, De Robertis F, Gaer JA, et al. Mid-term pattern of survival, hemodynamic performance and rate of complica-tions after Medtronic Freestyle versus homograft full aortic root replacement: results from a prospective randomized trial. J Heart Valve Dis. 2004;13(6):972-975. 222. Badiu CC, Eichinger W, Bleiziffer S, et al. Should root replacement with aortic valve-sparing be offered to patients with bicuspid valves or severe aortic regurgitation? Eur J Car-diothorac Surg. 2010;38(5):515-522. 223. David TE, Maganti M, Armstrong S. Aortic root aneurysm: principles of repair and long-term follow-up. J Thorac Car-diovasc Surg. 2010;140(6 suppl):S14-S19. 224. Zingone B, Gatti G, Spina A, et al. Current role and outcomes of ascending aortic replacement for severe nonaneurysmal aor-tic atherosclerosis. Ann Thorac Surg. 2010;89(2):429-434. 225. Achneck HE, Rizzo JA, Tranquilli M, Elefteriades JA. Safety of thoracic aortic surgery in the present era. Ann Thorac Surg. 2007;84(4):1180-1185. 226. Estrera AL, Miller CC, III, Madisetty J, et al. Ascending and transverse aortic arch repair: the impact of glomerular filtra-tion rate on mortality. Ann Surg. 2008;247(3):524-529. 227. Fleck TM, Czerny M, Hutschala D, et al. The inci-dence of transient neurologic dysfunction after ascending aortic replacement with circulatory arrest. Ann Thorac Surg. 2003;76(4):1198-1202. 228. Immer FF, Barmettler H, Berdat PA, et al. Effects of deep hypo-thermic circulatory arrest on outcome after resection of ascend-ing aortic aneurysm. Ann Thorac Surg. 2002;74(2):422-425. 229. Heinemann MK, Buehner B, Jurmann MJ, Borst HG. Use of the “elephant trunk technique” in aortic surgery. Ann Thorac Surg. 1995;60(1):2-6. 230. LeMaire SA, Carter SA, Coselli JS. The elephant trunk tech-nique for staged repair of complex aneurysms of the entire thoracic aorta. Ann Thorac Surg. 2006;81(5):1561-1569. 231. Safi HJ, Miller CC, III, Estrera AL, et al. Staged repair of extensive aortic aneurysms: long-term experience with the elephant trunk technique. Ann Surg. 2004;240(4):677-684. 232. Sundt TM, Moon MR, DeOliviera N, et al. Contempo-rary results of total aortic arch replacement. J Card Surg. 2004;19(3):235-239. 233. Svensson LG, Kim KH, Blackstone EH, et al. Elephant trunk procedure: newer indications and uses. Ann Thorac Surg. 2004;78(1):109-116. 234. Kazui T, Yamashita K, Washiyama N, et al. Aortic arch replacement using selective cerebral perfusion. Ann Thorac Surg. 2007;83(2):S796-798. 235. Bischoff MS, Brenner RM, Scheumann J, et al. Long-term outcome after aortic arch replacement with a trifurcated graft. J Thorac Cardiovasc Surg. 2010;140(6 suppl):S71-S76. 236. Iba Y, Minatoya K, Matsuda H, et al. Contemporary open aortic arch repair with selective cerebral perfusion in the era of endovascular aortic repair. J Thorac Cardiovasc Surg. 2013;145(3 suppl):S72-S77. 237. Thomas M, Li Z, Cook DJ, Greason KL, Sundt TM. Contem-porary results of open aortic arch surgery. J Thorac Cardio-vasc Surg. 2012;144(4):838-844. 238. Urbanski PP, Lenos A, Bougioukakis P, et al. Mild-tomoderate hypothermia in aortic arch surgery using circula-tory arrest: a change of paradigm? Eur J Cardiothorac Surg. 2012;41(1):185-191. 239. Kondoh H, Taniguchi K, Funatsu T, et al. Total arch replace-ment with long elephant trunk anastomosed at the base of the innominate artery: a single-centre longitudinal experience. Eur J Cardiothorac Surg. 2012;42(5):840-848. 240. Flores J, Kunihara T, Shiiya N, et al. Extensive deployment of the stented elephant trunk is associated with an increased risk of spinal cord injury. J Thorac Cardiovasc Surg. 2006;131(2): 336-342. 241. Koullias GJ, Wheatley GH, III. State-of-the-art of hybrid pro-cedures for the aortic arch: a meta-analysis. Ann Thorac Surg. 2010;90(2):689-697. 242. Antoniou GA, Mireskandari M, Bicknell CD, et al. Hybrid repair of the aortic arch in patients with extensive aortic dis-ease. Eur J Vasc Endovasc Surg. 2010;40(6):715-721. 243. Geisbusch P, Kotelis D, Muller-Eschner M, Hyhlik-Durr A, Bockler D. Complications after aortic arch hybrid repair. J Vasc Surg. 2011;53(4):935-941. 244. Czerny M, Weigang E, Sodeck G, et al. Targeting landing zone 0 by total arch rerouting and TEVAR: midterm results of a trans-continental registry. Ann Thorac Surg. 2012;94(1):84-89. 245. Trimarchi S, Eagle KA, Nienaber CA, et al. Role of age in acute type A aortic dissection outcome: report from the Inter-national Registry of Acute Aortic Dissection (IRAD). J Thorac Cardiovasc Surg. 2010;140(4):784-789. 246. Rampoldi V, Trimarchi S, Eagle KA, et al. Simple risk models to predict surgical mortality in acute type A aortic dissection: the International Registry of Acute Aortic Dissection score. Ann Thorac Surg. 2007;83(1):55-61. 247. Pape LA, Awais M, Woznicki EM, et al. Presentation, diag-nosis, and outcomes of acute aortic dissection: 17-year trends From the International Registry of Acute Aortic Dissection. Brunicardi_Ch22_p0853-p0896.indd 89501/03/19 5:42 PM 896SPECIFIC CONSIDERATIONSPART IIJ Am Coll Cardiol. 2015;66(4):350-358. A comprehensive analysis of outcomes in patients with acute aortic dissection from the largest existing international registry. 248. Boening A, Karck M, Conzelmann LO, et al. German Registry for Acute Aortic Dissection Type A: structure, results, and future perspectives. Thorac Cardiovasc Surg. 2017;65(2):77-84. 249. Kruger T, Weigang E, Hoffmann I, et al. Cerebral protection during surgery for acute aortic dissection type A: results of the German Registry for Acute Aortic Dissection Type A (GERAADA). Circulation. 2011;124(4):434-443. 250. Dake MD, Miller DC, Mitchell RS, et al. The “first genera-tion” of endovascular stent-grafts for patients with aneurysms of the descending thoracic aorta. J Thorac Cardiovasc Surg. 1998;116(5):689-703. 251. Demers P, Miller DC, Mitchell RS, et al. Midterm results of endovascular repair of descending thoracic aortic aneurysms with first-generation stent grafts. J Thorac Cardiovasc Surg. 2004;127(3):664-673. 252. Bavaria JE, Appoo JJ, Makaroun MS, et al. Endovascular stent grafting versus open surgical repair of descending thoracic aortic aneurysms in low-risk patients: a multicenter compara-tive trial. J Thorac Cardiovasc Surg. 2007;133(2):369-377. 253. Fairman RM, Criado F, Farber M, et al. Pivotal results of the Medtronic Vascular Talent Thoracic Stent Graft System: the VALOR trial. J Vasc Surg. 2008;48(3):546-554. 254. Matsumura JS, Cambria RP, Dake MD, et al. International controlled clinical trial of thoracic endovascular aneurysm repair with the Zenith TX2 endovascular graft: 1-year results. J Vasc Surg. 2008;47(2):247-257. 255. Makaroun MS, Dillavou ED, Wheatley GH, Cambria RP. Five-year results of endovascular treatment with the Gore TAG device compared with open repair of thoracic aortic aneurysms. J Vasc Surg. 2008;47(5):912-918. 256. Foley PJ, Criado FJ, Farber MA, et al. Results with the Talent thoracic stent graft in the VALOR trial. J Vasc Surg. 2012;56(5):1214-1221 e1221. 257. Miller DC. Through the looking glass: The first 20 years of thoracic aortic stent-grafting. J Thorac Cardiovasc Surg. 2013;145(3 suppl):S142-S148. 258. Coselli JS, LeMaire SA, Conklin LD, Adams GJ. Left heart bypass during descending thoracic aortic aneurysm repair does not reduce the incidence of paraplegia. Ann Thorac Surg. 2004;77(4):1298-1303. 259. Chiesa R, Tshomba Y, Civilini E, et al. Open repair of descend-ing thoracic aneurysms. HSR Proc Intensive Care Cardiovasc Anesth. 2010;2(3):177-190. 260. Estrera AL, Miller CC, III, Chen EP, et al. Descending thoracic aortic aneurysm repair: 12-year experience using distal aortic perfusion and cerebrospinal fluid drainage. Ann Thorac Surg. 2005;80(4):1290-1296. 261. LeMaire SA, Price MD, Green SY, Zarda S, Coselli JS. Results of open thoracoabdominal aortic aneurysm repair. Ann Cardiothorac Surg. 2012;1(3):286-292. 262. Chiesa R, Melissano G, Civilini E, et al. Ten years experience of thoracic and thoracoabdominal aortic aneurysm surgical repair: lessons learned. Ann Vasc Surg. 2004;18(5):514-520. 263. Coselli JS, Bozinovski J, LeMaire SA. Open surgical repair of 2286 thoracoabdominal aortic aneurysms. Ann Thorac Surg. 2007;83(2):S862-S864. 264. Conrad MF, Crawford RS, Davison JK, Cambria RP. Thoracoabdominal aneurysm repair: a 20-year perspective. Ann Thorac Surg. 2007;83(2):S856-861. 265. Schepens MA, Kelder JC, Morshuis WJ, et al. Long-term follow-up after thoracoabdominal aortic aneurysm repair. Ann Thorac Surg. 2007;83(2):S851-S855. 266. Rigberg DA, McGory ML, Zingmond DS, et al. Thirty-day mortality statistics underestimate the risk of repair of thora-coabdominal aortic aneurysms: a statewide experience. J Vasc Surg. 2006;43(2):217-222. 267. Cowan JA, Jr, Dimick JB, Henke PK, et al. Surgical treatment of intact thoracoabdominal aortic aneurysms in the United States: hospital and surgeon volume-related outcomes. J Vasc Surg. 2003;37(6):1169-1174. 268. Wong DR, Parenti JL, Green SY, et al. Open repair of tho-racoabdominal aortic aneurysm in the modern surgical era: contemporary outcomes in 509 patients. J Am Coll Surg. 2011;212(4):569-579. 269. Coselli JS, LeMaire SA, Preventza O, et al. Outcomes of 3309 thoracoabdominal aortic aneurysm repairs. J Thorac Cardiovasc Surg. 2016;151(5):1323-1337. This report describes the largest experience with open repair of thoracoabdominal aortic aneurysm and focuses on factors associated with adverse outcomes. 270. Trimarchi S, Tolenaar JL, Tsai TT, et al. Influence of clini-cal presentation on the outcome of acute B aortic dissec-tion: evidences from IRAD. J Cardiovasc Surg (Torino). 2012;53(2):161-168. 271. Tsai TT, Fattori R, Trimarchi S, et al. Long-term survival in patients presenting with type B acute aortic dissection: insights from the International Registry of Acute Aortic Dissection. Circulation. 2006;114(21):2226-2231. 272. Slonim SM, Miller DC, Mitchell RS, et al. Percutaneous balloon fenestration and stenting for life-threatening isch-emic complications in patients with acute aortic dissection. J Thorac Cardiovasc Surg. 1999;117(6):1118-1126. 273. Dake MD, Kato N, Mitchell RS, et al. Endovascular stent-graft placement for the treatment of acute aortic dissection. N Engl J Med. 1999;340(20):1546-1552. 274. Eggebrecht H, Nienaber CA, Neuhauser M, et al. Endovascu-lar stent-graft placement in aortic dissection: a meta-analysis. Eur Heart J. 2006;27(4):489-498. 275. White RA, Miller DC, Criado FJ, et al. Report on the results of thoracic endovascular aortic repair for acute, complicated, type B aortic dissection at 30 days and 1 year from a multidisciplinary subcommittee of the Soci-ety for Vascular Surgery Outcomes Committee. J Vasc Surg. 2011;53(4):1082-1090. 276. Brunkwall J, Lammer J, Verhoeven E, Taylor P. ADSORB: a study on the efficacy of endovascular grafting in uncom-plicated acute dissection of the descending aorta. Eur J Vasc Endovasc Surg. 2012;44(1):31-36. 277. Brunkwall J, Kasprzak P, Verhoeven E, et al. Endovascular repair of acute uncomplicated aortic type B dissection pro-motes aortic remodelling: 1 year results of the ADSORB trial. Eur J Vasc Endovasc Surg. 2014;48(3):285-291.Brunicardi_Ch22_p0853-p0896.indd 89601/03/19 5:42 PM
Arterial DiseasePeter H. Lin, Carlos F. Bechara, Changyi Chen, and Frank J. Veith 23chapterGeneral Approach to the  Vascular Patient 898The Vascular History / 898The Vascular Physical Examination / 899Noninvasive Diagnostic Evaluation of the Vascular Patient / 899Radiologic Evaluation of the Vascular Patient / 900Preoperative Cardiac Evaluation / 903Basic Principles of  Endovascular Therapy 903Needles and Access / 904Guidewires / 904Hemostatic Sheaths / 905Catheters / 905Angioplasty Balloons / 905Stents / 905Stent Grafts / 906Carotid Artery Disease 907Epidemiology and Etiology of Carotid Occlusive Disease / 907Clinical Manifestations of Cerebral Ischemia / 907Diagnostic Evaluation / 909Treatment of Carotid Occlusive Disease / 910Carotid Endarterectomy Versus Angioplasty and Stenting / 911Surgical Techniques of Carotid Endarterectomy / 912Techniques of Carotid Angioplasty and Stenting / 914Nonatherosclerotic Disease of the Carotid Artery / 916Abdominal Aortic Aneurysm 919Causes and Risk Factors / 919Natural History of Aortic Aneurysm / 920Clinical Manifestations / 920Relevant Anatomy / 920Diagnostic Evaluation / 921Surgical Repair of Abdominal Aortic Aneurysm / 921Endovascular Repair of Abdominal Aortic Aneurysm / 922Results From Clinical Studies Comparing Endovascular Versus Open Repair / 925Classification and Management of Endoleak / 927Mesenteric Artery Disease 928Anatomy and Pathophysiology / 928Types of Mesenteric Artery Occlusive Disease / 929Clinical Manifestations / 930Diagnostic Evaluation / 930Surgical Repair / 932Endovascular Treatment / 933Clinical Results of Interventions for Mesenteric Ischemia / 934Renal Artery Disease 935Etiology / 935Clinical Manifestations / 936Diagnostic Evaluation / 936Treatment Indications / 937Surgical Reconstruction / 938Clinical Results of Surgical Repair / 938Endovascular Treatment / 938Clinical Results of Endovascular Interventions / 939Aortoiliac Occlusive Disease 940Diagnostic Evaluation / 941Differential Diagnosis / 941Collateral Arterial Network / 941Disease Classification / 941General Treatment Considerations / 943Surgical Reconstruction of Aortoiliac Occlusive Disease / 944Complications of Surgical Aortoiliac Reconstruction / 946Endovascular Treatment for Aortic Disease / 947Endovascular Treatment for Iliac Artery Disease / 948Complications of Endovascular Aortoiliac Interventions / 949Clinical Results Comparing Surgical and Endovascular Treatment of Aortoiliac Disease / 949Lower Extremity Arterial Occlusive  Disease 950Epidemiology / 950Diagnostic Evaluation / 950Differential Diagnosis / 951Lower Extremity Occlusive Disease Classification / 951Etiology of Acute Limb Ischemia / 952Clinical Manifestations of Acute Limb Ischemia / 954Treatment Considerations for Acute Limb Ischemia / 955Endovascular Treatment / 955Surgical Treatment / 956Complications Related to Treatment for Acute Limb Ischemia / 956Clinical Manifestations of Chronic Limb Ischemia / 958Treatment Considerations for Chronic Limb Ischemia / 959Endovascular Treatment / 960Complications of Endovascular Interventions / 965Surgical Treatment for Chronic Limb Ischemia due to Femoropopliteal Disease / 966Complications of Surgical Reconstruction / 966Choice of Conduit for Infrainguinal Bypass Grafting / 967Clinical Results of Surgical and Endovascular Interventions for Femoropopliteal Occlusive Disease / 968Nonatherosclerotic Disorders  of Blood Vessels 969Giant Cell Arteritis (Temporal Arteritis) / 969Takayasu’s Arteritis / 969Ehlers-Danlos Syndrome / 970Marfan’s Syndrome / 970Pseudoxanthoma Elasticum / 970Kawasaki’s Disease / 971Inflammatory Arteritis and Vasculitis / 971Behçet’s Disease / 971Polyarteritis Nodosa / 971Radiation-Induced Arteritis / 972Raynaud’s Syndrome / 972Fibromuscular Dysplasia / 972Nonatherosclerotic Disease Affecting the Popliteal Artery Disease / 973Buerger’s Disease (Thromboangiitis Obliterans) / 974Brunicardi_Ch23_p0897-p0980.indd 89727/02/19 4:13 PM 898Table 23-1Pertinent elements in vascular history• History of stroke or transient ischemic attack• History of coronary artery disease, including previous myocardial infarction and angina• History of peripheral arterial disease• History of diabetes• History of hypertension• History of tobacco use• History of hyperlipidemiaGENERAL APPROACH TO THE VASCULAR PATIENTSince the vascular system involves every organ system in our body, the symptoms of vascular disease are as varied as those encountered in any medical specialty. Lack of adequate blood supply to target organs typically presents with pain, for exam-ple, calf pain with lower extremity claudication, postprandial abdominal pain from mesenteric ischemia, and arm pain with axillo-subclavian arterial occlusion. In contrast, stroke and tran-sient ischemic attack (TIA) are the presenting symptoms from middle cerebral embolization as a consequence of a stenosed internal carotid artery. The pain syndrome of arterial disease is usually divided clinically into acute and chronic types, with all shades of severity between the two extremes. Sudden onset of pain can indicate complete occlusion of a critical vessel, leading to more severe pain and critical ischemia in the target organ, resulting in lower limb gangrene or intestinal infarction. Chronic pain results from a slower, more progressive atheroscle-rotic occlusion, which can be totally or partially compensated by developing collateral vessels. Acute on chronic is another pain pattern in which a patient most likely has an underlying arterial stenosis that suddenly occludes, for example, the patient with a history of calf claudication who now presents with sudden, severe acute limb-threatening ischemia. The clinician should always try to understand and relate the clinical manifestations to the underlying pathologic process.The Vascular HistoryAppropriate history should be focused based on the present-ing symptoms related to the vascular system (Table 23-1). Of particular importance in the previous medical history is noting prior vascular interventions (endovascular or open surgical), and all vascular patients should have inquiry made about their prior cardiac history and current cardiac symptoms. Approximately 30% of vascular patients will be diabetic. A history of prior and current smoking status should be noted.The patient with carotid disease in most cases is com-pletely asymptomatic, having been referred based on the find-ing of a cervical bruit or duplex finding of stenosis. Symptoms of carotid territory TIAs include transient monocular blindness (amaurosis), contralateral weakness or numbness, and dys-phasia. Symptoms persisting longer than 24 hours constitute a stroke. In contrast, the patient with chronic mesenteric isch-emia is likely to present with postprandial abdominal pain and weight loss. The patient fears eating because of the pain, avoids food, and loses weight. It is very unlikely that a patient with abdominal pain who has not lost weight has chronic mesenteric ischemia.The patient with lower extremity pain on ambulation has intermittent claudication that occurs in certain muscle groups; for example, calf pain upon exercise usually reflects superficial femoral artery disease, while pain in the buttocks reflects iliac disease. In most cases, the pain manifests in one muscle group below the level of the affected artery, occurs only with exercise, and is relieved with rest only to recur at the same location, hence the term “window gazer’s disease.” Rest pain (a manifestation of severe underlying occlusive disease) is constant and occurs in the foot (not the muscle groups), typically at the metatarso-phalangeal junction, and is relieved by dependency. Often the Key Points1 Carotid intervention as a preventive strategy should be per-formed in patients with 60% or greater symptomatic internal carotid artery stenosis and those with 80% or greater asymp-tomatic internal carotid artery stenosis. Carotid intervention for asymptomatic stenosis between 60% and 79% remains controversial. The modality of carotid intervention—carotid endarterectomy versus carotid stenting—remains contro-versial; currently, carotid endarterectomy appears to be associated with lower stroke rate with long term durability, whereas carotid stenting is more suitable under certain chal-lenging anatomic or physiologic conditions.2 Abdominal aortic aneurysms should be repaired when the risk of rupture, determined mainly by aneurysm size, exceeds the risk of death due to perioperative complications or concurrent illness. Endovascular repair is associated with less perioperative morbidity and mortality compared with open reconstruction and is preferred in patients with suitable anatomic morphology for stent-graft placement.3 Treatment objectives for symptomatic mesenteric ischemia are to improve quality of life and prevent bowel infarc-tion. Endovascular intervention with stenting has similar treatment efficacy comparative with less perioperative mor-bidity compared to open mesenteric bypass. Surgical recon-struction has a proven durability and patency rate compared with endovascular intervention.4 Aortoiliac occlusive disease can be treated with either endovascular means or open reconstruction, depending on patient risk stratification, occlusion characteristics, and symptomatology.5 Claudication is a marker of extensive atherosclerosis and is mainly managed with risk factor modification and pharma-cotherapy. Only 5% of patients with claudication will need intervention because of disabling extremity pain. The 5-year mortality of a patient with claudication approaches 30%. Patients with rest pain or tissue loss need expeditious evalu-ation and vascular reconstruction to ameliorate the severe extremity pain and prevent limb loss. Endovascular interven-tion is preferred as the first line of therapy for lower extrem-ity occlusive disease, whereas bypass reconstruction should be considered in failed endovascular therapy or long seg-ment femoropopliteal occlusive disease.Brunicardi_Ch23_p0897-p0980.indd 89827/02/19 4:13 PM 899ARTERIAL DISEASECHAPTER 23Table 23-2Grading scales for peripheral pulsesTRADITIONAL SCALEBASIC SCALE4+Normal2+Normal3+Slightly reduced1+Diminished2+Markedly reduced0Absent1+Barely palpable  patient is prompted to sleep with their foot hanging off one side of the bed to increase the hydrostatic pressure.The Vascular Physical ExaminationSpecific vascular examination should include abdominal aortic palpation, carotid artery examination, and pulse examination of the lower extremity (femoral, popliteal, posterior tibial, and dorsalis pedis arteries). The abdomen should be palpated for an abdominal aortic aneurysm, detected as an expansile pulse above the level of the umbilicus. It should also be examined for the presence of bruits. Because the aorta typically divides at the level of the umbilicus, an aortic aneurysm is most frequently palpable in the epigastrium. In thin individuals, a normal aortic pulsation is palpable, while in obese patients, even large aor-tic aneurysms may not be detectable. Suspicion of a clinically enlarged aorta should lead to the performance of an ultrasound scan for a more accurate definition of aortic diameter.The carotids should be auscultated for the presence of bruits, although there is a higher correlation with coronary artery disease than underlying carotid stenosis. A bruit at the angle of the mandible is a significant finding, leading to follow-up duplex scanning. The differential diagnosis is a transmitted murmur from a sclerotic or stenotic aortic valve. The carotid is palpable deep to the sternocleidomastoid muscle in the neck. Palpation, however, should be gentle and rarely yields clinically useful information.Upper extremity examination is necessary when an arte-riovenous graft is to be inserted in patients who have symptoms of arm pain with exercise. Thoracic outlet syndrome (TOS) can result in occlusion or aneurysm formation of the subclavian artery. Distal embolization is a manifestation of TOS; conse-quently, the fingers should be examined for signs of ischemia and ulceration. The axillary artery enters the limb below the middle of the clavicle, where it can be palpated in thin patients. It is usually easily palpable in the axilla and medial upper arm. The brachial artery is most easily located at the antecubital fossa immediately medial to the biceps tendon. The radial artery is palpable at the wrist anterior to the radius.For lower extremity vascular examination, the femoral pulse is usually palpable midway between the anterior supe-rior iliac spine and the pubic tubercle. The popliteal artery is palpated in the popliteal fossa with the knee flexed to 45° and the foot supported on the examination table to relax the calf muscles. Palpation of the popliteal artery is a bimanual tech-nique. Both thumbs are placed on the tibial tuberosity anteriorly, and the fingers are placed into the popliteal fossa between the two heads of the gastrocnemius muscle. The popliteal artery is palpated by compressing it against the posterior aspect of the tibia just below the knee. The posterior tibial pulse is detected by palpation 2 cm posterior to the medial malleolus. The dorsa-lis pedis is detected 1 cm lateral to the hallucis longus extensor tendon, which dorsiflexes the great toe and is clearly visible on the dorsum of the foot. Pulses can be graded using either the traditional four-point scale or the basic two-point scale system (Table 23-2). The foot should also be carefully examined for pallor on elevation and rubor on dependency, as these findings are indicative of chronic ischemia. Note should also be made of nail changes and loss of hair. Ulceration and other findings specific to disease states are described in relevant sections later in this chapter.After reconstructive vascular surgery, the graft may be available for examination, depending on its type and course. The in situ lower extremity graft runs in the subcutaneous fat and can be palpated along most of its length. A change in pulse quality, aneurysmal enlargement, or a new bruit should be care-fully noted. Axillofemoral grafts, femoral-to-femoral grafts, and arteriovenous access grafts can usually be easily palpated as well.Noninvasive Diagnostic Evaluation of the Vascular PatientAnkle-Brachial Index. There is increasing interest in the use of the ankle-brachial index (ABI) to evaluate patients at risk for cardiovascular events. An ABI less than 0.9 correlates with increased risk of myocardial infarction and indicates significant, although perhaps asymptomatic, underlying peripheral vascular disease. The ABI is determined in the following ways. Blood pressure is measured in both upper extremities using the high-est systolic blood pressure as the denominator for the ABI. The ankle pressure is determined by placing a blood pressure cuff above the ankle and measuring the return to flow of the posterior tibial and dorsalis pedis arteries using a pencil Doppler probe over each artery. The ratio of the systolic pressure in each ves-sel divided by the highest arm systolic pressure can be used to express the ABI in both the posterior tibial and dorsalis pedis arteries (Fig. 23-1). Normal is more than 1. Patients with clau-dication typically have an ABI in the 0.5 to 0.7 range, and those with rest pain are in the 0.3 to 0.5 range. Those with gangrene have an ABI of less than 0.3. These ranges can vary depending on the degree of compressibility of the vessel. The test is less reliable in patients with heavily calcified vessels. Due to non-compressibility, some patients, such as diabetics and those with end-stage renal disease, may have ABI ≥1.40 and require addi-tional noninvasive diagnostic testing to evaluate for peripheral artery disease. Alternative tests include toe-brachial pressures, pulse volume recordings, transcutaneous oxygen measurements, or vascular imaging (duplex ultrasound).Segmental Limb Pressures. By placing serial blood pressure cuffs down the lower extremity and then measuring the pressure with a Doppler probe as flow returns to the artery below the cuff, it is possible to determine segmental pressures down the leg. This data can then be used to infer the level of the occlu-sion. The systolic pressure at each level is expressed as a ratio, with the highest systolic pressure in the upper extremities as the denominator. Normal segmental pressures commonly show high thigh pressures 20 mmHg or greater in comparison to the brachial artery pressures. The low thigh pressure should be equivalent to brachial pressures. Subsequent pressures should fall by no more than 10 mmHg at each level. A pressure gradient of 20 mmHg between two subsequent levels is usually indica-tive of occlusive disease at that level. The most frequently used index is the ratio of the ankle pressure to the brachial pressure, Brunicardi_Ch23_p0897-p0980.indd 89927/02/19 4:13 PM 900SPECIFIC CONSIDERATIONSPART IIFigure 23-1. Calculating the ankle-brachial index (ABI).Right ABI = ratio ofHigher of the right ankle systolic pressures (posterior tibial or dorsalis pedis)Higher arm systolic pressure (left or right arm)Left ABI = ratio ofHigher of the left ankle systolic pressures (posterior tibial or dorsalis pedis)Higher arm systolic pressure (left or right arm)the ABI. Normally, the ABI is greater than 1.0, and a value of less than 0.9 indicates some degree of arterial obstruction and has been shown to be correlated with an increased risk of coronary heart disease. Limitations of relying on segmental limb pressures include: (a) missing isolated moderate stenoses (usually iliac) that produce little or no pressure gradient at rest; (b) falsely elevated pressures in patients with diabetes and end-stage renal disease; and (c) the inability to differentiate between stenosis and occlusion.1 Patients with diabetes and end-stage renal disease have calcified vessels that are difficult to com-press, thus rendering this method inaccurate, due to recording of falsely elevated pressure readings. Noncompressible arter-ies yield ankle systolic pressures ≥250 mmHg and ABIs >1.40. In this situation, absolute toe and ankle pressures can be mea-sured to gauge critical limb ischemia. Ankle pressures less than  50 mmHg or toe pressures less than 30 mmHg are indica-tive of critical limb ischemia. The toe pressure is normally  30 mmHg less than the ankle pressure, and a toe-brachial index (TBI) <0.70 is abnormal. False-positive results with the TBI are unusual. The main limitation of this technique is that it may be impossible to measure pressures in the first and second toes due to preexisting ulceration.Pulse Volume Recording. In patients with noncompressible vessels, segmental plethysmography can be used to determine underlying arterial occlusive disease. Cuffs placed at different levels on the leg detect changes in blood volume and produce a pulse volume recording (PVR) when connected to a plethysmo-graph (Fig. 23-2). To obtain accurate PVR waveforms, the cuff is inflated to 60 to 65 mmHg, so as to detect volume changes without causing arterial occlusion. Pulse volume tracings are suggestive of proximal disease if the upstroke of the pulse is not brisk, the peak of the wave tracing is rounded, and there is disappearance of the dicrotic notch.Although isolated segmental limb pressures and PVR mea-surements are 85% accurate when compared with angiography in detecting and localizing significant atherosclerotic lesions, when used in combination, accuracy approaches 95%.2 For this reason, it is suggested that these two diagnostic modalities be used in combination when evaluating peripheral artery disease.Radiologic Evaluation of the Vascular PatientUltrasound. Ultrasound examinations are relatively time consuming, require experienced technicians, and may not visu-alize all arterial segments. Doppler waveform analysis can sug-gest atherosclerotic occlusive disease if the waveforms in the insonated arteries are biphasic, monophasic, or asymmetrical. B-mode ultrasonography provides black and white, real-time images. B-mode ultrasonography does not evaluate blood flow; thus, it cannot differentiate between fresh thrombus and flow-ing blood, which have the same echogenicity. Calcification in atherosclerotic plaques will cause acoustic shadowing. B-mode ultrasound probes cannot be sterilized. Use of the B-mode probe intraoperatively requires a sterile covering and gel to maintain an acoustic interface. Experience is needed to obtain and interpret images accurately. Duplex ultrasonography entails performance of B-mode imaging, spectral Doppler scanning, and color-flow duplex scanning. The caveat to performance of duplex ultraso-nography is meticulous technique by a certified vascular ultra-sound technician, so that the appropriate 60° Doppler angle is maintained during insonation with the ultrasound probe. Altera-tion of this angle can markedly alter waveform appearance and subsequent interpretation of velocity measurements. Direct imaging of intra-abdominal vessels with duplex ultrasound is less reliable because of the difficulty in visualizing the vessels through overlying bowel. These disadvantages currently limit the applicability of duplex scanning in the evaluation of aortoil-iac and infrapopliteal disease. A clinical study has shown that duplex ultrasonography had lower sensitivity in the calculation of infrapopliteal vessel stenosis in comparison to conventional digital subtraction or computed tomography angiography.3 Few surgeons rely solely on duplex ultrasonography for preopera-tive planning in lower extremity revascularizations; but with experience, lower extremity arteries can be insonated to deter-mine anatomy, and the functional significance of lesions can be determined by calculation of degree of stenosis from velocity ratios. Duplex scanning is unable to evaluate recently implanted polytetrafluoroethylene (PTFE) and polyester (Dacron) grafts because they contain air, which prevents ultrasound penetration.Computed Tomography Angiography. Computed tomogra-phy angiography (CTA) is a noninvasive, contrast-dependent method for imaging the arterial system. It depends on intrave-nous infusion of iodine-based contrast agents. The patient is advanced through a rotating gantry, which images serial trans-verse slices. The contrast-filled vessels can be extracted from the slices and rendered in three-dimensional format (Fig. 23-3). Brunicardi_Ch23_p0897-p0980.indd 90027/02/19 4:13 PM 901ARTERIAL DISEASECHAPTER 23Figure 23-2. Typical report of peripheral vascular study with arterial segmental pressure measurement plus Doppler evaluation of the lower extremity.Femoral0.750.500.250.000.25Sup.femoral1.501.000.500.000.50Popliteal1.501.000.500.000.50Posteriortibial1.501.000.500.000.50Dorsalispedis0.750.500.250.000.250.75Femoral0.500.250.000.25Popliteal0.750.500.250.000.25Posteriortibial0.750.500.250.000.25Dorsalispedis0.750.500.250.000.25Sup.femoral0.750.500.250.250.00149Brachial0.66U. thighL. thighCalfAnkle-PTAnkle-DPToe0.770.741.011.051.011.050.700.730.660.620.59Indexes144RightLeftDoppler waveforms1 sec/div15715015710910599PT 98DT 92PT 151DT 11111488ABFigure 23-3. A multidetector computed tomography angiography with three-dimensional reconstruction of the iliofemoral arterial circulation in two patients with lower leg claudication. A. A 50-year-old man with an occluded right superficial femoral artery (single long arrow) with reconstituted superficial femoral artery at the level of mid-thigh. Arterial calcifications (single short arrows) are present in the bilateral distal superficial femoral arteries. B. A 53-year-old man with occluded right common iliac artery (double arrows).The extracted images can also be rotated and viewed from sev-eral different directions during postacquisition image process-ing. This technology has been advanced as a consequence of aortic endografting. CTA provides images for postprocessing that can be used to display the aneurysm in a format that demon-strates thrombus, calcium, lumen, and the outer wall, and allows “fitting” of a proposed endograft into the aneurysm (Fig. 23-4). CTA is increasingly being used to image the carotid bifurca-tion, and as computing power increases, the speed of image acquisition and resolution will continue to increase. The major limitations of multidetector CTA are use of contrast and pres-ence of artifacts caused by calcification and stents. CTA can Brunicardi_Ch23_p0897-p0980.indd 90127/02/19 4:13 PM 902SPECIFIC CONSIDERATIONSPART IIFigure 23-4. Three-dimensional computed tomog-raphy angiogram of an abdominal aortic aneurysm that displays various aneurysm components including thrombus, aortic calcification, blood circulation, and aneurysm wall.Figure 23-5. Magnetic resonance angiogram of aortic arch and carotid arteries. This study can provide a three-dimensional analysis of vascular structure such as aortic arch branches and carotid and vertebral arteries.overestimate the degree of in-stent stenosis, while heavy calci-fication can limit the diagnostic accuracy of the method by caus-ing a “blooming artifact.”4 The artifacts can be overcome with alteration in image acquisition technique. There are no random-ized trials to document the superiority of multidetector CTA over traditional angiography, but there is emerging evidence to support the claim that multidetector CTA has sensitivity, speci-ficity, and accuracy that rival invasive angiography.4Magnetic Resonance Angiography. Magnetic resonance angiography (MRA) has the advantage of not requiring iodin-ated contrast agents to provide vessel opacification (Fig. 23-5). Gadolinium is used as a contrast agent for MRA studies, and because it is generally not nephrotoxic, it can be used in patients with elevated creatinine. MRA is contraindicated in patients with pacemakers, defibrillators, spinal cord stimulators, intrace-rebral shunts, cochlear implants, and cranial clips. Patients with claustrophobia may require sedation to be able to complete the test. The presence of metallic stents causes artifacts and signal drop-out; however, these can be dealt with using alternations in image acquisition and processing. Nitinol stents produce mini-mal artifact. Compared to other modalities, MRA is relatively slow and expensive. However, due to its noninvasive nature and decreased nephrotoxicity, MRA is being used more frequently for imaging vasculature in various anatomic distributions.Diagnostic Angiography. Diagnostic angiography is consid-ered the gold standard in vascular imaging. In many centers, its use is rapidly decreasing due to the development of noninvasive imaging modalities such as duplex arterial mapping, CTA, and MRA. Nevertheless, contrast angiography still remains in wide-spread use. The essential aspects of angiography are vascular access and catheter placement in the vascular bed that requires examination. The imaging system and the contrast agent are used to opacify the target vessel. Although in the past this func-tion has largely been delegated to the interventional radiology service, an increasing number of surgeons are performing this procedure and following the diagnostic imaging with immediate surgical or endovascular intervention. There are several consid-erations when relying on angiography for imaging.Approximately 70% of atherosclerotic plaques occur in an eccentric location within the blood vessel; therefore, images can be misleading when trying to evaluate stenoses because angiog-raphy is limited to a uniplanar “lumenogram.” With increased use of intravascular stent deployment, it has also been noted that assessment of stent apposition and stent position in rela-tion to surrounding branches may be inaccurate. Furthermore, angiography exposes the patient to the risks of both ionizing radiation and intravascular contrast. Nevertheless, contrast angi-ography remains the most common invasive method of vascular investigation for both diagnostic and therapeutic intervention. The angiogram usually provides the final information needed to decide whether or not to proceed with operation or endovascular interventions.Digital subtraction angiography (DSA) offers some advan-tages over conventional cut-film angiography such as excellent visualization despite use of lower volumes of contrast media. In particular, when multilevel occlusive lesions limit the amount of contrast reaching distal vessels, supplemental use of digital sub-traction angiographic techniques may enhance visualization and definition of anatomy. Intra-arterial DSA uses a portable, axially Brunicardi_Ch23_p0897-p0980.indd 90227/02/19 4:13 PM 903ARTERIAL DISEASECHAPTER 23Figure 23-6. Digital subtraction angiography (DSA) provides excellent visualization of intravascular circulation with intra-arterial contrast administration. As depicted in this DSA study, multilevel lesions are demonstrated, which include a focal left iliac artery stenosis (large arrow), right superficial femoral occlusion (curved arrows), left superficial femoral stenosis (small arrow), and mul-tiple tibial artery stenoses (arrowheads).rotatable imaging device that can obtain views from different angles. DSA also allows for real-time video replay (Fig. 23-6). An entire extremity can be filmed with DSA using repeated injections of small amounts of contrast agent to obtain sequen-tial angiographic images, the so-called pulse-chase technique.Preoperative Cardiac EvaluationThe most important and most controversial aspect of preopera-tive evaluation in patients with atherosclerotic disease requiring surgical intervention is the detection and subsequent manage-ment of associated coronary artery disease. Several studies have documented the existence of significant coronary artery disease in 40% to 50% or more of patients requiring peripheral vascular reconstructive procedures, 10% to 20% of whom may be relatively asymptomatic largely because of their inability to exercise.5 Myocardial infarction is responsible for the major-ity of both early and late postoperative deaths. Most available screening methods lack sensitivity and specificity to predict postoperative cardiac complications. There have been conflict-ing reports regarding the utility of preoperative dipyridamole-thallium nuclear imaging or dobutamine-echocardiography to stratify vascular patients in terms of perioperative cardiac mor-bidity and mortality. In nearly half of patients, thallium imaging proves to be unnecessary because cardiac risk can be predicted by clinical information alone.6 Even with coronary angiography, it is difficult to relate anatomic findings to functional signifi-cance and, hence, surgical risk. There are no data confirming that percutaneous coronary interventions or surgical revascu-larization prior to vascular surgical procedures impact mortality or incidence of myocardial infarctions. In fact, coronary angi-ography is associated with its own inherent risks, and patients undergoing coronary artery bypass grafting or coronary percuta-neous transluminal angioplasty (PTA) before needed aortoiliac reconstructions are subjected to the risks and complications of both procedures.The Coronary Artery Revascularization Prophylaxis (CARP) trial showed that coronary revascularization in patients with peripheral vascular disease and significant coronary artery disease, who are considered high risk for perioperative com-plications, did not reduce overall mortality or perioperative myocardial infarction.7 Additionally, patients who underwent prophylactic coronary revascularization had significant delays prior to undergoing their vascular procedure and increased limb morbidity compared to patients who did not. Studies do support improvement in cardiovascular and overall prognosis with med-ical optimization of patients.8 Therefore, use of perioperative β-blockade, as well as use of antiplatelet medication, statins, and angiotensin-converting enzyme inhibitors, is encouraged in vascular patients.BASIC PRINCIPLES OF ENDOVASCULAR THERAPYCardiovascular disease remains a major cause of mortality in the developed world since the beginning of the 21st century. Although surgical revascularization has played a predominant role in the management of patients with vascular disease, the modern treatment paradigms have evolved significantly with increased emphasis of catheter-based percutaneous interven-tions over the past two decades. The increasing role of this mini-mally invasive vascular intervention is fueled by various factors, including rapid advances in imaging technology, reduced mor-bidity and mortality in endovascular interventions, and faster convalescence following percutaneous therapy when compared to traditional operations. There is little doubt that with continued device development and refined image-guided technology, endo-vascular intervention will provide improved clinical outcomes and play an even greater role in the treatment of vascular disease.The technique of percutaneous access for both the diagnos-tic and therapeutic management of vascular disease has resulted in tremendous changes in the practice of several subspecialties, including interventional radiology, invasive cardiology, and vas-cular surgery. The development of catheter and endoscopic instru-mentation allows the vascular surgeon to operate via an intraor extraluminal route. Endovascular techniques are now able to treat the full spectrum of vascular pathology, including stenoses and occlusions resulting from several etiologies, aneurysmal pathol-ogy, and traumatic lesions. Many of these procedures have only recently been developed and, as such, have not been investigated Brunicardi_Ch23_p0897-p0980.indd 90327/02/19 4:13 PM 904SPECIFIC CONSIDERATIONSPART IIFigure 23-7. A. Antegrade femoral artery access. The needle is inserted just below the inguinal ligament in the common femoral artery whereby the guidewire is inserted in the ipsilateral super-ficial femoral artery. B. Brachial artery approach. The needle is inserted in a retrograde fashion in the brachial artery just above the antecubital fossa, whereby the guidewire is next inserted in the brachial artery.in a manner that would enable an accurate comparison with the more traditional methods of open surgical intervention. Long-term follow-up for these procedures is frequently lacking; how-ever, because of the potential to treat patients with decreased mortality and morbidity, endovascular skills and techniques are being adopted into mainstream vascular surgery.Needles and AccessNeedles are used to achieve percutaneous vascular access. The size of the needle will be dictated by the diameter of the guide-wire used. Most often, an 18-gauge needle is used, as it will accept a 0.035-inch guidewire. A 21-gauge micropuncture nee-dle will accept a 0.018-inch guidewire. The most popular access needle is the Seldinger needle, which can be used for singleand double-wall puncture techniques.Femoral arterial puncture is the most common site for access. The common femoral artery (CFA) is punctured over the medial third of the femoral head, which is landmarked using flu-oroscopy. The single-wall puncture technique requires a sharp, beveled needle tip and no central stylet. The anterior wall of the vessel is punctured with the bevel of the needle pointing up, and pulsatile back-bleeding indicates an intraluminal position. This method is most useful for graft punctures, patients with abnor-mal clotting profiles, or if thrombolytic therapy is anticipated. Once the needle assumes an intraluminal position, verified by pulsatile back-bleeding, the guidewire may be advanced. This is always passed gently and under fluoroscopic guidance to avoid subintimal dissection or plaque disruption. Double-wall puncture techniques are performed with a blunt needle that has a remov-able inner cannula. The introducer needle punctures both walls of the artery and is withdrawn until bleeding is obtained to confirm intraluminal position prior to advancing a guidewire. There can be troublesome bleeding from the posterior arterial wall punc-ture; therefore, single puncture techniques are preferred.Retrograde femoral access is the most common arte-rial access technique (Fig. 23-7). The advantages of this technique include the size and fixed position of the CFA, as well as the relative ease of compression against the femoral head at the end of the procedure. Care should be taken to avoid puncturing the external iliac artery above the inguinal ligament because this can result in retroperitoneal hemor-rhage secondary to ineffective compression of the puncture site. Likewise, puncturing too low, at or below the CFA bifurcation, can result in thrombosis or pseudoaneurysm for-mation of the superficial femoral artery (SFA) or profunda femoris artery (PFA). Antegrade femoral access is more dif-ficult than retrograde femoral access, and there is a greater tendency to puncture the SFA, but it is invaluable when the aortic bifurcation cannot be traversed or when devices are not long enough to reach a lesion from a contralateral femo-ral access approach. Occasionally, when the distal aorta or bilateral iliac arteries are inaccessible because of the extent of atherosclerotic lesions, scarring, or presence of bypass conduits, the brachial artery must be used to obtain access for diagnostic and therapeutic interventions. The left bra-chial artery is punctured because this avoids the origin of the carotid artery and thus decreases the risk of catheter-related emboli to the brain. The artery is accessed with a micropunc-ture needle just proximal to the antecubital crease. The use of brachial access is associated with a higher risk of thrombosis and nerve injuries than femoral access.GuidewiresGuidewires are used to introduce, position, and exchange cath-eters. A guidewire generally has a flexible and stiff end. In general, only the flexible end of the guidewire is placed in the vessel. All guidewires are composed of a stiff inner core and an outer tightly coiled spring that allows a catheter to track over the guidewire. There are five essential characteristics of guidewires: size, length, stiffness, coating, and tip configuration.Guidewires come in different maximum transverse diam-eters, ranging from 0.011 to 0.038 inches. For most aortoiliac procedures, a 0.035-inch wire is most commonly used, whereas the smaller diameter 0.018-inch guidewires are reserved for selective small vessel angiography such as infrageniculate or carotid lesions. In addition to diameter size, guidewires come in varying lengths, usually ranging from 180 to 260 cm in length. Increasing the length of the wire always makes it more difficult to handle and increases the risk of contamination. While per-forming a procedure, it is important to maintain the guidewire across the lesion until the completion arteriogram has been sat-isfactorily completed.The stiffness of the guidewire is also an important charac-teristic. Stiff wires allow for passage of large aortic stent graft devices without kinking. They are also useful when trying to perform sheath or catheter exchanges around a tortuous artery. An example of a stiff guidewire is the Amplatz wire. Hydro-philic coated guidewires, such as the Glidewire, have become invaluable tools for assisting in difficult catheterizations. The coating is primed by bathing the guidewire in saline solution. The slippery nature of this guidewire along with its torque capa-bility significantly facilitate in difficult catheterizations. Guide-wires also come in various tip configurations. Angled tip wires like the angled Glidewire can be steered to manipulate a catheter across a tight stenosis or to select a specific branch of a vessel. The Rosen wire has a soft curled end, which makes it ideal for renal artery stenting. The soft curl of this wire prevents it from perforating small renal branch vessels.Brunicardi_Ch23_p0897-p0980.indd 90427/02/19 4:13 PM 905ARTERIAL DISEASECHAPTER 23Figure 23-8. All percutaneous endovascular procedures are per-formed through an introducer sheath (large arrow), which pro-vides an access conduit from skin to intravascular compartment. The sheath also acts to protect the vessel from injury as guidewires (small arrows) and catheters are introduced.Hemostatic SheathsThe hemostatic sheath is a device through which endovascular procedures are performed. The sheath acts to protect the vessel from injury as wires and catheters are introduced (Fig. 23-8). A one-way valve prevents bleeding through the sheath, and a side-port allows contrast or heparin flushes to be administered during the procedure. Sheaths are sized by their inner diameter. The most commonly used sheaths for percutaneous access have a 5to 9-French inner diameter, but with open surgical exposure of the CFA, sheaths as large as 26 French can be introduced. Sheaths also vary in length, and long sheaths are available so that interventions remote from the site of arterial access can be performed.CathetersA wide variety of catheters exist that differ primarily in the con-figuration of the tip. The multiple shapes permit access to ves-sels of varying dimensions and angulations. Catheters are used to perform angiography and protect the passage of balloons and stents, and they can be used to direct the guidewire through tight stenoses or tortuous vessels.Figure 23-9. A. An artery with luminal narrowing caused by plaque. B. A balloon angioplasty catheter is positioned within the diseased artery, which is inflated to enlarge the intravascular channel. C. The plaque is compressed with widened flow lumen as the result of balloon angioplasty.Angioplasty BalloonsAngioplasty balloons differ primarily in their length and diam-eter, as well as the length of the catheter shaft. As balloon technology has advanced, lower profiles have been manufac-tured (i.e., the size that the balloon assumes upon deflation). Balloons are used to perform angioplasty on vascular stenoses, to deploy stents, and to assist with additional expansion after insertion of self-expanding stents (Fig. 23-9). Besides length and diameter, operators need to be familiar with several other balloon characteristics. Noncompliant and low-compliance balloons tend to be inflated to their preset diameter and offer greater dilating force at the site of stenosis. Low-compliance balloons are the mainstay for peripheral intervention. Lower profile balloons are less likely to get caught during passage through stents and are easier to pull out of sheaths. Under fluoroscopic guidance, balloon inflation is performed until the waist of the atherosclerotic lesion disappears and the balloon is at the full profile. The duration of balloon inflation and pres-sures used for the angioplasty depend on the indication for the intervention and the location and characteristics of the lesion being treated. Frequently, several inflations are required to achieve a full profile of the balloon. Occasionally, a lower pro-file balloon is needed to predilate the tight stenosis so that the selected balloon catheter can cross the lesion. After inflation, most balloons do not regain their preinflation diameter and assume a larger profile. Trackability, pushability, and cross-ability of the balloon should all be considered when choosing a particular balloon. Lastly, shoulder length is an important characteristic to consider when selecting a balloon because of the potential to cause injury during performance of PTA in adjacent arterial segments. There is always risk of causing dis-section or rupture during PTA; thus, a completion angiogram is performed while the wire is still in place. Leaving the wire in place provides access for repeating the procedure, placing a stent or stent graft if warranted.StentsVascular stents are commonly used after an inadequate angio-plasty with dissection or elastic recoil of an arterial stenosis. They serve to buttress collapsible vessels and help prevent atherosclerotic restenosis. Appropriate indications for primary stenting of a lesion without an initial trial of angioplasty alone are evolving in manners that are dependent on the extent and site of the lesion. Stents are manufactured from a variety of metals including stainless steel, tantalum, cobalt-based alloy, Brunicardi_Ch23_p0897-p0980.indd 90527/02/19 4:13 PM 906SPECIFIC CONSIDERATIONSPART IIFigure 23-10. Self-expanding stents are made of tempered stainless steel or nitinol, an alloy of nickel and titanium, and are restrained when folded inside a delivery catheter. After being released from the restraining catheter, the self-expanding stents will expand to a final diameter that is determined by stent geometry, hoop strength, and vessel size.Figure 23-11. In a balloon-expandable stent, the stent is pre-mounted on a balloon catheter. The balloon stretches the stent members beyond their elastic limit. The stent is deployed by full balloon expansion. This type of stent has a higher degree of crush resistance when compared to self-expanding stents, which is ideal for short-segment calcified ostial lesions.and nitinol. Vascular stents are classified into two basic categories: balloon-expandable stents and self-expanding stents.Self-expanding stents (Fig. 23-10) are deployed by retract-ing a restraining sheath and usually consist of Elgiloy (a cobalt, chromium, nickel alloy) or nitinol (a shape memory alloy com-posed of nickel and titanium), the latter of which will contract and assume a heat-treated shape above a transition temperature that depends on the composition of the alloy. Self-expanding stents will expand to a final diameter that is determined by stent geometry, hoop strength, and vessel size. The self-expanding stent is mounted on a central shaft and is placed inside an outer sheath. It relies on a mechanical spring-like action to achieve expansion. With deployment of these stents, there is some degree of foreshortening that has to be taken into account when choosing the area of deployment. In this way, self-expanding stents are more difficult to place with absolute precision. There are several advantages related to self-expanding stents. Self-expanding stents generally come in longer lengths than balloon-expandable stents and are therefore used to treat long and tortuous lesions. Their ability to continually expand after deliv-ery allows them to accommodate adjacent vessels of different size. This makes these stents ideal for placement in the internal carotid artery. These stents are always oversized by 1 to 2 mm relative to the largest diameter of normal vessel adjacent to the lesion in order to prevent immediate migration.Balloon-expandable stents are usually composed of stain-less steel, mounted on an angioplasty balloon, and deployed by balloon inflation (Fig. 23-11). They can be manually placed on a chosen balloon catheter or obtained premounted on a balloon catheter. The capacity of a balloon-expandable stent to shorten in length during deployment depends on both stent geometry and the final diameter to which the balloon is expanded. These stents are more rigid and are associated with a shorter time to complete endothelialization. They are often of limited flexibility and have a higher degree of crush resistance when compared to self-expanding stents. This makes them ideal for short-segment lesions, especially those that involve the ostia such as proximal common iliac or renal artery stenosis.An important area of evolution in endovascular therapy in recent years is the development of drug-eluting stents (DES). These stents are usually composed of nitinol and have vari-ous anti-inflammatory drugs bonded to them. Over time, the stents release the drug into the surrounding arterial wall and help prevent restenosis. Numerous randomized controlled trials have proven their benefit in coronary arteries.9 Clinical studies have similarly proved early efficacy of DES in the treatment of peripheral arterial disease.10Stent GraftsThe combination of a metal stent covered with fabric gave birth to the first stent grafts. Covered stents have been designed with either a surrounding PTFE or polyester fabric and have been used predominantly for treatment of traumatic vascular lesions, including arterial disruption and arteriovenous fistulas  (Fig. 23-12). However, these devices may well find a growing role in treatment of iliac or femoral arterial occlusive disease as well as popliteal aneurysms.Endovascular aneurysm repair using the concept of stent grafts was initiated by Parodi in 1991.11 Since that time, a large number of endografts have been inserted under the auspice of clinical trials initially and now as Food and Drug Administra-tion (FDA)–approved devices. Currently there are more than Brunicardi_Ch23_p0897-p0980.indd 90627/02/19 4:13 PM 907ARTERIAL DISEASECHAPTER 23Figure 23-12. A stent graft is a metal stent covered with fabric that is com-monly used for aneurysm exclusion.eight FDA-approved endovascular devices for abdominal aortic aneurysm repair. In general, majority of these devices require that patients have an infrarenal aneurysm with at least a 15-mm proximal aortic neck below the renal arteries and not greater than 60° of angulation. For those patients with associated com-mon iliac artery aneurysmal disease, endovascular treatment can be achieved by initial coil embolization of the ipsilateral hypogastric artery with extension of the endovascular device into the external iliac artery. Newer generation devices with branched endograft can be deployed in the internal iliac artery while maintain in-line flow from the common iliac to exter-nal iliac artery to exclude the common iliac artery aneurysm. Recent clinical trials have demonstrated clinical efficacy of fenestrated aortic endograft in treating aneurysm involving the visceral segment of the abdominal aorta.12 The FDA has simi-larly approved several thoracic endograft devices for the treat-ment of descending thoracic aortic aneurysm. Clinical studies have similarly demonstrated durability and efficacy of thoracic aortic devices in patients with traumatic aortic transections and aortic dissections.13CAROTID ARTERY DISEASEAtherosclerotic occlusive plaque is by far the most common pathology seen in the carotid artery bifurcation. Thirty percent to 60% of all ischemic strokes are related to atherosclerotic carotid bifurcation occlusive disease. In the following section, we first focus our discussion on the clinical presentation, diagnosis, and management—including medical therapy, surgical carotid end-arterectomy, and stenting—of atherosclerotic carotid occlusive disease. In the second part of the section, we provide a review on other less common nonatherosclerotic diseases involving the extracranial carotid artery, including kink and coil, fibromuscu-lar dysplasia, arterial dissection, aneurysm, radiation arteritis, Takayasu’s arteritis, and carotid body tumor.Epidemiology and Etiology of Carotid Occlusive DiseaseApproximately 700,000 Americans suffer a new or recur-rent stroke each year.14 Eighty-five percent of all strokes are ischemic, and 15% are hemorrhagic. Hemorrhagic strokes are caused by head trauma or spontaneous disruption of intracere-bral blood vessels. Ischemic strokes are due to hypoperfusion from arterial occlusion or, less commonly, to decreased flow resulting from proximal arterial stenosis and poor collateral network. Common causes of ischemic strokes are cardiogenic emboli in 35%, carotid artery disease in 30%, lacunar in 10%, miscellaneous in 10%, and idiopathic in 15%.19 The term cere-brovascular accident is often used interchangeably to refer to an ischemic stroke. A transient ischemic attack (TIA) is defined as a temporary focal cerebral or retinal hypoperfusion state that resolves spontaneously within 24 hours after its onset. However, the majority of TIAs resolve within minutes, and longer-lasting neurologic deficits more likely represent a stroke. Recently, the term brain attack has been coined to refer to an acute stroke or TIA, denoting the condition as a medical emergency requiring immediate attention, similar to a heart attack.Stroke due to carotid bifurcation occlusive disease is usu-ally caused by atheroemboli (Fig. 23-13). The carotid bifurca-tion is an area of low flow velocity and low shear stress. As the blood circulates through the carotid bifurcation, there is separa-tion of flow into the low-resistance internal carotid artery and the high-resistance external carotid artery. Characteristically, atherosclerotic plaque forms in the outer wall opposite to the flow divider (Fig. 23-14). Atherosclerotic plaque formation is complex, beginning with intimal injury, platelet deposition, smooth muscle cell proliferation, and fibroplasia, and leading to subsequent luminal narrowing. With increasing degree of ste-nosis in the internal carotid artery, flow becomes more turbu-lent, and the risk of atheroembolization escalates. The severity of stenosis is commonly divided into three categories accord-ing to the luminal diameter reduction: mild (<50%), moderate (50–69%), and severe (70–99%). Severe carotid stenosis is a strong predictor for stroke.15 In turn, a prior history of neuro-logic symptoms (TIA or stroke) is an important determinant for recurrent ipsilateral stroke. The risk factors for the development of carotid artery bifurcation disease are similar to those causing atherosclerotic occlusive disease in other vascular beds. Increas-ing age, male gender, hypertension, tobacco smoking, diabetes mellitus, homocysteinemia, and hyperlipidemia are well-known predisposing factors for the development of atherosclerotic occlusive disease.Clinical Manifestations of Cerebral IschemiaTIA is a focal loss of neurologic function, lasting for less than  24 hours. Crescendo TIAs refer to a syndrome comprising repeated TIAs within a short period of time that is character-ized by complete neurologic recovery in between. At a minimum, the term should probably be reserved for those with either daily events or multiple resolving attacks within 24 hours. Brunicardi_Ch23_p0897-p0980.indd 90727/02/19 4:13 PM 908SPECIFIC CONSIDERATIONSPART IIFigure 23-14. A. The carotid bifurcation is an area of low flow velocity and low shear stress. As the blood circulates through the carotid bifurcation, there is separation of flow into the low-resistance internal carotid artery and the high-resistance external carotid artery.  B. The carotid atherosclerotic plaque typi-cally forms in the outer wall opposite to the flow divider due in part to the effect of the low shear stress region, which also creates a tran-sient reversal of flow during the cardiac cycle.InternalcarotidarteryEmboliUlcerPlaqueCommoncarotidarteryExternalcarotidarterySuperiorthyroidarteryFigure 23-13. Stroke due to carotid bifurcation occlusive disease is usually caused by atheroemboli arising from the internal carotid artery, which provides the majority of blood flow to the cerebral hemisphere. With increasing degree of stenosis in the carotid artery, flow becomes more turbulent, and the risk of atheroembolization escalates.BASectional viewLow-shearregionHigh-shearregionHemodynamic TIAs represent focal cerebral events that are aggravated by exercise or hemodynamic stress and typically occur after short bursts of physical activity, postprandially, or after getting out of a hot bath. It is implied that these are due to severe extracranial disease and poor intracranial collateral recruitment. Reversible ischemic neurologic deficits refer to ischemic focal neurologic symptoms lasting longer than 24 hours but resolv-ing within 3 weeks. When a neurologic deficit lasts longer than  3 weeks, it is considered a completed stroke. Stroke in evolution refers to progressive worsening of the neurologic deficit, either linearly over a 24-hour period or interspersed with transient periods of stabilization and/or partial clinical improvement.Patients who suffer cerebrovascular accidents typically present with three categories of symptoms including ocular symptoms, sensory/motor deficit, and/or higher cortical dys-function. The common ocular symptoms associated with extra-cranial carotid artery occlusive disease include amaurosis fugax and presence of Hollenhorst plaques. Amaurosis fugax, com-monly referred to as transient monocular blindness, is a tempo-rary loss of vision in one eye that patients typically describe as a window shutter coming down or grey shedding of the vision. This partial blindness usually lasts for a few minutes and then resolves. Most of these phenomena (>90%) are due to embolic occlusion of the main artery or the upper or lower divisions. Monocular blindness progressing over a 20-minute period sug-gests a migrainous etiology. Occasionally, the patient will recall no visual symptoms while the optician notes a yellowish plaque within the retinal vessels, which is also known as Hollenhorst plaque. These plaques are frequently derived from cholesterol embolization from the carotid bifurcation and warrant further investigation. Additionally, several ocular symptoms may be caused by microembolization from extracranial carotid dis-eases including monocular visual loss due to retinal artery or optic nerve ischemia, the ocular ischemia syndrome, and visual field deficits secondary to cortical infarction and ischemia of the optic tracts. Typical motor and/or sensory symptoms asso-ciated with cerebrovascular accidents are lateralized or focal neurologic deficits. Ischemic events tend to have an abrupt onset, with the severity of the insult being apparent from the onset and not usually associated with seizures or paresthesia. In contrast, they represent loss or diminution of neurologic func-tion. Furthermore, motor or sensory deficits can be unilateral or Brunicardi_Ch23_p0897-p0980.indd 90827/02/19 4:14 PM 909ARTERIAL DISEASECHAPTER 23bilateral, with the upper and lower limbs being variably affected depending on the site of the cerebral lesion. The combination of a motor and sensory deficit in the same body territory is sug-gestive of a cortical thromboembolic event as opposed to lacu-nar lesions secondary to small vessel disease of the penetrating arterioles. However, a small proportion of the latter may present with a sensorimotor stroke secondary to small vessel occlusion within the posterior limb of the internal capsule. Pure sensory and pure motor strokes and those strokes where the weakness affects one limb only or does not involve the face are more typically seen with lacunar as opposed to cortical infarction. A number of higher cortical functions, including speech and language disturbances, can be affected by thromboembolic phe-nomena from the carotid artery, with the most important clinical example for the dominant hemisphere being dysphasia or apha-sia and visuospatial neglect being an example of nondominant hemisphere injury.Diagnostic EvaluationDuplex ultrasonography is the most widely used screening tool to evaluate for atherosclerotic plaque and stenosis of the extracranial carotid artery. It is also commonly used to monitor patients serially for progression of disease or after intervention (carotid endarterectomy or angioplasty). Duplex ultrasound of the carotid artery combines B-mode gray-scale imaging and Doppler waveform analysis. Characterization of the carotid plaque on gray-scale imaging provides useful information about its composition. However, there are currently no universal rec-ommendations that can be made based solely on the sonographic appearance of the plaque. On the other hand, criteria have been developed and well refined for grading the degree of carotid ste-nosis based primarily on Doppler-derived velocity waveforms.The external carotid artery has a high-resistance flow pat-tern with a sharp systolic peak and a small amount of flow in diastole. In contrast, a normal internal carotid artery will have a low-resistance flow pattern with a broad systolic peak and a large amount of flow during diastole. The flow pattern in the common carotid artery resembles that in the internal carotid artery, as 80% of the flow is directed to the internal carotid artery, with waveforms that have broad systolic peaks and mod-erate amount of flow during diastole. Conventionally, velocity measurements are recorded in the common, external, carotid bulb, and the proximal, mid, and distal portions of the internal carotid artery. Characteristically, the peak systolic velocity is increased at the site of the vessel stenosis. The end-diastolic velocity is increased with greater degree of stenosis. In addition, stenosis of the internal carotid artery can lead to color shifts with color mosaics indicating a poststenotic turbulence. Dampening of the Doppler velocity waveforms is typically seen in areas distal to severe carotid stenosis where blood flow is reduced. It is well known that occlusion of the ipsilateral internal carotid artery can lead to a “falsely” elevated velocity on the contralat-eral side due to an increase in compensatory blood flow. In the presence of a high-grade stenosis or occlusion of the internal carotid artery, the ipsilateral common carotid artery displays high flow resistance waveforms, similar to those seen in the external carotid artery. If there is a significant stenosis in the proximal common carotid artery, its waveforms may be damp-ened with low velocities.The Doppler grading systems of carotid stenosis were initially established by comparison to angiographic findings of disease. Studies have shown variability in the measurements of the duplex properties by different laboratories, as well as hetero-geneity in the patient population, study design, and techniques. One the most commonly used classifications was established at the University of Washington School of Medicine in Seattle, Washington.16 Diameter reduction of 50% to 79% is defined by peak systolic velocity greater than 125 cm/s with extensive spectral broadening. For stenosis in the range of 80% to 99%, the peak systolic velocity is greater than 125 cm/s, and peak diastolic velocity is greater than 140 cm/s. The ratio of inter-nal carotid to common carotid artery peak systolic velocity has also been part of various ultrasound diagnostic classifications.  A ratio greater than 4 is a great predictor of angiographic ste-nosis of 70% to 99%. A multispecialty consensus panel has developed a set of criteria for grading carotid stenosis by duplex examination (Table 23-3).MRA is increasingly being used to evaluate for athero-sclerotic carotid occlusive disease and intracranial circulation. MRA is noninvasive and does not require iodinated contrast agents. MRA uses phase contrast or time-of-flight, with either two-dimensional or three-dimensional data sets for greater accu-racy. Three-dimensional contrast-enhanced MRA allows data to be obtained in coronal and sagittal planes with improved image qualities due to shorter study time. In addition, the new MRA techniques allow for better reformation of images in vari-ous planes to allow better grading of stenosis. There have been numerous studies comparing the sensitivity and specificity of Table 23-3Carotid duplex ultrasound criteria for grading internal carotid artery stenosisDEGREE OF STENOSIS (%)ICA PSV (CM/S)ICA/CCA PSV RATIOICA EDV (CM/S)PLAQUE ESTIMATE (%)aNormal<125<2.0<40None<50<125<2.0<40<5050–69125–2302.0–4.040–100≥50≥70 to less than near occlusion>230>4.0>100≥50Near occlusionHigh, low, or not detectedVariableVariableVisibleTotal occlusionNot detectedNot applicableNot detectedVisible, no lumenaPlaque estimate (diameter reduction) with gray-scale and color Doppler ultrasound.CCA = common carotid artery; EDV = end-diastolic velocity; ICA = internal carotid artery; PSV = peak systolic velocity.Brunicardi_Ch23_p0897-p0980.indd 90927/02/19 4:14 PM 910SPECIFIC CONSIDERATIONSPART IIFigure 23-15. A. Carotid computed tomography angiography is a valuable imaging modality that can provide a three-dimensional image reconstruction with high image resolution. A carotid artery occlusion is noted in the internal carotid artery B. The entire segment of extracranial carotid artery is visualized from the thoracic compartment to the base of skull.Figure 23-16. A carotid angiogram reveals an ulcerated carotid plaque (arrow) in the proximal internal carotid artery, which also resulted in a high-grade internal carotid artery stenosis.MRA imaging for carotid disease to duplex and selective con-trast angiography.17 Magnetic resonance imaging (MRI) of the brain is essential in the assessment of acute stroke patients. MRI with diffusion-weighted imaging can differentiate areas of acute ischemia, areas still at risk for ischemia (penumbra), and chronic cerebral ischemic changes. However, computed tomography (CT) imaging remains the most expeditious test in the evaluation of acute stroke patients to rule out intracerebral hemorrhage. Recently, multidetector CTA has gained increasing popularity in the evaluation of carotid disease.18 This imaging modality can provide volume rendering, which allows rotation of the object with accurate anatomic structures from all angles (Fig. 23-15). The advantages of CTA over MRA include faster data acquisition time and better spatial resolution. However, grading of carotid stenosis by CTA requires further validation at the time of this writing before it can be widely applied.Historically, DSA has been the gold standard test to evalu-ate the extraand intracranial circulation (Fig. 23-16). This is an invasive procedure, typically performed via a transfemoral puncture, and involves selective imaging of the carotid and ver-tebral arteries using iodinated contrast. The risk of stroke during cerebral angiography is generally reported at approximately 1% and is typically due to atheroembolization related to wire and catheter manipulation in the arch aorta or proximal branch vessels. Over the last few decades, however, the incidence of neurologic complications following angiography has been reduced, due to the use of improved guidewires and catheters, better resolution digital imaging, and increased experience. Local access compli-cations of angiography are infrequent and include development of hematoma, pseudoaneurysm, distal embolization, and acute vessel thrombosis. Currently, selective angiography is particu-larly used for patients with suspected intracranial disease and for patients in whom percutaneous revascularization is con-sidered. The techniques of carotid angioplasty and stenting for carotid bifurcation occlusive disease are described in detail later in this chapter. We generally use CTA or MRA to get informa-tion about the aortic arch anatomy and presence of concomitant intracranial disease and collateral pathway in planning our strategy for carotid stenting or endarterectomy.Treatment of Carotid Occlusive DiseaseConventionally, patients with carotid bifurcation occlusive dis-ease are divided into two broad categories: patients without prior history of ipsilateral stroke or TIA (asymptomatic) and those with prior or current ipsilateral neurologic symptoms BA(symptomatic). It is estimated that 15% of all strokes are pre-ceded by a TIA. The 90-day risk of a stroke in a patient present-ing with a TIA is 3% to 17%.14 According to the Cardiovascular Health Study, a longitudinal population-based study of coronary artery disease and stroke in men and women, the prevalence of TIA in men was 2.7% for ages of 65 and 69 and 3.6% for ages 75 to 79; the prevalence in women was 1.4% and 4.1%, respectively.24 There have been several studies reporting on the effectiveness of stroke prevention with medical treatment and carotid endarterectomy for symptomatic patients with moderate to severe carotid stenosis. Early and chronic aspirin therapy has been shown to reduce stroke recurrence rate in sev-eral large clinical trials.19Symptomatic Carotid Stenosis. Currently, most stroke neu-rologists prescribe both aspirin and clopidogrel for secondary 1Brunicardi_Ch23_p0897-p0980.indd 91027/02/19 4:14 PM 911ARTERIAL DISEASECHAPTER 23stroke prevention in patients who have experienced a TIA or stroke.19 In patients with symptomatic carotid stenosis, the degree of stenosis appears to be the most important predic-tor in determining risk for an ipsilateral stroke. The risk of a recurrent ipsilateral stroke in patients with severe carotid ste-nosis approaches 40%. Two large multicenter randomized clinical trials, the European Carotid Surgery Trial (ECST) and the North American Symptomatic Carotid Endarterectomy Trial (NASCET), have both shown a significant risk reduction in stroke for patients with symptomatic high-grade stenosis (70–99%) undergoing carotid endarterectomy when compared to medical therapy alone.20,21 Although there has been much discussion regarding the different methodologies used in the measurement of carotid stenosis and calculation of the life-table data between the two studies, both of these studies had similar clinical results. The findings of these two landmark tri-als have also been reanalyzed in many subsequent publications. The main conclusions of the trials remain validated and widely acknowledged. Briefly, the NASCET study showed that for high-grade carotid stenosis, the cumulative risk of ipsilateral stroke was 26% in the medically treated group and 9% in the surgically treated group at 2 years. For patients with moderate carotid artery stenosis (50–69%), the benefit of carotid endar-terectomy is less but still favorable when compared to medical treatment alone; the 5-year fatal or nonfatal ipsilateral stroke rate was 16% in the surgically treated group versus 22% in the medically treated group.22 The risk of stroke was similar for the remaining group of symptomatic patients with less than 50% carotid stenosis, whether they had endarterectomy or medical treatment alone. The ECST reported similar stroke risk reduc-tion for patients with severe symptomatic carotid stenosis and no benefit in patients with mild stenosis when carotid endarter-ectomy was performed versus medical therapy.21The optimal timing of carotid intervention after acute stroke, however, remains debatable. Earlier studies showed an increased rate of postoperative stroke exacerbation and conver-sion of a bland to hemorrhagic infarction when carotid endarter-ectomy was carried out within 5 to 6 weeks after acute stroke. The dismal outcome reported in the early experience was likely related to poor patient selection. The rate of stroke recurrence is not insignificant during the interval period and may be reduced with early intervention for symptomatic carotid stenosis. Con-temporary series have demonstrated acceptable low rates of perioperative complications in patients undergoing carotid end-arterectomy within 4 weeks after acute stroke.22 In a recent ret-rospective series, carotid artery stenting when performed early (<2 weeks) after the acute stroke was associated with higher mortality than when delayed (>2 weeks).23Asymptomatic Carotid Stenosis. Whereas there is univer-sal agreement that carotid revascularization (endarterectomy or stenting) is effective in secondary stroke prevention for patients with symptomatic moderate and severe carotid stenosis, the management of asymptomatic patients remains an important controversy to be resolved. Generally, the detection of carotid stenosis in asymptomatic patients is related to the presence of a cervical bruit or based on screening duplex ultrasound findings. In one of the earlier observational studies, the authors showed that the annual occurrence rate of neurologic symptoms was 4% in a cohort of 167 patients with asymptomatic cervical bruits followed prospectively by serial carotid duplex scan.24 The mean annual rate of carotid stenosis progression to a greater than 50% stenosis was 8%. The presence of or progression to a greater than 80% stenosis correlated highly with either the development of a total occlusion of the internal carotid artery or new symptoms. The major risk factors associated with disease progression were cigarette smoking, diabetes mellitus, and age. This study supported the contention that it is prudent to fol-low a conservative course in the management of asymptomatic patients presenting with a cervical bruit.One of the first randomized clinical trials on the treatment of asymptomatic carotid artery stenosis was the Asymptomatic Carotid Atherosclerosis Study (ACAS), which evaluated the benefits of medical management with antiplatelet therapy versus carotid endarterectomy.25 Over a 5-year period, the risk of ipsi-lateral stroke in individuals with a carotid artery stenosis greater than 60% was 5.1% in the surgical arm. On the other hand, the risk of ipsilateral stroke in patients treated with medical man-agement was 11%. Carotid endarterectomy produced a relative risk reduction of 53% over medical management alone. The results of a larger randomized trial from Europe, the Asymptom-atic Carotid Surgery Trial (ACST), recently confirmed similar beneficial stroke risk reduction for patients with asymptomatic, greater than 70% carotid stenosis undergoing endarterectomy versus medical therapy.26 An important point derived from this latter trial was that even with improved medical therapy, includ-ing the addition of statin drugs and clopidogrel, medical ther-apy was still inferior to endarterectomy in the primary stroke prevention for patients with high-grade carotid artery stenosis. It is generally agreed that asymptomatic patients with severe carotid stenosis (80–99%) are at significantly increased risk for stroke and stand to benefit from either surgical or endovascular revascularization. However, revascularization for asymptomatic patients with a less severe degree of stenosis (60–79%) remains controversial.Carotid Endarterectomy Versus Angioplasty and StentingCurrently, the argument is no longer whether medical therapy alone is inferior to surgical endarterectomy in stroke preven-tion for severe carotid stenosis. Rather, the debate now revolves around whether carotid angioplasty and stenting produce the same benefits demonstrated by carotid endarterectomy. Since carotid artery stenting was approved by the FDA for clinical application in 2004, this percutaneous procedure has become a treatment alternative in patients who are deemed “high risk” for endarterectomy (Table 23-4). In contrast to many endovascular peripheral arterial interventions, percutaneous carotid stent-ing represents a much more challenging procedure, because it requires complex catheter-based skills using the 0.014-inch guidewire system and distal protection device. Moreover, cur-rent carotid stent devices predominantly use the monorail guide-wire system, which requires more technical agility compared with the over-the-wire catheter system that is routinely used in peripheral interventions. This percutaneous intervention often requires balloon angioplasty and stent placement through a long carotid guiding sheath via a groin approach. Poor techni-cal skills can result in devastating treatment complications such as stroke, which can occur in part due to plaque embolization during the balloon angioplasty and stenting of the carotid artery. Because of these various procedural components that require high technical proficiency, many early clinical investigations of carotid artery stenting, which included physicians with little or no carotid stenting experience, resulted in alarmingly poor Brunicardi_Ch23_p0897-p0980.indd 91127/02/19 4:14 PM 912SPECIFIC CONSIDERATIONSPART IITable 23-4Conditions qualifying patients as high surgical risk for carotid endarterectomyANATOMIC FACTORSPHYSIOLOGIC FACTORS• High carotid bifurcation (above C2 vertebral body)• Low common carotid artery (below clavicle)• Contralateral carotid occlusion• Restenosis of ipsilateral prior carotid endarterectomy• Previous neck irradiation• Prior radical neck dissection• Contralateral laryngeal nerve palsy• Presence of tracheostomy• Age ≥80 years• Left ventricular ejection fraction ≤30%• New York Heart Association class III/IV congestive heart failure• Unstable angina: Canadian Cardiovascular Society class III/IV angina pectoris• Recent myocardial infarction• Clinically significant cardiac disease (congestive heart failure, abnormal stress test, or need for coronary revascularization)• Severe chronic obstructive pulmonary disease• End-stage renal disease on dialysisclinical outcomes. A Cochrane review noted that, before 2006, a total of 1269 patients had been studied in five randomized controlled trials comparing percutaneous carotid intervention and surgical carotid reconstruction.27 Taken together, these trials revealed that carotid artery stenting had a greater procedural risk of stroke and death when compared to carotid endarterectomy (odds ratio, 1.33; 95% confidence interval, 0.86–2.04). Addi-tionally, a greater incidence of carotid restenosis was noted in the stenting group than the endarterectomy cohorts.However, the constant improvement of endovascular devices, procedural techniques, and adjunctive pharmacologic therapy will likely improve the treatment success of percutane-ous carotid intervention. Critical appraisals of several prospec-tive randomized trials comparing the efficacy of carotid stenting versus endarterectomy are available for review.28 Two recently published randomized controlled trial, the Carotid Revascu-larization Endarterectomy Versus Stent Trial (CREST) and the International Carotid Stenting Study (ICSS) have reported somewhat differing results.29 CREST compared the efficacy of carotid endarterectomy and carotid stenting in both symptom-atic and asymptomatic patients.30 Primary end points included 30-day periprocedural composite death, stroke, myocardial infarction, or any ipsilateral stroke up to 4 years. CREST inves-tigators reported no difference between stenting (5.2%) and endarterectomy (4.5%) in terms of primary end point. When each variable was independently analyzed, there was a higher rate of stroke in the stenting group at 30 days (4.1% vs. 2.3%) and a higher rate of myocardial infarction in the endarterectomy group (2.3% vs. 1.1%). The ICSS was a multicenter, interna-tional, randomized controlled trial comparing carotid stenting versus endarterectomy in patients with symptomatic carotid ste-nosis.31 The risk of stroke, death, and myocardial infarction in the stenting group (8.5%) was significantly higher than in the surgical arm (5.2%). The finding that carotid endarterectomy is safer than carotid stenting is also supported by the results of an MRI substudy, which showed significantly more new lesions by diffusion-weighted imaging in the carotid stenting than the carotid endarterectomy patients.All available randomized studies have provided some answers and raised some questions. Some ongoing clinical tri-als will undoubtedly provide more insights on the efficacy of carotid stenting in the near future. Currently, the Society for Vascular Surgeons recommends carotid endarterectomy as first-line treatment for most symptomatic patients with stenosis of 50% to 99% and asymptomatic patients with stenosis of 60% to 99%.32 The perioperative risk of stroke and death in asymp-tomatic patients must be below 3% to ensure benefit for the patient. Carotid artery stenting should be reserved for symptom-atic patients with stenosis of 50% to 99% at high risk for carotid endarterectomy for anatomic or medical reasons. Carotid artery stenting is not recommended for asymptomatic patients at this time. Asymptomatic patients at high risk for intervention or with a life expectancy of less than 3 years should be considered for medical management as the first-line therapy.Surgical Techniques of Carotid EndarterectomyAlthough carotid endarterectomy is one of the earliest vas-cular operations ever described and its techniques have been perfected in the last two decades, surgeons continue to debate many aspects of this procedure. For instance, there is no uni-versal agreement with regard to the best anesthetic of choice, the best intraoperative cerebral monitoring, whether to “rou-tinely” shunt, open versus eversion endarterectomy, and patch versus primary closure. Various anesthetic options are avail-able for patient undergoing carotid endarterectomy including general, local, and regional anesthesia. Typically, the anesthe-sia of choice depends on the preference of the surgeon, anes-thesiologist, and patient. However, depending on the anesthetic given, the surgeon must decide whether intraoperative cerebral monitoring is necessary or intra-arterial carotid shunting will be used. In general, if the patient is awake, then his or her abilities to respond to commands during carotid clamp period determine the adequacy of collateral flow to the ipsilateral hemisphere. On the other hand, intraoperative electroencepha-logram (EEG) or transcranial power Doppler (TCD) has been used to monitor for adequacy of cerebral perfusion during the clamp period for patients undergoing surgery under general anesthesia. Focal ipsilateral decreases in amplitudes and slow-ing of EEG waves are indicative of cerebral ischemia. Simi-larly, a decrease to less than 50% of baseline velocity in the ipsilateral middle cerebral artery is a sign of cerebral ischemia. For patients with poor collateral flow exhibiting signs of cere-bral ischemia, intra-arterial carotid shunting with removal of the clamp will restore cerebral flow for the remaining part of the surgery. Stump pressures have been used to determine the need for intra-arterial carotid shunting. Some surgeons prefer to shunt all patients on a routine basis and do not use intraop-erative cerebral monitoring.Brunicardi_Ch23_p0897-p0980.indd 91227/02/19 4:14 PM 913ARTERIAL DISEASECHAPTER 23Figure 23-17. To perform carotid endarterectomy, the patient’s neck is slightly hyperextended and turned to the contralateral side. An oblique incision is made along the anterior border of the ster-nocleidomastoid muscle centered on top of the carotid bifurcation.The patient’s neck is slightly hyperextended and turned to the contralateral side, with a roll placed between the shoulder blades. An oblique incision is made along the anterior border of the sternocleidomastoid muscle centered on top of the carotid bifurcation (Fig. 23-17). The platysma is divided completely. Typically, tributaries of the anterior jugular vein are ligated and divided. The dissection is carried medial to the sternocleido-mastoid. The superior belly of the omohyoid muscle is usually encountered just anterior to the common carotid artery. This muscle can be divided. The carotid fascia is incised, and the common carotid artery is exposed. The common carotid artery is mobilized cephalad toward the bifurcation. The dissection of the carotid bifurcation can cause reactive bradycardia related to stimulation of the carotid body. This reflex can be blunted with injection of lidocaine 1% into the carotid body or reversed with administration of intravenous atropine. A useful landmark in the dissection of the carotid bifurcation is the common facial vein. This vein can be ligated and divided. Frequently the 12th cranial nerve (hypoglossal nerve) traverses the carotid bifurcation just behind the common facial vein. The external carotid artery is mobilized just enough to get a clamp across. Often, a branch of the external carotid artery crossing to the sternocleidomas-toid can be divided to allow further cephalad mobilization of the internal carotid artery. For high bifurcation, division of the posterior belly of the digastric muscle is helpful in establishing distal exposure of the internal carotid artery.Intravenous heparin sulfate (1 mg/kg) is routinely admin-istered just prior to carotid clamping. The internal carotid artery is clamped first using a soft noncrushing vascular clamp to prevent distal embolization. The external and common carotid arteries are clamped subsequently. A longitudinal arteriotomy is made in the distal common carotid artery and extended into the bulb and past the occlusive plaque into the normal part of the internal carotid artery. Endarterectomy is carried out to remove the occlusive plaque (Fig. 23-18). If necessary, a tem-porary shunt can be inserted from the common carotid artery to the internal carotid artery to maintain continuous antegrade cerebral blood flow (Fig. 23-19). Typically, a plane is teased out from the vessel wall, and the entire plaque is elevated and Figure 23-18. A. During carotid endarterectomy, vascular clamps are applied in the common carotid, external carotid, and internal carotid arteries. Carotid plaque is elevated from the carotid lumen. B. Carotid plaque is removed, and the arteriotomy is closed either primarily or with a patch angioplasty.Figure 23-19. A temporary carotid shunt is inserted from the com-mon carotid artery (long arrow) to the internal carotid artery (short arrow) during carotid endarterectomy to provide continuous ante-grade cerebral blood flow.removed. The distal transition line in the internal carotid artery where the plaque had been removed must be examined care-fully and should be smooth. Tacking sutures are placed when an intimal flap remains in this transition to ensure no obstruction to flow (Fig. 23-20). The occlusive plaque is usually removed from the origin of the external carotid artery using the ever-sion technique. The endarterectomized surface is then irrigated and any debris removed. A patch (autogenous saphenous vein, synthetic such as polyester, PTFE, or biologic material) is sewn to close the arteriotomy (Fig. 23-21). Whether patch closure is necessary in all patients and which patch is the best remain con-troversial. However, most surgeons agree that patch closure is Brunicardi_Ch23_p0897-p0980.indd 91327/02/19 4:14 PM 914SPECIFIC CONSIDERATIONSPART IIFigure 23-20. The distal transition line (left side of the picture) in the internal carotid artery where the plaque had been removed must be examined carefully and should be smooth. Tacking sutures (arrows) are placed when an intimal flap remains in this transition to ensure no obstruction to flow.Figure 23-21. A. An autologous or synthetic patch can be used to close the carotid arteriotomy incision, which maintains the luminal patency. B. A completion closure of carotid endarterectomy incision using a synthetic patch.BAindicated particularly for the small vessel (<7 mm). The ever-sion technique has also been advocated for removing the plaque from the internal carotid artery. In the eversion technique, the internal carotid artery is transected at the bulb, the edges of the divided vessel are everted, and the occluding plaque is “peeled” off the vessel wall. The purported advantages of the eversion technique are no need for patch closure and a clear visualization of the distal transition area. Reported series have not shown a clear superiority of one technique over the others.33 Surgeons will likely continue to use the technique of their choice. Just prior to completion of the anastomosis to close the arteriotomy, we thoroughly flush the vessels of any potential debris. When the arteriotomy is closed, flow is restored to the external carotid artery first and to the internal carotid artery second. Intravenous protamine sulfate can be given to reverse the effect of heparin anticoagulation following carotid endarterectomy. The wound is closed in layers. After surgery, the patient’s neurologic con-dition is asserted in the operating room prior to transfer to the recovery area.Complications of Carotid Endarterectomy. Most patients tolerate carotid endarterectomy very well and typically are discharged home within 24 hours after surgery. Complica-tions after endarterectomy are infrequent but can be poten-tially life-threatening or disabling. Acute ipsilateral stroke is a dreaded complication following carotid endarterectomy. Cerebral ischemia can be due to either intraoperative or post-operative events. Embolizations from the occlusive plaque or prolonged cerebral ischemia are potential causes of intraopera-tive stroke. The most common cause of postoperative stroke is due to embolization. Less frequently, acute carotid artery occlu-sion can cause acute postoperative stroke. This is usually due to carotid artery thrombosis related to closure of the arteriotomy, an occluding intimal flap, or distal carotid dissection. When patients experience acute symptoms of neurologic ischemia after endarterectomy, immediate intervention may be indicated. Carotid duplex scan can be done expeditiously to assess patency of the extracranial internal carotid artery. Reexploration is man-dated for acute carotid artery occlusion. Cerebral angiography can be useful if intracranial revascularization is considered.Local complications related to surgery include excessive bleeding and cranial nerve palsies. Postoperative hematoma in the neck after carotid endarterectomy can lead to devastating airway compromise. Any expanding hematoma should be evac-uated and active bleeding stopped. Securing an airway is critical and can be extremely difficult in patients with large postopera-tive neck hematoma. The reported incidence of postoperative cranial nerve palsies after carotid endarterectomy varies from 1% to 30%.34 Well-recognized injuries involve the marginal mandibular, vagus, hypoglossal, superior laryngeal, and recur-rent laryngeal nerves. Often these are traction injuries but can also be due to severance of the respective nerves.Techniques of Carotid Angioplasty and StentingPercutaneous carotid artery stenting has become an accepted alternative treatment in the management of patients with carotid bifurcation disease (Fig. 23-22). The perceived advantages of percutaneous carotid revascularization are related to the mini-mal invasiveness of the procedure compared to surgery. There are anatomic conditions based on angiographic evaluation in which carotid artery stenting should be avoided due to increased procedure-related risks (Table 23-5). In preparation for carotid stenting, the patient should be given oral clopidogrel 3 days prior to the intervention if the patient was not already taking the drug. The procedure is done in either the operating room with angiographic capabilities or in a dedicated angiography room. The patient is placed in the supine position. The patient’s blood pressure and cardiac rhythm are closely monitored.To gain access to the carotid artery, a retrograde trans-femoral approach is most commonly used as the access site for carotid intervention. Using the Seldinger technique, we insert a diagnostic 5or 6-French sheath in the CFA. A diagnostic arch Brunicardi_Ch23_p0897-p0980.indd 91427/02/19 4:14 PM 915ARTERIAL DISEASECHAPTER 23BAFigure 23-22. A. Carotid angiogram demonstrating a high-grade stenosis of the left internal carotid artery. B. Com-pletion angiogram demonstrating a sat-isfactory result following a carotid stent placement.Table 23-5Unfavorable carotid angiographic appearance in which carotid stenting should be avoided• Extensive carotid calcification• Polypoid or globular carotid lesions• Severe tortuosity of the common carotid artery• Long-segment stenoses (>2 cm in length)• Carotid artery occlusion• Severe intraluminal thrombus (angiographic defects)• Extensive middle cerebral artery atherosclerosisaortogram is obtained. The carotid artery to be treated is then selected using a 5-French diagnostic catheter, and contrast is injected to show the carotid anatomy. It is important to assess the contralateral carotid artery, vertebrobasilar, and intracranial circulation if these are not known based on the preoperative noninvasive studies. Once the decision is made to proceed with carotid artery stenting, with the tip of the diagnostic catheter still in the common carotid artery, a 0.035-inch, 260-cm long stiff guidewire is placed in the ipsilateral external carotid artery. Anticoagulation with intravenous bivalirudin bolus (0.75 mg/kg) followed by an infusion rate of 2.5 mg/kg per hour for the remain-der of the procedure is routinely administered. Next the diagnos-tic catheter is withdrawn and a 90-cm, 6-French guiding sheath is advanced into the common carotid artery over the stiff glide wire. It is critical not to advance the sheath beyond the occlu-sive plaque in the carotid bulb. The stiff wire is then removed, and preparation is made to deploy the distal embolic protection device (EPD). Several distal EPDs are available (Table 23-6). The EPD device is carefully deployed beyond the target lesion. With regard to the carotid stents, there are several stents that have received approval from the FDA and are commercially Table 23-6Commonly used embolic protection devices (EPDs)MECHANISMNAME OF EPDPORE SIZE (μM)Distal balloon occlusionPercuSurge Guard Wire, Export catheter (Medtronic)NADistal filterAngioguard (Cordis)Accunet (Abbott)Emboshield (Abbott)FilterWire (Boston Scientific)SpiderRx (EV3)100150140110<100Flow reversalaParodi Neuro Protection (Gore)NAaClinical trial (EMPIRE) in United States.NA = not applicable.available for carotid revascularization (Table 23-7). All current carotid stents use the rapid-exchange monorail 0.014-inch plat-form. The size selection is typically based on the size of com-mon carotid artery. Predilatation using a 4-mm balloon may be necessary to allow passage of the stent delivery catheter. Once the stent is deployed across the occlusive plaque, postdilatation is usually performed using a ≤5.5-mm balloon. It is noteworthy that balloon dilation of the carotid bulb may lead to immediate bradycardia due to stimulation of the glossopharyngeal nerve. The EPD is then retrieved and the procedure is completed with removal of the sheath from the femoral artery. The puncture site is closed using available closure device or with manual compression. Throughout the procedure, the patient’s neuro-logic function is closely monitored. The bivalirudin infusion is Brunicardi_Ch23_p0897-p0980.indd 91527/02/19 4:14 PM 916SPECIFIC CONSIDERATIONSPART IITable 23-7Currently approved carotid stents in the United StatesNAME OF STENTMANUFACTURERCELL DESIGNTAPERED STENTDELIVERY SYSTEM SIZE (FRENCH)AcculinkAbbottOpenYes6ExactAbbottClosedYes6NexStentBoston ScientificClosedSelf-tapering5Protégé RXEV3OpenYes6Precise RXCordisOpenNo6ExponentMedtronicOpenNo6Figure 23-23. Excessive elongation of the carotid artery can result in carotid kinking (arrow), which can compromise cerebral blood flow and lead to cerebral ischemia.stopped and the patient is kept on clopidogrel (75 mg daily) for at least 1 month and aspirin indefinitely.Complications of Carotid Stenting. Although there have been no randomized trials comparing carotid stenting with and without EPD, the availability of EPDs appears to have reduced the risk of distal embolization and stroke. The results of the various clinical trials and registries of carotid stenting have been reported and compared. It is well known that distal embolization as detected by TCD is much more frequent with carotid stenting even with EPD, when compared with carotid endarterectomy. However, the clinical significance of the distal embolization detected by TCD is not clear because most are asymptomatic. Acute carotid stent thrombosis is rare. The incidence of in-stent carotid restenosis is not well known but is estimated at 10% to 30%. Duplex surveillance shows elevated peak systolic velocities within the stent after carotid stenting not infrequently. However, velocity criteria are being formulated to determine the severity of in-stent restenosis after carotid stenting by ultra-sound duplex.35 It appears that systolic velocities exceeding 300 to 400 cm/s would represent >70% to 80% restenosis. Bradycar-dia and hypotension occur in up to 20% of patients undergoing carotid stenting.36 Systemic administration of atropine is usually effective in reversing the bradycardia. Other technical compli-cations of carotid stenting are infrequent and include carotid artery dissection and access site complications, such as groin hematoma, femoral artery pseudoaneurysm, distal embolization, and acute femoral artery thrombosis.Nonatherosclerotic Disease of the Carotid ArteryCarotid Coil and Kink. A carotid coil consists of an excessive elongation of the internal carotid artery producing tortuosity of the vessel (Fig. 23-23). Embryologically, the carotid artery is derived from the third aortic arch and dorsal aortic root and is uncoiled as the heart and great vessels descend into the medi-astinum. In children, carotid coils appear to be congenital in origin. In contrast, elongation and kinking of the carotid artery in adults are associated with the loss of elasticity and an abrupt angulation of the vessel. Kinking is more common in women than men. Cerebral ischemic symptoms caused by kinks of the carotid artery are similar to those from atherosclerotic carotid lesions but are more likely due to cerebral hypoperfusion than embolic episodes. Classically, sudden head rotation, flexion, or extension can accentuate the kink and provoke ischemic symp-toms. Most carotid kinks and coils are found incidentally on carotid duplex scan. However, interpretation of the Doppler fre-quency shifts and spectral analysis in tortuous carotid arteries can be difficult because of the uncertain angle of insonation. Cerebral angiography, with multiple views taken in neck flex-ion, extension, and rotation, is useful in the determination of the clinical significance of kinks and coils.Fibromuscular Dysplasia. Fibromuscular dysplasia (FMD) usually involves medium-sized arteries that are long and have few branches (Fig. 23-24). Women in the fourth or fifth decade of life are more commonly affected than men. Hormonal effects on the vessel wall are thought to play a role in the pathogenesis of FMD. FMD of the carotid artery is commonly bilateral, and in about 20% of patients, the vertebral artery is also involved.37 Brunicardi_Ch23_p0897-p0980.indd 91627/02/19 4:14 PM 917ARTERIAL DISEASECHAPTER 23Figure 23-24. A carotid fibromuscular dysplasia with typical characteristics of multiple stenoses with intervening aneurysmal outpouching dilatations. The disease involves the media, with the smooth muscle being replaced by fibrous connective tissue.An intracranial saccular aneurysm of the carotid siphon or mid-dle cerebral artery can be identified in up to 50% of the patients with FMD. Four histologic types of FMD have been described in the literature. The most common type is medial fibroplasia, which may present as a focal stenosis or multiple lesions with intervening aneurysmal outpouchings. The disease involves the media with the smooth muscle being replaced by fibrous con-nective tissue. Commonly, mural dilations and microaneurysms can be seen with this type of FMD. Medial hyperplasia is a rare type of FMD, with the media demonstrating excessive amounts of smooth muscle. Intimal fibroplasia accounts for 5% of all cases and occurs equally in both sexes. The media and adven-titia remain normal, and there is accumulation of subendothe-lial mesenchymal cells with a loose matrix of connective tissue causing a focal stenosis in adults. Finally, premedial dyspla-sia represents a type of FMD with elastic tissue accumulating between the media and adventitia. FMD can also involve the renal and external iliac arteries. It is estimated that approxi-mately 40% of patients with FMD present with a TIA due to embolization of platelet aggregates.37 DSA demonstrates the characteristic “string of beads” pattern, which represents alter-nating segments of stenosis and dilatation. The string of beads can also be shown noninvasively by CTA or MRA. FMD should be suspected when an increased velocity is detected across a stenotic segment without associated atherosclerotic changes on carotid duplex ultrasound. Antiplatelet medication is the gener-ally accepted therapy for asymptomatic lesions. Endovascular treatment is recommended for patients with documented lateral-izing symptoms. Surgical correction is rarely indicated.Carotid Artery Dissection. Dissection of the carotid artery accounts for approximately 20% of strokes in patients younger than 45 years of age. The etiology and pathogenesis of sponta-neous carotid artery dissection remain incompletely understood. Arterial dissection involves hemorrhage within the media, which can extend into the subadventitial and subintimal layers. When the dissection extends into the subadventitial space, there is an increased risk of aneurysm formation. Subintimal dissections can lead to intramural clot or thrombosis. Traumatic dissection is typically a result of hyperextension of the neck during blunt trauma, neck manipulation, strangulation, or penetrating injuries to the neck. Even in supposedly spontaneous cases, a history of preceding unrecognized minor neck trauma is not uncommon. Connective disorders, such as Ehlers-Danlos syndrome, Marfan’s syndrome, α1-antitrypsin deficiency, or FMD, may predispose to carotid artery dissection. Iatrogenic dissections can also occur due to catheter manipulation or balloon angioplasty.Typical clinical features of carotid artery dissection include unilateral neck pain, headache, and ipsilateral Horner’s syndrome in up to 50% of patients, followed by manifestations of the cerebral or ocular ischemia and cranial nerve palsies. Neurologic deficits can result either because of hemodynamic failure (caused by luminal stenosis) or by an artery-to-artery thromboembolism. The ischemia may cause TIAs or infarctions, or both. Catheter angiography has been the method of choice to diagnose arterial dissections, but with the advent of duplex ultra-sonography, MRI/MRA, and CTA, most dissections can now be diagnosed using noninvasive imaging modalities (Fig. 23-25). The dissection typically starts in the internal carotid artery distal to the bulb. Uncommonly, the dissection can start in the com-mon carotid artery or is an extension of a more proximal aortic dissection. Medical therapy has been the accepted primary treat-ment of symptomatic of carotid artery dissection. Anticoagula-tion (heparin and warfarin) and antiplatelet therapy have been commonly used, although there have not been any randomized studies to evaluate their effectiveness. The prognosis depends on the severity of neurologic deficit but is generally good in extracranial dissections. The recurrence rate is low. Therapeutic interventions have been reserved for recurrent TIAs or strokes or failure of medical treatment. Endovascular options include intra-arterial stenting, coiling of associated pseudoaneurysms, or, more recently, deployment of covered stents.Figure 23-25. Carotid ultrasound reveals a patient with a carotid artery dissection in which carotid flow is separated in the true flow lumen (long arrow) from the false lumen (short arrow).Brunicardi_Ch23_p0897-p0980.indd 91727/02/19 4:14 PM 918SPECIFIC CONSIDERATIONSPART IIFigure 23-26. A. An anteroposterior angiogram of the neck revealing a carotid artery aneurysm. B. A lateral projection of the carotid artery aneurysm. C. Following endovascular placement, the carotid artery aneurysm is successfully excluded.Carotid Artery Aneurysms. Carotid artery aneurysms are rare, encountered in less than 1% of all carotid operations (Fig. 23-26). The true carotid artery aneurysm is generally due to atherosclerosis or medial degeneration. The carotid bulb is involved in most carotid aneurysms, and bilaterality is present in 12% of the patients. Patients typically present with a pul-satile neck mass. The available data suggest that, untreated, these aneurysms lead to neurologic symptoms from emboliza-tion. Thrombosis and rupture of the carotid aneurysm are rare. Pseudoaneurysms of the carotid artery can result from injury or infection. Mycotic aneurysms often involved syphilis in the past, but they are now more commonly associated with peri-tonsillar abscesses caused by Staphylococcus aureus infection. FMD and spontaneous dissection of the carotid artery can lead to A B CA BFigure 23-27. A. A carotid body tumor (arrow) located adjacent to the carotid bulb. B. Following periad-ventitial dissection, the carotid body tumor is removed.the formation of true aneurysms or pseudoaneurysms. Whereas conventional surgery has been the primary mode of treatment in the past, carotid aneurysms are currently being treated more commonly using endovascular approaches.38Carotid Body Tumor. The carotid body originates from the third branchial arch and from neuroectodermal-derived neural crest lineage. The normal carotid body is located in the adven-titia or periadventitial tissue at the bifurcation of the common carotid artery (Fig. 23-27). The gland is innervated by the glos-sopharyngeal nerve. Its blood supply is derived predominantly from the external carotid artery but can also come from the ver-tebral artery. Carotid body tumor is a rare lesion of the neuroen-docrine system. Other glands of neural crest origin are seen in Brunicardi_Ch23_p0897-p0980.indd 91827/02/19 4:14 PM 919ARTERIAL DISEASECHAPTER 23the neck, parapharyngeal spaces, mediastinum, retroperitoneum, and adrenal medulla. Tumors involving these structures have been referred to as paraganglioma, glomus tumor, or chemo-dectoma. Approximately 5% to 7% of carotid body tumors are malignant. Although chronic hypoxemia has been invoked as a stimulus for hyperplasia of carotid body, approximately 35% of carotid body tumors are hereditary.39 The risk of malignancy is greatest in young patients with familial tumors.Symptoms related to the endocrine products of the carotid body tumor are rare. Patients usually present between the fifth and seventh decades of life with an asymptomatic lateral neck mass. The diagnosis of carotid body tumor requires confir-mation on imaging studies. Carotid duplex scan can localize the tumor to the carotid bifurcation, but CT or MRI is usually required to further delineate the relationship of the tumor to the adjacent structures. Classically, a carotid body tumor will widen the carotid bifurcation. The Shamblin classification describes the tumor extent: I, tumor is less than 5 cm and relatively free of vessel involvement; II, tumor is intimately involved but does not encase the vessel wall; and III, tumor is intramural and encases the carotid vessels and adjacent nerves.40 With good-resolution CT and MRI, arteriography is usually not required. However, arteriography can provide an assessment of the vessel invasion and intracranial circulation and allows for preoperative embolization of the feeder vessels, which has been reported to reduce intraoperative blood loss. Surgical resection is the rec-ommended treatment for suspected carotid body tumor.Carotid Trauma. Blunt or penetrating trauma to the neck can cause injury to the carotid artery. Notwithstanding the massive bleeding from carotid artery transection, injury to the carotid artery can result in carotid dissection, thrombosis, or pseudoa-neurysm formation. Carotid duplex ultrasound can be useful to locate the site of injury in the cervical segment of the carotid artery. Spiral CTA has become the modality of choice to detect extracranial carotid artery injury. Confirmation of carotid injury by contrast cerebral angiography remains the gold standard diagnostic test. Injuries to the cervical segment of the common and internal carotid arteries can be repaired surgically. Acute carotid artery thrombosis is usually treated medically with anti-coagulation if the patient is asymptomatic. Revascularization should be considered for patients presenting with ongoing cere-bral ischemia related to carotid artery thrombosis. Traumatic carotid artery dissection can cause cerebral ischemia due to thromboembolization, decreased flow, or thrombosis. Com-monly, the dissection involves the distal portion of the cervi-cal and petrous segment of the internal carotid artery. Medical management with antiplatelet or anticoagulation therapy is usu-ally adequate for uncomplicated traumatic carotid dissection. In patients with pseudoaneurysms of the carotid artery that are located in a segment that is out of surgical reach, the use of selective coil embolization of the pseudoaneurysm or exclu-sion of the pseudoaneurysm by a covered stent graft has been reported. Bare metal stent has been used with success in the treatment of traumatic carotid artery dissection.ABDOMINAL AORTIC ANEURYSMDespite more than 50,000 patients undergoing elective repair of abdominal aortic aneurysm (AAA) each year in the United States, approximately 15,000 patients die annually as a result of ruptured aneurysm, making it the 10th leading cause of death in men in this country.41 The incidence appears to be increasing, and this is due in part to improvements in diagnostic imaging and, more importantly, a growing elderly population. With early diagnosis and timely intervention, aneurysm rupture–related death is largely preventable. Conventional treatment of an AAA involves replacing the aneurysmal segment of the aorta with a prosthetic graft, with the operation performed through a large abdominal incision. Techniques for this open abdominal surgery have been refined, adapted, and extensively studied by vascular surgeons over the past four decades. Despite a well-documented low perioperative mortality rate of 2% to 3% in large academic institutions, the thought of undergoing an open abdominal aortic operation often provokes a sense of anxiety in many patients due in part to the postoperative pain associated with the large abdominal incision as well as the long recovery time needed before the patient can return to normal physical activity.The most common location of aortic aneurysms is the infrarenal aorta. Endovascular stent graft placement represents a revolutionary and minimally invasive treatment for infrarenal AAAs that only requires 1 to 2 days of hospitalization, and the patient can return to normal physical activity within 1 week. The concept of using an endoluminal device in the management of vascular disease was first proposed by Dotter and colleagues, who successfully treated a patient with iliac occlusion using transluminal angioplasty in 1964.42 Nearly two decades later, Parodi and colleagues reported the first successful endovascu-lar repair of AAA using a stent graft device.11 Since then, a variety of stent graft technologies have been developed to treat AAA. The rapid innovation of this new treatment modality has undoubtedly captured the attention of patients with aortic aneu-rysms as well as physicians who practice endovascular therapy. Physicians in general should be knowledgeable regarding avail-able treatment options of AAA in order to provide adequate evaluation and education to patients and their families. The pur-pose of this section is to outline the treatment options for AAAs, including conventional repair and endovascular approach. Advantages and potential complications of these treatments will also be addressed.Causes and Risk FactorsThe pathogenesis of aneurysmal disease of the aorta is complex and multifactorial. A degenerative process in the aortic wall is the most common cause of AAA development.43 Matrix metal-loproteinases (MMP), proteolytic enzymes, are found abun-dantly in the wall of AAA. Atherosclerotic disease, age, male sex, smoking history, family history, hypertension, coronary artery disease, and chronic obstructive pulmonary disease are associated with the development of AAA.44 Diabetes and black race have negative association with AAA. Other less common causes include inflammation, infection, and connective tissue disease. Inflammatory AAA accounts for 5% to 10% of all AAAs.43 In contrast to atherosclerotic AAA, the inflammatory variant is characterized pathologically by marked thickening of the aneurysm wall, fibrosis of the adjacent retroperitoneum, and rigid adherence of the adjacent structures to the anterior aneurysm wall. Male sex and smoking are even stronger risk factors in inflammatory AAA.45 Smoking cessation is the first step of medical therapy, followed by surgical repair. Infectious or mycotic AAA is rare but is associated with high mortality. Patients with connective tissue disorders such as Marfan’s syn-drome and Ehlers-Danlos syndrome tend to have more exten-sive and larger aneurysms at a younger age.43Brunicardi_Ch23_p0897-p0980.indd 91927/02/19 4:14 PM 920SPECIFIC CONSIDERATIONSPART IITable 23-8Annualized risk of rupture of abdominal aortic aneurysm (AAA) based on sizeDESCRIPTIONDIAMETER OF AORTA (CM)ESTIMATED ANNUAL RISK OF RUPTURE (%)ESTIMATED 5-YEAR RISK OF RUPTURE (%)aNormal aorta2–300 (unless AAA develops)Small AAA4–515–10Moderate AAA5–62–530–40Large AAA6–73–10>50Very large AAA>7>10Approaching 100aThe estimated 5-year risk is more than five times the estimated annual risk because over that 5 years, the AAA, if left untreated, will continue to grow in size.Natural History of Aortic AneurysmThe natural history of an AAA is to expand and rupture. AAA exhibits a “staccato” pattern of growth, where periods of relative quiescence may alternate with expansion. Therefore, although an individual pattern of growth cannot be predicted, average aggregate growth is approximately 3 to 4 mm/year. There is some evidence to suggest that larger aneurysms may expand faster than smaller aneurysms, but there is significant overlap between the ranges of growth rates at each strata of size.Rupture risk appears to be directly related to aneurysm size as predicted by Laplace’s Law. Although more sophisti-cated methods of assessing rupture risk based on finite element analysis of wall stress are under active investigation, maximum transverse diameter remains the standard method of risk assess-ment for aneurysm rupture. In the past, AAA rupture risk has been overestimated. More recently, two landmark studies have served to better define the natural history of AAA.46,47 Based on best available evidence, the annualized risk of rupture is given in Table 23-8. The rupture risk is quite low below 5.5 cm and begins to rise exponentially thereafter. This size can serve as an appropriate threshold for recommending elective repair provided one’s surgical mortality is below 5%. For each size strata, however, women appear to be at higher risk for rup-ture than men, and a lower threshold of 4.5 to 5.0 cm may be reasonable in good-risk patients. Although data are less compel-ling, a pattern of rapid expansion of >0.5 cm within 6 months can be considered a relative indication for elective repair. Aneu-rysms that fall below these indications may safely be followed with CT or ultrasound at 6-month intervals, with long-term out-comes equivalent to earlier surgical repair. Interestingly, in the Aneurysm Detection and Management (ADAM) study, 80% of all AAAs that were followed in this manner eventually came to repair within 5 years.48Unless symptomatic or ruptured, AAA repair is a pro-phylactic repair. The rationale for recommending repair is predicated on the assumption that the risk of aneurysm rupture exceeds the combined risk of death from all other causes such as cardiopulmonary disease and cancer. On the other hand, our limitation in predicting timing and cause of death is underscored by the observation that over 25% of patients who were deemed unfit for surgical repair because of their comorbidities died from rupture of their aneurysms within 5 years.Clinical ManifestationsMost AAAs are asymptomatic and are usually found inciden-tally during workup for chronic back pain or kidney stones. Physical examination is neither sensitive nor specific except 2in thin patients. Large aneurysms may be missed in the obese, while normal aortic pulsations may be mistaken for an aneurysm in thin individuals. Rarely patients present with back pain and/or abdominal pain with a tender pulsatile mass. Patients with these symptoms must be treated as a rupture until proven otherwise. If the patient is hemodynamically stable and the aneurysm is intact on a CT scan, the patient is admitted for blood pressure control with intravenous antihypertensive agents and undergoes repair usually within 12 to 24 hours or at least during the same hospitalization. In contrast, patients who are hemodynamically unstable with a history of acute back pain and/or syncope and a known unrepaired AAA or a pulsatile abdominal mass should be immediately taken to the operating room with a presumed diagnosis of a ruptured AAA.Overall mortality of AAA rupture is 71% to 77%, which includes all out-of-hospital and in-hospital deaths, as compared with 2% to 6% for elective open surgical repair.49 Nearly half of all patients with ruptured AAA will die before reaching the hospital. For the remainder, surgical mortality is 45% to 50% and has not substantially changed in the last 30 years.50Relevant AnatomyAn AAA is defined as a pathologic focal dilation of the aorta that is greater than 30 mm or 1.5 times the adjacent diameter of the normal aorta (Fig. 23-28). Male aortas tend to be larger than female aortas, and there is generalized growth of the aortic diameter with each decade of life. Ninety percent of AAAs are infrarenal in location and have a fusiform morphology. There is a higher predilection for juxtarenal and suprarenal AAAs in women compared with men. Concomitant common iliac and/or hypogastric artery aneurysms can be found in 20% to 25% of patients. Although the etiology of most aortic aneurysms is ath-erosclerotic, clinically significant peripheral occlusive disease is unusual and present in less than 10% of all cases.Although extravascular anatomy is important for open surgical repair of AAA, intravascular anatomy and aortoiliac morphology are important for endovascular repair. Pertinent anatomic dimensions include the diameter of the proximal non-dilated infrarenal aortic neck, which can range from 18 to 30 mm; common iliac artery, which can range from 8 to 16 mm; and external iliac arteries, which can range from 6 to 10 mm. Mor-phologically, the aortic neck can manifest complex angulation above and below the renal arteries due to combination of elon-gation and anterolateral displacement by the posterior bulge of the aneurysmal aorta. Furthermore, the shape of the proxi-mal neck is rarely tubular, but often is conical, reverse coni-cal, or barrel-shaped. Distally, the iliac arteries can have severe Brunicardi_Ch23_p0897-p0980.indd 92027/02/19 4:14 PM 921ARTERIAL DISEASECHAPTER 23Figure 23-28. An operative view of an infrarenal aortic aneurysm.tortuosity with multiple compound turns. Although significant from hemodynamic standpoint, severe iliac calcifications com-bined with extreme tortuosity can pose a formidable challenge during endovascular repair.Diagnostic EvaluationPreoperative evaluation should include routine history and physical exam with particular attention to (a) any symptoms referable to the aneurysm, which may impact the timing of repair; (b) history of pelvic surgery or radiation, in the event retroperitoneal exposure is required or interruption of hypogas-tric circulation is planned; (c) claudication suggestive of sig-nificant iliac occlusive disease; (d) lower extremity bypass or other femoral reconstructive procedures; and (e) chronic renal insufficiency or contrast allergy.Cross-sectional imaging is required for definitive evalu-ation of AAA. Although ultrasound is safe, widely available, relatively accurate, and inexpensive and thus the screening modality of choice, CT scan remains the gold standard for deter-mination of anatomic eligibility for endovascular repair. Size of AAA may differ up to 1 cm between CT and ultrasound, and during longitudinal follow-up, comparisons should be made between identical modalities. With modern multirow detector scanners, a timed-bolus intravenous contrast-enhanced, 2.5to 3.0-mm slice spiral CT of the chest, abdomen, and pelvis can be performed in less than 30 seconds with a single breath hold. Extremely high-resolution images are obtained with submilli-meter spatial resolution (Fig. 23-29). Proper window level and width (brightness and contrast) are important for discrimination among aortic wall, calcific plaque, thrombus, and lumen. The only major drawback to CT is the risk of contrast nephropathy in diabetics and in patients with renal insufficiency.The spiral technique further affords the ability for three-dimensional reconstruction. Three-dimensional reconstructions Figure 23-29. High resolution of image displaying an aortic aneu-rysm (arrow) can be achieved with multidetector computed tomog-raphy angiography.can yield important morphologic information that is critical to endovascular therapy. Using third-party software, these images can be viewed and manipulated on one’s desktop computer, and so-called “center-line” (transverse slices perpendicular to the central flow lumen of the aorta) diameter and length measure-ments obtained. Conventional angiography has a minimal role in the current management of AAA. Angiography is invasive with an increased risk of complications. Indications for angiog-raphy are isolated to concomitant iliac occlusive disease (pres-ent in <10% of patients with AAA) and unusual renovascular anatomy.Surgical Repair of Abdominal Aortic AneurysmGeneral anesthesia is necessary when performing a conventional open AAA repair. While a retroperitoneal incision is a well-accepted surgical approach, a midline transabdominal incision remains the more common approach for open aortic aneurysm operation. Since the abdominal incision can lead to significant pain and discomfort, an epidural catheter can be placed prior to the operation for postoperative analgesic infusion to provide pain control. Once the abdominal cavity is opened, the small intestines and transverse colon are retracted to expose the ret-roperitoneum overlying the AAA. The retroperitoneum is next divided, followed by isolation of both proximal and distal seg-ments of the AAA. Intravenous heparin (100 IU/kg) is given followed by clamping of the proximal and distal segments of the aneurysm. The aneurysm sac is open next, and a prosthetic graft is used to reconstruct the aorta. If the aneurysm only involves the abdominal aorta, a tube graft can be used to replace the aorta (Fig. 23-30). If the aneurysm extends distally to the iliac arter-ies, a prosthetic bifurcated graft is used for either an aorto-bi-iliac or aorto-bi-femoral bypass reconstruction (Fig. 23-31). The overlying aneurysm sac and the retroperitoneum are closed to cover the prosthetic bypass graft to minimize potential bowel contact to the graft. Small and large intestines are returned to the abdominal cavity followed by the closure of the abdominal fascia and skin.Brunicardi_Ch23_p0897-p0980.indd 92127/02/19 4:14 PM 922SPECIFIC CONSIDERATIONSPART IIABFigure 23-30. A. Schematic depiction of an aortic tube graft used to repair an aortic aneurysm. B. Intraoperative image of an aortic tube graft reconstruction.Advantages and Risks of Open Abdominal Aortic Aneu-rysm Repair. The main advantage of a conventional open repair is that the AAA is permanently eliminated because it is entirely replaced by a prosthetic aortic graft. The risk of aneurysm recurrence or delayed rupture no longer exists. As a result, long-term imaging surveillance is not needed with these patients. In contrast, the long-term efficacy of endovascular repair remains unclear. Consequently, long-term imaging sur-veillance is critical to ensure that the aortic aneurysm remains properly sealed by the stent graft. Other potential advantages of open repair include direct assessment of the circulatory integrity of the colon. If signs of colonic ischemia become evident after aortic bypass grafting, a concomitant mesenteric artery bypass can be performed to revascularize the colonic circulation. In addition, open repair permits the surgeons to explore for other abdominal pathologies, such as gastrointestinal tumors, liver mass, or cholelithiasis.As for the risks associated with open repair, cardiac com-plications, in the form of either myocardial infarction or arrhyth-mias, remain the most common morbidity, with an incidence between 2% and 6%.51 Another significant complication is renal failure or transient renal insufficiency as a result of peri-operative hypotension, atheromatous embolization, inadvertent injury to the ureter, preoperative contrast-induced nephropathy, or suprarenal aortic clamping. Although the incidence of renal failure is less than 2% in elective aneurysm repair, it can occur in more than 20% of patients after repair of a ruptured AAA.49Ischemic colitis is a devastating potential complication after open repair. The likelihood of such a complication is highest in those who had a prior colon resection and undergo repair of a ruptured AAA, due to the loss of collateral blood supply to the rectosigmoid colon. It is estimated that 5% of patients who undergo elective aneurysm repair will develop partial-thickness ischemic colitis but without significant clini-cal sequelae.52 However, if the partial-thickness ischemia pro-gresses to full-thickness gangrene and peritonitis, mortality can be as high as 90%.52The incidence of prosthetic graft infection ranges between 1% and 4% after open repair.53 It is more common in those who undergo repair of a ruptured AAA. If the prosthetic graft is not fully covered by the aneurysm sac or retroperitoneum, intestinal adhesion with subsequent bowel erosion may occur, resulting in an aortoenteric fistula. The predominant sign of such a com-plication is massive hematemesis, and it typically occurs years after the operation. Despite these potential complications, how-ever, the majority of patients who undergo successful elective open repair have an uneventful recovery.Endovascular Repair of Abdominal Aortic AneurysmOver a decade has passed since the first report of human implan-tation of a homemade stent graft for endovascular repair of an AAA by Parodi in 1991.11 Several prospective clinical trials across different devices and analysis of large Medicare adminis-trative databases and meta-analyses of published literature have consistently demonstrated significantly decreased operative time, blood loss, hospital length of stay, and overall periopera-tive morbidity and mortality of endovascular repair compared Brunicardi_Ch23_p0897-p0980.indd 92227/02/19 4:14 PM 923ARTERIAL DISEASECHAPTER 23Figure 23-31. Intraoperative view of a bifurcated graft used to repair an aortic aneurysm.with open surgical repair. For patients who are at increased risk for surgery because of age or comorbidity, endovascular repair is a superior minimally invasive alternative.The principle of endovascular repair of AAA involves the implantation of an aortic stent graft that is fixed proximally and distally to nonaneurysmal aortoiliac segment and thereby endoluminally excluding the aneurysm from the aortic circu-lation (Fig. 23-32). Unlike open surgical repair, the aneurysm BAFigure 23-32. A. An aortogram dem-onstrating a large infrarenal abdominal aortic aneurysm. B. Following endovas-cular stent graft implantation, the aortic aneurysm is successfully excluded.sac is not resected, which is subjected for potential aneurysm expansion or even rupture. Importantly, aortic branches, such as lumbar arteries or the inferior mesenteric artery (IMA), are occluded, which can lead to persistent aneurysm pressurization and aneurysm expansion. Currently, there are more than fifteen different endovascular devices approved for clinical use for infrarenal aortic aneurysm implantation throughout the world. Despite some differences in physical appearance, mechanical properties, and endograft materials, these endovascular devices will be discussed collectively for this chapter. Most of these devices are modular devices consisting of a primary device or main body and one or two iliac limbs that insert into the main body to complete the repair. Depending on the device, there are varying degrees of flexibility in the choice of iliac limbs that can be matched to the main body, which can impact the customiz-ability for a particular anatomy.A severe limitation of the endovascular repair devices is the need for adequate proximal neck to achieve a durable seal-ing zone. Several techniques have been proposed to overcome this limitation. These include fenestrated or branched endografts and the “chimney,” “snorkel,” and “periscope” techniques. The fenestrated stent grafts rely on precise alignment between the fen-estration and the corresponding visceral artery.12,54 Multiple clinical trials using customized fenestrated stent graft for the treatment of short-necked and juxtarenal aortic aneurysm repair have shown promising shortand mid-term results.54,55 How-ever, fenestrated stent graft generally requires device customiza-tion which is accessible only to high volume tertiary institutions, and not widely available to all hospital facilities. Alternatively, some centers have reported good results with intraoperative surgeon-modified endograft to create fenestrations for the treat-ment of complex aortic aneurysms in high-risk patients.56 Fur-ther development of the fenestrated techniques also opens the way for endovascular treatment of suprarenal and thoracoab-dominal aneurysm.57 The review of literature showed that open surgery remains a safe and effective treatment option for good-risk patients with juxtarenal aortic aneurysm.58 Fenestrated endovascular repair is associated with low mortality and com-pares favorably with open surgery in terms of morbidity, espe-cially renal function impairment and cardiac complications.59Brunicardi_Ch23_p0897-p0980.indd 92327/02/19 4:14 PM 924SPECIFIC CONSIDERATIONSPART IIPatient Selection for Endovascular Aortic Aneurysm Repair. Anatomic eligibility for endovascular repair is mainly based on three areas: the proximal aortic neck, common iliac arteries, and external iliac and common femoral arteries, which relate to the proximal and distal landing zones or fixation sites and the access vessels, respectively. The requirements for the proximal aortic neck are a diameter of 18 to 28 mm and a mini-mum length of 15 mm (Table 23-9). Usually, multiple measure-ments of the diameter are taken along the length of the neck to assess its shape. All diameter measurements are mid-wall to mid-wall of the vessel. Secondary considerations include mural calcifications (<50% circumference), luminal thrombus (<50% circumference), and angulation (<45°). Presence of a significant amount of any one of these secondary features in combination with a relatively short proximal neck may compromise success-ful shortand long-term fixation of the stent graft and exclusion of the aneurysm. The usual distal landing zone is the common iliac artery. The external iliac artery may serve as an alternate site when the ipsilateral common iliac artery is aneurysmal or ectatic. The treatable diameters of common iliac arteries range from 8 to 20 mm, and there should be at least 20 mm of patent artery of uniform diameter to allow adequate fixation. Finally, at least one of two common femoral and external iliac arteries must be at least 7 mm in diameter in order to safely introduce the main delivery sheath. Slightly smaller iliac diameters may be tolerated depending on the specific device and in the absence of severe tortuosity and calcific disease. Difficult access is one of the main causes of increased procedural time and intraopera-tive complications. Using these criteria, approximately 60% of all AAAs are anatomic candidates for endovascular repair.The next step in the preoperative planning is device selec-tion. Typically, the proximal diameter of the main device is oversized by 10% to 20% of the nominal diameter of the aor-tic neck. Distally, the iliac limbs are oversized by 1 to 4 mm depending on the individual device’s instructions for use. The biggest challenge to proper device selection remains determin-ing the optimal length from the renal arteries to the hypogastric arteries. Despite availability of sophisticated three-dimensional reconstructions, the exact path that a device will take from the proximal aortic neck to the distal iliac arteries is difficult to pre-dict. It is dependent on a host of factors related to the mechanical properties of the stent graft and the morphology of the aortoiliac flow lumen. “Plumb-line” measurements of axial CT images can be quite inaccurate, typically grossly underestimating the Table 23-9Ideal characteristics of an aneurysm for endovascular abdominal aortic aneurysm repairNeck length (mm)>15Neck diameter (mm)>18, <32Aortic Neck angle (degrees)<60Neck mural calcification  (% circumference)<50Neck luminal thrombus  (% circumference)<50Common iliac artery diameter (mm)Between 8 and 20Common iliac artery length (mm)>20External iliac artery diameter (mm)>7length, whereas center-line measurements usually overestimate the length. Angiographic measurements using a marker catheter are invasive, require contrast and radiation exposure, and are also inaccurate because they fail to account for the stiffness of the stent graft. The consequences of not choosing the correct length of the device include inadvertent coverage of the hypo-gastric artery if too long and the need for additional devices if too short.Advantages and Risks of Endovascular Repair. The obvi-ous advantage of an endovascular AAA repair is its minimally invasive nature. Typically, patients who undergo this procedure stay in the hospital for only 1 to 3 days, in contrast to the 5to 10-day stay required after conventional open surgical repair. In our institution, patients who have had an endovascular repair are routinely transferred to a general vascular ward from the post-anesthesia recovery unit, avoiding admission to a more costly intensive care unit.Because an abdominal incision is not necessary in endo-vascular repair, the procedure is particularly beneficial in patients with severe pulmonary disease, such as chronic obstruc-tive pulmonary disease or emphysema. Patients can sustain ade-quate breathing in the postoperative period, avoiding respiratory complications or prolonged mechanical ventilation. Because the abdominal cavity has not been entered, the risk of gastro-intestinal complications, such as ileus, ventral hernia, or bowel obstruction due to intestinal adhesion, is also greatly reduced. Moreover, regional or epidural anesthesia can be used, avoid-ing the risks associated with general anesthesia in patients with severe cardiopulmonary dysfunction.Despite its many advantages, endovascular repair does have potential complications. Since the stent graft device is attached endoluminally within the abdominal aorta, an endoleak due to incomplete stent graft exclusion of the aneurysm can occur. With this type of leak, blood flow persists outside the lumen of the endoluminal graft but within an aneurysm sac. A meta-analysis of 1118 patients who underwent successful endo-vascular repair found an endoleak incidence of 24%.60 Although a small endoleak usually poses little clinical significance because it will typically become thrombosed spontaneously, a large or persistent endoleak may lead to continuous aneurysm perfusion and ultimately to aneurysm rupture. The rupture rate following an endovascular AAA repair has been reported to be less than 0.8%.61Stent graft iliac limb dysfunction resulting in thrombosis has been reported following endovascular repair. One possible cause is aneurysm remodeling, resulting in a shortening in the aortic length, which can cause the stent graft to kink. Alterna-tively, progression of an underlying iliac atherosclerotic lesion may cause compression of the iliac limb and ultimately result in graft-limb occlusion. Treatment options include thrombolysis or graft thrombectomy to determine the underlying cause and possibly additional stent graft placement. Renal artery occlusion may occur due to improper stent graft positioning or migration.62 Graft limb separation or dislocation has also been reported.62In patients with AAA and concurrent iliac artery aneu-rysms who undergo preoperative coil embolization of the inter-nal iliac artery, 20% to 45% experience symptoms of pelvic ischemia.63 These symptoms may include buttock claudication, impotence, gluteal skin sloughing, and colonic ischemia. Other complications pertaining to endovascular repair relate to the access site and include groin hematoma and wound infection. Brunicardi_Ch23_p0897-p0980.indd 92427/02/19 4:14 PM 925ARTERIAL DISEASECHAPTER 23Occasionally, the stent graft device can malfunction by either failing to deploy or dislodging during the deployment proce-dure. If the device cannot be salvaged or rescued endoluminally, open surgical repair of the aneurysm may be necessary.Technical Considerations of Endovascular Aortic Aneu-rysm Repair. Although endovascular AAA repair may be performed in any venue with appropriate digital fluoroscopic imaging capability, due to the need for absolute sterility and aseptic technique, it is most safely performed in a surgical suite. The patient is prepped and draped just as in open AAA repair. Patients with renal insufficiency should be started on periopera-tive oral N-acetylcysteine (Mucomyst) and sodium bicarbonate infusion to reduce the risk of contrast nephropathy. A variety of anesthetic options may be used. Regional anesthesia may be appropriate for patients with pulmonary disease. There are reports of success with local anesthetics alone, as the incisions are typically smaller than a typical open inguinal hernia repair.64Groin access for endovascular aortic aneurysm repair can be achieved by either surgical cutdown for femoral artery expo-sure or percutaneous approach using “preclose” technique with the Perclose suture-mediated vascular closure device (Abbott Perclose, Redwood City, CA). Review of reported series on this percutaneous technique suggest a technical success rate of 95% for medium-size sheaths ranging from 12 to 16 French, and 87% success for 18to 24-French sizes.65 Once femoral artery access is obtained followed by introducer sheath placement, initial soft-tipped starter guidewires are exchanged for stiff guidewires that are advanced to the thoracic arch. Intravenous heparin at 80 IU/kg are administered, and the activated clotting time is maintained at 200 to 250 seconds. These guidewires provide the necessary support for the subsequent introduction of the large-diameter delivery catheters and devices. In the absence of special anatomic considerations, the primary device is inserted through the right side and the contralateral iliac limb is inserted through the left side. After administration of heparin, the deliv-ery catheter or the introducer sheath is advanced to the L1-L2 vertebral space, which typically marks the location of the renal arteries. An angiographic catheter is advanced from the contra-lateral femoral artery to the same level.A road-mapping aortogram is obtained to localize the renal arteries. The primary device is rotated to the desired ori-entation and deployed immediate below the lowest renal artery (Fig. 23-33). The angiographic catheter is replaced with a direc-tional catheter and an angled guidewire, and the opening for the contralateral limb on the main device is cannulated. Intrastent passage of the guidewire is confirmed, and the angled guidewire is replaced with a stiff guidewire. The contralateral iliac limb is inserted into the docking opening of the primary device and deployed. A completion angiogram is performed looking for patency of the renal and hypogastric arteries, the device limbs, proximal and distal fixation, and endoleak. Adjunctive interven-tions including additional devices, balloons, and bare stents are performed as needed. The procedure is concluded with routine repairs of the femoral arteries and closure of the groin incisions. The patients recover in the recovery room for 2 to 4 hours and admitted to the general care floor. Although in the past, patients were admitted to the intensive care unit, this is rarely needed. Most patients can be started on a regular diet that evening and discharged the next morning.Surveillance Following Endovascular Aortic Aneurysm Repair. Life-long follow-up is essential to the long-term ADCBFigure 23-33. A. During an endovascular aortic aneurysm repair, the main endograft device is inserted through a femoral artery approach. B. The device is deployed in the aorta just below the renal arteries. C. A contralateral iliac endograft device is inserted through a contralateral gate opening, which is next deployed.  D. Completion of deployment of the endograft device should fully exclude an aortic aneurysm while preserving flow of the renal and hypogastric arteries.success after endovascular AAA repair. Indeed, one may go so far as to say that absence of appropriate follow-up is tantamount to not having had a repair at all. A triple-phase (noncontrast, contrast, and delayed) spiral CT scan and a four-view (antero-posterior, lateral, and two obliques) abdominal X-ray should be obtained within the first month. Subsequent imaging can be obtained at 6-month intervals in the first 1 to 2 years and yearly thereafter. After the first 6 months, patients who cannot travel easily may obtain their studies locally and submit them for review. The CT scan is for detection of endoleaks, subtle proxi-mal migrations, and changes in aneurysm size. The abdominal X-ray gives a “birds-eye” view of the overall morphology of the stent graft. Subtle changes in conformation of the iliac limbs relative to each other and/or the spine can provide early signs of impending component separation or loss of fixation. Further, stent fractures and/or suture breaks that can compromise long-term device integrity can sometimes only be detected on a plain film and not on a CT scan.Results From Clinical Studies Comparing Endovascular Versus Open RepairThe primary success rate after endovascular repair of AAA has been reported to be as high as 95%.41 The less invasive nature Brunicardi_Ch23_p0897-p0980.indd 92527/02/19 4:14 PM 926SPECIFIC CONSIDERATIONSPART IIof this procedure is appealing to many physicians and patients. In addition, virtually all reports indicate a decreased blood loss, transfusion requirements, and length of intensive care unit and hospital stay for endovascular repair of AAAs compared with the standard surgical approach.47 With the advent of bifurcated grafts and improved delivery systems in the future, the only real limitation will be cost. When evaluating the literature for results from clinical series, it is important to look at a comparison of endoluminal versus open repair and device-specific outcome and cost analysis studies.Early reports on results with endovascular repair were often flawed due to selection biases. This is because from its inception, endovascular repair has been used mostly in patients who are at higher risk for open repair. At the same time, only patients with favorable anatomy including less tortuosity and the presence of a suitable infrarenal neck were considered for endovascular repair. Randomization is also difficult because most patients who anatomically qualify for endovascular repair would withdraw from the study if randomized to open repair. Consequently, there are very few randomized controlled tri-als that have compared outcomes in patients with similar risk factors and anatomy who are eligible for both types of repair. Two such European trials have recently published short-term outcome data that are unbiased in design.The DREAM trial is a multicenter randomized trial that compared open versus endovascular repair among a group of 345 patients at 28 European centers using multiple different devices including Gore, AneuRx, and Zenith.66 Patients were included only if they were considered to be candidates for both types of repairs. The operative mortality rate was 4.6% in the operative group versus 1.2% in the endoluminal group at  30 days. When looking at the combined rate of operative mor-tality and severe complications, there was an incidence of 9.8% in the open repair group versus 4.7% in the endoluminal group. The difference here was largely due to the higher frequency of pulmonary complications seen in the open group. There was a higher incidence of graft-related complications in the endolu-minal group. There was no difference in the nonvascular local complication rate among the two groups. The Endovascular Repair-1 (EVAR-1) trial is also a multicenter randomized trial that compared open to endoluminal repair.67 This study was con-ducted on 1082 patients at 34 centers in the United Kingdom using all available devices. Short-term mortality at 30 days was 4.7% in the open group and 1.7% in the endoluminal group. The in-hospital mortality rate was also increased in the open when compared to the endoluminal group (6.2% vs. 2.1%). As expected, the secondary intervention rate was higher in the endoluminal group (9.8% vs. 5.8%). Complication rates were not reported in the EVAR-1 trial. Criticisms can be applied to both of these trials. Patients had to be eligible for either type of repair in order to be included in the study. Consequently, these findings cannot be generalized to patients who are too sick to undergo open surgery or to patients whose anatomy precludes them from undergoing endovascular repair.The Open Versus Endovascular Repair (OVER) Veter-ans Affairs Cooperative Study Group randomly assigned 881 patients with asymptomatic AAAs who were candidates for both procedures to either endovascular repair (n = 444) or open repair (n = 437) and followed them for up to 9 years.68 Reduction in perioperative mortality with endovascular repair was sustained at 3 years but not thereafter. There was no difference in pri-mary outcome of all-cause mortality. Endovascular repair and open repair resulted in similar long-term survival. Six aneurysm ruptures were confirmed in the endovascular repair group ver-sus none in the open repair group. Rupture after endovascular repair remains a concern. A significant interaction was observed between age and type of treatment. Endovascular repair led to increased long-term survival among younger patients but not among older patients, for whom a greater benefit from the endo-vascular approach had been expected.Device-Specific Outcome. Matsumura and associates com-pared endoluminal versus open repair using the Excluder device.69 In their review, they demonstrated a 30-day mortality rate of 1% along with endoleak rates of 17% and 20% at 1and 2-year intervals, respectively. The limb narrowing, limb migra-tion, and trunk migration were all 1% at 2 years. There were no deployment failures or early conversions. There was an annual 7% reintervention rate. Aneurysm growth was demonstrated in 14% of patients at 2 years. The Zenith device by Cook has been studied by Greenberg and associates, who compared standard surgical repair with endoluminal repair in low-risk patients and endoluminal repair in high-risk patients.70 They reported a 30-day mortality rate of 3.5%, which was equal to the open group. The endoleak rates were 7.4% and 5.4% at 1and 2-year intervals, respectively. There was a 5.3% migration of 5 mm at 1 year. Freedom from rupture was 100% in the low-risk group and 98.9% in the high-risk endoluminal group at 2 years. Expe-rience with the AneuRx device has been reported by Zarins.71 In this 4-year review, they found a 30-day mortality rate of 2.8%. Endoleak rate at 4 years was 13.9%, aneurysm enlargement was 11.5%, and stent graft migration was 9.5%. Freedom from rup-ture was noted to be 98.4% at 4 years. Criado and associates have reported on their 1-year experience with the Talent LPS device by Medtronic.72 They report a 30-day mortality rate of 0.8%. Endoleak rate was 10%. Three deployment failures were noted, and freedom from rupture was 100%. Aneurysm growth and migration rates were divided into three different neck size groups. Patients with a wide neck (>26 mm) had a 3% growth and migration rate. Narrow-neck patients (<26 mm) had a 1% growth rate and a 2% migration neck. Interestingly, short-neck patients (<15 mm) had no aneurysm growths and a 2% migra-tion rate.Cost Analysis. The current climate of cost containment and limited reimbursement for healthcare services mandates a criti-cal analysis of the economic impact of any new medical technol-ogy on the market. The in-hospital costs for both endovascular and open repair include graft cost, operating room fees, radiol-ogy, pharmacy, ancillary care, intensive care unit charges, and floor charges. Despite the improved morbidity and mortality rates, several early studies have reported no cost benefit with the application of endovascular repair.73,74 The limiting factor appears to be the cost of the device. Despite commercializa-tion of endovascular repair, the device costs are still in the range of $5000 to $6000 with no signs of abating. A report by Angle and associated further corroborates previous studies.75 In their review, despite decreased hospital and intensive care unit stays and utilization of pharmacy and respiratory services, cost of endovascular repair was 1.74 times greater than the stan-dard surgical approach. In addition, these cost analysis stud-ies are centered on in-hospital costs and do not even begin to address secondary costs such as postoperative surveillance that is required with endovascular repair. In the OVER trial, endo-vascular repair was found to be a cost-effective alternative to Brunicardi_Ch23_p0897-p0980.indd 92627/02/19 4:14 PM 927ARTERIAL DISEASECHAPTER 23open repair in the U.S. Veterans Affairs healthcare system for at least the first 2 years.76 The primary outcomes were mean total healthcare cost per life-year and per quality-adjusted life-year. There were no differences found in survival, quality of life, and costs after 2 years between the endovascular and the open group. Although graft costs were higher in the endovas-cular group, length of stay was shorter, resulting in lower cost of AAA repair hospitalization in the endovascular group. Costs remained lower after 2 years in the endovascular group, but the difference was no longer significant.Classification and Management of EndoleakAn endoleak is an extravasation of contrast outside the stent graft and within the aneurysm sac (Fig. 23-34). It can be pres-ent in up to 20% to 30% of all endovascular AAA repairs in the early postoperative period.77,78 In general, over half of these endoleaks will resolve spontaneously during the first 6 months, resulting in a 10% incidence of chronic endoleaks in all cases beyond the first year of follow-up. Endoleaks can be detected using conventional angiography, contrast CT (Fig. 23-35), MRA, and color-flow duplex ultrasound. Although there is no recognized gold standard, in practice, angiography is consid-ered the least sensitive but most specific for characterizing the Type I endoleak Type II endoleak Type III endoleak Type IV endoleakFigure 23-34. The four types of endoleak include the following: type I endoleak = attachment site leak; type II endoleak = side branch leak caused by lumbar or side branches; type III endoleak = endograft junctional leak due to overlapping device components; and type IV endoleak = endograft fabric or porosity leak.Figure 23-35. A computed tomography scan demonstrating an endoleak (small arrow) as evidenced by contrast flow outside the aortic endograft (long arrow).source of the endoleak, whereas the CT scan is the most sensi-tive but least specific. Widespread availability and reliability that is relatively independent of technique have made the CT scan the de facto standard imaging modality for postoperative surveillance. Conversely, routine use of duplex ultrasound and MRA has been limited by the lack of proper equipment and local expertise. On the other hand, investigational techniques such as time-resolved MRA may provide greater sensitivity and specificity than either angiography or CT in the future.Four types of endoleaks have been described (Table 23-10). Type I endoleak refers to fixation-related leaks that occur at the proximal or distal attachment sites. These represent less than 5% of all endoleaks and are seen as an early blush of contrast into the aneurysm sac from the proximal or distal ends of the device during completion angiography.77,78 Although seen as marker of poor patient selection or inadequate repair, over 80% of these leaks spontaneously seal in the first 6 months. Persistent type I endoleaks, on the other hand, require prompt treatment. Type II endoleak refers to retrograde flow originating from a lumbar, inferior mesenteric, accessory renal, or hypogastric artery. They are the most common type of endoleak, accounting for 20% to 30% of all cases, and about half resolve spontaneously. On angi-ography, they are seen as a late filling of the aneurysm sac from a branch vessel(s). Type II endoleaks carry a relatively benign natural history and do not merit intervention unless associated with aneurysm growth. Type III endoleaks refer to failure of device integrity or component separation from modular sys-tems. If detected intraoperatively or in the early perioperative period, it is usually from inadequate overlap between two stent Table 23-10Endoleak classificationCLASSIFICATIONDESCRIPTIONType I endoleakAttachment site leakType II endoleakSide branch leak caused by lumbar or inferior mesenteric arteriesType III endoleakJunctional leak (of overlapping endograft components) and graft fabric defectType IV endoleakEndograft fabric porosity leakBrunicardi_Ch23_p0897-p0980.indd 92727/02/19 4:14 PM 928SPECIFIC CONSIDERATIONSPART IIgrafts, whereas in the late period, the endoleak may be from a fabric tear or junctional separation from conformational changes of the aneurysm. Regardless of the etiology or timing, these should be promptly repaired. Finally, type IV endoleak refers to the diffuse, early blush seen during completion angiography due to graft porosity and/or suture holes of some Dacron-based devices. It does not have any clinical significance and usually cannot be seen after 48 hours and heparin reversal. Endoleaks that are initially considered type IV but persist become type III endoleaks by definition because this indicates a more significant material defect than simple porosity or a suture hole.Endotension Following Endovascular Aortic Aneurysm Repair. In approximately 5% of cases after an apparently suc-cessful endovascular repair, the aneurysm continues to grow without any demonstrable endoleak.79,80 This phenomenon has been described as endotension. Although it was initially thought that an endoleak was really present but simply not detected, case have been reported where the aneurysm has been surgically opened and the contents were completely devoid of any blood and no extravasation could be found. The mechanism of con-tinued pressurization of the aneurysm sac following successful exclusion from the arterial circulation remains unsolved at this time. One putative mechanism has been linked to a transuda-tive process related to certain expanded PTFE graft materials.81 More importantly, however, the natural history of these enlarg-ing aneurysms without endoleaks is unknown, but to date, there has been no evidence to suggest that they carry an increased risk of rupture. Conservatively speaking, until further long-term data become available, if the patient is a suitable surgical risk, elec-tive open conversion should be considered.Secondary Interventions Following Endovascular Aortic Aneurysm Repair. There is approximately 10% to 15% per year risk of secondary interventions following endovascular AAA repair.62 These procedures are critical in the long-term success of the primary procedure in prevention of aneurysm rup-ture and aneurysm-related death. These secondary procedures, in order of frequency, include proximal or distal extender place-ment for migrations, highly selective or translumbar emboliza-tion for type II endoleaks, direct surgical or laparoscopic branch vessel ligations, bridging cuffs for component separations, and late open surgical conversions.Multiple large series have reported that an annual rupture rate of approximately 1% to 1.5% per year after endovascular repair.82,83 The EUROSTAR registry reports a rupture rate of 2.3% over 15.4 months in patients with an endoleak, compared with 0.3% in those without.82,83 Various causes of late ruptures have been reported in the literature, although presence of a per-sistent endoleak with aneurysm enlargement remains a com-mon culprit for this complication. It has been shown that even successfully excluded aneurysms can lead to the development of attachment-site leaks and device failure, caused in part by aneurysm remodeling resulting in stent migration or kinking. Mehta and colleagues reported that 63% of delayed AAA rup-tures after endovascular repair were caused by type I endoleaks with endograft migration, 11% by type I without migration, 19% by type II, and the rest of unknown type.84Treatment of rupture may be open conversion or endo-vascular stent graft placement. May and associates reported a mortality rate of 43% in those patients who underwent open conversion.85 Emergent endovascular repair should be consid-ered in these patients since it is potentially much faster and less likely to cause physiologic stress than open conversion. Several reports have shown that endovascular repair can be performed successfully in patients previously treated with endoluminal prostheses.80,86MESENTERIC ARTERY DISEASEVascular occlusive disease of the mesenteric vessels is a rela-tively uncommon but potentially devastating condition that gen-erally presents in patients over 60 years of age, is three times more frequent in women, and has been recognized as an entity since 1936.87 The incidence of such a disease is low and repre-sents 2% of the revascularization operations for atheromatous lesions. The most common cause of mesenteric ischemia is atherosclerotic vascular disease. Autopsy studies have dem-onstrated splanchnic atherosclerosis in 35% to 70% of cases.88 Other etiologies exist and include FMD, panarteritis nodosa, arteritis, and celiac artery compression from a median arcuate ligament, but they are unusual and have an incidence of one in nine compared with that of atherosclerosis.Chronic mesenteric ischemia is related to a lack of blood supply in the splanchnic region and is caused by disease in one or more visceral arteries: the celiac trunk, the superior mesen-teric artery, and the IMA. Mesenteric ischemia is thought to occur when two of the three visceral vessels are affected with severe stenosis or occlusion; however, in as many as 9% of cases, only a single vessel is involved (SMA in 5% and celiac trunk in 4% of cases).89 This disease process may evolve in a chronic fashion, as in the case of progressive luminal oblitera-tion due to atherosclerosis. On the other hand, mesenteric isch-emia can occur suddenly, as in the case of thromboembolism. Despite recent progress in perioperative management and bet-ter understanding of pathophysiology, mesenteric ischemia is considered one of the most catastrophic vascular disorders with mortality rates ranging from 50% to 75%. Delays in diagnosis and treatment are the main contributing factors in its high mor-tality. It is estimated that mesenteric ischemia accounts for 1 in every 1000 hospital admissions in this country. The prevalence is rising due in part to the increased awareness of this disease, the advanced age of the population, and the significant comor-bidity of these elderly patients. Early recognition and prompt treatment before the onset of irreversible intestinal ischemia are essential to improve the outcome.Anatomy and PathophysiologyMesenteric arterial circulation is remarkable for its rich collat-eral network. Three main mesenteric arteries provide the arterial perfusion to the gastrointestinal system: the celiac artery (CA), the superior mesenteric artery (SMA), and the IMA. In gen-eral, the CA provides arterial circulation to the foregut (distal esophagus to duodenum), hepatobiliary system, and spleen; the SMA supplies the midgut (jejunum to mid-colon); and the IMA supplies the hindgut (mid-colon to rectum). The CA and SMA arise from the ventral surface of the infradiaphragmatic supra-renal abdominal aorta, whereas the IMA originates from the left lateral portion of the infrarenal aorta. These anatomic origins in relation to the aorta are important when a mesenteric angio-gram is performed to determine the luminal patency. In order to fully visualize the origins of the CA and SMA, it is necessary to perform both an anteroposterior and a lateral projection of the aorta since most arterial occlusive lesions occur in the proximal segments of these mesenteric trunks.Brunicardi_Ch23_p0897-p0980.indd 92827/02/19 4:14 PM 929ARTERIAL DISEASECHAPTER 23Because of the abundant collateral flow between these mesenteric arteries, progressive diminution of flow in one or even two of the main mesenteric trunks is usually tolerated, provided that uninvolved mesenteric branches can enlarge over time to provide sufficient compensatory collateral flow. In contrast, acute occlusion of a main mesenteric trunk may result in profound ischemia due to lack of sufficient collateral flow. Collateral networks between the CA and the SMA exist primarily through the superior and inferior pancreaticoduodenal arteries. The IMA may provide collateral arterial flow to the SMA through the marginal artery of Drummond, the arc of  Riolan, and other unnamed retroperitoneal collateral vessels termed meandering mesenteric arteries (Fig. 23-36). Lastly, collateral visceral vessels may provide important arterial flow to the IMA and the hindgut through the hypogastric arteries and the hemorrhoidal arterial network.Regulation of mesenteric blood flow is largely modulated by both hormonal and neural stimuli, which characteristically regulate systemic blood flow. In addition, the mesenteric cir-culation responds to the gastrointestinal contents. Hormonal regulation is mediated by splanchnic vasodilators, such as nitric oxide, glucagon, and vasoactive intestinal peptide. Certain intrinsic vasoconstrictors, such as vasopressin, can diminish the mesenteric blood flow. On the other hand, neural regulation is provided by the extensive visceral autonomic innervation.Clinical manifestation of mesenteric ischemia is pre-dominantly postprandial abdominal pain, which signifies that the increased oxygen demand of digestion is not met by the gastrointestinal collateral circulation. The postprandial pain fre-quently occurs in the mid-abdomen, suggesting that the diver-sion of blood flow from the SMA to supply the stomach impairs perfusion to the small bowel. This leads to transient anaerobic metabolism and acidosis. Persistent or profound mesenteric ischemia will lead to mucosal compromise with release of intra-cellular contents and by-products of anaerobic metabolism to Figure 23-36. An aortogram showing a prominent collateral ves-sel, which is the arc of Riolan (arrow) in a patient with an inferior mesenteric artery (IMA) occlusion. This vessel network provides collateral flow between the superior mesenteric artery and IMA.the splanchnic and systemic circulation. Injured bowel mucosa allows unimpeded influx of toxic substances from the bowel lumen with systemic consequences. If full-thickness necrosis occurs in the bowel wall, intestinal perforation ensues, which will lead to peritonitis. Concomitant atherosclerotic disease in cardiac or systemic circulation frequently compounds the diag-nostic and therapeutic complexity of mesenteric ischemia.Types of Mesenteric Artery Occlusive DiseaseThere are three major mechanisms of visceral ischemia involv-ing the mesenteric arteries: (a) acute mesenteric ischemia, which can be either embolic or thrombotic in origin; (b) chronic mes-enteric ischemia; and (c) nonocclusive mesenteric ischemia. Despite the variability of these syndromes, a common anatomic pathology is involved in these processes. The superior mesen-teric artery (SMA) is the most commonly involved vessel in acute mesenteric ischemia. Acute thrombosis occurs in patients with underlying mesenteric atherosclerosis, which typically involves the origin of the mesenteric arteries while sparing the collateral branches. In acute embolic mesenteric ischemia, the emboli typically originate from a cardiac source and frequently occur in patients with atrial fibrillation or following myocar-dial infarction (Figs. 23-37 and 23-38). Nonocclusive mesen-teric ischemia is characterized by a low flow state in otherwise normal mesenteric arteries and most frequently occurs in criti-cally ill patients on vasopressors. Finally, chronic mesenteric ischemia is a functional consequence of a long-standing ath-erosclerotic process that typically involves at least two of the three main mesenteric vessels. The gradual development of the occlusive process allows the development of collateral ves-sels that prevent the manifestations of acute ischemia, but are not sufficient to meet the high postprandial intestinal oxygen requirements, giving rise to the classical symptoms of postpran-dial abdominal pain and the resultant food fear.Several less common syndromes of visceral ischemia involving the mesenteric arteries can also cause serious debili-tation. Chronic mesenteric ischemic symptoms can occur due Figure 23-37. An anteroposterior view of a selective superior mesenteric artery angiogram shows an abrupt cutoff of the middle colic artery, which was caused by emboli (arrow) due to atrial fibrillation.Brunicardi_Ch23_p0897-p0980.indd 92927/02/19 4:14 PM 930SPECIFIC CONSIDERATIONSPART IIFigure 23-38. A lateral mesenteric angiogram showing an abrupt cutoff of the proximal superior mesenteric artery (SMA), which is consistent with SMA embolism (arrow).to extrinsic compression of the celiac artery by the diaphragm, which is termed median arcuate ligament syndrome or celiac artery compression syndrome. Acute visceral ischemia may occur following an aortic operation, due to ligation of the IMA in the absence of adequate collateral vessels. Furthermore, acute visceral ischemia may develop in aortic dissection, which involves the mesenteric arteries, or after coarctation repair. Finally, other unusual causes of ischemia include mesenteric arteritis, radiation arteritis, and cholesterol emboli.Clinical ManifestationsAbdominal pain out of proportion to physical findings is the classic presentation in patients with acute mesenteric ischemia and occurs following an embolic or thrombotic ischemic event of the SMA. Other manifestations include sudden onset of abdominal cramps in patients with underlying cardiac or ath-erosclerotic disease, often associated with bloody diarrhea, as a result of mucosal sloughing secondary to ischemia. Fever, nausea, vomiting, and abdominal distention are some common but nonspecific manifestations. Diffuse abdominal tenderness, rebound, and rigidity are late signs and usually indicate bowel infarction and necrosis.Clinical manifestations of chronic mesenteric ischemia are more subtle due to the extensive collateral development. How-ever, when intestinal blood flow is unable to meet the physio-logic gastrointestinal demands, mesenteric insufficiency ensues. The classical symptoms include postprandial abdominal pain, food fear, and weight loss. Persistent nausea and occasionally diarrhea may coexist. Diagnosis remains challenging, and most of the patients will undergo an extensive and expensive gastro-intestinal tract workup for the above symptoms prior to referral to a vascular service.The typical patient who develops nonocclusive mesenteric ischemia is an elderly patient who has multiple comorbidities, such as congestive heart failure, acute myocardial infarction with cardiogenic shock, hypovolemic or hemorrhagic shock, sepsis, pancreatitis, and administration of digitalis or vasocon-strictor agents such as epinephrine. Abdominal pain is only present in approximately 70% of these patients. When present, the pain is usually severe but may vary in location, character, and intensity. In the absence of abdominal pain, progressive abdominal distention with acidosis may be an early sign of isch-emia and impending bowel infarction.Abdominal pain due to narrowing of the origin of the CA may occur as a result of extrinsic compression or impingement by the median arcuate ligament (Fig. 23-39). This condition is known as celiac artery compression syndrome or median arcuate ligament syndrome. Angiographically, there is CA compression that augments with deep expiration and poststenotic dilatation. The celiac artery compression syndrome has been implicated in some variants of chronic mesenteric ischemia. Most patients are young females between 20 and 40 years of age. Abdominal symptoms are nonspecific, but the pain is localized in the upper abdomen, which may be precipitated by meals.Diagnostic EvaluationThe differential diagnosis of acute mesenteric ischemia includes other causes of severe abdominal pain of acute onset, such as perforated viscus, intestinal obstruction, pancreatitis, cholecys-titis, and nephrolithiasis. Laboratory evaluation is neither sensitive nor specific in distinguishing these various diagnoses. Figure 23-39. A lateral projection of the magnetic resonance angi-ography of the aorta showing a chronic compression of the celiac artery by the median arcuate ligament (arrow).Brunicardi_Ch23_p0897-p0980.indd 93027/02/19 4:14 PM 931ARTERIAL DISEASECHAPTER 23In the setting of mesenteric ischemia, complete blood count may reveal hemoconcentration and leukocytosis. Metabolic acidosis develops as a result of anaerobic metabolism. Elevated serum amylase may indicate a diagnosis of pancreatitis but is also com-mon in the setting of intestinal infarction. Finally, increased lac-tate levels, hyperkalemia, and azotemia may occur in the late stages of mesenteric ischemia.Plain abdominal radiographs may provide helpful infor-mation to exclude other causes of abdominal pain such as intes-tinal obstruction, perforation, or volvulus, which may exhibit symptoms mimicking intestinal ischemia. Pneumoperitoneum, pneumatosis intestinalis, and gas in the portal vein may indicate infarcted bowel. In contrast, radiographic appearance of an ady-namic ileus with a gasless abdomen is the most common finding in patients with acute mesenteric ischemia.Upper endoscopy, colonoscopy, or barium radiogra-phy does not provide any useful information when evaluating acute mesenteric ischemia. Moreover, barium enema is con-traindicated if the diagnosis of mesenteric ischemia is being considered. The intraluminal barium can obscure accurate visu-alization of mesenteric circulation during angiography. In addi-tion, intraperitoneal leakage of barium can occur in the setting of intestinal perforation, which can lead to added therapeutic challenges during mesenteric revascularization.Diagnosis of chronic mesenteric ischemia can be more challenging. Usually prior to the evaluation by a vascular ser-vice, the patients have undergone an extensive workup for the symptoms of chronic abdominal pain, weight loss, and anorexia. Rarely, the vascular surgeon is the first to encounter a patient with the above symptoms. In this situation, it is advisable to keep in mind that mesenteric ischemia is a rare entity and that a full diagnostic workup that should include CT scan of the abdo-men and evaluation by gastroenterologist should be performed. Mesenteric occlusive disease may coexist with malignancy, and symptoms of mesenteric vessel stenosis may be the result of extrinsic compression by a tumor.Duplex ultrasonography is a valuable noninvasive means of assessing the patency of the mesenteric vessels. Moneta and associates evaluated the use of duplex ultrasound in the diag-nosis of mesenteric occlusive disease in a blinded prospective study.90,91 A peak systolic velocity in the SMA >275 cm/s dem-onstrated a sensitivity of 92%, specificity of 96%, and overall accuracy of 96% for detecting >70% stenosis. The same authors found sensitivity and specificity of 87% and 82%, respectively, with an accuracy of 82% in predicting >70% celiac trunk ste-nosis. Duplex has been successfully used for follow-up after open surgical reconstruction or endovascular treatment of the mesenteric vessels to assess recurrence of the disease. Finally, spiral CT with three-dimensional reconstruction (Fig. 23-40) and MRA (Fig. 23-41) have been promising in providing clear radiographic assessment of the mesenteric vessels.The definitive diagnosis of mesenteric vascular disease is made by biplanar mesenteric arteriography, which should be performed promptly in any patient with suspected mesenteric occlusion. It typically shows occlusion or near-occlusion of the CA and SMA at or near their origins from the aorta. In most cases, the IMA has been previously occluded secondary to dif-fuse infrarenal aortic atherosclerosis. The differentiation of the different types of mesenteric arterial occlusion may be sug-gested with biplanar mesenteric arteriogram. Mesenteric emboli typically lodge at the orifice of the middle colic artery, which creates a “meniscus sign” with an abrupt cutoff of a normal Figure 23-40. Computed tomography angiogram of the abdomen with three-dimensional reconstruction provides a clear view of the celiac artery, superior mesenteric artery (SMA), and inferior mes-enteric artery (IMA).Figure 23-41. A cross-sectional view of a magnetic resonance angiogram provides a clear view of the luminal patency of the supe-rior mesenteric artery.proximal SMA several centimeters from its origin on the aorta. Mesenteric thrombosis, in contrast, occurs at the most proximal SMA, which tapers off at 1 to 2 cm from its origin. In the case of chronic mesenteric occlusion, the appearance of collateral circulation is typically present. Nonocclusive mesenteric isch-emia produces an arteriographic image of segmental mesenteric vasospasm with a relatively normal-appearing main SMA trunk (Fig. 23-42).Mesenteric arteriography can also play a therapeutic role. Once the diagnosis of nonocclusive mesenteric ischemia is Brunicardi_Ch23_p0897-p0980.indd 93127/02/19 4:14 PM 932SPECIFIC CONSIDERATIONSPART IIFigure 23-42. Mesenteric arteriogram showing nonocclusive mes-enteric ischemia as evidenced by diffuse spasm of intestinal arcades with poor filling of intramural vessels.made on the arteriogram, an infusion catheter can be placed at the SMA orifice, and vasodilating agents, such as papaverine, can be administered intra-arterially. The papaverine infusion may be continued postoperatively to treat persistent vasospasm, a common occurrence following mesenteric reperfusion. Trans-catheter thrombolytic therapy has little role in the management of thrombotic mesenteric occlusion. Although thrombolytic agents may transiently recannulate the occluded vessels, the underlying occlusive lesions require definitive treatment. Fur-thermore, thrombolytic therapy typically requires a prolonged period of time to restore perfusion, during which the intestinal viability will be difficult to assess.A word of caution would be appropriate here regarding patients with typical history of chronic intestinal angina who present with an acute abdomen and classical findings of peri-toneal irritation. Arteriography is the gold standard for the diagnosis of mesenteric occlusive disease; however, it can be a time-consuming diagnostic modality. In this group of patients, immediate exploration for assessment of intestinal viability and vascular reconstruction is the best choice.Surgical RepairAcute Embolic Mesenteric Ischemia. Initial management of patients with acute mesenteric ischemia includes fluid resus-citation and systemic anticoagulation with heparin to prevent further thrombus propagation. Significant metabolic acidosis not responding to fluid resuscitation should be corrected with sodium bicarbonate. A central venous catheter, peripheral arte-rial catheter, and Foley catheter should be placed for hemody-namic status monitoring. Appropriate antibiotics are given prior to surgical exploration. The operative management of acute mesenteric ischemia is dictated by the cause of the occlusion. It is helpful to obtain a preoperative mesenteric arteriogram to confirm the diagnosis and to plan appropriate treatment options. However, the diagnosis of mesenteric ischemia frequently can-not be established prior to surgical exploration, and therefore, patients in a moribund condition with acute abdominal symp-toms should undergo immediate surgical exploration, avoiding the delay required to perform an arteriogram.The primary goal of surgical treatment in embolic mes-enteric ischemia is to restore arterial perfusion with removal of the embolus from the vessel. The abdomen is explored through a midline incision, which often reveals variable degrees of intestinal ischemia from the mid-jejunum to the ascending or transverse colon. The transverse colon is lifted superiorly, and the small intestine is reflected toward the right upper quad-rant. The SMA is approached at the root of the small bowel mesentery, usually as it emerges from beneath the pancreas to cross over the junction of the third and fourth portions of the duodenum. Alternatively, the SMA can be approached by incising the retroperitoneum lateral to the fourth portion of the duodenum, which is rotated medially to expose the SMA. Once the proximal SMA is identified and controlled with vascular clamps, a transverse arteriotomy is made to extract the embolus, using standard balloon embolectomy catheters. In the event the embolus has lodged more distally, exposure of the distal SMA may be obtained in the root of the small bowel mesentery by isolating individual jejunal and ileal branches to allow a more comprehensive thromboembolectomy. Following the restora-tion of SMA flow, an assessment of intestinal viability must be made, and nonviable bowel must be resected. Several methods have been described to evaluate the viability of the intestine, which include intraoperative intravenous fluorescein injection and inspection with a Wood’s lamp, and Doppler assessment of antimesenteric intestinal arterial pulsations. A second-look pro-cedure should be considered in many patients and is performed 24 to 48 hours following embolectomy. The goal of the proce-dure is reassessment of the extent of bowel viability, which may not be obvious immediately following the initial embolectomy. If nonviable intestine is evident in the second-look procedure, additional bowel resections should be performed at that time.Acute Thrombotic Mesenteric Ischemia. Thrombotic mesenteric ischemia usually involves a severely atheroscle-rotic vessel, typically the proximal CA and SMA. Therefore, these patients require a reconstructive procedure to the SMA to bypass the proximal occlusive lesion and restore adequate mesenteric flow. The saphenous vein is the graft material of choice, and prosthetic materials should be avoided in patients with nonviable bowel, due to the risk of bacterial contamina-tion if resection of necrotic intestine is performed. The bypass graft may originate from either the aorta or iliac artery. Advan-tages from using the supraceliac infradiaphragmatic aorta as opposed to the infrarenal aorta as the inflow vessel include a smoother graft configuration with less chance of kinking and the absence of atherosclerotic disease in the supraceliac aortic segment. Exposure of the supraceliac aorta is technically more challenging and time consuming than that of the iliac artery, which unless calcified is an appropriate inflow. Patency rates are similar regardless of inflow vessel choice.92Chronic Mesenteric Ischemia. The therapeutic goal in patients with chronic mesenteric ischemia is to revascularize mesenteric circulation and prevent the development of bowel infarction. Mesenteric occlusive disease can be treated successfully by either transaortic endarterectomy or mesenteric artery bypass. Brunicardi_Ch23_p0897-p0980.indd 93227/02/19 4:14 PM 933ARTERIAL DISEASECHAPTER 23Transaortic endarterectomy is indicated for ostial lesions of pat-ent CA and SMA. A left medial rotation is performed, and the aorta and the mesenteric branches are exposed. A lat-eral aortotomy is performed encompassing both the CA and SMA orifices. The visceral arteries must be adequately mobi-lized so that the termination site of endarterectomy can be visu-alized. Otherwise, an intimal flap may develop, which can lead to early thrombosis or distal embolization.For occlusive lesions located 1 to 2 cm distal to the mes-enteric origin, mesenteric artery bypass should be performed. Multiple mesenteric arteries are typically involved in chronic mesenteric ischemia, and both the CA and SMA should be revascularized whenever possible. In general, bypass grafting may be performed either antegrade from the supraceliac aorta or retrograde from either the infrarenal aorta or iliac artery. Both autogenous saphenous vein grafts and prosthetic grafts have been used with satisfactory and equivalent success. An antegrade bypass also can be performed using a small-caliber bifurcated graft from the supraceliac aorta to both the CA and SMA, which yields an excellent long-term result.93Celiac Artery Compression Syndrome. The decision to intervene in patients with CA compression syndrome should be based on both an appropriate symptom complex and the finding of celiac artery compression in the absence of other findings to explain the symptoms. The treatment goal is to release the ligamentous structure that compresses the proximal CA and to correct any persistent stricture by bypass grafting. Some sur-geons advocate careful celiac plexus sympathectomy in addition to arcuate ligament decompression to ensure good treatment  outcome.102 The patient should be cautioned that relief of the celiac compression cannot be guaranteed to relieve the symp-toms. In a number of reports on endovascular management of chronic mesenteric ischemia, the presence of CA compres-sion syndrome has been identified as a major factor of techni-cal failure and recurrence. Therefore, angioplasty and stenting should not be undertaken if extrinsic compression of the CA by the median arcuate ligament is suspected based on preop-erative imaging studies. Open surgical treatment should be performed instead. A study that analyzed the outcome of lapa-roscopic and open median arcuate ligament release cases in the literature showed both approaches to be effective in symptom relief (85%), with no difference in late symptom recurrence rate (6.8% in the open group and 5.7% in the laparoscopic group).94Endovascular TreatmentChronic Mesenteric Ischemia. Endovascular treatment of mesenteric artery stenosis or short segment occlusion by bal-loon dilatation or stent placement represents a less invasive therapeutic alternative to open surgical intervention, particu-larly in patients whose medical comorbidities place them at a high operative risk category. Endovascular therapy is also suited in patients with recurrent disease or anastomotic steno-sis following previous open mesenteric revascularization. Pro-phylactic mesenteric revascularization is rarely performed in the asymptomatic patient undergoing an aortic procedure for other indications. However, the natural history of untreated chronic mesenteric ischemia may justify revascularization in some minimally symptomatic or asymptomatic patients if the operative risks are acceptable, since the first clinical presenta-tion may be acute intestinal ischemia in as many as 50% of the patients, with a mortality rate that ranges from 15% to 70%.95 3This is particularly true when the SMA is involved. Mesenteric angioplasty and stenting is particularly suitable for this patient subgroup given its low morbidity and mortality. Because of the limited experience with stent use in mesenteric vessels, appro-priate indications for primary stent placement have not been clearly defined. Guidelines generally include calcified ostial stenoses, high-grade eccentric stenoses, chronic occlusions, and significant residual stenosis >30% or the presence of dissection after angioplasty. Restenosis after PTA is also an indication for stent placement.96Acute Mesenteric Ischemia. Catheter-directed thrombo-lytic therapy is a potentially useful treatment modality for acute mesenteric ischemia, which can be initiated with intra-arterial delivery of thrombolytic agent into the mesenteric thrombus at the time of diagnostic angiography. Various thrombolytic medi-cations, including urokinase (Abbokinase; Abbott Laboratory, North Chicago, IL) or recombinant tissue plasminogen acti-vator (Activase; Genentech, South San Francisco, CA), have been reported to be successful in a small series of case reports. Catheter-directed thrombolytic therapy has a higher probabil-ity of restoring mesenteric blood flow success when performed within 12 hours of symptom onset. Successful resolution of a mesenteric thrombus will facilitate the identification of the underlying mesenteric occlusive disease process. As a result, subsequent operative mesenteric revascularization or mesen-teric balloon angioplasty and stenting may be performed elec-tively to correct the mesenteric stenosis. There are two main drawbacks with regard to thrombolytic therapy in mesenteric ischemia. Percutaneous catheter-directed thrombolysis does not allow the possibility to inspect the potentially ischemic intes-tine following restoration of the mesenteric flow. Additionally, a prolonged period of time may be necessary in order to achieve successful catheter-directed thrombolysis, due in part to serial angiographic surveillance to document thrombus resolution. An incomplete or unsuccessful thrombolysis may lead to delayed operative revascularization, which may further necessitate bowel resection for irreversible intestinal necrosis. Therefore, catheter-directed thrombolytic therapy for acute mesenteric ischemia should only be considered in selected patients under a closely scrutinized clinical protocol.Nonocclusive Mesenteric Ischemia. The treatment of non-occlusive mesenteric ischemia is primarily pharmacologic with selective mesenteric arterial catheterization followed by infu-sion of vasodilatory agents, such as tolazoline or papaverine. Once the diagnosis is made on the mesenteric arteriography (see Fig. 23-42), intra-arterial papaverine is given at a dose of 30 to 60 mg/h. This must be coupled with the cessation of other vaso-constricting agents. Concomitant intravenous heparin should be administered to prevent thrombosis in the cannulated vessels. Treatment strategy thereafter is dependent on the patient’s clini-cal response to the vasodilator therapy. If abdominal symptoms improve, mesenteric arteriography should be repeated to docu-ment the resolution of vasospasm. The patient’s hemodynamic status must be carefully monitored during papaverine infusion as significant hypotension can develop in the event that the infu-sion catheter migrates into the aorta, which can lead to systemic circulation of papaverine. Surgical exploration is indicated if the patient develops signs of continued bowel ischemia or infarction as evidenced by rebound tenderness or involuntary guarding. In these circumstances, papaverine infusion should be contin-ued intraoperatively and postoperatively. The operating room Brunicardi_Ch23_p0897-p0980.indd 93327/02/19 4:14 PM 934SPECIFIC CONSIDERATIONSPART IIshould be kept as warm as possible, and warm irrigation fluid and laparotomy pads should be used to prevent further intestinal vasoconstriction during exploration.Techniques of Endovascular Interventions. To perform endovascular mesenteric revascularization, intraluminal access is performed via a femoral or brachial artery approach. Once an introducer sheath is placed in the femoral artery, an anteroposte-rior and lateral aortogram just below the level of the diaphragm is obtained with a pigtail catheter to identify the origin of the CA and SMA. Initial catheterization of the mesenteric artery can be performed using a variety of selective angled catheters, which include the RDC, Cobra-2, Simmons I (Boston Scientific/Meditech, Natick, MA), or SOS Omni catheter (Angiodynam-ics, Queensbury, NY). Once the mesenteric artery is cannulated, systemic heparin (5000 IU) is administered intravenously. A selective mesenteric angiogram is then performed to identify the diseased segment, which is followed by the placement of a 0.035-inch or less traumatic 0.014to 0.018-inch guidewire to cross the stenotic lesion. Once the guidewire is placed across the stenosis, the catheter is carefully advanced over the guide-wire across the lesion. In the event that the mesenteric artery is severely angulated as it arises from the aorta, a second stiffer guidewire (Amplatz or Rosen Guidewire, Boston Scientific) may be exchanged through the catheter to facilitate the place-ment of a 6-French guiding sheath (Pinnacle, Boston Scientific).With the image intensifier angled in a lateral position to fully visualize the proximal mesenteric segment, a balloon angioplasty is advanced over the guidewire through the guiding sheath and positioned across the stenosis. The balloon diameter should be chosen based on the vessel size of the adjacent nor-mal mesenteric vessel. Once balloon angioplasty is completed, a postangioplasty angiogram is necessary to document the proce-dural result. Radiographic evidence of either residual stenosis or mesenteric artery dissection constitutes suboptimal angioplasty results that warrants mesenteric stent placement. Moreover, ath-erosclerotic involvement of the proximal mesenteric artery or vessel orifice should be treated with balloon-expandable stent placement. These stents can be placed over a low-profile 0.014or 0.018-inch guidewire system. It is preferable to deliver the balloon-mounted stent through a guiding sheath, which is posi-tioned just proximal to the mesenteric orifice while the balloon-mounted stent is advanced across the stenosis. The stent is next deployed by expanding the angioplasty balloon to its designated inflation pressure. The balloon is then deflated and carefully withdrawn through the guiding sheath.Completion angiogram is performed by hand injecting a small volume of contrast though the guiding sheath. It is criti-cal to maintain the guidewire access until satisfactory comple-tion angiogram is obtained. If the completion angiogram reveals suboptimal radiographic results, such as residual stenosis or dis-section, additional catheter-based intervention can be performed through the same guidewire. These interventions may include repeat balloon angioplasty for residual stenosis or additional stent placement for mesenteric artery dissection. During the procedure, intra-arterial infusion of papaverine or nitroglycerine can be used to decrease vasospasm. Administration of antiplatelet agents is also recommended for at least 6 months or even indefinitely if other risk factors of cardiovascular disease are present.Complications of Endovascular Treatment. Complica-tions are not common and rarely become life threatening. These include access site thrombosis, hematomas, and infection. Dissection can occur during PTA and is managed with place-ment of a stent. Balloon-mounted stents are preferred over the self-expanding ones because of the higher radial force and the more precise placement. Distal embolization has also been reported, but it never resulted in acute intestinal ischemia, likely due to the rich network of collaterals already developed.Clinical Results of Interventions for Mesenteric IschemiaThe first successful percutaneous angioplasty of the SMA was reported in 1980.97 Since 1995, multiple series and scattered case reports have reported results from endovascular manage-ment of mesenteric occlusive disease.92,96 A literature review by AbuRahma and colleagues in 2003 showed that endovascu-lar intervention had an overall technical success rate of 91%, early and late pain relief rates of 84% and 71%, respectively, and 30-day morbidity and mortality rates of 16.4% and 4.3%, respectively. The average patency was 63% during an average 26-month follow-up.98In our review of the literature from published series since 1995, restenosis developed in 22% of patients during  24.5 months of average follow-up.92 The long-term clinical relief without reintervention was 82%. Among the patients who experienced a technical failure, 15 were ultimately diagnosed with median arcuate ligament syndrome and underwent suc-cessful surgical treatment, an observation that emphasizes the need for careful patient selection. Interestingly, the addition of selective stenting after PTA that was started in 1998, while it slightly increases the technical success rate, is not correlated with any substantial overall clinical benefit or improved long-term patency rates.In contrast to endovascular treatment, open surgical tech-niques have achieved an immediate clinical success rate that approaches 100%, a surgical mortality rate of 0% to 17%, and an operative morbidity rate that ranges from 19% to 54% in a number of different series.89,93,99 AbuRahma and colleagues reported their experience of endovascular interventions of 22 patients with symptomatic mesenteric ischemia due to either SMA or CA stenosis.98 They noted an excellent initial technical and clinical success rates, which were 96% (23 of 24 patients) and 95% (21 of 22 patients), respectively, with no periopera-tive mortality or major morbidity. During a mean follow-up of 26 months (range, 1–54 months), the primary late clinical suc-cess rate was 61%, and freedom from recurrent stenosis was 30%. The freedom from recurrent stenosis rates at 1, 2, 3, and  4 years were 65%, 47%, 39%, and 13%, respectively. The authors concluded that mesenteric stenting, which provides excellent early results, is associated with a relative high inci-dence of late restenosis.Several studies have attempted to compare the endovas-cular with the standard open surgical approach.89,100 The results of the open surgery appear to be more durable, but it tends to be associated with higher morbidity and mortality rates and an overall longer hospital stay. In one study that compared the clin-ical outcome of open revascularization with percutaneous stent-ing for patients with chronic mesenteric ischemia, 28 patients underwent endovascular treatment and 85 patients underwent open mesenteric bypass grafting.99 With both patient cohorts having similar baseline comorbidities and symptom duration, there was no difference in early in-hospital complication or mortality rates. Moreover, both groups had similar 3-year cumu-lative recurrent stenosis and mortality rates. However, patients Brunicardi_Ch23_p0897-p0980.indd 93427/02/19 4:14 PM 935ARTERIAL DISEASECHAPTER 23treated with mesenteric stenting had a significantly higher inci-dence of recurrent symptoms. The authors concluded that opera-tive mesenteric revascularization should be offered to patients with low surgical risk.Based on the above results one could argue that mesen-teric angioplasty and stenting demonstrate an inferior technical and clinical success rate. Long-term patency rates appear to also be superior with the open technique. There is a general con-sensus, however, that the endovascular approach is associated with lower morbidity and mortality rates and is therefore more suitable for high-risk patients. One should also keep in mind that practices representing standard of care for stent placement today were absent in the early era of endovascular experience. These include perioperative heparinization and short-term anti-platelet therapy, use of stents with higher radial force, routine use of postoperative surveillance with arterial duplex and early reintervention to prevent a high-grade stenosis from progressing to occlusion, and placement of drug-eluting stents. One such example is a recent nonrandomized study to compare the out-comes of mesenteric angioplasty using covered stents or bare metal stents in patients undergoing primary or reintervention for chronic mesenteric ischemia. The study showed that covered stents are associated with less restenosis (18% vs. 47%), symp-tom recurrence (18% vs. 50%), and reintervention (9% vs. 44%) at 24 months and better primary patency at 3 years (92% vs. 52%) than bare metal stents in the primary intervention group.101 Similar results were found in the reintervention group as well.RENAL ARTERY DISEASEObstructive lesions of the renal artery can produce hypertension, resulting in a condition known as renovascular hypertension, which is the most common form of hypertension amenable to therapeutic intervention, and affects 5% to 10% of all hyperten-sive patients in the United States.102 Patients with renovascular hypertension are at an increased risk for irreversible end-organ dysfunction, including permanent kidney damage, if inadequate pharmacologic therapies are used to control the blood pressure. The majority of patients with renal artery obstructive disease have vascular lesions of either atherosclerotic disease or fibro-dysplasia involving the renal arteries. The proximal portion of the renal artery represents the most common location for the development of atherosclerotic disease. It is well established that renal artery intervention, either by surgical or endovascular revascularization, provides an effective treatment for controlling renovascular hypertension as well as preserving renal function. The decision for intervention is complex and needs to consider a variety of anatomic, physiologic, and clinical features, unique for the individual patient.EtiologyApproximately 80% of all renal artery occlusive lesions are caused by atherosclerosis, which typically involves a short seg-ment of the renal artery ostia and represents spillover disease from a severely atheromatous aorta (Fig. 23-43).102 Atheroscle-rotic lesions are bilateral in two thirds of patients. Individuals with this disease commonly present during the sixth decade of life. Men are affected twice as frequently as women. Atheroscle-rotic lesions in other territories such as the coronary, mesenteric, cerebrovascular, and peripheral arterial circulation are common. When a unilateral lesion is present, the disease process equally affects the right and left renal arteries.Figure 23-43. Occlusive disease of the renal artery typically involves the renal ostium (arrow) as a spillover plaque extension from aortic atherosclerosis.The second most common cause of renal artery stenosis is FMD, which accounts for 20% of cases and is most frequently encountered in young, often multiparous women. FMD of the renal artery represents a heterogeneous group of lesions that can produce histopathologic changes in the intima, media, or adventitia. The most common variety consists of medial fibro-plasia, in which thickened fibromuscular ridges alternate with attenuated media producing the classic angiographic “string of beads” appearance (Figs. 23-44 and 23-45). The cause of medial fibroplasia remains unclear. Most common theories involve a modification of arterial smooth muscle cells in response to Figure 23-44. Abdominal aortogram reveals a left renal artery fibromuscular dysplasia (arrows) with a characteristic “string of beads” appearance.Brunicardi_Ch23_p0897-p0980.indd 93527/02/19 4:14 PM 936SPECIFIC CONSIDERATIONSPART IIFigure 23-45. Magnetic resonance angiography of the abdominal aorta reveals the presence of a left renal artery fibromuscular dys-plasia (arrows).estrogenic stimuli during the reproductive years, unusual trac-tion forces on affected vessels, and mural ischemia from impair-ment of vasa vasorum blood flow. Fibromuscular hyperplasia usually affects the distal two thirds of the main renal artery, and the right renal artery is affected more frequently than the left. Other less common causes of renal artery stenosis include renal artery aneurysm (compressing the adjacent normal renal artery), arteriovenous malformations, neurofibromatosis, renal artery dissections, renal artery trauma, Takayasu’s arteritis, and renal arteriovenous fistula.Clinical ManifestationsRenovascular hypertension is the most common sequela of renal artery occlusive disease. Its prevalence varies from 2% in patients with diastolic blood pressure greater than 100 mmHg to almost 30% in those with diastolic blood pressure over  125 mmHg.103 Clinical features that may indicate the presence of renovascular hypertension include the following: (a) systolic and diastolic upper abdominal bruits; (b) diastolic hypertension of greater than 115 mmHg; (c) rapid onset of hypertension after the age of 50 years; (d) a sudden worsening of mild to moder-ate essential hypertension; (e) hypertension that is difficult to control with three or more antihypertensives; (f) development of renal insufficiency after angiotensin-converting enzyme inhibi-tors; and (g) development of hypertension during childhood.103All patients with significant hypertension, especially ele-vated diastolic blood pressure, must be considered as suspect for renovascular disease. Young adults with hypertension have a great deal to gain by avoiding lifelong treatment if renovascular hypertension is diagnosed and corrected. Appropriate diagnostic studies and intervention must be timely instituted to detect the possibility of renovascular hypertension in patients with pri-mary hypertension who present for clinical evaluation.Diagnostic EvaluationThe diagnostic requisites for renovascular hypertension include both hypertension and renal artery stenosis. Impairment of the renal function may coexist, although the occurrence of renal insufficiency prior to the development of hypertension is uncommon. Nearly all diagnostic studies for renovascular hypertension evaluate either the anatomic stenosis or renal parenchymal dysfunction attributed to the stenosis. The follow-ing section provides an overview of the strengths and limitations of the most common tests used in the diagnostic evaluation of the patient with suspected renovascular hypertension prior to intervention.Captopril renal scanning is a functional study that assesses renal perfusion before and after administration of the angioten-sin-converting enzyme inhibitor captopril. Captopril inhibits the secretion of angiotensin II. Through this mechanism, it reduces the efferent arteriole vasoconstriction and, as a result, the glo-merular filtration rate (GFR). The test consists of a baseline renal scan and a second renal scan after captopril administra-tion. A positive result indicates that captopril administration (a) increases the time to peak activity to more than 11 minutes or (b) the GFR ratio between sides increases to greater than 1.5:1 compared to a normal baseline scan. Significant parenchymal disease limits the reliability of this study.Renal artery duplex ultrasonography is a noninvasive test of assessing renal artery stenosis both by visualization of the vessel and measurement of the effect of stenosis on blood flow velocity and waveforms. The presence of a severe renal artery stenosis correlates with peak systolic velocities of greater than 180 cm/s and the ratio of these velocities to those in the aorta of greater than 3.5 (Table 23-11). Renal artery duplex is a techni-cally demanding exam, requiring a substantial amount of opera-tor expertise. In addition, the presence of bowel gas and obesity make the exam difficult to perform and interpret. However, in experienced hands and with appropriate patient selection, it can be a high-yield exam and is typically the initial screening test for patients with suspected renal artery occlusive disease.Selective catheterization of the renal vein via a femoral vein approach for assessing renin activity is a more invasive test of detecting the physiologic sequelae of renal artery stenosis. If unilateral disease is present, the affected kidney should secrete high levels of renin while the contralateral kidney should have low renin production. A ratio between the two kidneys, or the renal vein renin ratio (RVRR), of greater than 1.5 is indica-tive of functionally important renovascular hypertension, and it also predicts a favorable response from renovascular revascu-larization. Since this study assesses the ratio between the two kidneys, it is not useful in patients with bilateral disease because both kidneys may secrete abnormally elevated renin levels.The renal:systemic renin index (RSRI) is calculated by subtracting systemic renin activity from individual renal vein renin activity and dividing the remainder by systemic renin activity. This value represents the contribution of each kidney to renin production. In the absence of renal artery stenosis, the Table 23-11Renal duplex diagnostic criteriaRENAL ARTERY DIAMETER REDUCTIONRENAL ARTERY PSVRARNormal<180 cm/s<3.5<60%≥180 cm/s<3.5≥60%≥180 cm/s≥3.5OcclusionNo signalNo signalPSV = peak systolic velocity; RAR = renal-to-aortic ratio.Brunicardi_Ch23_p0897-p0980.indd 93627/02/19 4:14 PM 937ARTERIAL DISEASECHAPTER 23renal vein renin activity from each kidney is typically 24% or 0.24 higher than the systemic level. As the result, the total of both kidneys’ renin activity is usually 48% greater than the sys-temic activity, a value that represents a steady state of renal renin activity. The RSRI of the affected kidney in patients with renovascular hypertension is greater than 0.24. In the case of unilateral renal artery stenosis with normal contralateral kid-ney, the increase in ipsilateral renin release is normally balanced by suppression of the contralateral kidney renin production, which results in a drop in its RSRI to less than 0.24. Bilateral renal artery disease may negate the contralateral compensatory response, and the autonomous release of renin from both dis-eased kidneys may result in the sum of the individual RSRIs to be considerably greater than 0.48. The prognostic value of RSRI remains limited in that approximately 10% of patients with favorable clinical response following renovascular revas-cularization do not exhibit contralateral renin suppression. As a result, the use of RSRI must be applied with caution in the management of patients with renovascular hypertension.MRA with intravenous gadolinium contrast enhancement has been increasingly used for renal artery imaging because of its ability to provide high-resolution images (Figs. 23-46 and 23-47) while using a minimally nephrotoxic agent. Flow void may be inaccurately interpreted as occlusion or stenosis in MRA. Therefore, unless the quality of the image analysis soft-ware is superior, MRA should be interpreted with caution and used in conjunction with other modalities prior to making plans for operative or endovascular treatment.DSA remains the gold standard to assess renal artery occlusive disease. A flush aortogram is performed first so that any accessory renal arteries can be detected and the origins of all the renal arteries are adequately displayed. The presence of collateral vessels circumventing a renal artery stenosis strongly supports the hemodynamic importance of the stenosis. A pres-sure gradient of 10 mmHg or greater is necessary for collateral Figure 23-46. Magnetic resonance angiography of the abdominal aorta reveals bilateral normal renal arteries.Figure 23-47. Magnetic resonance angiography of the abdominal aorta reveals bilateral ostial renal artery stenosis (arrows).vessel development, which is also associated with activation of the renin-angiotensin cascade.Treatment IndicationsThe therapeutic goals in patients with renovascular disease include: (a) improved blood pressure control, in order to prevent end-organ damage on systems such as the cerebral, coronary, pulmonary, and peripheral circulations; and (b) preservation and possibly improvement of the renal function (Table 23-12).Table 23-12Indications for renal artery revascularizationAngiography Criteria• Documented renal artery stenosis (>70% diameter reduction)• Fibromuscular dysplasia lesion• Pressure gradient >20 mmHg• Affected/unaffected kidney renin ratio >1.5 to 1Clinical Criteria• Refractory or rapidly progressive hypertension• Hypertension associated with flash pulmonary edema without coronary artery disease• Rapidly progressive deterioration in renal function• Intolerance to antihypertensive medications• Chronic renal insufficiency related to bilateral renal artery occlusive disease or stenosis to a solitary functioning kidney• Dialysis-dependent renal failure in a patient with renal artery stenosis but without another definite cause of end-stage renal disease• Recurrent congestive heart failure or flash pulmonary edema not attributable to active coronary ischemiaBrunicardi_Ch23_p0897-p0980.indd 93727/02/19 4:14 PM 938SPECIFIC CONSIDERATIONSPART IIThe indications for endovascular treatment for renal artery occlusive disease include 70% or greater stenosis of one or both renal arteries and at least one of the following clinical criteria:• Inability to adequately control hypertension despite appropri-ate antihypertensive regimen.• Chronic renal insufficiency related to bilateral renal artery occlusive disease or stenosis to a solitary functioning kidney.• Dialysis-dependent renal failure in a patient with renal artery stenosis but without another definite cause of end-stage renal disease.• Recurrent congestive heart failure or flash pulmonary edema not attributable to active coronary ischemia.Prior to 1990, the most common treatment modality in patients with renal artery occlusive disease is surgical revascu-larization, with either renal artery bypass grafting or renal artery endarterectomy. The advancement of endovascular therapy in the past decade has led to various minimally invasive treatment strategies such as renal artery balloon angioplasty or stenting to control hypertension or to preserve renal function.Surgical ReconstructionThe typical approach for surgical renal artery revasculariza-tion involves a midline xiphoid-to-pubis incision. The posterior peritoneum is incised, and the duodenum is mobilized to the right, starting at the ligament of Treitz. The left renal hilum can be exposed by extending the retroperitoneal dissection to the left along the avascular plane along the inferior border of the pancreas. Mobilization of the left renal vein is essential in these cases and can be achieved by dividing the gonadal, ilio-lumbar, and adrenal veins. The proximal portion of the right renal artery can be exposed through the base of the mesentery by retraction of the left renal vein cephalad and the vena cava to the right. Accessing the most distal portion of the right renal artery requires a Kocher maneuver and duodenal mobiliza-tion. Another approach useful for treating bilateral renal artery lesions involves mobilization of the entire small bowel and the right colon, with a dissection that starts at the ligament of Treitz and proceeds toward the cecum and then along the line of Todd in the right paracolic gutter. Simultaneous dissection along the inferior border of the pancreas provides additional visualization of the left renal artery. Finally, division of the diaphragmatic crura that encircle the suprarenal aorta may sometimes be neces-sary to achieve suprarenal clamping.Types of Surgical Reconstruction. Aortorenal bypass is the most frequently performed reconstruction of ostial occlu-sive renal artery disease. After proximal and distal control is obtained, an elliptical segment of the aorta is excised, and the proximal anastomosis is performed in end-to-side fashion. Autologous vein is the preferred conduit. If the vein is not suit-able, then prosthetic material can be used. An end-to-end anas-tomosis is then performed between the conduit of choice and the renal artery using either a 6-0 or 7-0 polypropylene suture. The length of the arteriotomy needs to be at least three times the diameter of the renal artery to prevent anastomotic restenosis. In the event that the surgeon plans to perform a side-to-side anasto-mosis between the conduit and the renal artery, this is performed first, and the aortic anastomosis follows.Endarterectomy, either transrenal or transaortic, is an alter-native to bypass for short ostial lesions or in patients with mul-tiple renal arteries. The transrenal endarterectomy is performed with a transverse longitudinal incision on the aorta that extends into the diseased renal artery. After plaque removal, the arteri-otomy is closed with a prosthetic patch. Transaortic endarter-ectomy is well suited for patients with multiple renal arteries and short ostial lesions. The aorta is opened longitudinally and aortic sleeve endarterectomy is performed, followed by ever-sion endarterectomy of the renal arteries. Adequate mobiliza-tion of the renal arteries is essential for a safe and complete endarterectomy.Hepatorenal and splenorenal bypass are alternative options of revascularization for patients who might not tolerate aortic clamping or for those with calcified aorta that precludes ade-quate control. For hepatorenal bypass, a right subcostal inci-sion is used, and the hepatic artery is exposed with an incision in the lesser omentum. A Kocher maneuver is performed, the right renal vein is identified and mobilized, and the right renal artery is identified and controlled posteriorly to the vein. Greater saphenous vein is the conduit of choice. The anastomosis is per-formed end-to-side with the common hepatic artery, and end-to-end with the renal artery anterior to the inferior vena cava. The splenorenal bypass is performed via a left subcostal inci-sion. The splenic artery is mobilized from the lesser sac, brought through a retropancreatic plane, and anastomosed end-to-end to the renal artery.Reimplantation of the renal artery is an attractive option of reconstruction in children or in adults with ostial lesions. A redundant renal artery is a prerequisite for the procedure. After mobilization, the artery is transected and spatulated, eversion endarterectomy is performed if necessary, and an end-to-side anastomosis with the aorta is created.Clinical Results of Surgical RepairResults reflect the need for performance of renal artery bypass in high-volume and experienced centers. In a review from a large tertiary center, 92% of the patients with nonatherosclerotic vascular disease had improvement in hypertension, but only 43% were completely cured and taken off antihypertensives.104 Patients younger than age 45 fair better, with a cure rate of 68% and improvement rate of 32%. In patients with atherosclerotic renal artery disease, the cure rate was even smaller (12%), and the overall response to hypertension rate was 85%. The opera-tive mortality rates were 3.1% and 0% in the atherosclerotic and nonatherosclerotic groups, respectively.Renal function improvement occurs within the first week of the operation in approximately two-thirds of patients. A pro-gressive decrease in the GFR is seen after this initial improve-ment, but the rate of decrease is less compared with patients who did not respond at all to operative intervention. Up to three-quarters of patients were permanently removed from dialysis in a large series.105 Favorable response of renal function to revas-cularization improves overall survival.Endovascular TreatmentEndovascular treatment of renal artery occlusive disease was first introduced by Grüntzig who successfully dilated a renal artery stenosis using a balloon catheter technique. This tech-nique requires passage of a guidewire under fluoroscopic control typically from a femoral artery approach to across the stenosis in the renal artery. A balloon dilating catheter is passed over the guidewire and positioned within the area of stenosis and inflated to produce a controlled disruption of the arterial wall. Alternatively, a balloon-mounted expandable stent can be used Brunicardi_Ch23_p0897-p0980.indd 93827/02/19 4:14 PM 939ARTERIAL DISEASECHAPTER 23to primarily dilate the renal artery stenosis. Completion angiog-raphy is usually performed to assess the immediate results. The technical aspect of an endovascular renal artery revasculariza-tion is discussed in the following section.Techniques of Renal Artery Angioplasty and Stenting.  Access to the renal artery for endovascular intervention is typi-cally performed via a femoral artery approach, although a bra-chial artery approach can be considered in the event of severe aortoiliac occlusive disease, aortoiliac aneurysm, or severe cau-dal renal artery angulation. Once an introducer sheath is placed in the femoral artery, an aortogram is performed with a pigtail catheter placed in the suprarenal aorta. Additional oblique views are frequently necessary to more precisely visualize the orifice of the stenosed renal artery and thoroughly assess the presence of accessory renal arteries. Noniodinated contrast agents, such as carbon dioxide and gadolinium, can be used in endovascular renal intervention in patients with renal dysfunction or history of allergic reaction.After systemic heparinization, catheterization of the renal artery can be performed using a variety of selective angled cath-eters, including the RDC, Cobra-2, Simmons I, or SOS Omni catheter. A selective renal angiogram is then performed to con-firm position, and the lesion is crossed with either 0.035-inch or a 0.018to 0.014-inch guidewires. It is important to main-tain the distal wire position without movement in the tertiary renal branches during guiding sheath placement to reduce the possibility of parenchymal perforation and spasm. A guiding sheath or a guiding catheter is then advanced at the orifice of the renal artery and provides a secure access for balloon and stent deployment.Balloon angioplasty is performed with a balloon sized to the diameter of the normal renal artery adjacent to the stenosis. Choosing a balloon with diameter 4 mm is a reasonable first choice. The luminal diameter of the renal artery can be further assessed by comparing it to the fully inflated balloon. Such a comparison may provide a reference guide to determine whether renal artery dilatation with a larger diameter angioplasty balloon is necessary.Once balloon angioplasty of the renal artery is completed, an angiogram is performed to document the procedural result. Radiographic evidence of either residual stenosis or renal artery dissection constitutes suboptimal angioplasty results, which warrants an immediate renal artery stent placement. Moreover, atherosclerotic involvement of the very proximal renal artery that involves the vessel orifice typically requires stent place-ment. A balloon-expandable stent is typically used and is positioned in such a way that it protrudes into the aorta by  1 to 2 mm. The size of the stent is determined by the size of the renal artery, taking into account a desirable 10% to 20% over-sizing. After the stent deployment, the angiogram is repeated, and upon a satisfactory result, the devices are withdrawn. It is critical to maintain the guidewire access across the renal lesion until satisfactory completion angiogram is obtained. Spasm of the branches of the renal artery will usually respond to nitro-glycerin 100 to 200 μg administered through the guiding sheath directly into the renal artery.While endovascular therapy of renal artery occlusive disease is considerably less invasive than conventional renal artery bypass operation, complications relating to this treat-ment modality can occur. In a study in which Guzman and colleagues compared the complications following renal artery angioplasty and surgical revascularization, the authors noted that major complication rates following endovascular and sur-gical treatment were 17% and 31%, respectively.106 In contrast, significantly greater minor complications were associated with the endovascular cohort, with a minor complication rate of 48% compared with 7% in the surgical group. In a prospective randomized study that compared the clinical outcome of renal artery balloon angioplasty versus stenting for renal ostial ath-erosclerotic lesion, comparable complications rates were found in the two groups (39% vs. 43%, respectively). However, the incidence of restenosis at 6 months was significantly higher in the balloon angioplasty cohort than the stenting group (48% vs. 14%, respectively). This study underscores the clinical superior-ity of renal stenting compared to renal balloon angioplasty alone in patients with ostial stenosis.107Deterioration in renal function, albeit transient, is a com-mon complication following endovascular renal artery inter-vention. This is most likely the combined result of the use of iodinated contrast and the occurrence of renal parenchymal embolism due to wire and catheter manipulation. In most cases, this is a temporary problem, as supportive care with adequate fluid hydration is sufficient to reverse the renal dysfunction. However, transient hemodialysis may become necessary in approximately 1% of patients. Other complications include vas-cular access complications (bleeding, hematoma, femoral nerve injury, arteriovenous fistula, and pseudoaneurysm), target ves-sel dissection, perinephric hematoma, early postoperative renal artery thrombosis, and extremity atheroembolism from throm-bus in the aorta or the iliac arteries.Clinical Results of Endovascular InterventionsPercutaneous Transluminal Balloon Angioplasty. FMD of the renal artery is the most common treatment indication for percutaneous transluminal balloon angioplasty. Patients with symptomatic FMD such as hypertension or renal insufficiency usually respond well to renal artery balloon angioplasty alone. In contrast, balloon angioplasty generally is not an effective treat-ment for patients with renal artery stenosis or proximal occlusive disease of the renal artery, due to the high incidence of restenosis with balloon angioplasty alone. In the latter group of patients, primary stent placement is the preferred endovascular treatment. The long-term benefit of renal artery balloon angioplasty in patients with FMD was reported by Surowiec and colleagues.108 They followed 14 patients who underwent 19 interventions on 18 renal artery segments. The technical success rate of balloon angioplasty for FMD was 95%. Primary patency rates were 81%, 69%, 69%, and 69% at 2, 4, 6, and 8 years, respectively. Assisted primary patency rates were 87%, 87%, 87%, and 87% at 2, 4, 6, and 8 years, respectively. The restenosis rate was 25% at  8 years. Clinical benefit, as defined by either improved or cured hypertension, was found in 79% of patients overall, with two-thirds of patients having maintained this benefit at 8 years. The authors concluded that balloon angioplasty is highly effective in symptomatic FMD with excellent durable functional benefits.The utility of balloon angioplasty alone in the treatment of renovascular hypertension appears to be limited. van Jaars-veld and associates performed a prospective study in which patients with renal artery stenosis were randomized to either drug therapy or balloon angioplasty treatment.109 A total of 106 patients with 50% diameter stenosis or greater plus hyperten-sion or renal insufficiency were randomized in the study. At  3 months, there was no difference in the degree to which blood Brunicardi_Ch23_p0897-p0980.indd 93927/02/19 4:14 PM 940SPECIFIC CONSIDERATIONSPART IIpressure was controlled between the two groups. However, the degree and dose of antihypertensive medications were slightly lowered in the balloon angioplasty group. The above advantage of the angioplasty group completely disappeared at 12 months, making the authors conclude that in the treatment of patients with hypertension and renal artery stenosis, percutaneous trans-luminal balloon angioplasty alone offers minimal advantage over antihypertensive drug therapy.Renal Artery Stenting. Endovascular stent placement is the treatment of choice for patients with symptomatic or high-grade renal artery occlusive disease (Fig. 23-48). This is due in part to the high incidence of restenosis with balloon angioplasty alone, particularly in the setting of ostial stenosis. Renal artery stenting is also indicated for renal artery dissection caused by balloon angioplasty or other catheter-based interventions. Numerous studies have clearly demonstrated the clinical efficacy of renal artery stenting when compared to balloon angioplasty alone in patients with high-grade renal artery stenosis.White and colleagues conducted a study to evaluate the role of renal artery stenting in patients with poorly controlled hyper-tension and renal artery lesions that did not respond well to bal-loon angioplasty alone.110 The technical success of the procedure was 99%. The mean blood pressure values were 173 ± 25/88 ±  17 mmHg prior to stent implantation and 146 ± 20/77 ± 12 mmHg 6 months after renal artery stenting (P <0.01). Angiographic follow-up with 67 patients (mean 8.7 ± 5 months) demonstrated that restenosis, as defined by 50% or greater luminal narrowing, occurred in 15 patients (19%). The study concluded that renal artery stenting is a highly effective treatment for renovascular hypertension, with a low angiographic restenosis rate. In another similar study, Blum and colleagues prospectively performed renal artery stenting in 68 patients (74 lesions) with ostial renal artery stenosis and suboptimal balloon angioplasty.111 Patients were fol-lowed for a mean of 27 months with measurements of blood pres-sure and serum creatinine, duplex sonography, and intra-arterial angiography. Five-year patency was 84.5% (mean follow-up,  27 months). Restenosis occurred in 8 of 74 arteries (11%), but after reintervention, the secondary 5-year patency rate was 92.4%. Hypertension was cured or improved in 78% of patients. The authors concluded that primary stent placement is an effec-tive treatment for renal artery stenosis involving the ostium.BAFigure 23-48. Renal artery stenting. A. Focal lesion in the renal artery (arrow). B. Poststenting angiogram reveals a satisfactory result  following a renal artery stenting placement (arrow).The clinical utility of renal artery stenting in renal func-tion preservation was analyzed by several studies, which mea-sured serial serum creatinine levels to determine the response of renal function following endovascular intervention.112,113 In a study reported by Harden and colleagues who performed 33 renal artery stenting procedures in 32 patients with renal insuf-ficiency, they noted that renal function improved or stabilized in 22 patients (69%).113 In a similar study, Watson and associates evaluated the effect of renal artery stenting on renal function by comparing the slopes of the regression lines derived from the reciprocal of serum creatinine versus time.112 A total of 61 renal stenting procedures were performed in 33 patients, and the authors found that after stent placement, the slopes of the reciprocal of the serum creatinine (1/Scr) were positive in 18 patients and less negative in 7 patients. The study concluded that in patients with chronic renal insufficiency due to obstructive renal artery stenosis, renal artery stenting is effective in improv-ing or stabilizing renal function.The clinical outcome of several large clinical studies of renal artery stenting in the treatment of renovascular hyperten-sion or chronic renal insufficiency is shown in Table 23-13. These studies uniformly demonstrated an excellent technical success rate with low incidence of restenosis or procedural-related complications. A similar analysis was reported by Leer-touwer and colleagues who performed a meta-analysis of 14 studies comparing patients with renal arterial stent placement to those who underwent balloon angioplasty alone for renal arterial stenosis.114 The study found that stent placement proved highly successful, with an initial technical success of 98%. The overall cure rate for hypertension was 20%, whereas hypertension was improved in 49%. Renal function improved in 30% of patients and stabilized in 38% of patients. The restenosis rate at follow-up of 6 to 29 months was 17%. Renal stenting resulted in a higher technical success rate and a lower restenosis rate when compared to balloon angioplasty alone.AORTOILIAC OCCLUSIVE DISEASEThe distal abdominal aorta and the iliac arteries are common sites affected by atherosclerosis. The symptoms and natural history of the atherosclerotic process affecting the aortoiliac Brunicardi_Ch23_p0897-p0980.indd 94027/02/19 4:14 PM 941ARTERIAL DISEASECHAPTER 23arterial segment are influenced by the disease distribution and extent. Atherosclerotic plaques may cause clinical symptoms by restricting blood flow due to luminal obstruction or by embo-lizing atherosclerotic debris to the lower extremity circulation. If the aortoiliac plaques reach sufficient mass and impinge on the arterial lumen, obstruction of blood flow to lower extremi-ties occurs. Various risk factors exist that can lead to the devel-opment of aortoiliac occlusive disease. Recognition of these factors and understanding of this disease entity will enable phy-sicians to prescribe the appropriate treatment strategy, which may alleviate symptoms and improve quality of life.Diagnostic EvaluationOn clinical examination patients often have weakened femoral pulses and a reduced ABI. Verification of iliac occlusive dis-ease is usually made by color duplex scanning, which reveals either a peak systolic velocity ratio ≥2.5 at the site of stenosis and or a monophasic waveform. Noninvasive tests such as pulse volume recordings (PVRs) of the lower extremity with estima-tion of the thigh-brachial pressure index may be suggestive of aortoiliac disease. MRA and multidetector CTA are increasingly being used to determine the extent and type of obstruction. DSA offers the interventionalist the benefit of making a diagnosis and the option of performing an endovascular treatment in a single session. Angiography provides important information regard-ing distal arterial runoff vessels as well as the patency of the PFA. Presence of pelvic and groin collaterals is important to provide crucial collateral flow in maintaining lower limb viabil-ity. It must be emphasized, however, that patients should be subjected to angiography only if their symptoms warrant surgi-cal intervention.Differential DiagnosisDegenerative hip or spine disease, lumbar disk herniation, spinal stenosis, diabetic neuropathy, and other neuromuscular problems can produce symptoms that may be mistaken for vas-cular claudication. Such cases can be distinguished from true claudication by the fact that the discomfort from neuromuscular problems is often relieved by sitting or lying down, as opposed to cessation of ambulation. In addition, complaints that are Table 23-13Clinical outcome of renal artery stent placement in the treatment of renovascular hypertension and renal insufficiencyAUTHORYEARPATIENT NO.TECHNICAL SUCCESS (%)FOLLOW-UP (MONTHS)RENAL INSUFFICIENCY (%)RENOVASCULAR HYPERTENSION (%)COMPLICATION (%)RESTENOSIS (%)STABLEIMPROVEDCUREDIMPROVEDIannone1301996 63 991045364351314Harden1261997 32100 63434N/AN/A 313Blum1241997 6810027N/AN/A1662 011White1231997100 99 6N/A20N/AN/A 219Shannon1321998 21100 92943N/AN/A 90Rundback1311998 45 9417N/AN/AN/AN/A 925Dorros128199816310048N/AN/A35111N/AHenry1291999210 9925N/A291961 39Bush1272001 73 8920213813611216N/A = not applicable.experienced upon standing suggest nonvascular causes. When confusion persists, the use of noninvasive vascular laboratory testing modalities, including treadmill exercise, can help estab-lish the diagnosis.Collateral Arterial NetworkThe principal collateral pathways in severe aortoiliac artery occlusive disease or chronic aortic occlusion that may provide blood flow distal to the aortoiliac lesion include: (a) the superior mesenteric artery to the distal IMA via its superior hemorrhoidal branch to the middle and inferior hemorrhoidals to the internal iliac artery; (b) the lumbar arteries to the superior gluteal artery to the internal iliac system; (c) the lumbar arteries to the lateral and deep circumflex arteries to the CFA; and (d) Winslow’s pathway from the subclavian to the superior epigastric artery to the inferior epigastric artery to the external iliac arteries at the groin (Fig. 23-49). In general, treatment indications for aor-toiliac artery occlusive disease include disabling claudication, ischemic rest pain, nonhealing lower extremity tissue wound, and lower extremity microembolization that arises from aor-toiliac lesions.Disease ClassificationBased on the atherosclerotic disease pattern, aortoiliac occlusive disease can be classified into three types (Fig. 23-50). Type I aortoiliac disease, which occurs in 5% to 10% of patients, is confined to the distal abdominal aorta and common iliac vessels (Fig. 23-51). Due to the localized nature of this type of aortic obstruction and formation of collateral blood flow around the occluded segment, limb-threatening symptoms are rare in the absence of more distal disease (Fig. 23-52). This type of aor-toiliac occlusive disease occurs in a relatively younger group of patients (in their mid-50s), compared with patients who have more femoropopliteal disease. Patients with a type I disease pat-tern have a lower incidence of hypertension and diabetes but a significant frequency of abnormal blood lipid levels, particu-larly type IV hyperlipoproteinemia. Symptoms typically consist of bilateral thigh or buttock claudication and fatigue. Men report diminished penile tumescence and may have complete loss of erectile function. These symptoms in the absence of femoral Brunicardi_Ch23_p0897-p0980.indd 94127/02/19 4:14 PM 942SPECIFIC CONSIDERATIONSPART IIFigure 23-50. Aortoiliac disease can be classified into three types. Type I represents focal disease affecting the distal aorta and proxi-mal common iliac artery. Type II represents diffuse aortoiliac dis-ease above the inguinal ligament. Type III represents multisegment occlusive diseases involving aortoiliac and infrainguinal arterial vessels.Figure 23-51. Type I aortoiliac disease is confined to the distal abdominal aorta (long arrow) or proximal common iliac arteries. Due to the localized nature of this type of aortic obstruction and formation of collateral blood flow around the occluded segment (short arrows), limb-threatening symptoms are rare in the absence of more distal disease.Figure 23-49. Pertinent collateral pathways are developed in the event of chronic severe aortoiliac occlusive disease. As illustrated in this multidetector computed tomography angiography, these col-laterals include epigastric arteries (large white arrows), an enlarged inferior mesenteric artery (arrowhead), and enlarged lumbar arter-ies (black arrows).Type IType IIType IIIpulses constitute Leriche’s syndrome. Rest pain is unusual with isolated aortoiliac disease unless distal disease coexists. Occa-sionally patients report a prolonged history of thigh and buttock claudication that recently becomes more severe. It is likely that this group has underlying aortoiliac disease that has progressed to acute occlusion of the terminal aorta. Others may present with “trash foot,” which represents microembolization into the distal vascular bed (Fig. 23-53). Type II aortoiliac disease rep-resents a more diffuse atherosclerotic progression that involves predominately the abdominal aorta with disease extension into the common iliac artery. This disease pattern affects approxi-mately 25% patients with aortoiliac occlusive disease. Type III aortoiliac occlusive disease, which affects approximately 65% of patients with aortoiliac occlusive disease, is widespread dis-ease that is seen above and below the inguinal ligament (Fig. 23-54). Patients with “multilevel” disease are older, more com-monly male (with a male-to-female ratio of 6:1), and much more likely to have diabetes, hypertension, and associated atheroscle-rotic disease involving cerebral, coronary, and visceral arter-ies. Progression of the occlusive process is more likely in these patients than in those with localized aortoiliac disease. For these reasons, most patients with a type III pattern tend to present with symptoms of advanced ischemia and require revasculariza-tion for limb salvage rather than for claudication. These patients have a decreased 10-year life expectancy when compared to patients with localized aortoiliac disease.The most commonly used classification system of iliac lesions has been set forth by the TransAtlantic Inter-Society Consensus (TASC) group with recommended treatment options. This lesion classification categorizes the extent of atheroscle-rosis and has suggested a therapeutic approach based on this classification (Table 23-14 and Fig. 23-55).1 According to this consensus document, endovascular therapy is the treatment of choice for type A lesions, and surgery is the treatment of choice for type D lesions. Endovascular treatment is the preferred treat-ment for type B lesions, and surgery is the preferred treatment for good-risk patients with type C lesions. In comparison to the 2000 TASC document, the commission has not only made allowances for treatment of more extensive lesions, but it also takes into account the continuing evolution of endovascular technology and the skills of individual interventionalists when stating that the patient’s comorbidities, fully informed patient preference, and the local operator’s long-term success rates Brunicardi_Ch23_p0897-p0980.indd 94227/02/19 4:14 PM 943ARTERIAL DISEASECHAPTER 23Figure 23-52. A. Multidetector computed tomography angiography of the aortoiliac artery circulation in a 63-year-old male with buttock claudication. B. Three-dimensional image reconstruction shows intra-arterial calcification of the aorta (large arrow) and right common iliac artery (small arrow). This is consistent with type I aortoiliac occlusive disease.Figure 23-53. Atherosclerotic disease involving the aortoiliac segment can result in microembolization of the lower leg circulation, resulting in trash foot or digital gangrene of toes.must be considered when making treatment decisions for type B and type C lesions.1,115General Treatment ConsiderationsThere is no effective medical therapy for the management of aortoiliac disease, but control of risk factors may help slow pro-gression of atherosclerosis. Patients should have hypertension, hyperlipidemia, and diabetes mellitus controlled. They should be advised to stop smoking. Most patients are empirically placed on antiplatelet therapy. A graduated exercise program may improve walking efficiency, endothelial function, and metabolic adaptations in skeletal muscle, but, there is usually minimal improvement in patients with aortoiliac disease who are treated with these measures. Failure to respond to exercise and/or drug therapy should prompt consideration for limb revas-cularization. Patients with buttock claudication and reduced or absent femoral pulses who fail to respond to exercise and drug therapy should be considered for revascularization because they are less likely than patients with more distal lesions to improve without concomitant surgical or endovascular intervention.Brunicardi_Ch23_p0897-p0980.indd 94327/02/19 4:14 PM 944SPECIFIC CONSIDERATIONSPART IIFigure 23-54. Type III aortoiliac occlusive disease is a mul-tilevel disease pattern that affects the aortoiliac segment as well as infrainguinal femoropopliteal vessels. Most patients with this disease pattern tend to present with symptoms of advanced isch-emia and require revascularization for limb salvage rather than for claudication.Table 23-14TASC classification of aortoiliac occlusive lesionsType A lesions• Unilateral or bilateral stenoses of CIA• Unilateral or bilateral single short (≤3 cm) stenosis of EIAType B lesions• Short (≤3 cm) stenosis of infrarenal aorta• Unilateral CIA occlusion• Single or multiple stenosis totaling 3–10 cm involving the EIA not extending into the CFA• Unilateral EIA occlusion not involving the origins of internal iliac artery or CFAType C lesions• Bilateral CIA occlusions• Bilateral EIA stenoses 3–10 cm long not extending  into the CFA• Unilateral EIA stenosis extending into the CFA• Unilateral EIA occlusion that involves the origins of internal iliac artery and/or CFA• Heavily calcified unilateral EIA occlusion with or without involvement of origins of internal iliac artery and/or CFAType D lesions• Infrarenal aortoiliac occlusion• Diffuse disease involving the aorta and both iliac arteries requiring treatment• Diffuse multiple stenoses involving the unilateral CIA, EIA, and CFA• Unilateral occlusions of both CIA and EIA• Bilateral occlusions of EIA• Iliac stenoses in patients with AAA requiring treatment and not amenable to endograft placement or other lesions requiring open aortic or iliac surgeryAAA = abdominal aortic aneurysm; CFA = common femoral artery; CIA = common iliac artery; EIA = external iliac artery.Type A lesionsType B lesionsType D lesionsType C lesionsFigure 23-55. Schematic depiction of the TransAtlantic Inter-Society Consensus classification of aortoiliac occlusive lesions.Surgical Reconstruction of Aortoiliac Occlusive DiseaseAortobifemoral Bypass. Surgical options for treatment of aortoiliac occlusive diseases consist of various configurations of aortobifemoral bypass grafting, various types of extra-anatomic bypass grafts, and aortoiliac endarterectomy. The procedure performed is determined by several factors, including ana-tomic distribution of the disease, clinical condition of the patient, and personal preference of the surgeon.In most cases, aortobifemoral bypass is performed because patients usually have disease in both iliac systems. Although one side may be more severely affected than the other, progression does occur, and bilateral bypass does not complicate the procedure or add to the physiologic stress of the operation. Aortobifemoral bypass reliably relieves symp-toms, has excellent long-term patency (approximately 70–80% at 10 years), and can be completed with a tolerable periopera-tive mortality (2–3%).Technical Considerations for Aortobifemoral Bypass Both femoral arteries are initially exposed to ensure that they are ade-quate for the distal anastomoses. The abdomen is then opened in the midline, the small intestine is retracted to the right, and the posterior peritoneum overlying the aorta is incised. A retro-peritoneal approach may be selected as an alternative in certain situations. This approach involves making a left flank incision and displacing the peritoneum and its contents to the right. Such an approach is contraindicated if the right renal artery is acutely occluded, since visualization from the left flank is very poor. Tunneling of a graft to the right femoral artery is also more 4difficult from a retroperitoneal approach, but can be achieved. The retroperitoneal approach has been reputed to be better toler-ated than midline laparotomy for patients with multiple previ-ous abdominal operations and with severe pulmonary disease. Further proposed advantages of the retroperitoneal approach include less gastrointestinal disturbance, decreased third space Brunicardi_Ch23_p0897-p0980.indd 94427/02/19 4:14 PM 945ARTERIAL DISEASECHAPTER 23fluid losses, and ease with which the pararenal aorta can be accessed. There are randomized reports, however, that support and refute the superiority of this approach. A collagen-impreg-nated, knitted Dacron graft is used to perform the proximal aortic anastomosis, which can then be made in either an end-to-end or end-to-side fashion using 3-0 polypropylene suture. The proximal anastomosis should be made as close as possible to the renal arteries to decrease the incidence of restenosis from pro-gression of the atherosclerotic occlusive process in the future.An end-to-end proximal aortic anastomosis is necessary in patients with an aortic aneurysm or complete aortic occlu-sion extending up to the renal arteries (Fig. 23-56). Although in theory the end-to-end configuration allows for less turbulence and less chance of competitive flow with still patent host iliac vessels, there have not been consistent results to substantiate differences in patency between end-to-end and end-to-side grafts. Relative indications for an end-to-side proximal aortic anastomosis include the presence of large aberrant renal arter-ies, an unusually large IMA with poor back-bleeding suggesting inadequate collateralization, and/or occlusive disease involv-ing bilateral external iliac arteries. Under such circumstances, end-to-end bypass from the proximal aorta to the femoral level devascularizes the pelvic region because there is no antegrade or retrograde flow in the occluded external iliac arteries to supply the hypogastric arteries. As a result of the pelvic devasculariza-tion, there is an increased incidence of impotence, postoperative colon ischemia, buttock ischemia, and paraplegia secondary to spinal cord ischemia despite the presence of excellent femoral and distal pulses.An end-to-side proximal aortic anastomosis can be associ-ated with certain disadvantages, which include the potential for distal embolization when applying a partially occlusive aortic clamp (Fig. 23-57). Furthermore, the distal aorta often pro-ceeds to total occlusion after an end-to-side anastomosis. There Figure 23-56. In an end-to-end proximal aortic anastomosis, the aorta is divided in half. The proximal end of the aorta is anasto-mosed to the end of a prosthetic graft, while the distal divided aortic stump is oversewn.Figure 23-57. In an end-to-side aortic anastomosis, the end of a prosthetic graft is connected to the side of an aortic incision.may also be a higher incidence of aortoenteric fistula follow-ing construction of end-to-side proximal anastomoses because the anterior projection makes subsequent tissue coverage and reperitonealization of the graft more difficult. The limbs of the graft are tunneled through the retroperitoneum to the groin, where an end-to-side anastomosis is fashioned between the graft and the bifurcation of the CFA using 5-0 polypropylene suture. Endarterectomy or patch angioplasty of the profunda femo-ris may be required concurrently. Once the anastomoses have been fashioned and the graft thoroughly flushed, the clamps are removed and the surgeon carefully controls the degree of aortic occlusion until full flow is reestablished. During this period, the patient must be carefully monitored for hypotension. Declamp-ing hypotension is a complication of sudden restoration of aortic flow, particularly following prolonged occlusion. Once flow has been reestablished, the peritoneum is carefully reapproximated over the prosthesis to prevent fistulization into the intestine.Despite the presence of multilevel disease in most patients, a properly performed aortobifemoral operation can provide arterial inflow and alleviate claudication symptoms in 70% to 80% of patients; however, 10% to 15% of patients will require simultaneous outflow reconstruction to address distal ischemia and facilitate limb salvage. The advantage of concomitant distal revascularization is avoidance of reoperation in a scarred groin. As a rule, if the profunda femoris can accept a 4-mm probe and if a No. 3 Fogarty embolectomy catheter can be passed distally for 20 cm or more, the PFA will be sufficient for outflow, and concomitant distal revascularization is not necessary.Aortic Endarterectomy. Aortoiliac endarterectomy is rarely performed because it is associated with greater blood loss and greater sexual dysfunction and is more difficult to perform. Long-term patency is comparable with aortobifemoral grafting, and thus it remains a reasonable option in cases in which the risk of infection of a graft is excessive because it involves no pros-thetic tissue. Aortoiliac endarterectomy was useful when disease was localized to either the aorta or common iliac arteries; how-ever, at present, aortoiliac PTA, stents, and other catheter-based therapies have become first-line treatment in this scenario. End-arterectomy should not be performed if the aorta is aneurysmal because of continued aneurysmal degeneration of the endarter-ectomized segment. If there is total occlusion of the aorta to the level of the renal arteries, aortic transection several centime-ters below the renal arteries with thrombectomy of the aortic cuff followed by graft insertion is easier and more expeditious when compared to endarterectomy. Involvement of the external iliac artery makes aortic endarterectomy more difficult to com-plete because of decreased vessel diameter, increased length, and exposure issues. The ability to establish an appropriate Brunicardi_Ch23_p0897-p0980.indd 94527/02/19 4:14 PM 946SPECIFIC CONSIDERATIONSPART IIendarterectomy plane is compromised due to the muscular and inherently adherent nature of the media in this location. There is a higher incidence of early thrombosis and late failure with extended aortoiliofemoral endarterectomy when compared to bypass grafting as a result of recurrent stenosis.Axillofemoral Bypass. An axillofemoral bypass is an extra-anatomic reconstruction that derives arterial inflow from the axillary artery to the femoral artery. This is a treatment option for patients with medical comorbidities that prohibit an abdominal vascular reconstruction. It may be performed under local anesthesia and is used for limb salvage. Extra-anatomic bypasses have lower patency when compared to aortobifemo-ral and, therefore, are seldom recommended for claudication. Before performing this operation, the surgeon should check pulses and blood pressure in both arms to ensure that there is no obvious disease affecting flow through the axillary system. Angiography of the axillosubclavian vasculature is not neces-sary, but can be helpful if performed at the time of aortography. The axillary artery is exposed below the clavicle, and a 6to 8-mm externally reinforced PTFE graft is tunneled subcutane-ously down the lateral chest wall and lateral abdomen to the groin. It is anastomosed ipsilaterally at the CFA bifurcation into the SFA and PFA. A femorofemoral crossover graft using a 6to 8-mm externally reinforced PTFE graft is then used to revascularize the opposite extremity if necessary. Reported patency rates over 5 years vary from 30% to 80%.116 Paradoxi-cally, although it is a less complex procedure than aortofemoral grafting, the mortality rate is higher (10%), reflecting the com-promised medical status of these patients.Iliofemoral Bypass. One option for patients with unilateral occlusion of the distal common iliac or external iliac arteries is iliofemoral grafting (Fig. 23-58). Long-term patency is compa-rable to aortounifemoral bypass, and because the procedure can be performed using a retroperitoneal approach without clamping the aorta, the perioperative mortality is less.116Femorofemoral Bypass. A femorofemoral bypass is another option for patients with unilateral stenosis or occlusion of the common or external iliac artery who have rest pain, tissue loss, BAFigure 23-58. A. Skin markings showing the incisions of an ilio-femoral bypass. B. A prosthetic bypass graft is used for an iliofemo-ral artery bypass in which the proximal anastomosis is connected to the common iliac artery (long arrow) while the distal anastomosis is connected to the common femoral artery (short arrow).or intractable claudication. The primary (assisted) patency at 5 years is reported to be 60% to 70%, and although this is inferior when compared to aortofemoral bypass, there are physi-ologic benefits, especially for patients with multiple comorbidi-ties because it is not necessary to cross-clamp the aorta.117 There are no studies supporting the superiority of unsupported or exter-nally supported PTFE over Dacron for choice of conduit. The fear of the recipient extremity stealing blood from the extremity ipsilateral to the donor limb is not realized unless the donor iliac artery and donor outflow arteries are diseased. Depending on the skills of the interventionalist or surgeon, many iliac lesions classified as TASC B, C, or D can now be addressed using an endovascular approach, thus obviating the need to perform a femorofemoral bypass. Additionally, femorofemoral bypass can be used as an adjuvant procedure after iliac inflow has been optimized with endovascular methods.Obturator Bypass. An obturator bypass is used to recon-struct arterial anatomy in patients with groin sepsis resulting from prior prosthetic grafting, intra-arterial drug abuse, groin neoplasm, or damage from prior groin irradiation. This bypass can originate from the common iliac artery, external iliac artery, or uninvolved limb of an aortobifemoral bypass. A conduit of Dacron, PTFE, or autologous vein is tunneled through the anteromedial portion of the obturator membrane to the distal superficial femoral artery or popliteal artery. The obturator membrane must be divided sharply so as avoid injury to adja-cent structures, and care must be taken to identify the obturator artery and nerve that pass posterolaterally. After the bypass is completed and the wounds isolated, the infected area is entered, the involved arteries are debrided to healthy tissue, and vascu-larized muscle flaps are mobilized to cover the ligated ends. There have been varied results in terms of patency and limb salvage for obturator bypass. Some authors have reported 57% 5-year patency and 77% 5-year limb salvage rates, whereas others have shown a high rate of reinfection and low patency requiring reintervention.118,119Thoracofemoral Bypass. The indications for thoracofemoral bypass are (a) multiple prior surgeries with a failed infrarenal aortic reconstruction and (b) infected aortic prosthesis. This pro-cedure is more physiologically demanding than other extra-ana-tomic reconstructions because the patient must not only tolerate clamping the descending thoracic aorta but also performance of a left thoracotomy. The graft is tunneled to the left CFA from the left thorax posterior to the left kidney in the anterior axillary line using a small incision in the periphery of the diaphragm and an incision in the left inguinal ligament to gain access to the extraperitoneal space from below. The right limb is tunneled in the space of Retzius in an attempt to decrease kinking that is more likely to occur with subcutaneous, suprapubic tunneling. Thoracofemoral bypass has long-term patency comparable to aortofemoral bypass.Complications of Surgical Aortoiliac ReconstructionWith current surgical techniques and conduits, early postopera-tive hemorrhage is unusual and occurs in 1% to 2%, which is usually the result of technical oversight or coagulation abnor-mality.120 Acute limb ischemia occurring after aortoiliac surgery may be the result of acute thrombosis or distal thromboembo-lism. The surgeon can prevent thromboembolic events by (a) avoiding excessive manipulation of the aorta, (b) ensuring Brunicardi_Ch23_p0897-p0980.indd 94627/02/19 4:14 PM 947ARTERIAL DISEASECHAPTER 23adequate systemic heparinization, (c) judicious placement of vascular clamps, and (d) thorough flushing prior to restoring blood flow. Acute thrombosis of an aortofemoral graft limb in the early perioperative period occurs in 1% to 3% of patients.120 Thrombectomy of the graft limb is performed through a trans-verse opening in the hood of the graft at the femoral anastomo-sis. With this approach, it is possible to inspect the interior of the anastomosis and pass embolectomy catheters distally to clear the superficial femoral and profunda arteries. Various complica-tions may be encountered following aortoiliac or aortobifemoral reconstruction (Table 23-15).Intestinal ischemia following aortic reconstruction occurs in approximately 2% of cases; however, with colonoscopy mucosal ischemia, which is a milder form, is seen more fre-quently. The surgeon can identify patients who require con-comitant revascularization of the IMA, hypogastric arteries, or mesenteric arteries by examining the preoperative arteriogram for the presence of associated occlusive lesions in the celiac axis, the superior mesenteric arteries, or both. Likewise, patients with a patent and enlarged IMA or a history of prior colonic resections will benefit from IMA reimplantation.In a comprehensive review of 747 patients who had aor-toiliac operations for occlusive disease, secondary operations for late complications such as reocclusion, pseudoaneurysms, and infection were necessary in 21% over a 22-year period.121 The most frequent late complication is graft thrombosis. Limb occlusion occurs in 5% to 10% of patients within 5 years of the index operation and in 15% to 30% of patients ≥10 years after the index operation. Anastomotic pseudoaneurysms occur in 1% and 5% of femoral anastomoses in patients with aortofemo-ral grafts. Predisposing factors to pseudoaneurysm formation Table 23-15Perioperative complications of aortobifemoral bypass graftingMedical Complications• Perioperative myocardial infarction• Respiratory failure• Ischemia-induced renal failure• Bleeding from intravenous heparinization• StrokeProcedure-Related ComplicationsEarly• Declamping shock• Graft thrombosis• Retroperitoneal bleeding• Groin hematoma• Bowel ischemia/infarction• Peripheral embolization• Erectile dysfunction• Lymphatic leak• Chylous ascites• ParaplegiaLate• Graft infection• Anastomotic pseudoaneurysm• Aortoenteric fistula• Aortourinary fistula• Graft thrombosisinclude progression of degenerative changes within the host artery, excessive tension at the anastomosis, and infection.121 Due to the associated risks of thrombosis, distal emboliza-tion, infection, and rupture, anastomotic aneurysms should be repaired expeditiously.Infection following aortoiliac reconstruction is a devastat-ing complication that occurs in 1% of cases. Femoral anastomo-ses of aortofemoral reconstructions and axillofemoral bypasses are prone to infection. Use of prophylactic antibiotics and metic-ulous surgical technique are vital in preventing contamination of the graft at the time of implantation. If infection appears local-ized to a single groin, graft preservation and local measures such as antibiotic irrigation, aggressive debridement, and soft tissue coverage with rotational muscle flaps may prove successful. Most patients with infected aortoiliofemoral reconstructions usually require graft excision and revascularization via remote uncontaminated routes or the use of in situ replacement to clear the infective process and maintain limb viability. Aortoenteric fistula and associated gastrointestinal hemorrhage are devas-tating complications, with a 50% incidence of death or limb loss. The incidence of aortoenteric fistula formation appears to be higher after an end-to-side proximal anastomosis because it is more difficult to cover the prosthesis with viable tissue and avoid contact with the gastrointestinal tract with this configu-ration.121 Treatment of aortoenteric fistula requires resection of all prosthetic material, closure of the infrarenal abdominal aorta, repair of the gastrointestinal tract, and revascularization by means of an extra-anatomic graft.Endovascular Treatment for Aortic DiseaseAlthough aortofemoral bypass surgery has excellent long-term patency and can be performed with low mortality rates, there are patients who are unable to withstand the physiologic stress of longer open procedures performed under general anesthe-sia, which require aortic cross-clamping and which are associ-ated with greater blood loss. These patients are more suited to endovascular interventions despite the decreased durability and requirement for more frequent reinterventions.Focal Aortic Stenosis. The endovascular technique used to treat infrarenal aortic stenoses is similar to that used for iliac artery disease. Bilateral CFA access is established followed by insertion of a 6-French sheath. The lesion is crossed using a hydrophilic wire and a supporting selective catheter and then changed for a stiffer guidewire. A self-expanding nitinol stent or a balloon-expandable stent mounted on a larger-caliber angio-plasty balloon is implanted followed by adequate postdilation. At the physician’s discretion, “kissing” stents, simultaneous bilateral proximal iliac stents, are deployed if the lesion is in the distal aorta in the proximity of the aortic bifurcation. The role of covered stents such as cuffs made for endoluminal AAA repair has not been rigorously studied. The aortic diameter should be sized with a calibrated catheter during the angiography or by preintervention CT scanning to avoid undersizing. Balloon size will range from 12 to 18 mm in most cases. A single stent is generally sufficient in most cases. Concentric aortic stenosis may encroach upon the IMA, and coverage of this vessel may be unavoidable. Care should be taken to use low inflation pres-sures (5 mmHg) to minimize the risk of aortic rupture. Patient complaints of back or abdominal pain during balloon infla-tion should be taken seriously as they may suggest impending rupture. In case of a calcified small-caliber, hypoplastic aorta (≤12 mm, typically in female patients), it is recommended to Brunicardi_Ch23_p0897-p0980.indd 94727/02/19 4:14 PM 948SPECIFIC CONSIDERATIONSPART IIuse smaller diameter stents. To achieve clinical improvement, these patients can be recanalized to an aortic diameter of 8 or  9 mm. Distal embolization is one of the potential complications of endovascular treatment for aortic stenoses. Full hepariniza-tion, meticulous technique during wire and catheter manipula-tions, and primary stenting reduce the risk of this complication. Since calcified aortic stenoses are prone to rupture during dila-tion, it is recommended to be cognizant of the extent of the calcification with preoperative CT scans. In case of aortic rup-ture, as long as wire access has been maintained, an occlusion balloon can be inflated proximal to the disrupted segment to achieve hemostasis, and the rupture can be covered with a stent graft or repaired with open surgery.Occlusive Lesions of the Aortic Bifurcation. Occlusive lesions are treated with the kissing balloon technique to avoid dislodging aortic plaque. Two angioplasty balloons of equal size are positioned across the ostia of the common iliac arteries, using a retrograde approach, and inflated. Simultaneous bal-loon dilatation at the origins of both common iliac arteries is advocated, even in the presence of unilateral lesion, to protect the contralateral common iliac artery from dissection or plaque embolization. Calcified lesions that typically occur at the aor-tic bifurcation are not amenable to balloon dilatation and fre-quently require that a distal aortic reconstruction be performed using “kissing stents.” Fears that the proximal ends of the stents that extend into the distal aorta will become a nidus for throm-bus formation or cause hemolysis have not been realized. The results are difficult to interpret because these bifurcation lesions are usually included in studies with iliac artery lesions. Patency rates for aortic bifurcation PTA range from 76% to 92% at  3 years. The largest series reported to date includes 79 patients with aortic bifurcation lesions. The cumulative clinical success rate at a mean of 4 years was 93%.122 Stents have also been used to reconstruct the aortic bifurcation with high success rates. The kissing stent technique is well suited for orificial lesions. Technical success with kissing stents at the aortic bifurcation has been reported to be 95% to 100%.123 In the largest series reported, the primary patency at 3 years was 79%.124Endovascular Treatment for Iliac Artery DiseasePercutaneous Transluminal Angioplasty. PTA is most use-ful in the treatment of isolated iliac stenoses of less than 4 cm in length. When used for stenoses rather than occlusion, a 2-year patency of 86% can be achieved.125 The complication rate is approximately 2%, consisting of distal embolization, medial dissection, and acute thrombosis.Technical Considerations for Iliac Interventions Crossing a high-grade stenosis or occlusion can be challenging in the iliac arteries. It is vital to image the lesion well because multiple views and use of the image intensifier will frequently uncover the anatomic reason for the difficulty. Frequently, the difficulty is the result of vessel tortuosity that cannot be appreciated on the original view. Use of an angled hydrophilic guidewire and an angled catheter can provide steering and add extra support for the wire trying to cross the lesion. Patience, persistence, and periodic reimaging will facilitate the crossing of a lesion in the great majority of cases. Guidewire traversal must be achieved for performance of endovascular iliac intervention. Over 90% of iliac occlusions can be passed with simple guidewire tech-niques. The preferred approach for recanalizing a common iliac artery occlusion is retrograde passage of devices from an ipsi-lateral CFA puncture because, in this manner, distance to the lesion is short and access is straighter. A stenosis is normally crossed using a combination of a soft-tip 0.035-inch guidewire (i.e., Bentson-type wire) or hydrophilic wire and a 5-French straight or selective catheter. One of the hazards of retrograde recanalization is that the guidewire stays in a subintimal loca-tion and cannot be redirected into the true lumen at the aortic bifurcation. There are several approaches that can be used to achieve reentry of total chronic occlusions. Specialized cath-eters allow passage of a needle and guidewire across the intima distal to the occlusion. Intravascular ultrasound can be used for true lumen reentry under fluoroscopic guidance. Another method of achieving true lumen reentry involves performing the recanalization from an antegrade contralateral CFA approach. A 4-French Berenstein catheter (Cordis Corp., Miami Lakes, FL) is used to probe the occlusion. The lesion can be crossed in most instances (5–20% failure rate) with a hydrophilic guidewire or occasionally with its stiffer back end. As soon as the guidewire has crossed the obstruction and lies within the ipsilateral exter-nal iliac artery lumen, it is snared and partially pulled out of the ipsilateral CFA. A short catheter is then inserted in a retrograde fashion over the wire end into the abdominal aorta proximal to the lesion. The hydrophilic guidewire is then exchanged for a stiffer Amplatz (Boston Scientific, Natick, MA) guidewire to facilitate iliac stenting.Obtaining arterial access when there are absent femoral pulsations is aided by the use of ultrasound guidance and “road-map” imaging software, which is available on modern angio-graphic equipment. When the lesion is successfully crossed, balloons of an appropriate size and length are selected for the angioplasty. Most common iliac arteries will accommodate 8to 10-mm diameter balloons, whereas most external iliac arteries will accommodate 6to 8-mm diameter balloons. Inflation is performed with caution, especially if there is heavy calcifica-tion, and should be guided by patient discomfort, pressure gauge readings, and changes in balloon outline.If guidewire traversal is straightforward, consideration should be given to the presence of an acute thrombosis that may benefit from catheter-directed thrombolysis. If guidewire traversal is challenging, it is unlikely that catheter-directed thrombolysis will be beneficial. Stents should be placed after inadequate angioplasty. Stents are warranted when there is a greater than 30% residual stenosis, when there is a flow-limiting dissection, or when there is a pressure gradient of ≥5 mmHg across the treated segment. Placement of stents can precipitate distal embolization in up to 10%, especially if lesions are friable and vulnerable to manipulation. Routine primary stent place-ment is not recommended because it has not been found to be superior to selective stenting in terms of outcomes or cost.Primary Stenting Versus Selective Stenting in Iliac Arteries. Primary stenting rather than selective stenting should be considered for longer iliac lesions and for all TASC C and D lesions. The primary patency rates at 1, 2, and 3 years were 96%, 90%, and 72%, respectively, for longer lesions (>5 cm) that were primarily stented versus 46%, 46%, and 28%, respectively, with selective stenting.126 Primary stenting is generally advocated for chronic iliac artery occlusions, recur-rent stenosis after previous iliac PTA, and complex stenoses with eccentric, calcified, ulcerated plaques or plaques with spontaneous dissection. All of these lesions are prone to distal Brunicardi_Ch23_p0897-p0980.indd 94827/02/19 4:14 PM 949ARTERIAL DISEASECHAPTER 23embolization during manipulation of wires and angioplasty balloons. Distal embolization with isolated PTA is not com-mon for uncomplicated lesions, but can occur in up to 24% of cases, when treating ulcerated plaques, aortoiliac bifurca-tion lesions, or iliac occlusions. It is believed that direct stent placement without predilation significantly reduces the risk of distal embolization by trapping potentially embologenic material between the arterial wall and the stent mesh. While PTA has demonstrated excellent results in focal stenoses of the abdominal aorta and iliacs, primary stenting in these locations is safe, improves patency rates, reduces the degree of resteno-sis when compared with PTA alone, and decreases the risk of distal embolization. Additional potential advantages of direct stenting include shorter procedural time and less radiation exposure. The Dutch Iliac Stent Trial has provided evidence that refutes the superiority of primary stenting over angio-plasty alone.151 Most interventionalists continue to perform angioplasty first and stent selectively for inadequate results. The approach to aortoiliac stenting is intuitive. Individual judgment and experience are important in the decision-making process, and there are lesions with unstable morphology such as long occlusions, ulceration, and dissection that warrant pri-mary stenting.Stent Graft Placement for Aortoiliac Interventions. Stent grafts have been used to treat complex iliac lesions in an attempt to exclude these sources of embolization. A recent report sug-gested that the use of stent grafts was beneficial for TASC C and D lesions.127 Bosiers and colleagues published a series of 91 limbs with diseased iliacs that they treated with 107 stent grafts. They reported successful deployment in all patients with-out distal embolization or vessel rupture and a primary patency rate of 91.1% at 1 year.128 The authors commented about their concerns of causing embolization during placement of the stent grafts and recommended that once an occlusion was traversed with the guidewire, to gently predilate with a 5-mm balloon, followed by smooth stent graft insertion into the newly created channel. The role of stent grafts in aortoiliac occlusive disease has not been fully elucidated yet.Complications of Endovascular Aortoiliac InterventionsIliac artery angioplasty is associated with a 2% to 4% major complication rate and 4% to 15% minor complication rate. Many of these minor complications are related to the arterial puncture site. The most frequent complications relate to access site cannulation. Hemorrhage can range from the more common access site hematoma to the rarer retroperitoneal and intraperi-toneal hemorrhage. Distal embolization occurs in 2% to 10% of iliac PTA and stenting procedures.120 Percutaneous catheter aspiration should be the initial treatment for calf vessel embo-lization, but, for larger emboli, such as those that lodge in the profunda femoris or common femoral arteries, surgical embo-lectomy may be required because the embolic material contains atherosclerotic plaque, which is not amenable to transcatheter aspiration or catheter-directed thrombolysis. The incidence of pseudoaneurysm formation at the puncture site is 0.5%. The treatment of choice for pseudoaneurysms >2 cm in diameter is percutaneous thrombin injection under ultrasound guidance. Arterial rupture may complicate the procedure in 0.3% of cases. Tamponade of the ruptured artery with an occlusion balloon should be performed, and a covered stent should be placed. In case of failure, surgical treatment is required.Clinical Results Comparing Surgical and Endovascular Treatment of Aortoiliac DiseaseThe mortality risk of aortobifemoral bypass in patients with iso-lated, localized aortoiliac disease is relatively low, whereas for patients with concomitant atherosclerosis in coronary, carotid, and visceral vessels, mortality and morbidity are higher. For this reason, the cumulative long-term survival rate for patients receiving aortoiliac reconstruction remains 10 to 15 years less than anticipated for a normal ageand sex-matched population. Twenty-five percent to 30% of patients with concomitant ath-erosclerosis in other vascular distributions are dead within 5 years, and 50% to 60% will have died by 10 years.129Compared with conventional aortobifemoral bypass, common iliac angioplasty was shown to have a 10% to 20% lower overall patency rate. It should be noted that these results were reported in early trials that used older generations of endovascular equipment. With continued progress and newer angioplasty balloons and stenting practices, more comparable outcomes are being reported. Review of the literature confirms that there is an 85% to 90% graft patency rate at 5 years and a 70% to 75% graft patency rate at 10 years after aortobifemo-ral reconstruction.127 Due in part to factors including continued refinements in anesthetic management, intraoperative monitor-ing, and postoperative intensive care, low perioperative mortal-ity rates for aortobifemoral bypass can be achieved commonly in today’s clinical practice. The most recent systematic review and meta-analysis of 5358 patients who underwent direct open bypass or endovascular treatment for aortoiliac occlusive dis-ease demonstrated superior durability for open bypass, although with longer length of stay and increased risk for complications and mortality, when compared to the endovascular approach.130 In this study, poor preoperative runoff was greater in the open bypass group (50.0% vs. 24.6%). Mean length of hospital stay was 13 days for open bypass versus 4 days for endovascular treatment procedures. The open bypass group experienced more complications (18.0% vs. 13.4%) and greater 30-day mortality (2.6% vs. 0.7%). At 1, 3, and 5 years, pooled primary patency rates were greater in the open bypass group (94.8% vs. 86.0%, 86.0% vs. 80.0%, and 82.7% vs. 71.4%, respectively); the same was true for secondary patency (95.7% vs. 90.0%, 91.5% vs. 86.5%, and 91.0% vs. 82.5%, respectively).Despite its lower long-term success, common iliac angio-plasty is a useful procedure in patients with focal disease and mild symptoms in whom a major surgical revascularization is not justified. Angioplasty of the iliac vessels can be a useful adjunct to distal surgical bypass as well, increasing the success of dis-tal revascularization and eliminating the risks associated with aortoiliac bypass. Thus, with long-term patency less than, but comparable to, open surgical bypass, and with more favorable morbidity rates, iliac angioplasty has become a well-accepted modality of treatment for iliac occlusive disease. Ideal iliac angioplasty lesions are nonocclusive and short. Patency after intervention is better when lesions occur in larger diameter ves-sels, when stenoses rather than occlusions are treated, when run-off vessels are patent, and when the indication for intervention is lifestyle-limiting claudication rather than critical limb ischemia.Becker and colleagues estimated a 5-year patency rate of 72% in an analysis of 2697 cases of iliac angioplasty and noted a better patency (79%) in claudicants.131 Less favorable results are obtained with long stenoses, external iliac stenoses, and tan-dem lesions. The reported technical and initial clinical success of balloon angioplasty in iliac artery stenoses exceeds 90% in 5Brunicardi_Ch23_p0897-p0980.indd 94927/02/19 4:14 PM 950SPECIFIC CONSIDERATIONSPART IImost series, and the 5-year patency rates range from 54% to 92%. The reported technical and initial clinical success of bal-loon angioplasty in iliac artery occlusions ranges from 78% to 98%, and the 3-year patency rates range from 48% to 85%.131,132Factors reported to affect the patency of aortoiliac endovas-cular interventions adversely include quality of runoff vessels, severity of ischemia, and length of diseased segments treated. Likewise, as vessel diameter and flow rates change, so do suc-cess rates after angioplasty. It was reported in the literature that location of the lesion at the external iliac artery adversely affects both primary and assisted-primary patency. Following angio-plasty of the common iliac artery, patency rates were 81% and 52% at 1 and 6 years, respectively; whereas, after external iliac artery angioplasty, they were 74% and 48% at 1 and 4 years, respectively.133 Although some literature supports location of the lesion in the external iliac artery as a factor that adversely affects both primary and assisted-primary patency, this has not been a universal finding. Female patients are also reported to have lower patency rates than males following iliac PTA, with or without stent placement in the external iliac artery.134Stenting of the iliac arteries provides a durable and curative treatment, with a 3-year patency rate of 41% to 92% for stenosis and a 3-year patency rate of 64% to 85% and 4-year patency rate of 54% to 78% for occlusions.132 A meta-analysis of 2116 patients by Bosch and Hunink showed that aortoiliac stenting resulted in a 39% improvement in long-term patency compared to balloon angioplasty, despite the fact that complication rates and 30-day mortality rates did not differ significantly.135 Park and colleagues presented long-term follow-up results in a cohort of patients with all four TASC types of iliac lesions. The authors presented primary patency rates of 87%, 83%, 61%, and 49% at 3, 5, 7, and 10 years, respectively, after the index intervention.136 Leville and colleagues achieved primary and secondary patency rates of 76% and 90%, respectively, after 3 years, in a cohort of patients who received stents for iliac occlusions.137 The authors postulated that endovascular treatment for iliac occlusive dis-ease should be extended to type C and D lesions, because they observed no detectable differences between the four TASC clas-sifications in terms of primary and secondary patency rates.137 They concluded that presence of TASC C and D lesions should not preclude endovascular treatment and believe that endovas-cular attempts should be exhausted before open surgical repair of iliac occlusions is attempted because of the decreased periop-erative morbidity and good midterm durability.Not all results have been in favor of stenting, and at present, universal primary stenting cannot be recommended. Although stents are often used to improve the outcome of PTA, there is no general consensus that stenting should be mandatory in all iliac lesions. Complex, ulcerated iliac lesions with high embologenic potential or recanalized chronic iliac occlusions may be an exception. In the Dutch Iliac Stent Trial, primary stenting did not prove to be superior to iliac angioplasty and selective stenting.138 The researchers in this prospective ran-domized multicenter study concluded that balloon angioplasty with selective stenting had comparable 2-year patency rates with primary stenting (77% and 78%, respectively). It must be noted, however, that it was necessary to stent 43% of the patients in the PTA treatment group due to unsatisfactory angioplasty results. The 5-year outcomes between the two groups were also similar, with 82% and 80% of the treated iliac segments remaining free of the need for new revascularization procedures after a mean follow-up of 5.6 ± 1.3 years.138LOWER EXTREMITY ARTERIAL OCCLUSIVE DISEASEThe symptoms of lower extremity occlusive disease are classi-fied into two large categories: acute limb ischemia (ALI) and chronic limb ischemia (CLI). Ninety percent of acute ischemia cases are either thrombotic or embolic. Frequently, sudden onset of limb-threatening ischemia may be the result of acute exacerbation of the preexisting atherosclerotic disease. Chronic ischemia is largely due to atherosclerotic changes of the lower extremity that manifest from asymptomatic to limb-threatening gangrene. As the population ages, the prevalence of chronic occlusive disease of the lower extremity is increasing, and it significantly influences lifestyle, morbidity, and mortality. In addition, multiple comorbid conditions increase risks of surgical procedures. Endovascular interventions become an important alternative in treating lower extremity occlusive disease. How-ever, despite rapidly evolving endovascular technology, lower extremity endovascular intervention continues to be one of the most controversial areas of endovascular therapy.EpidemiologyIn a detailed review of the literature, McDaniel and Cronenwett concluded that claudication occurred in 1.8% of patients under 60 years of age, 3.7% of patients between 60 and 70 years of age, and 5.2% of patients over 70 years of age.139 Leng and his colleagues scanned 784 subjects using ultrasound in a random sample of men and women age 56 to 77 years. Of the subjects who were scanned, 64% demonstrated atherosclerotic plaque.140 However, a large number of patients had occlusive disease with-out significant symptoms. In a study by Schroll and Munck, only 19% of patients with peripheral vascular disease were symptomatic.141 Using ABIs, Stoffers and colleagues scanned 3171 individuals between the ages of 45 and 75 and identified that 6.9% of patients had ABIs <0.95, only 22% of whom had symptoms.142 In addition, they demonstrated that concomitant cardiovascular and cerebrovascular diseases were three to four times higher among the group with asymptomatic peripheral vascular diseases than those without peripheral vascular disease. Furthermore, they confirmed that 68% of all peripheral arterial obstructive diseases were unknown to the primary care physi-cian, and this group mainly represented less advanced cases of atherosclerosis. However, among patients with an ABI ratio <0.75, 42% were unknown to the primary physicians.Diagnostic EvaluationThe diagnosis of lower extremity occlusive disease is often made based on a focused history and physical examination and confirmed by the imaging studies. A well-performed physi-cal examination often reveals the site of lesions by detecting changes in pulses, temperature, and appearances. The bedside ABIs using blood pressure cuff also aid in diagnosis. Various clinical signs and symptoms are useful to differentiate condi-tions of viable, threatened, and irreversible limb ischemia caused by arterial insufficiency (Table 23-16).Noninvasive studies are important in documenting the severity of occlusive disease objectively. Ultrasound Dopplers measuring ABIs and segmental pressures are widely used in North America and Europe. Normal ABI is greater than 1.0. In patients with claudication, ABIs decrease to 0.5 to 0.9 and to even lower levels in patients with rest pain or tissue loss. Seg-mental pressures are helpful in identifying the level of involve-ment. Decrease in segmental pressure between two segments indicates significant disease. Ultrasound duplex scans are used Brunicardi_Ch23_p0897-p0980.indd 95027/02/19 4:14 PM 951ARTERIAL DISEASECHAPTER 23Table 23-16Signs and symptoms of acute limb ischemiaDESCRIPTIONCATEGORYVIABLETHREATENEDIRREVERSIBLEClinical descriptionNot immediately  threatenedSalvageable if promptly  treatedMajor tissue loss, amputation unavoidableCapillary returnIntactIntact, slowAbsent (marbling)Muscle weaknessNoneMild, partialProfound, paralysis (rigor)Sensory lossNoneMild, incompleteProfound anestheticArteriovenous Doppler findingAudibleInaudible or audibleInaudibleto identify the site of lesion by revealing flow disturbance and velocity changes. A meta-analysis of 71 studies by Koelemay and associates confirmed that duplex scanning is accurate for assessing arterial occlusive disease in patients suffering from claudication or critical ischemia with an accumulative sensitiv-ity of 80% and specificity of over 95%.143 Adding an ultrasound contrast agent further increases the sensitivity and specificity of ultrasound technology. Other noninvasive imaging technolo-gies, such as MRA and CTA, are rapidly evolving and gaining popularity in the diagnosis of lower extremity occlusive disease (Figs. 23-59 and 23-60).Contrast angiography remains the gold standard imaging study. Using contrast angiography, interventionists can locate and size the anatomic significant lesions and measure the pres-sure gradient across the lesion, as well as plan for potential inter-vention. Angiography is, however, semi-invasive and should be confined to patients for whom surgical or percutaneous inter-vention is contemplated. Patients with borderline renal function may need to have alternate contrast agents, such as gadolinium or carbon dioxide, to avoid contrast-induced nephrotoxicity.Differential DiagnosisArterial insufficiency frequently leads to muscle ischemic pain involving the lower extremity muscles, particularly during exer-cise. Intermittent claudication is pain affecting the calf and, less commonly, the thigh and buttock that is induced by exercise and relieved by rest. Symptom severity varies from mild to severe. Intermittent claudication occurs as a result of muscle ischemia during exercise caused by obstruction to arterial flow. Regarding the differential diagnosis of intermittent claudication, there are a variety of neurologic, musculoskeletal, and venous conditions that may produce symptoms of calf pain (Table 23-17). Addi-tionally, various nonatherosclerotic conditions can also cause symptoms consistent with intermittent lower extremity claudi-cation (Table 23-18). Nocturnal calf muscle spasms or night cramps are not indicative of arterial disease. They are common but are difficult to diagnose with certainty. Foot ulceration is not always the result of arterial insufficiency. Ischemic ulcers occur on the toes or lateral side of the foot and are painful. By com-parison, venous ulcers, which are also common, occur above the medial malleolus, usually in an area with the skin changes of lipodermatosclerosis, and cause mild discomfort. Neuropathic ulcers are usually found on weight-bearing surfaces, have thick calluses, and are pain free. Ulcers may be the result of more than one etiology. Rest pain must be distinguished from periph-eral neuropathy, which is prevalent in diabetic patients. Patients with diabetic neuropathy tend to have decreased vibration and Figure 23-59. High-resolution computed tomography angiogra-phy of a patient with normal right lower extremity arterial circu-lation. Distal occlusive disease is noted in the left tibial arteries (arrow).position sense and decreased reflexes. Spinal stenosis causes pain that is exacerbated with standing and back extension.Lower Extremity Occlusive Disease ClassificationLower extremity occlusive disease may range from exhibiting no symptoms to limb-threatening gangrene. There are two major classifications developed based on the clinical presentations.Brunicardi_Ch23_p0897-p0980.indd 95127/02/19 4:15 PM 952SPECIFIC CONSIDERATIONSPART IIFigure 23-60. Multidetector computed tomography angiography of a patient with an (A) infrapopliteal arterial circulation and (B) pedal arterial circulation. The high spatial resolution and image quality of these images shows three patent infrapopliteal runoff vessels and patent pedal vessels at the foot level.BAThe Fontaine classification uses four stages: Fontaine I is the stage when patients are asymptomatic; Fontaine II is when they have mild (IIa) or severe (IIb) claudication; Fon-taine III is when they have ischemic rest pain; and Fontaine IV is when patients suffer tissue loss, such as ulceration or gangrene (Table 23-19).144The Rutherford classification has four grades (0–III) and seven categories (0–6). Asymptomatic patients are classi-fied into category 0; claudicants are stratified into grade I and divided into three categories based on the severity of the symp-toms; patients with rest pain belong to grade II and category 4; and patients with tissue loss are classified into grade III and categories 5 and 6 based on the significance of the tissue loss.2 These clinical classifications help to establish uniform standards in evaluating and reporting the results of diagnostic measure-ments and therapeutic interventions (Table 23-19).The most clinically useful classification of lower extrem-ity atherosclerotic disease should be based on the morphologic character of the lesions. The TASC taskforce published a guide-line separating lower extremity arterial diseases into femoropop-liteal and infrapopliteal lesions (Table 23-20). This guideline is particularly useful in determining intervention strategies based on the disease classifications. Based on the guideline, femoro-popliteal lesions are divided into four types: A, B, C, and D. Type A lesions are single focal lesions less than 3 cm in length and do not involve the origins of the SFA or the distal popliteal artery. Type B lesions are single lesions 3 to 5 cm in length not involving the distal popliteal artery or multiple or heavily calci-fied lesions less than 3 cm in length. Type C lesions are multiple stenoses or occlusions greater than 15 cm in length or recurrent stenoses or occlusions that need treatment after two endovascu-lar interventions. Type D lesions are those with complete occlu-sion of CFA, SFA, or popliteal artery.115In a similar fashion, infrapopliteal arterial diseases are classified into four types based on TASC guideline (Fig. 23-61). Type A lesions are single lesions less than 1 cm in length not involving the trifurcation. Type B lesions are multiple lesions less than 1 cm in length or single lesions shorter than 1 cm involving the trifurcation. Type C lesions are lesions that exten-sively involve trifurcation or 1to 4-cm stenotic or 1to 2-cm occlusive lesions. Type D lesions are occlusions longer than  2 cm or diffuse lesions.115Etiology of Acute Limb IschemiaALI is defined as sudden loss of limb perfusion, and the term is applicable up to 2 weeks after an initiating event. While the instances of acute leg ischemia caused by emboli have decreased due to more effective treatment of rheumatic fever and atrial fibrillation, the incidence of thrombotic acute leg ischemia has increased. Even with the extensive use of newer endovascular techniques including thrombolysis, most published series report a 10% to 30% 30-day amputation rate.115 The short-term mortal-ity of patients presenting with acute ischemia is 15% to 20%. The most common etiologies of ALI include embolism, native vessel thrombosis, reconstruction thrombosis, trauma, and com-plications of peripheral aneurysm. Most cases of lower extrem-ity ALI are the result of thrombosis of a prosthetic conduit. This stems from increased use of prosthetic conduits to address CLI.Presenting symptoms in ALI are pain and loss of sensory or motor function. The abruptness and time of onset of the pain, its location and intensity, and change in severity over time should all be taken into consideration. The duration and inten-sity of the pain and presence of motor or sensory changes are very important in clinical decision making and urgency of revas-cularization. Thrombolysis may be less effective for thrombosis of ≥2 weeks in duration compared with acute thrombosis.145Arterial Embolism. The heart is the most common source of distal emboli, which accounts for more than 90% of peripheral arterial embolic events. Atrial fibrillation is the most common source. Sudden cardioversion results in the dilated noncon-tractile atrial appendage regaining contractile activity, which can dislodge the contained thrombus. Other cardiac sources include mural thrombus overlying a myocardial infarction or thrombus forming within a dilated left ventricular aneurysm. Mural thrombi can also develop within a ventricle dilated by Brunicardi_Ch23_p0897-p0980.indd 95227/02/19 4:15 PM 953ARTERIAL DISEASECHAPTER 23Table 23-17Differential diagnosis of intermittent claudicationCONDITIONLOCATION OF PAIN OR DISCOMFORTCHARACTERISTIC DISCOMFORTONSET RELATIVE TO EXERCISEEFFECT OF RESTEFFECT OF BODY POSITIONOTHER CHARACTERISTICSIntermittent claudication (calf)Calf musclesCramping painAfter same degree of exerciseQuickly relievedNoneReproducibleChronic compartment syndromeCalf musclesTight, bursting painAfter much exercise (e.g., jogging)Subsides very slowlyRelief speeded by elevationTypically heavy-muscled athletesVenous claudicationEntire leg, but usually worse in thigh and groinTight, bursting painAfter walkingSubsides slowlyRelief speeded by elevationHistory of iliofemoral deep venous thrombosis, signs of venous congestion, edemaNerve root compression (e.g., herniated disk)Radiates down leg, usually posteriorlySharp lancinating painSoon, if not immediately after onsetNot quickly relieved (also often present at rest)Relief may be aided by adjusting back positionHistory of back problemsSymptomatic Baker’s cystBehind knee, down calfSwelling, soreness, tendernessWith exercisePresent at restNoneNot intermittentIntermittent claudication (hip, thigh, buttock)Hip, thigh, buttocksAching discomfort, weaknessAfter same degree of exerciseQuickly relievedNoneReproducibleHip arthritisHip, thigh, buttocksAching discomfortAfter variable degree of exerciseNot quickly relieved (and may be present at rest)More comfortable sitting, weight taken off legsVariable, may relate to activity level, weather changesSpinal cord compressionHip, thigh, buttocks (follows dermatome)Weakness more than painAfter walking or standing for same length of timeRelieved by stopping only if position changedRelief by lumbar spine flexion (sitting or stooping forward) pressureFrequent history of back problems, provoked by increased intra-abdominal pressureIntermittent claudication (foot)Foot, archSevere deep pain and numbnessAfter same degree of exerciseQuickly relievedNoneReproducibleArthritic, inflammatory processFoot, archAching painAfter variable degree of exerciseNot quickly relieved (and may be present at rest)May be relieved by not bearing weightVariable, may relate to activity levelBrunicardi_Ch23_p0897-p0980.indd 95327/02/19 4:15 PM 954SPECIFIC CONSIDERATIONSPART IITable 23-18Nonatherosclerotic causes of intermittent claudication• Aortic coarctation• Arterial fibrodysplasia• Iliac syndrome of the cyclist• Peripheral emboli• Persistent sciatic artery• Popliteal aneurysm• Popliteal cyst• Popliteal entrapment• Primary vascular tumors• Pseudoxanthoma elasticum• Remote trauma or radiation injury• Takayasu’s disease• Thromboangiitis obliteransTable 23-19Classification of peripheral arterial disease based on the Fontaine and Rutherford classificationsFONTAINE CLASSIFICATIONRUTHERFORD CLASSIFICATIONSTAGECLINICALGRADECATEGORYCLINICALIAsymptomatic00AsymptomaticIIaMild claudicationI1Mild claudicationIIbModerate to severe claudicationI2Moderate claudication  I3Severe claudicationIIIIschemic rest painII4Ischemic rest painIVUlceration or gangreneIII5Minor tissue loss  III6Major tissue losscardiomyopathy. Emboli that arise from a ventricular aneurysm or from a dilated cardiomyopathy can be very large and can lodge at the aortic bifurcation (saddle embolus), thus rendering both legs ischemic. Diseased valves are another source of distal embolization. Historically, this occurred as a result of rheumatic heart disease. Currently, subacute endocarditis and acute bacte-rial endocarditis are the more common causes. Infected emboli can seed the recipient vessel wall, creating mycotic aneurysms.An electrocardiogram (ECG) will diagnose atrial fibrilla-tion. A transthoracic or transesophageal echocardiogram should be performed looking for a cardiac source. It is important to seek other sources of the embolus using CT scanning of the descending thoracic and abdominal aorta. More unusual sources include mural thrombus from an aortic aneurysm, and occa-sionally, idiopathic arterial-to-arterial thrombus occurs, usually from thrombus that has formed in an atherosclerotic aortic arch or descending thoracic aorta. The presence of mobile plaque on transesophageal echocardiography is suggestive of this source.Paradoxical embolus occurs when a patient has a patent foramen ovale and an embolus from a deep venous thrombosis crosses through the atrial defect into the left side of the heart and passes into the peripheral circulation. This is diagnosed using a bubble echocardiography, in which air bubbles introduced into the venous circulation can be seen traversing the septal defect.Arterial Thrombosis. Thrombosis can occur in native arteries and in arterial reconstructions. Patients with thrombosed arte-rial segments often have an underlying atherosclerotic lesion at the site of thrombosis or aneurysmal degeneration with mural thrombosis. It is important to obtain a history, determine risk factors for atherosclerosis and hypercoagulable status, and examine the contralateral extremity for circulatory problems. Patients with thrombosis of prior arterial reconstructions have limb incisions from previous surgery, and graft occlusion can be confirmed with duplex imaging.Clinical Manifestations of Acute Limb IschemiaAcute lower extremity ischemia manifests with the “five Ps”: pain, pallor, paresthesias, paralysis, and pulselessness, to which some add a sixth “P”—poikilothermia or “perishing cold.” Pain is the usual symptom that causes a patient to present to the emergency room. The most common location for an embolus to lodge in the leg is at the common femoral bifurcation. Typically, a patient will complain of foot and calf pain. Pulses are absent, and there may be diminution of sensation. Inability to move the affected muscle group is a sign of very severe ischemia and necessitates urgent revascularization. During evaluation of the affected extremity, it is important to compare findings with the contralateral limb. Clinical evaluation is extremely important in determining the etiology and location of the obstruction. One of the most important pieces of information to obtain is whether the patient has had prior vascular procedures or if there is a history of lower extremity claudication. Either of these features suggests preexisting vascular disease, renders revasculariza-tion more complicated, and usually mandates angiography to permit surgical planning. On the contrary, in a patient with no history suggestive of prior vascular disease, the etiology is most likely embolic, and simple thrombectomy is more likely to be successful.Absent bilateral femoral pulses in a patient with bilateral lower extremity ischemia is most likely due to saddle embolus to the aortic bifurcation. A palpable femoral pulse and absent popliteal and distal pulses may either be due to distal common femoral embolus (the pulse being palpable above the level of occlusion) or embolus to the superficial femoral or popliteal arteries. Typically, emboli lodge at arterial bifurcations where they are trapped due to sudden reductions in arterial diameter. A popliteal trifurcation embolus will present with calf ischemia and absent pedal pulses, possibly with a popliteal pulse present. The finding of palpable contralateral pulses and the absence of ipsilateral pulses in the acutely ischemic leg are suggestive of an embolus, irrespective of presence of Doppler signals. Brunicardi_Ch23_p0897-p0980.indd 95427/02/19 4:15 PM 955ARTERIAL DISEASECHAPTER 23Table 23-20TransAtlantic Inter-Society Consensus classification of femoral popliteal occlusive lesionsType A lesions• Single stenosis ≤10 cm in length• Single occlusion ≤5 cm in lengthType B lesions• Multiple lesions (stenoses or occlusions), each ≤5 cm• Single stenosis or occlusion ≤15 cm not involving the infrageniculate popliteal artery• Single or multiple lesions in the absence of continuous tibial vessels to improve inflow for a distal bypass• Heavily calcified occlusion ≤5 cm in length• Single popliteal stenosisType C lesions• Multiple stenoses or occlusions totaling >15 cm with or without heavy calcification• Recurrent stenoses or occlusions that need treatment after two endovascular interventionsType D lesions• Chronic total occlusions of CFA or SFA (>20 cm, involving the popliteal artery)• Chronic total occlusion of popliteal artery and proximal trifurcation vesselsCFA = common femoral artery; SFA = superficial femoral artery.Type A lesionsType B lesionsType C lesionsType D lesionsFigure 23-61. Schematic depiction of TransAtlantic Inter-Society Consensus classification of femoral popliteal occlusive lesions.Arteriography is not mandatory in patients without antecedent history suggestive of vascular disease; nevertheless, all patients should be positioned on the operating room table in such a way that fluoroscopic access to the entire inflow and outflow tract is possible if necessary.The main question to be answered by the history and phys-ical examination is the severity of the ALI, which is the major consideration in early management decisions. Patients with ALI should be evaluated in a fashion that considers the severity and duration of ischemia at the time of presentation. Ideally, all patients with acute ischemia should be investigated with imag-ing, especially if there is an antecedent vascular reconstruction; however, the clinical condition and access to resources must guide further investigations. Unnecessary delays can result in amputation. Arteriography, if it can be performed in a timely fashion, is an excellent modality for localizing obstructions and deciding which type of intervention (endovascular, embolec-tomy, or bypass) patients will benefit more from. One of the goals of treatment for ALI is to prevent thrombus propagation; therefore, expedient anticoagulation with heparin is indicated as soon as the diagnosis is suspected.Treatment Considerations for Acute Limb IschemiaIn the absence of any significant contraindication, the patient with an ischemic lower extremity should be immediately anti-coagulated. This will prevent propagation of the clot into unaf-fected vascular beds. Intravenous fluid should be started and a Foley catheter inserted to monitor urine output. Baseline labs should be obtained and creatinine levels noted. A hypercoagula-ble workup should be performed prior to initiation of heparin if there is sufficient suspicion. According to results from random-ized trials, there is no clear superiority for thrombolysis over surgery in terms of 30-day limb salvage or mortality. Access to each treatment option is a major issue in the decision-making process, as time is often critical. National registry data from the United States reveal that surgery is used threeto five-fold more frequently than thrombolysis. Three randomized studies have investigated the role of catheter-directed thrombolytic therapy in the treatment of ALI.145Endovascular TreatmentThe potential to reduce mortality and morbidity while achiev-ing limb salvage is the impetus that makes thrombolysis prefer-able to open surgery as first-line treatment in patients with ALI (classes I and IIa). Advantages of thrombolytic therapy over balloon embolectomy include the reduced endothelial trauma and potential for more gradual and complete clot lysis in branch vessels usually too small to access by embolectomy balloons. It is hoped that the more gradual clot dissolution with throm-bolysis may decrease the incidence of reperfusion injury that is encountered after open surgical procedures where rapid return of blood flow may precipitate compartment syndrome. Skeletal muscle tissue appears to be most vulnerable to ischemia. Patho-physiologic studies reveal that irreversible damage to muscle tissue starts after 3 hours of ischemia and is nearly complete at 6 hours. Progressive microvascular damage appears to follow rather than precede skeletal muscle tissue damage. The more severe the cellular damage, the greater are the microvascu-lar changes. When the musculature and microvasculature are severely damaged, amputation rather than attempts at revascu-larization may be the most prudent course to prevent wash-out of toxic by-product from the ischemic limb into the systemic circulation. The mortality rate associated with reperfusion syn-drome is high because of the development of concomitant adult respiratory distress syndrome, shock, disseminated intravascular coagulation, and renal failure.Patients with small-vessel occlusion are poor candidates for surgery because they lack distal target vessels to use for bypass. These patients should be offered a trial of thromboly-sis, unless they have contraindications to thrombolysis or their Brunicardi_Ch23_p0897-p0980.indd 95527/02/19 4:15 PM 956SPECIFIC CONSIDERATIONSPART IIischemia is so severe that the time needed to achieve adequate lysis is considered too long. The major contraindications of thrombolysis are recent stroke, intracranial primary malignancy, brain metastases, or intracranial surgical intervention. Relative contraindications for performance of thrombolysis include renal insufficiency, allergy to contrast material, cardiac thrombus, diabetic retinopathy, coagulopathy, and recent arterial puncture or surgery (Table 23-21).Advances in clot removal techniques with percutaneous mechanical thrombectomy and thromboaspiration may extend the applicability of this intervention to patients with more advanced degrees of ALI (class IIb) and contraindications to thrombolysis. Several thrombectomy devices have received FDA approval for acute lower extremity arterial thrombosis. The utility of these thrombectomy devices is that they can be used as standalone therapy when there are contraindications for thrombolytic therapy. Additionally, these thrombectomy devices can be used in conjunction with thrombolytic agents, for pharmacomechanical thrombectomy, to enhance clot lysis and to limit the doses and time required for thrombolysis.145Surgical TreatmentEmbolectomy. When a decision is made to proceed with open surgical intervention, the abdomen, contralateral groin, and entire lower extremity are prepped in the field. The groin is opened through a vertical incision, exposing the CFA and its bifurcation. Frequently, the location of the embolus at the femo-ral bifurcation is readily apparent by the presence of a palpable proximal femoral pulse, which disappears distally. The artery is clamped and opened transversely over the bifurcation. Throm-bus is extracted by passing a Fogarty balloon embolectomy catheter. Good back-bleeding and antegrade bleeding suggest that the entire clot has been removed. Embolic material often forms a cast of the vessel and is sent for culture and histologic examination. Completion angiography is advisable to ascertain Table 23-21Contraindications to thrombolytic therapyAbsolute contraindicationsEstablished cerebrovascular events (including transient ischemic attack) within last 2 monthsActive bleeding diathesisRecent (<10 days) gastrointestinal bleedingNeurosurgery (intracranial or spinal) within last 3 monthsIntracranial trauma within last 3 monthsIntracranial malignancy or metastasisRelative major contraindicationsCardiopulmonary resuscitation within last 10 daysMajor nonvascular surgery or trauma within last 10 daysUncontrolled hypertension (>180 mmHg systolic  or >110 mmHg diastolic)Puncture of noncompressible vesselIntracranial tumorRecent eye surgeryMinor contraindicationsHepatic failure, particularly with coagulopathyBacterial endocarditisPregnancyDiabetic hemorrhagic retinopathythe adequacy of clot removal. The artery is then closed and the patient fully anticoagulated.When an embolus lodges in the popliteal artery, in most cases it can be extracted via a femoral incision using the tech-niques previously described. A femoral approach is preferred because the larger diameter of the femoral artery results in decreased likelihood of arterial compromise when the arte-riotomy is closed. The disadvantage with using the femoral approach for embolectomy is the greater difficulty involved in directing the embolectomy catheter into each of the infrapopli-teal arteries. Use of fluoroscopic imaging and an over-the-wire thrombectomy catheter can overcome this problem. Alterna-tively, use of a separate incision to expose the popliteal bifurca-tion may be necessary to achieve a complete thrombectomy.A more complex situation arises when a patient has antecedent peripheral vascular disease and in situ thrombosis develops on top of preexisting atheroma because, frequently, embolectomy catheters will not pass through these occlusions. Similarly, when a bypass graft fails, it is usually due to progres-sion of atheroma proximal or distal to the graft anastomoses or to intrinsic stenoses that develop within a vein graft. In these scenarios, expeditious angiography is useful to determine the extent of the occlusion, to search for inflow and distal outflow vessels, and to decide whether thrombolysis or surgery will be the better intervention. Although the surgeon’s preference tends to dictate the approach selected, the decision is based on the presence or absence of good target vessels and availability of a suitable bypass conduit. If there are good distal vessels and the saphenous vein is suitable, surgical bypass is recommended because it is fast, durable, and reliable. In the absence of a good distal target and saphenous vein, or in a patient at high risk for surgery, lysis is recommended.Bypass Graft Thrombectomy. Bypass thrombectomy is more likely to succeed with prosthetic bypasses. Bypass graft revision or replacement is more appropriate for acute vein graft failures because they are less likely to respond to thrombolysis and require some type of revision, such as valve lysis, interposition, or extension. Thrombectomy of autogenous grafts is prone to failure unless an anatomic cause for failure such as a retained valve or unligated side branch is found and corrected. The per-formance of a fasciotomy to circumvent reperfusion injury/com-partment syndrome is an important consideration.Complications Related to Treatment for Acute Limb IschemiaAdverse events related to catheter-directed thrombolysis are primarily related to bleeding complications. The overall risk of hemorrhagic stroke from a thrombolysis procedure has been reported to be 1% to 2.3%, with 50% of hemorrhagic compli-cations occurring during the thrombolytic procedure.146 Hema-toma at the vascular puncture site has been reported in 12% to 17% of cases. Gastrointestinal bleeding is reported in 5% to 10% of cases. Hematuria following thrombolysis is uncom-mon and should prompt a search for urinary tumors. Hemor-rhage requiring transfusion can occur in approximately 25% of patients undergoing thrombolysis. Lytic agents are absolutely contraindicated in patients with intracranial surgery, intracra-nial hemorrhage within the last 3 months, or any active bleed-ing. Most bleeding complications occur at the arterial puncture sites, but concealed retroperitoneal bleeding is possible. The most feared complication that patients can sustain is intrace-rebral hemorrhage. Older patients may be more susceptible Brunicardi_Ch23_p0897-p0980.indd 95627/02/19 4:15 PM 957ARTERIAL DISEASECHAPTER 23to this complication, and thus many interventionalists are extremely reticent to use thrombolysis in patients older than 80 years of age.Patients who are treated for acute ischemia are susceptible to two major complications following revascularization: reper-fusion and compartment syndromes. Other procedure-related complications include arterial rethrombosis, recurrent emboli-zation, and arterial injuries secondary to the balloon catheter manipulations.Reperfusion of the ischemic limb is variable in its physi-ologic effects and directly relates to the severity and extent of the ischemia. Patients with a saddle embolus of the aortic bifurcation and severely ischemic limbs may develop the full-blown “reperfusion syndrome,” whereas patients with minimal muscle ischemia who are reperfused in a timely fashion essen-tially develop no effects. Many patients with ALI have severe underlying cardiac disease and are unable to tolerate even short ischemic periods. Complications occurring after revasculariza-tion of the lower extremity and causes of recurrent thrombosis are listed in Table 23-22.Compartment syndrome occurs after prolonged ischemia is followed by reperfusion. The capillaries leak fluid into the interstitial space in the muscles, which are enclosed within a nondistensible fascial envelope. When the pressure inside the compartment exceeds the capillary perfusion pressure, nutrient flow ceases and progressive ischemia occurs, even in the pres-ence of peripheral pulses. Consequently, every patient who has sustained an ischemic event and is reperfused is monitored for compartment syndrome, which is characterized by excessive Table 23-22Complications of arterial revascularizationCompartment syndromeIschemic neuropathyMuscle necrosisRecurrent thrombosisLower leg swellingReperfusion syndrome Hypotension Hyperkalemia Myoglobinuria Renal failureTable 23-23Fascial compartments of the lower leg ANTERIOR COMPARTMENTLATERAL COMPARTMENTSUPERFICIAL POSTERIOR COMPARTMENTDEEP POSTERIOR COMPARTMENTMusclesTibialis anteriorExtensor digitorum longusPeroneus tertiusExtensor hallucis longusExtensor digitorum brevisExtensor hallucis brevisPeroneus longusPeroneus brevisGastrocnemiusPlantarisSoleusTibialis posteriorFlexor digitorum longusFlexor hallucis longusArteryAnterior tibial arteryAnterior and posterior tibial branches of the popliteal arteryPosterior tibial arteryPeroneal arteryNerveDeep peroneal nerveSuperficial peroneal nerve Tibial nervepain in the compartment, pain on passive stretching of the com-partment, and sensory loss due to nerve compression of the nerves coursing through the compartment (Table 23-23 and  Fig. 23-62). The most commonly affected compartment is the anterior compartment in the leg. Numbness in the web space between the first and second toes is diagnostic due to com-pression of the deep peroneal nerve. Compartment pressure is measured by inserting an arterial line into the compartment and recording the pressure. Although controversial, pressures greater than 20 mmHg are an indication for fasciotomy. Com-partment pressures are relieved in the leg by medial and lateral incisions. Through the medial incision, long openings are then made in the fascia of the superficial and deep posterior com-partments. Through the lateral incision, the anterior and pero-neal compartments are opened. Both skin and fascial incisions should be of adequate length to ensure full compartment decom-pression. Laboratory evidence of rhabdomyolysis is seen in 20% of cases. The myoglobin from damaged muscle precipitates in kidney tubules and causes acute tubular necrosis. Alkalinization of urine increases the solubility of myoglobin, thus preventing Tibia AnteriorcompartmentLateralcompartmentFibulaDeep posteriorcompartmentSuperficial posterior compartmentFigure 23-62. Schematic illustration of fascial compartments of the lower extremity.Brunicardi_Ch23_p0897-p0980.indd 95727/02/19 4:15 PM 958SPECIFIC CONSIDERATIONSPART IIit from crystallizing in the tubules. In addition to alkalinization, therapy consists of forced saline diuresis and removal of the source of dead muscle that is releasing the myoglobin.Clinical Manifestations of Chronic Limb IschemiaThe term CLI is reserved for patients with objectively proven arterial occlusive disease and symptoms lasting for more than 2 weeks. Symptoms include rest pain and tissue loss, such as ulceration or gangrene (Table 23-24). The diagnosis should be corroborated with noninvasive diagnostic tests, such as the ABI, toe pressures, and transcutaneous oxygen measurements. Ischemic rest pain most commonly occurs below an ankle pres-sure of 50 mmHg or a toe pressure less than 30 mmHg. Ulcers are not always of an ischemic etiology (Table 23-25). In many instances, there are other etiologic factors (traumatic, venous, or neuropathic) that are contributory, but it is underlying peripheral arterial disease that may be responsible for delayed or absent healing (Fig. 23-63). Healing of ulcers requires an inflammatory response and greater perfusion than is required to support intact skin and underlying tissues. As a result, the ankle and toe pres-sure levels needed for healing are higher than the pressures seen with ischemic rest pain. For patients with ulcers or gangrene, the presence of CLI is suggested by an ankle pressure less than 70 mmHg or a toe systolic pressure less than 50 mmHg.147 It is important to understand that there is no definite consensus regarding the vascular hemodynamic parameters required to make the diagnosis of CLI.One of the most common sites for occlusive disease is in the distal SFA as it passes deep through the adductor canal. It may be that the entrapment by the adductor hiatus prevents the compensatory dilation that occurs in atherosclerotic vessels. Stenoses, which develop here, progress to occlusion of the dis-tal third of the SFA (Fig. 23-64). When distal SFA occlusion develops slowly, it may be totally asymptomatic because of development of collaterals from the proximal SFA, or the PFA can bypass the occlusion and reconstitute the popliteal artery. Table 23-24Clinical categories of chronic limb ischemiaGRADECATEGORYCLINICAL DESCRIPTIONOBJECTIVE CRITERIA00Asymptomatic—no hemodynamically significant occlusive diseaseNormal treadmill or reactive hyperemia test 1Mild claudicationAble to complete treadmill exercisea; AP after exercise  >50 mmHg but at least 20 mmHg lower than resting valueI2Moderate claudicationBetween categories 1 and 3 3Severe claudicationCannot complete standard treadmill exercisea and AP after exercise <50 mmHgIIb4Ischemic rest painResting AP <40 mmHg, flat or barely pulsatile ankle or metatarsal PVR; TP <30 mmHgIIIb5Minor tissue loss—nonhealing ulcer, focal gangrene with diffuse pedal ischemiaResting AP <60 mmHg, ankle or metatarsal PVR flat or barely pulsatile; TP <40 mmHg 6Major tissue loss—extending above TM level, functional foot no longer salvageableSame as category 5aFive minutes at 2 miles per hour on a 12% incline of treadmill exercise.bGrades II and III, categories 4, 5, and 6, are encompassed by the term chronic critical ischemia.AP = ankle pressure; PVR = pulse volume recording; TM = transmetatarsal; TP = toe pressure.Table 23-25Symptoms and signs of neuropathic ulcer versus ischemic ulcerNEUROPATHIC ULCERISCHEMIC ULCERPainlessPainfulNormal pulsesAbsent pulsesRegular margins, typically punched-out appearanceIrregular marginOften located on plantar surface of footCommonly located on toes, glabrous marginsPresence of callusesCalluses absent or infrequentLoss of sensation, reflexes, and vibrationVariable sensory findingsIncreased in blood flow (arteriovenous shunting)Decreased in blood flowDilated veinsCollapsed veinsDry, warm footCold footBony deformitiesNo bony deformitiesRed or hyperemic in appearancePale and cyanotic in appearanceSymptom development is a function of the extent of occlusion, adequacy of collaterals, and the activity level of the patients.Presenting symptoms of femoropopliteal occlusive dis-ease are broadly classified into two types: limb-threatening and non–limb-threatening ischemia. Claudication is non– limb-threatening, while rest pain, ulceration, and gangrene are limb-threatening and warrant urgent intervention. Occlusive disease of the femoral artery may be isolated or occur in con-junction with multilevel disease that involves both the aortoil-iac segment and the tibial vessels. Symptoms in patients with Brunicardi_Ch23_p0897-p0980.indd 95827/02/19 4:15 PM 959ARTERIAL DISEASECHAPTER 23BAFigure 23-63. A. A neuropathic ulcer is characterized by a punched-out appearance with loss of sensation in the surrounding skin. The foot may be warm to touch, and pulses may be present in the distal pedal arteries. B. An ischemic ulcer is characterized by a gangrenous skin change in the foot or toes. The foot is usually cold to touch with absent pedal pulses. The foot is painful to touch with decreased distal capil-lary refills.Figure 23-64. Computed tomography angiogram of a patient with an occluded left superficial femoral artery (single long arrow) with reconstituted superficial femoral artery at the level of mid-thigh. Diffuse arterial calcifications (double small arrows) are noted in the mid and distal left superficial femoral arteries.multilevel disease are more severe than in those with single-level disease. Pain from isolated SFA and popliteal occlusion typically manifests as calf claudication. Cramping pain develops in the calf on ambulation, occurs at a reproducible distance, and is relieved by rest. Activities such as climbing stairs or going uphill also exacerbate the pain. Many patients report worsen-ing symptoms during cold weather. It is important to evaluate whether the symptoms are progressive or static. In greater than 70% of patients, the disease is stable, particularly with risk fac-tor modification.Progression of the underlying atherosclerotic process is more likely to occur in patients with diabetes, those who con-tinue to smoke, and those who fail to modify their atherosclerotic risk factors. In comparison, rest pain is constant, and usually occurs in the forefoot across the metatarsophalangeal joint. It is worse at night and requires placing the foot in a dependent posi-tion to improve symptoms. Patients may report that they either sleep in a chair or hang the foot off the side of the bed. The pain is severe and relentless, even with narcotics. Ischemic ulcer-ation most commonly involves the toes. Any toe can be affected. Occasionally ulcers develop on the dorsum of the foot. Ulcer-ation can occur in atypical positions in an ischemic foot from trauma such as friction from poorly fitting shoes. Injury to a foot with borderline ischemia can convert an otherwise stable situ-ation into one that is limb-threatening. The initial development of gangrene commonly involves the digits. As with all vascular patients, it is important to evaluate their risk factors, intercurrent cardiac diseases, and any prior vascular interventions.Treatment Considerations for Chronic Limb IschemiaPatients with vascular diseases frequently have complicated medical comorbidities. Careful patient evaluation and selection should be performed for any peripheral arterial vascular proce-dure. The fundamental principle is to assess not only the surgi-cal risk from the peripheral arterial system but also the global nature of the atherosclerotic process. Full cardiac evaluations are often necessary due to the high incidence of concomitant atherosclerotic coronary artery disease, resulting in a high risk for ischemic events. Hertzer and associates reviewed coronary angiographies on 1000 patients undergoing elective vascu-lar procedure and identified 25% of concomitant correctable coronary artery disease, including 21% in patients undergoing elective peripheral vascular intervention.5 Conte and associates analyzed their 20-year experience in 1642 open lower extremity reconstructive surgeries and concluded that patients requiring lower extremity reconstruction presented an increasingly com-plex medical and surgical challenge compared with the previous decade in a tertiary practice setting.148 With aging of the popu-lation, a growing number of vascular patients have prohibitive medical comorbidities and are deemed high-risk for open sur-gical repair. Endovascular intervention provides an attractive alternative.As for open surgical repair, the clinical indications for endovascular intervention of lower extremity peripheral arte-rial diseases include lifestyle-limiting claudication, ischemic rest pain, and tissue loss or gangrene. Importantly, endovas-cular procedures should be performed by a competent vas-cular interventionist who understands the vascular disease process and is familiar with a variety of endovascular tech-niques. In addition, certain lesions may not be amendable Brunicardi_Ch23_p0897-p0980.indd 95927/02/19 4:15 PM 960SPECIFIC CONSIDERATIONSPART IIto endovascular treatment or may be associated with poor outcomes, such as long segment occlusion, heavily calcified lesion, orifice lesion, or lesions that cannot be traversed by a guidewire. Proper selection of patients and techniques is criti-cal in achieving good long-term outcome.Endovascular intervention for lower extremity occlusive disease is continuously evolving. Success and patency rates of endovascular intervention are closely related to the anatomic and morphologic characteristics of the treated lesions. The TASC work group made recommendations on the intervention strate-gies of lower extremity arterial diseases based on the morpho-logic characteristics. Based on TASC guidelines, endovascular treatment is recommended for type A lesions, open surgery is recommended for type D lesions, and no recommendations were made for types B and C lesions. However, with rapid advance-ment in endovascular technologies, there are increased numbers of lesions amendable to endovascular interventions.There is less literature support for infrapopliteal endo-vascular intervention due to higher complication and lower success rates. The treatment is restricted for patients with limb-threatening ischemia who lack surgical alternatives. However, with further advancement of endovascular technology and the development of new devices, endovascular intervention is becoming an integral part of treatment (Table 23-26). By itself or combined with open technique, percutaneous intervention plays an important role in therapeutic options for lower extrem-ity occlusive disease. As described by TASC guidelines, four criteria should be measured to evaluate the clinical success of the treatment: improvement in walking distance, symptomatic improvement, quality of life, and overall graft patency. These criteria should all be carefully weighed and evaluated for each individual prior to endovascular therapy.Table 23-26Summary of endovascular treatment strategies using device-based infrapopliteal interventionINTERVENTIONADVANTAGESDISADVANTAGESAngioplasty• Easy to use• Broad range of applications• Failure in long lesions, calcified lesions, and disease at multiple levelsBalloon-expandable stent• Overcomes arterial recoil from angioplasty• Useful in treatment of flow-limiting dissection• Crushability can lead to restenosis• Poor distal runoff can result in stent thrombosis• Limited dataSelf-expanding stent• Vessel conformability and wall apposition prevent kinking and crushing of stent• Limited sizes• Limited data; multicenter trials under wayBioabsorbable stent• Overcomes arterial recoil from angioplasty• Absorbed long term to prevent risk of stent thrombosis• Limited data; multicenter trials under wayCryoplasty• Reduces the risk of flow-limiting dissection, therefore reducing the need for stent implantation• Short-term results of a multicenter trial are promising; however, long-term data are limitedCutting balloon• Useful in anastomotic segments of bypass grafts and in-stent restenosis where “watermelon seeding” can prevent adequate expansion of plaque• Limited dataMechanical atherectomy• Allows for debulking of plaque without the need for stent implantation in most cases• Allows for removal of plaque for histologic analysis• Limited use in areas of heavy calcification• No large, randomized, prospective trial comparing this technique to angioplasty and stentingLaser• Useful in acute thrombotic and chronic total occlusions• Minimal data in infrapopliteal arteries• Need adjunctive treatment with angioplasty, stenting, or atherectomyEndovascular TreatmentTechnical Considerations. A sterile field is required in either an operating room or an angiography suite with image capabil-ity. The most common and safest access site is CFA via either a retrograde or an antegrade approach. For diagnostic angiogra-phy, arterial access should be contralateral to the symptomatic sides. For therapeutic procedures, location of the lesion and the anatomic structures of the arterial tree determine the puncture site. To avoid puncturing the iliac artery or SFA, the femoral head is located under the fluoroscopy and used as the guide for the level of needle entry. In addition, there are several useful techniques to help access a pulseless CFA including ultrasound-guided puncture, using a micropuncture kit, and targeting cal-cification in a calcified vessel. The antegrade approach may be challenging, particularly in obese patients. Meticulous technique is crucial in preventing complications, and a bony landmark can be used as guidance to ensure CFA puncture.Traversing the lesion with a wire is the most critical part of the procedure. Typically, 0.035-inch guidewires are used for femoropopliteal lesions, and 0.014or 0.018-inch guidewires are used for infrapopliteal access. Hydrophilic-coated wires, such as Glidewires, are useful in navigating through tight ste-nosis or occlusion. An angled-tip wire with a torque device may be helpful in crossing an eccentric lesion, and a shaped selective catheter is frequently used to help manipulate the wire across the lesion. The soft and floppy end of the wire is care-fully advanced crossing the lesion under fluoroscopy, and gentle force is applied while manipulating the wire. Once the lesion us traversed, one needs to pay particular attention on the tip of the wire to ensure a secure wire access and avoid vessel wall perforation or dissection.Brunicardi_Ch23_p0897-p0980.indd 96027/02/19 4:15 PM 961ARTERIAL DISEASECHAPTER 23Once the access to the diseased vessel is secured and the wire has successfully traversed the lesion, several treatment modalities can be used either alone or in conjunction with oth-ers, including angioplasty, stent or stent graft placement, and atherectomy. The available angioplasty techniques are balloon angioplasty, cryoplasty, subintimal angioplasty, and cutting bal-loon; the most commonly used atherectomy techniques include percutaneous atherectomy catheter and laser atherectomy device.Systemic anticoagulation should be maintained routinely during lower extremity arterial interventions to minimize the risk of pericatheter thrombosis. Unfractionated heparin is the most commonly used agent, administered using a weight-based formula. We typically use 80 to 100 mg/kg initial bolus for therapeutic procedure to achieve an activated clotting time above 250 seconds upon catheter insertion and administer a sub-sequent 1000 units for each additional hour of the procedure. Newer agents, such as low molecular weight heparin, platelet IIb/IIIa inhibitors, direct thrombin inhibitors, or recombinant hirudin, have been available and can be used either alone or in conjunction with heparin, particularly in patients who are sensi-tive to unfractionated heparin. After the procedure, all patients are placed on antiplatelet therapy, such as aspirin. Additional antiplatelet agents, such as clopidogrel (Plavix), are given to selected patients with stent placement for at least 6 weeks after lower extremity interventions unless otherwise contraindicated.Percutaneous Transluminal Balloon Angioplasty. After the lesion is crossed with a wire, an appropriated balloon angio-plasty catheter is selected and tracked along the wire to traverse the lesion. The length of the selected catheter should be slightly longer than the lesion, and the diameter should be equal to the adjacent normal vessel. The balloon tends to be approximately 10% to 20% oversized. The radiopaque markers of the balloon catheter are placed so that they will straddle the lesion. Then, the balloon is inflated with saline and contrast mixture to allow visualization of the insufflation process under the fluoroscopy (Fig. 23-65). The patient may experience mild pain, which is not uncommon. However, severe pain can be indicative of ves-sel rupture, dissection, or other complications. An angiography is crucial in confirming the intraluminal location of the catheter and absence of contrast extravasation. The inflation is continued until the waist of the atherosclerotic lesion is disappeared and the balloon is at the full profile. Frequently, several inflations are required to achieve a full profile of the balloon (Fig. 23-66). Occasionally, a lower profile balloon is needed to predilate the tight stenosis so that the selected balloon catheter can cross the lesion.Besides length and diameter, the operators need to be familiar with several balloon characters. Noncompliant and low-compliant balloons tend to be inflated to their preset diam-eter and offer greater dilating force at the site of stenosis. Low-compliant balloons are the mainstay for peripheral intervention. A balloon with a low profile is used to minimize complications at the entry site and for crossing the tight lesions. Upon infla-tion, most balloons do not rewrap to their preinflation diameter and assume larger profiles. Furthermore, trackability, pushabil-ity, and crossability of the balloon should be considered when choosing a particular type of balloon. Lastly, shoulder length is an important characteristic when performing PTA to avoid injury to the adjacent arterial segments. After PTA, a comple-tion angiogram is performed while the wire is still in place. Leaving the wire in place provides access for repeating the pro-cedure if the result is unsatisfactory.PTA is an established and effective therapy for select patients with lower extremity occlusive diseases. Studies have shown that PTA of femoropopliteal segment achieved over 90% technical success rate and 38% to 58% 5-year primary patency rates.149,150 However, efficacy of PTA is highly dependent on anatomic selection and patient condition. PTA of lesions longer than 7 to 10 cm offers limited patency, whereas PTA of shorter lesions, such as those less than 3 cm, has fairly good results. Lofberg and associates performed 127 femoropopliteal PTA Figure 23-65. A. Angiogram demonstrating a focal stenosis in the superficial femoral artery (arrow). B. This lesion was treated with a bal-loon angioplasty catheter that inflated a dilating balloon and expanded the flow lumen. C. Completion angiogram demonstrating satisfactory radiographic result.Brunicardi_Ch23_p0897-p0980.indd 96127/02/19 4:15 PM 962SPECIFIC CONSIDERATIONSPART IIFigure 23-66. A. Angiogram demonstrating a segmental occlusion in the distal superficial femoral artery (single arrow). B. This lesion was treated with cryoplasty, which lowered the balloon catheter temperature to a temporary freezing state during the balloon angioplasty procedure (double arrows). C. Completion angiogram demonstrated satisfactory result with no evidence of vessel dissection.procedures and reported a primary 5-year success rate of 12% in limbs with occlusion longer than 5 cm versus 32% in limbs with occlusion less than 5 cm in length.151 Occlusive lesions have much worse initial technical success rates than stenotic lesions. Concentric lesions respond better to PTA than eccentric lesions, and heavy calcifications have a negative impact on success rates. A meta-analysis by Hunink and associates showed that adjusted 5-year primary patencies after angioplasty of femoropopliteal lesions varied from 12% to 68%, with the best results being for patients with claudication and stenotic lesions.152 Distal runoff is another powerful predictor of long-term success. Johnston analyzed 254 consecutive patients who underwent femoral and popliteal PTA and reported a 5-year patency rate of 53% for ste-notic lesions and 36% for occlusive lesions in patients with good runoff versus a 5-year patency rate of 31% for stenotic lesions and 16% for occlusive lesions in patients with poor runoff.149 Literature reviews showed that 5-year patency rates varied from 27% to 67% based on runoff status.152Due to limited success with infrapopliteal PTA, the indi-cation for infrapopliteal PTA is stringent and reserved for limb salvage. Current patency rates from infrapopliteal PTA can be improved further by proper patient selection, ensuring straight-line flow to the foot in at least one tibial vessel, and close patient surveillance for early reintervention. Possible future advances, including the use of drug-eluting stents, cutting balloons, and atherectomy devices, are being investigated to improve clini-cal outcomes following endovascular interventions on the tibial arteries. Varty and associates reported a 1-year limb salvage rate of 77% in patients with critical ischemia who underwent infrapopliteal PTA.153 In patients with favorable anatomies, the 2-year limb salvage rate after infrapopliteal PTA is expected to exceed 80%.Subintimal Angioplasty. The technique of subintimal angio-plasty was first described in 1987 when successful establish-ment of flow was made by accidental creation of a subintimal channel during treatment of a long popliteal artery occlusion. Subintimal angioplasty is recommended for chronic occlusion, long segment of lesion, and heavily calcified lesions. In addi-tion, this technique is applicable for vessels with diffuse dis-ease and for vessels that had previously failed an intraluminal approach, when it is difficult to negotiate the wire across the entire diseased segment without dissection.The principle of this technique is to bypass the occlusion by deliberately creating a subintimal dissection plan commenc-ing proximal to the lesion and continuing in the subintimal space before retry into the true lumen distal to the lesion. The occluded lumen is recanalized through the subintimal plan. Sub-intimal angioplasty can be performed through either an ipsilat-eral antegrade or contralateral retrograde approach using the CFA approach. If selecting contralateral CFA puncture, a long guiding sheath is placed across the aortic bifurcation to provide access for the femoropopliteal and infrapopliteal vessels. The subintimal dissection is initiated at the origin of an occlusion by directing the tip of an angled guide wire, usually an angled hydrophilic wire, such as a Glidewire. A supporting catheter is used to guide the tip of the guidewire away from the impor-tant collaterals. When the wire is advanced, a loop is naturally formed at the tip of the guidewire. Once the subintimal plan is entered, the wire tends to move freely in dissection space. Sub-intimal location of the wire and the catheter can be confirmed by injecting a small amount of diluted contrast. At this point, the wire and the catheter are then advanced along the subintimal plan until the occlusion segment is passed. A loss of resistance is often encountered as the guidewire reenters the true lumen distal to the occlusion. Recanalization is confirmed by advanc-ing the catheter over the guidewire beyond the point of reen-try and obtaining an angiogram. This is followed by a balloon angioplasty. To confirm the patency following balloon dilata-tion, a completion angiogram is performed prior to withdraw-ing the catheter and wire. If flow is impaired, repeat balloon Brunicardi_Ch23_p0897-p0980.indd 96227/02/19 4:15 PM 963ARTERIAL DISEASECHAPTER 23dilatation may be necessary. Frequently, a stent is required to maintain a patent lumen and treat residual stenosis if more than 30% luminal reduction is confirmed on completion angiogram.Multiple studies have demonstrated the efficacy of subin-timal angioplasty. Bolia and colleagues reported their extensive experiences on subintimal angioplasty for treating long-segment occlusions of infrainguinal vessels.154 They achieved a techni-cal success rate of over 80% for both femoropopliteal and tibial arteries. One-year patency rates varied from 53% for infrapopli-teal vessels to 71% for femoropopliteal segments. Limb salvage rates reached over 80% at 12 months. They also reported that the factors influencing patency are smoking, number of runoff vessels, and occlusion length. Studies by other groups showed similar results.155 Treiman and colleagues treated 25 patients with 6to 18-cm femoropopliteal occlusion and achieved a technical success rate of 92% and a 13-month primary patency rate of 92%,156 whereas Lipsitz and associates reported a techni-cal success rate of 87% in 39 treated patients and a 12-month cumulative patency rate of 74%.155 In addition, Ingle and asso-ciates reported a technical success rate of 87% in 67 patients with femoropopliteal lesions and a 36-month limb salvage rate of 94%.157 As demonstrated herein, although technical success rates are similar in most series, the patency rates vary widely in different studies. Patient selection, anatomic character, and lesion locations may account for the wide range of outcomes.Stent Placement. Although suggested by Dotter during the late 1960s, the use of an endoluminal stent was not pursued until the limitations of PTA were widely recognized. There are sev-eral situations where stent placement is appealing. The primary indication is the potential salvage of an unacceptable angio-plasty result. Stent placement is typically used when residual stenosis after PTA is 30% or greater. An endoluminal stent is also used for dissection, perforation, and other PTA complica-tions. Primary stent placement has become a viable alternative for treating ulcerative lesions that may potentially be the source for embolization. Primary stent is also used to treat occlusive lesions that have a tendency for reocclusion and distal emboliza-tion after PTA. In addition, an endoluminal stent is potentially beneficial for early restenosis after PTA. Drug-eluting stents are currently under investigation in the United States and may be promising in decreasing restenosis rates.Although technical success rates are high, published series on femoropopliteal artery stents show that patency rates are comparable to PTA alone, with primary patency rates vary-ing from 18% to 72% at 3 years.158 Gray and associates stented 58 limbs after suboptimal PTA for long SFA lesions and dem-onstrated a 1-year primary patency rate of 22%.159 However, Mewissen treated 137 limbs using self-expanding SMART niti-nol stents in patients with TASC A, B, and C femoropopliteal lesions and reported a 1-year primary patency of 76% and a 24-month primary patency rate of 60%.160 Appropriate patient selection and the anatomic characteristics of the lesions are cru-cial in the success of treatment outcomes. Additionally, stent characteristics may contribute to the patency rate.Several clinical studies have demonstrated the significant improvements of the new generation of nitinol stents for the SFA lesions: the German Multicenter Experience, the Mewis-sen trial, the BLASTER Trial, and the SIROCCO trial.161 The German Multicenter Experience was a retrospective review of 111 SFA stenting procedures and predicted that the 6-month patency rate for SMART stents was 82% versus 37% for the Wallstent. The BLASTER (Bilateral Lower Arterial Stenting Employing Reopro) Trial evaluated the feasibility of using nitinol stents with and without intravenous abciximab for the treatment of femoral artery disease, and the preliminary results showed a 1-year clinical patency rate of 83%.162Furthermore, the drug-eluting stent, which proved effec-tive in decreasing restenosis in coronary intervention, may offer another promising alternative in lower extremity diseases. The drug released over a period of time interferes with smooth mus-cle cell proliferation, the main cellular element and source of extracellular matrix–producing restenosis. The first drug-eluting stent clinical trial used Cordis Cypher SMART stents coated with sirolimus (SIROCCO trial).163 The SIROCCO results showed binary in-lesion restenosis rates of 0% in the sirolimus-eluting group versus 23.5% in the noneluting group at 6-month follow-up angiography. The PaRADISE (Preventing Amputa-tions Using Drug-Eluting Stents) Trial investigated the efficacy and safety of using balloon-expandable drug-eluting stents to prevent amputations in patients with below-the-knee critical limb ischemia.164 One hundred six patients (118 limbs) were treated with drug-eluting stents in this prospective, nonrandom-ized trial. There were 228 drug-eluting stents implanted (83% Cypher [Cordis, Johnson & Johnson, Warren, NJ], 17% Taxus [Boston Scientific, Maple Grove, MN]). The average length treated was 60 mm. The 3-year cumulative incidence of amputa-tion was 6%, the survival rate was 71%, and the amputation-free survival rate was 68%. Only 12% of patients who died had a preceding major amputation. Rutherford category, age, creati-nine level, and dialysis were predictors of death but not amputa-tion. Target limb revascularization occurred in 15% of patients.Stent Graft. The concept of endoluminal bypass using stent graft in treating atherosclerotic SFA disease has been enter-tained. A stent graft is placed percutaneously across a long segment or multiple segments of lesions and is used to create a femoropopliteal bypass. Theoretically, endobypass has the potential of being as successful as surgical bypass graft by relin-ing the vessel wall in its anatomic position without the nega-tive impact of anastomosis. Stent grafts can be divided into two categories: unsupported and fully supported. The unsupported grafts consist of segments of bypass graft, such as PTFE, with an expandable stent at one or both ends. The unsupported grafts are flexible with a low profile, but prone to external compres-sion. The supported stent grafts consist of a metallic skeleton covered with graft fabric. The presence of a dense metal skele-ton promotes an extensive inflammatory response and increases the risk of thrombosis. There is no FDA-approved stent graft for peripheral intervention. However, Viabahn (WL Gore & Associates, Flagstaff, AZ) is the most commonly used device in the United States and is composed of an ultra-thin PTFE graft externally supported by self-expanding nitinol meshwork. The Viabahn device has a specific delivery mechanism by pulling back the attached string, which results in proximal-to-distal delivery of the endoprosthesis.Although it is an intriguing concept, data on endobypass results are limited, and the graft thrombosis rate is high. Addi-tionally, covering major collateral vessels can potentially jeop-ardize the viability of the limb if stent graft occlusion occurs. Bauermeister treated 35 patients with Hemobahn and reported a 28.6% occlusion rate at an average 7-month follow-up.165 Kedora and colleagues recently conducted a prospective, randomized study comparing covered PTFE/nitinol self-expanding stent grafts with prosthetic above-the-knee femoropopliteal bypass. Fifty limbs were randomized into each group. Primary patency Brunicardi_Ch23_p0897-p0980.indd 96327/02/19 4:15 PM 964SPECIFIC CONSIDERATIONSPART IIat 1 year was approximately 74% for both cohorts, with a mean follow-up of 18 months. The covered nitinol/PTFE stent graft in the SFA had a 1-year patency comparable to surgical bypass, with a significantly shorter hospital stay (0.9 vs. 3.1 days).166 A recent randomized prospective study comparing the treatment of SFA occlusive disease percutaneously with an expanded PTFE (ePTFE)/nitinol self-expanding stent graft (stent graft) versus surgical femoral to above-knee popliteal artery bypass with synthetic graft material showed no difference between the two groups with respect to primary or secondary patency rates at  48 months.167 Mean total lesion length of the treated arterial seg-ment in the stent graft group was 25.6 cm. The stent graft group demonstrated a primary patency of 72%, 63%, 63%, and 59% with a secondary patency of 83%, 74%, 74%, and 74% at 12, 24, 36, and 48 months, respectively. The surgical femoral-popliteal group demonstrated a primary patency of 76%, 63%, 63%, and 58% with a secondary patency of 86%, 76%, 76%, and 71% at 12, 24, 36, and 48 months, respectively. The authors concluded that ePTFE/nitinol self-expanding stent graft placement can be offered as an alternative to treatment of the SFA segment for revascularization when prosthetic bypass is being considered or when autologous conduit is unavailable.Atherectomy. The basic principle of atherectomy is to remove the atheroma from obstructed arterial vessels. The currently available atherectomy devices can be generally categorized into directional, nondirectional, orbital, and rotational types based on their mechanism. A few examples of FDA-approved atherectomy devices are Simpson AtheroCath (DVI, Redwood City, CA), Transluminal Extraction Catheter (Interventional Technologies, San Diego, CA), Thoratec recanalization arterial catheter (Thoratec, Pleasanton, CA), Auth Rotablator (Heart Technologies, Redmond, WA), SilverHawk system (FoxHollow Technologies, Redwood City, CA), Jetstream atherectomy sys-tem (Bayer, Indianola, PA), Diamondback 360° orbital atherec-tomy device (Cardiovascular Systems, Inc, St. Paul, MN), and Rotablator system (Boston Scientific Corporation, Natick, MA). These devices either cut and remove or pulverize the atheroma plaques.The Simpson AtheroCath has a directional cutting ele-ment that is exposed to one-third of the circumference of the arterial wall. The atheroma protruding into the window is excised and pushed into the collection chamber. The Translu-minal Extraction Catheter has an over-the-wire nondirectional cutter mounted on the distal end of a torque tube. The excised atheroma is simultaneously removed by aspiration through the torque tube. The Thoratec recanalization arterial catheter is a nondirectional, noncoaxial, atheroablative device. The rotating cam tip pulverizes the atheromatous lesion into minute particles. The Auth Rotablator is a nondirectional, coaxial, atheroablative device with a metal burr embedded with fine diamond chips. SilverHawk device is a monorail catheter designed to overcome the drawbacks of a directional atherectomy catheter. The work-ing end consists of a hinged housing unit containing a carbide cutting blade. The blade is activated from the motor drive unit, and the catheter is then advanced through the length of the lesion. Once each pass is completed, the cutter then packs the tissue into the distal end of the nosecone to maximize collec-tion capacity. The SilverHawk can then either be removed or torqued to treat a different quadrant in the same lesion or other lesions. Jetstream atherectomy system is a rotating, aspirat-ing catheter with tip sizes of 1.6 and 1.8 mm for tibial arteries, and an expandable catheter with a tip size ranging from 2.1 to  3.4 mm for active removal of atherosclerotic debris and throm-bus. The Diamondback 360° orbital atherectomy device uses a drive shaft with an eccentrically mounted, diamond-coated crown to create an orbital spin. As the speed of the crown increases from centrifugal force, it sands wider spaces, thereby providing variability in its working range. It can create a lumen that is >1.75 times the crossing profile depending on the size of the grit and the eccentricity of the offset. The greater the speed of the crown, the larger is the arc of debulking and, ultimately, the resultant lumen size. A constant flow of saline solution is delivered by a roller pump that lubricates the device and helps to flush the debris. The Rotablator system high-speed rotational device uses calcium ablation to achieve larger lumens. It has been used for more than 20 years to treat challenging, calcified coronary artery disease. The diamond-coated burr is designed to preferentially engage calcium and modify lesion compliance.Despite the promising early technical and clinical success, the midand long-term results have been disappointing due to high incidence of restenosis. A multicenter clinical registry of plaque atherectomy in patients with femoropopliteal occlusive disease showed potential clinical efficacy of this technology, as the 6and 12-month rates of survival free of target lesion revascularization were 90% and 80%, respectively.168 Impor-tantly, nearly three-quarters (73%) of patients treated with plaque excision modality did not require adjunctive endovas-cular therapy as infrainguinal stenting was necessary in only 6.3% of lesions. Results from the TALON registry support the role of plaque excision in selected patients with lower extremity arterial disease.Recent technologic advances have made it possible to increase the spectrum of treatable peripheral arterial lesions with high acute procedure success rates. Recently presented data from multiple registries have shown some promising results in terms of short-term primary patency rates and freedom from unplanned major amputation.169 Randomized clinical trials, which may provide conclusions on the effectiveness of these procedures, are expected.Laser Atherectomy. Since laser atherectomy was reported in the 1960s, a variety of innovative approaches have been devel-oped trying to overcome the limitation of laser angioplasty. Recent developments in Excimer laser technology have led to increased optimism regarding the ability to safely deliver laser energy. Excimer laser atherectomy approved by the FDA for peripheral artery intervention employs precision laser energy control (shallow tissue penetration) and safer wavelengths (ultraviolet as opposed to the infrared spectra in older laser technology), which decrease perforation and thermal injury to the treated vessels.A laser atherectomy catheter, with diameters varying from 0.9 to 2.5 mm, is tracked over the guidewire to the desired tar-get. Once activated, the Excimer laser uses ultraviolet energy to ablate the lesion and create a nonthrombogenic arterial lumen. This lumen is further dilated by an angioplasty balloon. Because the Excimer laser can potentially reduce the rate of distal embo-lization by evaporating the lesion, it may be used as an adjunct tool for ostial lesions and lesions that can be traversed by a wire but not an angioplasty balloon catheter.Several studies regarding the use of Excimer laser atherectomy combined with balloon angioplasty on lower extremity occlusive disease have shown promising clinical outcomes.199,200 The Peripheral Excimer Laser Angioplasty (PELA) trial involved 318 patients with chronic SFA occlusion Brunicardi_Ch23_p0897-p0980.indd 96427/02/19 4:15 PM 965ARTERIAL DISEASECHAPTER 23and achieved a technical success rate of 83.2%, a 1-year pri-mary patency rate of 33.6%, and an assisted-primary patency rate of 65%.170 Steinkamp and colleagues treated 127 patients with long-segment popliteal artery occlusion using laser ather-ectomy followed by balloon angioplasty and reported a 3-year primary patency rate of 22%.171 A multicenter clinical trial, the Laser Angioplasty for Critical Limb Ischemia (LACI) trial, sup-ports the efficacy of this treatment modality in selected patients, with 6-month primary patency and clinical improvement rates of 33% and 89%, respectively.172 The technology and devices continue to evolve. With the TurboBooster and Turbo-Tandem technologies (Spectranetics Corporation, Colorado Springs, CO), the efficacy of plaque reduction was reported to be sig-nificantly improved in the CliRpath Excimer Laser System to Enlarge Lumen Openings (CELLO) study.173 The CELLO study was a single-arm, prospective registry trial conducted at 17 investigational sites in the United States to evaluate the safety and efficacy of a modified laser catheter designed for the endovascular treatment of peripheral artery disease affecting the SFA and proximal popliteal artery. Laser ablation reduced percent diameter stenosis from 77% to 21% after adjunctive therapy with balloon angioplasty or balloon angioplasty with stenting; 12.3% patients did not receive postlaser adjunctive therapy. Patency rates were 59% and 54% at 6 and 12 months, respectively. Target lesion revascularization was not required in 76.9% of CELLO participants within the 1-year follow-up.Complications of Endovascular InterventionsAngioplasty-Related Complications. Complications related to PTA vary widely and include dissection, rupture, emboliza-tion, pseudoaneurysms, restenosis, hematoma, and acute occlu-sion secondary to thrombosis, vasospasm, or intimal injury. Clark and associates analyzed the data from 205 patients in the SCVIR Transluminal Angioplasty and Revascularization (STAR) registry and reported a complication rate of 7.3% for patients undergoing femoropopliteal angioplasty.174 Minor complications accounted for 75% of the cases, including distal emboli (41.7%), puncture site hematomas (41.7%), contained vessel rupture (8.3%), and vagal reactions (8.3%). In another study, Axisa and colleagues reported an overall rate of significant complica-tions for patients undergoing PTA of the lower extremities of 4.2%, including retroperitoneal bleeding (0.2%), false aneurysm (0.2%), ALI (1.5%), and vessel perforation (1.7%).175Complications limiting the application of subintimal angioplasty are parallel to those of PTA. A study investigating the use of subintimal angioplasty in 65 patients with SFA occlu-sion found that complications developed in 15% of patients.176 These complications included significant stenosis (44%), SFA rupture (6%), distal embolization (3%), retroperitoneal hemor-rhage (1.5%), and pseudoaneurysm (1.5%). Additional compli-cations reported included perforation, thrombosis, dissection, and extensions beyond the planned reentry site.177 Importantly, damage to significant collateral vessels may occur in 1% to 1.5% of patients who undergo subintimal angioplasty. If a suc-cessful channel is not achieved in this situation, the patient may have a compromised distal circulation that necessitates dis-tal bypass. Cryoplasty is a modified form of angioplasty, and long-term results on lower extremity intervention are not yet available. Fava and associates treated 15 patients with femo-ropopliteal disease and had a 13% complication rate involving guidewire dissection and PTA-induced dissection of a tandem lesion remote to the cryoplasty zone.178Endoluminal Stent– and Stent Graft–Related Complica-tions. In addition to the aforementioned complications with angioplasty, endoluminal stent is associated with the risk of stent fraction and deformity. The adductor canal has nonlami-nar flow dynamics, especially with walking. The forces exerted on the SFA include torsion, compression, extension, and flex-ion. These forces exert significant stress on the SFA and stents. In addition, the lower extremity is subject to external trauma, which further increases the risk of stent deformity and fracture (Fig. 23-67). The SIROCCO study showed that stent fracture, although not associated with clinical symptoms, occurs in 18.2% of the procedures involving both drug-eluting stents and control stents.163Stent grafts may present the additional complication of covering important collaterals, which results in compromised distal circulation. A prospective study evaluating Hemo-bahn stent grafts in the treatment of femoropopliteal arterial Figure 23-67. Due to various geometric forces, including torsion, compression, extension, and flexion, exerted on the superficial fem-oral artery (SFA), stent fracture (arrows) is a known complication following SFA stent placement.Brunicardi_Ch23_p0897-p0980.indd 96527/02/19 4:15 PM 966SPECIFIC CONSIDERATIONSPART IIocclusions demonstrated a 23% immediate complication rate including distal embolization (7.7%), groin hematoma (13.5%), and arteriovenous fistula (1.9%).179Atherectomy-Related Complications. Overall complication rates associated with atherectomy range from 15.4% to 42.8%, including spasm, thrombosis, dissection, perforation, distal emboli, no reflow, and hematoma.180,181 Jahnke and associates conducted a prospective study evaluating high-speed rotational atherectomy in 15 patients with infrapopliteal occlusive disease. They yielded a 94% technical success rate, but success was complicated by vessel rupture (5%), distal embolization (5%), and arterial spasm (5%).179 Although Excimer laser atherectomy reduces embolic events by evaporating the lesion, embolization still remains a problematic complication. Studies show that dis-tal embolic events occur in 3% to 4% of procedures and perfora-tion occurs in 2.2% to 4.3% of cases.170,171 Other complications associated with laser atherectomy therapy include acute throm-bosis, vasospasm, direct vessel injury, and dissection.170,171Surgical Treatment for Chronic Limb Ischemia due to Femoropopliteal DiseaseEndarterectomy. Endarterectomy has a limited, albeit impor-tant role in lower extremity occlusive disease. It is most fre-quently used when there is disease in the CFA or involving the PFA. In this procedure, the surgeon opens the diseased segment longitudinally and develops a cleavage plane within the media that is developed proximally and distally. This permits the inner layer containing the atheroma to be excised. Great care must be taken at the distal end of the endarterectomy to either ensure a smooth transition or tack down the distal endpoint to prevent the flow from elevating a potentially occlusive atheromatous flap. Currently, there is essentially no role for long open endar-terectomy in the treatment of SFA stenoses or occlusions. The high incidence of restenosis is what limits utility of endarterec-tomy in this location. Short-segment stenoses are more appro-priately treated with balloon angioplasty. Endarterectomy using a catheter-based approach (e.g., Moll endarterectomy device) supplemented with stent grafting or stenting across the endpoint of the endarterectomy is currently being reevaluated; however, no long-term data are available.Bypass Grafting. Bypass grafting remains the primary inter-vention for lower extremity occlusive disease. The type of bypass and the type of conduit are important variables to con-sider. Patients with occlusive disease limited to the SFA, who have at least 4 cm (ideally 10 cm) of normal popliteal artery reconstituted above the knee joint, and with at least one continu-ous vessel to the foot can be treated with an above-knee femo-ropopliteal bypass graft. Despite the fact that in this above-knee location, the differential patencies between prosthetic (PTFE) and vein graft are comparable, undoubtedly, it remains ideal to use a saphenous vein as the bypass conduit if possible. Saving the vein for future coronary artery bypass or distal leg bypass grafting has been shown to be a flawed argument. One must also consider that the consequences to the vascular outflow after a thrombosed prosthetic are worse than after a thrombosed vein graft.When the disease extends to involve the popliteal artery or the tibial vessels, the surgeon must select an appropriate out-flow vessel to perform a bypass. Suitable outflow vessels are defined as uninterrupted flow channels beyond the anastomosis into the foot. Listed in order of descending preference, they are as follows: above-knee popliteal artery, below-knee popli-teal artery, posterior tibial artery, anterior tibial artery, and peroneal artery. In patients with diabetes, it is frequently the peroneal artery that is spared. Although it has no direct flow into the foot, collateralization to the posterior tibial and anterior tibial arteries makes it an appropriate outflow vessel. There is no objective evidence to preferentially select tibial over peroneal arteries if they are vessels of equal caliber and quality. The dor-salis pedis, which is the continuation of the anterior tibial in the foot, is frequently spared from atherosclerotic disease and can be used as a target for distal bypasses. Patency is affected by the length of the bypass (longer bypasses have reduced patency), quality of the recipient artery, extent of runoff to the foot, and quality of the conduit (saphenous vein/graft). Five-year assisted patency rate for infrapopliteal venous bypasses is 60%. Venous conduits have also been shown to be suitable for bypasses to plantar arteries. In this location, venous conduits have a 3-year limb salvage rate of 84% and a 3-year secondary patency rate of 74%.1 A meta-analysis suggests unsatisfactory results when PTFE-coated grafts are used to bypass to infrapopliteal arteries. In this location, prosthetic grafts have a 5-year primary patency rate of 30.5%.182 Additionally, due to distal embolization and compromise of outflow vessels, prosthetic graft occlusion may have more severe consequences than vein graft occlusion.Two techniques are used for distal bypass grafting: reversed saphenous vein grafting and in situ saphenous vein grafting. There is no difference in outcomes (patency or limb salvage) between these techniques. In the former, the vein is excised in its entirety from the leg using open or endoscopic vein harvest, reversed to render the valves nonfunctional, and tunneled from the CFA inflow to the distal target vessels. End-to-side anastomoses are then created.Several adjunctive techniques have been used to try to improve the patency of bypass grafts to tibial arteries. Cre-ation of an arteriovenous fistula at the distal anastomosis is one option, but it has not been shown to improve patency.183 Another method involves creating varying configurations of vein cuffs or patches at the distal anastomosis in an attempt to streamline the flow and to reduce the likelihood of neointimal hyperplasia. Results with this approach are more promising, especially when done to improve patency of a below-the-knee prosthetic; how-ever, there are no definitive comparative trials that support the superiority of one configuration over another.Amputation. Primary amputation is defined as an amputation that is performed without a prior attempt at surgical or endovas-cular revascularization. It is rarely necessary in patients who, as a result of neglect, present with class III ALI. Primary ampu-tation may play a role in patients with critical limb ischemia who are deemed nonambulatory because of knee contractures, debilitating strokes, or dementia.Complications of Surgical ReconstructionVein Graft Stenoses. Fifteen percent of vein grafts will develop intrinsic stenoses within the first 18 months follow-ing implantation. Consequently, patients with vein grafts were entered into duplex surveillance protocols (scans every 3 months) to detect elevated (>300 cm/s) or abnormally low (<45 cm/s) graft velocities early. Stenoses greater than 50%, especially if associated with changes in ABI, should be repaired to prevent graft thrombosis. Repair usually entails patch angio-plasty or short-segment venous interposition, but PTA/stenting Brunicardi_Ch23_p0897-p0980.indd 96627/02/19 4:15 PM 967ARTERIAL DISEASECHAPTER 23is an option for short, focal lesions. Grafts with stenoses that are identified and repaired prior to thrombosis have assisted-primary patency identical to primary patency, whereas a throm-bosed autogenous bypass has limited longevity resulting from ischemic injury to the vein wall. Secondary patency is mark-edly inferior to primary assisted patency. The recommenda-tion for routine duplex ultrasound surveillance of autogenous infrainguinal bypasses was recently brought into question by a randomized controlled trial that demonstrated no cost benefit or quality-of-life improvement in patients with femoropopliteal venous bypasses after 18 months.184 Many surgeons continue with programs of vein graft surveillance, as has been suggested in older trials, awaiting further confirmation of the findings from the more recent study. When intervening in a failing infraingui-nal bypass, the original indication for surgery is an important consideration. Limb salvage rates for occluded grafts are better if the indication for the original bypass was claudication rather than rest pain or tissue loss. An acutely occluded infrainguinal graft (≤30 postoperative days) has a 25% limb salvage rate.185Limb Swelling. Limb swelling is common following revascu-larization and usually returns to baseline within 2 to 3 months. The etiology is multifactorial with lymphatic interruption, inter-stitial edema, and disruption of venous drainage all contributing. Limb swelling tends to worsen with repeat revascularization (see Table 23-22).Wound Infection. Since the most common inflow vessel for distal bypass is the CFA, groin infection is common and occurs in 7% of cases.186 When an autogenous conduit such as the saphenous vein is used, most infections can be managed with local wound care because the infection involves the subcutane-ous tissue or skin rather than infection of the actual vein. When a prosthetic graft has been used, management of graft infection is a major undertaking. Infection of a lower extremity prosthetic bypass graft is associated with a significant amputation rate because of the tendency for graft thrombosis and anastomotic disruption. Prosthetic graft infections cannot be eradicated with antibiotics and mandate graft excision and complex revascular-ization using a vein if available.Choice of Conduit for Infrainguinal Bypass GraftingAutogenous Vein. The autogenous vein is superior to pros-thetic conduits for all infrainguinal bypasses, even in the above-knee position. This preference is applicable not only for the initial bypass but also for reoperative cases. For long bypasses, the ipsilateral great saphenous vein, contralateral great saphe-nous vein, small saphenous vein, arm vein, and spliced vein are used in decreasing order of preference. If only a short segment of vein is missing, the SFA can be endarterectomized and the proximal anastomosis performed distally to decrease the length of the conduit and to avoid harvesting and splicing additional vein. When the great saphenous vein is not available and a rela-tively short bypass is necessary, the arm vein or small saphe-nous vein is effective. The small saphenous vein is of particular utility when a posterior approach is used. If a longer bypass with vein is necessary, the arm vein is preferable because it is less awkward to harvest. Another conduit alternative is to har-vest the upper arm basilic, median cubital, and cephalic veins in continuity, while incising valves in the basilic segment and using the cephalic segment in reversed configuration to provide a relatively long, unspliced autogenous conduit.187Cryopreserved Grafts. Cryopreserved grafts are usually cadaveric arteries or veins that have been subjected to rate-controlled freezing with dimethyl sulfoxide (DMSO) and other cryopreservants. Cryopreserved vein grafts are more expensive than prosthetic grafts and are more prone to failure. The endo-thelial lining is lost as part of the freezing process, making these grafts prone to early thrombosis. Cryopreserved grafts are also prone to aneurysmal degeneration. Despite the fact that these grafts have not performed as well as prosthetic bypasses and autogenous vein bypasses in clinical practice, they can still play a role when revascularization is required following removal of infected prosthetic bypass grafts, especially when the autog-enous vein is unavailable to create a new bypass through clean tissue planes.Human Umbilical Vein. Human umbilical vein (HUV) is less commonly used than PTFE because it is thicker and more cum-bersome to handle and because of concerns about aneurysmal degeneration. HUV allografts are stabilized with glutaralde-hyde and do not have viable cells or antigenic reactivity. These grafts have poor handling characteristics and require extra care when suturing because of an outer Dacron mesh wrapping that is used to decrease aneurysmal degeneration. Dardik and col-leagues have reported favorable results after using HUV and an adjunctive distal arteriovenous fistula.188 One trial compar-ing HUV with PTFE and saphenous vein showed that HUV was better than PTFE but worse than saphenous vein in terms of 5-year patency in the above-knee location.189 In a system-atic review, HUV appears to perform better than cryopre-served veins in terms of 1-year graft patency in infrainguinal revascularization.190Prosthetic Conduits and Adjunctive Modifications. If a vein is truly unavailable, PTFE or Dacron is the best option for above-knee bypass. The addition of rings to PTFE did not con-fer benefit in a single prospective, randomized clinical trial.191 For infrageniculate prosthetic bypasses, use of a vein patch, cuff, or other venous anastomotic modification can improve patency (52% patency at 2 years for PTFE with vein cuff vs. 29% for PTFE with no cuff) and also improve limb salvage (84% vs. 62%).192Although prosthetic grafts are quickly available, easy to handle, and do not require extensive dissection to harvest, their propensity to undergo thrombosis and develop neointimal hyperplasia makes them a less favorable alternative when com-pared to vein. In a recent review of vein and prosthetic above-knee femoropopliteal bypasses, the 5-year primary patency rates were reported to be 74% and 39%, respectively.193 Outcomes were even worse for below-knee prosthetic bypasses. Unfortu-nately, the use of autologous venous conduits is not possible in as many as 30% of patients. The great saphenous vein may be unsuitable because of small size and poor quality or unavailable due to prior harvest.Methods to improve prosthetic graft performance have consisted of altering the geometry at the distal anastomosis to get the benefit obtained with vein cuffs (Distaflo; Bard Peripheral Vascular, Tempe, AZ) and covalently bonding agents onto the luminal surface with anticoagulant, anti-inflammatory, and anti-proliferative characteristics (Propaten; Gore, Flagstaff, AZ). One randomized trial that compared precuffed PTFE versus PTFE with a vein cuff enrolled 104 patients at 10 centers. Of 89 patients, 47 were randomized to precuffed PTFE bypasses and 44 were randomized to bypasses with a vein cuff.194 At 1 and  Brunicardi_Ch23_p0897-p0980.indd 96727/02/19 4:15 PM 968SPECIFIC CONSIDERATIONSPART II2 years, primary patency rates were 52% and 49% in the pre-cuffed group and 62% and 44% in the vein cuffed group, respec-tively. At 1 and 2 years, the limb salvage rates were 72% and 65% in the precuffed group and 75% and 62% in the vein cuffed group, respectively. Although numbers are small and follow-up short, the midterm analysis revealed that Distaflo precuffed grafts and PTFE grafts with vein cuff had similar results. The authors concluded that a precuffed graft was a reasonable alternative for infragenicular reconstruction in the absence of saphenous vein.194 Other authors have been less optimistic and question whether there is any benefit derived from geometri-cally altering prosthetic conduits.195Another approach for improving outcomes when using prosthetic for bypass grafts involves bonding anticoagulants to the conduit. The Gore Propaten graft has heparin bonded onto the luminal surface of the PTFE graft using Carmeda BioActive Surface (CBAS) technology, which immobilizes the heparin molecule with a single covalent bond that does not alter its anti-coagulant properties.196 The heparin binding does not alter the microstructure and handling characteristics of the PTFE. A pro-spective, randomized trial by Devine and colleagues suggested that heparin-bonded Dacron or PTFE was superior to plain PTFE for above-knee popliteal bypasses. The 3-year primary patency rate for the heparin-bonded grafts was 55% compared with 42% for PTFE (P <0.044). Both of these patency rates are inferior to great saphenous vein grafts; however, if the improved results with heparin bonding continue to be substantiated, then heparin-bonded prosthetic grafts will become the preferred con-duit for above-knee bypass in the absence of suitable vein.197 A recent review of available studies with this graft showed an 80% 1-year patency rate for below-knee bypasses.198 Randomized controlled clinical trials with more patients and longer follow-up are necessary to validate whether the Propaten vascular graft is superior to other prosthetics and whether it is comparable to autogenous vein for below-knee interventions.Clinical Results of Surgical and Endovascular Interventions for Femoropopliteal Occlusive DiseaseBalloon angioplasty of the femoropopliteal vessels has not enjoyed the degree of success seen with iliac angioplasty. Patency in this region is dependent on whether the patient pres-ents with claudication versus limb-threatening ischemia, the sta-tus of the distal runoff vessels, and lesion morphology. Initial technical success for femoropopliteal angioplasty is seen in 80% to 90% of cases, with failure to cross a lesion occurring in 7% of stenoses and 18% of occlusive lesions. Studies have shown that PTA of the femoropopliteal segment achieved a greater than 90% technical success rate and had a 38% to 58% 5-year pri-mary patency rate.152,199 PTA of lesions longer than 7 to 10 cm results in compromised patency, whereas PTA of shorter lesions (<3 cm) gives fairly good results. Lofberg and colleagues per-formed 127 femoropopliteal PTA procedures and reported a primary patency rate at 5-year follow-up of 12% in limbs with occlusion longer than 5 cm versus 32% in limbs with occlusion less than 5 cm in length.151 Occlusive lesions have much worse initial technical success rates than stenotic lesions. Concentric lesions respond better to PTA than eccentric lesions, and heavy calcifications have a negative impact on success rates. Distal runoff is another powerful predictor of long-term success.Johnston analyzed 254 consecutive patients who under-went femoropopliteal PTA and reported a 5-year patency rate of 53% for stenotic lesions and 36% for occlusive lesions in patients with good runoff versus a 5-year patency rate of 31% for stenotic lesions and 16% for occlusive lesions in patients with poor runoff.149 A meta-analysis by Hunink and colleagues showed that adjusted 5-year primary patencies after angioplasty of femoropopliteal lesions varied from 12% to 68%, with the best results occurring in patients with claudication and stenotic lesions.152 Although the initial technical success is better for stenoses than occlusions, long-term patency rates for stenoses and short occlusions have been variable, and there have been conflicting results regarding the efficacy of stent use. Early pub-lished series that examined efficacy of femoropopliteal artery stents showed patency rates that were comparable to standalone PTA, with primary patency rates varying from 18% to 72% at 3 years.158 Patient selection and the anatomic character of the lesions may play important roles in the outcomes. Additionally, stent characteristics may contribute to the patency rate. Several recent clinical studies have demonstrated significant improve-ments in patency when the newer generations of nitinol stents are used to treat SFA lesions.160,200Mewissen treated 137 lower limbs in 122 patients with CLI, secondary to TASC A (n = 12) or TASC B or C (n = 125) lesions in the SFA. Patients were treated with Cordis SMART self-expanding nitinol stents. Binary restenosis (>50%) was measured by standard duplex velocity criteria at various postint-ervention intervals. Primary stent patency, defined as absence of binary restenosis in this study, was calculated by life-table methods from the time of intervention. The mean lesion length was 12.2 cm (range, 4–28 cm). The technical success was 98%. Mean follow-up was 302 days. The primary stent patency rates were 92%, 76%, 66%, and 60% at 6, 12, 18, and 24 months, respectively.160 Ferreira and colleagues treated 59 patients who had 74 femoropopliteal lesions (60% TASC D) with Zilver nitinol self-expanding stents (Cook, Bloomington, IN). Mean recanalization length was 19 cm (range, 3–53 cm). Mean fol-low-up time was 2.4 years (range, 3 days–4.8 years). Kaplan-Meier estimates for primary patency rates were 90%, 78%, 74%, 69%, and 69% at 1, 2, 3, 4, and 4.8 years, respectively.201There is general agreement that for suboptimal PTA of an SFA lesion, stent placement is indicated, but a recent random-ized trial by Schillinger and associates suggests that primary stenting results in lower restenosis rates than PTA and selective stenting. Restenosis rates at 2 years were 45.7% versus 69.2% in favor of primary stenting compared with PTA and optional secondary stenting using an intent-to-treat analysis (P = 0.031). Consistently, stenting, both primary and selective, was supe-rior to standalone PTA with respect to the occurrence of reste-nosis (49.2% vs. 74.3%; P = 0.028) by a treatment-received analysis.202Nitinol bare metal stents that are designed specifically for below-knee interventions are showing very encouraging results. Bosiers and colleagues reported their 12-month results using the commercially available non–drug-eluting Xpert (Abbott Vascular, Santa Clara, CA) nitinol stent system in below-knee arterial interventions.203 They had a 12-month primary patency rate of 76.3% and a limb salvage rate of 95.9%. They fol-lowed patients for 12 months and performed angiography with quantitative vessel analysis on the 73% of patients available. Angiography revealed a binary restenosis rate (>50%) of only 20.5%, which is comparable to well-accepted coronary drug-eluting stent study outcomes. The authors attributed this opti-mal performance to the maintenance of flow dynamics because Brunicardi_Ch23_p0897-p0980.indd 96827/02/19 4:15 PM 969ARTERIAL DISEASECHAPTER 23the stent was specifically designed for use in small vessels. Kickuth and colleagues also have obtained good results using the Xpert stent. After stent placement, the primary cumulative patency rate at 6 months for the study group of 35 patients was 82%. The sustained clinical improvement rate as evidenced by improved ABI was 80%, and freedom from major amputation was 100% at the 6-month follow-up. The rate of major compli-cations was 17%.204Wolf and colleagues published a multicenter, prospec-tive randomized trial comparing PTA with bypass in 263 men who had iliac, femoral, or popliteal artery obstruction.205 In 56 patients, cumulative 1-year primary patency rate was 43% after PTA and 82% after bypass surgery, demonstrating that for long SFA stenoses or occlusions, surgery is better than PTA. Another recent randomized study (BASIL trial) of 452 patients with CLI demonstrated no difference in amputation-free survival at 6 months between surgery and PTA/stenting.206 The authors com-mented that surgery was somewhat more expensive and rec-ommended that endovascular intervention should be used as first-line therapy especially in medically unfit patients. They did conclude that at the 2-year follow-up, healthy patients with-out medical comorbidities derived greater benefit from surgery because it was associated with decreased need for reintervention and had a decreased hazard ratio in terms of all-cause mortality. The recently published randomized prospective study compar-ing the treatment of SFA occlusive disease percutaneously with an ePTFE/nitinol self-expanding stent graft versus surgical fem-oral to above-knee popliteal artery bypass with synthetic graft material showed no difference between the two groups with respect to primary or secondary patency rate at four years.167 This finding suggests that ePTFE/nitinol self-expanding stent graft placement can be offered as an alternative to treatment of the SFA segment for revascularization when prosthetic bypass is being considered or when autologous conduit is unavailable. Using the 2000 TASC definitions and a Markov state transi-tion model decision analysis, Nolan and colleagues showed that PTA/stenting surpasses bypass efficacy for TASC C lesions if PTA/stenting primary patency is >32% at 5 years, patient age is >80 years, and/or greater saphenous vein bypass operative mortality is >6%.207NONATHEROSCLEROTIC DISORDERS OF BLOOD VESSELSThe majority of cases of peripheral vascular disease that are seen by vascular surgeons are attributable to underlying athero-sclerosis. Nonatherosclerotic disease states that result in arterial pathology are less commonly encountered, but are nonetheless important, as they are potentially treatable lesions that may mimic atherosclerotic lesions and result in vascular insuffi-ciency (see Table 23-18). A thorough knowledge of these rare disease states is important for the practicing vascular surgeon in order to make medical recommendations and provide appropri-ate surgical treatment.Giant Cell Arteritis (Temporal Arteritis)Giant cell arteritis is also known as temporal arteritis, which is a systemic chronic inflammatory vascular disease with many characteristics similar to those of Takayasu’s disease. The histo-logic and pathologic changes and laboratory findings are similar. Patients tend to be white women over the age of 50 years, with a high incidence in Scandinavia and women of Northern European descent. Genetic factors may play a role in disease pathogenesis, with a human leukocyte antigen (HLA) variant having been identified. Differences exist between Takayasu’s and giant cell arteritis in terms of presentation, disease location, and therapeutic efficacy. The inflammatory process typically involves the aorta and its extracranial branches, of which the superficial temporal artery is specifically affected.The clinical syndrome begins with a prodromal phase of constitutional symptoms, including headache, fever, malaise, and myalgias. The patients may be initially diagnosed with coexisting polymyalgia rheumatica; an HLA-related associa-tion may exist between the two diseases. As a result of vascular narrowing and end-organ ischemia, complications may occur such as visual alterations, including blindness and mural weak-ness, resulting in acute aortic dissection that may be devastating. Ischemic optic neuritis resulting in partial or complete blindness occurs in up to 40% of patients and is considered a medical emergency. Cerebral symptoms occur when the disease process extends to the carotid arteries. Jaw claudication and temporal artery tenderness may be experienced. Aortic lesions are usually asymptomatic until later stages and consist of thoracic aneu-rysms and aortic dissections.The diagnostic gold standard is a temporal artery biopsy, which will show the classic histologic findings of multinucle-ated giant cells with a dense perivascular inflammatory infil-trate. Treatment regimens are centered on corticosteroids, and giant cell arteritis tends to rapidly respond. Remission rates are high, and treatment tends to have a beneficial and preventative effect on the development of subsequent vascular complications.Takayasu’s ArteritisTakayasu’s arteritis is a rare but well-recognized chronic inflam-matory arteritis affecting large vessels, predominantly the aorta and its main branches (Table 23-27). Chronic vessel inflamma-tion leads to wall thickening, fibrosis, stenosis, and thrombus formation. Symptoms are related to end-organ ischemia. The acute inflammation can destroy the arterial media and lead to aneurysm formation. This rare autoimmune disease occurs pre-dominantly in women between the ages of 10 and 40 years who are of Asian descent. Genetic studies have demonstrated a high frequency of HLA haplotypes in patients from Japan and Mexico, suggesting increased susceptibility to developing the disease in patients with certain alleles. However, these associations have not been seen in North America. Vascular inflammation leads Table 23-27Angiographic classification of Takayasu’s arteritisTYPEVESSEL INVOLVEMENTType IBranches from the aortic archType IIaAscending aorta, aortic arch and its branchesType IIbAscending aorta, aortic arch and its branches, thoracic descending aortaType IIIThoracic descending aorta, abdominal aorta, and/or renal arteriesType IVAbdominal aorta and/or renal arteriesType VCombined features of types IIb and IVInvolvement of the coronary or pulmonary arteries is designated as C (+) or P (+), respectively.Brunicardi_Ch23_p0897-p0980.indd 96927/02/19 4:15 PM 970SPECIFIC CONSIDERATIONSPART IIto arterial wall thickening, stenosis, and eventually, fibrosis and thrombus formation. The pathologic changes produce stenosis, dilation, aneurysm formation, and/or occlusion.The clinical course of Takayasu’s arteritis begins with a “prepulseless” phase in which the patient demonstrates constitu-tional symptoms. These include fever, anorexia, weight loss, gen-eral malaise, arthralgias, and malnutrition. As the inflammation progresses and stenoses develop, more characteristic features of the disease become evident. During the chronic phase, the dis-ease is inactive or “burned out.” It is during this latter stage that patients most frequently present with bruits and vascular insuf-ficiency according to the arterial bed involved. Laboratory data may show elevations in erythrocyte sedimentation rate, C-reactive protein, and white blood cell count, or conversely, anemia may predominate. Characteristic clinical features during the second phase vary according to the involved vascular bed and include hypertension reflecting renal artery stenosis, retinopathy, aortic regurgitation, cerebrovascular symptoms, angina and con-gestive heart failure, abdominal pain or gastrointestinal bleeding, pulmonary hypertension, or extremity claudication.The gold standard for diagnosis remains angiography showing narrowing or occlusion of the entire aorta or its pri-mary branches, or focal or segmental changes in large arteries in the upper or lower extremities. Six types of Takayasu’s arteritis exist and are graded in terms of severity: type I, affecting the aorta and arch vessels; type IIa, affecting the ascending aorta, aortic arch, and branches; type IIb, affecting the ascending aorta, aortic arch and branches, and thoracic descending aorta;  type III, affecting the thoracic descending aorta, abdominal aorta, and/or renal arteries; type IV, affecting the abdominal aorta and/or renal arteries; and type V, with combined features of types IIb and IV.208Treatment consists of steroid therapy initially, with cyto-toxic agents used in patients who do not achieve remission. Surgical treatment is performed only in advanced stages, and bypass needs to be delayed during active phases of inflam-mation. There is no role for endarterectomy, and synthetic or autogenous bypass grafts need to be placed onto disease-free segments of vessels. For focal lesions, there have been reports of success with angioplasty.Ehlers-Danlos SyndromeEhlers-Danlos syndrome is one of the more significant inheritable disorders affecting the connective tissue, along with Marfan’s syndrome. This syndrome represents a heterogenous group of connective tissue disorders (types I through IV) that were first described in 1682 by van Meekeren.238 It is an autosomal domi-nant disorder affecting approximately 1 in 5000 persons that is characterized by skin elasticity, joint hypermobility, tissue fragility, multiple ecchymoses, and subcutaneous pseudotu-mors. Ehlers-Danlos syndrome is a disorder of fibrillar collagen metabolism with identifiable, specific defects that have been found in the collagen biosynthetic pathway that produce clini-cally distinct forms of this disease. Ten different phenotypes have been described, each with variable modes of inheritance and biochemical defects. Of the four basic types of collagen found in the body, the predominant type in blood vessels is type III. Within the vessel wall, type III collagen contributes to structural integrity and tensile strength and plays a role in platelet aggregation and thrombus formation.Of the three types of Ehlers-Danlos syndrome that have arterial complications, type IV represents 5% of cases and is the one most likely to be seen by a vascular surgeon. These patients synthesize abnormal type III collagen (mutation COL3A1) and represent 5% of all cases.209 Affected individuals do not show the typical skin and joint manifestations, and thus typically pres-ent for diagnosis when a major vascular catastrophe occurs. In a review of 36 patients with this disorder, Cikrit and colleagues reported a 44% mortality rate from major hemorrhage prior to any surgical intervention.210 In the 20 patients who underwent 29 vascular procedures, there was a 29% mortality rate. Arterial rupture, aneurysm formation, and acute aortic dissection may occur in any major artery, with the most frequent site of rupture being the abdominal cavity. Repair is problematic because the vessel wall is soft and sutures pull through the fragile tissue. Ligation may be the only option in many circumstances.Marfan’s SyndromeAnother heterogeneous heritable disorder of connective tissue, Marfan’s syndrome is characterized by abnormal musculo-skeletal, ocular, and cardiovascular features first described by Antoine Marfan in 1896.211 The inborn error of metabolism in this syndrome has been localized to the long arm of chromo-some 15 (15q21.3). Defects occur in fibrillin, a basic protein in the microfibrillar apparatus that serves as a backbone for elas-tin, which is one of the main extracellular structural proteins in blood vessels. This is an autosomal dominant gene with high penetrance; however, approximately 15% to 20% of cases are secondary to new spontaneous mutations.Classic recognizable features of Marfan’s syndrome include tall stature, long limbs (dolichostenomelia), long fingers (arachnodactyly), joint hyperextensibility, chest wall deformi-ties, and scoliosis. Ocular manifestations are flattened corneas, lens subluxation, and myopia. Ninety-five percent of patients have cardiovascular involvement, which may include ascend-ing aortic dilatation, mitral valve prolapse, valvular regurgita-tion, and aortic dissection. Skin, central nervous system, and pulmonary features may be present as well. Aortic root dilata-tion will generally occur in all patients. This may not be evident on standard chest radiograph until dilatation has resulted in an ascending aortic aneurysm, aortic valve regurgitation, or dis-section. Left untreated, the cardiovascular complications are devastating and reduce the life expectancy to about 40 years for men and slightly higher for women. Death is usually attrib-utable to life-threatening complications of aortic regurgitation, dissection, and rupture after the ascending aorta has dilated to 6 cm or more.Aggressive medical management with β-adrenergic block-ing agents and other blood pressure–lowering regimens is cru-cial to treatment. Surgical intervention entails replacement of the aortic root with a composite valve graft (e.g., Bentall pro-cedure).212 Prophylactic operative repair is indicated for an aneurysm greater than 5.5 cm, with an acceptable perioperative mortality of less than 5%.Pseudoxanthoma ElasticumPseudoxanthoma elasticum is a rare inherited disorder of con-nective tissue that is characterized by an unbalanced elastic fiber metabolism and synthesis, resulting in fragmentation and calci-fication of the fibers. Clinical manifestations occur in the skin, ocular, gastrointestinal, and cardiovascular systems. Character-istic skin lesions are seen in the axilla, antecubital and popliteal fossae, and groin. The yellow, xanthoma-like papules occur in redundant folds of skin and are said to resemble plucked chicken skin. The inheritance pattern includes both autosomal dominant Brunicardi_Ch23_p0897-p0980.indd 97027/02/19 4:15 PM 971ARTERIAL DISEASECHAPTER 23and recessive types and has a prevalence of 1 in 160,000 indi-viduals.213 The ATP-binding cassette subfamily C member 6 (ABCC6) gene has been demonstrated to be responsible, and 43 mutations have been identified, all of which lead to calcification of the internal elastic laminae of medium-sized vessel walls.214Cardiovascular features are common and include prema-ture coronary artery disease, cerebrovascular disease, renovas-cular hypertension, diminished peripheral pulses, and restrictive cardiomyopathy. Symptom onset typically occurs in the second decade of life, with onset at an average age of 13 years. Patients should be counseled to reduce potential contributing factors for atherosclerosis such as tobacco use and high cholesterol levels. Calcium intake should be restricted in adolescents, as a positive correlation has been found between disease severity and cal-cium intake. Surgical management involves standard vascular techniques, with the exception that arterial conduits should not be employed in cardiac bypass.Kawasaki’s DiseaseKawasaki’s disease was first described in 1967, as a mucocu-taneous lymph node syndrome occurring in young children. In most studies, more than half the patients are younger than 2 years of age, with a higher prevalence in boys.215 Although originally described in Japan, the disease is found worldwide. An infec-tious agent may be causative; however, no specific agent has been identified. Immune activation with the contribution of cytokines, elastases, growth factors, and metalloproteinases is believed to be a mechanism for inflammation and aneurysm for-mation. Coronary artery aneurysms, the hallmark of the disease, histologically demonstrate a panarteritis with fibrinoid necro-sis. Coronary arteriography may show occlusions, recanaliza-tion, and localized stenosis, in addition to multiple aneurysms. A variety of constitutional symptoms and signs resulting from systemic vasculitis are present in the acute phase of the illness.Medical therapy for Kawasaki’s disease clearly decreases the manifestations of coronary artery involvement. Intravenous gamma globulin and aspirin therapy are most successful if begun within the first 10 days of illness. Up to 20% of untreated patients will develop coronary arterial lesions. A long-term, low-dose aspirin therapy regimen is usually recommended.Inflammatory Arteritis and VasculitisChronic inflammatory arteritis and vasculitis (i.e., inflamma-tory changes within veins as well as arteries) include a spec-trum of disease processes caused by immunologic mechanisms. These terms signify a necrotizing transmural inflammation of the vessel wall associated with antigen-antibody immune com-plex deposition within the endothelium. These conditions show pronounced cellular infiltration in the adventitia, thickened inti-mal fibrosis, and organized thrombus. These disease processes may clinically mimic atherosclerosis, and most are treated by corticosteroid therapy or chemotherapeutic agents. Even so, it is important to recognize distinguishing characteristics of each disease in order to establish the course of treatment and long-term prognosis. A classification system of systemic vasculitis by vessel size is shown in Table 23-28.Behçet’s DiseaseBehçet’s disease is a rare syndrome characterized by oral and genital ulcerations and ocular inflammation, affecting males in Japan and the Mediterranean. An HLA linkage has been found, indicating a genetic component to the etiology.216 Vascular involvement is seen in 7% to 38% of patients and is localized Table 23-28Classification of vasculitis based on vessel involvementLarge-Vessel VasculitisTakayasu’s arteritisGiant cell arteritisBehçet’s diseaseMedium-Vessel VasculitisPolyarteritis nodosaKawasaki’s diseaseBuerger’s diseaseSmall-Vessel VasculitisHypersensitivity angiitisto the abdominal aorta, femoral artery, and pulmonary artery. Vascular lesions may also include venous complications such as deep venous thrombosis or superficial thrombophlebitis. Arterial aneurysmal degeneration can occur; however, this is an uncommon, albeit potentially devastating, complication. Mul-tiple true aneurysms and pseudoaneurysms may develop, and rupture of an aortic aneurysm is the major cause of death in patients with Behçet’s disease.217Histologically, degeneration of the vasa vasorum with surrounding perivascular lymphocyte infiltration is seen, along with thickening of the elastic laminae around the tunica media. Aneurysm formation is believed to be associated with a loss of the nutrient flow and elastic component of the vessels, lead-ing to progressive dilatation. Multiple aneurysms are relatively common, with a reported occurrence of 36% in affected Japanese patients.218 Furthermore, pseudoaneurysm formation after surgical bypass is common at anastomotic suture lines due to the vascular wall fragility and medial destruction. Systemic therapy with corticosteroids and immunosuppressive agents may diminish symptoms related to the inflammatory process; however, they have no effect on the rate of disease progression and arterial degeneration.Polyarteritis NodosaPolyarteritis nodosa (PAN) is another systemic inflammatory disease process, which is characterized by a necrotizing inflam-mation of medium-sized or small arteries that spares the small-est blood vessels (i.e., arterioles and capillaries). This disease predominantly affects men over women by a 2 to 1 ratio. PAN develops subacutely, with constitutional symptoms that last for weeks to months. Intermittent, low-grade fevers, malaise, weight loss, and myalgias are common presenting symptoms. As medium-sized vessels lie within the deep dermis, cutane-ous manifestations occur in the form of livedo reticularis, nod-ules, ulcerations, and digital ischemia.218 Skin biopsies of these lesions may be sufficient for diagnosis. Inflammation may be seen histologically, with pleomorphic cellular infiltrates and segmental transmural necrosis leading to aneurysm formation.Neuritis from nerve infarction occurs in 60% of patients, and gastrointestinal complications occur in up to 50%.219 Addi-tionally, renal involvement is found in 40% and manifests as microaneurysms within the kidney or segmental infarctions. Cardiac disease is a rare finding except at autopsy, where thickened, diseased coronary arteries may be seen, as well as patchy myocardial necrosis. Patients may succumb to renal fail-ure, intestinal hemorrhage, or perforation. End-organ ischemia from vascular occlusion or aneurysm rupture can be disastrous Brunicardi_Ch23_p0897-p0980.indd 97127/02/19 4:15 PM 972SPECIFIC CONSIDERATIONSPART IIcomplications with high mortality rates. The mainstay of treat-ment is steroid and cytotoxic agent therapy. Up to 50% of patients with active PAN will experience remission with high dosing.Radiation-Induced ArteritisRadiation-induced arteritis results from progressive stenosis due to endothelial damage that leads to cellular proliferation and fibrosis. These are well-described complications of combined irradiation and chemotherapy for the treatment of head and neck malignancy. Arterial lesions are known complications of radia-tion and are similar to those found in atherosclerotic occlusive disease. A history of therapeutic irradiation to the neck can complicate the management of carotid artery occlusive disease. Radiation-induced damage to blood vessels has been well stud-ied. The small capillaries and sinusoids are most susceptible to radiation effects, as endothelial cells are the most radiosensi-tive cells. The radiation effects on the mediumand large-sized arteries include myointimal proliferation, with or without lipid deposits, and thrombosis. Characteristically, irregular spindle-shaped cells are seen replacing the normal endothelial cells in the healing phase. Occlusive lesions develop in the irradiated carotid arteries and are either the result of vessel wall fibrosis or, more commonly, due to accelerated atherosclerosis. Neuro-logic complications related to radiation-induced carotid artery disease are similar to those due to nonirradiated atherosclerotic occlusive disease.Rupture of the carotid artery has been reported following neck irradiation and is likely related to local wound compli-cation and superimposed infection. The diagnosis of radiation arteritis is based on the clinical history and confirmation of the occlusive lesion by duplex ultrasound, MRA, CTA, or sub-traction angiography. Irradiated lesions can be confined to the irradiated segment of the internal carotid artery with the remain-ing part of the vessel spared of disease. Characteristically, the radiation-induced atherosclerotic lesion does not involve the carotid bulb, unlike the nonradiated atherosclerotic lesions. The indications for intervention in radiation-induced carotid lesions are the same as previously discussed for atherosclerotic carotid occlusive lesions. However, asymptomatic irradiated carotid artery lesions should be considered for intervention because they can be more prone to progression and develop-ment of neurologic complications. Endovascular treatment with carotid angioplasty/stenting has become the treatment of choice for radiation-induced lesions, although surgical endarterectomy and bypass have been shown to be safe. The rate of recurrent stenosis is higher in radiation-induced carotid lesions, whether stented or surgically treated.Raynaud’s SyndromeFirst described in 1862 by Maurice Reynaud, the term Raynaud’s syndrome applies to a heterogeneous symptom array associated with peripheral vasospasm, more commonly occurring in the upper extremities. The characteristically intermittent vasospasm classically follows exposure to various stimuli, including cold temperatures, tobacco, or emotional stress. Formerly, a distinc-tion was made between Raynaud’s “disease” and Raynaud’s “phenomenon” for describing a benign disease occurring in isolation or a more severe disease secondary to another under-lying disorder, respectively. However, many patients develop collagen vascular disorders at some point after the onset of vaso-spastic symptoms; progression to a connective tissue disorder ranges from 11% to 65% in reported series.220 Therefore, the term Raynaud’s syndrome is now used to encompass both the primary and secondary conditions.Characteristic color changes occur in response to the arterio-lar vasospasm, ranging from intense pallor to cyanosis to redness as the vasospasm occurs. The digital vessels then relax, even-tually leading to reactive hyperemia. The majority of patients are young women less than 40 years of age. Up to 70% to 90% of reported patients are women, although many patients with only mild symptoms may never present for treatment.220 Geo-graphic regions with cooler, damp climates such as the Pacific Northwest and Scandinavian countries have a higher reported prevalence of the syndrome. Certain occupational groups, such as those who use vibrating tools, may be more predisposed to Raynaud’s syndrome or digital ischemia. The exact patho-physiologic mechanism behind the development of such severe vasospasm remains elusive, and much attention has focused on increased levels of α2-adrenergic receptors and their hypersen-sitivity in patients with Raynaud’s syndrome, as well as abnor-malities in the thermoregulatory response, which is governed by the sympathetic nervous system.The diagnosis of severe vasospasm may be made using noninvasive measurements in the vascular laboratory. Angiog-raphy is usually reserved for those who have digital ulceration and in whom an embolic or obstructive cause is believed to be present and potentially surgically correctable. Different changes in digital blood pressure will occur in patients with Raynaud’s syndrome. Normal individuals will show only a slight decrease in digital blood pressure in response to external cold stimuli, whereas those with Raynaud’s syndrome will show a similar curve until a critical temperature is reached. It is at this point that arterial closure acutely occurs.There is no cure for Raynaud’s syndrome; thus, all treat-ments mainly palliate symptoms and decrease the severity and perhaps frequency of attacks. Conservative measures predomi-nate, including the wearing of gloves, use of electric or chemi-cally activated hand warmers, avoiding occupational exposure to vibratory tools, abstinence from tobacco, and relocating to a warmer, dryer climate. The majority (90%) of patients will respond to avoidance of cold and other stimuli. The remaining 10% of patients with more persistent or severe syndromes can be treated with a variety of vasodilatory drugs, albeit with only a 30% to 60% response rate. Calcium channel–blocking agents such as diltiazem and nifedipine are the drugs of choice. The selective serotonin reuptake inhibitor fluoxetine has been shown to reduce the frequency and duration of vasospastic episodes. Intravenous infusions of prostaglandins have been reserved for nonresponders with severe symptoms.Surgical therapy is limited to debridement of digital ulcer-ations and amputation of gangrenous digits, which are rare complications. Upper extremity sympathectomy may provide relief in 60% to 70% of patients; however, the results are short-lived with a gradual recurrence of symptoms in 60% of patients within 10 years.221Fibromuscular DysplasiaFMD is a vasculopathy of uncertain etiology that is character-ized by segmental arterial involvement. Histologically, fibrous tissue proliferation, smooth muscle cell hyperplasia, and elastic fiber destruction alternate with mural thinning. The characteris-tic beaded appearance of FMD is due to areas of medial thinning alternating with areas of stenosis. The most commonly affected Brunicardi_Ch23_p0897-p0980.indd 97227/02/19 4:15 PM 973ARTERIAL DISEASECHAPTER 23are medium-sized arteries, including the internal carotid, renal, vertebral, subclavian, mesenteric, and iliac arteries. The inter-nal carotid artery is the second most common site of involve-ment after the renal arteries. FMD occurs most frequently in women (90%) and is recognized at approximately 55 years of age.222 Only 10% of patients with FMD will have complications attributable to the disease. Pathologically, FMD is a heterog-enous group of four distinct types of lesions that are subgrouped based on the predominant site of involvement within the vessel wall. Of the four types (medial fibroplasia, intimal fibroplasia, medial hyperplasia, and perimedial dysplasia), medial fibropla-sia is the most common pathologic type, affecting the internal carotid artery (ICA) and the renal artery, and occurring in 85% of reported cases.223The two main clinical syndromes associated with FMD are TIAs from disease in the internal carotid artery and hyper-tension from renal artery involvement. Symptoms produced by FMD are generally secondary to associated arterial stenosis and are clinically indistinguishable from those caused by atheroscle-rotic disease. Often, asymptomatic disease is found incidentally on conventional angiographic studies being performed for other reasons. Within the internal carotid artery, FMD lesions tend to be located higher in the extracranial segment than with athero-sclerotic lesions and may not be readily demonstrated by duplex scan.Clinically, symptoms are due to encroachment on the ves-sel lumen and a reduction in flow. Additionally, thrombi may form in areas of mural dilatation from a stagnation of flow, lead-ing to distal embolization. Surgical treatment has been favored for symptomatic patients with angiographically proven disease. Due to the distal location of FMD lesions in the extracranial carotid artery, resection and repair are not usually feasible. Instead, graduated luminal dilatation under direct vision has been used successfully in patients, with antiplatelet therapy continued postoperatively. PTA has been used effectively in patients with FMD-induced hypertension. Several series have documented a high technical success rate, with recurrence rates of 8% to 23% at more than 1 year.223 However, the therapeutic effect of blood pressure control may continue to be observed despite restenosis. Surgical reconstruction of the renal arteries for FMD has good long-term results and is recommended for recurrent lesions after angioplasty. Open balloon angioplasty of the ICA has been described, which allows for precise fluo-roscopic guidance, rather than blind dilatation with calibrated metal probes, and back-bleeding after dilatation to eliminate cerebral embolization. Distal neuroprotective devices may allow this procedure to be performed completely percutane-ously, thereby lessening the threat of cerebral emboli.Nonatherosclerotic Disease Affecting the Popliteal Artery DiseaseThere are three distinct nonatherosclerotic disease entities that may result in lower extremity claudication that predominantly occur in 40to 50-year-old men. Adventitial cystic disease, pop-liteal artery entrapment syndrome, and Buerger’s disease should be considered in any young patients presenting with intermittent claudication.Adventitial Cystic Disease of the Popliteal Artery. The first successful operative repair of popliteal artery occlusion caused by a cyst arising from the adventitia was reported in 1954 by Ejrup and Hierton.224 Adventitial cystic disease is a rare arterial condition occurring at an incidence of 0.1%, usually in the popliteal artery. This disease affects men in a ratio of approximately 5:1 and appears predominantly in the fourth and fifth decades. The incidence is approximately 1 in 1200 cases of claudication or 1 in 1000 peripheral arteriograms. The predominance of reported cases is found in Japan and Europe. However, this disease may affect other vascular sites, such as the femoral, external iliac, radial, ulnar, and brachial arteries. Besides claudication as a symptom, this diagnosis should be considered in young patients who have a mass in a nonaxial ves-sel in proximity to a related joint. These synovial-like, mucin-filled cysts reside in the subadventitial layer of the vessel wall and have a similar macroscopic appearance to ganglion cysts. Despite this similarity and suggestion of a joint origin for these lesions, histochemical markers have failed to link the cystic lin-ing to synovium.Patients presenting at a young age with bilateral lower extremity claudication and minimal risk factors for atheroma formation should be evaluated for adventitial cystic disease, as well as the other two nonatherosclerotic vascular lesions described here. Because of luminal encroachment and com-pression, peripheral pulses may be present in the limb when extended, but then can disappear during knee joint flexion. Noninvasive studies may suggest arterial stenosis with ele-vated velocities. Color-flow duplex scanning followed by T2-weighted MRI now appears to be the best diagnostic choice. Angiography will demonstrate a smooth, well-defined, crescent-shaped filling defect, the classic “scimitar” sign.224 There may be associated calcification in the cyst wall and no other evidence of atherosclerotic occlusive disease.Various therapeutic methods have been described for the treatment of adventitial cystic disease. The recommended treat-ments are excision of the cyst with the cystic wall, enucleation, or simple aspiration when the artery is stenotic. Retention of the cystic lining leads to continued secretion of the cystic fluid and recurrent lesions. In 30% of patients who have an occluded artery, resection of the affected artery, followed by an interposi-tion graft using autogenous saphenous vein, is recommended.Popliteal Artery Entrapment Syndrome. Love and col-leagues first coined the term popliteal artery entrapment in 1965 to describe a syndrome combining muscular involvement with arterial ischemia occurring behind the knee, with the suc-cessful surgical repair having taken place 6 years earlier.225 This is a rare disorder with an estimated prevalence of 0.16% that occurs with a male-to-female ratio of 15:1. Five types of anatomic entrapment have been defined, according to the posi-tion of the medial head of the gastrocnemius muscle, abnormal muscle slips or tendinous bands, or the course of the popliteal artery itself (Table 23-29). Concomitant popliteal vein impinge-ment occurs in up to 30% of cases. Twenty-five percent of cases are bilateral.The typical patient presents with swelling and claudica-tion of isolated calf muscle groups following vigorous physi-cal activity. Various differential diagnoses must be considered when encountering patients with symptoms and signs sugges-tive of popliteal artery entrapment syndrome (Table 23-30). In a large series of 240 patients, the median age for surgical treat-ment was 28.5 years.226 Noninvasive studies with ABIs should be performed with the knee extended and the foot in a neutral, forced plantar, and dorsiflexed position. A drop in pressure of 50% or greater or dampening of the plethysmographic wave-forms in plantar or dorsiflexion is a classic finding. Contraction Brunicardi_Ch23_p0897-p0980.indd 97327/02/19 4:15 PM 974SPECIFIC CONSIDERATIONSPART IITable 23-29Classification of popliteal entrapment syndromeTYPEDESCRIPTIONIPopliteal artery is displaced medially around a normal medial head of the gastrocnemiusIIMedial head of gastrocnemius, which arises lateral to popliteal arteryIIIPopliteal artery is compressed by an accessory slip of muscle from medial head of gastrocnemiusIVEntrapment by a deeper popliteus muscleVAny of the above plus popliteal vein entrapmentVIFunctional entrapmentTable 23-30Differential diagnosis for popliteal entrapment syndromeVascular EtiologiesAtherosclerosisBuerger’s diseaseTraumaPopliteal aneurysmAdventitial cystic diseaseExtrinsic compressionCardiac embolismDeep vein thrombosisVenous entrapmentMusculoskeletal EtiologiesGastrocnemius or soleus strainPeriostitisCompartment syndromeStress fracturesTibialis posterior tendonitisMuscular anomaliesGeneral Neurologic EtiologiesSpinal stenosisof the gastrocnemius should compress the entrapped popliteal artery. The sudden onset of signs and symptoms of acute isch-emia with absent distal pulses is consistent with popliteal artery occlusion secondary to entrapment. Other conditions resulting from entrapment are thrombus formation with distal emboli or popliteal aneurysmal degeneration. Although CT and MRI have been employed, angiography remains the most widely used test. Angiography performed with the foot in a neutral position may demonstrate classical medial deviation of the popliteal artery or normal anatomic positioning. Coexisting abnormalities may include stenosis, luminal irregularity, delayed flow, aneurysm, or complete occlusion. Diagnostic accuracy is increased with the use of ankle stress view-active plantar flexion and passive dorsiflexion.The treatment of popliteal artery entrapment consists of surgical decompression of the impinged artery with possible arterial reconstruction. Division of the anomalous musculoten-dinous insertion site with or without saphenous vein interposi-tion grafting to bypass the damaged arterial segment has been described to be the procedure of choice. The natural history of entrapment is progressive arterial degeneration leading to com-plete arterial thrombosis. In such instances, thrombolytic ther-apy is needed with subsequent release of the functional arterial impairment. Lysis will improve distal runoff and may improve limb-salvage and bypass patency rates.Buerger’s Disease (Thromboangiitis Obliterans)Buerger’s disease, also known as thromboangiitis obliterans, is a progressive nonatherosclerotic segmental inflammatory disease that most often affects smalland medium-sized arteries, veins, and nerves of the upper and lower extremities. The clinical and pathologic findings of this disease entity were published in 1908 by Leo Buerger in a description of 11 amputated limbs.227 The typical age range for occurrence is 20 to 50 years, and the dis-order is more frequently found in males who smoke. The upper extremities may be involved, and a migratory superficial phlebi-tis may be present in up to 16% of patients, thus indicating a sys-temic inflammatory response. In young adults presenting to the Mayo Clinic (1953–1981) with lower limb ischemia, Buerger’s disease was diagnosed in 24%.228 Conversely, the diagnosis was made in 9% of patients with ischemic finger ulcerations. The cause of thromboangiitis obliterans is unknown; however, use of or exposure to tobacco is essential to both the diagnosis and progression of the disease.Pathologically, thrombosis occurs in smallto medium-sized arteries and veins with associated dense polymorphonu-clear leukocyte aggregation, microabscesses, and multinucleated giant cells. The chronic phase of the disease shows a decrease in the hypercellularity and frequent recanalization of the vessel lumen. End-stage lesions demonstrate organized thrombus and blood vessel fibrosis. Although the disease is common in Asia, North American males do not appear to have any particular pre-disposition, as the diagnosis is made in less than 1% of patients with severe limb ischemia.Buerger’s disease typically presents in young male smok-ers, with symptoms beginning prior to age 40. Patients initially present with foot, leg, arm, or hand claudication, which may be mistaken for joint or neuromuscular problems. Progression of the disease leads to calf claudication and eventually ischemic rest pain and ulcerations on the toes, feet, or fingers. A complete history should exclude diabetes, hyperlipidemia, or autoimmune disease as possible etiologies for the occlusive lesions. Because it is likely that multiple limbs are involved, angiography should be performed of all four limbs. Even if symptoms are not yet present in a limb, angiographic findings may be demonstrated. Characteristic angiographic findings show disease confinement to the distal circulation, usually infrapopliteal and distal to the brachial artery. The occlusions are segmental and show “skip” lesions with extensive collateralization, the so-called corkscrew collaterals.The treatment of thromboangiitis obliterans revolves around strict smoking cessation. In patients who are able to abstain, disease remission is impressive, and amputation avoid-ance is increased. In the experience reported from the Oregon Health Sciences Center, no disease progression with associated tissue loss occurred after discontinuation of tobacco. The role of surgical intervention is minimal in Buerger’s disease, as there is often no acceptable target vessel for bypass. Furthermore, autog-enous vein conduits are limited secondary to coexisting migra-tory thrombophlebitis. Mills and associates reported their results Brunicardi_Ch23_p0897-p0980.indd 97427/02/19 4:15 PM 975ARTERIAL DISEASECHAPTER 23of 31% limb loss in 26 patients over 15 years, thus authenti-cating the virulence of Buerger’s disease involving the lower extremities.229 In addition, others have described a significant discrepancy in limb loss in patients who continued to smoke versus those who discontinued tobacco use (67% vs. 35%).REFERENCESEntries highlighted in bright blue are key references. 1. Norgren L, Hiatt WR, Dormandy JA, et al. Inter-society consensus for the management of peripheral arterial disease (TASC II). Eur J Vasc Endovasc Surg. 2007;33(suppl 1): S1-S75. 2. Jones DN, Rutherford RB. Peripheral vascular assessment and its role in predicting wound healing potential. Clin Podiatr Med Surg. 1991;8(4):909-921. 3. Favaretto E, Pili C, Amato A, et al. Analysis of agreement between Duplex ultrasound scanning and arteriography in patients with lower limb artery disease. J Cardiovasc Med (Hagerstown). 2007;8(5):337-341. 4. Jakobs TF, Wintersperger BJ, Becker CR. MDCT-imaging of peripheral arterial disease. Semin Ultrasound CT MR. 2004; 25(2):145-155. 5. Hertzer NR, Beven EG, Young JR, et al. Coronary artery dis-ease in peripheral vascular patients. A classification of 1000 coronary angiograms and results of surgical management. Ann Surg. 1984;199(2):223-233. 6. Eagle KA, Coley CM, Newell JB, et al. Combining clini-cal and thallium data optimizes preoperative assessment of cardiac risk before major vascular surgery. Ann Intern Med. 1989;110(11):859-866. 7. McFalls EO, Ward HB, Moritz TE, et al. Predictors and out-comes of a perioperative myocardial infarction following elective vascular surgery in patients with documented coro-nary artery disease: results of the CARP trial. Eur Heart J. 2008;29(3):394-401. 8. Landoni G, Pisano A, Lomivorotov V, et al. Randomized evi-dence for reduction of perioperative mortality: an updated consensus process. J Cardiothorac Vasc Anesth. 2017;31(2): 719-730. 9. Ali WE, Vaidya SR, Ejeh SU, Okoroafor KU. Meta-analysis study comparing percutaneous coronary intervention/drug eluting stent versus coronary artery bypass surgery of unpro-tected left main coronary artery disease: Clinical outcomes during short-term versus long-term (>1 year) follow-up. Medi-cine (Baltimore). 2018;97(7):e9909. 10. Altit R, Gray WA. New innovations in drug-eluting stents for peripheral arterial disease. Curr Cardiol Rep. 2017;19(11):117. 11. Parodi JC, Marin ML, Veith FJ. Transfemoral, endovascular stented graft repair of an abdominal aortic aneurysm. Arch Surg. 1995;130(5):549-552. 12. Brinster CJ, Milner R. Fenestrated endovascular aortic repair and clinical trial devices for complex abdominal aortic aneu-rysms. J Cardiovasc Surg (Torino). 2018;59(3):342-359. 13. Ergun O, Canyigit M, Hidiroglu M, et al. Endovascular treat-ment for acute traumatic thoracic aortic transection. Ulus Travma Acil Cerrahi Derg. 2015;21(4):285-290. 14. Donnan GA, Fisher M, Macleod M, Davis SM. Stroke. Lancet. 2008;371(9624):1612-1623. 15. Chaer RA, DeRubertis B, Patel S, Lin SC, Kent CK, Faries PL. Current management of extracranial carotid artery disease. Rev Recent Clin Trials. 2006;1(3):293-301. 16. Grant EG, Benson CB, Moneta GL, et al. Carotid artery stenosis: grayscale and Doppler ultrasound diagnosis--Society of Radi-ologists in Ultrasound consensus conference. Ultrasound Q.  2003;19(4):190-198. 17. Brinjikji W, Huston J 3rd, Rabinstein AA, Kim GM,  Lerman A, Lanzino G. Contemporary carotid imaging: from degree of stenosis to plaque vulnerability. J Neurosurg. 2016; 124(1):27-42. 18. Zhao DL, Wan Y, Wang GK, et al. Evaluation of image quality in carotid and cerebrovascular disease: a comparative study between subtraction and routine computed tomography angi-ography. Echocardiography. 2016;33(11):1735-1740. 19. Cheng SF, Brown MM. Contemporary medical therapies of atherosclerotic carotid artery disease. Semin Vasc Surg. 2017; 30(1):8-16. 20. Kita MW. Carotid endarterectomy in symptomatic carotid stenosis: NASCET comparative results at 30 months of follow-up. J Insur Med. 1992;24(1):42-46. 21. Warlow CP. Symptomatic patients: the European Carotid Surgery Trial (ECST). J Mal Vasc. 1993;18(3):198-201. 22. Rothwell PM, Eliasziw M, Gutnikov SA, et al. Analysis of pooled data from the randomised controlled trials of endar-terectomy for symptomatic carotid stenosis. Lancet. 2003; 361(9352):107-116. 23. Topakian R, Strasak AM, Sonnberger M, et al. Timing of stent-ing of symptomatic carotid stenosis is predictive of 30-day outcome. Eur J Neurol. 2007;14(6):672-678. 24. Roederer GO, Langlois YE, Jager KA, et al. The natural his-tory of carotid arterial disease in asymptomatic patients with cervical bruits. Stroke. 1984;15(4):605-613. 25. Fisher M, Martin A, Cosgrove M, Norris JW. The NASCET-ACAS plaque project. North American Symptomatic Carotid Endarterectomy Trial. Asymptomatic Carotid Atherosclerosis Study. Stroke. 1993;24(12 suppl):I24-25; discussion I31-2. 26. Halliday A, Mansfield A, Marro J, et al. Prevention of dis-abling and fatal strokes by successful carotid endarterectomy in patients without recent neurological symptoms: randomised controlled trial. Lancet. 2004;363(9420):1491-1502. 27. Coward LJ, Featherstone RL, Brown MM. Safety and efficacy of endovascular treatment of carotid artery stenosis compared with carotid endarterectomy: a Cochrane systematic review of the randomized evidence. Stroke. 2005;36(4):905-911. 28. Lin PH, Barshes NR, Annambhotla S, Huynh TT. Prospec-tive randomized trials of carotid artery stenting versus carotid endarterectomy: an appraisal of the current literature. Vasc Endovascular Surg. 2008;42(1):5-11. 29. Berkefeld J, Chaturvedi S. The International Carotid Stent-ing Study and the North American Carotid Revascularization Endarterectomy versus Stenting Trial: fueling the debate about carotid artery stenting. Stroke. 2010;41(11):2714-2715. 30. Brott TG, Hobson RW 2nd, Howard G, et al. Stenting versus endarterectomy for treatment of carotid-artery stenosis. N Engl J Med. 2010;363(1):11-23. 31. Bonati LH, Jongen LM, Haller S, et al. New ischaemic brain lesions on MRI after stenting or endarterectomy for symptom-atic carotid stenosis: a substudy of the International Carotid Stenting Study (ICSS). Lancet Neurol. 2010;9(4):353-362. 32. Ricotta JJ, Aburahma A, Ascher E, et al. Updated Society for Vas-cular Surgery guidelines for management of extracranial carotid disease: executive summary. J Vasc Surg. 2011;54(3)832-836. 33. Crawford RS, Chung TK, Hodgman T, Pedraza JD, Corey M, Cambria RP. Restenosis after eversion vs patch closure carotid endarterectomy. J Vasc Surg. 2007;46(1):41-48. 34. Organ N, Walker PJ, Jenkins J, Foster W, Jenkins J. 15 year experience of carotid endarterectomy at the Royal Brisbane and Women’s Hospital: outcomes and changing trends in man-agement. Eur J Vasc Endovasc Surg. 2008;35(3):273-279. 35. Zhou W, Felkai DD, Evans M, et al. Ultrasound criteria for severe in-stent restenosis following carotid artery stenting.  J Vasc Surg. 2008;47(1):74-80. 36. Lin PH, Zhou W, Kougias P, El Sayed HF, Barshes NR, Huynh TT. Factors associated with hypotension and bradycardia after Brunicardi_Ch23_p0897-p0980.indd 97527/02/19 4:15 PM 976SPECIFIC CONSIDERATIONSPART IIcarotid angioplasty and stenting. J Vasc Surg. 2007;46(5): 846-853; discussion 853-844. 37. Plouin PF, Perdu J, La Batide-Alanore A, Boutouyrie P, Gimenez-Roqueplo AP, Jeunemaitre X. Fibromuscular dys-plasia. Orphanet J Rare Dis. 2007;2:28. 38. Zhou W, Lin PH, Bush RL, et al. Carotid artery aneurysm: evolution of management over two decades. J Vasc Surg. 2006;43(3):493-496; discussion 497. 39. Woolen S, Gemmete JJ. Paragangliomas of the head and neck. Neuroimaging Clin N Am. 2016;26(2):259-278. 40. Khan MM, Khan MI, Ali H, Kazmi T, Iqbal H. Diagnostic, surgical, and postoperative challenges of neuroendocrine tumors of the neck: clinical experience and literature review. Ann Vasc Surg. 2017;45:92-97. 41. Chandra V, Trang K, Virgin-Downey W, Dalman RL, Mell MW. Long-term outcomes after repair of symptom-atic abdominal aortic aneurysms. J Vasc Surg. 2018. pii: S0741-5214(18)30435-X. 42. Dotter CT, Judkins MP, Rosch J. Transluminal angioplasty in arteriosclerotic obstruction of the lower extremities. Med Times. 1969;97(7):95-108. 43. Lin CJ, Lin CY, Stitziel NO. Genetics of the extracellular matrix in aortic aneurysmal diseases. Matrix Biol. 2018. pii: S0945-053X(17)30468-7. 44. Matthews EO, Rowbotham SE, Moxon JV, Jones RE, Vega de Ceniga M, Golledge J. Meta-analysis of the association between peripheral artery disease and growth of abdominal aortic aneurysms. Br J Surg. 2017;104(13):1765-1774. 45. Boese A, Chang L, Yin KJ, Chen YE, Lee JP, Hamblin MH. Sex Differences in Abdominal Aortic Aneurysms. Am J Physiol Heart Circ Physiol. 2018. 46. Fleming C, Whitlock EP, Beil TL, Lederle FA. Screening for abdominal aortic aneurysm: a best-evidence systematic review for the U.S. Preventive Services Task Force. Ann Intern Med. 2005;142(3):203-211. 47. Lederle FA, Johnson GR, Wilson SE, et al. Yield of repeated screening for abdominal aortic aneurysm after a 4-year inter-val. Aneurysm Detection and Management Veterans Affairs Cooperative Study Investigators. Arch Intern Med. 2000; 160(8):1117-1121. 48. Patel MS, Brown DA, Wilson SE. Relevance of the ADAM and UK Small Aneurysm trial data in the age of endovascular aneurysm repair. Arch Surg. 2009;144(9):806-810. 49. Soares Ferreira R, Gomes Oliveira N, Oliveira-Pinto J, et al. Review on management and outcomes of ruptured abdomi-nal aortic aneurysm in women. J Cardiovasc Surg (Torino). 2018;59(2):195-200. 50. Marques-Rios G, Oliveira-Pinto J, Mansilha A. Predictors of long-term mortality following elective endovascular repair of abdominal aortic aneurysms. Int Angiol. 2018;37(4):277-285. 51. Yang JH, Kim JW, Choi HC, et al. Comparison of clinical outcomes between surgical repair and endovascular stent for the treatment of abdominal aortic aneurysm. Vasc Specialist Int. 2017;33(4):140-145. 52. Williams CR, Brooke BS. Effectiveness of open versus endo-vascular abdominal aortic aneurysm repair in population set-tings: a systematic review of statewide databases. Surgery. 2017;162(4):707-720. 53. Joo HC, Lee SH, Chang BC, Lee S, Yoo KJ, Youn YN. Late open conversion after endovascular abdominal aortic repair: a 20 year experience. J Cardiovasc Surg (Torino). 2018. 54. Spanos K, Antoniou G, Giannoukas AD, et al. Durability of fenestrated endovascular aortic repair for juxta-renal abdomi-nal aortic aneurysm repair. J Cardiovasc Surg (Torino). 2018; 59(2):213-224. 55. Georgiadis GS, van Herwaarden JA, Saengprakai W, et al. Endovascular treatment of complex abdominal and thoracoabdominal type IV aortic aneurysms with fenestrated technology. J Cardiovasc Surg (Torino). 2017;58(4):574-590. 56. Cochennec F, Kobeiter H, Gohel M, et al. Early results of physician modified fenestrated stent grafts for the treatment of thoraco-abdominal aortic aneurysms. Eur J Vasc Endovasc Surg. 2015;50(5):583-592. 57. Mendes BC, Greiten LE, Oderich GS. Endovascular repair of a thoracoabdominal aortic aneurysm with a patient-specific fenestrated-branched stent-graft. J Endovasc Ther. 2017;24(5):665-669. 58. Sala-Almonacil VA, Zaragoza-Garcia JM, Ramirez-Montoya M, Molina-Nacher V, Martinez-Perello I, Gomez-Palones FJ. Fenestrated and chimney endovascular aneurysm repair versus open surgery for complex abdominal aortic aneurysms. J Car-diovasc Surg (Torino). 2017;58(6):801-813. 59. Oderich GS, Ribeiro M, Hofer J, et al. Prospective, nonran-domized study to evaluate endovascular repair of pararenal and thoracoabdominal aortic aneurysms using fenestrated-branched endografts based on supraceliac sealing zones.  J Vasc Surg. 2017;65(5):1249-1259 e1210. 60. Schurink GW, Aarts NJ, van Bockel JH. Endoleak after stent-graft treatment of abdominal aortic aneurysm: a meta-analysis of clinical studies. Br J Surg. 1999;86(5):581-587. 61. Kuziez MS, Sanchez LA, Zayed MA. Abdominal aortic aneu-rysm type II endoleaks. J Cardiovasc Dis Diagn. 2016;4(5). pii: 255. 62. Zaiem F, Almasri J, Tello M, Prokop LJ, Chaikof EL, Murad MH. A systematic review of surveillance after endovascular aortic repair. J Vasc Surg. 2018;67(1):320-331 e337. 63. Lin PH, Bush RL, Chaikof EL, et al. A prospective evaluation of hypogastric artery embolization in endovascular aortoiliac aneurysm repair. J Vasc Surg. 2002;36(3):500-506. 64. Elisha S, Nagelhout J, Heiner J, Gabot M. Anesthesia case management for endovascular aortic aneurysm repair. AANA J.  2014;82(2):145-152. 65. Nelson PR, Kracjer Z, Kansal N, et al. A multicenter, ran-domized, controlled trial of totally percutaneous access ver-sus open femoral exposure for endovascular aortic aneurysm repair (the PEVAR trial). J Vasc Surg. 2014;59(5):1181-1193. 66. Prinssen M, Verhoeven EL, Buth J, et al. A randomized trial comparing conventional and endovascular repair of abdominal aortic aneurysms. N Engl J Med. 2004;351(16): 1607-1618. 67. Greenhalgh RM, Brown LC, Kwong GP, Powell JT, Thomp-son SG. Comparison of endovascular aneurysm repair with open repair in patients with abdominal aortic aneurysm (EVAR trial 1), 30-day operative mortality results: ran-domised controlled trial. Lancet. 2004;364(9437):843-848. 68. Lederle FA, Freischlag JA, Kyriakides TC, et al. Long-term comparison of endovascular and open repair of abdominal aor-tic aneurysm. N Engl J Med. 2012;367(21):1988-1997. 69. Matsumura JS, Brewster DC, Makaroun MS, Naftel DC. A multicenter controlled clinical trial of open versus endovas-cular treatment of abdominal aortic aneurysm. J Vasc Surg. 2003;37(2):262-271. 70. Greenberg RK, Chuter TA, Sternbergh WC 3rd, Fearnot NE. Zenith AAA endovascular graft: intermediate-term results of the US multicenter trial. J Vasc Surg. 2004;39(6):1209-1218. 71. Zarins CK. The US AneuRx Clinical Trial: 6-year clinical update 2002. J Vasc Surg. 2003;37(4):904-908. 72. Criado FJ, Clark NS, McKendrick C, Longway J, Domer GS. Update on the talent LPS AAA stent graft: results with “enhanced talent.” Semin Vasc Surg. 2003;16(2): 158-165. 73. Bertges DJ, Zwolak RM, Deaton DH, et al. Current hospital costs and medicare reimbursement for endovascular abdomi-nal aortic aneurysm repair. J Vasc Surg. 2003;37(2):272-279.Brunicardi_Ch23_p0897-p0980.indd 97627/02/19 4:15 PM 977ARTERIAL DISEASECHAPTER 23 74. Seiwert AJ, Wolfe J, Whalen RC, Pigott JP, Kritpracha B, Beebe HG. Cost comparison of aortic aneurysm endograft exclusion versus open surgical repair. Am J Surg. 1999;178(2):117-120. 75. Angle N, Dorafshar AH, Moore WS, et al. Open versus endo-vascular repair of abdominal aortic aneurysms: what does each really cost? Ann Vasc Surg. 2004;18(5):612-618. 76. Lederle FA, Stroupe KT, Kyriakides TC, Ge L, Freischlag JA, Open vs endovascular repair Veterans Affairs cooperative study G. Long-term cost-effectiveness in the Veterans Affairs open vs endovascular repair study of aortic abdominal aneu-rysm: a randomized clinical trial. JAMA Surg. 2016;151(12): 1139-1144. 77. Abraha I, Luchetta ML, De Florio R, et al. Ultrasonography for endoleak detection after endoluminal abdominal aortic aneu-rysm repair. Cochrane Database Syst Rev. 2017;6:CD010296. 78. Baum RA, Stavropoulos SW, Fairman RM, Carpenter JP. Endoleaks after endovascular repair of abdominal aortic aneu-rysms. J Vasc Interv Radiol. 2003;14(9 pt 1):1111-1117. 79. Dubenec SR, White GH, Pasenau J, Tzilalis V, Choy E, Erdelez L. Endotension. A review of current views on pathophysiol-ogy and treatment. J Cardiovasc Surg (Torino). 2003;44(4): 553-557. 80. Kougias P, Lin PH, Dardik A, Lee WA, El Sayed HF, Zhou W. Successful treatment of endotension and aneurysm sac enlargement with endovascular stent graft reinforcement.  J Vasc Surg. 2007;46(1):124-127. 81. Lin PH, Bush RL, Katzman JB, et al. Delayed aortic aneurysm enlargement due to endotension after endovascular abdominal aortic aneurysm repair. J Vasc Surg. 2003;38(4):840-842. 82. Buth J, Harris PL, Van Marrewijk C, Fransen G. Endoleaks during follow-up after endovascular repair of abdominal aortic aneurysm. Are they all dangerous? J Cardiovasc Surg (Torino). 2003;44(4):559-566. 83. Harris PL, Vallabhaneni SR, Desgranges P, Becquemin JP, van Marrewijk C, Laheij RJ. Incidence and risk factors of late rup-ture, conversion, and death after endovascular repair of infra-renal aortic aneurysms: the EUROSTAR experience. European Collaborators on Stent/graft techniques for aortic aneurysm repair. J Vasc Surg. 2000;32(4):739-749. 84. Mehta M, Paty PS, Roddy SP, et al. Treatment options for delayed AAA rupture following endovascular repair. J Vasc Surg. 2011;53(1):14-20. 85. May J, White GH, Yu W, et al. Endoluminal repair of abdomi-nal aortic aneurysms: strengths and weaknesses of various prostheses observed in a 4.5-year experience. J Endovasc Surg. 1997;4(2):147-151. 86. Teufelsbauer H, Prusa AM, Prager M, et al. Endovascular treatment of a multimorbid patient with late AAA rupture after stent-graft placement: 1-year follow-up. J Endovasc Ther. 2002;9(6):896-900. 87. Yasuhara H. Acute mesenteric ischemia: the challenge of gas-troenterology. Surg Today. 2005;35(3):185-195. 88. Zelenock GB, Graham LM, Whitehouse WM Jr, et al. Splanch-nic arteriosclerotic disease and intestinal angina. Arch Surg. 1980;115(4):497-501. 89. Karwowski J, Arko F. Surgical management of mesenteric ischemia. Tech Vasc Interv Radiol. 2004;7(3):151-154. 90. Mitchell EL, Moneta GL. Mesenteric duplex scanning. Per-spect Vasc Surg Endovasc Ther. 2006;18(2):175-183. 91. Moneta GL, Lee RW, Yeager RA, Taylor LM Jr, Porter JM. Mesenteric duplex scanning: a blinded prospective study.  J Vasc Surg. 1993;17(1):79-84; discussion 85-76. 92. Kougias P, El Sayed HF, Zhou W, Lin PH. Management of chronic mesenteric ischemia. The role of endovascular ther-apy. J Endovasc Ther. 2007;14(3):395-405. 93. Kougias P, Lau D, El Sayed HF, Zhou W, Huynh TT, Lin PH. Determinants of mortality and treatment outcome following surgical interventions for acute mesenteric ischemia. J Vasc Surg. 2007;46(3):467-474. 94. Jimenez JC, Harlander-Locke M, Dutson EP. Open and laparo-scopic treatment of median arcuate ligament syndrome. J Vasc Surg. 2012;56(3):869-873. 95. Park WM, Cherry KJ Jr, Chua HK, et al. Current results of open revascularization for chronic mesenteric ischemia: a standard for comparison. J Vasc Surg. 2002;35(5):853-859. 96. Silva JA, White CJ, Collins TJ, et al. Endovascular therapy for chronic mesenteric ischemia. J Am Coll Cardiol. 2006;47(5): 944-950. 97. Furrer J, Gruntzig A, Kugelmeier J, Goebel N. Treatment of abdominal angina with percutaneous dilatation of an arteria mesenterica superior stenosis. Preliminary communication. Cardiovasc Intervent Radiol. 1980;3(1):43-44. 98. AbuRahma AF, Stone PA, Bates MC, Welch CA. Angioplasty/stenting of the superior mesenteric artery and celiac trunk: early and late outcomes. J Endovasc Ther. 2003;10(6):1046-1053. 99. Kasirajan K, O’Hara PJ, Gray BH, et al. Chronic mesenteric ischemia: open surgery versus percutaneous angioplasty and stenting. J Vasc Surg. 2001;33(1):63-71. 100. Atkins MD, Kwolek CJ, LaMuraglia GM, Brewster DC, Chung TK, Cambria RP. Surgical revascularization versus endovascular therapy for chronic mesenteric ischemia: a com-parative experience. J Vasc Surg. 2007;45(6):1162-1171. 101. Oderich GS, Erdoes LS, Lesar C, et al. Comparison of covered stents versus bare metal stents for treatment of chronic athero-sclerotic mesenteric arterial disease. J Vasc Surg. 2013;58(5): 1316-1323. 102. Textor SC. Atherosclerotic renal artery stenosis: overtreated but underrated? J Am Soc Nephrol. 2008;19(4):656-659. 103. Tafur JD, White CJ. Renal artery stenosis: when to revascular-ize in 2017. Curr Probl Cardiol. 2017;42(4):110-135. 104. Cherr GS, Hansen KJ, Craven TE, et al. Surgical manage-ment of atherosclerotic renovascular disease. J Vasc Surg. 2002;35(2):236-245. 105. Hansen KJ, Cherr GS, Craven TE, et al. Management of ischemic nephropathy: dialysis-free survival after surgical repair. J Vasc Surg. 2000;32(3):472-481; discussion 481-482. 106. Guzman RP, Zierler RE, Isaacson JA, Bergelin RO, Strand-ness DE Jr. Renal atrophy and arterial stenosis. A prospec-tive study with duplex ultrasound. Hypertension. 1994;23(3): 346-350. 107. van de Ven PJ, Kaatee R, Beutler JJ, et al. Arterial stenting and balloon angioplasty in ostial atherosclerotic renovas-cular disease: a randomised trial. Lancet. 1999;353(9149): 282-286. 108. Surowiec SM, Sivamurthy N, Rhodes JM, et al. Percutane-ous therapy for renal artery fibromuscular dysplasia. Ann Vasc Surg. 2003;17(6):650-655. 109. van Jaarsveld BC, Krijnen P. Prospective studies of diagno-sis and intervention: the Dutch experience. Semin Nephrol. 2000;20(5):463-473. 110. White CJ, Ramee SR, Collins TJ, Jenkins JS, Escobar A, Shaw D. Renal artery stent placement: utility in lesions dif-ficult to treat with balloon angioplasty. J Am Coll Cardiol. 1997;30(6):1445-1450. 111. Blum U, Krumme B, Flugel P, et al. Treatment of ostial renal-artery stenoses with vascular endoprostheses after unsuccess-ful balloon angioplasty. N Engl J Med. 1997;336(7):459-465. 112. Watson PS, Hadjipetrou P, Cox SV, Piemonte TC, Eisenhauer AC. Effect of renal artery stenting on renal function and size in patients with atherosclerotic renovascular disease. Circulation. 2000;102(14):1671-1677. 113. Harden PN, MacLeod MJ, Rodger RS, et al. Effect of renal-artery stenting on progression of renovascular renal failure. Lancet. 1997;349(9059):1133-1136.Brunicardi_Ch23_p0897-p0980.indd 97727/02/19 4:15 PM 978SPECIFIC CONSIDERATIONSPART II 114. Leertouwer TC, Gussenhoven EJ, Bosch JL, et al. Stent place-ment for renal arterial stenosis: where do we stand? A meta-analysis. Radiology. 2000;216(1):78-85. 115. Lyden SP, Smouse HB. TASC II and the endovascular man-agement of infrainguinal disease. J Endovasc Ther. 2009; 16(2 suppl 2):II5-II18. 116. Martin D, Katz SG. Axillofemoral bypass for aortoiliac occlu-sive disease. Am J Surg. 2000;180(2):100-103. 117. Criado E, Burnham SJ, Tinsley EA Jr, Johnson G Jr, Keagy BA. Femorofemoral bypass graft: analysis of patency and fac-tors influencing long-term outcome. J Vasc Surg. 1993;18(3): 495-504; discussion 504-495. 118. Patel A, Taylor SM, Langan EM 3rd, et al. Obturator bypass: a classic approach for the treatment of contemporary groin infection. Am Surg. 2002;68(8):653-658; discussion 658-659. 119. Sautner T, Niederle B, Herbst F, et al. The value of obturator canal bypass. A review. Arch Surg. 1994;129(7):718-722. 120. Brewster DC, Cambria RP, Darling RC, et al. Long-term results of combined iliac balloon angioplasty and distal surgi-cal revascularization. Ann Surg. 1989;210(3):324-330; discus-sion 331. 121. van den Akker PJ, van Schilfgaarde R, Brand R, van Bockel JH, Terpstra JL. Long term success of aortoiliac operation for arteriosclerotic obstructive disease. Surg Gynecol Obstet. 1992;174(6):485-496. 122. Insall RL, Loose HW, Chamberlain J. Long-term results of double-balloon percutaneous transluminal angioplasty of the aorta and iliac arteries. Eur J Vasc Surg. 1993;7(1):31-36. 123. Mendelsohn FO, Santos RM, Crowley JJ, et al. Kissing stents in the aortic bifurcation. Am Heart J. 1998;136(4 pt 1): 600-605. 124. Haulon S, Mounier-Vehier C, Gaxotte V, et al. Percutaneous reconstruction of the aortoiliac bifurcation with the “kiss-ing stents” technique: long-term follow-up in 106 patients.  J Endovasc Ther. 2002;9(3):363-368. 125. Sapoval MR, Long AL, Pagny JY, et al. Outcome of per-cutaneous intervention in iliac artery stents. Radiology. 1996;198(2):481-486. 126. Mousa AY, Beauford RB, Flores L, Faries PL, Patel P, Fogler R. Endovascular treatment of iliac occlusive disease: review and update. Vascular. 2007;15(1):5-11. 127. Psacharopulo D, Ferrero E, Ferri M, et al. Increasing efficacy of endovascular recanalization with covered stent graft for TransAtlantic Inter-Society Consensus II D aortoiliac complex occlusion. J Vasc Surg. 2015;62(5):1219-1226. 128. Bosiers M, Iyer V, Deloose K, Verbist J, Peeters P. Flemish experience using the Advanta V12 stent-graft for the treatment of iliac artery occlusive disease. J Cardiovasc Surg (Torino). 2007;48(1):7-12. 129. Szilagyi DE, Elliott JP Jr, Smith RF, Reddy DJ, McPharlin M. A thirty-year survey of the reconstructive surgical treatment of aortoiliac occlusive disease. J Vasc Surg. 1986;3(3):421-436. 130. Indes JE, Pfaff MJ, Farrokhyar F, et al. Clinical outcomes of 5358 patients undergoing direct open bypass or endovascular treatment for aortoiliac occlusive disease: a systematic review and meta-analysis. J Endovasc Ther. 2013;20(4):443-455. 131. Becker GJ, Cikrit DF, Lalka SG, et al. Early experience with the Palmaz stent in human iliac angioplasty. Indiana Med. 1989;82(4):286-292. 132. Tsetis D, Uberoi R. Quality improvement guidelines for endo-vascular treatment of iliac artery occlusive disease. Cardiovasc Intervent Radiol. 2008;31(2):238-245. 133. Powell RJ, Fillinger M, Bettmann M, et al. The durability of endovascular treatment of multisegment iliac occlusive dis-ease. J Vasc Surg. 2000;31(6):1178-1184. 134. Timaran CH, Stevens SL, Grandas OH, Freeman MB, Gold-man MH. Influence of hormone replacement therapy on the outcome of iliac angioplasty and stenting. J Vasc Surg. 2001;33(2 suppl):S85-S92. 135. Bosch JL, Hunink MG. Meta-analysis of the results of per-cutaneous transluminal angioplasty and stent placement for aortoiliac occlusive disease. Radiology. 1997;204(1):87-96. 136. Park KB, Do YS, Kim JH, et al. Stent placement for chronic iliac arterial occlusive disease: the results of 10 years experience in a single institution. Korean J Radiol. 2005;6(4):256-266. 137. Leville CD, Kashyap VS, Clair DG, et al. Endovascular man-agement of iliac artery occlusions: extending treatment to TransAtlantic Inter-Society Consensus class C and D patients. J Vasc Surg. 2006;43(1):32-39. 138. Tetteroo E, van der Graaf Y, Bosch JL, et al. Randomised com-parison of primary stent placement versus primary angioplasty followed by selective stent placement in patients with iliac-artery occlusive disease. Dutch Iliac Stent Trial Study Group. Lancet. 1998;351(9110):1153-1159. 139. McDaniel MD, Cronenwett JL. Basic data related to the natu-ral history of intermittent claudication. Ann Vasc Surg. 1989; 3(3):273-277. 140. Leng GC, Papacosta O, Whincup P, et al. Femoral atheroscle-rosis in an older British population: prevalence and risk fac-tors. Atherosclerosis. 2000;152(1):167-174. 141. Schroll M, Munck O. Estimation of peripheral arteriosclerotic disease by ankle blood pressure measurements in a population study of 60-year-old men and women. J Chronic Dis. 1981; 34(6):261-269. 142. Stoffers HE, Rinkens PE, Kester AD, Kaiser V, Knottnerus JA. The prevalence of asymptomatic and unrecognized periph-eral arterial occlusive disease. Int J Epidemiol. 1996;25(2): 282-290. 143. Koelemay MJ, den Hartog D, Prins MH, Kromhout JG,  Legemate DA, Jacobs MJ. Diagnosis of arterial disease of the lower extremities with duplex ultrasonography. Br J Surg. 1996; 83(3):404-409. 144. Bah F, Bhimji SS. Peripheral arterial disease. StatPearls. Trea-sure Island (FL); 2018. 145. Ouriel K. Current status of thrombolysis for peripheral arterial occlusive disease. Ann Vasc Surg. 2002;16(6):797-804. 146. Ouriel K. Comparison of surgical and thrombolytic treatment of peripheral arterial disease. Rev Cardiovasc Med. 2002; 3(suppl 2):S7-S16. 147. Mahe G, Jaquinandi V. Diagnosis of lower limb peripheral artery disease [in French]. Presse Med. 2018;47(1):47-55. 148. Conte MS, Belkin M, Upchurch GR, Mannick JA, Whittemore AD, Donaldson MC. Impact of increasing comorbidity on infrainguinal reconstruction: a 20-year perspective. Ann Surg. 2001;233(3):445-452. 149. Johnston KW. Femoral and popliteal arteries: reanalysis of results of balloon angioplasty. Radiology. 1992;183(3):767-771. 150. Kok HK, Asadi H, Sheehan M, McGrath FP, Given MF, Lee MJ. Outcomes of infrapopliteal angioplasty for limb salvage based on the updated TASC II classification. Diagn Interv Radiol. 2017;23(5):360-364. 151. Lofberg AM, Karacagil S, Ljungman C, et al. Percutaneous transluminal angioplasty of the femoropopliteal arteries in limbs with chronic critical lower limb ischemia. J Vasc Surg. 2001;34(1):114-121. 152. Hunink MG, Wong JB, Donaldson MC, Meyerovitz MF, Har-rington DP. Patency results of percutaneous and surgical revas-cularization for femoropopliteal arterial disease. Med Decis Making. 1994;14(1):71-81. 153. Varty K, Bolia A, Naylor AR, Bell PR, London NJ. Infrapopli-teal percutaneous transluminal angioplasty: a safe and success-ful procedure. Eur J Vasc Endovasc Surg. 1995;9(3):341-345. 154. Bolia A, Sayers RD, Thompson MM, Bell PR. Subinti-mal and intraluminal recanalisation of occluded crural Brunicardi_Ch23_p0897-p0980.indd 97827/02/19 4:15 PM 979ARTERIAL DISEASECHAPTER 23arteries by percutaneous balloon angioplasty. Eur J Vasc Surg. 1994;8(2):214-219. 155. Lipsitz EC, Ohki T, Veith FJ, et al. Does subintimal angio-plasty have a role in the treatment of severe lower extremity ischemia? J Vasc Surg. 2003;37(2):386-391. 156. Treiman GS, Whiting JH, Treiman RL, McNamara RM, Ashrafi A. Treatment of limb-threatening ischemia with percu-taneous intentional extraluminal recanalization: a preliminary evaluation. J Vasc Surg. 2003;38(1):29-35. 157. Ingle H, Nasim A, Bolia A, et al. Subintimal angioplasty of isolated infragenicular vessels in lower limb ischemia: long-term results. J Endovasc Ther. 2002;9(4):411-416. 158. Becquemin JP, Favre JP, Marzelle J, Nemoz C, Corsin C, Leizorovicz A. Systematic versus selective stent placement after superficial femoral artery balloon angioplasty: a mul-ticenter prospective randomized study. J Vasc Surg. 2003; 37(3):487-494. 159. Gray BH, Sullivan TM, Childs MB, Young JR, Olin JW. High incidence of restenosis/reocclusion of stents in the percutaneous treatment of long-segment superficial femo-ral artery disease after suboptimal angioplasty. J Vasc Surg. 1997;25(1):74-83. 160. Mewissen MW. Self-expanding nitinol stents in the femoro-popliteal segment: technique and mid-term results. Tech Vasc Interv Radiol. 2004;7(1):2-5. 161. Laird JR. Interventional options in SFA. Endovascular Today. 2004;(supp):9-12. 162. Ansel GM, Silver MJ, Botti CF Jr, et al. Functional and clini-cal outcomes of nitinol stenting with and without abciximab for complex superficial femoral artery disease: a randomized trial. Catheter Cardiovasc Interv. 2006;67(2):288-297. 163. Duda SH, Poerner TC, Wiesinger B, et al. Drug-eluting stents: potential applications for peripheral arterial occlusive disease. J Vasc Interv Radiol. 2003;14(3):291-301. 164. Feiring AJ, Krahn M, Nelson L, Wesolowski A, Eastwood D, Szabo A. Preventing leg amputations in critical limb ischemia with below-the-knee drug-eluting stents: the PaRADISE (PRe-venting Amputations using Drug eluting StEnts) trial. J Am Coll Cardiol. 2010;55(15):1580-1589. 165. Bauermeister G. Endovascular stent-grafting in the treatment of superficial femoral artery occlusive disease. J Endovasc Ther. 2001;8(3):315-320. 166. Kedora J, Hohmann S, Garrett W, Munschaur C, Theune B, Gable D. Randomized comparison of percutaneous Viabahn stent grafts vs prosthetic femoral-popliteal bypass in the treat-ment of superficial femoral arterial occlusive disease. J Vasc Surg. 2007;45(1):10-16; discussion 16. 167. McQuade K, Gable D, Pearl G, Theune B, Black S. Four-year randomized prospective comparison of percutaneous ePTFE/nitinol self-expanding stent graft versus prosthetic femoral-popliteal bypass in the treatment of superficial femoral artery occlusive disease. J Vasc Surg. 2010;52(3):584-590; discus-sion 590-581, 591 e581-591 e587. 168. Ramaiah V, Gammon R, Kiesz S, et al. Midterm outcomes from the TALON Registry: treating peripherals with SilverHawk: outcomes collection. J Endovasc Ther. 2006;13(5):592-602. 169. Franzone A, Ferrone M, Carotenuto G, et al. The role of ather-ectomy in the treatment of lower extremity peripheral artery disease. BMC Surg. 2012;12(suppl 1):S13. 170. Scheinert D, Laird JR Jr, Schroder M, Steinkamp H, Balzer JO, Biamino G. Excimer laser-assisted recanalization of long, chronic superficial femoral artery occlusions. J Endovasc Ther. 2001;8(2):156-166. 171. Steinkamp HJ, Rademaker J, Wissgott C, et al. Percutane-ous transluminal laser angioplasty versus balloon dilation for treatment of popliteal artery occlusions. J Endovasc Ther. 2002;9(6):882-888. 172. Laird JR, Reiser C, Biamino G, Zeller T. Excimer laser assisted angioplasty for the treatment of critical limb ischemia. J Car-diovasc Surg (Torino). 2004;45(3):239-248. 173. Dave RM, Patlola R, Kollmeyer K, et al. Excimer laser recana-lization of femoropopliteal lesions and 1-year patency: results of the CELLO registry. J Endovasc Ther. 2009;16(6):665-675. 174. Clark TW, Groffsky JL, Soulen MC. Predictors of long-term patency after femoropopliteal angioplasty: results from the STAR registry. J Vasc Interv Radiol. 2001;12(8):923-933. 175. Axisa B, Fishwick G, Bolia A, et al. Complications follow-ing peripheral angioplasty. Ann R Coll Surg Engl. 2002;84(1): 39-42. 176. Yilmaz S, Sindel T, Yegin A, Luleci E. Subintimal angioplasty of long superficial femoral artery occlusions. J Vasc Interv Radiol. 2003;14(8):997-1010. 177. Desgranges P, Boufi M, Lapeyre M, et al. Subintimal angio-plasty: feasible and durable. Eur J Vasc Endovasc Surg. 2004; 28(2):138-141. 178. Fava M, Loyola S, Polydorou A, Papapavlou P, Mendiz O, Joye JD. Cryoplasty for femoropopliteal arterial disease: late angiographic results of initial human experience. J Vasc Interv Radiol. 2004;15(11):1239-1243. 179. Jahnke T, Andresen R, Muller-Hulsbeck S, et al. Hemobahn stent-grafts for treatment of femoropopliteal arterial obstruc-tions: midterm results of a prospective trial. J Vasc Interv Radiol. 2003;14(1):41-51. 180. Grubnic S, Heenan SD, Buckenham TM, Belli AM. Evalu-ation of the pullback atherectomy catheter in the treatment of lower limb vascular disease. Cardiovasc Intervent Radiol. 1996;19(3):152-159. 181. Savader SJ, Venbrux AC, Mitchell SE, et al. Percutaneous transluminal atherectomy of the superficial femoral and pop-liteal arteries: long-term results in 48 patients. Cardiovasc Intervent Radiol. 1994;17(6):312-318. 182. Albers M, Battistella VM, Romiti M, Rodrigues AA, Pereira CA. Meta-analysis of polytetrafluoroethylene bypass grafts to infrapopliteal arteries. J Vasc Surg. 2003;37(6):1263-1269. 183. Hamsho A, Nott D, Harris PL. Prospective randomised trial of distal arteriovenous fistula as an adjunct to femoro-infrap-opliteal PTFE bypass. Eur J Vasc Endovasc Surg. 1999;17(3): 197-201. 184. Davies AH, Hawdon AJ, Sydes MR, Thompson SG. Is duplex surveillance of value after leg vein bypass grafting? Princi-pal results of the Vein Graft Surveillance Randomised Trial (VGST). Circulation. 2005;112(13):1985-1991. 185. Baldwin ZK, Pearce BJ, Curi MA, et al. Limb salvage after infrainguinal bypass graft failure. J Vasc Surg. 2004;39(5): 951-957. 186. Stone PA, Flaherty SK, Aburahma AF, et al. Factors affect-ing perioperative mortality and wound-related complications following major lower extremity amputations. Ann Vasc Surg. 2006;20(2):209-216. 187. Holzenbein TJ, Pomposelli FB Jr, Miller A, et al. The upper arm basilic-cephalic loop for distal bypass grafting: techni-cal considerations and follow-up. J Vasc Surg. 1995;21(4): 586-592; discussion 592-594. 188. Dardik H, Wengerter K, Qin F, et al. Comparative decades of experience with glutaraldehyde-tanned human umbilical cord vein graft for lower limb revascularization: an analysis of 1275 cases. J Vasc Surg. 2002;35(1):64-71. 189. Johnson WC, Lee KK. A comparative evaluation of polytet-rafluoroethylene, umbilical vein, and saphenous vein bypass grafts for femoral-popliteal above-knee revascularization: a prospective randomized Department of Veterans Affairs coop-erative study. J Vasc Surg. 2000;32(2):268-277. 190. Fahner PJ, Idu MM, van Gulik TM, Legemate DA. Sys-tematic review of preservation methods and clinical Brunicardi_Ch23_p0897-p0980.indd 97927/02/19 4:15 PM 980SPECIFIC CONSIDERATIONSPART IIoutcome of infrainguinal vascular allografts. J Vasc Surg. 2006;44(3):518-524. 191. Gupta SK, Veith FJ, Kram HB, Wengerter KR. Prospective, randomized comparison of ringed and nonringed polytetra-fluoroethylene femoropopliteal bypass grafts: a preliminary report. J Vasc Surg. 1991;13(1):163-172. 192. Stonebridge PA, Prescott RJ, Ruckley CV. Randomized trial comparing infrainguinal polytetrafluoroethylene bypass graft-ing with and without vein interposition cuff at the distal anas-tomosis. The Joint Vascular Research Group. J Vasc Surg. 1997;26(4):543-550. 193. Klinkert P, van Dijk PJ, Breslau PJ. Polytetrafluoroethylene femorotibial bypass grafting: 5-year patency and limb salvage. Ann Vasc Surg. 2003;17(5):486-491. 194. Panneton JM, Hollier LH, Hofer JM. Multicenter randomized prospective trial comparing a pre-cuffed polytetrafluoroethyl-ene graft to a vein cuffed polytetrafluoroethylene graft for infra-genicular arterial bypass. Ann Vasc Surg. 2004;18(2):199-206. 195. Bellosta R, Luzzani L, Carugati C, Melloni C, Sarcina A. Which distal anastomosis should be used in PTFE femoro-tibial bypass? J Cardiovasc Surg (Torino). 2005;46(5):499-503. 196. Begovac PC, Thomson RC, Fisher JL, Hughson A, Gallhagen A. Improvements in GORE-TEX vascular graft performance by Carmeda BioActive surface heparin immobilization. Eur J Vasc Endovasc Surg. 2003;25(5):432-437. 197. Devine C, Hons B, McCollum C. Heparin-bonded Dacron or polytetrafluoroethylene for femoropopliteal bypass grafting: a multicenter trial. J Vasc Surg. 2001;33(3):533-539. 198. Walluscheck KP, Bierkandt S, Brandt M, Cremer J. Infrain-guinal ePTFE vascular graft with bioactive surface heparin bonding. First clinical results. J Cardiovasc Surg (Torino). 2005;46(4):425-430. 199. Hunink MG, Donaldson MC, Meyerovitz MF, et al. Risks and benefits of femoropopliteal percutaneous balloon angioplasty. J Vasc Surg. 1993;17(1):183-192; discussion 192-194. 200. Dua A, Koprowski S, Upchurch G, Lee CJ, Desai SS. Pro-gressive shortfall in open aneurysm experience for vascular surgery trainees with the impact of fenestrated and branched endovascular technology. J Vasc Surg. 2017;65(1):257-261. 201. Ferreira M, Lanziotti L, Monteiro M, et al. Superficial femo-ral artery recanalization with self-expanding nitinol stents: long-term follow-up results. Eur J Vasc Endovasc Surg. 2007; 34(6):702-708. 202. Schillinger M, Sabeti S, Dick P, et al. Sustained benefit at 2 years of primary femoropopliteal stenting compared with balloon angioplasty with optional stenting. Circulation. 2007;115(21):2745-2749. 203. Bosiers M, Deloose K, Verbist J, Peeters P. Nitinol stenting for treatment of “below-the-knee” critical limb ischemia: 1-year angiographic outcome after Xpert stent implantation. J Car-diovasc Surg (Torino). 2007;48(4):455-461. 204. Kickuth R, Keo HH, Triller J, Ludwig K, Do DD. Initial clinical experience with the 4-F self-expanding XPERT stent system for infrapopliteal treatment of patients with severe claudication and critical limb ischemia. J Vasc Interv Radiol. 2007;18(6):703-708. 205. Wolf GL, Wilson SE, Cross AP, Deupree RH, Stason WB. Sur-gery or balloon angioplasty for peripheral vascular disease: a randomized clinical trial. Principal investigators and their Associates of Veterans Administration Cooperative Study Number 199. J Vasc Interv Radiol. 1993;4(5):639-648. 206. Adam DJ, Beard JD, Cleveland T, et al. Bypass versus angio-plasty in severe ischaemia of the leg (BASIL): multicentre, ran-domised controlled trial. Lancet. 2005;366(9501):1925-1934. 207. Nolan B, Finlayson S, Tosteson A, Powell R, Cronenwett J. The treatment of disabling intermittent claudication in patients with superficial femoral artery occlusive disease--decision analysis. J Vasc Surg. 2007;45(6):1179-1184. 208. Maffei S, Di Renzo M, Bova G, Auteri A, Pasqui AL. Takayasu’s arteritis: a review of the literature. Intern Emerg Med. 2006;1(2):105-112. 209. Baxter BT. Heritable diseases of the blood vessels. Cardiovasc Pathol. 2005;14(4):185-188. 210. Cikrit DF, Glover JR, Dalsing MC, Silver D. The Ehlers-Danlos specter revisited. Vasc Endovascular Surg. 2002; 36(3):213-217. 211. Ho NC, Tran JR, Bektas A. Marfan’s syndrome. Lancet. 2005;366(9501):1978-1981. 212. Davies JE, Sundt TM. Surgery insight: the dilated ascending aorta—indications for surgical intervention. Nat Clin Pract Cardiovasc Med. 2007;4(6):330-339. 213. London NJ, Srinivasan R, Naylor AR, et al. Subintimal angio-plasty of femoropopliteal artery occlusions: the long-term results. Eur J Vasc Surg. 1994;8(2):148-155. 214. Chassaing N, Martin L, Calvas P, Le Bert M, Hovnanian A. Pseudoxanthoma elasticum: a clinical, pathophysiological and genetic update including 11 novel ABCC6 mutations. J Med Genet. 2005;42(12):881-892. 215. Yeung RS. Pathogenesis and treatment of Kawasaki’s disease. Curr Opin Rheumatol. 2005;17(5):617-623. 216. Greco A, De Virgilio A, Ralli M, et al. Behcet’s disease: new insights into pathophysiology, clinical features and treatment options. Autoimmun Rev. 2018;17(6):567-575. 217. Uygunoglu U, Siva A. Behcet’s syndrome and nervous system involvement. Curr Neurol Neurosci Rep. 2018;18(7):35. 218. Muhammad JS, Ishaq M, Ahmed K. Genetics and epigenetics pathogenesis of Behcet’s syndrome. Curr Rheumatol Rev. 2018. 219. Stanton M, Bhimji SS. Polyarteritis nodosa. StatPearls. Trea-sure Island (FL); 2018. 220. Temprano KK. A review of Raynaud’s disease. Mo Med. 2016; 113(2):123-126. 221. Hinojosa CA, Anaya-Ayala JE, Bermudez-Serrato K, et al. Surgical interventions for organ and limb ischemia associ-ated with primary and secondary antiphospholipid antibody syndrome with arterial involvement. Vasc Endovascular Surg. 2017;51(8):550-554. 222. Narula N, Kadian-Dodov D, Olin JW. Fibromuscular dyspla-sia: contemporary concepts and future directions. Prog Car-diovasc Dis. 2018;60(6):580-585. 223. Baradhi KM, Bream P. Fibromuscular dysplasia. StatPearls. Treasure Island (FL); 2018. 224. Li S, King BN, Velasco N, Kumar Y, Gupta N. Cystic adven-titial disease-case series and review of literature. Ann Transl Med. 2017;5(16):327. 225. Lejay A, Ohana M, Lee JT, et al. Popliteal artery entrapment syndrome. J Cardiovasc Surg (Torino). 2014;55(2 suppl 1): 225-237. 226. Gokkus K, Sagtas E, Bakalim T, Taskaya E, Aydin AT. Pop-liteal entrapment syndrome. A systematic review of the lit-erature and case presentation. Muscles Ligaments Tendons J. 2014;4(2):141-148. 227. Rivera-Chavarria IJ, Brenes-Gutierrez JD. Thromboangiitis obliterans (Buerger’s disease). Ann Med Surg (Lond). 2016; 7:79-82. 228. Sugimoto M, Miyachi H, Morimae H, et al. Fate of ischemic limbs in patients with Buerger’s disease based on our 30-year experience: does smoking have a definitive impact on the late loss of limbs? Surg Today. 2015;45(4):466-470. 229. Mills JL Sr. Buerger’s disease in the 21st century: diagnosis, clinical features, and therapy. Semin Vasc Surg. 2003;16(3): 179-189.Brunicardi_Ch23_p0897-p0980.indd 98027/02/19 4:15 PM
Venous and Lymphatic DiseaseAtish Chopra, Timothy K. Liem, and Gregory L. Moneta 24chapterVENOUS ANATOMYVeins are part of a dynamic and complex system that returns low-nutrient deoxygenated blood to the heart. Venous blood flow is dependent on multiple factors such as gravity, venous valves, the cardiac and respiratory cycles, blood volume, and the calf muscle and feet pumps. Alterations in the intricate balance of these factors can result in venous pathology.Structure of VeinsVeins are thin-walled, highly distensible, and collapsible. Their structure specifically supports the primary functions of veins to transport blood toward the heart and serve as a reservoir to prevent intravascular volume overload.The venous intima is composed of a nonthrombogenic endothelium with an underlying basement membrane and an elastic lamina. The endothelium produces endothelium-derived relaxing factors such as nitric oxide and prostacy-clin, which help maintain a nonthrombogenic surface through inhibition of platelet aggregation and promotion of platelet disaggregation.1 The capacitance function of veins is facili-tated by circumferential rings of elastic tissue, and smooth muscle located in the media of the vein allows for changes in vein caliber with minimal changes in venous pressure. The adventitia is most prominent in large veins and consists of collagen, elastic fibers, and fibroblasts. When a vein is maxi-mally distended, its diameter may be several times greater than that in the supine position.In the axial veins, unidirectional blood flow is achieved with multiple venous valves. The inferior vena cava (IVC), common iliac veins, portal venous system, and cranial sinuses are valveless. In the axial veins, valves are more numerous distally in the extremities than proximally. Each valve consists of two thin cusps of a fine connective tissue skeleton covered by endothelium. Venous valves close in response to cephalad-to-caudal blood flow at a velocity of at least 30 cm/s.2Lower Extremity VeinsLower extremity veins are divided into superficial, deep, and perforating veins. The superficial venous system lies above the uppermost fascial layer of the leg and thigh and consists of the great saphenous vein (GSV) and small saphenous vein (SSV) and their tributaries. The GSV originates from the dorsal pedal venous arch and courses cephalad and medially, anterior to the medial malleolus, entering the common femoral vein approxi-mately 4 cm inferior and lateral to the pubic tubercle. The saphe-nous nerve accompanies the GSV medially from the ankle to the level of the knee and supplies cutaneous sensation to the medial leg and ankle. The SSV originates laterally from the dorsal pedal venous arch and courses cephalad in the posterior calf. Most often, it penetrates the popliteal fossa, between the medial and lateral heads of the gastrocnemius muscle, to join the popliteal vein. The termination of the SSV may be quite vari-able, however, with a proximal extension of the SSV (the vein of Giacomini) connecting with the deep femoral vein or GSV. The sural nerve accompanies the SSV laterally along its course and supplies cutaneous sensation to the lateral malleolar region.The deep veins follow the course of major arteries in the extremities. In the lower leg, paired veins parallel the course of the anterior tibial, posterior tibial, and peroneal arteries, to join behind the knee forming the popliteal vein. Venous bridges con-nect the paired axial tibial veins in the lower leg. The popliteal vein continues through the adductor hiatus to become the femo-ral vein. In the proximal thigh, the femoral vein joins with the deep femoral vein to form the common femoral vein, becoming the external iliac vein at the inguinal ligament.Multiple perforator veins traverse the deep fascia to connect the superficial and deep venous systems. Potentially clinically important perforator veins are the posterior tibial and paratibial perforators (formerly known as the Cockett and Boyd perforators, respectively). The posterior tibial perforator veins drain the medial lower leg and are relatively constant. They Venous Anatomy981Structure of Veins / 981Lower Extremity Veins / 981Upper Extremity Veins / 982Evaluation of the Venous System982Clinical Evaluation / 982Venous Thromboembolism984Epidemiology / 984Risk Factors / 984Diagnosis / 986Treatment / 987Prophylaxis / 992Other Venous Thrombotic Disorders994Superficial Vein Thrombophlebitis / 994Upper Extremity Vein Thrombosis / 995Mesenteric Vein Thrombosis / 996Varicose Veins996Chronic Venous Insufficiency997Evaluation of Venous Insufficiency / 997Lymphedema1001Pathophysiology / 1001Clinical Diagnosis / 1001Radiologic Diagnosis / 1002Management / 1002Summary1003Brunicardi_Ch24_p0981-p1008.indd 98122/02/19 3:00 PM 982connect the posterior accessory GSV (formerly known as the posterior arch vein, a tributary to the GSV) and the posterior tibial vein. They may become varicose or incompetent in venous insufficiency states. The posterior accessory GSV has relevance as it represents a connection of the three ankle perforating veins, which are likely of particular importance in the development of a venous stasis ulcers. The paratibial perforator veins connect the GSV to the deep veins approximately 10 cm below the knee and 1 to 2 cm medial to the tibia. Additional perforators in the thigh are known as the perforators of the femoral canal (also known as Hunter’s and Dodd’s perforators).Venous sinuses are thin-walled, large veins located within the substance of the soleus and gastrocnemius muscles. These sinuses are valveless and are linked by valved, small venous channels that prevent reflux. A large amount of blood can be stored in the venous sinuses before draining into the posterior tibial and peroneal veins. With each contraction of the calf muscle bed, blood is pumped out through the venous channels into the main conduit veins to return to the heart.Upper Extremity VeinsAs in the lower extremity, there are deep and superficial veins in the upper extremity. Deep digital veins form the palmar venous arches of the hand and empty into the paired radial and ulnar veins. These follow the named arteries in the arm and are known as the venae comitantes. They become the brachial veins most often near the antecubital fossa and then combine to contrib-ute to forming the axillary vein. Superficial veins of the upper extremity are the cephalic and basilic veins and their tributaries. The cephalic vein originates at the lateral wrist and courses over the lateral ventral surface of the forearm. In the upper arm, the cephalic vein terminates in the infraclavicular fossa, piercing the clavipectoral fascia to empty into the axillary vein. The basilic vein runs medially along the forearm and penetrates the deep fascia as it courses past the elbow in the upper arm. It then joins with the deep brachial veins to become the axil-lary vein, a landmark for identification of the axillary vein. The median antecubital vein joins the cephalic and the basilic veins on the ventral surface of the elbow.The axillary vein becomes the subclavian vein at the lat-eral border of the first rib. At the medial border of the scalenus anterior muscle, the subclavian vein joins with the internal jugu-lar vein to become the brachiocephalic vein, with the subclavian vein coursing anterior to the scalenus anterior muscle. The left and right brachiocephalic veins join to become the superior vena cava, which empties into the right atrium.EVALUATION OF THE VENOUS SYSTEMClinical EvaluationEvaluation of the venous system begins with a detailed history and physical examination. Risk factors for acute and chronic venous disease are identified. They include increased age, his-tory of venous thromboembolism (VTE), malignancy, trauma and spinal cord injury, hospitalization and immobilization, obe-sity, nephrotic syndrome, pregnancy, recent postpartum state, oral contraceptive use or hormone replacement therapy, vari-cose veins, and hypercoagulable states, as well as the postopera-tive state. Venous pathology is often, but not always, associated with visible or palpable signs that can be identified during the physical examination. There is variation among individuals in the prominence of superficial veins when the person is standing (Fig. 24-1). The superficial veins of a lean athletic person, even when normal, will appear large and easily visualized, but these veins will be far less obvious in the obese individual. Signs of superficial venous abnormalities are listed in Table 24-1. Key Points1 Thrombolytic therapy, surgical thrombectomy, and place-ment of inferior vena cava filters are adjunctive treatments that may be indicated in patients with extensive and compli-cated venous thromboembolism.2 Deep vein thrombosis (DVT) and pulmonary embolism are well-recognized complications after major abdominal and orthopedic procedures. The risk is further increased in patients with malignancy and a history of venous thrombo-embolism. Options for DVT prophylaxis include intermit-tent pneumatic compression, use of graduated compression stockings, and administration of low-dose unfractionated heparin, low molecular weight heparin, fondaparinux, and vitamin K antagonists. Direct thrombin inhibitors and factor Xa inhibitors are approved for prophylactic use only for orthopedic procedures and for recurrent VTE. However, prophylaxis should be stratified based on the patient’s level of risk.3 In patients with established DVT, unfractionated heparin, low molecular weight heparin, fondaparinux, and some factor Xa inhibitors are options for initial antithrombotic therapy. Vitamin-K antagonists, direct thrombin inhibitors, and factor Xa inhibitors are utilized for long-term anticoagulation. The duration and type of long-term anticoagulation should be stratified based on the provoked or unprovoked nature of the DVT, the location of the DVT, previous occurrence of DVT, and presence of concomitant malignancy.4 High ligation and stripping, endovenous laser, or radiofre-quency ablation and sclerotherapy are effective therapies for patients with saphenous vein valvular insufficiency. Con-comitant varicose veins may be managed with compression therapy, sclerotherapy, and phlebectomy. New nonthermal ablative techniques, including the combination of sclero-therapy with endoluminal mechanical injury as well as injec-tion of cyanoacrylate, show early promising results.5 The mainstay of treatment for chronic venous insufficiency is compression therapy. Sclerotherapy, perforator vein liga-tion, and venous reconstruction or ablative techniques may be indicated in patients in whom conservative management fails or as a means to decrease ulcer recurrence.6 Lymphedema is categorized as congenital, primary (with early or delayed onset), or secondary. The goals of treatment are to minimize edema and prevent infection. Lymphatic massage, sequential pneumatic compression, use of com-pression garments, and limb elevation are effective forms of therapy.Brunicardi_Ch24_p0981-p1008.indd 98222/02/19 3:00 PM 983VENOUS AND LYMPHATIC DISEASECHAPTER 24Figure 24-1. Varicose vein demonstrating evidence of chronic venous insufficiency.Figure 24-2. Characteristic hyperpigmentation of chronic venous insufficiency.Table 24-1Possible signs of superficial venous abnormalitiesTortuosityVaricosityVenous sacculeDistended subdermal venules (corona phlebectatica)Distended intradermal venules (spider angiomata)Warmth, erythema, tenderness (superficial thrombophlebitis)The deep veins cannot be directly assessed clinically, and abnormalities within them can only be inferred indirectly from changes found on clinical examination.Chronic venous insufficiency (CVI) may lead to character-istic changes in the skin and subcutaneous tissues in the affected limb. CVI results from incompetence of venous valves, venous obstruction, or both. Most CVI involves venous reflux, and severe CVI often reflects a combination of reflux and venous obstruction. It is important to remember that although CVI originates with abnormalities of the veins, the target organ of CVI is the skin, and the underlying physiologic and biochemical mechanisms leading to the cutaneous abnormalities associated with CVI are poorly understood. A typical leg affected by CVI will be edematous, with edema increasing over the course of the day. The leg may also be indurated and pigmented with eczema and dermatitis. These changes are associated with excessive proteinaceous capillary exudate. Deposition of a pericapil-lary fibrin cuff may limit nutritional exchange. In addition, an increase in white blood cell trapping within the skin microcir-culation in CVI patients may lead to microvascular congestion and thrombosis. Subsequently, white blood cells may migrate into the interstitium and release necrotizing lysosomal enzymes, potentially leading to tissue destruction and eventual ulceration.Fibrosis can eventually develop from impaired nutrition, chronic inflammation, and fat necrosis (lipodermatosclerosis). Hemosiderin deposition due to the extravasation of red cells and subsequent lysis in the skin contributes to the characteristic pigmentation of chronic venous disease (Fig. 24-2). Ulceration can develop with longstanding venous hypertension and is associated with alterations in microcirculatory and cutaneous lymphatic anatomy and function. The most common location of venous ulceration is approximately 3 cm proximal to the medial malleolus, frequently referred to the “gaiter” region (Fig. 24-3).Trendelenburg’s test is a clinical test, historically impor-tant but now rarely used, that can help determine whether incompetent valves are present and in which of the three venous systems (superficial, deep, or perforator) the valves are abnormal. There are two components to this test. First, with the patient supine, the leg is elevated 45° to empty the veins, and the GSV is occluded with the examiner’s hand or with a rub-ber tourniquet. Then, with the GSV still occluded, the patient stands, and the superficial veins are observed for blood filling. The compression on the GSV is released, and the superficial veins are observed for filling with blood. A positive result is the sudden filling of veins with standing while the GSV remains occluded, indicating incompetent perforator and deep veins. Additionally, the GSV valves are incompetent if rapid filling is noted following release of compression. A negative result, indicating no clinically relevant venous reflux, is the gradual filling of the veins from arterial inflow. Interpretation of the findings of Trendelenburg’s test is subjective, and therefore, it has largely been supplanted by the more objective noninvasive vascular laboratory tests to localize sites of venous reflux.Noninvasive Evaluation. Before the development of vascu-lar ultrasound, noninvasive techniques to evaluate the venous system were based on plethysmographic techniques. Although a variety of plethysmographic techniques are used in the Brunicardi_Ch24_p0981-p1008.indd 98322/02/19 3:01 PM 984SPECIFIC CONSIDERATIONSPART IIFigure 24-3. Venous ulceration located proximal to the medial malleolus.evaluation of both acute and chronic venous disease, they are all based on the detection of volume changes in the limb in response to blood flow.Duplex ultrasonography (DUS) augmented by color flow imaging is now the most important noninvasive diagnos-tic method in the evaluation of the venous system. DUS has become standard for the detection of infrainguinal deep vein thrombosis (DVT), with near 100% sensitivity and specificity in symptomatic patients.3 It is also the preferred method of evalu-ation for upper extremity venous thrombosis and is useful in the evaluation of CVI by documenting the presence of valvular reflux and venous obstruction. Overlying bowel gas and large body habitus many times make DUS less applicable to evalu-ation of intra-abdominal veins. Magnetic resonance venogra-phy (MRV) and computed tomography (CT) venography are alternative noninvasive techniques for evaluation of pelvic and intra-abdominal veins.Invasive Evaluation. Improved accuracy of noninvasive techniques for diagnostic purposes has made the use of invasive procedures more selective. Both venography and intravascular ultrasound (IVUS) are used as adjuncts to percutaneous or open surgical treatment of venous disorders. When planning endo-vascular or open surgical treatment, venography may be used to identify areas of obstruction in infrainguinal, intra-abdominal, and upper extremity veins as well as reflux in intra-abdominal and infrainguinal veins. IVUS, with access generally via the common femoral vein, is used primarily to assess for occlusive lesions of the iliac veins and appears more sensitive than venog-raphy in detecting iliac vein obstruction.4Complications of venography include pain, thrombosis, or hematoma at the puncture site. Pain is lower with nonionic low-osmolality contrast media than with conventional contrast agents (with 18% vs. 44% of patients experiencing discomfort, respectively).5 Systemic effects of iodinated contrast media include allergic reaction and risk of renal failure. Postvenogra-phy venous thrombosis occurs distal to the venous puncture site in 1% to 9% of patients undergoing venography secondary to intimal damage from the intravenous (IV) contrast agent.5 Com-plications and limitations of IVUS are related to complications at the access site and cost of the catheters.VENOUS THROMBOEMBOLISMEpidemiologyDespite increased awareness and use of prophylactic modalities, DVT or pulmonary embolism (PE), venous thromboembolism (VTE), remain important preventable sources of morbidity and mortality, especially in the surgical patient. The incidence of VTE is approximately 100 per 100,000 people per year in the general population, with 20% of the diagnoses made within 3 months of a surgical procedure. Of the symptomatic patients, one-third will present with PE and two-thirds with DVT.6,7 The estimated number of cases of VTE may well be over 600,000 per year in the United States, making it a major U.S. health problem.8 Furthermore, death occurs in 6% of DVT and 12% of PE cases within 1 month of diagnosis, although not all deaths are directly secondary to VTE, with many related to the under-lying problem leading to the VTE event.6 However, not only does VTE pose a veritable threat to life, it also places patients at higher risk for recurrence and post-VTE sequelae such as pul-monary hypertension and postthrombotic syndrome, with 4% and up to 30% incidence, respectively.9-11Risk FactorsThree broadly stated conditions, first described by Rudolf Vir-chow in 1862, contribute to VTE formation: stasis of blood flow, endothelial damage, and hypercoagulability. Of these risk factors, relative hypercoagulability appears most impor-tant in cases of spontaneous VTE, or so-called idiopathic VTE, whereas stasis and endothelial damage likely play a greater role in secondary VTE, or so-called provoked VTE, occurring in association with transient risk factors such as immobiliza-tion, surgical procedures, and trauma. Identifiable risk factors for VTE generally relate to one of the conditions described by Virchow. Often more than one risk factor is present contribut-ing in an exponential, rather than additive, manner. Specific risk factors for VTE are listed in Table 24-2.The more common acquired VTE risk factors include older age (>40 years), hospitalization and immobilization, hor-mone replacement and oral contraceptive therapy, pregnancy and the recently postpartum state, prior VTE, malignancy, major surgery, obesity, nephrotic syndrome, trauma and spinal cord injury, long-haul travel (>6 hours), varicose veins, antiphospho-lipid syndrome, myeloproliferative disorders, and polycythemia. Heritable risk factors include male sex, factor V Leiden muta-tion; prothrombin 20210A gene variant; antithrombin, protein C, and protein S deficiencies; and dysfibrinogenemias. In some patients, the cause of the thrombophilia may have both a heri-table and an acquired component. These mixed causes include homocysteinemia; factors VII, VIII, IX, and XI elevation; hyperfibrinogenemia; and activated protein C resistance in the Brunicardi_Ch24_p0981-p1008.indd 98422/02/19 3:01 PM 985VENOUS AND LYMPHATIC DISEASECHAPTER 24Table 24-2Risk factors for venous thromboembolismAcquiredAdvanced ageHospitalization/immobilizationHormone replacement therapy and oral contraceptive usePregnancy and puerperiumPrior venous thromboembolismMalignancyMajor surgeryObesityNephrotic syndromeTrauma or spinal cord injuryLong-haul travel (>6 hours)Varicose veinsAntiphospholipid antibody syndromeMyeloproliferative diseasePolycythemiaInheritedFactor V LeidenProthrombin 20210AAntithrombin deficiencyProtein C deficiencyProtein S deficiencyFactor XI elevationDysfibrinogenemiaMixed EtiologyHomocysteinemiaFactors VII, VIII, IX, XI elevationHyperfibrinogenemiaActivated protein C resistance without factor V Leidenabsence of factor V Leiden.12 There may be a synergistic effect when particular multiple inherited and acquired risk factors are present in the same patient.Other patient-specific factors associated with venous thrombosis include the traditional cardiovascular risk factors of obesity, hypertension, and diabetes. VTE is more common in whites and African Americans than Asians and Native Americans.13,14 Certain gene variants (single nucleotide polymorphisms) are also associated with a mildly increased risk for VTE, and their presence may interact with other risk factors to increase the overall risk for venous thrombosis.15Anatomic factors may also contribute to development of DVT. At the site where the right iliac artery crosses over the left iliac vein, the left iliac vein may become chronically compressed predisposing to iliofemoral venous thrombosis, so-called May-Thurner syndrome. External compression of major veins by masses of various types can also lead to venous thrombosis.Many cases of VTE are potentially preventable. Accord-ingly, in current clinical practice, preoperative VTE risk assess-ment is becoming increasingly common to identify patients at moderate and high risk. Scoring systems have been developed that take into account the number of VTE risk factors in an individual patient. These risk stratification scores, such as the Rogers score16 and Caprini score,17 provide individual patient risk stratification and recommendations for prophylactic anti-coagulation. The ninth edition of the American College of Chest Physicians (ACCP) Guidelines for Prevention of VTE in Non-Orthopedic Surgical Patients acknowledges both the Rogers and Caprini scores and provides recommendations for VTE prophylaxis (Table 24-3). Orthopedic surgical patients are generally excluded from risk assessment scores because of the disproportionately increased risk of VTE in orthopedic surgery compared with the general and abdominopelvic surgery population.Table 24-3Thromboembolism risk and recommended thromboprophylaxis in surgical patientsLEVEL OF RISKAPPROXIMATE DVT RISK WITHOUT THROMBOPROPHYLAXIS (%)SUGGESTED THROMBOPROPHYLAXIS OPTIONSVery low risk General or abdominopelvic surgery<0.5% (Rogers score <7; Caprini score 0)No specific thromboprophylaxisEarly ambulationLow risk General or abdominopelvic surgery∼1.5% (Rogers score 7–10; Caprini score 1–2)Mechanical prophylaxisModerate risk General or abdominopelvic surgery∼3.0% (Rogers score >10; Caprini score 3–4)LMWH (at recommended doses), LDUH, or mechanical prophylaxisHigh bleeding risk Mechanical prophylaxisHigh risk General or abdominopelvic surgery∼6% (Caprini score ≥5)LMWH (at recommended doses), fondaparinux and mechanical prophylaxisHigh bleeding risk General or abdominopelvic surgery for cancer Mechanical thromboprophylaxisExtended-duration LMWH (4 weeks)DVT = deep vein thrombosis; INR = international normalized ratio; LDUH = low-dose unfractionated heparin; LMWH = low molecular weight heparin; VTE = venous thromboembolism.Data from Gould MK, Garcia DA, Wren SM, et al: Prevention of VTE in nonorthopedic surgical patients: Antithrombotic Therapy and Prevention of Thrombosis, 9th ed: American College of Chest Physicians Evidence-Based Clinical Practice Guidelines, Chest. 2012 Feb;141(2 Suppl):e227S-e277S.Brunicardi_Ch24_p0981-p1008.indd 98522/02/19 3:01 PM 986SPECIFIC CONSIDERATIONSPART IIFigure 24-4. Phlegmasia cerulea dolens of the left leg. Note the bluish discoloration.Figure 24-5. Duplex ultrasound scan of a normal femoral vein with phasic flow signals.DiagnosisClinical Evaluation. Early in the course of DVT development, venous thrombosis is thought to begin in an area of relative stasis, such as a soleal sinus vein or immediately downstream of the cusps of a venous valve in an axial calf vein. Isolated proxi-mal DVT without tibial vein thrombosis is unusual. Early in the course of a DVT, there may be no or few clinical findings such as pain or swelling. Even extensive DVT may sometimes be present without signs or symptoms if the patient is nonambula-tory or bedbound. History and physical examination are notori-ously unreliable in the diagnosis of DVT. In addition, symptoms and signs often associated with DVT, such as extremity pain and/or swelling, are nonspecific. In large studies, DVT has been found by venography or DUS in ≤50% of patients in whom it was clinically suspected.18,19 Objective studies are therefore required to confirm a diagnosis of VTE or to exclude the pres-ence of VTE.Clinical symptoms may worsen as DVT propagates and involves the major proximal deep veins. Extensive DVT of the major axial deep venous channels of the lower extremity with rel-ative sparing of collateral veins causes a condition called phleg-masia cerulea dolens (Fig. 24-4). This condition is characterized by pain and pitting edema with associated cyanosis. When the thrombosis extends to the collateral veins, massive fluid seques-tration and more significant edema ensue, resulting in a condition known as phlegmasia alba dolens.20 The affected extremity in phlegmasia alba dolens is extremely painful and edematous and pale secondary to arterial insufficiency from dramatically ele-vated below lower knee compartment pressures. Both phlegmasia cerulean dolens and phlegmasia alba dolens can be complicated by venous gangrene and the need for amputation.Vascular Lab and Radiologic Evaluation Duplex Ultrasound DUS is now the most commonly per-formed test for the detection of infrainguinal DVT, both above and below the knee, and has a sensitivity and specificity of >95% in symptomatic patients.3 DUS refers to the combina-tion of real-time B-mode ultrasound with compression and flow augmentation amneuvres combined with pulsed Doppler capa-bility. For VTE detection, color flow imaging is an additional extremely useful adjunct in the evaluation of possible axial calf vein DVT and evaluation of intra-abdominal veins. DUS provides the ability to noninvasively visualize venous anatomy, detect occluded and partially occluded venous segments, and demonstrate physiologic flow characteristics.In the supine patient, normal lower extremity venous flow is phasic (Fig. 24-5), decreasing with inspiration in response to increased intra-abdominal pressure with the descent of the diaphragm and then increasing with expiration as the diaphragm rises and intra-abdominal pressure decreases. When the patient is upright, the decrease in intra-abdominal pressure with expira-tion cannot overcome the hydrostatic column of pressure exist-ing between the right atrium and the calf. Muscular contractions of the calf, along with the one-way venous valves, are then required to promote venous return to the heart. Flow also can be increased by leg elevation or compression and decreased by sud-den elevation of intra-abdominal pressure (Valsalva maneuver). In a venous DUS examination performed with the patient supine, spontaneous flow, variation of flow with respiration, and response of flow to Valsalva maneuver are all assessed. From the common femoral through the popliteal vein, the primary method of detecting DVT with ultrasound is demonstration of the lack of compressibility of the vein with probe pressure on B-mode imaging. Normally, in transverse section, the vein walls should coapt with pressure. Lack of coaptation indicates throm-bus. Axial calf vein thrombi are often best detected by abnor-malities in color flow imaging as compressibility is difficult in the calf.The examination begins at the ankle and continues proxi-mally to the groin. Each vein is visualized, and the flow signal is assessed with distal and proximal compression. Lower extremity DVT can be diagnosed by any of the following DUS findings: lack of spontaneous flow (Fig. 24-6), inability to compress the vein (Fig. 24-7), absence of color filling of the lumen by color flow DUS, loss of respiratory flow variation, and venous disten-tion. Again, lack of venous compression on B-mode imaging is the primary diagnostic variable. Several studies comparing B-mode ultrasound to venography for the detection of femo-ropopliteal DVT in patients clinically suspected to have DVT report sensitivities of >91% and specificities of >97%.21,22 The ability of DUS to assess isolated calf vein DVT varies greatly, with sensitivities ranging from 50% to 93% and specificities approaching 100%.23,24Impedance Plethysmography Impedance plethysmography (IPG) was the primary noninvasive method of diagnosing DVT before the widespread use of DUS but is infrequently used today. Changes in electrical resistance resulting from lower extremity blood volume changes are quantified. IPG is less accurate than DUS for the detection of proximal DVT, with 83% sensitivity in symptomatic patients. It is a poor detector of calf vein DVT.25Brunicardi_Ch24_p0981-p1008.indd 98622/02/19 3:01 PM 987VENOUS AND LYMPHATIC DISEASECHAPTER 24Figure 24-6. Duplex ultrasound of a femoral vein containing thrombus demonstrating no flow within the femoral vein.No compressionCompressionR FVPR FVPFigure 24-7. B-mode ultrasound of the femoral vein in crosssection. The femoral vein does not collapse with external compres-sion (arrows).Figure 24-8. Venogram showing a filling defect in the popliteal vein (arrows).Iodine-125 Fibrinogen Uptake Iodine-125 fibrinogen uptake (FUT) is a seldom-used technique that involves IV administra-tion of radioactive fibrinogen and monitoring for increased uptake in fibrin clots. An increase of 20% or more in one area of a limb indicates an area of thrombus. FUT can detect DVT in the calf, but high background radiation from the pelvis and the urinary tract limits its ability to detect proximal DVT. It also cannot be used in an extremity that has recently undergone surgery or has active inflammation. In a prospective study, FUT had a sensitivity of 73% and specificity of 71% for identification of DVT in a group of symptomatic and asymptomatic patients.26 Currently, FUT is primarily a research tool of historic interest.Venography Venography is the gold standard to which other diagnostic modalities are compared. A small catheter is placed in a dorsal foot vein with injection of a radiopaque contrast agent. Radiographs are obtained in at least two projections. A positive study result is failure to fill the deep system with passage of the contrast medium into the superficial system or demonstration of discrete filling defects (Fig. 24-8). A normal study result virtually excludes the presence of DVT. In a study of 160 patients with a normal venogram followed for 3 months, only two patients (1.3%) subsequently developed DVT, and no patients experienced symptoms of PE.27 Venography is not routinely used in clinical practice because of its invasiveness and complication risk. It is still, however, sometimes used in research studies evaluating DVT prophylaxis.TreatmentOnce the diagnosis of VTE has been made, antithrombotic ther-apy should be initiated promptly. If clinical suspicion for VTE is high, it may be prudent to start treatment before the diagnosis is objectively confirmed. The goals of VTE treatment are the pre-vention of mortality and morbidity associated with PE and the prevention of the postthrombotic syndrome (PTS). Treatment regimens may include antithrombotic therapy, temporary or permanent vena cava filter placement, catheter-directed or systemic thrombolytic therapy, and operative thrombectomy.Antithrombotic Therapy. Most often, antithrombotic therapy for VTE is initiated with IV or subcutaneous (SC) unfraction-ated heparin or SC low molecular weight heparin. Fondaparinux, a synthetic pentasaccharide, is sometimes also used as an alter-native to heparin to initiate therapy. An oral vitamin K antago-nist, usually sodium warfarin, is begun shortly after initiation of IV or SC therapy. Either SC or IV therapy is continued until effective oral anticoagulation with warfarin is achieved as indi-cated by an international normalized ratio (INR) ≥2 for 24 hours. A minimum of 5 days of heparin or fondaparinux therapy is 1Brunicardi_Ch24_p0981-p1008.indd 98722/02/19 3:01 PM 988SPECIFIC CONSIDERATIONSPART IIrecommended.28 Recently, several oral anticoagulants that function by either directly inhibiting thrombin or inhibit-ing factor Xa have additionally been approved by the United States Food and Drug Administration (FDA) for both treatment and prophylaxis for VTE. A principle advantage is they do not require monitoring of laboratory parameters for use.Unfractionated heparin (UFH) binds to antithrombin via a specific 18-saccharide sequence. This increases antithrombin activity over a thousandfold. The antithrombin-heparin complex primarily inhibits factor IIa (thrombin) and factor Xa and, to a lesser degree, factors IXa, XIa, and XIIa of the coagulation cascade. In addition, UFH also binds to tissue factor pathway inhibitor, which inhibits the conversion of factors X to Xa, and factors IX to IXa. Finally, UFH catalyzes the inhibition of thrombin by heparin cofactor II via a mechanism independent of antithrombin.UFH therapy is most commonly administered with an initial IV bolus of 80 units/kg. Weight-based UFH dosages have been shown to be more effective than standard fixed boluses in rapidly achieving therapeutic levels.29 The initial bolus is followed by a continuous IV drip at 18 units/kg per hour. The half-life of IV UFH ranges from 45 to 90 minutes and is dose dependent. The level of antithrombotic therapy should be moni-tored every 6 hours using the activated partial thromboplastin time (aPTT), with the goal range of 1.5 to 2.5 times control values. This should correspond with plasma heparin anti-Xa activity levels of 0.3 to 0.7 IU/mL.Initial anticoagulation with UFH may also be administered SC, although this route is less commonly used. Adjusted-dose therapeutic SC UFH is initiated with 17,500 units, followed by 250 units/kg twice daily, and dosing is adjusted to an aPTT goal range similar to that for IV UFH. Fixed-dose unmonitored SC UFH is started with a bolus of 333 units/kg, followed by 250 units/kg twice daily.30Hemorrhage is the primary complication of UFH therapy. The rate of major hemorrhage (fatal, intracranial, retroperitoneal, or requiring transfusion of >2 units of packed red blood cells) is approximately 5% in hospitalized patients undergoing UFH therapy (1% in medical patients and 8% in surgical patients).30 For patients with UFH-related bleeding complications, cessation of UFH is required, and anticoagulation may be reversed with protamine sulfate. Protamine sulfate binds to UFH and forms an inactive salt compound. Each milligram of protamine neutral-izes 90 to 115 units of heparin, and the dosage should not exceed 50 mg IV over any 10-minute period. Side effects of protamine sulfate include hypotension, pulmonary edema, and anaphylaxis. Patients with prior exposure to protamine-containing insulin (NPH) and patients with allergy to fish may have an increased risk of hypersensitivity, although no direct relationship has been established. Protamine administration should be performed judi-ciously and terminated if any side effects occur.In addition to hemorrhage, heparin also has other, unique, complications. Heparin-induced thrombocytopenia (HIT) results from heparin-associated antiplatelet antibodies (HAAbs) directed against platelet factor 4 complexed with heparin.31 HIT occurs in 1% to 5% of patients treated with heparin.32,33 In patients with repeat heparin exposure (such as vascular surgery patients), the incidence of HAAbs may be as high as 21%.34 HIT occurs most frequently in the second week of therapy and may lead to disastrous venous or arterial thrombotic complications. Therefore, platelet counts should be monitored periodically in patients receiving continuous heparin therapy.HIT is diagnosed based on previous exposure to heparin, platelet count less than 100,000, and/or platelet count decline of 50% following exposure. All heparin must be stopped and alter-native anticoagulation initiated immediately to avoid thrombotic complications, which may approach 50% over the subsequent 30 days in affected individuals.35Another complication of prolonged high-dose heparin therapy is osteopenia. Heparin-induced osteopenia results from impairment of bone formation and enhancement of bone resorp-tion by heparin.Low molecular weight heparins (LMWHs) are derived from the depolymerization of porcine UFH. Like UFH, LMWHs bind to antithrombin via a specific pentasaccharide sequence to expose an active site for the neutralization of fac-tor Xa. However, LMWHs have fewer additional saccharide units. This results in less inactivation of thrombin (factor IIa). In comparison to UFH, LMWHs have increased bioavailability (>90% after SC injection), longer half-lives (approximately 4 to 6 hours), and more predictable elimination rates.Most patients treated with weight-based onceor twice-daily SC LMWH injections do not require laboratory monitoring for anticoagulant effect, a distinct advantage over continuous IV infusions of UFH. Patients who do require monitoring include those with significant renal insufficiency, pediatric patients, obese patients greater than 120 kg, and pregnant patients. Moni-toring may be performed using anti-Xa activity assays. The ther-apeutic anti-Xa goal range depends on the type of LMWH and the frequency of dosing. There are numerous LMWHs avail-able, and the various preparations differ in their anti-Xa and anti-IIa activities. Treatment dosing for one LMWH, therefore, cannot be extrapolated for use with another. The anticoagulant effect of LMWHs may be partially reversed (approximately 60%) with protamine sulfate.Numerous well-designed trials comparing SC LMWH with IV and SC UFH for the treatment of DVT have been critically evaluated in several meta-analyses and demonstrate a decrease in thrombotic complications, bleeding, and mortality with LMWHs.36-38 LMWHs also are associated with a decreased rate of HAAb formation and HIT (<2%) compared with UFH (at least in prophylactic doses).30 However, patients with estab-lished HIT also should not receive LMWHs because there is cross-reactivity between the drugs.39A major benefit of LMWHs is that it allows outpatient treatment of VTE.40,41 In a randomized study comparing IV UFH and the LMWH nadroparin calcium,40 there was no sig-nificant difference in recurrent thromboembolism (8.6% for UFH vs. 6.9% for LMWH) or major bleeding complications (2.0% for UFH vs. 0.5% for LMWH). There was, however, a 67% reduction in mean days in the hospital for the LMWH group.Fondaparinux currently is a synthetic pentasaccharide that has been approved by the FDA for the initial treatment of DVT and PE. Its five-polysaccharide sequence binds and activates antithrombin, causing specific inhibition of factor Xa. In two large noninferiority trials, fondaparinux was compared with the LMWH enoxaparin for the initial treatment of DVT and with IV UFH for the initial treatment of PE.42,43 The rates of recurrent VTE ranged from 3.8% to 5%, with rates of major bleeding of 2% to 2.6%, for all treatment arms. The drug is administered SC once daily with a weight-based dosing protocol: 5 mg, 7.5 mg, or 10 mg for patients weighing <50 kg, 50 to 100 kg, or >100 kg, respectively. The half-life of fondaparinux is approximately 2Brunicardi_Ch24_p0981-p1008.indd 98822/02/19 3:01 PM 989VENOUS AND LYMPHATIC DISEASECHAPTER 2417 hours in patients with normal renal function. There are rare case reports of fondaparinux-induced thrombocytopenia.44Direct thrombin inhibitors (DTIs) include parental forms with recombinant hirudin, argatroban, and bivalirudin, as well as an oral agent, dabigatran. These antithrombotic agents bind to thrombin, inhibiting the conversion of fibrinogen to fibrin as well as thrombin-induced platelet activation. These actions are independent of antithrombin. The parental DTIs should be reserved for (a) patients in whom there is a high clinical suspi-cion or confirmation of HIT, and (b) patients who have a his-tory of HIT or test positive for heparin-associated antibodies whereas dabigatran can be used as an alternative to Warfarin when INR monitoring is difficult or impractical. In patients with established HIT, DTIs should be administered for at least 7 days, or until the platelet count normalizes. Warfarin may then be introduced slowly, overlapping therapy with a DTI for at least 5 days, or dabigatran may be continued instead of Warfarin.45Bivalirudin is approved primarily for patients with or without HIT who undergo percutaneous coronary intervention and is rarely used outside of that setting.Argatroban is indicated for the prophylaxis and treatment of thrombosis in HIT. It also is approved for patients with, or at risk for, HIT undergoing percutaneous coronary intervention. Antithrombotic prophylaxis and therapy are initiated with a con-tinuous IV infusion of 2 µg/kg per minute, without the need for a bolus. The half-life ranges from 39 to 51 minutes, and the dosage is adjusted to maintain an aPTT of 1.5 to 3 times normal. Large ini-tial boluses and higher rates of continuous infusion are reserved for patients with coronary artery thrombosis and myocardial infarc-tion. In these patients, therapy is monitored using the activated clotting time. Argatroban is metabolized and excreted by the liver; therefore, dosage adjustments are needed in patients with hepatic impairment. There is no reversal agent for argatroban.The oral agent, dabigatran, is US FDA-approved since 2014 for the treatment of VTE and prophylaxis for recurrent VTE. Additionally, limited approval was obtained in 2015 for prophylaxis of VTE after hip replacement surgery. It is admin-istered as a prodrug, dabigatran etexilate, that is converted to the active form, dabigatran, in the liver. The half-life ranges from 12 to 17 hours; it is therefore administered once daily for prophylaxis and twice daily for VTE therapy. Absorption is not dietary dependent, and no drug level monitoring is required. Dabigatran is metabolized in the kidney, and dose adjustment is required for renal insufficiency. Data on use in obese patients is limited; therefore, use is not recommended for patients with a body mass index ≥40 kg/m2 or ≥120 kg.46 Dyspepsia is a com-mon side effect that may limit use in some patients.47 Dabigatran may be reversed with idarucizumab in emergent situations.48 It is contraindicated in patients with mechanical heart valves.Direct factor Xa inhibitors, which are comprised of the oral agents rivaroxaban, apixiban, and edoxaban, are FDA approved for treatment in VTE and prophylaxis for recurrent VTE. Additionally, rivaroxoban and apixiban are approved by the FDA for VTE prophylaxis following knee and hip replace-ment surgery. These medications function by inactivating cir-culating and thrombus-bound factor Xa. They are metabolized in the kidney (25–35%) and in the liver; therefore, use is not rec-ommended in patients with renal insufficiency (creatinine clear-ance <30 mL/min for rivaroxaban, or <15 mL/min for apixiban and edoxaban) or severe hepatic insufficiency. As with the oral DTI, dabigatran, data on use in obese patients is limited; there-fore, use is not recommended in these patients. Additionally, these agents are contraindicated in pregnancy. There are no specific reversal agents available for direct factor Xa inhibi-tors. For severe cases of hemorrhage, indirect partial reversal may be achieved with use of prothrombin complex concentrate administration.49Rixaroxaban has a half-life of 7 to 17 hours. Therapy does not require monitoring. Prophylactic dosing is 10 mg once daily, and therapeutic dosing is 15 mg twice daily for 21 days, fol-lowed by 20 mg once daily thereafter.Apixiban has a half-life of 5 to 9 hours. Therapy does not require monitoring, and there are no dietary restrictions. If monitoring is desired in situations of bleeding or concern for subor supratherapeutic dosing, serum anti-Xa levels can be obtained. Prophylactic dosing is 2.5 mg twice daily, and thera-peutic dosing is 10 mg daily for 7 days, followed by 5 mg twice daily thereafter.Edoxaban has a half-life of 10 to 14 hours. Therapy does not require monitoring. Typical dosing is 60 mg once daily, and 30 mg once daily if creatinine clearance ranges from 15 to 50 mL/min, or body weight ≤60 kg.Vitamin K antagonists, which include warfarin and other coumarin derivatives, are the traditional mainstay of long-term antithrombotic therapy in patients with VTE. Warfarin inhib-its the γ-carboxylation of vitamin K–dependent procoagulants (factors II, VII, IX, and X) and anticoagulants (proteins C and S), resulting in formation of less functional proteins. Warfarin usu-ally requires several days to achieve full effect because normal circulating coagulation proteins must first undergo their normal degradation. Factors X and II have the longest half-lives, in the range of 36 and 72 hours, respectively. A steady-state concen-tration of warfarin is usually not reached for 4 to 5 days.Warfarin therapy is monitored by measuring the INR, calculated using the following equation:INR = (patient prothrombin time/laboratorynormal prothrombin time)ISIwhere ISI is the international sensitivity index. The ISI describes the strength of the thromboplastin that is added to activate the extrinsic coagulation pathway. The therapeutic target INR range is usually 2.0 to 3.0, but the response to warfarin is variable and depends on liver function, diet, age, and concomitant medica-tions. In patients receiving anticoagulation therapy without con-comitant thrombolysis or venous thrombectomy, the vitamin K antagonist may be started on the same day as the initial paren-teral anticoagulant, usually at doses ranging from 5 to 10 mg. Smaller initial doses may be needed in older and malnourished patients, in those with liver disease or congestive heart failure, and in those who have recently undergone major surgery.49The recommended duration of warfarin antithrombotic therapy is stratified based on whether the DVT was provoked or unprovoked, whether it was the first or a recurrent episode, where the DVT is located, and whether malignancy or thrombophilia is present. Current ACCP recommendations for duration of warfarin therapy are summarized in Table 24-4.In patients with proximal DVT, several randomized clini-cal trials have demonstrated that shorter-term antithrombotic therapy (4 to 6 weeks) is associated with a higher rate of VTE recurrence than 3 to 6 months of anticoagulation.50-52 In these trials, most of the patients with transient risk factors had a low rate of recurrent VTE, and most recurrences were in patients with continuing risk factors. The ACCP recommendation, there-fore, is that 3 months of anticoagulation are sufficient to prevent 3Brunicardi_Ch24_p0981-p1008.indd 98922/02/19 3:01 PM 990SPECIFIC CONSIDERATIONSPART IITable 24-4Summary of American College of Chest Physicians recommendations regarding duration of long-term antithrombotic therapy for deep vein thrombosis (DVT)CLINICAL SUBGROUPANTITHROMBOTIC TREATMENT DURATIONFirst episode DVT/transient risk/surgeryVKA or LMWH for 3 monthsFirst episode DVT/unprovokedVKA or LMWH for 3 monthsConsider for long-term therapy if:• Proximal DVT• Minimal bleeding risk• Stable coagulation monitoringDistal DVT/unprovoked• Symptomatic• Asymptomatic and no risk factors for progressionVKA for 3 monthsSerial imaging in 2 weeks, if progression VKA for 3 monthsSecond episode DVT/unprovokedDVT and cancerVKA for extended therapyLMWH for extended therapy over VKALMWH = low molecular weight heparin; VKA = vitamin K antagonist.Data from Kearon C, Akl EA, Comerota AJ, et al: Antithrombotic therapy for VTE disease: Antithrombotic Therapy and Prevention of Thrombosis, 9th ed: American College of Chest Physicians Evidence-Based Clinical Practice Guidelines, Chest. 2012 Feb;141(2 Suppl): e419S-e496S.recurrent VTE in patients with DVT occurring around the time of a transient risk factor (e.g., hospitalization or orthopedic or major general surgery).In contrast to patients with thrombosis related to transient risk factors, patients with unprovoked VTE are much more likely to develop recurrence (rates as high as 40% at 10 years). In this latter group of patients, numerous clinical trials have compared 3 to 6 months of anticoagulation therapy with extended-duration warfarin therapy, both at low intensity (INR of 1.5 to 2.0) and at conventional intensity (INR of 2.0 to 3.0).53-55 In patients with idiopathic DVT, extended-duration antithrombotic therapy is associated with a relative reduction in the rate of recurrent VTE by 75% to >90%. In addition, conventional-intensity warfarin reduces the risk even further compared with low-intensity war-farin (0.7 events per 100 person-years vs. 1.9 events per 100 person-years) without an increase in bleeding complications.56In patients with VTE in association with a hypercoagulable condition, the optimal duration of anticoagulation therapy is influ-enced more by the clinical circumstances at the time of the VTE (idiopathic vs. secondary) than by the actual presence or absence of the more common thrombophilic conditions. In patients with VTE related to malignancy, increasing evidence suggests that longer-term therapy with LMWH (up to 6 months) is associated with a lower VTE recurrence than treatment using conventional vitamin K antagonists.57,58 The primary complication of warfarin therapy is hemorrhage, and the risk is related to the magnitude of INR prolongation. Depending on the INR and the presence of bleeding, warfarin anticoagulation may be reversed by (a) omit-ting or decreasing subsequent dosages, (b) administering oral or parenteral vitamin K, or (c) administering fresh frozen plasma, prothrombin complex concentrate, or recombinant factor VIIa.49Warfarin therapy rarely may be associated with the devel-opment of skin necrosis and limb gangrene. These conditions occur more commonly in women (4:1), and the most commonly affected areas are the breast, buttocks, and thighs. This com-plication, which usually occurs in the first days of therapy, is occasionally, but not exclusively, associated with protein C or S deficiency and malignancy. Patients who require continued anticoagulation may restart low-dose warfarin (2 mg) while receiving concomitant therapeutic heparin. The warfarin dosage is then gradually increased over a 1to 2-week period.49Systemic and Catheter-Directed Thrombolysis. Patients with extensive proximal, iliofemoral DVT may benefit from systemic thrombolysis or catheter-directed thrombolysis (CDT). CDT appears to be more effective (see later in chapter) and potentially reduces acute congestive lower extremity symp-toms more rapidly than anticoagulation alone and decreases the development of PTS.Several thrombolytic agents are available, including strep-tokinase, urokinase, alteplase (recombinant tissue plasminogen activator), reteplase, and tenecteplase. All share the ability to con-vert plasminogen to plasmin, which leads to the degradation of fibrin. They differ with regard to their half-lives, their potential for inducing fibrinogenolysis (generalized lytic state), their poten-tial for antigenicity, and their FDA-approved indications for use.Streptokinase is purified from β-hemolytic Streptococcus and is approved for the treatment of acute myocardial infarction, PE, DVT, arterial thromboembolism, and occluded central lines and arteriovenous shunts. It is not specific for fibrin-bound plas-minogen, however, and its use is limited by its significant rates of antigenicity. Fevers and shivering occur in 1% to 4% of patients.Urokinase is derived from human neonatal kidney cells grown in tissue culture. Currently, it is only approved for lysis of massive PE or PE associated with unstable hemodynamics.Alteplase, reteplase, and tenecteplase all are recombinant variants of tissue plasminogen activator. Alteplase is indicated for the treatment of acute myocardial infarction, acute ischemic stroke, and acute massive PE. However, it often is used for CDT of DVT. Reteplase and tenecteplase are indicated only for the treatment of acute myocardial infarction.Systemic thrombolysis was evaluated in numerous older prospective and randomized clinical trials, and its efficacy was summarized in a recent Cochrane Review.59 In 12 studies involving over 700 patients, systemic thrombolysis was associ-ated with significantly more clot lysis (relative risk [RR] 0.24 to 0.37) and significantly less PTS (RR 0.66). However, venous function was not significantly improved. In addition, more bleeding complications occurred (RR 1.73).In an effort to minimize bleeding complications and increase efficacy, CDT techniques were developed for the treat-ment of symptomatic primarily iliofemoral DVT. With catheterdirected therapy, venous access may be achieved through percutaneous catheterization of the ipsilateral popliteal vein, retrograde catheterization through the contralateral femoral vein, or retrograde cannulation from the internal jugular vein. Multi–side-hole infusion catheters, with or without infusion wires, are used to deliver the lytic agent directly into the throm-bus. Lytic agents may be administered alone or, now more commonly, in combination with catheter-based methods to Brunicardi_Ch24_p0981-p1008.indd 99022/02/19 3:01 PM 991VENOUS AND LYMPHATIC DISEASECHAPTER 24ABFigure 24-9. Preoperative computed tomography imaging and intraoperative photo demonstrating erosion of IVC filter through the IVC wall.physically break up the clot—so-called pharmacomechanical thrombolysis. One commonly used device to perform phar-macomechanical thrombolysis is the AngioJet, which utilizes pulsed injection of thrombolytic via a percutaneously inserted catheter followed by active aspiration to remove the thrombus.The efficacy of CDT for the treatment of symptomatic iliofemoral DVT has been reported previously in a large, multi-center, randomized control trial. Two-hundred and nine patients with proximal DVT identified within 21 days of onset of symp-toms were assigned to conventional anticoagulant therapy vs. conventional anticoagulant therapy plus CDT. In the CDT group, placement of a venous stent was permitted for any identified iliac vein stenotic lesion. At 6 months, iliac vein patency was signifi-cantly improved in the thrombolysis group (65.9% vs. 47.4%). At 2 years, in the CDT group, there was an absolute risk reduc-tion of nearly 15% for development of PTS, translating to a num-ber needed to treat of seven patients to prevent one case of PTS.60 However, these results were, in part, contradictory to the results reported the more recent Acute Venous Thrombosis: Throm-bus Removal with Adjunctive Catheter-Directed Thrombolysis (ATTRACT) trial, a prospective, randomized, multicenter trial evaluating nearly 700 patients comparing anticoagulant use with CDT in patients with acute femoropopliteal, and/or iliac vein DVT.61 However, the purpose of this trial was to see if indica-tions for CDT should be extended for isolated femoropopliteal DVT (43% of the patients in this study) and therefore, was under-powered to compare treatment efficacy for iliofemoral DVT, which known to have a higher risk of PTS. The study found that PTS occurred with equal frequency in the two groups (47% vs. 48%, P = NS), but patients who were treated with pharmacom-echanical CDT plus anticoagulation were less likely to develop moderate-to-severe PTS than those treated with anticoagulation alone (18% vs. 24%, P = .003). There was no difference between the two groups in quality of life. There was an increase in both overall hemorrhage (4.5% vs. 1.7%) and major hemorrhage (1.7% vs 0.3%) with CDT but no fatal or intracranial hemor-rhage in either cohort. Taken in combination, the findings from these trials support selective use of CDT with anticoagulation in young patients with acute iliofemoral DVT and anticoagulation alone in the remaining patient with DVT.There are contraindications to thrombolytic therapy. Absolute contraindications include prior history of ischemic or hemorrhagic stroke within 3 months, head trauma within 3 months, neurologic surgery within 6 months, known intra-cranial neoplasm, internal bleeding within 6 weeks, active or known bleeding disorder, traumatic cardiopulmonary resuscita-tion within 3 weeks or suspected aortic dissection. Fortunately, serious remote bleeding is uncommon, and intracranial hem-orrhage rarely occurs. The majority of bleeding complications are limited to the venous access site. Symptomatic pulmonary embolism occurs uncommonly and is very rarely fatal.Inferior Vena Caval Filters. Since the introduction of the Kimray-Greenfield filter in the United States in 1973, numerous vena caval filters have been developed. Although the designs are variable, they all are designed to prevent pulmonary emboli, while allowing continuation of venous blood flow through the IVC. Early filters were placed surgically through the femoral vein. Currently, less invasive techniques allow percutaneous filter placement through a femoral vein, internal jugular vein, or a peripheral vein under fluoroscopic or ultrasound guidance.Placement of an IVC filter is indicated for patients who have manifestations of lower extremity VTE and absolute contraindications to anticoagulation, those that have a bleeding complication from anticoagulation therapy of acute VTE, or those who develop recurrent DVT or PE despite adequate anticoagula-tion therapy and for patients with severe pulmonary hypertension.When possible, anticoagulation therapy should be contin-ued in patients with vena cava filters. The duration of antico-agulation is determined by the underlying VTE and not by the presence of the IVC filter itself. Practically speaking, however, many patients who require an IVC filter for recurrent VTE are the same ones who would benefit most from indefinite antico-agulation. In patients who are not able to receive anticoagulants due to recent surgery or trauma, the clinician should continually reassess if anticoagulation may be started safely at a later date.Placement of permanent IVC filters has been evaluated as an adjunct to routine anticoagulation in patients with proximal DVT.62 Routine IVC filter placement has not been shown to prolong early or late survival in patients with proximal DVT but did decrease the rate of PE (HR, 0.22; 95% CI, 0.05–0.90); however, there is an increased rate of recurrent DVT in patients with IVC filters (HR, 1.87; 95% CI, 1.10–3.20).IVC filters are associated with acute and late complica-tions. Acute complications include thrombosis or bleeding at the insertion site and misplacement of the filter. Late complications include thrombosis of the IVC, DVT, breaking, migration, or ero-sion of the filter through the IVC (Fig. 24-9). The rate of fatal complications is <0.12%.63 As a result of the increasing number Brunicardi_Ch24_p0981-p1008.indd 99122/02/19 3:01 PM 992SPECIFIC CONSIDERATIONSPART IIFigure 24-10. Autopsy specimen showing a massive pulmonary embolism.of reported complications with IVC filters, the FDA issued a warning in 2010 recommending removal of IVC filters as soon as they are no longer needed.64 This was followed by an update in 2014 where the recommendation was made to remove IVC filters within 29 and 54 days after implantation based upon a mathemati-cal model that suggested an increased risk-to-benefit ratio at this time point.65In some patients, the need for an IVC filter may be self-limited. Such patients can be treated with so-called removable IVC filters. Depending on the device, removable IVC filters are potentially removable by percutaneous endovascular tech-niques for up to several months after their initial implantation, assuming the filter is no longer required and does not have large amounts of trapped thrombi. IVC filters that have been in place for an extended period of time may require adjunctive techniques, including laser-assisted removal or open surgical removal when they are embedded within the vena cava. All tem-porary IVC filters are approved for permanent implantation, and many so-called temporary filters end up as permanent devices with all the potential complications of permanent IVC filters.Operative Venous Thrombectomy. In patients with acute iliofemoral DVT, surgical therapy is generally reserved for patients who worsen with anticoagulation therapy and those with phlegmasia cerulea dolens and impending venous gan-grene. If the patient has phlegmasia cerulea dolens, a fasciotomy of the calf compartments is first performed. In iliofemoral DVT, a longitudinal venotomy is made in the common femoral vein, and a venous balloon embolectomy catheter is passed through the thrombus into the IVC and pulled back several times until no further thrombus can be extracted. The distal thrombus in the leg is removed by manual pressure beginning in the foot. This is accomplished by application of a tight rubber elastic wrap beginning at the foot and extending to the thigh. If the thrombus in the femoral vein is old and cannot be extracted, the vein may be ligated. For a thrombus that extends into the IVC, the IVC is exposed transperitoneally and controlled below the renal veins. The IVC is opened, and the thrombus is removed by gentle mas-sage. An intraoperative completion venogram determines if any residual thrombus or stenosis is present. If a residual iliac vein stenosis is present, intraoperative angioplasty and stenting can be performed. In most cases, an arteriovenous fistula is then created by anastomosing the great saphenous vein (GSV) end to side with the superficial femoral artery in an effort to main-tain patency of the thrombectomized iliofemoral venous seg-ment. Heparin is administered postoperatively for several days. Warfarin anticoagulation is maintained for at least 6 months after thrombectomy. Complications of iliofemoral thrombec-tomy include PE in up to 20% of patients67 and death in <1% of patients.68One study followed 77 limbs for a mean of 8.5 years after thrombectomy for acute iliofemoral DVT. In limbs with suc-cessful thrombectomy, valvular competence in the thrombecto-mized venous segment was 80% at 5 years and 56% at 10 years. More than 90% of patients had minimal or no symptoms of PTS. There were 12 (16%) early thrombectomy failures. Patients were required to wear compression stockings for at least 1 year after thrombectomy.69Survival rates for surgical pulmonary embolectomy have improved over the past 20 years with the addition of cardio-pulmonary bypass. Emergency pulmonary embolectomy for acute PE is rarely indicated. Patients with preterminal massive PE (Fig. 24-10) for whom thrombolysis has failed or who have contraindications to thrombolytics may be candidates for this procedure. Open pulmonary artery embolectomy is performed through a posterolateral thoracotomy with direct visualization of the pulmonary arteries. Mortality rates range between 20% and 40%.70-72Percutaneous catheter-based techniques for removal of a PE involve mechanical thrombus fragmentation or embolec-tomy using suction devices. Mechanical clot fragmentation is followed by CDT. Results of catheter-based fragmentation are based on small case series. In a study in which a fragmentation device was used in 10 patients with acute massive PE, frag-mentation was successful in 7 patients with a mortality rate of 20%.73 Transvenous catheter pulmonary suction embolectomy has also been performed for acute massive PE with a reported 76% successful extraction rate and a 30-day survival of 70%.74ProphylaxisPatients who undergo major general surgical, gynecologic, urologic, and neurosurgical procedures without thrombopro-phylaxis have a significant incidence of perioperative DVT. An estimated one-third of the 150,000 to 200,000 VTE-related deaths per year in the United States occur following surgery.75 The goal of prophylaxis is to reduce the mortality and morbidity associated with VTE. The first manifestation of VTE may be a life-threatening PE (Fig. 24-11), and as indicated earlier, clinical evaluation to detect DVT before PE is unreliable.Effective methods of VTE prophylaxis involve the use of one or more pharmacologic or mechanical modalities. Cur-rently available pharmacologic agents include low-dose UFH, LMWH, synthetic pentasaccharides, and vitamin K antago-nists. Mechanical methods include intermittent pneumatic com-pression (IPC) and graduated compression stockings. There is insufficient evidence to consider aspirin alone as adequate DVT prophylaxis. Methods of prophylaxis vary with regard to efficacy, and the 2012 ACCP Clinical Practice Guidelines strat-ify their uses according to the patient’s level of VTE risk, bleed-ing risk, and the values and preferences of individual patients (see Table 24-3).Venous Thromboembolism Prophylaxis in Nonorthopedic Surgery. The risk for VTE associated with a surgical procedure depends on the type of operation, type of anesthesia, duration of surgery, and other risk factors, such as patient age, presence of cancer, prior VTE, obesity, presence of infection, and known thrombophilic disorders. VTE risk can be stratified according to Brunicardi_Ch24_p0981-p1008.indd 99222/02/19 3:01 PM 993VENOUS AND LYMPHATIC DISEASECHAPTER 24Figure 24-11. Computed tomography angiogram showing mul-tiple pulmonary embolisms (arrows). (Used with permission from Dr. Scott Ambruster.)Table 24-5Risk assessment model from the Patient Safety in Surgery StudyRISK FACTORRISK SCORE POINTSOperation type other than endocrine Respiratory and hernia Thoracoabdominal aneurysm, embolectomy/thrombectomy, venous reconstruction, and endovascular repair Aneurysm Mouth, palate Stomach, intestines Integument Hernia9744432ASA, physical status classification 3,4, or 5 2 Female sex211Work RVU >17 10–1732Two points for each of these conditions Disseminated cancer Chemotherapy for malignancy within 30 days of operation Preoperative serum sodium >145 mmol/L Transfusion >4 units packed RBCs in 72 hours before operation Ventilator dependent2One point for each of these conditions Wound class (clean/contaminated) Preoperative hematocrit ≤38% Preoperative bilirubin >1 mg/dL Dyspnea Albumin ≤3.5 mg/dL Emergency1Zero points for each of these conditions ASA physical class of 1 Work RVU <10 Male sex0ASA = American Society of Anesthesiologists; RBCs = red blood cells; RVU = relative value unit.Reproduced with permission from Rogers SO Jr, Kilaru RK, Hosokawa P, et al: Multivariable predictors of postoperative venous thromboembolic events after general and vascular surgery: results from the patient safety in surgery study, J Am Coll Surg. 2007 Jun;204(6):1211-1221.the previously mentioned risk assessment models, the Caprini score and Rogers score. These risk assessment models are included in the prophylaxis guidelines for nonorthopedic sur-gery (Tables 24-5 and 24-6). A composite score is created using assigned values for each risk factor. The cumulative score for each patient is then used to predict thrombosis risk and provide recommendations regarding VTE prophylaxis.Patients at very low risk (<0.5%; Rogers score <7; Caprini score 0) who undergo general or abdominopelvic procedures do not require pharmacologic or mechanical pro-phylaxis; however, early ambulation is required. Patients at low risk (<1.5%; Rogers score 7–10; Caprini score 1–2) should receive mechanical prophylaxis. Patients at moderate risk (3%; Rogers score >10; Caprini score 3–4) should receive LMWH at recommended doses, low-dose UFH, or mechanical pro-phylaxis. Patients at high risk (6%; Caprini score ≥5) should receive LMWH at recommended doses or low-dose UFH and mechanical prophylaxis. Thromboprophylaxis should con-tinue until discharge, except in select high-risk patients with malignancy in whom extended-duration prophylaxis (up to 4–6 weeks) may be beneficial. Patients with significant risk for bleeding should receive mechanical prophylaxis until this risk subsides.75Overall, low-dose UFH and LMWH reduce the risk for symptomatic and asymptomatic VTE by 60% to 70%. The risks for bleeding differ, depending on the dosage. Lower dosages of LMWH appear to be associated with less bleeding risk than low-dose UFH, but the latter produces less bleeding risk than higher prophylactic dosages of LMWH.76 Other advantages of LMWH include once-daily dosing protocols and a lower rate of heparin-associated antibody formation.Fondaparinux has been compared with the LMWH dalte-parin in patients who undergo high-risk major abdominal sur-gery. It also has been compared with IPC alone in patients undergoing non–high-risk abdominal surgery.77,78 Fondaparinux demonstrated rates of VTE prevention, bleeding complications, and mortality similar to those of LMWH. It was more beneficial than IPC alone in reducing VTE but with a higher rate of bleed-ing (1.6% vs. 0.2%).Prophylactic insertion of IVC filters has been suggested for VTE prophylaxis in high-risk trauma patients, bariatric surgical patients, and some patients with malignancy who have contraindications for LMWH therapy.79 A 5-year study of prophylactic IVC filter placement in 132 trauma patients at high risk of PE (head injury, spinal cord injury, pelvic or Brunicardi_Ch24_p0981-p1008.indd 99322/02/19 3:01 PM 994SPECIFIC CONSIDERATIONSPART IITable 24-6Caprini risk assessment model1 POINT2 POINTS3 POINTS5 POINTSAge 41–60Age 61–74Age ≥75Stroke (<1 month)Minor surgeryArthroscopic surgeryHistory of VTEElective arthroplastyBMI >25 kg/m2Major open surgery (> 45 minutes)Family history of VTEHip, pelvis, or leg fractureSwollen legsLaparoscopic surgery (> 45 minutes)Factor V LeidenAcute spinal cord injury (<1 month)Varicose veinsMalignancyProthrombin 20210A Pregnancy or postpartumConfined to bed (>72 hours)Lupus anticoagulant History of unexplained or recurrent spontaneous abortionImmobilizing plaster castAnticardiolipin antibody Oral contraceptives of hormone replacementCentral venous accessElevated serum homocysteine Sepsis (<1 month) Heparin-induced thrombocytopenia Serious lung disease, including pneumonia (<1 month) Other congenital or acquired thrombophilia Abnormal pulmonary function test   Acute myocardial infarction   Congestive heart failure   History of inflammatory bowel disease   Medical patient at bed rest   BMI = body mass index; VTE = venous thromboembolism.Data from Bahl V, Hu HM, Henke PK, et al: A validation study of retrospective venous thromboembolism risk scoring method, Ann Surg. 2010 Feb; 251(2):344-350.long bone fractures) reported a 0% incidence of symptom-atic PE in patients with a correctly positioned IVC filter.80 In 47 patients with a malpositioned IVC filter (strut malposition or filter tilt), there was a 6.3% incidence of symptomatic PE with three deaths. DVT occurred at the insertion site in 3.1% of the patients. IVC patency was 97.1% at 3 years.Fatal and nonfatal PE can still occur in patients with vena cava interruption. As noted earlier, long-term complications associated with permanent IVC filters include IVC thrombo-sis and DVT. Currently, the ACCP recommends IVC filters be placed only if a proximal DVT is present and anticoagula-tion therapy is contraindicated. Placement of an IVC filter in the setting of severe pulmonary embolism development while anticoagulated remains controversial. IVC filter insertion is not recommended for primary prophylaxis.75Removable IVC filters may be placed in patients with a temporarily increased risk of PE.81 The best patient groups for retrievable filter placement may include young trauma patients with transient immobility, patients undergoing surgi-cal procedures associated with a high risk of PE, and patients with hypercoagulable states who cannot receive anticoagula-tion therapy for a short period of time. Careful follow-up is required to assure all potentially removable filters are in fact removed.OTHER VENOUS THROMBOTIC DISORDERSSuperficial Vein ThrombophlebitisSuperficial vein thrombophlebitis (SVT) most commonly occurs in varicose veins but can occur in normal veins. When SVT recurs at variable sites in normal superficial veins, thrombophlebitis migrans, it may signify a hidden visceral malignancy or a systemic disorder such as a blood dyscrasia and/or a collagen vascular disease. SVT also frequently occurs as a complication of indwelling catheters, with or without asso-ciated extravasation of injected material. Upper extremity vein thrombosis has been reported to occur in 38% of patients with peripherally inserted central catheters; 57% of these developed in the cephalic vein (Fig. 24-12).82 Suppurative SVT may occur in veins with indwelling catheters and may be associated with generalized sepsis.Clinical signs of SVT include redness, warmth, and ten-derness along the distribution of the affected veins, often asso-ciated with a palpable cord. Patients with suppurative SVT may have fever and leukocytosis. DUS should be performed in patients with signs and symptoms of acute SVT to confirm the diagnosis and to determine if any associated DVT is present. Concomitant lower extremity DVT may be present in 5% to 40% of patients with SVT; most occur in patients with greater Brunicardi_Ch24_p0981-p1008.indd 99422/02/19 3:01 PM 995VENOUS AND LYMPHATIC DISEASECHAPTER 24Figure 24-12. Duplex ultrasound of a brachial vein containing thrombus and percutaneously inserted central catheter (PICC).Figure 24-13. Upper extremity venogram showing stenosis of the right subclavian vein at the first rib (arrow).saphenous vein SVT within 1 cm of the saphenofemoral junction. A follow-up DUS should be performed in 5 to 7 days in patients with SVT in the proximal GSV but without deep vein involvement. Approximately 10% to 20% of patients with SVT involving the proximal GSV experience progression to deep venous involvement within 1 week.83,84Treatment of SVT is quite variable. A Cochrane Review reported that LMWHs and nonsteroidal anti-inflammatory drugs both reduce the rate of SVT extension or recurrence.85 Addi-tionally, a multicenter, randomized, blinded trial comparing use of fondaparinux to placebo in lower extremity SVT found use of fondaparinux reduced the rate of VTE formation by 85%, though the incidence of VTE formation was low in both groups (0.2% vs. 1.3%, P <.001). The number needed to treat to prevent one episode of VTE was 88 patients. There was no difference in mortality between the two arms of the trial.85Topical medications appear to improve local symptoms. Surgical treatment, combined with the use of graduated com-pression stockings, is associated with a lower rate of VTE and SVT progression.86 The treatment is individualized and depends on the location of the thrombus and the severity of symptoms. In patients with SVT not within 1 cm of the saphenofemoral junction, treatment consists of compression and administra-tion of an anti-inflammatory medication such as indomethacin. In patients with suppurative SVT, antibiotics and removal of any existing indwelling catheters are mandatory. Excision of the vein may be necessary but is usually reserved for patients with systemic symptoms or when excision of the involved vein is straightforward. If the SVT extends proximally to within 1 cm of the saphenofemoral junction, extension into the com-mon femoral vein is more likely to occur. In these patients, anticoagulation therapy for 6 weeks and GSV ligation appear equally effective in preventing thrombus extension into the deep venous system.87,88Upper Extremity Vein ThrombosisAxillary-subclavian venous thrombosis (ASVT) is classified into two forms. Primary ASVT occurs in only a small minority of all patients with ASVT. In the primary form, no clear cause for the thrombosis is readily identifiable at initial evaluation. Patients with primary ASVT often give a history of performing prolonged, repetitive motion activities, which results in damage to the subclavian vein, usually where it passes between the head of the clavicle and the first rib in association with the subclavius muscle. This condition is also known as venous thoracic outlet syndrome, effort thrombosis, and Paget-Schroetter syndrome. Secondary ASVT is more common and is associated with an easily identified cause such as an indwelling catheter or a hyper-coagulable state. Over 30% of patients with tunneled subclavian vein access devices develop ASVT.89A patient with ASVT may be asymptomatic or may pres-ent with varying degrees of upper extremity edema, tenderness, and conspicuous superficial venous enlargement. DUS can be performed initially to confirm the diagnosis, but limitations to the exam by the clavicle and collateralization can lead to a false-negative study. Venography is recommended when there is nonconcordance between the duplex study and clinical suspi-cion. Anticoagulation therapy should be initiated once ASVT is diagnosed to prevent PE and decrease symptoms.Treatment of patients with primary upper extremity venous thrombosis is controversial because the natural history of the disease may vary from minimal to no symptoms to significant symptoms with vigorous upper extremity activities. In recent years, patients presenting with acute symptomatic primary ASVT are often considered candidates for CDT therapy with the goal of minimizing long-term symptoms of venous congestion. Venography is performed through a catheter placed using an ultrasound-guided percutaneous basilic vein approach to docu-ment the extent of the thrombus (Fig. 24-13). A guidewire is traversed through the thrombus, and a catheter is placed within the thrombus. Typically, tissue plasminogen activator is admin-istered through a multi–side-hole infusion catheter. Various catheter-based mechanical techniques may also be employed to speed thrombus removal. Heparin is administered concurrently with the thrombolytic infusion. After completion of thrombo-lytic therapy, a follow-up venogram is obtained. Correctable anatomic abnormalities may then be considered for treatment. Adjuvant procedures after thrombolytic therapy may include Brunicardi_Ch24_p0981-p1008.indd 99522/02/19 3:01 PM 996SPECIFIC CONSIDERATIONSPART IIcervical or first rib resection for thoracic outlet abnormalities, scalenectomy, surgical venous reconstruction, and balloon angioplasty of residual venous stenosis.90 The ACCP guidelines recommend the same intensity and duration of anticoagulant therapy in patients who undergo thrombolysis as in patients who are treated with anticoagulation alone.Mesenteric Vein ThrombosisFive percent to 15% of cases of acute mesenteric ischemia occur as a result of mesenteric vein thrombosis (MVT). Mortality rates in patients with MVT may approach 50%.91 The usual present-ing symptom is nonspecific abdominal pain and distention, often accompanied by nausea, vomiting, and diarrhea.92 Perito-neal signs, suggesting intestinal infarction, are present in fewer than half of MVT patients. MVT is more common in patients with a hypercoagulable states, malignancy, and cirrhosis. MVT also occurs as a rare complication of laparoscopic surgery.92,93Most cases of MVT are diagnosed with contrast-enhanced CT scanning or magnetic resonance imaging (MRI) in the course of an evaluation for abdominal pain. The sensitivity and speci-ficity for CT and MRI approach 100% and 98%, respectively.94 Ultrasound can also be used and has reported sensitivity and specificity of 93% and 99%, respectively.Patients with MVT are treated with fluid resuscitation, heparin anticoagulation, and bowel rest. Once the patient’s clinical status improves, oral intake can be carefully started. The patient is transitioned to oral anticoagulation over 3 to 4 days and, depending on the etiology of the MVT, continued for 3 to 6 months or indefinitely. Most patients with MVT can be treated nonoperatively, but urgent laparotomy is indicated in patients with peritoneal findings. Broad-spectrum antibiotics are admin-istered perioperatively. Operative findings consist of edema and cyanotic discoloration of the mesentery and bowel wall. In more advanced cases, thrombus involves the distal mesenteric veins. The arterial supply to the involved bowel is usually intact. Nonviable bowel is resected, and primary anastomosis can be performed. If the viability of the remaining bowel is in question, a second-look operation is performed within 24 to 48 hours.VARICOSE VEINSVaricose veins are common and are present in at least 10% of the general population.95 The findings of varicose veins may include dilated and tortuous veins, telangiectasias, and fine reticular varicosities. Risk factors for varicose veins include obesity, female sex, inactivity, and family history.96 Varicose veins can be classified as primary or secondary. Primary vari-cose veins result from intrinsic abnormalities of the venous wall, whereas secondary varicose veins are associated with deep and/or superficial venous insufficiency.Patients with varicose veins may complain of unsightly appearance, aching, heaviness, pruritus, and early fatigue of the affected leg. These symptoms worsen with prolonged standing and sitting and are relieved by elevation of the leg above the level of the heart. A mild amount of edema is often present. More severe signs include thrombophlebitis, hyperpigmentation, lipodermato-sclerosis, ulceration, and bleeding from attenuated vein clusters.An important component of treatment for patients with vari-cose veins is the use of elastic compression stockings. Patients may be prescribed elastic stockings with compression ranging from 20 to 30, 30 to 40, or even 40 to 50 mmHg. Stockings range in length from knee high to waist high, and they should cover the symptomatic varices. Elastic compression provides sufficient relief of symptoms in many symptomatic patients.Cosmetic concerns may lead to intervention. Addition-ally, interventions are warranted in patients whose symptoms worsen or are unrelieved despite compression therapy or who have lipodermatosclerosis or venous ulcer. Randomized trials of symptomatic patients with varicose veins have demonstrated improved quality of life with interventional treatment. Interven-tional management includes injection sclerotherapy, thermal ablation, surgical therapy, or a combination of these techniques. Injection sclerotherapy alone can be successful in varicose veins and in telangiectatic vessels. A recent multicenter, randomized trial compared foam sclerotherapy versus placebo for symp-tomatic varicose veins found significant symptom relief and improved cosmetic appearance with sclerotherapy.97 Sclero-therapy acts by destroying the venous endothelium. Scleros-ing agents include hypertonic saline, sodium tetradecyl sulfate, and polidocanol. Concentrations of 11.7% to 23.4% hypertonic saline, 0.125% to 0.250% sodium tetradecyl sulfate, and 0.5% polidocanol are used for telangiectasias. Larger varicose veins require higher concentrations: 23.4% hypertonic saline, 0.50% to 1% sodium tetradecyl sulfate, and 0.75% to 1.0% polidocanol.92 Elastic bandages are wrapped around the leg after injection and worn continuously for 3 to 5 days to produce apposition of the inflamed vein walls and prevent thrombus formation. After the bandages are removed, elastic compression stockings should be worn for a minimum of 2 weeks. Complications from sclero-therapy include allergic reaction, local hyperpigmentation, thrombophlebitis, DVT, and possible skin necrosis.Newer devices combine sclerotherapy with catheter-based mechanical endoluminal injury to achieve nonthermal ablation.98 Additional nonthermal, nonsclerosant ablative techniques using proprietary adhesive formulations with cyanoacrylate are current being evaluated and have demonstrated promising early results.99Patients with symptomatic GSV or SSV reflux may be treated with endovenous ablation techniques or surgical removal of the affected vein. Endovenous laser and radiofrequency abla-tion (RFA) techniques have gained in popularity in the past several years. Such techniques are generally associ-ated with equally effective but more rapid postprocedure recov-ery than traditional open surgical stripping of the GSV.With either endoluminal technique, the distal thigh or proximal calf GSV is punctured with a 21-gauge needle under ultrasound guidance. A sheath is placed over a guidewire, and the laser fiber or RFA catheter is advanced until it is near to, but not at, the saphenofemoral junction. Tumescent anesthetic is administered around the GSV, and the vein is treated as the catheter is withdrawn. Endovenous laser treatment and RFA result in durable ablation of the GSV, with rates of varicose vein recurrence and clinical severity scores comparable to those seen with open surgery.100,101 Risks of endovenous ablation include DVT, ecchymosis, and saphenous nerve injury.Saphenous vein ligation and stripping may still be the pre-ferred therapy for patients with GSVs of very large diameter (>2 cm). Surgical removal of the GSV usually is performed via small incisions placed medially in the groin and just below the knee. The GSV is removed using a blunt tip catheter or an invagi-nation pin stripper. Complications associated with GSV stripping include ecchymosis, hematoma, lymphocele, DVT, infection, and saphenous nerve injury. GSV stripping is associated with a lower rate of recurrence of varicose veins and a better quality of life than saphenofemoral junction ligation alone.4Brunicardi_Ch24_p0981-p1008.indd 99622/02/19 3:01 PM 997VENOUS AND LYMPHATIC DISEASECHAPTER 24Figure 24-14. Removal of varicose veins via stab avulsions.Larger varicose veins are best treated by surgical exci-sion using the “stab avulsion” technique. Stab avulsions are performed by making 2-mm incisions directly over branch varicosities, and the varicosity is dissected from the surrounding subcutaneous tissue as far proximally and distally as possible through the small incisions (Fig. 24-14). In most cases the vein is simply avulsed with no attempt at ligation. Bleeding is easily controlled with leg elevation, manual compression, and prepro-cedure tumescent anesthesia.CHRONIC VENOUS INSUFFICIENCYChronic venous insufficiency (CVI) affects an estimated 600,000 people in the United States.102 Patients complain of leg fatigue, discomfort, and heaviness. Signs of CVI may include varicose veins, pigmentation, lipodermatosclerosis, and venous ulceration. Importantly, severe CVI is not necessarily associ-ated with varicose veins. Chronic venous ulcers carry significant negative physical, financial, and psychological implications. A quality-of-life study reported that 65% of patients with chronic leg ulcers had severe pain, 81% had decreased mobility, and 100% experienced a negative impact of their disease on their work capacity.103 The socioeconomic impact of chronic venous leg ulcers is staggering, with an estimated 2 million workdays lost per year.102 The annual healthcare cost in the United States to treat CVI is estimated at $1 billion.105CVI can be primary or secondary. Primary CVI results from intrinsic abnormalities of the vein wall, whereas second-ary CVI, so-called postthrombotic syndrome (PTS), occurs as a result of DVT. The signs and symptoms of CVI can therefore be attributed to venous reflux, venous obstruction, calf muscle pump dysfunction, or a combination of these factors, as well as loss of venous wall elasticity.106 In the majority of patients with CVI, the most important factor appears to be venous reflux, although most severe cases tend to have an obstructive etiology as well. Venous reflux results from abnormalities of the venous valve. Primary valvular reflux or incompetence is diagnosed when there is no known underlying cause of valvular dysfunction. Secondary valvular reflux is diagnosed when an identifiable cause is present. The most frequent secondary cause is DVT.Evaluation of Venous InsufficiencyEarly diagnostic studies to evaluate CVI required invasive mea-surements of ambulatory venous pressure (AVP) and venous recovery time (VRT). To measure AVP and VRT, a needle is inserted into a dorsal foot vein and connected to a pressure transducer. The patient is asked to perform 10 tiptoe exercises. Initially there is often a slight upward deflection of pressure with the onset of exercise followed by a decline in pressure with each subsequent tiptoe maneuver. After approximately 10 tiptoes, the measured pressure stabilizes and reflects a bal-ance of venous inflow and outflow. The pressure at this point is the AVP, which is measured in millimeters of mercury. The patient is then asked to stop exercising to allow the vein to fill with return of the venous pressure to baseline. The time required for the venous pressure to return from the AVP level to 90% of baseline pressure is referred to as the VRT. A normal VRT typically ranges from 20 to 60 seconds. Values less than 20 seconds indicate significant reflux with increasing severity. To distinguish between superficial and deep venous reflux, a thigh tourniquet can be placed inflated to 50 mmHg to eliminate influence of the superficial venous. A VRT that remains below 20 seconds after tourniquet inflation suggests both superficial and deep venous reflux. Elevations of AVP indicate venous hypertension. The magnitude of AVP reflects the severity of CVI. There is an 80% incidence of venous ulceration in patients with an AVP of >80 mmHg.107Plethysmography. Noninvasive plethysmography has been used to evaluate CVI. Venous photoplethysmography indirectly evaluates venous function through the use of infrared light. A light-emitting diode is placed just above the medial malleolus, and the patient then performs a series of tiptoe maneuvers. Pho-toplethysmography provides a measurement of VRT. In limbs with CVI, VRT is shortened compared with that in a normal limb. AVP and VRT are only measures of the overall venous function of a lower extremity venous system. They cannot local-ize the site of reflux or evaluate the function of the calf pump.Air plethysmography is a theoretically attractive but not widely used method to assess calf pump function, venous reflux, and overall lower extremity venous function.108 An air-filled plastic pressure bladder is placed on the calf to detect volume changes in the leg during a standard set of maneuvers. The patient is first supine, and then the leg is elevated and the minimum volume of venous blood recorded. The patient is then asked to assume an upright position with the examined leg non-weight bearing. The venous volume of the examined leg is determined when the volume curve flattens. The venous fill-ing index (VFI), a measure of reflux, is calculated by dividing the maximum venous volume by the time required to achieve maximum venous volume. Next, the patient performs a single tiptoe maneuver, and the ejection fraction (EF) is determined. The EF is the volume change between the recorded volume before and after the tiptoe maneuver and is a measure of calf pump function. At this point, the veins of the leg are allowed to refill. The patient then performs 10 tiptoe maneuvers, and the residual volume fraction is calculated by dividing the venous volume in the leg after 10 tiptoe exercises by the venous volume present before the exercises. The residual volume fraction is a reflection of overall venous function. Theoretically, patients with increased VFIs and normal EFs (indicating the presence of reflux with normal calf pump function) would benefit from anti-reflux surgery, whereas patients with normal VFIs and dimin-ished EFs would not.Venous Duplex Ultrasound. Venous DUS has become the gold standard for evaluation of venous function largely supplanting venographic and plethysmographic techniques. Brunicardi_Ch24_p0981-p1008.indd 99722/02/19 3:01 PM 998SPECIFIC CONSIDERATIONSPART IIFigure 24-15. Evaluation of a patient with chronic venous insuf-ficiency with duplex ultrasonography.Figure 24-16. Multilayered dressing for treatment of chronic venous insufficiency.The principle advantage of DUS is that it can be used to evalu-ate reflux in individual venous segments targeting abnormal areas for treatment. The examination has been validated when performed with the patient in the standing position and the examined leg non-weight bearing. Pneumatic pressure cuffs of appropriate size are placed around the thigh, calf, and fore-foot. The ultrasound transducer is positioned over the venous segment to be examined, just proximal to the pneumatic cuff (Fig. 24-15). The cuff is then inflated to a standard pressure for 3 seconds and then rapidly deflated. Ninety-five percent of normal venous valves close within 0.5 second.109 The presence of reflux for >0.5 second is considered abnormal. Typically, the common femoral, femoral, popliteal, and posterior tibial veins, as well as the GSV and SSV, are evaluated in a complete examination.Nonoperative Treatment of Chronic Venous Insufficiency Compression Therapy. Compression therapy is the mainstay of CVI management. Compression can be achieved using a vari-ety of techniques, including elastic compression stockings, paste gauze boots (Unna’s boots), multilayer elastic wraps or dressings (Fig. 24-16), and pneumatic compression devices. Nonelastic compression bandages generally achieve higher and more prolonged degrees of compression than elastic compression bandages. The exact mechanism by which compression therapy can improve CVI remains uncertain. An improvement in skin and 5subcutaneous tissue microcirculatory hemodynamics as well as a direct effect on subcutaneous pressure have been hypothesized as the mechanisms of efficacy of compression therapy.110 Addition-ally, compression therapy has demonstrated quantifiable differ-ences in ulcer healing with decreases in matrix metalloproteins and inflammatory cytokines.111,112 Clinically, routine use of elastic and nonelastic bandages reduces lower extremity edema in patients with CVI. In addition, supine perimalleolar subcutaneous pressure has been demonstrated to increase with elastic compression.111 With edema reduction, cutaneous metabolism may improve due to enhanced diffusion of oxygen and other nutrients to the cellular elements of skin and subcutaneous tissues. Increases in subcutaneous tissue pressure with elastic compres-sion bandages may counteract transcapillary Starling forces, which favor leakage of fluid out of the capillary.Before the initiation of therapy for CVI, patients must be educated about their chronic disease and the need to comply with their treatment plan to heal ulcers and prevent recurrence. A definitive diagnosis of venous ulceration must be made before treatment is initiated. A detailed history should be obtained from a patient presenting with lower extremity ulcerations, includ-ing medications used and associated medical conditions that may promote lower extremity ulceration. Arterial insufficiency is assessed by physical examination or noninvasive studies. In addition, systemic conditions that affect wound healing and leg edema, such as diabetes mellitus, immunosuppression, mal-nutrition, and congestive heart failure, should be improved as much as possible.Compression therapy is most commonly achieved with graduated elastic compression stockings. Elastic compression stockings are available in various compositions, strengths, and lengths, and can be customized for a particular patient. The ben-efits of elastic compression stocking therapy for the treatment of CVI and healing of ulcerations have been well documented.114-117 In a retrospective study involving 113 venous ulcer patients,115 the use of below-knee, 30to 40-mmHg elastic compression stockings, after edema and cellulitis were first resolved if pres-ent, resulted in 93% healing. Complete ulcer healing occurred in 99 of 102 patients (97%) who were compliant with stocking use vs. 6 of 11 patients (55%) who were noncompliant (P <.0001). The mean time to ulcer healing was 5 months. The rate of ulcer recurrence was lower in patients who were compliant with their compression therapy. By life table analysis, ulcer recurrence was 29% at 5 years for compliant patients and 100% at 3 years for noncompliant patients.In addition to promoting ulcer healing, elastic compres-sion therapy can also improve quality of life in patients with CVI. In one prospective study,118 112 patients with CVI docu-mented by DUS were administered a questionnaire to quantify the symptoms of swelling, pain, skin discoloration, cosmesis, activity tolerance, depression, and sleep alterations. Patients were treated with 30to 40-mmHg elastic compression stock-ings. There were overall improvements in symptom severity scores at 1 month after initiation of treatment. Further improve-ments were noted at 16 months after treatment.Patient compliance with compression therapy is crucial in treating CVI and especially venous leg ulcers. Many patients are initially intolerant of compression in areas of hypersensitiv-ity adjacent to an active ulcer or at sites of previously healed ulcers. They may also have difficulty applying elastic stockings. To improve compliance, patients should be instructed to wear their stockings initially only as long as it is easily tolerated and Brunicardi_Ch24_p0981-p1008.indd 99822/02/19 3:01 PM 999VENOUS AND LYMPHATIC DISEASECHAPTER 24Figure 24-17. Elastic compression device with Velcro to facilitate treatment of chronic venous insufficiency.then gradually to increase the amount of time the stockings are worn. Alternatively, patients can be fitted with lower-strength stockings initially followed by introduction of higher-strength stockings over a period of several weeks. Many commercially available devices, such as silk inner toe liners, adjustable elas-tic compression with Velcro, stockings with zippered sides (Fig. 24-17), and metal fitting aids (Fig. 24-18), are available to assist patients in applying elastic stockings. However, despite all these available adjuncts, many patients remain noncompliant with elastic compression therapy.Another method of compression was developed by the German dermatologist Paul Gerson Unna. Unna’s boot has been used for many years to treat venous ulcers and is available in many versions. A typical Unna’s boot consists of a three-layer dressing and requires application by trained personnel. A rolled gauze bandage impregnated with calamine, zinc oxide, glyc-erin, sorbitol, gelatin, and magnesium aluminum silicate is first applied with graded compression from the forefoot to just below the knee. The next layer consists of a 10-cm-wide continuous gauze dressing followed by an outer layer of elastic wrap, also applied with graded compression. The bandage becomes stiff after drying, and the rigidity may aid in preventing edema for-mation. Unna’s boot is changed weekly or sooner if the patient experiences significant drainage and soiling of the dressing.Once applied, Unna’s boot requires minimal patient involvement and provides continuous compression and topical therapy. However, Unna’s boot has several disadvantages. It Figure 24-18. Metal fitting aid to assist in placement of elastic compression stockings.is bulky and can be uncomfortable, which may affect patient compliance. In addition, the ulcer cannot be monitored after the boot is applied, the technique is labor intensive, and the degree of compression provided is operator dependent. Occasionally, patients may also develop contact dermatitis to the components of Unna’s boot.The efficacy of Unna’s dressing has been studied. A ret-rospective 15-year survey encompassing 998 patients with one or more venous ulcers treated weekly with Unna’s dressing119 reported that 73% of ulcers healed in patients who returned for more than one treatment. The median time to healing for individual ulcers was 9 weeks. Unna’s dressing has been com-pared to other forms of treatment. A randomized, prospective study comparing Unna’s boot to polyurethane foam dressing in 36 patients with venous ulcers demonstrated superior healing over 12 months in patients treated with Unna’s boot (94.7% vs. 41.2%).120 A recent Cochrane Review of 39 randomized controlled trials demonstrated that compression increases ulcer healing rates compared with no compression, multicomponent systems are more effective than single-component systems, and multicomponent systems that include an elastic bandage are more effective than those composed mainly of inelastic constituents.121Other forms of compression dressing available to treat CVI include multilayered dressings and legging orthoses. The purported advantages of multilayered dressings include main-tenance of compression for a longer period of time, more even distribution of compression, and better absorption of wound Brunicardi_Ch24_p0981-p1008.indd 99922/02/19 3:01 PM 1000SPECIFIC CONSIDERATIONSPART IIFigure 24-19. Apligraf skin graft material supplied as a disk on an agarose gel nutrient medium.Figure 24-20. Trocar placement for subfascial endoscopic perfo-rator vein surgery. (Used with permission from Dr. Pankaj Patel.)exudates. However, the efficacy of multilayered dressings depends on the wrapping technique of healthcare personnel. A commercially available legging orthosis consisting of multiple adjustable loop-and-hook closure compression bands provides compression similar to that of Unna’s boot and can be applied daily by the patient.122Skin Substitutes. Several types of skin substitutes are com-mercially available or under clinical study in the United States.105 Bioengineered skin ranges in composition from acellular skin substitutes to partial living skin substitutes. Their mechanism of action in healing venous ulcers is uncertain; however, they may serve as delivery vehicles for various growth factors and cytokines important in wound healing.Apligraf is a commercially available bilayered living skin construct that closely approximates human skin for use in the treatment of venous ulcers. It contains a protective stratum corneum and a keratinocyte-containing epidermis overlying a dermis consisting of dermal fibroblasts in a collagen matrix.122 Apligraf is between 0.5 mm and 1.0 mm thick and is supplied as a disk of living tissue on an agarose gel nutrient medium. It must be used within 5 days of release from the manufacturer123 (Fig. 24-19). The disk is easily handled and applied and con-forms to irregularly contoured ulcer beds though it is very costly.A prospective randomized study comparing multilayer compression therapy alone to treatment with Apligraf in addi-tion to multilayered compression therapy has been performed to assess the efficacy of Apligraf in the treatment of venous ulcers.118 More patients treated with Apligraf had ulcer healing at 6 months (63% vs. 49%, P = .02). The median time to com-plete ulcer closure was significantly shorter in patients treated with Apligraf (61 days vs. 181 days, P = .003). The ulcers that showed the greatest benefit with the living skin construct were ones that were large and deep (>1000 mm2) or were longstand-ing (>6 months). No evidence of rejection or sensitization has been reported in response to Apligraf application.Surgical/Interventional Treatment of Chronic Venous Insufficiency Perforator Vein Ligation. Incompetence of the perforating veins connecting the superficial and deep venous systems of the lower extremities has been implicated in the development of venous ulcers. The classic open tech-nique described by Linton in 1938 for perforator vein ligation has a high incidence of wound complications and has largely been abandoned.124 A minimally invasive technique termed subfascial endoscopic perforator vein surgery (SEPS) evolved with improvement of endoscopic equipment.DUS is performed preoperatively in patients undergoing SEPS to document deep venous competence and to identify per-forating veins in the posterior compartment. The patient is posi-tioned on the operating table with the affected leg elevated at 45° to 60°. An Esmarch bandage and a thigh tourniquet are used to exsanguinate the limb. The knee is then flexed, and two small incisions are made in the proximal medial leg away from areas of maximal induration at the ankle. Laparoscopic trocars are then positioned, and the subfascial dissection is performed with a combination of blunt and sharp dissection. Carbon dioxide is then used to insufflate the subfascial space. The thigh tourni-quet is inflated to prevent air embolism. The perforators are then identified and doubly clipped and divided. After completion of the procedure, the leg is wrapped in a compression bandage for 5 days postoperatively.The efficacy of SEPS as a stand-alone procedure in treatment of venous insufficiency is controversial and unproven. In a report from a large North American registry of 146 patients undergoing SEPS125 (Fig. 24-20), healing was achieved in 88% of ulcers (75 of 85) at 1 year. Adjunctive procedures, primarily superficial vein stripping, were performed in 72% of patients. Ulcer recurrence was predicted to be 16% at 1 year and 28% at 2 years by life table analysis. These results are similar to those achieved in some studies with compression therapy alone. A review of several studies from 2003 to 2011 demonstrated, when taken in aggregate, that 2059 limbs with 896 ulcers underwent SEPS and concomitant saphenous vein ablation (70%) with a 0% to 16% complication rate and achieved ulcer healing in 90% of patients.126 There has been a multicenter, prospective, European trial performed in patients with venous ulcers to evaluate the efficacy of SEPS. Post hoc analysis suggested possible benefit for SEPS in certain categories of patients with venous ulcer. Overall, however, primary analysis of the study’s end points indicated no advantage to SEPS in addition to superficial venous surgery and compression in the healing of venous ulcers.127 The technique appears to have fallen out of favor in most institutions with injection sclerotherapy preferred due to ease of use.Superficial Venous Surgery. Currently it is accepted that superficial venous surgery in addition to compression therapy has a role in the treatment of patients with venous ulcer. The ESCHAR trial was a randomized prospective trial performed in the United Kingdom to evaluate the combination of superficial Brunicardi_Ch24_p0981-p1008.indd 100022/02/19 3:01 PM 1001VENOUS AND LYMPHATIC DISEASECHAPTER 24Figure 24-21. Patient with severe longstanding lymphedema.venous surgery and compression vs. compression alone in the treatment of venous ulcer. Superficial venous surgery had no additive effect to compression alone in the healing of a venous ulcer but significantly reduced venous ulcer recurrence at 4 years. Based on the results of this trial, it is reasonable to offer ablation or removal of the GSV in addition to compression therapy in patients with abnormal saphenous veins and signs and/or symptoms of severe CVI.128Deep Venous Valvular Reconstruction. In the absence of sig-nificant deep vein valvular incompetence, saphenous vein stripping and possibly perforator vein ligation can be effective in the treat-ment of CVI. However, in patients with a combination of superfi-cial and deep vein valvular incompetence, the addition of deep vein valvular reconstruction theoretically may improve ulcer healing.130 Numerous techniques of deep vein valve correction have been reported. These techniques consist of repair of existing valves, transplant of venous segments from the arm, transposition of an incompetent vein onto an adjacent competent vein, and implanta-tion of cryopreserved vein segments including competent valves.Successful long-term outcomes of 60% to 80% have been reported for venous valve reconstructions by internal suture repair.129,130 However, among patients who initially had ulcer-ation, 40% to 50% still had persistence or recurrence of ulcers in the long term.127,129Valve transplantation involves replacement of a segment of incompetent femoral vein or popliteal vein with a segment of axillary or brachial vein with competent valves. Early results are similar to those for venous valve reconstruction.129,130 How-ever, in the long term, the transplanted venous segments tend to develop incompetence, intimal hyperplasia, and cusp sinus thrombosis with long-term outcomes that are poorer than those for venous valve reconstructions. The outcomes for venous transposition are similar to those for valve transplantation.Currently, reconstruction techniques for deep venous insufficiency and associated CVI are rarely performed.Venous Stenting. Currently there is great interest in the role of venous stents in the treatment of CVI. Stenotic lesions of the iliac veins, primarily documented with IVUS, are being reported in a very high percentage of patients with edema, lipo-dermatosclerosis, or ulceration secondary to venous disease. It appears possible to percutaneously place stents in the iliac veins with near 100% technical success and excellent patency of the stent out to 4 years. Retrospective case series suggest favorable effects on ulcer healing, symptoms of CVI, and quality of life in patients with CVI. The role of venous stenting as an indepen-dent procedure in the treatment of patients with CVI remains an area of active investigation.131LYMPHEDEMAPathophysiologyLymphedema is extremity swelling that results from a reduction in lymphatic transport and accumulation of lymph within the interstitial space. It is caused by anatomic and or physiologic abnormalities such as lymphatic hypoplasia, functional insuf-ficiency, or absence of lymphatic valves.The original classification system, described by Allen, is based on the cause of the lymphedema. Primary lymphedema is further subdivided into congenital lymphedema, lymph-edema praecox, and lymphedema tarda. Congenital lymph-edema may involve a single lower extremity, multiple limbs, the genitalia, or the face. The edema typically develops before 2 years 6of age and may be associated with specific hereditary syndromes (Turner syndrome, Milroy syndrome, Klippel-Trénaunay-Weber syndrome). Lymphedema praecox is the most common form of primary lymphedema, accounting for 94% of cases. Lymphedema praecox is far more common in women, with the gender ratio favoring women 10:1. The onset is during childhood or the teen-age years, and the swelling involves the foot and calf. Lymph-edema tarda is uncommon, accounting for <10% of cases of primary lymphedema. The onset of edema is after 35 years of age.Secondary lymphedema is far more common than primary lymphedema. Secondary lymphedema develops as a result of lymphatic obstruction or disruption. Axillary node dissection leading to lymphedema of the arm is the most common cause of secondary lymphedema in the United States. Other causes of secondary lymphedema include radiation therapy, trauma, infection, and malignancy. Globally, filariasis (an infection caused by Wuchereria bancrofti, Brugia malayi, and Brugia timori) and environmental exposure to minerals in volcanic soil resulting in podoconiosis in barefoot populations are the most common causes of secondary lymphedema.Clinical DiagnosisIn most patients, the diagnosis of lymphedema can be made based on the history and physical examination alone. Patients commonly complain of heaviness and fatigue in the affected extremity. The limb size increases throughout the day and decreases to some extent, usually minimally, over the course of the night when the patient is recumbent. The limb, however, never completely nor-malizes. In the lower extremity, the swelling classically involves the dorsum of the foot, and the toes have a squared-off appear-ance. In advanced cases, hyperkeratosis of the skin develops, and fluid weeps from lymph-filled vesicles (Fig. 24-21).Brunicardi_Ch24_p0981-p1008.indd 100122/02/19 3:01 PM 1002SPECIFIC CONSIDERATIONSPART IIFigure 24-22. Lymphoscintigraphy of the lower extremity.Figure 24-23. Normal lymphangiogram of the pelvis.Recurrent cellulitis is a common complication of lymph-edema. Repeated infection results in further lymphatic damage, worsening existing disease. The clinical presentation of cellu-litis ranges from subtle erythema and worsening of edema to a rapidly progressive soft tissue infection with systemic toxicity.Many medical conditions can cause edema. If the symp-toms are mild, distinguishing lymphedema from other causes of leg swelling can be difficult. Venous insufficiency is often confused with lymphedema. However, patients with advanced venous insufficiency typically have lipodermatosclerosis in the gaiter region, skin ulceration, and/or varicose veins. Bilateral pitting edema is typically associated with congestive heart fail-ure, renal failure, or a hypoproteinemic state.Radiologic DiagnosisDuplex Ultrasound. When a patient is evaluated for edema, it is often difficult to distinguish the early stages of lymphedema from venous insufficiency. DUS of the venous system can determine if there is concomitant venous thrombosis or venous reflux, perhaps contributing to extremity edema. The diagnostic modalities discussed in the following sections have limited use in clinical practice. They are invasive and tedious and rarely change the management of a patient with lymphedema. Most physicians rely on the patient’s history and physical examina-tion alone to make the diagnosis of lymphedema.Lymphoscintigraphy. Lymphoscintigraphy has become the most commonly, but still overall uncommonly, used diagnostic test to identify lymphatic abnormalities. It has largely replaced lymphangiography. A radiolabeled sulfur colloid (technetium 99 m sulfur colloid) is injected into the subdermal, interdigital region of the affected limb. The lymphatic transport is moni-tored with a whole-body gamma camera, and major lymphatics and nodes can be visualized (Fig. 24-22). In normal individu-als, tracer activity may be detected in the inguinal region within 15 to 60 minutes. Within 3 hours, uptake should be present in the pelvic and abdominal lymph nodes. In patients with lymph-edema, various patterns may be seen on lymphoscintigraphy. There may be delayed or absent transport to the inguinal nodes. Increased cutaneous collaterals may be seen with obstruction of the primary axial channels. There may also be localized regions of reduced uptake in patients with prior node dissection or radia-tion therapy.Lymphangiography. Radiologic lymphangiography is per-formed by first visualizing the lymphatics by injecting colored dye into the hand or foot. The visualized lymphatic segment is exposed through a small incision and cannulated with a 27to 30-gauge needle. An oil-based dye is then injected slowly into the lymphatics over several hours. The lym-phatic channels and nodes are then visualized with traditional radiographs (Figs. 24-23 and 24-24). Lymphangiography is reserved for patients with lymphangiectasia or lymphatic fis-tulas, and patients who are being considered for microvascular reconstruction.ManagementAn important aspect of the management of lymphedema is patient understanding that there is no cure for lymphedema. The primary goals of treatment are to minimize swelling and to prevent recurrent infections. Controlling the chronic limb swelling can improve discomfort, heaviness, and tightness, and potentially reduce the progression of disease.132Brunicardi_Ch24_p0981-p1008.indd 100222/02/19 3:01 PM 1003VENOUS AND LYMPHATIC DISEASECHAPTER 24Figure 24-24. Normal lymphangiogram of the thigh and lower leg.Compression Garments. Graded compression stockings are widely used in the treatment of lymphedema. The stockings reduce the amount of swelling in the involved extremity by decreasing edema accumulation while the extremity is dependent. When worn daily, compression stockings have been associated with long-term maintenance of reduced limb circumference.134 They may also protect the tissues against chronically elevated intrinsic pressures, which lead to thickening of the skin and sub-cutaneous tissue.135 Compression stockings also offer a degree of protection against external trauma that may lead to cellulitis.The amount of compression required for controlling lymphedema ranges from 20 to 60 mmHg and varies among patients. The stockings can be custom made or prefabricated and are available in aboveand below-knee lengths. The stock-ings should be worn during waking hours. The garments should be replaced approximately every 6 months when they lose elasticity.Bedrest and Leg Elevation. Elevation is an important aspect of controlling lower extremity swelling and is often the first recommended intervention. However, continuous elevation throughout the day can interfere with quality of life more than lymphedema itself. Elevation is an adjunct to lymphedema ther-apy but is not the mainstay of treatment.Intermittent Pneumatic Compression Therapy. The use of IPC with a single-chamber or multichamber pump temporar-ily reduces edema and provides another adjunct to the use of compression stockings. These devices have been shown to be effective in reducing limb volume; however, use of compres-sion stockings is necessary to maintain the volume reduction when the patient is no longer supine because fluid transport is not associated with the transport of macromolecules (proteins) from the tissue. Typically, IPC is used for 4 to 6 hours per day at home when the patient is supine, with pressure ranges between 30 and 60 mmHg demonstrated to be most effective.135Lymphatic Massage. Manual lymphatic drainage is a form of massage developed by Vodder136 that is directed at reduc-ing edema. In combination with the use of compression stock-ings, manual lymphatic drainage is associated with a long-term reduction in edema and fewer infections per patient per year.137Antibiotic Therapy. Patients with lymphedema are at increased risk of developing cellulitis in the affected extremity due to microscopic breakdown in the skin barrier either second-ary to swelling or unrecognized and untreated tinea pedis. Recur-rent infection can damage the lymphatics, aggravating the edema and increasing the risk for subsequent infection. Staphylococcus and β-hemolytic Streptococcus are the most common organisms causing soft tissue infection. Aggressive antibiotic therapy and elevation with compression are recommended at the earliest signs or symptoms of cellulitis. The drug of choice is penicil-lin or a cephalosporin active against Streptococcus for 5 days. In patients with recurrent cellulitis despite methods to reduced edema, treatment with monthly intramuscular injections of ben-zathine penicillin 1.2 MU, twice-daily erythromycin 250 mg, or penicillin V 1 g daily has proven effective at suppression.138Surgery. A variety of surgical procedures have been devised for the treatment of lymphedema. Surgical treatment involves either excision of extra tissue139 or anastomosis of a lymphatic vessel to another lymphatic or vein.140 In excisional procedures, part or all of the edematous tissue is removed. This does not improve lymphatic drainage but debulks redundant tissue. The microsurgical procedures involve the creation of a lymphati-colymphatic or lymphaticovenous anastomosis, which theo-retically improves lymphatic drainage. No long-term follow-up data are available for these interventions, and therefore opera-tive therapy for lymphedema is not well accepted worldwide. Furthermore, operative intervention has the potential to further obliterate lymphatic channels, worsening the edema.141SUMMARYLymphedema is a chronic condition caused by ineffective lymphatic transport, which results in edema and skin damage. Lymphedema is not curable, but the symptoms and long-term effects can be controlled with a combination of elastic com-pression stockings, limb elevation, pneumatic compression, and massage. Controlling the edema protects the skin and potentially prevents cellulitis.REFERENCESEntries highlighted in bright blue are key references. 1. Moncada S, Radomski MW, Palmer RM. Endothelium-derived relaxing factor. Identification as nitric oxide and role in the control of vascular tone and platelet function. Biochem Pharmacol. 1988;37:2495-2501. 2. van Bemmelen PS, Beach K, Bedford G, et al. The mecha-nism of venous valve closure. Its relationship to the velocity of reverse flow. Arch Surg. 1990;125:617-619. 3. Moneta GL, Strandness DE, Jr. Basic data concerning nonin-vasive vascular testing. Ann Vasc Surg. 1989;3:190-193. 4. Neglen P, Berry MA, Raju S. Endovascular surgery in the treatment of chronic primary and post-thrombotic iliac vein obstruction. Eur J Vasc Endovasc Surg. 2000;20(6):560-571. 5. Bettman MA, Robbins A, Braun SD, et al. Contrast venogra-phy of the leg: diagnostic efficacy, tolerance, and complica-tion rates with ionic and nonionic contrast media. Radiology. 1987;165:113-116.Brunicardi_Ch24_p0981-p1008.indd 100322/02/19 3:01 PM 1004SPECIFIC CONSIDERATIONSPART II 6. White R. The epidemiology of venous thromboembolism. Circulation. 2003;107:I4-I8. 7. Spyropoulos AC, Hussein M, Lin J, et al. Rates of symptom-atic venous thromboembolism in US surgical patients: a ret-rospective administrative database. J Thromb Thrombolysis. 2009;28:458-464. 8. Heit JA, Cohen AT, Anderson FA. Estimated annual number of incident and recurrent, non-fatal and fatal venous thromboem-bolism (VTE) events in the US. Blood. 2005;106:910. 9. Pengo V, Lensing AWA, Prins MH, et al. Incidence of chronic thromboembolic pulmonary hypertension after pulmonary embolism. N Engl J Med. 2004;350:2257-2264. 10. Kahn SR, Ginsberg JS. The post-thrombotic syndrome: current knowledge, controversies and directions for future research. Blood Rev. 2002;16:155-165. 11. Mohr DN, Silverstein MD, Heit JA, et al. The venous sta-sis syndrome after deep venous thrombosis or pulmonary embolism: a population-based study. Mayo Clin Proc. 2000;75:1249-1256. 12. Rosendaal FR. Risk factors for venous thrombotic disease. Thromb Haemost. 1999;82:610. 13. Ageno W, Becattini C, Brighton T, et al. Cardiovascular risk factors and venous thromboembolism: a meta-analysis. Circulation. 2008;117:93-102. 14. White R, Zhou H, Romano P. Incidence of idiopathic deep venous thrombosis and secondary thromboembo-lism among ethnic groups in California. Ann Intern Med. 1998;128:737-740. 15. Bezemer ID, Bare LA, Doggen CJM, et al. Gene variants asso-ciated with deep vein thrombosis. JAMA. 2008;299:1306-1314. 16. Rogers SO, Jr, Kilaru RK, Hosokawa P, et al. Multivariable predictors of postoperative venous thromboembolic events after general and vascular surgery: results from the Patient Safety in Surgery Study. J Am Coll Surg. 2007;204:1211-1221. 17. Bahl V, Hu HM, Henke PK, Wakefield TW, Campbell DA, Jr, Caprini JA. A validation study of retrospective venous thromboembolism risk scoring method. Ann Surg. 2010;251:344-350. 18. Markel A, Manzo RA, Bergelin RO, et al. Pattern and dis-tribution of thrombi in acute venous thrombosis. Arch Surg. 1992;127:305-309. 19. Nicolaides AN, Kakkar VV, Field ES, et al. The origin of deep vein thrombosis: a venographic study. Br J Radiol. 1971;44:653-663. 20. Brockman SK, Vasko JS. The pathologic physiology of phleg-masia cerulea dolens. Surgery. 1966;59:997-1007. 21. Lensing AW, Prandoni P, Brandjes D, et al. Detection of deep-vein thrombosis by real-time B-mode ultrasonography. N Engl J Med. 1989;320:342-345. 22. O’Leary DH, Kane RA, Chase BM. A prospective study of the efficacy of B-scan sonography in the detection of deep venous thrombosis in the lower extremities. J Clin Ultrasound. 1988;16:1-8. 23. Mussurakis S, Papaioannou S, Voros D, et al. Compression ultrasonography as a reliable imaging monitor in deep venous thrombosis. Surg Gynecol Obstet. 1990;171:233-239. 24. Habscheid W, Hohmann M, Wilhelm T, et al. Real-time ultra-sound in the diagnosis of acute deep venous thrombosis of the lower extremity. Angiology. 1990;41:599-608. 25. Comerota AJ, Katz ML, Grossi RJ, et al. The comparative value of noninvasive testing for diagnosis and surveillance of deep vein thrombosis. J Vasc Surg. 1988;7:40-49. 26. Gomes AS, Webber MM, Buffkin D. Contrast venography vs. radionuclide venography: a study of discrepancies and their possible significance. Radiology. 1982;142:719-728. 27. Hull R, Hirsh J, Sackett DL, et al. Clinical validity of a nega-tive venogram in patients with clinically suspected venous thrombosis. Circulation. 1981;64:622-625. 28. Kearon C, Akl E, Comerota A, et al. Antithrombotic ther-apy for venous thromboembolic disease: antithrombotic therapy and prevention of thrombosis. American College of Chest Physicians evidence-based clinical practice guidelines (9th edition). Chest. 2012;141(2 suppl):e419S-e496S. The most recent American College of Chest Physicians clinical practice guidelines on antithrombotic therapy for venous thromboembolic disease. These recommendations cover multimodality therapies and are based upon an exhaustive review of the literature, including randomized clinical trials. 29. Raschke RA, Reilly BM, Guidry JR, et al. The weight-based heparin dosing nomogram compared with a standard care nomogram. A randomized controlled trial. Ann Intern Med. 1993;119:874-881. 30. Hylek EM, Regan S, Henault LE, et al. Challenges to the effective use of unfractionated heparin in the hospital-ized management of acute thrombosis. Arch Intern Med. 2003;163:621-627. 31. Amiral J, Bridey F, Dreyfus M, et al. Platelet factor 4 com-plexed to heparin is the target for antibodies generated in heparin-induced thrombocytopenia. Thromb Haemost. 1992;68:95-96. 32. Warkentin TE, Levine MN, Hirsh J, et al. Heparin-induced thrombocytopenia in patients treated with low-molecular-weight heparin or unfractionated heparin. N Engl J Med. 1995;332:1330-1335. 33. Warkentin TE, Kelton JG. Heparin and platelets. Hematol Oncol Clin North Am. 1990;4:243-264. 34. Calaitges JG, Liem TK, Spadone D, et al. The role of heparin-associated antiplatelet antibodies in the outcome of arterial reconstruction. J Vasc Surg. 1999;29:779-786. 35. Warkentin TE, Kelton JG. A 14-year study of heparin-induced thrombocytopenia. Am J Med. 1996;101:502-507. 36. Gould MK, Dembitzer AD, Doyle RL, et al. Low-molecular-weight heparins compared with unfractionated heparin for treatment of acute deep venous thrombosis: a meta-anal-ysis of randomized, controlled trials. Ann Intern Med. 1999;130:800-809. 37. Dolovich LR, Ginsberg JS, Douketis JD, et al. A meta-analysis comparing low-molecular-weight heparins with unfraction-ated heparin in the treatment of venous thromboembolism: examining some unanswered questions regarding location of treatment, product type, and dosing frequency. Arch Intern Med. 2000;160:181-188. 38. Van Dongen CJJ, van der Belt AGM, Prins MH, et al. Fixed dose subcutaneous low molecular weight heparins versus adjusted dose unfractionated heparin for venous thromboem-bolism. Cochrane Database Syst Rev. 2004;4:CD001100. 39. Kikta MJ, Keller MP, Humphrey PW, et al. Can low molecular weight heparins and heparinoids be safely given to patients with heparin-induced thrombocytopenia syndrome? Surgery. 1993;114:705-710. 40. Koopman MM, Prandoni P, Piovella F, et al. Treatment of venous thrombosis with intravenous unfractionated heparin administered in the hospital as compared with subcutaneous low-molecular-weight heparin administered at home. The Tas-man Study Group. N Engl J Med. 1996;334:682-687. 41. Levine M, Gent M, Hirsh J, et al. A comparison of low-molecularweight heparin administered primarily at home with unfraction-ated heparin administered in the hospital for proximal deep-vein thrombosis. N Engl J Med. 1996;334:677-681. 42. Büller HR, Davidson BL, Decousus H, et al. Fondaparinux or enoxaparin for the initial treatment of symptomatic deep venous thrombosis: a randomized trial. Ann Intern Med. 2004;140:867-873. 43. The Matisse Investigators. Subcutaneous fondaparinux versus intravenous unfractionated heparin in the initial treatment of pulmonary embolism. N Engl J Med. 2003;349:1695-1702.Brunicardi_Ch24_p0981-p1008.indd 100422/02/19 3:01 PM 1005VENOUS AND LYMPHATIC DISEASECHAPTER 24 44. Warkentin TE, Maurer BT, Aster RH. Heparin-induced throm-bocytopenia associated with fondaparinux. N Engl J Med. 2007;356:2653-2655. 45. Kelton JG. The pathophysiology of heparin-induced thrombocytopenia: biological basis for treatment. Chest. 2005;127:9S-20S. 46. Martin K, Beyer-Westendorf J, Davidson BL, Huisman MV, Sandset PM, Moll S. Use of the direct oral anticoagulants in obese patients: guidance from the SSC of the ISTH. J Thromb Haemost. 2016;14(6):1308-1313. 47. Schulman S, Shortt B, Robinson M, Eikelboom JW. Adher-ence to anticoagulant treatment with dabigatran in a real-world setting. J Thromb Haemost. 2013;11(7):1295-1299. 48. Pollack CV, Jr, Reilly PA, Eikelboom J, et al. Idarucizumab for Dabigatran Reversal. N Engl J Med. 2015;373(6):511-520. 49. Eerenberg ES, Kamphuisen PW, Sijpkens MK, Meijers JC, Buller HR, Levi M. Reversal of rivaroxaban and dabigatran by prothrombin complex concentrate: a randomized, placebo-controlled, crossover study in healthy subjects. Circulation. 2011;124(14):1573-1579. 50. Holbrook A, Schulman S, Witt DM, et al. Evidence based management of anticoagulant therapy. American College of Chest Physicians Evidence-Based Clinical Practice Guide-lines, 9th ed. Chest. 2012;114:e152S-e184S. 51. Schulman S, Rhedin A-S, Lindmarker P, et al. A comparison of six weeks with six months of oral anticoagulant therapy after a first episode of venous thromboembolism. N Engl J Med. 1995;332:1661-1665. 52. Research Committee of the British Thoracic Society. Optimal duration of anticoagulation for deep vein thrombosis and pul-monary embolism. Lancet. 1992;340:873-876. 53. Levine MN, Hirsh J, Gent M, et al. Optimal duration of oral anticoagulant therapy: a randomized trial comparing four weeks with three months of warfarin in patients with proximal deep vein thrombosis. Thromb Haemost. 1995;74:606-611. 54. Kearon C, Gent M, Hirsh J, et al. A comparison of three months of anticoagulation with extended anticoagulation for a first episode of idiopathic venous thromboembolism. N Engl J Med. 1999;340:901-907. 55. Agnelli G, Prandoni P, Santamaria MG, et al. Three months versus one year of oral anticoagulant therapy for idiopathic deep venous thrombosis. N Engl J Med. 2001;345:165-169. 56. Ridker PM, Goldhaber SZ, Danielson E, et al. Long-term, low-intensity warfarin therapy for the prevention of recurrent venous thromboembolism. N Engl J Med. 2003;348:1425. 57. Kearon C, Ginsber JS, Kovacs MJ, et al. Comparison of low-intensity warfarin therapy with conventional-intensity warfarin therapy for long-term prevention of recurrent venous thrombo-embolism. N Engl J Med. 2003;349:631-639. 58. Lee AYY, Levine MN, Baker RI, et al. Low-molecular-weight heparin versus a coumarin for the prevention of recurrent venous thromboembolism in patients with cancer. N Engl J Med. 2003;349:146-153. 59. Akl EA, Barba M, Rohilla S, et al. Anticoagulation for the long term treatment of venous thromboembolism in patients with cancer. Cochrane Database Syst Rev. 2008;2:CD006650. 60. Watson LI, Armon MP. Thrombolysis for treatment of acute deep vein thrombosis. Cochrane Database Syst Rev. 2004;4:CD002783. 61. Vedantham S, Goldhaber S, Julian J, et al. Pharmacomechanical Catheter-Directed Thrombolysis for Deep-Vein Thrombosis. N Engl J Med. 2017;377:2240-2252. 62. Vedantham S, Goldhaber S, Julian, J, et al. Interventional ther-apy for prevention of the post-thrombotic syndrome: results of the NHLBI-sponsored ATTRACT trial. 2017. Unpublished manuscript. 63. Decousus H, Leizorovicz A, Parent F, et al. A clinical trial of vena caval filters in the prevention of pulmonary embolism in patients with proximal deep-vein thrombosis. Prévention du Risque d’Embolie Pulmonaire par Interruption Cave Study Group. N Engl J Med. 1998;338:409-415. 64. Becker DM, Philbrick JT, Selby JB. Inferior vena cava filters. Indications, safety, effectiveness. Arch Intern Med. 1992;152:1985-1994. 65. Morales JP, Li X, Irony TZ, Ibrahim NG, Moynahan M, Cavanaugh KJ Jr. Decision analysis of retrievable inferior vena cava filters in patients without pulmonary embolism. J Vasc Surg Venous Lymphat Disord. 2013;1(4):376-384. 66. Morales JP, Li X, Irony TZ, Ibrahim NG, Moynahan M, Cava-naugh KJ, Jr. Decision analysis of retrievable inferior vena cava filters in patients without pulmonary embolism. J Vasc Surg Venous Lymphat Disord. 2013;1(4):376-384. 67. Plate G, Ohlin P, Eklof B. Pulmonary embolism in acute ilio-femoral venous thrombosis. Br J Surg. 1985;72:912-915. 68. Eklof B, Kistner RL, Masuda EM. Surgical treatment of acute iliofemoral deep venous thrombosis. In: Gloviczki P, Yao JST, eds. Handbook of Venous Disorders. New York: Arnold; 2001:202. This chapter reviews outcomes following surgical treatment for acute iliofemoral deep venous thrombo-sis in addition to an illustrative review of surgical technique. 69. Juhan CM, Alimi YS, Barthelemy PJ, et al. Late results of ilio-femoral venous thrombectomy. J Vasc Surg. 1997;25:417-422. 70. Schmid C, Zietlow S, Wagner TO, et al. Fulminant pulmonary embolism: symptoms, diagnostics, operative technique, and results. Ann Thorac Surg. 1991;52:1102-1105. 71. Kieny R, Charpentier A, Kieny MT. What is the place of pulmonary embolectomy today? J Cardiovasc Surg. 1991;32:549-554. 72. Gulba DC, Schmid C, Borst HG, et al. Medical compared with surgical treatment for massive pulmonary embolism. Lancet. 1994;343:576-577. 73. Schmitz-Rode T, Janssens U, Schild HH, et al. Fragmentation of massive pulmonary embolism using a pigtail rotation cath-eter. Chest. 1998;114:1427-1436. 74. Greenfield LJ, Proctor MC, Williams DM, et al. Long-term experience with transvenous catheter pulmonary embolec-tomy. J Vasc Surg. 1993;18:450-457. 75. Gould MK, Garcia DA, Wren SM, et al. Prevention of VTE in nonorthopedic surgical patients: antithrombotic therapy and prevention of thrombosis, 9th ed: American College of Chest Physicians evidence-based clinical practice guidelines. Chest. 2012;141(2 suppl): e227S-e277S. The most recent American College of Chest Physicians clinical practice guidelines on prevention of venous thromboembolism in nonorthopedic surgical patients. These recommendations review evidence-based literature regarding perioperative venous thromboembolism prophylaxis. 76. Mismetti P, Laporte S, Darmon JY, et al. Meta-analysis of low molecular weight heparin in the prevention of venous throm-boembolism in general surgery. Br J Surg. 2001;88:913-930. 77. Agnelli G, Bergqvist D, Cohen AT, et al. Randomized clinical trial of postoperative fondaparinux versus perioperative dalte-parin for prevention of venous thromboembolism in high-risk abdominal surgery. Br J Surg. 2005;92:1212-1220. 78. Turpie AG, Bauer KA, Caprini JA, et al. Fondaparinux combined with intermittent pneumatic compression versus intermittent pneumatic compression alone for prevention of venous thrombo-embolism after abdominal surgery: a randomized, double-blind comparison. J Thromb Haemost. 2007;5:1854-1861. 79. Rogers FB, Shackford SR, Ricci MA, et al. Routine prophy-lactic vena cava filter insertion in severely injured trauma patients decreases the incidence of pulmonary embolism. J Am Coll Surg. 1995;180:641-647. 80. Rogers FB, Strindberg G, Shackford SR, et al. Five-year follow-up of prophylactic vena cava filters in high-risk trauma patients. Arch Surg. 1998;133:406-411.Brunicardi_Ch24_p0981-p1008.indd 100522/02/19 3:01 PM 1006SPECIFIC CONSIDERATIONSPART II 81. Millward SF, Oliva VL, Bell SD, et al. Gunther tulip retriev-able vena cava filter: results from the Registry of the Canadian Interventional Radiology Association. J Vasc Intervent Radiol. 2001;12:1053-1058. 82. Allen AW, Megargell JL, Brown DB, et al. Venous thrombosis associated with the placement of peripherally inserted central catheters. J Vasc Intervent Radiol. 2000;11:1309-1314. 83. Chengelis DL, Bendick PJ, Glover JL, et al. Progression of superficial venous thrombosis to deep vein thrombosis. J Vasc Surg. 1996;24:745-749. 84. Lutter KS, Kerr TM, Roedersheimer LR, et al. Superficial thrombophlebitis diagnosed by duplex scanning. Surgery. 1991;110:42-46. 85. Di Nisio M, Wichers IM, Middeldorp S. Treatment for superfi-cial thrombophlebitis of the leg. Cochrane Database Syst Rev. 2013(4):CD004982. 86. Decousus H, Prandoni P, Mismetti P, et al. Fondaparinux for the treatment of superficial-vein thrombosis in the legs. N Engl J Med. 2010;363(13):1222-1232. 87. Lohr JM, McDevitt DT, Lutter KS, et al. Operative manage-ment of greater saphenous thrombophlebitis involving the saphenofemoral junction. Am J Surg. 1992;164:269-275. 88. Ascer E, Lorensen E, Pollina RM, et al. Preliminary results of a nonoperative approach to saphenofemoral junction thrombo-phlebitis. J Vasc Surg. 1995;22:616-621. 89. Horne MK III, May DJ, Alexander HR, et al. Venographic surveillance of tunneled venous access devices in adult oncol-ogy patients. Ann Surg Oncol. 1995;2:174-178. 90. Landry GL, Liem TK. Endovascular management of Paget-Schroetter syndrome. Vascular. 2007;15:290-296. 91. Rhee RY, Gloviczki P, Jost C, et al. Acute mesenteric venous thrombosis. In: Gloviczki P, Yao JST, eds. Handbook of Venous Disorders. New York: Arnold; 2001:244. 92. Morasch MD, Ebaugh JL, Chiou AC, et al. Mesenteric venous thrombosis: a changing clinical entity. J Vasc Surg. 2001;34:680-684. 93. James AW, Rabl C, Westphalen AC, et al. Portomesenteric venous thrombosis after laparoscopic surgery: a systematic literature review. Arch Surg. 2009;144:520-526. 94. Bach AM, Hann LE, Brown KT, et al. Portal vein evaluation with US: comparison to angiography combined with CT arte-rial portography. Radiology. 1996;201:149-154. 95. Burkitt DP. Varicose veins, deep vein thrombosis, and haem-orrhoids: epidemiology and suggested aetiology. Br Med J. 1972;2:556-561. 96. Brand FN, Dannenberg AL, Abbott RD, et al. The epidemiol-ogy of varicose veins: the Framingham Study. Am J Prev Med. 1988;4:96-101. 97. Gibson K, Kabnick L, Varithena 013 Investigator G. A mul-ticenter, randomized, placebo-controlled study to evaluate the efficacy and safety of Varithena(R) (polidocanol endove-nous microfoam 1%) for symptomatic, visible varicose veins with saphenofemoral junction incompetence. Phlebology. 2017;32(3):185-193. 98. Witte ME, Reijnen MM, de Vries JP, Zeebregts CJ. Mechano-chemical Endovenous Occlusion of Varicose Veins Using the ClariVein(R) Device. Surg Technol Int. 2015;26:219-225. 99. Proebstle TM, Alm J, Dimitri S, et al. The European multi-center cohort study on cyanoacrylate embolization of refluxing great saphenous veins. J Vasc Surg Venous Lymphat Disord. 2015;3(1):2-7. 100. Lurie F, Creton D, Eklof B, et al. Prospective randomized study of endovenous radiofrequency obliteration (closure) versus ligation and vein stripping (EVOLVeS): two-year follow-up. Eur J Vasc Endovasc Surg. 2005;29:67-73. 101. Darwood RJ, Theivacumar N, Dellagrammaticas D, et al. Ran-domized clinical trial comparing endovenous laser ablation with surgery for the treatment of primary great saphenous varicose veins. Br J Surg. 2008;95:294-301. 102. Falanga V. Venous ulceration. J Dermatol Surg Oncol. 1993;19:764-771. 103. Phillips T, Stanton B, Provan A, et al. A study of the impact of leg ulcers on quality of life: financial, social, and psychologic implications. J Am Acad Dermatol. 1994;31:49-53. 104. Skin Substitute Consensus Development Panel. Nonoperative management of venous ulcers: evolving role of skin substi-tutes. Vasc Surg. 1999;33:197. 105. Abenhaim L, Kurz X. The VEINES study (VEnous Insuffi-ciency Epidemiologic and Economic Study): an international cohort study on chronic venous disorders of the leg. VEINES Group. Angiology. 1997;48:59-66. 106. Clarke H, Smith SR, Vasdekis SN, et al. Role of venous elasticity in the development of varicose veins. Br J Surg. 1989;76:577-580. 107. Nicolaides AN, Hussein MK, Szendro G, et al. The relation of venous ulceration with ambulatory venous pressure measure-ments. J Vasc Surg. 1993;17:414-419. 108. Christopoulos DG, Nicolaides AN, Szendro G, et al. Air-pleth-ysmography and the effect of elastic compression on venous hemodynamics of the leg. J Vasc Surg. 1987;5:148-159. 109. van Bemmelen PS, Bedford G, Beach K, et al. Quantitative segmental evaluation of venous valvular reflux with duplex ultrasound scanning. J Vasc Surg. 1989;10:425-431. 110. Nehler MR, Porter JM. The lower extremity venous system. Part II: the pathophysiology of chronic venous insufficiency. Perspect Vasc Surg. 1992;5:81-97. 111. Beidler SK, Douillet CD, Berndt DF, et al. Multiplexed analy-sis of matrix metalloproteinases in leg ulcer tissue of patients with chronic venous insufficiency before and after compres-sion therapy. Wound Repair Regen. 2008;16:642-648. 112. Beidler SK, Douillet CD, Berndt DF, et al. Inflammatory cyto-kine levels in chronic venous insufficiency ulcer tissue before and after compression therapy. J Vasc Surg. 2009;49:1013-1020. 113. Nehler MR, Moneta GL, Woodard DM, et al. Perimalleolar subcutaneous tissue pressure effects of elastic compression stockings. J Vasc Surg. 1993;18:783-788. 114. Dinn E. Treatment of venous ulceration by injection sclero-therapy and compression hosiery: a 5-year study. Phlebology. 1992;7:23-26. 115. Mayberry JC, Moneta GL, Taylor LM, Jr, et al. Fifteen-year results of ambulatory compression therapy for chronic venous ulcers. Surgery. 1991;109(5):575-581. This review highlights the impact of compression therapy in venous ulcer therapy. 116. Falanga V, Margolis D, Alvarez O, et al. Rapid healing of venous ulcers and lack of clinical rejection with an allergenic cultured human skin equivalent. Human Skin Equivalent Investigators Group. Arch Dermatol. 1998;134:293-300. 117. Phillips TJ. New skin for old: developments in biological skin substitutes [editorial; comment]. Arch Dermatol. 1998;134:344. 118. Motykie GD, Caprini JA, Arcelus JI, et al. Evaluation of therapeutic compression stockings in the treatment of chronic venous insufficiency. Dermatol Surg. 1999;25:116-120. 119. Lippmann HI, Fishman LM, Farrar RH, et al. Edema control in the management of disabling chronic venous insufficiency. Arch Phys Med Rehabil. 1994;75:436-441. 120. Rubin JR, Alexander J, Plecha EJ, et al. Unna’s boot vs. polyurethane foam dressings for the treatment of venous ulceration. A randomized prospective study. Arch Surg. 1990;125:489-490. 121. O’Meara S, Cullum NA, Nelson EA. Compression for venous leg ulcers. Cochrane Database Syst Rev. 2009;1:CD000265. 122. Vernick SH, Shapiro D, Shaw FD. Legging orthosis for venous and lymphatic insufficiency. Arch Phys Med Rehabil. 1987;68:459-461.Brunicardi_Ch24_p0981-p1008.indd 100622/02/19 3:01 PM 1007VENOUS AND LYMPHATIC DISEASECHAPTER 24 123. Sibbald RG. Apligraf living skin equivalent for healing venous and chronic wounds. J Cutan Med Surg. 1998;3(suppl 1): S1-24-8. 124. Linton R. The communicating veins of the lower leg and the operative technique for their ligation. Ann Surg. 1938;107:582-593. 125. Gloviczki P, Bergan JJ, Rhodes JM, Canton LG, Harmsen S, Ilstrup DM. Mid-term results of endoscopic perforator vein interruption for chronic venous insufficiency: lessons learned from the North American Subfascial Endoscopic Perforator Surgery Registry. The North American Study Group. J Vasc Surg. 1999;29(3):489-502. This study reviews registry outcomes following subfacial endoscopic perforator surgery performed across 17 centers in North America. 126. Vashist MG, Malik V, Singhal N. Role of subfascial endo-scopic perforator surgery (SEPS) in management of perfora-tor incompetence in varicose veins: a prospective randomized study. India J Surg. 2014;76(2):117-123. 127. van Gent WB, Hop WC, van Praag MC, et al. Conservative versus surgical treatment of venous leg ulcers: a prospective randomized, multicenter trial. J Vasc Surg. 2006;44:563-571. 128. Gohel MS, Barwell JR, Taylor M, et al. Long term results of compression therapy alone versus compression plus surgery in chronic venous ulceration (ESCHAR): randomized controlled trial. BMJ. 2007;335:83. 129. Sottiurai VS. Surgical correction of recurrent venous ulcer. J Cardiovasc Surg. 1991;32:104-109. 130. Raju S, Fredericks R. Valve reconstruction procedures for non-obstructive venous insufficiency: rationale, techniques, and results in 107 procedures with twoto eight-year follow-up. J Vasc Surg. 1988;7:301-310. 131. Raju S, Darcey R, Neglen P. Unexpected major role for venous stenting in deep reflux disease. J Vasc Surg. 2010;51:401-408. 132. Masuda EM, Kistner RL. Long-term results of venous valve reconstruction: a fourto twenty-one-year follow-up. J Vasc Surg. 1994;19:391-403. 133. Rockson SG, Miller LT, Senie R, et al. American Cancer Soci-ety Lymphedema Workshop. Workgroup III: diagnosis and management of lymphedema. Cancer. 1998;83:2882-2885. 134. Yasuhara H, Shigematsu H, Muto T. A study of the advan-tages of elastic stockings for leg lymphedema. Int Angiol. 1996;15:272-277. 135. Feldman JL, Stout NL, Wanchai A, et al. Intermittent pneu-matic compression therapy: a systematic review. Lymphology. 2012;45:13-25. 136. Vodder E. Le Drainage Lymphatique, une Novelle Méthode Thérapeutique. Paris: Santé pour tous; 1936. 137. Ko DS, Lerner R, Klose G, et al. Effective treatment of lymph-edema of the extremities. Arch Surg. 1998;133:452-458. 138. Stevens DL, Bisno AL, Chambers HF, et al. Practice guide-lines for the diagnosis and management of skin and soft tissue infections. Clin Infect Dis. 2005;41:1373-1406. 139. Miller TA, Wyatt LE, Rudkin GH. Staged skin and subcutane-ous excision for lymphedema: a favorable report of long-term results. Plast Reconstr Surg. 1998;102:1486-1501. 140. Baumeister RG, Siuda S. Treatment of lymphedema by micro-surgical lymphatic grafting: what is proved? Plast Reconstr Surg. 1990;85:64-74. 141. Bernas MJ, Witte CL, Witte MH. The diagnosis and treatment of peripheral lymphedema: draft revision of the 1995 Con-sensus Document of the International Society of Lymphology Executive Committee for discussion at the September 3–7, 2001, XVIII International Congress of Lymphology in Genoa, Italy. Lymphology. 2001;34:84-91.Brunicardi_Ch24_p0981-p1008.indd 100722/02/19 3:01 PM
Brunicardi_Ch24_p0981-p1008.indd 100822/02/19 3:01 PMThis page intentionally left blankSURGICAL ANATOMYThe esophagus is a muscular tube that starts as the continu-ation of the pharynx and ends as the cardia of the stomach. When the head is in a normal anatomic position, the transi-tion from pharynx to esophagus occurs at the lower border of the sixth cervical vertebra. Topographically this corresponds to the cricoid cartilage anteriorly and the palpable transverse process of the sixth cervical vertebra laterally (Fig. 25-1). The esophagus is firmly attached at its upper end to the cricoid cartilage and at its lower end to the diaphragm; during swal-lowing, the proximal points of fixation move craniad the dis-tance of one cervical vertebral body.The esophagus lies in the midline, with a deviation to the left in the lower portion of the neck and upper portion of the thorax, and returns to the midline in the midportion of the tho-rax near the bifurcation of the trachea (Fig. 25-2). In the lower portion of the thorax, the esophagus again deviates to the left and anteriorly to pass through the diaphragmatic hiatus.Esophagus and Diaphragmatic HerniaBlair A. Jobe, John G. Hunter, and David I. Watson 25chapterSurgical Anatomy1009Physiology1015Swallowing Mechanism / 1015Physiologic Reflux / 1017Assessment of Esophageal Function1018Tests to Detect Structural Abnormalities / 1018Tests to Detect Functional Abnormalities / 1019Videoand Cineradiography / 1028Tests to Detect Increased Exposure to Gastric Juice / 1028Tests of Duodenogastric Function / 1030Gastroesophageal Reflux Disease1031The Human Antireflux Mechanism and the Pathophysiology of Gastroesophageal Reflux Disease / 1032Complications Associated With Gastroesophageal Reflux Disease / 1033Metaplastic (Barrett’s Esophagus) and Neoplastic (Adenocarcinoma) Complications / 1035Respiratory Complications / 1035Surgical Therapy for Gastroesophageal Reflux Disease / 1038Primary Antireflux Repairs / 1040Giant Diaphragmatic (Hiatal) Hernias1045Incidence and Etiology / 1045Clinical Manifestations / 1047Diagnosis / 1047Pathophysiology / 1048Treatment / 1048Diaphragmatic Repair / 1048The Short Esophagus and PEH / 1049Results / 1049Schatzki’s Ring1049Scleroderma1050Eosinophilic Esophagitis1051Symptoms / 1051Signs / 1051Pathology / 1051Treatment / 1051Motility Disorders of the Pharynx and Esophagus1052Clinical Manifestations / 1052Motility Disorders of the Pharynx and Upper Esophagus—Transit Dysphagia / 1052Diagnostic Assessment of the Cricopharyngeal Segment / 1052Motility Disorders of the Esophageal Body and Lower Esophageal Sphincter / 1055Operations for Esophageal Motor Disorders and Diverticula1060Long Esophageal Myotomy for Motor Disorders of the Esophageal Body / 1060Myotomy of the Lower Esophageal Sphincter (Heller Myotomy) / 1063Open Esophageal Myotomy / 1065Laparoscopic Cardiomyotomy / 1065Per Oral Endoscopic Myotomy (POEM) / 1065Outcome Assessment of the Therapy for Achalasia / 1065Esophageal Resection for End-Stage Motor Disorders of the Esophagus / 1068Carcinoma of the Esophagus1068Clinical Manifestations / 1068General Approach to Esophageal Cancer / 1069Staging of Esophageal Cancer / 1069Clinical Approach to Carcinoma of the Esophagus and Cardia / 1070Palliation of Esophageal Cancer / 1074Surgical Treatment / 1074Comparative Studies of Esophagectomy Technique / 1077Alternative Therapies / 1077Sarcoma of the Esophagus1078Benign Tumors and Cysts1080Leiomyoma / 1081Esophageal Cyst / 1083Esophageal Perforation1083Diagnosis / 1083Management / 1084Mallory-Weiss Syndrome1085Caustic Injury1086Pathology / 1086Clinical Manifestations / 1086Treatment / 1086Acquired Fistula1088Techniques of Esophageal Reconstruction1089Partial Esophageal Resection / 1089Reconstruction After Total Esophagectomy / 1089Composite Reconstruction / 1090Vagal Sparing Esophagectomy With Colon Interposition / 1090Brunicardi_Ch25_p1009-p1098.indd 100901/03/19 6:01 PM 1010abcdeA BKey Points1 Benign esophageal disease is common and is best evaluated with thorough physiologic testing (high resolution esopha-geal motility, 24-hour ambulatory pH measurement, and/or esophageal impedance testing) and anatomic testing (esoph-agoscopy, video esophagography, and/or computed tomog-raphy [CT] scanning).2 Gastroesophageal reflux disease (GERD) is the most com-mon disease of the gastrointestinal tract for which patients seek medical therapy. When GERD symptoms (heartburn, regurgitation, chest pain, and/or supraesophageal symptoms) are troublesome despite adequately dosed PPI, surgical cor-rection may be indicated.3 Barrett’s esophagus is the transformation of the distal esoph-ageal epithelium from squamous to a specialized columnar epithelium capable of further neoplastic progression. The detection of Barrett’s esophagus on endoscopy and biopsy increases the future risk of cancer by >40x compared to indi-viduals without Barrett’s esophagus.4 Giant hiatal hernia, otherwise known as paraesophageal her-nia, should be repaired when symptomatic or associated with iron deficiency anemia. Laparoscopic hiatal hernia repair with fundoplication is the most common approach to repair.5 Achalasia is the most common primary esophageal motor disorder. It is characterized by an absence of peristalsis and a hypertensive nonrelaxing lower esophageal sphincter. It is best treated with laparoscopic Heller myotomy and partial fundoplication.6 Most esophageal cancer presents with dysphagia, at which time it has invaded the muscularis of the esophagus and is often associated with lymph node metastases. The preferred treatment at this stage is multimodality therapy with chemo-radiation therapy followed by open or minimally invasive esophagectomy.Figure 25-1. A. Topographic relationships of the cervical esophagus: (a) hyoid bone, (b) thyroid cartilage, (c) cricoid cartilage, (d) thyroid gland, (e) sternoclavicular. B. Lateral radio-graphic appearance with landmarks identified as labeled in A. The location of C6 is also included (f). (Reproduced with permission from Shields TW: General Thoracic Surgery, 3rd ed. Philadelphia, PA: Lea & Febiger; 1989.)Three normal areas of esophageal narrowing are evident on the barium esophagogram or during esophagoscopy. The uppermost narrowing is located at the entrance into the esopha-gus and is caused by the cricopharyngeal muscle. Its luminal diameter is 1.5 cm, and it is the narrowest point of the esopha-gus. The middle narrowing is due to an indentation of the ante-rior and left lateral esophageal wall caused by the crossing of the left main stem bronchus and aortic arch. The luminal diameter at this point is 1.6 cm. The lowermost narrowing is at the hiatus of the diaphragm and is caused by the gastroesophageal sphincter mechanism. The luminal diameter at this point varies somewhat, depending on the distention of the esophagus by the passage of food, but has been measured at 1.6 to 1.9 cm. These normal constrictions tend to hold up swallowed foreign objects, and the overlying mucosa is subject to injury by swallowed corrosive liquids due to their slow passage through these areas.Figure 25-3 shows the average distance in centimeters measured during endoscopic examination between the incisor teeth and the cricopharyngeus, aortic arch, and cardia of the stomach. Manometrically, the length of the esophagus between the lower border of the cricopharyngeus and upper border of the lower sphincter varies according to the height of the individual.Brunicardi_Ch25_p1009-p1098.indd 101001/03/19 6:01 PM 1011ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25ABFigure 25-2. Barium esophagogram. A. Posterior-anterior view. White arrow shows deviation to left. Black arrow shows return to midline. B. Lateral view. Black arrow shows anterior deviation. (Reproduced with permission from Shields TW: General Thoracic Surgery, 3rd ed. Philadelphia, PA: Lea & Febiger; 1989.)Pharynx24–26cmUpper sphincter(C6)40cm38cmLower sphincter(T11)15cm14cmAortic arch(T4)25cm 23cmIncisor teethFigure 25-3. Important clinical endoscopic measurements of the esophagus in adults. (Reproduced with permission from Shields TW: General Thoracic Surgery, 3rd ed. Philadelphia, PA: Lea & Febiger; 1989.) Superior pharyngeal constrictor m.Middle pharyngeal constrictor m.Inferior pharyngeal constrictor m.Cricopharyngeus m.EsophagusBAFigure 25-4. External muscles of the pharynx. A. Posterolateral view. B. Posterior view. Dotted line represents usual site of myotomy. (Reproduced with permission from Shields TW: General Thoracic Surgery, 3rd ed. Philadelphia, PA: Lea & Febiger; 1989.)The pharyngeal musculature consists of three broad, flat, overlapping fan-shaped constrictors (Fig. 25-4). The opening of the esophagus is collared by the cricopharyngeal muscle, which arises from both sides of the cricoid cartilage of the lar-ynx and forms a continuous transverse muscle band without an interruption by a median raphe. The fibers of this muscle Brunicardi_Ch25_p1009-p1098.indd 101101/03/19 6:02 PM 1012SPECIFIC CONSIDERATIONSPART IIblend inseparably with those of the inferior pharyngeal constric-tor above and the inner circular muscle fibers of the esophagus below. Some investigators believe that the cricopharyngeus is part of the inferior constrictor; that is, that the inferior constric-tor has two parts, an upper or retrothyroid portion having diago-nal fibers, and a lower or retrocricoid portion having transverse fibers. Keith in 1910 showed that these two parts of the same muscle serve totally different functions. The retrocricoid portion serves as the upper sphincter of the esophagus and relaxes when the retrothyroid portion contracts, to force the swallowed bolus from the pharynx into the esophagus.The cervical portion of the esophagus is approximately 5 cm long and descends between the trachea and the vertebral column, from the level of the sixth cervical vertebra to the level of the interspace between the first and second thoracic verte-brae posteriorly, or the level of the suprasternal notch anteriorly. The recurrent laryngeal nerves lie in the right and left grooves between the trachea and the esophagus. The left recurrent nerve lies somewhat closer to the esophagus than the right, owing to the slight deviation of the esophagus to the left, and the more lateral course of the right recurrent nerve around the right sub-clavian artery. Laterally, on the left and right sides of the cervi-cal esophagus are the carotid sheaths and the lobes of the thyroid gland.The thoracic portion of the esophagus is approximately 20 cm long. It starts at the thoracic inlet. In the upper portion of the thorax, it is in intimate relationship with the posterior wall of the trachea and the prevertebral fascia. Just above the tracheal bifurcation, the esophagus passes to the right of the aorta. This anatomic positioning can cause a notch indentation in its left lateral wall on a barium swallow radiogram. Immediately below this notch, the esophagus crosses both the bifurcation of the trachea and the left main stem bronchus, owing to the slight deviation of the terminal portion of the trachea to the right by the aorta (Fig. 25-5). From there down, the esophagus passes over the posterior surface of the subcarinal lymph nodes (LNs), and then descends over the pericardium of the left atrium to reach the diaphragmatic hiatus (Fig. 25-6). From the bifurcation of the trachea downward, both the vagal nerves and the esophageal nerve plexus lie on the muscular wall of the esophagus.Dorsally, the thoracic esophagus follows the curvature of the spine and remains in close contact with the vertebral bod-ies. From the eighth thoracic vertebra downward, the esopha-gus moves vertically away from the spine to pass through the hiatus of the diaphragm. The thoracic duct passes through the hiatus of the diaphragm on the anterior surface of the verte-bral column behind the aorta and under the right crus. In the thorax, the thoracic duct lies dorsal to the esophagus between the azygos vein on the right and the descending thoracic aorta on the left.The abdominal portion of the esophagus is approximately 2 cm long and includes a portion of the lower esophageal sphincter (LES). It starts as the esophagus passes through the diaphragmatic hiatus and is surrounded by the phrenoesopha-geal membrane, a fibroelastic ligament arising from the subdia-phragmatic fascia as a continuation of the transversalis fascia lining the abdomen (Fig. 25-7). The upper leaf of the membrane attaches itself in a circumferential fashion around the esopha-gus, about 1 to 2 cm above the level of the hiatus. These fibers blend in with the elastic-containing adventitia of the abdominal esophagus and the cardia of the stomach. This portion of the esophagus is subjected to the positive-pressure environment of the abdomen.The musculature of the esophagus can be divided into an outer longitudinal and an inner circular layer. The upper 2 to 6 cm of the esophagus contains only striated muscle fibers. From then on, smooth muscle fibers gradually become more abundant. Most clinically significant esophageal motility dis-orders involve only the smooth muscle in the lower two-thirds of the esophagus. When a long surgical esophageal myotomy is indicated, the incision needs to extend only this distance.The longitudinal muscle fibers originate from a crico-esophageal tendon arising from the dorsal upper edge of the anteriorly located cricoid cartilage. The two bundles of mus-cle diverge and meet in the midline on the posterior wall of the esophagus about 3 cm below the cricoid (see Fig. 25-4). From this point on, the entire circumference of the esophagus is cAThymusPericardiumSuperior vena cavaTracheal carinaRight main stembronchusEsophagusAscending aortaLeft main stem bronchusBottom of aortic archDescendingaortaIVBaebdFigure 25-5. A. Cross-section of the thorax at the level of the tracheal bifurcation. B. Computed tomographic scan at same level viewed from above: (a) ascending aorta, (b) descending aorta, (c) tracheal carina, (d) esophagus, (e) pulmonary artery. (Reproduced with permission from Shields TW: General Thoracic Surgery, 3rd ed. Philadelphia, PA: Lea & Febiger; 1989.)Brunicardi_Ch25_p1009-p1098.indd 101201/03/19 6:02 PM 1013ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25BAPericardiumRight ventricleRight atriumPericardiumPleuraVIIPleuraAortaEsophagusLeft atriumLeft ventriclefdecabgFigure 25-6. A. Cross-section of the thorax at the midleft atrial level. B. Computed tomographic scan at same level viewed from above: (a) aorta, (b) esophagus, (c) left atrium, (d) right atrium, (e) left ventricle, (f) right ventricle, (g) pulmonary vein. (Reproduced with permission from Shields TW: General Thoracic Surgery, 3rd ed. Philadelphia, PA: Lea & Febiger; 1989.)Phreno-esophageal membrane(Ascending leaf)ParietalperitoneumVisceralperitoneumDiaphragmPara-esophageal fat padPhreno-esophageal membrane(Descending leaf)Figure 25-7. Attachments and structure of the phrenoesophageal membrane. Transversalis fascia lies just above the parietal peri-toneum. (Reproduced with permission from Shields TW: General Thoracic Surgery, 3rd ed. Philadelphia, PA: Lea & Febiger; 1989.)covered by a layer of longitudinal muscle fibers. This configura-tion of the longitudinal muscle fibers around the most proximal part of the esophagus leaves a V-shaped area in the posterior wall covered only with circular muscle fibers. Contraction of the longitudinal muscle fibers shortens the esophagus. The cir-cular muscle layer of the esophagus is thicker than the outer longitudinal layer. In situ, the geometry of the circular muscle is helical and makes the peristalsis of the esophagus assume a wormlike drive, as opposed to segmental and sequential squeez-ing. As a consequence, severe motor abnormalities of the esoph-agus assume a corkscrew-like pattern on the barium swallow radiogram.The cervical portion of the esophagus receives its main blood supply from the inferior thyroid artery. The thoracic por-tion receives its blood supply from the bronchial arteries, with 75% of individuals having one right-sided and two left-sided branches. Two esophageal branches arise directly from the aorta. The abdominal portion of the esophagus receives its blood supply from the ascending branch of the left gastric artery and from inferior phrenic arteries (Fig. 25-8). On entering the wall of the esophagus, the arteries assume a T-shaped division to form a longitudinal plexus, giving rise to an intramural vascular network in the muscular and submucosal layers. As a conse-quence, the esophagus can be mobilized from the stomach to the level of the aortic arch without fear of devascularization and ischemic necrosis. Caution, however, should be exercised as to the extent of esophageal mobilization in patients who have had a previous thyroidectomy with ligation of the inferior thyroid arteries proximal to the origin of the esophageal branches.Blood from the capillaries of the esophagus flows into a submucosal venous plexus, and then into a periesophageal Left gastric arteryRight bronchialartery Inferior thyroid arterySuperior leftbronchial arteryInferior leftbronchial arteryAortic esophagealarteriesAscending branches ofleft gastric artery Esophageal branchFigure 25-8. Arterial blood supply of the esophagus. (Reproduced with permission from Shields TW: General Thoracic Surgery, 3rd ed. Philadelphia, PA: Lea & Febiger; 1989.)Brunicardi_Ch25_p1009-p1098.indd 101301/03/19 6:02 PM 1014SPECIFIC CONSIDERATIONSPART IIInferior thyroid veinsAccessory azygous veinHemiazygous veinShort gastric veinsSplenic veinSuperior mesenteric vein Portal vein Coronary vein Azygous vein Figure 25-9. Venous drainage of the esophagus. (Reproduced with permission from Shields TW: General Thoracic Surgery, 3rd ed. Philadelphia, PA: Lea & Febiger; 1989.)Left vagus nerveLeft recurrentlaryngeal nerveThoracic chainLeft or anteriorvagal trunkRight or posterior vagal trunkAnterior esophagealplexusRight recurrentlaryngeal nerveRight vagus nerveRecurrent laryngealnervesFigure 25-10. Innervation of the esophagus. (Reproduced with permission from Shields TW: General Thoracic Surgery, 3rd ed. Philadelphia, PA: Lea & Febiger; 1989.)Internal jugularnodesParatrachealnodesSubcarinal nodesInferior paraesophagealnodesParahiatal nodes Splenic arterynodesCeliac artery nodes Hepatic artery nodesLeft gastric artery nodesPulmonary hilarnodesSuperiorparaesophageal nodesFigure 25-11. Lymphatic drainage of the esophagus. (Reproduced with permission from DeMeester TR, Barlow AP. Surgery and cur-rent management for cancer of the esophagus and cardia: Part I, Curr Probl Surg. 1988 Jul;25(7):475-531.)venous plexus from which the esophageal veins originate. In the cervical region, the esophageal veins empty into the inferior thy-roid vein; in the thoracic region, they empty into the bronchial, azygos, or hemiazygos veins; and in the abdominal region, they empty into the coronary vein (Fig. 25-9). The submucosal venous networks of the esophagus and stomach are in continuity with each other, and, in patients with portal venous obstruction, this communication functions as a collateral pathway for portal blood to enter the superior vena cava via the azygos vein.The parasympathetic innervation of the pharynx and esophagus is provided mainly by the vagus nerves. The con-strictor muscles of the pharynx receive branches from the pharyngeal plexus, which is on the posterior lateral surface of the middle constrictor muscle, and is formed by pharyngeal branches of the vagus nerves with a small contribution from cra-nial nerves IX and XI (Fig. 25-10). The cricopharyngeal sphinc-ter and the cervical portion of the esophagus receive branches from both recurrent laryngeal nerves, which originate from the vagus nerves—the right recurrent nerve at the lower margin of the subclavian artery and the left at the lower margin of the aortic arch. They are slung dorsally around these vessels and ascend in the groove between the esophagus and trachea, giving branches to each. Damage to these nerves interferes not only with the function of the vocal cords but also with the function of the cricopharyngeal sphincter and the motility of the cervical esophagus, predisposing the individual to pulmonary aspiration on swallowing.Afferent visceral sensory pain fibers from the esophagus end without synapse in the first four segments of the thoracic spinal cord, using a combination of sympathetic and vagal path-ways. These pathways are also occupied by afferent visceral sensory fibers from the heart; hence, both organs have similar symptomatology.The lymphatics located in the submucosa of the esopha-gus are so dense and interconnected that they constitute a single plexus (Fig. 25-11). There are more lymph vessels than blood capillaries in the submucosa. Lymph flow in the submucosal plexus runs in a longitudinal direction, and, on injection of a contrast medium, the longitudinal spread is seen to be about six times that of the transverse spread. In the upper two-thirds of the esophagus, the lymphatic flow is mostly cephalad, and, in the lower third, caudad. In the thoracic portion of the esophagus, Brunicardi_Ch25_p1009-p1098.indd 101401/03/19 6:02 PM 1015ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25the submucosal lymph plexus extends over a long distance in a longitudinal direction before penetrating the muscle layer to enter lymph vessels in the adventitia. As a consequence of this nonsegmental lymph drainage, a primary tumor can extend for a considerable length superiorly or inferiorly in the submucosal plexus. Consequently, free tumor cells can follow the submu-cosal lymphatic plexus in either direction for a long distance before they pass through the muscularis and on into the regional LNs. The cervical esophagus has more direct segmental lymph drainage into the regional nodes, and, as a result, lesions in this portion of the esophagus have less submucosal extension and a more regionalized lymphatic spread.The efferent lymphatics from the cervical esophagus drain into the paratracheal and deep cervical LNs, and those from the upper thoracic esophagus empty mainly into the paratracheal LNs. Efferent lymphatics from the lower thoracic esophagus drain into the subcarinal nodes and nodes in the inferior pulmo-nary ligaments. The superior gastric nodes receive lymph not only from the abdominal portion of the esophagus, but also from the adjacent lower thoracic segment.PHYSIOLOGYSwallowing MechanismThe act of alimentation requires the passage of food and drink from the mouth into the stomach. One-third of this distance con-sists of the mouth and hypopharynx, and two-thirds is made up by the esophagus. To comprehend the mechanics of alimenta-tion, it is useful to visualize the gullet as a mechanical model in which the tongue and pharynx function as a piston pump with three valves, and the body of the esophagus and cardia function as a worm-drive pump with a single valve. The three valves in the pharyngeal cylinder are the soft palate, epiglottis, and cricopharyngeus. The valve of the esophageal pump is the LES. Failure of the valves or the pumps leads to abnormali-ties in swallowing—that is, difficulty in food propulsion from mouth to stomach—or regurgitation of gastric contents into the esophagus or pharynx.Food is taken into the mouth in a variety of bite sizes, where it is broken up, mixed with saliva, and lubricated. Once initiated, swallowing is entirely a reflex act. When food is ready for swallowing, the tongue, acting like a piston, moves the bolus into the posterior oropharynx and forces it into the hypopharynx (Fig. 25-12). Concomitantly with the posterior movement of the tongue, the soft palate is elevated, thereby closing the passage between the oropharynx and nasopharynx. This partitioning prevents pressure generated in the oropharynx from being dissipated through the nose. When the soft palate is paralyzed, for example, after a cerebrovascular accident, food is commonly regurgitated into the nasopharynx. During swal-lowing, the hyoid bone moves upward and anteriorly, elevating the larynx and opening the retrolaryngeal space, bringing the epiglottis under the tongue (see Fig. 25-12). The backward tilt of the epiglottis covers the opening of the larynx to prevent aspi-ration. The entire pharyngeal part of swallowing occurs within 1.5 seconds.During swallowing, the pressure in the hypopharynx rises abruptly, to at least 60 mmHg, due to the backward movement of the tongue and contraction of the posterior pharyngeal con-strictors. A sizable pressure difference develops between the hypopharyngeal pressure and the less-than-atmospheric mid-esophageal or intrathoracic pressure (Fig. 25-13). This pressure 1. Elevation of tongue2. Posterior movement of tongue3. Elevation of soft palate4. Elevation of hyoid5. Elevation of larynx6. Tilting of epiglottis123456Figure 25-12. Sequence of events during the oropharyngeal phase of swallowing. (Reproduced with permission from Zuidema GD, Orringer MB: Shackelford’s Surgery of the Alimentary Tract, 3rd ed. Vol 1. Philadelphia, PA: Elsevier/Saunders; 1991.)gradient speeds the movement of food from the hypopharynx into the esophagus when the cricopharyngeus or upper esopha-geal sphincter relaxes. The bolus is both propelled by peristaltic contraction of the posterior pharyngeal constrictors and sucked into the thoracic esophagus. Critical to receiving the bolus is the compliance of the cervical esophagus; when compliance is lost due to muscle pathology, dysphagia can result. The upper esophageal sphincter closes within 0.5 seconds of the initiation of the swallow, with the immediate closing pressure reaching Pressure (mm Hg)% Esophagus length100–10–505101520253035408060Upright position40200DESGECPAirFigure 25-13. Resting pressure profile of the foregut showing the pressure differential between the atmospheric pharyngeal pressure (P) and the less-than-atmospheric midesophageal pressure (E) and greater-than-atmospheric intragastric pressure (G), with the inter-posed high-pressure zones of the cricopharyngeus (C) and distal esophageal sphincter (DES). The necessity for relaxation of the cri-copharyngeus and DES pressure to move a bolus into the stomach is apparent. Esophageal work occurs when a bolus is pushed from the midesophageal area (E), with a pressure less than atmospheric, into the stomach, which has a pressure greater than atmospheric (G). (Reproduced with permission from Waters PF, DeMeester TR: Foregut motor disorders and their surgical managemen, Med Clin North Am. 1981 Nov;65(6):1235-1268.)Brunicardi_Ch25_p1009-p1098.indd 101501/03/19 6:02 PM 1016SPECIFIC CONSIDERATIONSPART II0102030405060mmHgSwallowSeconds01020304050SecondsSeconds01020304050Seconds01020304050Seconds01020304050StomachHigh pressure zoneEsophageal bodyCricopharyngeusPharynxFigure 25-14. Intraluminal esophageal pressures in response to swallowing. (Reproduced with permission from Waters PF, DeMeester TR: Foregut motor disorders and their surgical man-agemen, Med Clin North Am. 1981 Nov;65(6):1235-1268.)approximately twice the resting level of 30 mmHg. The postre-laxation contraction continues down the esophagus as a peri-staltic wave (Fig. 25-14). The high closing pressure and the initiation of the peristaltic wave prevents reflux of the bolus from the esophagus back into the pharynx. After the peristaltic wave has passed farther down the esophagus, the pressure in the upper esophageal sphincter returns to its resting level.Swallowing can be started at will, or it can be reflexively elicited by the stimulation of areas in the mouth and pharynx, among them the anterior and posterior tonsillar pillars or the posterior lateral walls of the hypopharynx. The afferent sen-sory nerves of the pharynx are the glossopharyngeal nerves and the superior laryngeal branches of the vagus nerves. Once aroused by stimuli entering via these nerves, the swallowing center in the medulla coordinates the complete act of swallow-ing by discharging impulses through cranial nerves V, VII, X, XI, and XII, as well as the motor neurons of C1 to C3. Dis-charges through these nerves occur in a rather specific pattern and last for approximately 0.5 seconds. Little is known about the organization of the swallowing center, except that it can trigger swallowing after a variety of different inputs, but the response is always a rigidly ordered pattern of outflow. Following a cere-brovascular accident, this coordinated outflow may be altered, causing mild to severe abnormalities of swallowing. In more severe injury, swallowing can be grossly disrupted, leading to repetitive aspiration.The striated muscles of the cricopharyngeus and the upper one-third of the esophagus are activated by efferent motor fibers distributed through the vagus nerve and its recurrent laryngeal branches. The integrity of innervation is required for the cri-copharyngeus to relax in coordination with the pharyngeal contraction, and resume its resting tone once a bolus has entered the upper esophagus. Operative damage to the innervation can interfere with laryngeal, cricopharyngeal, and upper esophageal function, and predispose the patient to aspiration.The pharyngeal activity in swallowing initiates the esoph-ageal phase. The body of the esophagus functions as a worm-drive propulsive pump due to the helical arrangement of its circular muscles, and it is responsible for transferring a bolus of food into the stomach. The esophageal phases of swallow-ing represent esophageal work done during alimentation, in that food is moved into the stomach from a negative-pressure environment of –6 mmHg intrathoracic pressure, to a positive-pressure environment of 6 mmHg intra-abdominal pressure, or over a gradient of 12 mmHg (see Fig. 25-13). Effective and coordinated smooth muscle function in the lower one-third of the esophagus is therefore important in pumping the food across this gradient.The peristaltic wave generates an occlusive pressure vary-ing from 30 to 120 mmHg (see Fig. 25-14). The wave rises to a peak in 1 second, lasts at the peak for about 0.5 seconds, and then subsides in about 1.5 seconds. The whole course of the rise and fall of occlusive pressure may occupy one point in the esophagus for 3 to 5 seconds. The peak of a primary peri-staltic contraction initiated by a swallow (primary peristalsis) moves down the esophagus at 2 to 4 cm/s and reaches the distal esophagus about 9 seconds after swallowing starts. Consecutive swallows produce similar primary peristaltic waves, but when the act of swallowing is rapidly repeated, the esophagus remains relaxed and the peristaltic wave occurs only after the last move-ment of the pharynx. Progress of the wave in the esophagus is caused by sequential activation of its muscles, initiated by effer-ent vagal nerve fibers arising in the swallowing center.Continuity of the esophageal muscle is not necessary for sequential activation if the nerves are intact. If the muscles, but not the nerves, are cut across, the pressure wave begins dis-tally below the cut as it dies out at the proximal end above the cut. This allows a sleeve resection of the esophagus to be done without destroying its normal function. Afferent impulses from receptors within the esophageal wall are not essential for prog-ress of the coordinated wave. Afferent nerves, however, do go to the swallowing center from the esophagus because if the esoph-agus is distended at any point, a contraction wave begins with a forceful closure of the upper esophageal sphincter and sweeps down the esophagus. This secondary contraction occurs without any movements of the mouth or pharynx. Secondary peristalsis can occur as an independent local reflex to clear the esophagus of ingested material left behind after the passage of the primary wave. Current studies suggest that secondary peristalsis is not as common as once thought.Despite the powerful occlusive pressure, the propulsive force of the esophagus is relatively feeble. If a subject attempts to swallow a bolus attached by a string to a counterweight, the maximum weight that can be overcome is 5 to 10 g. Orderly contractions of the muscular wall and anchoring of the esopha-gus at its inferior end are necessary for efficient aboral propul-sion to occur. Loss of the inferior anchor, as occurs with a large hiatal hernia, can lead to inefficient propulsion.The LES provides a pressure barrier between the esopha-gus and stomach and acts as the valve on the worm-drive pump of the esophageal body. Although an anatomically distinct LES has been difficult to identify, microdissection studies show that, in humans, the sphincter-like function is related to the Brunicardi_Ch25_p1009-p1098.indd 101601/03/19 6:02 PM 1017ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Gastro-esophagealmuscular ringObliquefibersGreater curvaturewall thicknessLesser curvaturewall thicknessAnterior wall thicknessPhreno-esophagealmembraneSemi-circularfibers50-0-20--50-0 mm-20-50-0 mm-20Figure 25-15. Wall thickness and orientation of fibers on micro-dissection of the cardia. At the junction of the esophageal tube and gastric pouch, there is an oblique muscular ring composed of an increased muscle mass inside the inner muscular layer. On the lesser curve side of the cardia, the muscle fibers of the inner layer are oriented transversely and form semicircular muscle clasps. On the greater curve side of the cardia, these muscle fibers form oblique loops that encircle the distal end of the cardia and gastric fundus. Both the semicircular muscle clasps and the oblique fibers of the fundus contract in a circular manner to close the cardia. (Reproduced with permission from Glenn WWL: Thoracic and Cardiovascular Surgery, 4th ed. Norwalk, CT: Appleton-Century-Crofts; 1983.)architecture of the muscle fibers at the junction of the esoph-ageal tube with the gastric pouch (Fig. 25-15). The sphincter actively remains closed to prevent reflux of gastric contents into the esophagus and opens by a relaxation that coincides with a pharyngeal swallow (see Fig. 25-14). The LES pressure returns to its resting level after the peristaltic wave has passed through the esophagus. Consequently, reflux of gastric juice that may occur through the open valve during a swallow is cleared back into the stomach.If the pharyngeal swallow does not initiate a peristaltic con-traction, then the coincident relaxation of the LES is unguarded and reflux of gastric juice can occur. This may be an explanation for the observation of spontaneous lower esophageal relaxation, thought by some to be a causative factor in gastroesophageal reflux disease (GERD). The power of the worm-drive pump of the esophageal body is insufficient to force open a valve that does not relax. In dogs, a bilateral cervical parasympathetic blockade abolishes the relaxation of the LES that occurs with pharyngeal swallowing or distention of the esophagus. Conse-quently, vagal function appears to be important in coordinating the relaxation of the LES with esophageal contraction.The antireflux mechanism in human beings is composed of three components: a mechanically effective LES, efficient esophageal clearance, and an adequately functioning gastric reservoir. A defect of any one of these three components can lead to increased esophageal exposure to gastric juice and the development of mucosal injury.Physiologic RefluxOn 24-hour esophageal pH monitoring, healthy individuals have occasional episodes of gastroesophageal reflux. This physi-ologic reflux is more common when awake and in the upright position than during sleep in the supine position. When reflux of gastric juice occurs, normal subjects rapidly clear the acid gastric juice from the esophagus regardless of their position.There are several explanations for the observation that physiologic reflux in normal subjects is more common when they are awake and in the upright position than during sleep in the supine position. First, reflux episodes occur in healthy vol-unteers primarily during transient losses of the gastroesophageal barrier, which may be due to a relaxation of the LES or intra-gastric pressure overcoming sphincter pressure. Gastric juice can also reflux when a swallow-induced relaxation of the LES is not protected by an oncoming peristaltic wave. The average frequency of these “unguarded moments” or of transient losses of the gastroesophageal barrier is far less while asleep and in the supine position than while awake and in the upright posi-tion. Consequently, there are fewer opportunities for reflux to occur in the supine position. Second, in the upright position, there is a 12-mmHg pressure gradient between the resting, posi-tive intra-abdominal pressure measured in the stomach and the most negative intrathoracic pressure measured in the esophagus at midthoracic level. This gradient favors the flow of gastric juice up into the thoracic esophagus when upright. The gradi-ent diminishes in the supine position. Third, the LES pressure in normal subjects is significantly higher in the supine posi-tion than in the upright position. This is due to the apposition of the hydrostatic pressure of the abdomen to the abdominal portion of the sphincter when supine. In the upright position, the abdominal pressure surrounding the sphincter is negative compared with atmospheric pressure, and, as expected, the abdominal pressure gradually increases the more caudally it is measured. This pressure gradient tends to move the gastric con-tents toward the cardia and encourages the occurrence of reflux into the esophagus when the individual is upright. In contrast, in the supine position, the gastroesophageal pressure gradient diminishes, and the abdominal hydrostatic pressure under the diaphragm increases, causing an increase in sphincter pressure and a more competent cardia.The LES has intrinsic myogenic tone, which is modu-lated by neural and hormonal mechanisms. α-Adrenergic neu-rotransmitters or β-blockers stimulate the LES, and α-blockers and β-stimulants decrease its pressure. It is not clear to what extent cholinergic nerve activity controls LES pressure. The vagus nerve carries both excitatory and inhibitory fibers to the esophagus and sphincter. The hormones gastrin and motilin have been shown to increase LES pressure; and cholecystokinin, estrogen, glucagon, progesterone, somatostatin, and secretin decrease LES pressure. The peptides bombesin, l-enkephalin, and substance P increase LES pressure; and calcitonin gene-related peptide, gastric inhibitory peptide, neuropeptide Y, and vasoactive intestinal polypeptide decrease LES pressure. Some pharmacologic agents such as antacids, cholinergics, agonists, domperidone, metoclopramide, and prostaglandin F2 are known to increase LES pressure; and anticholinergics, barbiturates, cal-cium channel blockers, caffeine, diazepam, dopamine, meperi-dine, prostaglandin E1 and E2, and theophylline decrease LES pressure. Peppermint, chocolate, coffee, ethanol, and fat are all associated with decreased LES pressure and may be responsible for esophageal symptoms after a sumptuous meal.Brunicardi_Ch25_p1009-p1098.indd 101701/03/19 6:02 PM 1018SPECIFIC CONSIDERATIONSPART IIASSESSMENT OF ESOPHAGEAL FUNCTIONA thorough understanding of the patient’s underlying anatomic and functional deficits before making therapeutic decisions is fundamental to the successful treatment of esophageal disease. The diagnostic tests, as presently used, may be divided into four broad groups: (a) tests to detect structural abnormalities of the esophagus; (b) tests to detect functional abnormalities of the esophagus; (c) tests to detect increased esophageal expo-sure to gastric juice; and (d) tests of duodenogastric function as they relate to esophageal disease.Tests to Detect Structural AbnormalitiesEndoscopic Evaluation. The first diagnostic test in patients with suspected esophageal disease is usually upper gastrointesti-nal endoscopy. This allows assessment and biopsy of the mucosa of the stomach and the esophagus, as well as the diagnosis and assessment of obstructing lesions in the upper gastrointestinal tract. In any patient complaining of dysphagia, esophagoscopy is indicated, even in the face of a normal radiographic study.For the initial endoscopic assessment, the flexible fiber-optic esophagoscope is the instrument of choice because of its technical ease, patient acceptance, and the ability to simultane-ously assess the stomach and duodenum. Rigid endoscopy is now only rarely required, mainly for the disimpaction of diffi-cult foreign bodies impacted in the esophagus, and few individ-uals now have the skill set and experience to use this equipment.When GERD is the suspected diagnosis, particular atten-tion should be paid to detecting the presence of esophagitis and Barrett’s columnar-lined esophagus (CLE). When endoscopic esophagitis is seen, severity and the length of esophagitis involved are recorded. Whilst many different grading systems have been proposed, the commonest system now in use is the Los Angeles (LA) grading system. In this system, mild esopha-gitis is classified LA grade A or B—one or more erosions lim-ited to the mucosal fold(s) and either less than or greater than 5 mm in longitudinal extent respectively (Fig. 25-16). More severe esophagitis is classified LA grade C or D. In grade C, erosions extend over the mucosal folds but over less than three-quarters of the esophageal circumference; in grade D, confluent erosions extend across more than three-quarters of the esopha-geal circumference. In addition to these grades, more severe damage can lead to the formation of a stricture. A stricture’s severity can be assessed by the ease of passing a standard endo-scope. When a stricture is observed, the severity of the esopha-gitis above it should be recorded. The absence of esophagitis above a stricture suggests the possibility of a chemical-induced injury or a neoplasm as a cause. The latter should always be considered and is ruled out only by evaluation of a tissue biopsy of adequate size. It should be remembered that gastroesophageal reflux is not always associated with visible mucosal abnormali-ties, and patients can experience significant reflux symptoms, despite an apparently normal endoscopy examination.Barrett’s esophagus (BE) is a condition in which the tubu-lar esophagus is lined with columnar epithelium, as opposed to the normal squamous epithelium (see Fig. 25-16). Histologi-cally, it appears as intestinal metaplasia (IM). It is suspected at endoscopy when there is difficulty in visualizing the squamoco-lumnar junction at its normal location, and by the appearance of a redder, salmon-colored mucosa in the lower esophagus, with a clearly visible line of demarcation at the top of the Barrett’s esophagus segment. Its presence is confirmed by biopsy. Mul-tiple biopsy specimens should be taken in a cephalad direction to confirm the presence of IM, and to evaluate the Barrett’s epi-thelium for dysplastic changes. BE is susceptible to ulceration, bleeding, stricture formation, and, most important, malignant degeneration. The earliest sign of the latter is high grade dys-plasia or intramucosal adenocarcinoma (see Fig. 25-16). These dysplastic changes have a patchy distribution, so a minimum of four biopsy samples spaced 2 cm apart should be taken from the Barrett’s-lined portion of the esophagus. Changes seen in one biopsy are significant. Nishimaki has determined that the tumors occur in an area of specialized columnar epithelium near the squamocolumnar junction in 85% of patients, and within 2 cm of the squamocolumnar junction in virtually all patients. Particular attention should be focused on this area in patients suspected of harboring a carcinoma.Abnormalities of the gastroesophageal flap valve can be visualized by retroflexion of the endoscope. Hill has graded the appearance of the gastroesophageal valve from I to IV according to the degree of unfolding or deterioration of the normal valve architecture (Fig. 25-17). The appearance of the valve correlates with the presence of increased esophageal acid exposure, occur-ring predominantly in patients with grade III and IV valves.A hiatal hernia is endoscopically confirmed by finding a pouch lined with gastric rugal folds lying 2 cm or more above the margins of the diaphragmatic crura, identified by having the patient sniff. A hernia is best demonstrated with the stomach fully insufflated and the gastroesophageal junction observed with a retroflexed endoscope. A prominent sliding hiatal hernia frequently is associated with increased esophageal exposure to gastric juice. When a paraesophageal hernia (PEH) is observed, particular attention is taken to exclude gastric (Cameron’s) ulcers or gastritis within the pouch. The intragastric retroflex or J maneuver is important in evaluating the full circumference of the mucosal lining of the herniated stomach.When an esophageal diverticulum is seen, it should be carefully explored with the flexible endoscope to exclude ulceration or neoplasia. When a submucosal mass is identified, biopsy specimens are usually not performed. At the time of sur-gical resection, a submucosal leiomyoma or reduplication cyst can generally be dissected away from the intact mucosa, but if a biopsy sample is taken, the mucosa may become fixed to the underlying abnormality. This complicates the surgical dissec-tion by increasing the risk of mucosal perforation. Endoscopic ultrasound provides a better method for evaluating these lesions.Radiographic Evaluation. Barium swallow evaluation is under-taken selectively to assess anatomy and motility. The anatomy of large hiatal hernias is more clearly demonstrated by contrast radi-ology than endoscopy, and the presence of coordinated esopha-geal peristalsis can be determined by observing several individual swallows of barium traversing the entire length of the organ, with the patient in the horizontal position. Hiatal hernias are best demonstrated with the patient prone because the increased intra-abdominal pressure produced in this position promotes displace-ment of the esophagogastric junction above the diaphragm. To detect lower esophageal narrowing, such as rings and strictures, fully distended views of the esophagogastric region are crucial. The density of the barium used to study the esophagus can poten-tially affect the accuracy of the examination. Esophageal disorders shown clearly by a full-column technique include circumferential carcinomas, peptic strictures, large esophageal ulcers, and hia-tal hernias. A small hiatal hernia is usually not associated with significant symptoms or illness, and its presence is an irrelevant finding unless the hiatal hernia is large (Fig. 25-18) or the hernia 1Brunicardi_Ch25_p1009-p1098.indd 101801/03/19 6:02 PM 1019ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Figure 25-16. Complications of reflux disease as seen on endoscopy. A. Linear erosions of LA grade B esophagitis. B. Uncomplicated Barrett’s mucosa. C. High-grade dysplasia in Barrett’s mucosa. D. Early adenocarcinoma arising in Barrett’s mucosa.is of the paraesophageal variety. Lesions extrinsic but adjacent to the esophagus can be reliably detected by the full-column tech-nique if they contact the distended esophageal wall. Conversely, a number of important disorders may go undetected if this is the sole technique used to examine the esophagus. These include small esophageal neoplasms, mild esophagitis, and esophageal varices. Thus, the full-column technique should be supplemented with mucosal relief or double-contrast films to enhance detection of these smaller or more subtle lesions.Motion-recording techniques greatly aid in evaluating functional disorders of the pharyngoesophageal and esophageal phases of swallowing. The technique and indications for cineand videoradiography will be discussed in the section entitled “Videoand Cineradiography,” as they are more useful to evalu-ate function and seldom used to detect structural abnormalities.The radiographic assessment of the esophagus is not com-plete unless the entire stomach and duodenum have been examined. A gastric or duodenal ulcer, partially obstructing gastric neoplasm, or scarred duodenum and pylorus may contribute significantly to symptoms otherwise attributable to an esophageal abnormality.When a patient’s complaints include dysphagia and no obstructing lesion is seen on the barium swallow, it is useful to have the patient swallow a barium-impregnated marshmallow, a barium-soaked piece of bread, or a hamburger mixed with bar-ium. This test may bring out a functional disturbance in esopha-geal transport that can be missed when liquid barium is used.Tests to Detect Functional AbnormalitiesIn many patients with symptoms of an esophageal disorder, standard radiographic and endoscopic evaluation fails to dem-onstrate a structural abnormality. In these situations, esophageal function tests are necessary to identify a functional disorder.Esophageal Motility. Esophageal motility is a widely used technique to examine the motor function of the esophagus and ABCDBrunicardi_Ch25_p1009-p1098.indd 101901/03/19 6:02 PM 1020SPECIFIC CONSIDERATIONSPART IIBACFigure 25-17. A. Grade I flap valve appearance. Note the ridge of tissue that is closely approximated to the shaft of the retroflexed endoscope. It extends 3 to 4 cm along the lesser curve. B. Grade II flap valve appearance. The ridge is slightly less well defined than in grade I and it opens rarely with respiration and closes promptly. C. Grade III flap valve appearance. The ridge is barely present, and there is often failure to close around the endoscope. It is nearly always accompanied by a hiatal hernia. D. Grade IV flap valve appearance. There is no muscular ridge at all. The gastroesophageal valve stays open all the time, and squamous epithelium can often be seen from the retroflexed position. A hiatal hernia is always present. (Reproduced with permission from Hill LD, Kozarek RA, Kraemer SJ, et al: The gastroesophageal flap valve: in vitro and in vivo observations, Gastrointest Endosc. 1996 Nov;44(5):541-547.)Brunicardi_Ch25_p1009-p1098.indd 102001/03/19 6:02 PM 1021ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Figure 25-18. Radiogram of an intrathoracic stomach. This is the end stage of a large hiatal hernia, regardless of its initial classification.RIP = Respiratory inversion pointRIP43424140393837 cmOverall lengthPressure10 secEsophagealbaselinepressureAbdominal lengthGastricbaselinepressureFigure 25-19. Manometric pressure profile of the lower esophageal sphincter. The distances are measured from the nares. (Reproduced with permission from Zaninotto G, DeMeester TR, Schwizer W, et al: The lower esophageal sphincter in health and disease, Am J Surg. 1988 Jan;155(1):104-11.)DFigure 25-17. (Continued )its sphincters. The esophageal motility study (EMS) is indicated whenever a motor abnormality of the esophagus is suspected on the basis of complaints of dysphagia, odynophagia, or noncar-diac chest pain, and the barium swallow or endoscopy does not show a clear structural abnormality. EMS is particularly neces-sary to confirm the diagnosis of specific primary esophageal motility disorders (i.e., achalasia, diffuse esophageal spasm [DES], nutcracker esophagus, and hypertensive LES). It also identifies nonspecific esophageal motility abnormalities and motility disorders secondary to systemic disease such as sclero-derma, dermatomyositis, polymyositis, or mixed connective tis-sue disease. In patients with symptomatic GERD, manometry of the esophageal body can identify a mechanically defective LES and evaluate the adequacy of esophageal peristalsis and contraction amplitude. EMS has become an essential tool in the preoperative evaluation of patients before antireflux surgery, guiding selection of the appropriate procedure based upon the patient’s underlying esophageal function and excluding patients with achalasia who can be misdiagnosed with gastroesophageal reflux when clinical and endoscopic parameters alone are used for diagnosis.EMS is performed using electronic, pressure-sensitive transducers located within the catheter, or water-perfused cath-eters with lateral side holes attached to transducers outside the body. The traditional water perfused catheter has largely been replaced by high resolution motility (HRM), but knowledge of traditional methods of assessing esophageal motility is helpful for understanding esophageal physiology.As the pressure-sensitive station is brought across the gas-troesophageal junction (GEJ), a rise in pressure above the gas-tric baseline signals the beginning of the LES. The respiratory inversion point is identified when the positive excursions that occur in the abdominal cavity with breathing change to negative deflections in the thorax. The respiratory inversion point serves as a reference point at which the amplitude of LES pressure and the length of the sphincter exposed to abdominal pressure are measured. As the pressure-sensitive station is withdrawn into the body of the esophagus, the upper border of the LES is identified by the drop in pressure to the esophageal baseline. From these measurements, the pressure, abdominal length, and overall length of the sphincter are determined (Fig. 25-19). To Brunicardi_Ch25_p1009-p1098.indd 102101/03/19 6:02 PM 1022SPECIFIC CONSIDERATIONSPART IILALPLPARPRRA25050Figure 25-20. Radial configuration of the lower esophageal sphincter. A = anterior; L = left; LA = left anterior; LP = left pos-terior; P = posterior; R = right; RA = right anterior; RP = right pos-terior. (Reproduced with permission from Winans CS: Manometric asymmetry of the lower-esophageal high-pressure zone, Am J Dig Dis. 1977 Apr;22(4):348-354.)Table 25-1Normal manometric values of the distal esophageal sphincter, n = 50  MEDIAN PERCENTILE2.597.5Pressure (mmHg)135.827.7Overall length (cm)3.62.15.6Abdominal length (cm)20.94.7 MEANMEAN – 2 SDMEAN + 2 SDPressure (mmHg)13.8 ± 4.64.623.0Overall length (cm)3.7 ± 0.82.15.3Abdominal length (cm)2.2 ± 0.80.63.8SD = standard deviation.Reproduced with permission from Moody FG, Carey LC, Jones RS, et al: Surgical Treatment of Digestive Disease. Chicago, IL: Year Book Medical; 1990.account for the asymmetry of the sphincter (Fig. 25-20), the pressure profile is repeated with each of the five radially ori-ented transducers, and the average values for sphincter pressure above gastric baseline, overall sphincter length, and abdominal length of the sphincter are calculated.Table 25-1 shows the values for these parameters in 50 normal volunteers without subjective or objective evidence of a foregut disorder. A mechanically defective sphincter is identified by having one or more of the following characteristics: an average LES pressure of <6 mmHg, an average length exposed to the positive-pressure environment in the abdomen of 1 cm or less, and/or an average overall sphincter length of 2 cm or less.High-Resolution Manometry. Esophageal manometry was introduced into clinical practice in the 1970s and, until recently, has changed little. In 1991, Ray Clouse introduced the concept of improving conventional manometry by increasing the number of recording sites and adding a three-dimensional assessment. This “high-resolution manometry” is a variant of the conventional manometry in which multiple, circumferential recording sites are used, in essence creating a “map” of the esophagus and its sphincters. High-resolution catheters contain 36 miniaturized pressure sensors positioned every centimeter along the length of the catheter. The vast amount of data generated by these sensors is then processed and presented in traditional linear plots or as a visually enhanced spatiotemporal video tracing that is readily interpreted. The function of the esophageal body is assessed with 10 to 15 wet swallows. Amplitude, duration, and morphology of contractions following each swallow are visually displayed (Fig. 25-21).The relationship of the esophageal contractions following a swallow is classified as peristaltic or simultaneous. The data are used to identify motor disorders of the esophagus.The position, length, and function of the lower esopha-geal sphincter (LES) are demonstrated by a high-pressure zone that should relax at the inception of swallowing and contract after the water or solid bolus passes through the LES. Simul-taneous acquisition of data for the upper esophageal sphinc-ter, esophageal body, LES, and gastric pressure minimizes the movement artifacts and study time associated with conven-tional esophageal manometry. This technology significantly enhances esophageal diagnostics, bringing it into the realm of “image”-based studies. High-resolution manometry may allow the identification of focal motor abnormalities previ-ously overlooked. It has enhanced the ability to predict bolus propagation and increased sensitivity in the measurement of pressure gradients.Esophageal Impedance. Newer technology introduced into the clinical realm a decade ago allows measurement of esophageal function and gastroesophageal reflux in a way that was previously not possible. An intraluminal electrical imped-ance catheter is used to measure GI function. Impedance is the ratio of voltage to current, and is a measure of the electrical conductivity of a hollow organ and its contents. Intraluminal electrical impedance is inversely proportional to the electrical conductivity of the luminal contents and the cross-sectional area of the lumen. Air has a very low electrical conductivity and, therefore, high impedance. Saliva and food cause an imped-ance decrease because of their increased conductivity. Luminal dilatation results in a decrease in impedance, whereas luminal contraction yields an impedance increase. Investigators have established the impedance waveform characteristics that define esophageal bolus transport. This allows for the characterization of both esophageal function, via quantification of bolus trans-port, and gastroesophageal reflux (Fig. 25-22). The probe mea-sures impedance between adjacent electrodes, with measuring segments located at 2, 4, 6, 8, 14, and 16 cm from the distal tip. An extremely low electric current of 0.00025 μW is transmitted across the electrodes at a frequency of 1 to 2 kHz and is limited Brunicardi_Ch25_p1009-p1098.indd 102201/03/19 6:02 PM 1023ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Figure 25-21A. Normal high-resolution manometry motility study. Pressure measurements are recorded with color coding (red = high; blue = low). LES = lower esophageal sphincter; PIP = pressure inversion point; UES = upper esophageal sphincter.UES19.0LES41.840.343.7Gastric 46.2PIP42.3EsophagusPharynxStomachBrunicardi_Ch25_p1009-p1098.indd 102301/03/19 6:02 PM 1024SPECIFIC CONSIDERATIONSPART IIFigure 25-21B. High-resolution manometry motility study in patient with mechanically defective lower esophageal sphincter. Note the absence of lower esophageal sphincter tone. Pressure measure-ments are recorded with color coding (red = high; blue = low). LES = lower esophageal sphincter; PIP = pressure inversion point; UES = upper esophageal sphincter.EsophagusStomachPharynxUES20.8LES41.9PIP41.841.342.7Gastric 50.3Brunicardi_Ch25_p1009-p1098.indd 102401/03/19 6:02 PM 1025ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Figure 25-21C. High-resolution manometry motility study in patient with deficient esophageal body peristalsis. Note the very weak peristalsis in the lower two-thirds of the esophagus. Pressure measurements are recorded with color coding (red = high; blue = low). LES = lower esophageal sphincter; PIP = pressure inversion point; UES = upper esophageal sphincter.EsophagusPharynxUES18.740.944.6Gastric 47.5LES42.2PIP42.3StomachBrunicardi_Ch25_p1009-p1098.indd 102501/03/19 6:02 PM 1026SPECIFIC CONSIDERATIONSPART IIFigure 25-21D. High-resolution manometry motility study in patient with achalasia. Note the complete absence of esophageal body peristalsis, and the lack of relaxation of the lower esophageal sphincter. Pressure measurements are recorded with color coding (red = high; blue = low). LES = lower esophageal sphincter; PIP = pressure inversion point; UES = upper esophageal sphincter.EsophagusUES18.0Gastric 48.542.745.7LES43.8PIP44.1StomachPharynxBrunicardi_Ch25_p1009-p1098.indd 102601/03/19 6:03 PM 1027ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Figure 25-21E. High-resolution manometry motility study in patient with diffuse esophageal spasm. Note the very high amplitude contractions in the esophageal body. Pressure measurements are recorded with color coding (red = high; blue = low). LES = lower esophageal sphincter; PIP = pressure inversion point; UES = upper esophageal sphincter.Gastric 51.745.6PharynxEsophagusLES47.4PIP47.1UES20.349.7StomachBrunicardi_Ch25_p1009-p1098.indd 102701/03/19 6:03 PM 1028SPECIFIC CONSIDERATIONSPART IIpH siteImpedence site17cm15cm9cm7cm5cmDistance above LESDistance above LES5cmLES3cmFigure 25-22. Esophageal impedance probe measures electrical resistance between evenly spaced electrodes. LES = lower esopha-geal sphincter.to 8 μA. This is below the stimulation threshold for nerves and muscles and is three orders of magnitude below the thresh-old of cardiac stimulation. A standard pH electrode is located 5 cm from the distal tip so that the acidic or nonacidic nature of refluxate can be correlated with the number of reflux events.Esophageal impedance has been validated as an appropri-ate method for the evaluation of GI function and is used selec-tively for the diagnosis of gastroesophageal reflux. It has been compared to cineradiography showing that impedance waves correspond well with actual bolus transport illustrated by radi-ography. Bolus entry, transit, and exit can be clearly identified by impedance changes in the corresponding measuring seg-ments. Studies comparing standard esophageal manometry with impedance measurements in healthy volunteers have shown that esophageal impedance correlates with peristaltic wave progres-sion and bolus length.Twenty-four-hour pH monitoring, the historical gold stan-dard for diagnosing and quantifying gastroesophageal reflux, has some significant limitations. With 24-hour ambulatory pH testing, reflux is defined as a drop in the pH below 4, which effectively “blinds” the test to reflux occurring at higher pH values. Furthermore, in patients with persistent symptoms on proton pump inhibitor (PPI) therapy, pH monitoring has lim-ited use as it can only detect abnormal acid reflux (pH <4), the occurrence of which has been altered by the antisecretory medi-cation. Given that PPI antisecretory therapy is highly effective in neutralizing gastric acid, the question of whether persistent symptoms are a result of persistent acid reflux, nonacid reflux, or are not reflux related becomes a key issue in surgical decision making. Until recently, this differentiation could not be made. Detection of both acid and nonacid reflux has potential to define these populations of patients and thus improve patient selection for antireflux surgery. Multichannel intraluminal impedance technology allows the measurement of both acid and nonacid reflux, with potential to enhance diagnostic accuracy.Using this technology, Balaji and colleagues showed that most gastroesophageal reflux remains despite acid suppression. Impedance pH may be particularly useful in evaluating patients with persistent symptoms despite PPI treatment, patients with respiratory symptoms, and postoperative patients who are hav-ing symptoms that are elusive to diagnosis.Esophageal Transit Scintigraphy. The esophageal transit of a 10-mL water bolus containing technetium-99m (99mTc) sulfur colloid can be recorded with a gamma camera. Using this tech-nique, delayed bolus transit has been shown in patients with a variety of esophageal motor disorders, including achalasia, scleroderma, DES, and nutcracker esophagus.Videoand CineradiographyHigh-speed cinematic or video recording of radiographic studies allows re-evaluation by reviewing the studies at various speeds. This technique is more useful than manometry in the evaluation of the pharyngeal phase of swallowing. Observations suggesting oropharyngeal or cricopharyngeal dysfunction include misdirec-tion of barium into the trachea or nasopharynx, prominence of the cricopharyngeal muscle, a Zenker’s diverticulum, a narrow pharyngoesophageal segment, and stasis of the contrast medium in the valleculae or hypopharyngeal recesses (Fig. 25-23). These findings are usually not specific, but rather common manifesta-tions of neuromuscular disorders affecting the pharyngoesoph-ageal area. Studies using liquid barium, barium-impregnated solids, or radiopaque pills aid the evaluation of normal and abnormal motility in the esophageal body. Loss of the normal stripping wave or segmentation of the barium column with the patient in the recumbent position correlates with abnormal motility of the esophageal body. In addition, structural abnor-malities such as small diverticula, webs, and minimal extrin-sic impressions of the esophagus may be recognized only with motion-recording techniques. The simultaneous computerized capture of videofluoroscopic images and manometric tracings is now available and is referred to as manofluorography. Mano-fluorographic studies allow precise correlation of the anatomic events, such as opening of the upper esophageal sphincter, with manometric observations, such as sphincter relaxation. Mano-fluorography, although not widely available, is presently the best means available to evaluate complex functional abnormalities.Tests to Detect Increased Exposure to Gastric JuiceTwenty-Four-Hour Ambulatory pH Monitoring. The most direct method of measuring increased esophageal exposure to gas-tric juice is by an indwelling pH electrode, or, more recently, via a radiotelemetric pH monitoring capsule that can be clipped to the esophageal mucosa. The latter consists of an antimony pH elec-trode fitted inside a small, capsule-shaped device accompanied by a battery and electronics that allow 48-hour monitoring and transmission of the pH data via transcutaneous radio telemetry to a waist-mounted data logger. The device can be introduced either transorally or transnasally, and it can be clipped to the esophageal mucosa using endoscopic fastening techniques. It passes sponta-neously within 1 to 2 weeks. Prolonged monitoring of esophageal pH is performed by placing the pH probe or telemetry capsule 5 cm above the manometrically measured upper border of the dis-tal sphincter for 24 hours. It measures the actual time the esopha-geal mucosa is exposed to gastric juice, measures the ability of the esophagus to clear refluxed acid, and correlates esophageal acid exposure with the patient’s symptoms. A 24to 48-hour period is necessary so that measurements can be made over one or two complete circadian cycles. This allows measuring the effect of physiologic activity, such as eating or sleeping, on the reflux of gastric juice into the esophagus (Fig. 25-24).Brunicardi_Ch25_p1009-p1098.indd 102801/03/19 6:03 PM 1029ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25mpmppH8642mppH8642pH8642sp06:0000:0022:0002:0004:0022:0016:0014:0018:0020:0014:0008:0006:0010:0012:00Figure 25-24. Strip chart display of a 24-hour esophageal pH monitoring study in a patient with increased esophageal acid expo-sure. mp = meal period; sp = supine period. (Reproduced with per-mission from Zuidema GD, Orringer MB: Shackelford’s Surgery of the Alimentary Tract, 3rd ed. Vol 1. Philadelphia, PA: Elsevier/Saunders; 1991.)BATable 25-2Normal values for esophageal exposure to pH <4 (n = 50)COMPONENTMEANSD95%Total time1.511.364.45Upright time2.342.348.42Supine time0.631.03.45No. of episodes19.0012.7646.90No. >5 min0.841.183.45Longest episode6.747.8519.80SD = standard deviation.Reproduced with permission from Moody FG, Carey LC, Jones RS, et al: Surgical Treatment of Digestive Disease. Chicago, IL: Year Book Medical; 1990.Figure 25-23. Esophagograms from a patient with cricopharyngeal achalasia. A. Anteropos-terior film showing retention of the contrast medium at the level of the vallecula and piriform recesses, with no barium passing into the esopha-gus. B. Lateral film, taken opposite the C5–C6 vertebrae, showing posterior indentation of the cricopharyngeus, retention in the hypopharynx, and tracheal aspiration. (Reproduced with per-mission from DeMeester TR, Matthews H: Inter-national Trends in General Thoracic Surgery. Vol 3. Benign Esophageal Disease. St. Louis, Mo: Mosby; 1987.)The 24-hour esophageal pH monitoring should not be con-sidered a test for reflux, but rather a measurement of the esopha-geal exposure to gastric juice. The measurement is expressed by the time the esophageal pH was below a given threshold during the 24-hour period (Table 25-3). This single assess-ment, although concise, does not reflect how the exposure has occurred; that is, did it occur in a few long episodes or several short episodes? Consequently, two other assessments are neces-sary: the frequency of the reflux episodes and their duration.The units used to express esophageal exposure to gastric juice are: (a) cumulative time the esophageal pH is below a cho-sen threshold, expressed as the percentage of the total, upright, and supine monitored time; (b) frequency of reflux episodes below a chosen threshold, expressed as number of episodes per 24 hours; and (c) duration of the episodes, expressed as the number of episodes >5 minutes per 24 hours, and the time in minutes of the longest episode recorded. Table 25-2 shows the normal values for these components of the 24-hour record at the whole-number pH threshold derived from 50 normal asymptom-atic subjects. The upper limits of normal were established at the 95th percentile. Most centers use pH 4 as the threshold.Based on these studies and extensive clinical experience, 48-hour esophageal pH monitoring is considered to be the gold standard for the diagnosis of GERD.The Bravo pH Capsule (Medtronics, Minneapolis, MN) measures pH levels in the esophagus and transmits continuous Brunicardi_Ch25_p1009-p1098.indd 102901/03/19 6:03 PM 1030SPECIFIC CONSIDERATIONSPART II210:0012:0014:0016:0018:0047pH218:0020:0022:0000:0002:0047202:0004:0006:0008:0010:0047pH probe5 cmabove5 cmbelowBACombined 24-hourgastric and esophagealpH monitoringFigure 25-25. A. Combined esophageal and gastric pH monitoring showing position of probes in relation to the lower esophageal sphincter. B. Combined ambulatory esophageal (upper tracing) and gastric (lower tracing) pH monitoring showing duodenogastric reflux (arrows) with propagation of the alkaline juice into the esophagus of a patient with complicated Barrett’s esophagus. The gastric tracing (lower) is taken from a probe lying 5 cm below the upper esophageal sphincter. The esophageal tracing (upper) is taken from a probe lying 5 cm above the lower esophageal sphincter. Note that in only a small proportion of time does duodenogastric reflux move the pH of the esophagus above the threshold of 7, causing the iceberg effect. (Reproduced with permission from Zuidema GD, Orringer MB: Shackelford’s Surgery of the Alimentary Tract, 3rd ed. Vol 1. Philadelphia, PA: Elsevier/Saunders; 1991.)Table 25-3Normal composite score for various pH thresholds: upper level of normal valuepH THRESHOLD95TH PERCENTILE<114.2<217.37<314.10<414.72<515.76<612.76>714.90>88.50Reproduced with permission from Moody FG, Carey LC, Jones RS, et al: Surgical Treatment of Digestive Disease. Chicago, IL: Year Book Medical; 1990.esophageal pH readings to a receiver worn on the patient’s belt or waistband (Fig. 25-25). Symptoms that the patient experi-ences are recorded in a diary and/or by pressing buttons on the receiver unit. Generally, 48 hours of pH data are measured with this probe. A recent study has shown that the addition of a second day of pH monitoring increased the sensitivity of pH measurement by 22%. The capsule eventually detaches and passes through the digestive tract in 5 to 7 days.Radiographic Detection of Gastroesophageal Reflux. The definition of radiographic gastroesophageal reflux varies depend-ing on whether reflux is spontaneous or induced by various maneu-vers. In only about 40% of patients with classic symptoms of GERD is spontaneous reflux (i.e., reflux of barium from the stom-ach into the esophagus with the patient in the upright position) observed by the radiologist. In most patients who show spon-taneous reflux on radiography, the diagnosis of increased esophageal acid exposure is confirmed by 24-hour esophageal pH monitoring. Therefore, the radiographic demonstration of sponta-neous regurgitation of barium into the esophagus in the upright position is a reliable indicator that reflux is present. However, fail-ure to see this does not indicate the absence of disease, and for this reason this test is rarely used for clinical diagnosis.Tests of Duodenogastric FunctionEsophageal disorders are frequently associated with abnormali-ties of duodenogastric function. Abnormalities of the gastric res-ervoir or increased gastric acid secretion can be responsible for increased esophageal exposure to gastric juice. Reflux of alka-line duodenal juice, including bile salts, pancreatic enzymes, and bicarbonate, is thought to have a role in the pathogenesis of esophagitis and complicated Barrett’s esophagus. Furthermore, functional disorders of the esophagus are often not confined to 2Brunicardi_Ch25_p1009-p1098.indd 103001/03/19 6:03 PM 1031ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25the esophagus alone, but are associated with functional disor-ders of the rest of the foregut (i.e., stomach and duodenum). Tests of duodenogastric function that are helpful to investigate esophageal symptoms include gastric emptying studies, gastric acid analysis, and cholescintigraphy (for the diagnosis of patho-logic duodenogastric and/or duodenogastroesophageal reflux).Gastric Emptying Study. Gastric emptying studies are performed with radionuclide-labeled meals. Emptying of solids and liquids can be assessed simultaneously when both phases are marked with different tracers. After ingestion of a labeled standard meal, gamma camera images of the stomach are obtained at 5to 15-minute inter-vals for 2 to 4 hours. After correction for decay, the counts in the gastric area are plotted as the percentage of total counts at the start of the imaging. The resulting emptying curve can be compared with data obtained in normal volunteers. In general, normal subjects will empty 59% of a meal within 90 minutes. Although delayed gas-tric emptying is often associated with gastroesophageal reflux, in general delayed emptying does not correlate with a poorer clinical outcome after antireflux surgery, and it should not be considered a contraindication to surgical treatment.GASTROESOPHAGEAL REFLUX DISEASEGERD was not recognized as a significant clinical problem until the mid-1930s and was not identified as a precipitating cause for esophagitis until after World War II. In the early 21st century, it has grown to be a very common problem and now accounts for a majority of esophageal pathology. It is recognized as a chronic disease, and when medical therapy is required, it is often lifelong treatment. Recent efforts at the development of various endoscopic antireflux interventions, although innovative, have not been successful in consistently controlling gastroesophageal reflux. Antireflux surgery is an effective and long-term therapy and is the only treatment that is able to restore the gastroesopha-geal barrier. Despite the common prevalence of GERD, it can be one of the most challenging diagnostic and therapeutic problems in clinical medicine. A contributing factor to this is the lack of a universally accepted definition of the disease.The most simplistic approach is to define the disease by its symptoms. However, symptoms thought to be indicative of GERD, such as heartburn or acid regurgitation, are very com-mon in the general population and many individuals consider them to be normal and do not seek medical attention. Even when excessive, these symptoms are not specific for gastroesophageal reflux. They can be caused by other diseases such as achalasia, DES, esophageal carcinoma, pyloric stenosis, cholelithiasis, gastritis, gastric or duodenal ulcer, and coronary artery disease.A thorough, structured evaluation of the patient’s symptoms is essential before any therapy, particularly any form of esopha-geal surgery. The presence and severity of both typical symp-toms of heartburn, regurgitation, and dysphagia, and atypical symptoms of cough, hoarseness, chest pain, asthma, and aspira-tion should be discussed with the patient in detail. Many of these atypical symptoms may not be esophageal related and hence will not improve and may even worsen with antireflux surgery.Heartburn is generally defined as a substernal burning-type discomfort, beginning in the epigastrium and radiating upward. It is often aggravated by meals, spicy or fatty foods, chocolate, alcohol, and coffee and can be worse in the supine position. It is commonly, although not universally, relieved by antacid or antisecretory medications. Epidemiologic studies have shown that heartburn occurs monthly in as many as 40% Table 25-4American Gastroenterologic Association Gallup poll on nighttime gastroesophageal reflux disease symptoms• 50 million Americans have nighttime heartburn at least 1/wk• 80% of heartburn sufferers had nocturnal symptoms—65% both day & night• 63% report that it affects their ability to sleep and impacts their work the next day• 72% are on prescription medications• Nearly half (45%) report that current remedies do not relieve all symptomsto 50% of the Western population. The occurrence of heartburn at night and its effect on quality of life have recently been high-lighted by a Gallup poll conducted by the American Gastroen-terologic Society (Table 25-4).Regurgitation, the effortless return of acid or bitter gastric contents into the chest, pharynx, or mouth, is highly suggestive of foregut pathology. It is often particularly severe at night when supine or when bending over and can be secondary to either an incompetent or obstructed GEJ. With the latter, as in achalasia, the regurgitant is often bland, as if food was put into a blender. When questioned, most patients can distinguish the two. It is the regurgitation of gastric contents that may result in associated pulmonary symptoms, including cough, hoarseness, asthma, and recurrent pneumonia. Bronchospasm can be precipitated by esophageal acidification and cough by either acid stimulation or distention of the esophagus.Dysphagia, or difficulty swallowing, is a relatively non-specific term but arguably the most specific symptom of foregut disease. It can be a sign of underlying malignancy and should be aggressively investigated until a diagnosis is established. Dyspha-gia refers to the sensation of difficulty in the passage of food from the mouth to the stomach and can be divided into oropharyngeal and esophageal etiologies. Oropharyngeal dysphagia is charac-terized by difficulty transferring food out of the mouth into the esophagus, nasal regurgitation, and/or aspiration. Esophageal dys-phagia refers to the sensation of food sticking in the lower chest or epigastrium. This may or may not be accompanied by pain (ody-nophagia) that will be relieved by the passage of the bolus.Chest pain, although commonly and appropriately attrib-uted to cardiac disease, is frequently secondary to esophageal pathology as well. Nearly 50% of patients with severe chest pain, normal cardiac function, and normal coronary arterio-grams have positive 24-hour pH studies, implicating gastro-esophageal reflux as the underlying etiology. Exercise-induced gastroesophageal reflux is well known to occur, and may result in exertional chest pain similar to angina. It can be quite diffi-cult, if not impossible, to distinguish between the two etiologies, particularly on clinical grounds alone. Nevens and colleagues evaluated the ability of experienced cardiologists to differentiate pain of cardiac vs. esophageal origin. Of 248 patients initially seen by cardiologists, 185 were thought to have typical angina, and 63 were thought to have atypical chest pain. Forty-eight (26%) of those thought to have classic angina had normal coro-nary angiograms, and 16 of the 63 with atypical pain had abnor-mal angiogram. Thus, the cardiologists’ clinical impression was wrong 25% of the time. Finally, Pope and associates investi-gated the ultimate diagnosis in 10,689 patients presenting to an Brunicardi_Ch25_p1009-p1098.indd 103101/03/19 6:03 PM 1032SPECIFIC CONSIDERATIONSPART IITable 25-5Normal manometric values of the distal esophageal sphincter, n = 50PARAMETERMEDIAN VALUE2.5TH PERCENTILE97.5TH PERCENTILEPressure (mmHg)135.827.7Overall length (cm)3.62.15.6Abdominal length (cm)20.94.7emergency department with acute chest pain. Approximately 17% were found to have acute ischemia, 6% had stable angina, 21% had other cardiac causes, and 55% had noncardiac causes. The investigators concluded that the majority of people present-ing to the emergency department with chest pain do not have an underlying cardiac etiology for their symptoms. Chest pain pre-cipitated by meals, occurring at night while supine, nonradiat-ing, responsive to antacid medication, or accompanied by other symptoms suggesting esophageal disease such as dysphagia or regurgitation should trigger the thought of possible esophageal origin. Furthermore, the distinction between heartburn and chest pain is also difficult and largely dependent upon the individual patient. One person’s heartburn is another’s chest pain.The precise mechanisms accounting for the generation of symptoms secondary to esophageal pathology remain unclear. Considerable insight has been acquired, however. Investiga-tions into the effect of luminal content, esophageal distention and muscular function, neural pathways, and brain localization have provided a basic understanding of the stimuli responsible for symptom generation. It is also clear that the visceroneural pathways of the foregut are complexly intertwined with that of the tracheobronchial tree and heart. This fact accounts for the common overlap of clinical presentations with diverse disease processes in upper GI, cardiac, and pulmonary systems.The Human Antireflux Mechanism and the Pathophysiology of Gastroesophageal Reflux DiseaseThere is a high-pressure zone located at the esophagogastric junc-tion in humans. Although this is typically referred to as the lower esophageal “sphincter,” there are no distinct anatomical land-marks that define its beginning and end. Architecturally speak-ing, there is a specialized thickening in this region that is made up of the collar sling musculature and the clasp fibers. The collar sling is located on the greater curvature side of the junction, and the clasp fibers are located on the lesser curvature side. These muscles remain in tonic opposition until the act of swallowing, whereupon receptive relaxation occurs allowing passage of a food bolus into the stomach. In addition, the LES will also open when the gastric fundus is distended with gas and liquid, thus resulting in an unfolding of the valve and enabling venting of gas (a belch). Whether physiologic or pathologic, the common denominator for most episodes of gastroesophageal reflux is the loss of the high-pressure zone and thus a decrease in the resistance it imparts to the retrograde flow of gastric juice into the esophageal body.The Lower Esophageal Sphincter. As defined by esophageal manometry, there are three characteristics of the LES that work in unison to maintain its barrier function. These characteristics include the resting LES pressure, its overall length, and the intra-abdominal length that is exposed to the positive pressure environment of the abdomen (Table 25-5). The resistance to gastroesophageal reflux is a function of both the resting LES pressure and length over which this pressure is exerted. Thus, as the sphincter becomes shorter, a higher pressure will be required in order to prevent a given amount of reflux (Fig. 25-26). Much like the neck of a balloon as it is inflated, as the stomach fills and distends, sphincter length decreases. Therefore, if the over-all length of the sphincter is permanently short from repeated distention of the fundus secondary to large volume meals, then with minimal episodes of gastric distention and pressure, there will be insufficient sphincter length for the barrier to remain competent, and reflux will occur.LES length (cm)LES pressure (mmHg)60012CompetentIncompetent345121824Figure 25-26. As the esophageal sphincter becomes shorter, increased pressure is necessary to maintain competence. LES = lower esophageal sphincter.A third characteristic of the LES that impacts its ability to prevent reflux is its position about the diaphragm. It is important that a portion of the total length of the LES be exposed to the effects of an intra-abdominal pressure. That is, during periods of elevated intra-abdominal pressure, the resistance of the barrier would be overcome if pressure were not applied equally to both the LES and stomach simultaneously. Thus, in the presence of a hiatal hernia, the sphincter resides entirely within the chest cavity and cannot respond to an increase in intra-abdominal pressure because the pinch valve mechanism is lost and gastro-esophageal reflux is more liable to occur.Therefore, a permanently defective sphincter is defined by one or more of the following characteristics: an LES with a mean resting pressure of less than 6 mmHg, an overall sphincter length of <2 cm, and intra-abdominal sphincter length of <1 cm. Compared to normal subjects without GERD these values are below the 2.5 percentile for each parameter. The most com-mon cause of a defective sphincter is an inadequate abdominal length.Once the sphincter is permanently defective, this condi-tion is irreversible, and although esophageal mucosal injury may be healed with antisecretory medication, reflux will continue to occur. Additionally, the presence of a defective LES may be associated with reduced esophageal body function and thus decrease clearance times of refluxed material. In addition, the progressive loss of effective esophageal clearance may predis-pose the patient to severe mucosal injury, volume regurgitation, aspiration, and pulmonary injury. Reflux may occur in the face of a normal LES resting pressure. This condition is usually due to a functional problem of gastric emptying or excessive air swallowing. These conditions may lead to gastric disten-tion, increased intra-gastric pressure, a resultant shortening or Brunicardi_Ch25_p1009-p1098.indd 103201/03/19 6:03 PM 1033ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Table 25-6Complications of gastroesophageal reflux disease: 150 consecutive cases with proven gastroesophageal reflux disease (24-hour esophageal pH monitoring endoscopy, and motility)COMPLICATIONNO.STRUCTURALLY NORMAL SPHINCTER (%)STRUCTURALLY DEFECTIVE SPHINCTER (%)None595842Erosive esophagitis472377aStricture191189Barrett’s esophagus250100Total150  aGrade more severe with defective cardia.Reproduced with permission from Moody FG, Carey LC, Jones RS, et al: Surgical Treatment of Digestive Disease. Chicago, IL: Year Book Medical; 1990.unfolding of the LES, and subsequent reflux. The mechanism by which gastric distention contributes to LES unfolding pro-vides a mechanical explanation for “transient LES relaxation.” It is thought that with repeated gastric distention secondary to large meal volume or chronic air swallowing, there is repeated unfolding of the LES and subsequent attenuation of the collar sling musculature. It is at this point that the physiologic and nor-mal mechanism of gastric venting is replaced with pathologic and severe postprandial reflux disease. In addition, patients with GERD will increase the frequency of swallowing in an effort to neutralize the refluxed acid with their saliva (pH 7.0). This phe-nomenon leads to increased air swallowing and further gastric distention, thus compounding the problem. Therefore, GERD may have its origins in the stomach secondary to gastric disten-tion due to overeating/drinking, air swallowing, or consump-tion of carbonated liquids, and this may be further compounded by the ingestion of fatty meals, which result in delayed gastric emptying.Relationship Between Hiatal Hernia and Gastroesopha-geal Reflux Disease. As the collar sling musculature and clasp fibers become attenuated with repeated gastric distention, the esophagogastric junction begins to assume an “upside down funnel” appearance, with progressive opening of the acute angle of His. This in turn may result in attenuation and stretching of the phrenoesophageal ligament, with subsequent enlargement of the hiatal opening and axial herniation. There is a high degree of correlation between reflux threshold and the degree of hiatal herniation (Fig. 25-27).Summary. It is believed that GERD has its origins within the stomach. Distention of the fundus occurs because of overeat-ing and delayed gastric emptying secondary to a high-fat diet. The resultant distention causes “unrolling” of the sphincter by the expanding fundus, and this subsequently exposes the squa-mous epithelium in the region of the distal LES to gastric juice. Repeated exposure results in inflammation and the development of columnar epithelium at the cardia. This is the initial step of the development of carditis and explains why in early disease esophagitis is mild and commonly limited to the very distal aspect of the esophagus. The patient attempts to compensate for Yield pressure (mmHg)04No hernia< 3 cm hernia3 cm hernia81216202428323640Figure 25-27. Yield pressure of the lower esophageal sphincter decreases as hiatal hernia size increases.this by increased swallowing, allowing the saliva to neutralize the refluxed gastric juice and thus, alleviate the discomfort induced by the reflux event. The increased swallowing results in aeropha-gia, bloating, and belching. This in turn creates a vicious cycle of increased gastric distention and thus further exposure and repeti-tive injury to the distal esophagus. The development of carditis explains the complaint of epigastric pain often experienced by patients with early reflux disease. Additionally, this process can lead to a fibrotic mucosal ring located at the squamocolumnar junction, which is termed a “Schatzki ring” and which may result in dysphagia. This inflammatory process may extend into muscu-laris propria and thus result in a progressive loss in the length and pressure of the LES. This explanation for the pathophysiology of GERD is supported by the observation that severe esophagitis is almost always associated with a defective LES.Complications Associated With Gastroesophageal Reflux DiseaseThe complications of gastroesophageal reflux disease may result from the direct injurious effects of gastric fluid on the mucosa, larynx, or respiratory epithelium. Complications due to repetitive reflux are esophagitis, stricture, and BE; repetitive aspiration may lead to progressive pulmonary fibrosis. The severity of the complications is directly related to the prevalence of a structurally defective sphincter (Table 25-6). The observation that a structurally defective sphincter occurs in 42% of patients without complications (most of whom have one or two components failed) suggests that disease may be confined to the sphincter due to compensation by a vigorously contracting esophageal body. Eventually, all three components of the sphincter fail, allowing unrestricted reflux of gastric juice into the esophagus and overwhelming its normal clearance mechanisms. This leads to esophageal mucosal injury with progressive deterioration of esophageal contractility, as is commonly seen in patients with strictures and BE. The loss of esophageal clearance increases the potential for regurgitation into the pharynx with aspiration.Brunicardi_Ch25_p1009-p1098.indd 103301/03/19 6:03 PM 1034SPECIFIC CONSIDERATIONSPART II70Prevalence%Gastric reflux(n = 22)Mixed reflux(n = 31)6050403020100A20151050% TimepH<4BpH4–7pH>7Figure 25-29. A. Prevalence of reflux types in 53 patients with gastroesophageal reflux disease. B. Esophageal luminal pH dur-ing bilirubin exposure. (Reproduced with permission from Kauer WK, Peters JH, DeMeester TR, etal: Mixed reflux of gastric and duodenal juices is more harmful to the esophagus than gastric juice alone. The need for surgical therapy re-emphasized, Ann Surg. 1995 Oct;222(4):525-531.)350300250200150100500123pH4567891018:00Time06:00Bile acid conc. umol/l0Figure 25-28. Sample bile acid concentration and esophageal pH plotted against time to obtain detailed profiles; in this case showing both significant bile acid (vertical bars) and acid (linear plot) reflux. (Reproduced with permission from Nehra D, Watt P, Pye JK, et al. Automated oesophageal reflux sampler: a new device used to moni-tor bile acid reflux in patients with gastroesophageal reflux disease, J Med Eng Technol. 1997 Jan-Feb;21(1):1-9.)The potential injurious components that reflux into the esophagus include gastric secretions such as acid and pepsin, as well as biliary and pancreatic secretions that regurgitate from the duodenum into the stomach. There is a considerable body of experimental evidence to indicate that maximal epithelial injury occurs during exposure to bile salts combined with acid and pepsin. These studies have shown that while acid alone does minimal damage to the esophageal mucosa, the combination of acid and pepsin is highly deleterious. Similarly, the reflux of duodenal juice alone does little damage to the mucosa, although the combination of duodenal juice and gastric acid is particu-larly noxious.Complications of gastroesophageal reflux such as esopha-gitis, stricture, and Barrett’s metaplasia occur in the presence of two predisposing factors: a mechanically defective LES and an increased esophageal exposure to fluid containing duodenal content that includes bile and pancreatic juice. The duodenal origin of esophageal contents in patients with an increased exposure to a pH >7 has previously been confirmed by esopha-geal aspiration studies (Fig. 25-28). Studies have clarified and expanded these observations by measuring esophageal bilirubin exposure over a 24-hour period as a marker for the presence of duodenal juice. Direct measurement of esophageal bilirubin exposure as a marker for duodenal juice has shown that 58% of patients with GERD have increased esophageal exposure to duodenal juice and that this exposure occurs most commonly when the esophageal pH is between 4 and 7 (Fig. 25-29). These earlier studies have been confirmed by other studies that mea-sure volume reflux using impedance technology (Fig. 25-30).If reflux of gastric juice is allowed to persist and sustained or repetitive esophageal injury occurs, two sequelae can result. First, a luminal stricture can develop from submucosal and even-tually intramural fibrosis. Second, the tubular esophagus may become replaced with columnar epithelium. The columnar epi-thelium is resistant to acid and is associated with the alleviation of the complaint of heartburn. This columnar epithelium often becomes intestinalized, identified histologically by the presence 100Prevalence of patients with increased bilirubin806040200Normalsubjectsn = 25No mucosalinjuryn = 16Erosiveesophagitisn = 10Barrett’sesophagusn = 27Figure 25-30. Prevalence of abnormal esophageal bilirubin expo-sure in healthy subjects and in patients with gastroesophageal reflux disease with varied degrees of mucosal injury. (*P <.03 vs. all other groups; **P <.03 vs. healthy subjects.) (Reproduced with permis-sion from Kauer WK, Peters JH, DeMeester TR, et al: Mixed reflux of gastric and duodenal juices is more harmful to the esophagus than gastric juice alone. The need for surgical therapy re-emphasized, Ann Surg. 1995 Oct;222(4):525-531.)Brunicardi_Ch25_p1009-p1098.indd 103401/03/19 6:03 PM 1035ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25of goblet cells. This specialized IM is currently required for the diagnosis of BE. Endoscopically, BE can be quiescent or associ-ated with complications of esophagitis, stricture, Barrett’s ulcer-ation, and dysplasia. The complications associated with BE may be due to the continuous irritation from refluxed duodenogastric juice. This continued injury is pH dependent and may be modi-fied by medical therapy. The incidence of metaplastic Barrett’s epithelium becoming dysplastic and progressing to adenocarci-noma is approximately 0.2% to 0.5% per year.An esophageal stricture can be associated with severe esophagitis or BE. In the latter situation, it occurs at the site of maximal inflammatory injury (i.e., the columnar-squamous epi-thelial interface). Patients who have a stricture in the absence of Barrett’s esophagus should have the presence of gastroesopha-geal reflux documented before the presence of the stricture is ascribed to reflux esophagitis. In patients with normal acid exposure and no endoscopic or CT evidence of cancer, the stric-ture may be a result of a drug-induced chemical injury, the latter resulting from the lodgment of a capsule or tablet in the distal esophagus. In such patients, dilation usually corrects the prob-lem of dysphagia. It is also possible for drug-induced injuries to occur in patients who have underlying esophagitis and a distal esophageal stricture secondary to gastroesophageal reflux. In this situation, a long, string-like stricture progressively devel-ops as a result of repetitive caustic injury from capsule or tablet lodgment on top of an initial reflux stricture. These strictures are often resistant to dilation. The incidence of this problem has lessened since the introduction of proton pump inhibitor medication.Metaplastic (Barrett’s Esophagus) and Neoplastic (Adenocarcinoma) ComplicationsThe condition whereby the tubular esophagus is lined with columnar epithelium rather than squamous epithelium was first described by Norman Barrett in 1950. He incorrectly believed it to be congenital in origin. It is now realized that it is an acquired abnormality, occurs in 10% to 15% of patients with GERD, and represents the end stage of the natural history of this disease. It is also distinctly different from the congenital condition in which islands of gastric fundic epithelium are found in the upper half of the esophagus.The definition of BE has evolved considerably over the past decade. Traditionally, BE was identified by the presence of columnar mucosa extending at least 3 cm into the esophagus. It is now recognized that the specialized, intestinal-type epi-thelium, or intestinal metaplasia (IM) found in the Barrett’s mucosa, is the only tissue predisposed to malignant degenera-tion. Consequently, the diagnosis of BE is presently made given any length of endoscopically identifiable columnar mucosa that proves, on biopsy, to show IM. Although long segments of columnar mucosa without IM do occur, they are uncommon and might be congenital in origin.The hallmark of IM is the presence of intestinal goblet cells. There is a high prevalence of biopsy-demonstrated IM at the cardia, on the gastric side of the squamocolumnar junction, in the absence of endoscopic evidence of a CLE. Evidence is accumulating that these patches of what appears to be Barrett’s in the cardia have a similar malignant potential as in the longer segments, and are precursors for carcinoma of the cardia.The long-term relief of symptoms remains the primary rea-son for performing antireflux surgery in patients with BE. Heal-ing of esophageal mucosal injury and the prevention of disease progression are important secondary goals. In this regard, patients with BE are no different than the broader population of patients with gastroesophageal reflux. They should be con-sidered for antireflux surgery when patient data suggest severe disease or predict the need for long-term medical management. Most patients with BE are symptomatic. Although it has been argued that some patients with BE may not have symptoms, careful history taking will reveal the presence of symptoms in most, if not all, patients.Patients with BE have a spectrum of disease ranging from visually identifiable but short segments, to long segments of classic BE. In general, however, they represent a relatively severe stage of gastroesophageal reflux, usually with markedly increased esophageal acid exposure, deficient LES characteris-tics, poor esophageal body function, and a high prevalence of duodenogastroesophageal reflux. Gastric hypersecretion occurs in 44% of patients. Most will require long-term PPI therapy for relief of symptoms and control of coexistent esophageal muco-sal injury. Given such profound deficits in esophageal physi-ology, antireflux surgery is an excellent means of long-term control of reflux symptoms for most patients with BE.The typical complications in BE include ulceration in the columnar-lined segment, stricture formation, and a dysplasia-cancer sequence. Barrett’s ulceration is unlike the erosive ulceration of reflux esophagitis in that it more closely resem-bles peptic ulceration in the stomach or duodenum, and has the same propensity to bleed, penetrate, or perforate. Fortunately, this complication occurs very rarely. The strictures found in BE occur at the squamocolumnar junction, and they are typically higher than peptic strictures in the absence of BE. Ulceration and stricture in association with BE were commonly reported before 1975, but with the advent of potent acid suppression medication, they have become less common. In contrast, the complication of adenocarcinoma developing in Barrett’s mucosa has become more common. Adenocarcinoma developing in Bar-rett’s mucosa was considered a rare tumor before 1975. Today, it occurs at approximately 0.2% to 0.5% per year of follow-up, which represents a risk 40 times that of the general popula-tion. Most, if not all, cases of adenocarcinoma of the esophagus arise in Barrett’s epithelium (Fig. 25-31). About one-third of all patients with BE present with malignancy.The long-term risk of progression to dysplasia and ade-nocarcinoma, although not the driving force behind the deci-sion to perform antireflux surgery, is a significant concern for both patient and physician. Although to date, there have been no prospective randomized studies documenting that antireflux surgery has an effect on the risk of progression to dysplasia and carcinoma, complete control of reflux of gastric juice into the esophagus is clearly a desirable goal.Respiratory ComplicationsA significant proportion of patients with GERD will have associated respiratory symptoms. These patients may have laryngopharyngeal reflux-type symptoms, adult-onset asthma, or even idiopathic pulmonary fibrosis. These symptoms and organ injury may occur in isolation or in conjunction with typi-cal reflux symptoms such as heartburn and regurgitation. Sev-eral studies have demonstrated that up to 50% of patients with asthma have either endoscopically evident esophagitis or abnor-mal distal esophageal acid exposure. These findings support a causal relationship between GERD and aerodigestive symptoms and complications in a proportion of patients.3Brunicardi_Ch25_p1009-p1098.indd 103501/03/19 6:03 PM 1036SPECIFIC CONSIDERATIONSPART IIABFigure 25-31. Photomicrographs. A. Barrett’s epithelium with severe dysplasia. (×200.) Note nuclear irregularity, stratification, and loss of polarity. B. Barrett’s epithelium with intramucosal carcinoma. (×66.) Note malignant cells in the mucosa (upper arrow), but not invading the muscularis mucosae (bottom arrow). (Reproduced with permission from Zuidema GD, Orringer MB: Shackelford’s Surgery of the Alimentary Tract, 3rd ed. Vol 1. Philadelphia, PA: Elsevier/Saunders; 1991.)Etiology of Reflux-Induced Respiratory Symptoms. There are two mechanisms that have been proposed as the cause of reflux-induced respiratory symptoms. The reflux theory sug-gests that these symptoms are the direct result of laryngopha-ryngeal exposure and aspiration of gastric contents. The reflex theory suggests that the vagal-mediated afferent fibers result in bronchoconstriction during episodes of distal esophageal acidification. The evidence supporting a mechanism of direct exposure to the aerodigestive system is based in clinical studies that have documented a strong correlation between idiopathic pulmonary fibrosis and hiatal hernia. In addition, the presence of GERD was demonstrated to be highly associated with several pulmonary diseases in a recent Department of Veteran Affairs multivariate analysis. Next, with ambulatory pH testing, acid exposure within the proximal esophagus is more frequently identified in patients with gastroesophageal reflux and respi-ratory symptoms than in patients who have gastroesophageal reflux symptoms alone. These findings are supported by scinti-graphic studies, which have demonstrated aspiration of ingested radioisotope in patients with both gastroesophageal reflux and pulmonary symptoms. In animal studies, tracheal instillation of acid has been demonstrated to profoundly increase airway resis-tance. Finally, in patients who have undergone multichannel intraluminal impedance testing with a catheter configured to detect laryngopharyngeal reflux, a correlation between proxi-mal fluid movement and laryngopharyngeal symptoms, such as cough, can be demonstrated.The reflex mechanism is supported by the bronchocon-striction that occurs with the infusion of acid into the distal esophagus. There is a shared embryologic origin of the tracheo-esophageal tract and vagus nerve, and this reflex is thought to be an afferent fiber–mediated reflex that protects the aerodigestive system from the aspiration of refluxate. In patients with respira-tory symptoms and documented gastroesophageal reflux with-out proximal esophageal acid exposure, pulmonary symptoms will often times significantly improve or completely resolve after undergoing laparoscopic fundoplication. It is likely that both of the proposed mechanisms work simultaneously to cause these symptoms in the face of GERD.The most difficult clinical challenge in formulating a treat-ment plan for reflux-associated respiratory symptoms resides in establishing the diagnosis. Although the diagnosis may be straightforward in patients with predominately typical reflux symptoms and secondary respiratory complaints, a substan-tial number of patients will have respiratory symptoms that dominate the clinical scenario. Typical gastroesophageal reflux Brunicardi_Ch25_p1009-p1098.indd 103601/03/19 6:03 PM 1037ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25symptoms, such as heartburn and regurgitation, may often be completely absent only to be uncovered with objective esopha-geal physiology testing. Traditionally, the diagnosis of reflux-induced respiratory injury is established using ambulatory dual probe pH monitoring, with one probe positioned within the dis-tal esophagus and the other at a proximal location. Proximal probe positioning has included multiple locations such as the trachea, pharynx, and proximal esophagus. Although ambu-latory esophageal pH monitoring allows a direct correlation between esophageal acidification and respiratory symptoms, sensitivity of this testing modality is poor, and the temporal rela-tionship between laryngeal or pulmonary symptoms and reflux events is complex. In addition, as the refluxed gastric fluid trav-els proximally, it may be neutralized by saliva and therefore go undetected with pH monitoring. Impedance testing may also be used to detect the movement of fluid throughout the entire esophageal column regardless of pH content.Treatment. Once the diagnosis is established, treatment may be initiated with either PPI therapy or antireflux surgery. A trial of high-dose PPI therapy may help establish that reflux is partly or completely responsible for the respiratory symptoms. It is important to note that the persistence of symptoms in the face of aggressive PPI treatment does not necessarily rule out reflux as a possible cofactor or sole etiology.Although there is probably some element of a placebo effect, relief of respiratory symptoms can be anticipated in up to 50% of patients with reflux-induced asthma treated with anti-secretory medications. However, when examined objectively, <15% of patients can be expected to have improvement in their pulmonary function with medical therapy. In properly selected patients, antireflux surgery improves respiratory symptoms in nearly 90% of children and 70% of adults with asthma and reflux disease. Improvements in pulmonary function can be demonstrated in around 30% of patients. Uncontrolled studies of the two forms of therapy (PPI and surgery) and the evidence from the two randomized controlled trials of medical vs. sur-gical therapy indicate that surgical valve reconstruction is the most effective therapy for reflux-induced asthma. The superi-ority of the surgery over PPI is most noticeable in the supine position, which corresponds with the nadir of PPI blood levels and resultant acid breakthrough and is the time in the circadian cycle when asthma symptoms are at their worst.In asthmatic patients with an esophageal motility disorder, performing an antireflux operation will not prevent the regur-gitation and possible aspiration of swallowed liquid or food “upstream” to the valve reconstruction. It is critical that esopha-geal body function be considered prior to surgical intervention in this patient population.Medical Therapy for Gastroesophageal Reflux Disease.  With the widespread availability of over-the-counter antisecre-tory medications, most patients with mild or moderate symp-toms will carry self-medication. When initially identified with mild symptoms of uncomplicated GERD, patients can be placed on 12 weeks of simple antacids before diagnostic testing is initi-ated. This approach may successfully and completely resolve the symptoms. Patients should be counseled to elevate the head of the bed; avoid tight-fitting clothing; eat small, frequent meals; avoid eating the nighttime meal immediately prior to bedtime; and avoid alcohol, coffee, chocolate, and peppermint, which are known to reduce resting LES pressure and may aggravate symptoms.Used in combination with simple antacids, alginic acid may augment the relief of symptoms by creating a physical bar-rier to reflux, as well as by acid reduction. Alginic acid reacts with sodium bicarbonate in the presence of saliva to form a highly viscous solution that floats like a raft on the surface of the gastric contents. When reflux occurs, this protective layer is refluxed into the esophagus, and acts as a protective barrier against the noxious gastric contents. Medications to promote gastric emptying, such as metoclopramide or domperidone, are beneficial in early disease but of little value in more severe disease.In patients with persistent symptoms, the mainstay of medical therapy is acid suppression. High-dosage regimens of hydrogen potassium PPIs, such as omeprazole (up to 40 mg/d), can reduce gastric acidity by as much as 80% to 90%. This usu-ally heals mild esophagitis. In severe esophagitis, healing may occur in only one-half of the patients. In patients who reflux a combination of gastric and duodenal juice, acid-suppression therapy may give relief of symptoms, while still allowing mixed reflux to occur. This can allow persistent mucosal damage in an asymptomatic patient. Unfortunately, within 6 months of discontinuation of any form of medical therapy for GERD, 80% of patients have a recurrence of symptoms, and 40% of individuals with daily GERD eventually develop symptoms that “breakthrough” adequately dosed PPIs. Once initiated, most patients with GERD will require lifelong treatment with PPIs, both to relieve symptoms and to control any coexistent esophagitis or stricture. Although control of symptoms has his-torically served as the endpoint of therapy, the wisdom of this approach has recently been questioned, particularly in patients with BE. Evidence suggesting that reflux control may prevent the development of adenocarcinoma and lead to regression of dysplastic and nondysplastic Barrett’s segments has led many to consider control of reflux, and not symptom control, a better therapeutic endpoint. However, this hypothesis remains contro-versial. It should be noted that complete control of reflux using PPIs can be difficult, as has been highlighted by studies of acid breakthrough while on PPI therapy and of persistent reflux fol-lowing antireflux surgery. Castell, Triadafilopoulos, and others have shown that 40% to 80% of patients with BE continue to have abnormal esophageal acid exposure despite up to 20 mg twice daily of PPIs. Ablation trials have shown that mean doses of 56 mg of omeprazole were necessary to normalize 24-hour esophageal pH studies. It is likely that antireflux surgery results in more reproducible and reliable elimination of reflux of both acid and duodenal contents, although long-term outcome studies suggest that as many as 25% of postfundoplication patients will have persistent pathologic esophageal acid exposure confirmed by positive 24-hour pH studies.Suggested Therapeutic Approach. Traditionally a stepwise approach is used for the treatment of GERD. First-line therapy entails antisecretory medication, usually PPIs, in most patients. Failure of medication to adequately control GERD symptoms suggests either that the patient may have relatively severe dis-ease or a non-GERD cause for his or her symptoms. Endoscopic examination at this stage of the patient’s evaluation is recom-mended and will provide the opportunity to assess the degree of mucosal injury and presence of BE. Treatment options for these patients entails either long term PPI use vs. antireflux surgery. Laparoscopic antireflux surgery in these patients achieves long-term control of symptoms in 85% to 90%. The measurement Brunicardi_Ch25_p1009-p1098.indd 103701/03/19 6:03 PM 1038SPECIFIC CONSIDERATIONSPART IIof esophageal acid exposure via 24-hour pH should be under-taken when patients are considered for surgery. The status of the LES and esophageal body function with esophageal manom-etry should also be performed at this stage. These studies will serve to establish the diagnosis and assess esophageal body dysfunction.Surgical Therapy for Gastroesophageal Reflux DiseaseSelection of Patients for Surgery. Studies of the natural history of GERD indicate that most patients have a relatively benign form of the disease that is responsive to lifestyle changes and dietary and medical therapy and do not need surgical treat-ment. Approximately 25% to 50% of the patients with GERD have persistent or progressive disease, and it is this patient pop-ulation that is best suited to surgical therapy. In the past, the presence of esophagitis and a structurally defective LES were the primary indications for surgical treatment, and many inter-nists and surgeons were reluctant to recommend operative pro-cedures in their absence. However, one should not be deterred from considering antireflux surgery in a symptomatic patient with or without esophagitis or a defective sphincter, provided the disease process has been objectively documented by 24-hour pH monitoring. This is particularly true in patients who have become dependent upon therapy with PPIs, or require increasing doses to control their symptoms. It is important to note that a good response to medical therapy in this group of patients pre-dicts an excellent outcome following antireflux surgery.In general, the key indications for antireflux surgery are (a) objectively proven gastroesophageal reflux disease, and (b) typical symptoms of gastroesophageal reflux disease (heartburn and/or regurgitation) despite adequate medical management, or (c) a younger patient unwilling to take lifelong medication. In addition, a structurally defective LES can also predict which patients are more likely to fail with medical therapy. Patients with normal sphincter pressures tend to remain well controlled with medical therapy, whereas patients with a structurally defec-tive LES may not respond as well to medical therapy, and often develop recurrent symptoms within 1 to 2 years of beginning therapy. Such patients should be considered for an antireflux operation, regardless of the presence or absence of endoscopic esophagitis.Young patients with documented reflux disease with or without a defective LES are also excellent candidates for anti-reflux surgery. They usually will require long-term medical therapy for control of their symptoms, and some will go on to develop complications of the disease. An analysis of the cost of therapy based on data from the Veterans Administration Coop-erative trial indicates that surgery has a cost advantage over medical therapy in patients <49 years of age.Severe endoscopic esophagitis in a symptomatic patient with a structurally defective LES is also an indication for early surgical therapy. These patients are prone to breakthrough of their symptoms while receiving medical therapy. Symptoms and mucosal injury can be controlled in such patients, but careful monitoring is required, and increasing dosages of PPIs are nec-essary. In everyday clinical practice, however, such treatment can be both difficult and impractical, and, in such cases, antire-flux surgery can be considered early, especially if PPI therapy is problematic.The development of a stricture in a patient represents a fail-ure of medical therapy, and it is also an indication for a surgical antireflux procedure. In addition, strictures are often associated with a structurally defective sphincter and loss of esophageal contractility. Before proceeding with surgical treatment, malig-nancy and a drug-related etiology of the stricture should be excluded, and the stricture should be progressively dilated up to a 50 to 60F bougie. When the stricture is fully dilated, the relief of dysphagia is evaluated, and esophageal manometry is performed to determine the adequacy of peristalsis in the distal esophagus. If dysphagia is relieved and the amplitude of esopha-geal contractions is adequate, an antireflux procedure should be performed; if there is a global loss of esophageal contractility, caution should be exercised in performing an antireflux proce-dure with a complete fundoplication, and a partial fundoplica-tion should be considered.Barrett’s CLE is commonly associated with a severe structural defect of the LES and often poor contractility of the esophageal body. Patients with BE are at risk of the development of an adenocarcinoma. Whilst surgeons would like to think that an antireflux procedure can reduce the risk of progression to cancer, the evidence supporting this is relatively weak, and for now Barrett’s esophagus should be considered to be evidence that the patient has gastroesophageal reflux, and progression to antireflux surgery is indicated for the treatment of reflux symptoms, not cancer progression. If, however, high grade dysplasia or intramucosal carcinoma is found on mucosal biopsy specimens, treatment should then be directed at the BE and the lesion, using either evaluation endoscopic ablation, endoscopic resection, or esophageal resection.The majority of patients requiring treatment for reflux have a relatively mild form of disease and will respond to antise-cretory medications. Patients with more severe forms of disease, particularly those who develop persistent or progressive disease, should be considered for definitive therapy. Laparoscopic fun-doplication will provide a long-term cure in the majority of these patients, with minimal discomfort and an early return to normal activity.Preoperative Evaluation. Before proceeding with an antire-flux operation, several factors should be evaluated. The clinical symptoms should be consistent with the diagnosis of gastro-esophageal reflux. Patients presenting with the typical symp-toms of heartburn and/or regurgitation which have responded, at least partly, to PPI therapy, will generally do well following surgery, whereas patients with atypical symptoms have a less predictable response. Reflux should also be objectively con-firmed by either the presence of ulcerative esophagitis or an abnormal 24-hour pH study.The propulsive force of the body of the esophagus should be evaluated by esophageal manometry to determine if it has sufficient power to propel a bolus of food through a newly reconstructed valve. Patients with normal peristaltic contrac-tions can be considered for a 360° Nissen fundoplication or a partial fundoplication, depending on patient and surgeon pref-erences. When peristalsis is absent, a partial fundoplication is probably the procedure of choice, but only if achalasia has been ruled out.Hiatal anatomy should also be assessed. In patients with smaller hiatal hernias, endoscopy evaluation usually provides sufficient information. However, when patients present with a very large hiatus hernia or for revision surgery after previous antireflux surgery, contrast radiology provides better anatomical information. The concept of anatomic shortening of the esoph-agus is controversial, with divergent opinions held about how Brunicardi_Ch25_p1009-p1098.indd 103801/03/19 6:03 PM 1039ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25DistentionFigure 25-32. A graphic illustration of the shortening of the lower esophageal sphincter that occurs as the sphincter is “taken up” by the cardia as the stomach distends.common this problem is. Believers claim that anatomic short-ening of the esophagus compromises the ability of the surgeon to perform an adequate repair without tension and that this can lead to an increased incidence of breakdown or thoracic displace-ment of the repair. Some of those who hold this view claim that esophageal shortening is present when a barium swallow X-ray identifies a sliding hiatal hernia that will not reduce in the upright position or that measures more than 5 cm in length at endoscopy. When such identification is made, these surgeons usually add a gastroplasty to the antireflux procedure. Others claim that esoph-ageal shortening is overdiagnosed and rarely seen, and that the morbidity of adding a gastroplasty outweighs any benefits. These surgeons would recommend a standard antireflux procedure in all patients undergoing primary surgery.Principles of Surgical Therapy. The primary goal of anti-reflux surgery is to safely create a new antireflux valve at the gastroesophageal junction, while preserving the patient’s abil-ity to swallow normally and to belch to relieve gaseous disten-tion. Regardless of the choice of the procedure, this goal can be achieved if attention is paid to some basic principles when reconstructing the antireflux mechanism. First, the operation should create a flap valve which prevents regurgitation of gas-tric contents into the esophagus. This will result in an increase in the pressure of the distal esophageal sphincter region. Follow-ing a Nissen fundoplication the expected increase is to a level twice the resting gastric pressure (i.e., 12 mmHg for a gastric pressure of 6 mmHg). The extent of the pressure rise is often less following a partial fundoplication, although with all types of fundoplication the length of the reconstructed valve should be at least 3 cm. This not only augments sphincter characteristics in patients in whom they are reduced before surgery but also prevents unfolding of a normal sphincter in response to gastric distention (Fig. 25-32). Preoperative and postoperative esopha-geal manometry measurements have shown that the resting sphincter pressure and the overall sphincter length can be surgi-cally augmented over preoperative values, and that the change in the former is a function of the degree of gastric wrap around the esophagus (Fig. 25-33). However, the aim of any fundopli-cation is to create a loose wrap and to maintain the position of the gastric fundus close to the distal intra-abdominal esophagus, in a flap valve arrangement. The efficacy of this relies on the close relationship between the fundus and the esophagus, not the “tightness” of the wrap.Second, the operation should place an adequate length of the distal esophageal sphincter in the positive-pressure 051015˜ P mmHg 20240Degree of wrapY = 4.63 + .023 (x)P < .01BelseyHillN=15NissenN=15N=15360Figure 25-33. The relationship between the augmentation of sphincter pressure over preoperative pressure (ΔP) and the degree of gastric fundic wrap in three different antireflux procedures. (Repro-duced with permission from O’Sullivan GC, DeMeester TR, Joels-son BE, et al: Interaction of lower esophageal sphincter pressure and length of sphincter in the abdomen as determinants of gastro-esophageal competence, Am J Surg. 1982 Jan;143(1):40-47.)environment of the abdomen by a method that ensures its response to changes in intra-abdominal pressure. The permanent restoration of 2 or more cm of abdominal esophagus ensures the preservation of the relationship between the fundus and the esophagus. All of the popular antireflux procedures increase the length of the sphincter exposed to abdominal pressure by an average of at least 1 cm.Third, the operation should allow the reconstructed car-dia to relax on deglutition. In normal swallowing, a vagally mediated relaxation of the distal esophageal sphincter and the gastric fundus occurs. The relaxation lasts for approximately 10 seconds and is followed by a rapid recovery to the former tonicity. To ensure relaxation of the sphincter, three factors are important: (a) Only the fundus of the stomach should be used to buttress the sphincter, because it is known to relax in con-cert with the sphincter; (b) the gastric wrap should be properly placed around the sphincter and not incorporate a portion of the stomach or be placed around the stomach itself, because the body of the stomach does not relax with swallowing; and (c) damage to the vagal nerves during dissection of the thoracic esophagus should be avoided because it may result in failure of the sphincter to relax.Fourth, the fundoplication should not increase the resis-tance of the relaxed sphincter to a level that exceeds the peri-staltic power of the body of the esophagus. The resistance of the relaxed sphincter depends on the degree, length, and diameter of the gastric fundic wrap, and on the variation in intra-abdominal pressure. A 360° gastric wrap should be no longer than 2 cm and constructed over a large (50 to 60F) bougie. This will ensure that the relaxed sphincter will have an adequate diameter with minimal resistance. A bougie is not necessary when construct-ing a partial wrap.Fifth, the operation should ensure that the fundoplication can be placed in the abdomen without undue tension and main-tained there by approximating the crura of the diaphragm above the repair. Leaving the fundoplication in the thorax converts a sliding hernia into a PEH, with all the complications associ-ated with that condition. Maintaining the repair in the abdomen Brunicardi_Ch25_p1009-p1098.indd 103901/03/19 6:03 PM 1040SPECIFIC CONSIDERATIONSPART IIunder tension predisposes to an increased incidence of recur-rence. How common this problem is encountered is disputed, with some surgeons advocating lengthening the esophagus by gastroplasty and constructing a partial fundoplication, and oth-ers claiming that this issue is now rarely encountered.Procedure Selection. A laparoscopic approach is now used routinely in all patients undergoing primary antireflux surgery. Some surgeons advocate the use of a single antireflux procedure for all patients, whereas others advocate a tailored approach. Advocates of the laparoscopic Nissen fundoplication as the pro-cedure of choice for a primary antireflux repair would generally apply this procedure in all patients with normal or near normal esophageal motility, and they would reserve a partial fundopli-cation for use in individuals with poor esophageal body motility. Others, based on the good longer-term outcomes now reported following partial fundoplication procedures, advocate the rou-tine application of a partial fundoplication procedure, thereby avoiding any concerns about constructing a fundoplication in individuals with poor esophageal motility.Experience and randomized studies have shown that both the Nissen fundoplication and various partial fundoplication procedures are all effective and durable antireflux repairs that generate an excellent outcome in approximately 90% of patients at longer-term follow-up.Primary Antireflux RepairsNissen Fundoplication. The most common antireflux proce-dure is the Nissen fundoplication. In the past, this procedure has been performed through an open abdominal or a chest incision, but with the development of laparoscopic approaches primary antireflux surgery is now routinely undertaken using the laparo-scope. Rudolph Nissen described this procedure as a 360° fun-doplication around the lower esophagus for a distance of 4 to 5 cm, without division of the short gastric blood vessels. Although this provided good control of reflux, it was associated with a number of side effects that have encouraged modifica-tions of the procedure as originally described. These include using only the gastric fundus to envelop the esophagus in a fash-ion analogous to a Witzel jejunostomy, sizing the fundoplication with a large (50 to 60F) bougie, limiting the length of the fun-doplication to 1 to 2 cm, and dividing the short gastric vessels. The essential elements necessary for the performance of a trans-abdominal fundoplication are common to both the laparoscopic and open procedures and include the following:1. Hiatal dissection and preservation of both vagi along their entire length2. Circumferential esophageal mobilization3. Hiatal closure, usually posterior to the esophagus4. Creation of a short and floppy fundoplication over an esoph-ageal dilatorIn addition, many surgeons also routinely divide the short gastric blood vessels, although this step is not universally applied, and the results of several randomized trials have failed to show that this step yields any benefit.The laparoscopic approach to fundoplication has now replaced the open abdominal Nissen fundoplication as the pro-cedure of choice. Five ports are usually used (Fig. 25-34), and dissection is begun by incising the gastrohepatic omentum above and below the hepatic branch of the anterior vagus nerve, which is usually preserved. The circumference of the diaphragmatic L R Figure 25-34. Patient positioning and trocar placement for lap-aroscopic antireflux surgery. The patient is placed with the head elevated approximately 30° in the modified lithotomy position. The surgeon stands between the patient’s legs, and the procedure is completed using five abdominal access ports.hiatus is dissected and the esophagus is mobilized by careful dis-section of the anterior and posterior soft tissues within the hiatus. The esophagus is held anterior and to the left and the hiatal pillars are approximated with interrupted nonabsorbable sutures, starting posteriorly and working anteriorly. A tension-free fundoplication should be constructed. This can usually be achieved either with or without division of the short gastric blood vessels, accord-ing to surgeon preference. If the vessels are divided, the upper one-third of the greater curvature is mobilized by sequentially dissecting and dividing these vessels, commencing distally and working proximally. Following complete fundal mobilization, the posterior wall of the fundus is brought behind the esophagus to the right side, and the anterior wall of the fundus is brought anterior to the esophagus. The fundic lips are manipulated to allow the fundus to envelop the esophagus without twisting. A 50 to 60F bougie is passed to properly size the fundoplication, and it is sutured using nonabsorbable sutures. Some surgeons use a single U-stitch of 2-0 polypropylene buttressed with felt pledgets (Fig. 25-35), and others use 2-4 interrupted sutures.Brunicardi_Ch25_p1009-p1098.indd 104001/03/19 6:03 PM 1041ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Posterior Partial Fundoplication. Partial fundoplications were developed as an alternative to the Nissen procedure in an attempt to minimize the risk of postfundoplication side effects, such as dysphagia, inability to belch, and flatulence. The commonest approach has been a posterior partial or Toupet fundoplication. Some surgeons use this type of procedure for all patients present-ing for antireflux surgery, whereas others apply a tailored approach in which a partial fundoplication is constructed in patients with impaired esophageal motility, in which the propulsive force of the esophagus is thought to be insufficient to overcome the outflow obstruction of a complete fundoplication. The Toupet posterior partial fundoplication consists of a 270° gastric fundoplication around the distal 4 cm of esophagus (Fig. 25-36). It is usually stabilized by anchoring the wrap posteriorly to the hiatal rim.Anterior Partial Fundoplication. An alternative approach to partial fundoplication is to construct an anterior partial fundopli-cation. Following posterior hiatal repair, the anterior fundus is rolled over the front of the esophagus and sutured to the hiatal rim and the esophageal wall. Division of the short gastric vessels Figure 25-35. A. Laparoscopic Nissen fundoplication is performed with a five-trocar technique. B. The liver retractor is affixed to a mechani-cal arm to hold it in place throughout the operation. C. After division of the gastrohepatic omentum above the hepatic branch of the vagus (pars flaccida), the surgeon places a blunt atraumatic grasper beneath the phrenoesophageal ligament. D. After completion of the crural closure, an atraumatic grasper is placed right to left behind the gastroesophageal junction. The grasper is withdrawn, pulling the posterior aspect of the gastric fundus behind the esophagus. E. Once the suture positions are chosen, the first stitch (2-0 silk, 20 cm long) is introduced through the 10-mm trocar, and the needle is passed first through the left limb of the fundus, then the esophagus (2.5 cm above the gastroesophageal junction), then through the right limb of the fundus. F. Final position of the fundoplication.Brunicardi_Ch25_p1009-p1098.indd 104101/03/19 6:03 PM 1042SPECIFIC CONSIDERATIONSPART IIFigure 25-36. Completed laparoscopic posterior partial (Toupet) fundoplication. The fundoplication does not cover the anterior sur-face of the esophagus, and it is stabilized by suturing the fundus to the side of the esophagus, and posteriorly to the right hiatal pillar.is never needed when constructing this type of fundoplication. Various degrees of anterior partial fundoplication have been described—90°, 120°, 180°. The anterior 180° partial fundopli-cation (Fig. 25-37) provides a more robust fundoplication and achieves an excellent longer-term outcome in approximately 90% of patients at follow-up of at least 10 years. With this procedure, the fundus and esophagus are sutured to the right side of the hiatal rim to create a flap valve at the gastroesophageal junction and to stabilize a 3 to 4 cm length of intra-abdominal esophagus.Collis Gastroplasty. When a shortened esophagus is encoun-tered, many surgeons choose to add an esophageal lengthening procedure before fundoplication, to reduce the tension on the gastroesophageal junction, believing this will minimize the risk of failure due to postoperative hiatus hernia. The commonest approach to this is the Collis gastroplasty. This entails using a stapler to divide the cardia and upper stomach, parallel to the lesser curvature of Figure 25-37. Completed laparoscopic anterior 180° partial fun-doplication. The fundoplication fully covers the anterior surface of the esophagus, and it is stabilized by suturing the fundus to the right side of the esophagus, and to the right hiatal pillar. Unlike the Nissen procedure, the fundus is not pulled behind the esophagus.the stomach, thereby creating a gastric tube in continuity with the esophagus, and effectively lengthening the esophagus by several centimeters. Laparoscopic techniques for Collis gastroplasty have been described (Fig. 25-38). Following gastroplasty a fundoplica-tion is constructed, with the highest suture is placed on the native esophagus when constructing a Nissen fundoplication. Not all sur-geons choose to undertake a Collis procedure, however, as there is controversy about the actual incidence of the shortened esophagus and widely divergent views are held about how often this prob-lem is encountered. In addition, some surgeons have questioned the wisdom of creating an amotile tube of gastric wall, which can secrete acid, and then placing a Nissen fundoplication below this.Outcome After Fundoplication. Studies of long-term outcome following both open and laparoscopic fundoplication document the ability of laparoscopic fundoplication to relieve typical reflux symptoms (heartburn, regurgitation, and dysphagia) in more than Figure 25-35. (Continued )Brunicardi_Ch25_p1009-p1098.indd 104201/03/19 6:03 PM 1043ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Figure 25-38. A. After removal of the fat pad and release of tension on the Penrose drain, the gastroesophageal junction (GES) retracts to the level of the hiatus. The interior end of the staple line is marked 2/5 cm below the angle of His. B. The first horizontal firing of the stapler occurs by maximally articulating the stapler to the left, aiming toward the previously marked spot adjacent to the dilator. C. The vertical staple line is created by a single firing of the GIA placed parallel and flush against the 48F dilator. D. The highest Nissen fundoplication suture is placed on the native esophagus, and the second suture tucks in the apex of the staple line.90% of patients at follow-up intervals averaging 2 to 3 years and 80% to 90% of patients 5 years or more following surgery. This includes evidence-based reviews of antireflux surgery, pro-spective randomized trials comparing antireflux surgery to PPI therapy and open to laparoscopic fundoplication and analysis of U.S. national trends in use and outcomes. Postoperative pH stud-ies indicate that more than 90% of patients will normalize their pH tracings. The results of laparoscopic fundoplication compare favorably with those of the “modern” era of open fundoplica-tion. They also indicate the less predictable outcome of atypical reflux symptoms (cough, asthma, laryngitis) after surgery, being relieved in only two-thirds of patients.The goal of surgical treatment for GERD is to relieve the symptoms of reflux by reestablishing the gastroesophageal barrier. The challenge is to accomplish this without inducing dysphagia or other untoward side effects. Dysphagia, existing before surgery, usually improves following laparoscopic fun-doplication. Temporary dysphagia is common after surgery and generally resolves within 3 months, but it can take up to 12 months in some individuals, and dysphagia sufficient to require ongoing dietary modification persists in up to 5% of individuals following Nissen fundoplication. Other side effects common to antireflux surgery include the inability to belch and vomit and increased flatulence. Most patients cannot vomit through an intact wrap, though this is rarely clinically relevant. Most patients are unable to belch gas from the stomach in the first 3 to 6 months after fundoplication, but 80% to 90% regain the ability to belch normally beyond the first 12 months of fol-low-up. Hyperflatulence is a common and noticeable problem, likely related to increased air swallowing that is present in most patients with reflux disease, aggravated by the inability to belch in some patients.Brunicardi_Ch25_p1009-p1098.indd 104301/03/19 6:03 PM 1044SPECIFIC CONSIDERATIONSPART IIRandomized Controlled Trials Addressing Surgical Technique Division of the Short Gastric Blood Vessels Originally, Nissen’s description of a total fundoplication entailed a 360° fundoplication during which the short gastric blood vessels were left intact. However, with reports of troublesome postoperative dysphagia, division of these vessels—to achieve full fundal mobilization and thereby ensure a loose fundoplication—was promoted and has entered common practice. The evidence sup-porting dividing these vessels has been based on the outcomes from uncontrolled case series of patients undergoing Nissen fundoplication either with vs. without division of the short gas-tric vessels. However, the results from these studies have been conflicting, with different proponents reporting good results irrespective of whether these vessels have been divided or not. To address this issue, six randomized trials that enrolled a total of 438 patients have been reported. None of these trials demon-strated any differences for the postoperative dysphagia or recur-rent gastro-esophageal reflux. However, in the three largest of the six trials an increased incidence of flatulence and bloating symptoms, as well as greater difficulty with belching, was seen in patients in whom the short gastric vessels were divided.A recent meta-analysis from Engstrom et al, generated by combining the raw data from Australian and Swedish trials, eval-uated a larger cohort of 201 patients, with 12 years of follow-up in 170, and also confirmed equivalent reflux control but found more abdominal bloating after division of the short gastric ves-sels. Overall, these trials fail to support the belief that dividing the short gastric vessels improves any outcome following Nissen fun-doplication. The trials actually suggest that dividing the vessels increases the complexity of the procedure and leads to a poorer outcome due to the increase in bloating symptoms.Nissen vs. Posterior Partial Fundoplication Eleven randomized trials have compared Nissen vs. posterior partial fundoplication. Some of the trials contributed little to the pool of evidence, as they are either small or underpowered, and failed to show significant outcome differences. The larger trials, however, have consistently demonstrated equivalent reflux control, but they also show a reduced incidence of wind-related side-effects (flatulence, bloating, and inability to belch) following posterior partial fundoplication procedures, although less dysphagia fol-lowing a posterior fundoplication was only demonstrated in 2 of the 11 trials. Lundell et al reported the outcomes of Nissen vs. Toupet partial fundoplication in a trial that enrolled 137 patients with reported follow-up to 18 years. Reflux control and dyspha-gia symptoms were similar, but flatulence was commoner after Nissen fundoplication at some medium-term follow-up time points, and revision surgery was more common following Nissen fundoplication, mainly to correct postoperative paraoesophageal herniation. At 18 years follow-up, success rates of more than 80% were reported for both procedures, as well as no significant differences in the incidence of side effects. The data from this trial suggested that the mechanical side effects following Nis-sen fundoplication progressively improve with very long-term follow-up. Strate et al reported 2-year follow-up in a trial that enrolled 200 patients. Approximately 85% of each group was satisfied with the clinical outcome, but dysphagia was signifi-cantly more common following Nissen fundoplication (19 vs. 8 patients).Other trials (Guérin et al–140 patients, Booth et al–127, Khan et al–121, Shaw et al–100) also report similar reflux control within the first few years of follow-up. Only Booth et al demonstrated less dysphagia following posterior fundoplica-tion. Subgroup analysis in 3 trials (Booth, Shaw, Zornig) did not reveal differences between patients with vs. without poor pre-operative oesophageal motility. Overall these trials suggest that some side-effects, mainly wind-related issues, are less common following posterior partial fundoplication. However, the hypoth-esis that dysphagia is less of a problem following posterior par-tial fundoplication has only been substantiated in 2 of 11 trials.Nissen vs. Anterior Fundoplication Six trials have evaluated Nissen vs. anterior partial fundoplication variants. Four have assessed Nissen vs. anterior 180° partial fundoplication (Watson et al–107 patients, Baigrie et al–161, Cao et al–100, Raue et al–64). These trials all demonstrated equivalent reflux control, but less dysphagia and less wind-related side effects after anterior 180° partial fundoplication at up to 5 years follow-up. Only the study from Watson et al has reported follow-up to 10 years, and at late follow-up in their trial there were no significant outcome differences for the two procedures, with equivalent control of reflux, and no differences for side effects due to a progressive decline in dysphagia as follow-up extended beyond 5 years.Two trials compared laparoscopic anterior 90° partial fundoplication vs. Nissen fundoplication (Watson et al–112 patients, Spence et al–79). In both of these trials, side-effects were less common following anterior 90° fundoplication, but this was offset by a slightly higher incidence of recurrent reflux at up to 5 years follow-up. Satisfaction with the overall outcome was similar for both fundoplication variants.Anterior vs. Posterior Partial Fundoplication Two ran-domized trials have directly compared anterior vs. posterior partial fundoplication. Hagedorn et al randomized 95 patients to undergo either Toupet vs. anterior 120° partial fundoplica-tion, and Khan et al enrolled 103 patients to anterior 180° vs. posterior partial fundoplication. Both studies demonstrated bet-ter reflux control, offset by more side effects following posterior partial fundoplication. The anterior 120° partial fundoplication performed by Hagedorn et al was similar to the anterior 90° vari-ant described above. However, the outcomes following this pro-cedure were much worse in this trial than the outcomes in other studies, with the average exposure time to acid (pH <4%–5.6%) following anterior fundoplication in their study unusually high compared to other studies. Khan et al only reported 6 months follow-up, and longer-term outcomes are awaited before draw-ing firm conclusions. The overall results from all eight trials that included an anterior fundoplication variant suggest that this type of fundoplication achieves satisfactory reflux control, with less dysphagia and other side-effects, yielding a good overall outcome. However, the reduced incidence of troublesome side-effects is traded off against a higher risk of recurrent reflux.Outcome of Antireflux Surgery in Patients With Barrett’s Esophagus. Few studies have focused on the alleviation of symp-toms after antireflux surgery in patients with BE (Table 25-7). Those that are available document excellent to good results in 72% to 95% of patients at 5 years following surgery. Several nonrandomized studies have compared medical and surgical therapy and report better outcomes after antireflux surgery. Par-rilla and colleagues reported the only randomized trial to evaluate this issue. They enrolled 101 patients over 18 years, and median follow-up was 6 years. Medical therapy consisted of 20 mg of omeprazole (PPI) twice daily since 1992 in all medically treated patients, and surgical therapy consisted of an open Nissen Brunicardi_Ch25_p1009-p1098.indd 104401/03/19 6:03 PM 1045ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Table 25-7Symptomatic outcome of surgical therapy for Barrett’s esophagusAUTHORYEARNO. OF PATIENTS% EXCELLENT TO GOOD RESPONSEMEAN FOLLOW-UP, YEARSStarnes19848752Williamson199037923DeMeester199035773McDonald199611382.26.5Ortiz19963290.65fundoplication. The symptomatic outcome in the two groups was nearly identical, although esophagitis and/or stricture persisted in 20% of the medically treated patients, compared to only 3% to 7% of patients following antireflux surgery. About 15% of patients had abnormal acid exposure after surgery. Although pH data were not routinely collected in patients on PPI therapy, in the subgroup of 12 patients that did have 24-hour monitoring on treat-ment, 3 of 12 (25%) had persistently high esophageal acid expo-sure, and most (75%) had persistently high bilirubin exposure.The common belief that Barrett’s epithelium cannot be reversed by antireflux surgery may not be correct. Within the control arm of a randomized trial of ablation vs. surveillance, Bright and associates identified approximately 50% regression in the length of Barrett’s esophagus in 20 patients within the control arm of a randomized trial of ablation vs. surveillance.Current data indicate that patients with BE should remain in an endoscopic surveillance program following antireflux surgery. Biopsy specimens should be reviewed by a patholo-gist with expertise in the field. If low-grade dysplasia is con-firmed, biopsy specimens should be repeated after 12 weeks of high-dose acid suppression therapy. If high-grade dysplasia or intramucosal cancer is evident on more than one biopsy speci-men, then treatment is escalated. Treatment options include endoscopic mucosal resection, endoscopic ablation of the BE, or esophageal resection. Esophageal resection is advisable when an invasive cancer (stage T1b or deeper) is present, or for mul-tifocal long segment BE in younger and fit patients in whom endoscopic treatments are unlikely to be adequate. Endoscopic mucosal resection allows smaller intramucosal tumors to be removed with clear pathology margins, and it can be used as a “big biopsy” to obtain better pathological staging, and even to excise shorter segments of BE in a piecemeal fashion. Ablation, commonly using radiofrequency ablation, has been shown at short-term follow-up in a randomized trial to reduce the rate of progression from high grade dysplasia to invasive cancer by approximately 50%. However, following any endoscopic treatment, patients need to continue with close endoscopic sur-veillance as recurrence can occur and the longer-term outcome following these treatments remains uncertain. Early detection and treatment have been shown to decrease the mortality rate from esophageal cancer in these patients.If the dysplasia is reported as lower grade or indetermi-nant, then inflammatory change that is often confused with dysplasia should be suppressed by a course of acid suppression therapy in high doses for 2 to 3 months, followed by rebiopsy of the Barrett’s segment.Reoperation for Failed Antireflux Repairs. Failure of an antireflux procedure occurs when, after the repair, the patient is unable to swallow normally, experiences upper abdominal dis-comfort during and after meals, or has recurrence or persistence of reflux symptoms. The assessment of these symptoms and the selection of patients who need further surgery are challenging problems. Functional assessment of patients who have recur-rent, persistent, or emergent new symptoms following a primary antireflux repair is critical to identifying the cause of the failure. Analysis of patients requiring reoperation after a previous anti-reflux procedure shows that placement of the wrap around the stomach is the most frequent cause for failure after open proce-dures, while herniation of the repair into the chest is the most frequent cause of failure after a laparoscopic procedure. Partial or complete breakdown of the fundoplication and construction of a too-tight a fundoplication or overnarrowing the esophageal hiatus occurs with both open and closed procedures.Patients who have recurrence of heartburn and regurgitation without dysphagia and have good esophageal motility are most amenable to reoperation, and they can be expected to have an excellent outcome. When dysphagia is the cause of failure, the sit-uation can be more difficult to manage. If the dysphagia occurred immediately following the repair, it is usually due to a technical failure, most commonly a misplaced fundoplication around the upper stomach, or overnarrowing of the esophageal diaphragmatic hiatus and reoperation is usually satisfactory. When dysphagia is associated with poor motility and multiple previous repairs, fur-ther revision fundoplication is unlikely to be successful, and in otherwise fit patients it is appropriate to seriously consider esopha-geal resection. With each reoperation, the esophagus is damaged further, and the chance of preserving function is decreased. Also, blood supply is reduced, and ischemic necrosis of the esophagus can occur after several previous mobilizations.GIANT DIAPHRAGMATIC (HIATAL) HERNIASWith the advent of clinical radiology, it became evident that a diaphragmatic hernia was a relatively common abnormality and was not always accompanied by symptoms. Three types of esophageal hiatal hernia were identified: (a) the sliding hernia, type I, characterized by an upward dislocation of the cardia in the posterior mediastinum (Fig. 25-39A); (b) the roll-ing or PEH, type II, characterized by an upward dislocation of the gastric fundus alongside a normally positioned cardia (Fig. 25-39B); and (c) the combined sliding-rolling or mixed hernia, type III, characterized by an upward dislocation of both the cardia and the gastric fundus (Fig. 25-39C). The end stage of type I and type II hernias occurs when the whole stomach migrates up into the chest by rotating 180° around its longitu-dinal axis, with the cardia and pylorus as fixed points. In this situation, the abnormality is usually referred to as an intratho-racic stomach (Fig. 25-39D). In some taxonomies, a type IV hiatal hernia is declared when an additional organ, usually the colon, herniates as well. Types II–IV hiatal hernias are also referred to as paraesophageal hernia (PEH), as a portion of the stomach is situated adjacent to the esophagus, above the gastroesophageal junction.Incidence and EtiologyThe true incidence of a hiatal hernia is difficult to determine because of the absence of symptoms in a large number of patients who are subsequently shown to have a hernia. When radiographic examinations are done in response to GI symptoms, Brunicardi_Ch25_p1009-p1098.indd 104501/03/19 6:03 PM 1046SPECIFIC CONSIDERATIONSPART IICDBAFigure 25-39. A. Radiogram of a type I (sliding) hiatal hernia. B. Radiogram of a type II (rolling or paraesophageal) hernia. C. Radiogram of a type III (combined sliding-rolling or mixed) hernia. D. Radiogram of an intrathoracic stomach. This is the end stage of a large hiatal hernia regardless of its initial classification. Note that the stomach has rotated 180° around its longitudinal axis, with the cardia and pylorus as fixed points. (Reproduced with permission from Nyhus LM, Condon RE: Hernia, 3rd ed. Philadelphia, PA: Lippincott Williams & Wilkins; 1989.)Brunicardi_Ch25_p1009-p1098.indd 104601/03/19 6:03 PM 1047ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25the incidence of a sliding hiatal hernia is seven times higher than that of a PEH. The PEH is also known as the giant hiatal hernia. Over time the pressure gradient between the abdomen and chest enlarges the hiatal hernia. In many cases the type 1 sliding hernia will evolve into a type III mixed hernia. Type II hernias are quite rare. The age distribution of patients with PEHs is significantly different from that observed in sliding hiatal hernias. The median age of the former is 61 years old; of the latter, 48 years old. PEHs are more likely to occur in women by a ratio of 4:1.Structural deterioration of the phrenoesophageal mem-brane over time may explain the higher incidence of hiatal her-nias in the older age group. These changes involve thinning of the upper fascial layer of the phrenoesophageal membrane (i.e., the supradiaphragmatic continuation of the endothoracic fascia) and loss of elasticity in the lower fascial layer (i.e., the infra-diaphragmatic continuation of the transversalis fascia). Conse-quently, the phrenoesophageal membrane yields to stretching in the cranial direction due to the persistent intra-abdominal pres-sure and the tug of esophageal shortening on swallowing. Inter-estingly, the stretching and thinning occurs more anteriorly and posteriorly, with fixation of the left crus of the diaphragm to the stomach at the 3 o’clock position, as viewed from the foot. This creates an anterior and posterior hernia sac, the latter of which is often filled with epiphrenic and retroperitoneal fat. These obser-vations point to the conclusion that the development of a hiatal hernia is an age-related phenomenon secondary to repetitive upward stretching of the phrenoesophageal membrane.Clinical ManifestationsThe clinical presentation of a giant hiatal (paraesophageal) her-nia differs from that of a sliding hernia. There is usually a higher prevalence of symptoms of dysphagia and postprandial fullness with PEHs, but the typical symptoms of heartburn and regurgi-tation present in sliding hiatal hernias can also occur. Both are caused by gastroesophageal reflux secondary to an underlying mechanical deficiency of the cardia. The symptoms of dysphagia and postprandial fullness in patients with a PEH are explained by the compression of the adjacent esophagus by a distended cardia, or twisting of the GEJ by the torsion of the stomach that occurs as it becomes progressively displaced in the chest. The postprandial fullness or retrosternal chest pain is a thought to be a result of distension of the stomach with gas or food in the hiatal hernia. Many patients with sliding hernias and reflux symptoms will lose the reflux symptoms when the hernia evolves into the paraesophageal variety. This can be explained by the recreation of the cardiophrenic angle when the stomach herniates along-side the GEJ or becomes twisted in the sac. Repair of the hernia without addressing the reflux can create extremely bothersome heartburn. Respiratory complications are frequently associated with a PEH and consist of dyspnea and recurrent pneumonia from aspiration. New research demonstrates that the cause of dyspnea in the presence of a giant PEH is more likely to be left atrial compression, decreasing cardiac output, than a restrictive pulmonary effect, as has been hypothesized for many years.Approximately one-third of patients with a PEH are found to be anemic, which is due to recurrent bleeding from ulceration of the gastric mucosa in the herniated portion of the stomach, even if ulcerations are not detected at the time of endoscopy. The association of anemia and PEH is best proven by fixing the hernia. Anemia is corrected in >90% of patients with this condition. With time, more and more stomach migrates into the chest and can cause intermittent foregut obstruction due to the rotation that has occurred. In contrast, many patients with PEH are asymptomatic or complain of minor symptoms. However, the presence of a PEH can be life-threatening in that the hernia can lead to sudden catastrophic events, such as excessive bleed-ing or volvulus with acute gastric obstruction or infarction. With mild dilatation of the stomach, the gastric blood supply can be markedly reduced, causing gastric ischemia, ulceration, perfora-tion, and sepsis. The probability of incarceration/strangulation is not well known, although recent studies suggest that the lifetime risk is less than 5%, making this concern an insufficient concern for routine repair of the asymptomatic PEH.The symptoms of sliding hiatal hernias are usually due to functional abnormalities associated with gastroesophageal reflux and include heartburn, regurgitation, and dysphagia. These patients have a mechanically defective LES, giving rise to the reflux of gastric juice into the esophagus and the symp-toms of heartburn and regurgitation. The symptom of dysphagia occurs from the presence of mucosal edema, Schatzki’s ring, stricture, or the inability to organize peristaltic activity in the body of the esophagus as a consequence of the disease.There is a group of patients with sliding hiatal hernias not associated with reflux disease who have dysphagia without any obvious endoscopic or manometric explanation. Video barium radiograms have shown that the cause of dysphagia in these patients is an obstruction of the swallowed bolus by diaphrag-matic impingement on the herniated stomach. Manometrically, this is reflected by a double-humped high-pressure zone at the GEJ. The first pressure rise is due to diaphragmatic impinge-ment on the herniated stomach, and the second is due to the true distal esophageal sphincter. These patients usually have a mechanically competent sphincter, but the impingement of the diaphragm on the stomach can result in propelling the contents of the supradiaphragmatic portion of the stomach up into the esophagus and pharynx, resulting in complaints of pharyngeal regurgitation and aspiration. Consequently, this abnormality is often confused with typical GERD. Surgical reduction of the hernia results in relief of the dysphagia in 91% of patients.DiagnosisA chest X-ray with the patient in the upright position can diag-nose a hiatal hernia if it shows an air-fluid level behind the car-diac shadow. This is usually caused by a PEH or an intrathoracic stomach. The accuracy of the upper GI barium study in detect-ing a paraesophageal hiatal hernia is greater than for a sliding hernia because the latter can often spontaneously reduce. The paraesophageal hiatal hernia is a permanent herniation of the stomach into the thoracic cavity, so a barium swallow provides the diagnosis in virtually every case. Attention should be focused on the position of the GEJ, when seen, to differentiate it from a type II hernia (see Fig. 25-39B and C). Fiber-optic esophagos-copy is useful in the diagnosis and classification of a hiatal hernia because the scope can be retroflexed. In this position, a sliding hiatal hernia can be identified by noting a gastric pouch lined with rugal folds extending above the impression caused by the crura of the diaphragm, or measuring at least 2 cm between the crura, identified by having the patient sniff, and the squamoco-lumnar junction on withdrawal of the scope (Fig. 25-40). A PEH is identified on retroversion of the scope by noting a separate orifice adjacent to the GEJ into which gastric rugal folds ascend. A sliding-rolling or mixed hernia can be identified by noting a gastric pouch lined with rugal folds above the diaphragm, with the GEJ entering about midway up the side of the pouch.Brunicardi_Ch25_p1009-p1098.indd 104701/03/19 6:03 PM 1048SPECIFIC CONSIDERATIONSPART IIFigure 25-40. Endoscopic view through a retroflexed fiber-optic gastroscope showing the shaft of the scope (arrow) coming down through a sliding hernia. Note the gastric rugal folds extending above the impression caused by the crura of the diaphragm. (Repro-duced with permission from Nyhus LM, Condon RE: Hernia, 3rd ed. Philadelphia, PA: Lippincott Williams & Wilkins; 1989.)PathophysiologyPhysiologic testing with 24-hour esophageal pH monitoring has shown increased esophageal exposure to acid gastric juice in 60% of the patients with a paraesophageal hiatal hernia, com-pared with the observed 71% incidence in patients with a sliding hiatal hernia. It is now recognized that paraesophageal hiatal her-nia can be associated with pathologic gastroesophageal reflux.Physiologic studies have also shown that the competency of the cardia depends on an interrelationship between distal esophageal sphincter pressure, the length of the sphincter that is exposed to the positive-pressure environment of the abdomen, and the overall length of the sphincter. A deficiency in any one of these manometric characteristics of the sphincter is associated with incompetency of the cardia regardless of whether a hernia is present. Patients with a PEH who have an incompetent cardia have been shown to have a distal esophageal sphincter with nor-mal pressure, but a shortened overall length and displacement outside the positive-pressure environment of the abdomen. One might expect esophageal body function to be diminished with the esophagus “accordioned” up into the chest. Surprisingly, esophageal peristalsis in patients with PEH is normal in 88%.TreatmentThe treatment of paraesophageal hiatal hernia is largely surgi-cal. Controversial aspects include: (a) indications for repair, (b) diaphragmatic repair, (c) role of fundoplication, and (d) exis-tence and treatment of the short esophagus.Indications and Surgical Approach. The presence of a paraesophageal hiatal hernia has traditionally been consid-ered an indication for surgical repair. This recommendation is largely based upon two clinical observations. First, retrospec-tive studies have shown a significant incidence of catastrophic, life-threatening complications of bleeding, infarction, and per-foration in patients being followed with known paraesophageal herniation. Second, emergency repair carries a high mortality. In the classic report of Skinner and Belsey, six of 21 patients with a PEH, treated medically because of minimal symptoms, died from the complications of strangulation, perforation, exsangui-nating hemorrhage, or acute dilatation of the herniated intratho-racic stomach. For the most part, these catastrophes occurred without warning. Others have reported similar findings.Recent studies suggest that catastrophic complications may be somewhat less common. Allen and colleagues followed 23 patients for a median of 78 months with only four patients pro-gressively worsening. There was a single mortality secondary to aspiration that occurred during a barium swallow examination to investigate progressive symptoms. Although emergency repairs had a median hospital stay of 48 days compared to a stay of 9 days in those having elective repair, there were only three cases of gastric strangulation in 735 patient-years of follow-up.If surgery is delayed and repair is done on an emergency basis, operative mortality is high, compared to <1% for an elec-tive repair. With this in mind, patients with a PEH are generally counseled to have elective repair of their hernia, particularly if they are symptomatic. Watchful waiting of asymptomatic PEHs may be an acceptable option.The surgical approach to repair of a paraesophageal hiatal hernia may be either transabdominal (laparoscopic or open) or transthoracic. Each has its advantages and disadvantages. A transthoracic approach facilitates complete esophageal mobi-lization but is rarely used because the access trauma and postopera-tive pain are significantly greater than a laparoscopic approach.The transabdominal approach facilitates reduction of the volvulus that is often associated with PEHs. Although some degree of esophageal mobilization can be accomplished tran-shiatally, complete mobilization to the aortic arch is difficult or impossible without risk of injury to the vagal nerves.Laparoscopic repair of PEH would appear to have become the standard approach. Laparoscopic repair of a pure type II, or mixed type III PEH is an order of magnitude more difficult than a standard laparoscopic Nissen fundoplication. Most would rec-ommend that these procedures are best avoided until the surgeon has accumulated considerable experience with laparoscopic antireflux surgery. There are several reasons for this. First, the vertical and horizontal volvulus of the stomach often associated with PEHs makes identification of the anatomy, in particular the location of the esophagus, difficult. Second, dissection of a large PEH sac may result in significant bleeding if the surgeon deviates from the correct plane of dissection between the peri-toneal sac and the endothoracic fascia. Finally, redundant tissue present at the GEJ following dissection of the sac frustrates the creation of a fundoplication. This tissue, which includes the epi-phrenic fat pad and hernia sac should be removed at the time of PEH repair. Mindful of these difficulties, and given appropriate experience, patients with PEH may be approached laparoscopi-cally, with expectation of success in the majority.Diaphragmatic RepairIt has been shown that PEH repair has a relatively high incidence of recurrence (10–40%) when the crura is closed primarily with permanent suture. Techniques to reduce hernia recurrence con-tinue to evolve. Most surgeons believe that recurrence may be reduced with the use of synthetic or biologic mesh to reinforce the standard crural closure. Randomized controlled studies have 4Brunicardi_Ch25_p1009-p1098.indd 104801/03/19 6:04 PM 1049ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25demonstrated a reduction in PEH recurrence rate when mesh was used. Nonabsorbable synthetic mesh must be used carefully and not in a keyhole fashion at the hiatus because of a potential risk of esophagus or gastric erosion and mesh infection. Bio-logic mesh (acellular porcine dermis, acellular human dermis, porcine small intestinal submucosa) has become more widely used, but these meshes are significantly more expensive than synthetic mesh, and the only randomized study supporting bio-logic mesh usage failed to demonstrate superiority over suture alone after 5 years of rigorous follow-up.Role of Fundoplication in Giant Hiatal Hernia Repair.  Controversy remains as to whether to perform an antireflux procedure at all, in selected cases only, or in all patients. Most advocate the routine addition of an antireflux procedure follow-ing repair of the hernia defect. There are several reasons for this. Physiologic testing with 24-hour esophageal pH monitoring has shown increased esophageal exposure to acid gastric juice in 60% to 70% of patients with a paraesophageal hiatal hernia, nearly identical to the observed 71% incidence in patients with a sliding hiatal hernia. Furthermore, there is no relation between the symptoms experienced by the patient with a PEH and the competency of the cardia. Finally, dissection of the gastro-esophageal esophagus may lead to postoperative reflux despite a negative preoperative pH score.The Short Esophagus and PEHGiant PEH can be associated with a short esophagus in up to 5% to 20% of patients as a result of chronic cephalad displacement of the GEJ. The presence of a short esophagus increases the dif-ficulty of laparoscopic PEH repair. Approximately 10% to 20% of surgical failures with PEH repair is due to the lack of recogni-tion of a short esophagus. Preoperative results of barium swallow and esophagogastroduodenoscopy may provide an indication of short esophagus, but no combination of preoperative clinical vari-ables reliably predict the presence of short esophagus, defined as the failure to achieve 2.5 cm of intra-abdominal esophagus with standard mediastinal dissection techniques. Hence, the diagno-sis of this entity continues to be made definitively only in the operating room. Collis gastroplasty achieves esophageal length-ening by creation of a neoesophagus using the gastric cardia. The totally laparoscopic approach to the short esophagus has evolved from a method using an end-to-end anastomosis circular stapler to the current approach that uses a linear stapler creating a sta-pled wedge gastroplasty. Elements of importance in fashioning the fundoplication after Collis gastroplasty include placement of the initial suture of the fundoplication on the esophagus, immedi-ately above the GEJ to ensure that acid-secreting (gastric) mucosa does not reside above the fundoplication. A second element that ensures safety and avoids wrap deformation is to place the gastric portion of the staple line against the neoesophagus, such that the tip of the gastric staple line sits adjacent to the middle suture of the fundoplication on the right side of the esophagus.ResultsMost outcome studies report relief of symptoms following sur-gical repair of PEHs in more than 90% of patients. The current literature suggests that laparoscopic repair of a paraesophageal hiatal hernia can be successful. Most authors report symptom-atic improvement in 80% to 90% of patients, and <10% to 15% prevalence of recurrent symptomatic hernia. However, the problem of recurrent asymptomatic or minimally symp-tomatic hernia following PEH repair, open or laparoscopic, is Figure 25-41. Barium esophagogram showing Schatzki’s ring (i.e., a thin circumferential ring in the distal esophagus at the squa-mocolumnar junction). Below the ring is a hiatal hernia.becoming increasingly appreciated. Recurrent hiatal hernia is the most common cause of anatomic failure following laparoscopic Nissen fundoplication done for GERD (5–10%), but this risk is compounded for the giant hernia where radiologic recurrence is detected in 25% to 40% of patients. It appears that optimal results with open or laparoscopic giant hiatal hernia repair should include options for mesh buttressing of hiatal closure and selec-tive esophageal lengthening with one of the many techniques developed for the creation of a Collis gastroplasty. Despite this high incidence of radiologic recurrence, and the surgical pursuit of a remedy, it must be reinforced that asymptomatic recurrent hernias, like primary PEH, do not need to be repaired. The risk of incarceration, strangulation, or obstruction is minimal.SCHATZKI’S RINGSchatzki’s ring is a thin submucosal circumferential ring in the lower esophagus at the squamocolumnar junction, often associ-ated with a hiatal hernia. Its significance and pathogenesis are unclear (Fig. 25-41). The ring was first noted by Templeton, but Schatzki and Gary defined it as a distinct entity in 1953. Its prevalence varies from 0.2% to 14% in the general population, depending on the technique of diagnosis and the criteria used. Stiennon believed the ring to be a pleat of mucosa formed by infolding of redundant esophageal mucosa due to shortening of the esophagus. Others believe the ring to be congenital, and still others suggest it is an early stricture resulting from inflamma-tion of the esophageal mucosa caused by chronic reflux.Schatzki’s ring is a distinct clinical entity having different symptoms, upper GI function studies, and response to treatment compared with patients with a hiatal hernia, but without a ring. Twenty-four-hour esophageal pH monitoring has shown that patients with a Schatzki’s ring have a lower incidence of reflux than hiatal hernia controls. They also have better LES function. This, together with the presence of a ring, could represent a pro-tective mechanism to prevent gastroesophageal reflux.Brunicardi_Ch25_p1009-p1098.indd 104901/03/19 6:04 PM 1050SPECIFIC CONSIDERATIONSPART IISymptoms associated with Schatzki’s ring are brief epi-sodes of dysphagia during hurried ingestion of solid foods. Its treatment has varied from dilation alone to dilation with antire-flux measures, antireflux procedure alone, incision, and even excision of the ring. Little is known about the natural progres-sion of Schatzki’s rings. Using radiologic techniques, Chen and colleagues showed progressive stenosis of rings in 59% of patients, whereas Schatzki found that the rings decreased in diameter in 29% of patients and remained unchanged in the rest.Symptoms in patients with a ring are caused more by the presence of the ring than by gastroesophageal reflux. Most patients with a ring but without proven reflux respond to one dilation, while most patients with proven reflux require repeated dilations. In this regard, the majority of Schatzki’s ring patients without proven reflux have a history of ingestion of drugs known to be damaging to the esophageal mucosa. Bonavina and associates have suggested drug-induced injury as the cause of stenosis in patients with a ring, but without a history of reflux. Because rings also occur in patients with proven reflux, it is likely that gastroesophageal reflux also plays a part. This is supported by the fact that there is less drug ingestion in the history of these patients. Schatzki’s ring is prob-ably an acquired lesion that can lead to stenosis from chemical-induced injury by pill lodgment in the distal esophagus, or from reflux-induced injury to the lower esophageal mucosa.The best form of treatment of a symptomatic Schatzki’s ring in patients who do not have reflux consists of esophageal dilation for relief of the obstructive symptoms. In patients with a ring who have proven reflux and a mechanically defective sphincter, an antireflux procedure is necessary to obtain relief and avoid repeated dilation.SCLERODERMAScleroderma is a systemic disease accompanied by esophageal abnormalities in approximately 80% of patients. In most, the disease follows a prolonged course. Renal involvement occurs in a small percentage of patients and signals a poor prognosis. The onset of the disease is usually in the third or fourth decade of life, occurring twice as frequently in women as in men.Small vessel inflammation appears to be an initiating event, with subsequent perivascular deposition of normal col-lagen, which may lead to vascular compromise. In the GI tract, the predominant feature is smooth muscle atrophy. Whether the atrophy in the esophageal musculature is a primary effect or occurs secondary to a neurogenic disorder is unknown. The results of pharmacologic and hormonal manipulation, with agents that act either indirectly via neural mechanisms or directly on the muscle, suggest that scleroderma is a pri-mary neurogenic disorder. Methacholine, which acts directly on smooth muscle receptors, causes a similar increase in LES pressure in normal controls and in patients with scleroderma. Edrophonium, a cholinesterase inhibitor that enhances the effect of acetylcholine when given to patients with sclero-derma, causes an increase in LES pressure that is less marked in these patients than in normal controls, suggesting a neurogenic rather than myogenic etiology. Muscle ischemia due to peri-vascular compression has been suggested as a possible mecha-nism for the motility abnormality in scleroderma. Others have observed that in the early stage of the disease, the manomet-ric abnormalities may be reversed by reserpine, an agent that depletes catecholamines from the adrenergic system. This sug-gests that, in early scleroderma, an adrenergic overactivity may be present that causes a parasympathetic inhibition, supporting SclerodermammHg35 –0Esophagus25 cmEsophagus30 cmEsophagus35 cmSSSS35 –0035 –Figure 25-42. Esophageal motility record in a patient with sclero-derma showing aperistalsis in the distal two-thirds of the esopha-geal body with peristalsis in the proximal portion. (Reproduced with permission from Waters PF, DeMeester TR: Foregut motor disorders and their surgical management, Med Clin North Am. 1981 Nov;65(6):1235-1268.)a neurogenic mechanism for the disease. In advanced disease manifested by smooth muscle atrophy and collagen deposition, reserpine no longer produces this reversal. Consequently, from a clinical perspective, the patient can be described as having a poor esophageal pump and a poor valve.The diagnosis of scleroderma can be made manometrically by the observation of normal peristalsis in the proximal striated esophagus, with absent peristalsis in the distal smooth muscle por-tion (Fig. 25-42). The LES pressure is progressively weakened as the disease advances. Because many of the systemic sequelae of the disease may be nondiagnostic, the motility pattern is fre-quently used as a specific diagnostic indicator. Gastroesophageal reflux commonly occurs in patients with scleroderma because they have both hypotensive sphincters and poor esophageal clearance. This combined defect can lead to severe esophagitis and stricture formation. The typical barium swallow shows a dilated, barium-filled esophagus, stomach, and duodenum, or a hiatal hernia with distal esophageal stricture and proximal dilatation (Fig. 25-43).Traditionally, esophageal symptoms have been treated with PPIs, antacids, elevation of the head of the bed, and multiple dilations for strictures, with generally unsatisfac-tory results. The degree of esophagitis is usually severe and may lead to marked esophageal shortening as well as stric-ture. Scleroderma patients have frequently had numerous dilations before they are referred to the surgeon. The surgi-cal management is somewhat controversial, but the major-ity of opinion suggests that a partial fundoplication (anterior or posterior) performed laparoscopically is the procedure of choice. The need for a partial fundoplication is dictated by the likelihood of severe dysphagia if a total fundoplication is performed in the presence of aperistalsis. Esophageal short-ening may require a Collis gastroplasty in combination with a partial fundoplication. Surgery reduces esophageal acid exposure but does not return it to normal because of the poor Brunicardi_Ch25_p1009-p1098.indd 105001/03/19 6:04 PM 1051ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Figure 25-43. Barium esophagogram of a patient with sclero-derma and stricture. Note the markedly dilated esophagus and retained food material. (Reproduced with permission from Waters PF, DeMeester TR: Foregut motor disorders and their surgical management, Med Clin North Am. 1981 Nov;65(6):1235-1268.)Figure 25-44. The esophagus on the left shows a stacking of rings, demonstrating eosinophilic esophagus. The esophagus on the right is a normal barium swallow.EOSINOPHILIC ESOPHAGITISEosinophilic esophagitis (EE) was first described in 1977, but it has become well known only in the last two decades. The condi-tion is characterized by a constellation of symptoms, endoscopic and radiologic findings, and distinctive pathology. The etiology of eosinophilic esophagitis is not entirely known but its simi-larities, immunologically, to asthma suggest that it is a form of “allergic esophagitis.”SymptomsThe presentation of eosinophilic esophagitis is chest pain (often postprandial) and dysphagia. Dysphagia may occur with liquids or solids, but solid food dysphagia is most common. Because dysphagia and chest pain are characteristic of GERD, EE is often confused with GERD; however, EE does not respond to proton pump inhibitors. The evaluation of the patient with EE and dysphagia and chest pain with esophagram and endoscopy usually reveals the diagnosis.SignsA barium swallow should be the first test obtained in the patient with dysphagia. EE has a characteristic finding often called the “ringed esophagus” or the “feline esophagus,” as the esophageal rings are felt to look like the stripes on a housecat (Fig. 25-44). The endoscopic appearance of EE is also characteristic, and also appears as a series of rings (Fig. 25-45).PathologyEndoscopic biopsy specimens should be taken when eosin-ophilic esophagus is suspected. To make the diagnosis of EE, the pathologist should see a minimum of 15 eosinophils per high powered field, usually at the base of the epithelium (Fig. 25-46).TreatmentThe treatment of EE is largely symptomatic and includes test-ing for food allergies and elimination of identified items from the diet. Second-line therapy includes inhaled or ingested cor-ticosteroids, as would be used to treat asthma. If dysphagia is not relieved with steroids, it may be necessary to dilate the clearance function of the body of the esophagus. Only 50% of the patients have a good-to-excellent result. If the esopha-gitis is severe, or there has been a previous failed antireflux procedure and the disease is associated with delayed gastric emptying, a gastric resection with Roux-en-Y gastrojejunos-tomy has proved the best option.Brunicardi_Ch25_p1009-p1098.indd 105101/03/19 6:04 PM 1052SPECIFIC CONSIDERATIONSPART IIFigure 25-46. A cluster of eosinophils are visualized in the esophageal epithelium in a patient with EE.Figure 25-45. The endoscopic appearance of eosinophilic esopha-gitis is characteristically a series of stacked mucosal rings.esophagus. Because of the length of esophageal involvement, rigid dilators (Maloney or Savary) are often used. Great care must be exercised, as the inflamed EE is quite friable. The mucosal tears easily, and esophageal perforation (full thickness laceration) has been reported with EE dilation.MOTILITY DISORDERS OF THE PHARYNX AND ESOPHAGUSClinical ManifestationsDysphagia (i.e., difficulty in swallowing) is the primary symp-tom of esophageal motor disorders. Its perception by the patient is a balance between the severity of the underlying abnormality causing the dysphagia and the adjustment made by the patient in altering eating habits. Consequently, any complaint of dyspha-gia must include an assessment of the patient’s dietary history. It must be known whether the patient experiences pain, chokes, or vomits with eating; whether the patient requires liquids with the meal, is the last to finish, or is forced to interrupt or avoid a social meal; and whether he or she has been admitted to the hos-pital for food impaction. These assessments, plus an evaluation of the patient’s nutritional status, help to determine how severe the dysphagia is and judge the need for surgical intervention, rather than more conservative methods of treating dysphagia.Motility Disorders of the Pharynx and Upper Esophagus—Transit DysphagiaDisorders of the pharyngeal phase of swallowing result from a discoordination of the neuromuscular events involved in chew-ing, initiation of swallowing, and propulsion of the material from the oropharynx into the cervical esophagus. They can be categorized into one or a combination of the following abnor-malities: (a) inadequate oropharyngeal bolus transport; (b) inability to pressurize the pharynx; (c) inability to elevate the larynx; (d) discoordination of pharyngeal contraction and cri-copharyngeal relaxation; and (e) decreased compliance of the pharyngoesophageal segment secondary to neuromuscular dis-ease. The latter may result in incomplete relaxation of the crico-pharyngeus and cervical esophagus during swallowing. Taken together, these disorders are termed transit dysphagia by many.Transit dysphagia is usually congenital or results from acquired disease involving the central and peripheral nervous system. This includes cerebrovascular accidents, brain stem tumors, poliomyelitis, multiple sclerosis, Parkinson’s disease, pseudobulbar palsy, peripheral neuropathy, and operative dam-age to the cranial nerves involved in swallowing. Pure muscular diseases such as radiation-induced myopathy, dermatomyositis, myotonic dystrophy, and myasthenia gravis are less common causes. Rarely, extrinsic compression of the cervical esophagus by thyromegaly, lymphadenopathy, or hyperostosis of the cervi-cal spine can cause transit dysphagia.Diagnostic Assessment of the Cricopharyngeal SegmentTransit dysphagia difficult to assess with standard manometric techniques because of the rapidity of the oropharyngeal phase of swallowing, the elevation of the larynx, and the asymmetry of the cricopharyngeus. Videoor cineradiography is currently the Brunicardi_Ch25_p1009-p1098.indd 105201/03/19 6:04 PM 1053ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25ABFigure 25-47. A. Zenker’s diverticulum, initially discovered 15 years ago and left untreated. B. Note its marked enlargement and evidence of laryngeal inlet aspiration on recent esophagogram. (Reproduced with permission from Waters PF, DeMeester TR: Foregut motor disorders and their surgical management, Med Clin North Am. 1981 Nov;65(6):1235-1268.)Time 0Peak pharyngealpressureAtmosphericpressureABBolus pressureinitialMaximum residual(MaxR)contractionB0finalMinimum Residual(MinR)Subatomic pressureFigure 25-48. A. Schematic drawing of a pharyngeal pressure wave indicating the presence of the bolus pressure. B. Schematic drawing of the manometric recording typically seen during crico-pharyngeal sphincter relaxation.most objective test to evaluate oropharyngeal bolus transport, pharyngeal compression, relaxation of the pharyngoesophageal segment, and the dynamics of airway protection during swal-lowing. It readily identifies a diverticulum (Fig. 25-47), stasis of the contrast medium in the valleculae, a cricopharyngeal bar, and/or narrowing of the pharyngoesophageal segment. These are anatomic manifestations of neuromuscular disease, and they result from the loss of muscle compliance in portions of the pharynx and esophagus composed of skeletal muscle.Careful analysis of videoor cineradiographic studies com-bined with manometry using specially designed catheters can identify the cause of a pharyngoesophageal dysfunction in most sit-uations (Fig. 25-48). Motility studies may demonstrate inadequate pharyngeal pressurization, insufficient or lack of cricopharyngeal relaxation, marked discoordination of pharyngeal pressurization, cricopharyngeal relaxation and cervical esophageal contraction, or a hypopharyngeal bolus pressure suggesting decreased compli-ance of the skeletal portion of the cervical esophagus.In many patients with cricopharyngeal dysfunction, including those with Zenker’s diverticulum, it has been difficult to consistently demonstrate a motility abnormality or discoor-dination of pharyngoesophageal events. The abnormality most apt to be present is a loss of compliance in the pharyngoesopha-geal segment manifested by an increased bolus pressure. Cook and colleagues have demonstrated an increased resistance to the movement of a bolus through what appears on manometry to be a completely relaxed cricopharyngeal sphincter. Using simulta-neous manometry and videofluoroscopy, they showed that, in these patients, the cricopharyngeus is only partially relaxed; that is, the sphincter is relaxed enough to allow a drop of its pressure to esophageal baseline on manometry, but insufficiently relaxed to allow unimpaired passage of the bolus into the esophagus. This incomplete relaxation is due to a loss of compliance of the muscle in the pharyngoesophageal segment, and may be associ-ated with a cricopharyngeal bar or Zenker’s diverticulum. This decreased compliance of the cricopharyngeal sphincter can be recognized on esophageal manometry by a “shoulder” on the pharyngeal pressure wave, the amplitude of which correlates directly with the degree of outflow obstruction (Fig. 25-49). Increasing the diameter of this noncompliant segment reduces the resistance imposed on the passage of a bolus. Consequently, patients with low pharyngeal pressure (i.e., poor piston function of the pharynx), or patients with increased resistance of the pha-ryngocervical esophageal segment from loss of skeletal muscle compliance, are improved by a cricopharyngeal myotomy. This enlarges the pharyngoesophageal segment and reduces outflow resistance. Esophageal muscle biopsy specimens from patients with Zenker’s diverticulum have shown histologic evidence of the restrictive myopathy in the cricophayngeous muscle. These findings correlate well with the observation of a decreased com-pliance of the upper esophagus demonstrated by videoradiog-raphy and the findings on detailed manometric studies of the pharynx and cervical esophagus. They suggest that the diver-ticulum develops as a consequence of the outflow resistance to bolus transport through the noncompliant muscle of the pharyn-goesophageal segment.The requirements for a successful pharyngoesophageal myotomy are (a) adequate oropharyngeal bolus transport; (b) the presence of an intact swallowing reflex; (c) reasonable coordi-nation of pharyngeal pressurization with cricopharyngeal relax-ation; and (d) a cricopharyngeal bar, Zenker’s diverticulum, or a narrowed pharyngoesophageal segment on videoesophagogram and/or the presence of excessive pharyngoesophageal shoulder pressure on motility study.Zenker’s Diverticulum. In the past, the most common recog-nized sign of cricopharyngeal dysfunction was the presence of a Brunicardi_Ch25_p1009-p1098.indd 105301/03/19 6:04 PM 1054SPECIFIC CONSIDERATIONSPART IIZenker’s diverticulum, originally described by Ludlow in 1769. The eponym resulted from Zenker’s classic clinicopathologic descriptions of 34 cases published in 1878. Pharyngoesophageal diverticula have been reported to occur in 1 of 1000 routine barium examinations, and classically occur in elderly, white males. Zenker’s diverticula tend to enlarge progressively with time due to the decreased compliance of the skeletal portion of the cervical esophagus that occurs with aging.Presenting symptoms include dysphagia associated with the spontaneous regurgitation of undigested, bland material, often interrupting eating or drinking. On occasion, the dyspha-gia can be severe enough to cause debilitation and significant weight loss. Chronic aspiration and repetitive respiratory infec-tion are common associated complaints. Once suspected, the diagnosis is established by a barium swallow. Endoscopy is usually difficult in the presence of a cricopharyngeal diverticu-lum, and potentially dangerous, owing to obstruction of the true esophageal lumen by the diverticulum and the attendant risk of diverticular perforation.Cricopharyngeal Myotomy. The low morbidity and mor-tality associated with cricopharyngeal and upper esophageal myotomy have encouraged a liberal approach toward its use for almost any problem in the oropharyngeal phase of swallowing. This attitude has resulted in an overall success rate in the relief of symptoms of only 64%. When patients are selected for sur-gery using radiographic or motility markers of disease, a much higher proportion will benefit. Two methods of cricopharyngo-esophageal myotomy are in common use, one using traditional surgical approaches, and one using rigid laryngoscopy and a linear cutting stapler.Open Cricopharyngeal Myotomy, Diverticulopexy, and Diverticulectomy. The myotomy can be performed under local or general anesthesia through an incision along the anterior border of the left sternocleidomastoid muscle. The pharynx and cervi-cal esophagus are exposed by retracting the sternocleidomastoid muscle and carotid sheath laterally and the thyroid, trachea, and larynx medially (Fig. 25-50). When a pharyngoesophageal diverticulum is present, localization of the pharyngoesophageal segment is easy. The diverticulum is carefully freed from the overlying areolar tissue to expose its neck, just below the inferior pharyngeal constrictor and above the cricopharyngeus muscle. It can be difficult to identify the cricopharyngeus muscle in the absence of a diverticulum. A benefit of local anesthesia is that the patient can swallow and demonstrate an area of persistent nar-rowing at the pharyngoesophageal junction. Furthermore, before closing the incision, gelatin can be fed to the patient to ascertain whether the symptoms have been relieved, and to inspect the opening of the previously narrowed pharyngoesophageal seg-ment. Under general anesthesia, and in the absence of a diver-ticulum, the placement of a nasogastric tube to the level of the manometrically determined cricopharyngeal sphincter helps in localization of the structures. The myotomy is extended cephalad by dividing 1 to 2 cm of inferior constrictor muscle of the phar-ynx, and caudad by dividing the cricopharyngeal muscle and the cervical esophagus for a length of 4 to 5 cm. The cervical wound is closed only when all oozing of blood has ceased because a hematoma after this procedure is common and is often associated with temporary dysphagia while the hematoma absorbs. Oral ali-mentation is started the day after surgery. The patient is usually discharged on the first or second postoperative day.mm Hg40–0102030400HypopharynxCricopharyngeusFigure 25-50. Cross-section of the neck at the level of the thyroid isthmus that shows the sur-gical approach to the hypopharynx and cervical esophagus. (Reproduced with permission from Waters PF, DeMeester TR: Foregut motor dis-orders and their surgical management, Med Clin North Am. 1981 Nov;65(6):1235-1268.)Swallow volume010Pharyngeal shoulderpressure mmHgControlsZenker’s2030405101520200150100UES area mm25005101520Zenker’sControlsFigure 25-49. Pharyngeal shoulder pressures and diameter of the pharyngoesophageal segment in controls and patients with Zenker’s diverticulum. UES = upper esophageal sphincter. (Data from Cook IJ, et al. Zenker’s diverticu-lum: evidence for a restrictive cricopharyngeal myopathy. Gastroenterology. 1989;96:A98.)Brunicardi_Ch25_p1009-p1098.indd 105401/03/19 6:04 PM 1055ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Prevertebral fascia MyotomyZenker’sdiverticulumFigure 25-51. Posterior of the anatomy of the pharynx and cervical esophagus showing pharyngoesophageal myotomy and pexing of the diverticulum to the prevertebral fascia.If a diverticulum is present and is large enough to persist after a myotomy, it may be sutured in the inverted position to the prevertebral fascia using a permanent suture (i.e., diverticu-lopexy) (Fig. 25-51). If the diverticulum is excessively large so that it would be redundant if suspended, or if its walls are thick-ened, a diverticulectomy should be performed. This is best per-formed under general anesthesia by placing a Maloney dilator (48F) in the esophagus, after controlling the neck of the diver-ticulum and after myotomy. A linear stapler is placed across the neck of the diverticulum, and the diverticulum is excised distal to the staple line. The security of this staple line and effective-ness of the myotomy may be tested before hospital discharge with a water-soluble contrast esophagogram. Postoperative complications include fistula formation, abscess, hematoma, recurrent nerve paralysis, difficulties in phonation, and Horner’s syndrome. The incidence of the first two can be reduced by per-forming a diverticulopexy rather than diverticulectomy.Endoscopic Cricopharyngotomy. Endoscopic stapled crico-pharyngotomy and diverticulotomy recently has been described. This procedure is most effective for larger diverticula (>2 cm) and may be impossible to perform for the small diverticulum. The procedure uses a specialized “diverticuloscope” with two retractable valves passed into the hypopharynx. The lips of the diverticuloscope are positioned so that one lip lies in the esopha-geal lumen and the other in the diverticular lumen. The valves of the diverticuloscope are retracted appropriately so as to visu-alize the septum interposed between the diverticulum and the esophagus. An endoscopic linear stapler is introduced into the diverticuloscope and positioned against the common septum with the anvil in the diverticulum and the cartridge in the esoph-ageal lumen. Firing of the stapler divides the common septum between the posterior esophageal and the diverticular wall over a length of 30 mm, placing three rows of staples on each side. More than one stapler application may be needed, depending on the size of the diverticulum (Fig. 25-52). The patient is allowed to resume liquid feeds immediately and is usually discharged the day after surgery. Complications are rare and may include perforation at the apex of the diverticulum and failure to relieve dysphagia resulting from incomplete myotomy. The former complication can usually be treated with antibiotics, but it may, rarely, require neck drainage.Recurrence of a Zenker’s diverticulum may occur with long follow-up and is more common after diverticulectomy without myotomy, presumably due to persistence of the under-lying loss of compliance of the cervical esophagus when a myot-omy is not performed. After endoscopic cricopharyngotomy Figure 25-52. The technique for transoral cricopharyngotomy and Zenker’s diverticulotomy.lateral residual “pouches” may be seen on radiographs, but they are rarely responsible for residual or recurrent symptoms if the myotomy has been complete.Postoperative motility studies have shown that the peak pharyngeal pressure generated on swallowing is not affected, the resting cricopharyngeal pressure is reduced but not elimi-nated, and the cricopharyngeal sphincter length is shortened. Consequently, after myotomy, there is protection against esoph-agopharyngeal regurgitation.Motility Disorders of the Esophageal Body and Lower Esophageal SphincterDisorders of the esophageal phase of swallowing result from abnormalities in the propulsive pump action of the esophageal body or the relaxation of the LES. These disorders result from either primary esophageal abnormalities, or from generalized neural, muscular, or collagen vascular disease (Table 25-8). The use of standard and high-resolution esophageal manometry techniques has allowed specific primary esophageal motility disorders to be identified out of a pool of nonspecific motil-ity abnormalities. Primary esophageal motor disorders include achalasia, DES, nutcracker esophagus, and the hypertensive LES. The manometric characteristics of these disorders are shown in Table 25-9.The boundaries between the primary esophageal motor disorders are vague, and intermediate types exist, some of which may combine more than one type of motility pattern. These findings indicate that esophageal motility disorders should be looked at as a spectrum of abnormalities that reflects various stages of destruction of esophageal motor function.Achalasia. The best known and best understood primary motil-ity disorder of the esophagus is achalasia, with an incidence of six Brunicardi_Ch25_p1009-p1098.indd 105501/03/19 6:04 PM 1056SPECIFIC CONSIDERATIONSPART IITable 25-9Manometric characteristics of the primary esophageal motility disordersAchalasiaIncomplete lower esophageal sphincter (LES) relaxation (<75% relaxation)Aperistalsis in the esophageal bodyElevated LES pressure ≤26 mmHgIncreased intraesophageal baseline pressures relative to gastric baselineDiffuse esophageal spasm (DES)Simultaneous (nonperistaltic contractions) (>20% of wet swallows)Repetitive and multipeaked contractionsSpontaneous contractionsIntermittent normal peristalsisContractions may be of increased amplitude and durationNutcracker esophagusMean peristaltic amplitude (10 wet swallows) in distal esophagus ≥180 mmHgIncreased mean duration of contractions (>7.0 s)Normal peristaltic sequenceHypertensive lower esophageal sphincterElevated LES pressure (≥26 mmHg)Normal LES relaxationNormal peristalsis in the esophageal bodyIneffective esophageal motility disordersDecreased or absent amplitude of esophageal peristalsis (<30 mmHg)Increased number of nontransmitted contractionsReproduced with permission from Zuidema GD, Orringer MB: Shackelford’s Surgery of the Alimentary Tract, 3rd ed. Vol 1. Philadelphia, PA: Elsevier/Saunders; 1991.Simultaneous esophageal waves develop as a result of the increased resistance to esophageal emptying caused by the nonre-laxing LES. This conclusion is supported by experimental studies in which a band placed loosely around the GEJ in experimental models did not change sphincter pressures but resulted in impaired relaxation of the LES and outflow resistance. This led to a mark-edly increased frequency of simultaneous waveforms and a decrease in contraction amplitude. The changes were associated with radiographic dilation of the esophagus and were reversible after removal of the band. Observations in patients with pseudo-achalasia due to tumor infiltration, a tight stricture in the distal esophagus, or an antireflux procedure that is too tight also provide evidence that dysfunction of the esophageal body can be caused by the increased outflow obstruction of a nonrelaxing LES. The observation that esophageal peristalsis can return in patients with classic achalasia following dilation or myotomy provides further support that achalasia is a primary disease of the LES.The pathogenesis of achalasia is presumed to be a neuro-genic degeneration, which is either idiopathic or due to infec-tion. In experimental animals, the disease has been reproduced by destruction of the nucleus ambiguus and the dorsal motor nucleus of the vagus nerve. In patients with the disease, degenerative changes have been shown in the vagus nerve and in the ganglia in the myenteric plexus of the esophagus itself. This degeneration results in hypertension of the LES, a failure of the sphincter to relax on swallowing, elevation of intraluminal esophageal pres-sure, esophageal dilatation, and a subsequent loss of progressive peristalsis in the body of the esophagus. The esophageal dilatation results from the combination of a nonrelaxing sphincter, which causes a functional retention of ingested material in the esopha-gus, and elevation of intraluminal pressure from repetitive pha-ryngeal air swallowing (Fig. 25-53). With time, the functional disorder results in anatomic alterations seen on radiographic stud-ies, such as a dilated esophagus with a tapering, “bird’s beak”-like narrowing of the distal end (Fig. 25-54). There is usually an air-fluid level in the esophagus from the retained food and saliva, the height of which reflects the degree of resistance imposed by the nonrelaxing sphincter. As the disease progresses, the esophagus becomes massively dilated and tortuous.A subgroup of patients with otherwise typical features of classic achalasia has simultaneous contractions of their esopha-geal body that can be of high amplitude. This manometric pattern has been termed vigorous achalasia, and chest pain episodes are a common finding in these patients. Since the development of high resolution esophageal manometry technology, the term vigorous achalasia has been replaced with Chicago type 3 achalasia. Dif-ferentiation of type 3 achalasia from DES can be difficult. In both diseases, videoradiographic examination may show a cork-screw deformity of the esophagus and diverticulum formation.Diffuse and Segmental Esophageal Spasm. DES is charac-terized by substernal chest pain and/or dysphagia. DES differs from classic achalasia in that it is primarily a disease of the esophageal body, produces a lesser degree of dysphagia, causes more chest pain, and has less effect on the patient’s general con-dition. Nonetheless, it is impossible to differentiate achalasia from DES on the basis of symptoms alone. Esophagogram and esophageal manometry are required to distinguish these two entities. True symptomatic DES is a rare condition, occurring about five times less frequently than achalasia.The causation and neuromuscular pathophysiology of DES are unclear. The basic motor abnormality is rapid wave progression down the esophagus secondary to an abnormality in Table 25-8Esophageal motility disordersPrimary esophageal motility disordersAchalasia, “vigorous” achalasiaDiffuse and segmental esophageal spasmNutcracker esophagusHypertensive lower esophageal sphincterNonspecific esophageal motility disordersSecondary esophageal motility disordersCollagen vascular diseases: progressive systemic sclerosis, polymyositis and dermatomyositis, mixed connective tissue disease, systemic lupus erythematosus, etc.Chronic idiopathic intestinal pseudoobstructionNeuromuscular diseasesEndocrine and metastatic disordersper 100,000 population per year. Although complete absence of peristalsis in the esophageal body has been proposed as the major abnormality, present evidence indicates achalasia is a primary disorder of the LES. This is based on 24-hour outpatient esophageal motility monitoring, which shows that, even in advanced disease, up to 5% of contractions can be peristaltic. 5Brunicardi_Ch25_p1009-p1098.indd 105601/03/19 6:04 PM 1057ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25A34140120100806050403020100–10–2056*60453525159–5–15–25–3550403020100–10–206040200–20100 mmHg10 mins10 secs100 mmHgB3*4*1501401201008060402001501401201008060402005*1501401201008060402006*1451251051008565455–15MealFigure 25-53. Pressurization of esophagus: ambulatory motility tracing of a patient with achalasia. A. Before esophageal myotomy. B. After esophageal myotomy. The tracings have been compressed to exaggerate the motility spikes and baseline elevations. Note the rise in esophageal baseline pressure during a meal represented by the rise off the baseline to the left of panel A. No such rise occurs postmyotomy (B).Figure 25-54. Barium esophagogram showing a markedly dilated esophagus and characteristic “bird’s beak” in achalasia. (Repro-duced with permission from Waters PF, DeMeester TR: Foregut motor disorders and their surgical management, Med Clin North Am. 1981 Nov;65(6):1235-1268.)the latency gradient. Hypertrophy of the muscular layer of the esophageal wall and degeneration of the esophageal branches of the vagus nerve have been observed in this disease, although these are not constant findings. Manometric abnormalities in DES may be present over the total length of the esophageal body but usually are confined to the distal two-thirds. In segmental esophageal spasm, the manometric abnormalities are confined to a short segment of the esophagus.The classic manometric findings in these patients are characterized by the frequent occurrence of simultaneous wave-forms and multipeaked esophageal contractions, which may be of abnormally high amplitude or long duration. Key to the diag-nosis of DES is that there remain some peristaltic waveforms in excess of those seen in achalasia. A criterion of 30% or more peristaltic waveforms out of 10 wet swallows has been used to differentiate DES from vigorous achalasia. However, this figure is arbitrary and often debated.The LES in patients with DES usually shows a normal resting pressure and relaxation on swallowing. A hypertensive sphincter with poor relaxation may also be present. In patients with advanced disease, the radiographic appearance of tertiary contractions appears helical and has been termed corkscrew esophagus or pseudodiverticulosis (Fig. 25-55). Patients with segmental or diffuse esophageal spasm can compartmentalize the esophagus and develop an epiphrenic or midesophageal diverticulum between two areas of high pressure occurring simultaneously (Fig. 25-56).Nutcracker Esophagus. The disorder, termed nutcracker or supersqueezeresophagus, was recognized in the late 1970s. Other terms used to describe this entity are hypertensive peri-stalsis or high-amplitude peristaltic contractions. It is the most common of the primary esophageal motility disorders. By definition the so-called nutcracker esophagus is a manomet-ric abnormality in patients who are characterized by peristal-tic esophageal contractions with peak amplitudes greater than two SDs above the normal values in individual laboratories. Contraction amplitudes in these patients can easily be above 400 mmHg. At the lower end of peak pressure, it is unclear whether nutcracker esophagus causes any symptoms. In fact, chest pain symptoms in nutcracker esophagus patients may be related to GERD rather than intraluminal hypertension. Treatment in these patients should be aimed at the treatment of GERD. At the high end (peak pressures >300 mmHg) chest pain may be the result of the nutcracker physiology, as treatment directed at reducing intraluminal pressure is more effective than when used for those with lower peak pressures.Hypertensive Lower Esophageal Sphincter. Hyperten-sive lower esophageal sphincter (LES) in patients with chest pain or dysphagia was first described as a separate entity by Code and associates. This disorder is characterized by an ele-vated basal pressure of the LES with normal relaxation and Brunicardi_Ch25_p1009-p1098.indd 105701/03/19 6:04 PM 1058SPECIFIC CONSIDERATIONSPART IIFigure 25-56. Barium esophagogram showing a high epiphrenic diverticulum in a patient with diffuse esophageal spasm. (Repro-duced with permission from Castell DO: The Esophagus. Boston, MA: Little, Brown; 1992.)normal propulsion in the esophageal body. About one-half of these patients, however, have associated motility disorders of the esophageal body, particularly hypertensive peristalsis and simultaneous waveforms. In the remainder, the disorder exists as an isolated abnormality. Dysphagia in these patients may be caused by a lack of compliance of the sphincter, even in its relaxed state. Myotomy of the LES may be indicated in patients not responding to medical therapy or dilation. When the symp-tom contribution of the hypertensive sphincter is in doubt, it is possible to inject the LES with botulinum toxin, endoscopically. If symptoms are relieved (temporarily) with this technique, then it is likely that myotomy will provide more permanent benefit.Secondary Esophageal Motility Disorders. Connective tissue disease, particularly scleroderma and the CREST syn-drome, exhibits severe esophageal motility disorders. Addi-tionally, patients treated as infants for esophageal atresia will often develop secondary motility disorders manifest later in life. Symptoms of these disorders are heartburn and dysphagia. The latter may be a result of a peptic stricture rather than the esophageal dysmotility. An esophageal motility study will usu-ally show severely reduced or absent peristalsis with severely reduced or absent LES pressure. The role of antireflux surgery under these conditions is controversial but, if performed, should be limited to partial fundoplication, as full (Nissen) fundoplica-tion may result in severe dysphagia.Nonspecific Esophageal Motor Disorders and Ineffective Esophageal Motility. Many patients complaining of dys-phagia or chest pain of noncardiac origin demonstrate a vari-ety of wave patterns and contraction amplitudes on esophageal manometry that are clearly out of the normal range, but do not meet the criteria of a primary esophageal motility disor-der. Esophageal motility in these patients frequently shows an increased number of multipeaked or repetitive contractions, contractions of prolonged duration, nontransmitted contrac-tions, an interruption of a peristaltic wave at various levels of the esophagus, or contractions of low amplitude. These motility abnormalities have been termed nonspecific esophageal motility disorders. Their significance in the causation of chest pain or dysphagia is still unclear. Surgery plays no role in the treatment of these disorders unless there is an associated diverticulum.A clear distinction between primary esophageal motility disorders and nonspecific esophageal motility disorders is often not possible. Patients diagnosed as having nonspecific esophageal motility abnormalities on repeated studies will occasionally show abnormalities consistent with nutcracker esophagus. Similarly, progression from a nonspecific esophageal motility disorder to classic DES has been demonstrated. Therefore, the finding of a nonspecific esophageal motility disorder may represent only a manometric marker of an intermittent, more severe esophageal motor abnormality. Combined ambulatory 24-hour esophageal pH and motility monitoring has shown that an increased esopha-geal exposure to gastric juice is common in patients diagnosed as having a nonspecific esophageal motility disorder. In some situ-ations, the motor abnormalities may be induced by the irritation of refluxed gastric juice; in other situations, it may be a primary event unrelated to the presence of reflux. High-amplitude peristal-sis (nutcracker esophagus) and low-amplitude peristalsis (ineffec-tive esophageal motility) are frequently associated with GERD.Diverticula of the Esophageal Body. Diverticula of the esophagus may be characterized by their location in the esoph-agus (proximal, mid-, or distal esophagus), or by the nature of Figure 25-55. Barium esophagogram of patient with diffuse spasm showing the corkscrew deformity.Brunicardi_Ch25_p1009-p1098.indd 105801/03/19 6:04 PM 1059ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Figure 25-57. Barium esophagogram showing a midesophageal diverticulum. Despite the anatomic distortion, the patient was asymptomatic. (Reproduced with permission from Waters PF, DeMeester TR: Foregut motor disorders and their surgical man-agement, Med Clin North Am. 1981 Nov;65(6):1235-1268.)InflamednodesTraction diverticulumFigure 25-58. Illustration of the pathophysiology of midesopha-geal diverticulum showing traction on the esophageal wall from adhesions to inflamed subcarinal lymph nodes.concomitant pathology. Diverticula associated with motor dis-orders are termed pulsion diverticula and those associated with inflammatory conditions are termed traction diverticula. Pulsion diverticula occur most commonly with nonspecific motility disor-ders, but they can occur with all of the primary motility disorders. In the latter situation, the motility disorder is usually diagnosed before the development of the diverticulum. When associated with achalasia, the development of a diverticulum may temporar-ily alleviate the symptom of dysphagia by becoming a receptacle for ingested food and substitute the symptom of dysphagia for postprandial pain and regurgitation of undigested food. If a motil-ity abnormality of the esophageal body or LES cannot be identi-fied, a traction or congenital cause for the diverticulum should be considered.Because development in radiology preceded develop-ment in motility monitoring, diverticula of the esophagus were considered historically to be a primary abnormality, the cause, rather than the consequence, of motility disorders. Conse-quently, earlier texts focused on them as specific entities based upon their location.Epiphrenic diverticula arise from the terminal third of the thoracic esophagus and are usually found adjacent to the diaphragm. They have been associated with distal esophageal muscular hypertrophy, esophageal motility abnormalities, and increased luminal pressure. They are “pulsion” diverticula, and they are associated with diffuse spasm, achalasia, or nonspecific motor abnormalities in the body of the esophagus.Whether the diverticulum should be surgically resected or suspended depends on its size and proximity to the vertebral body. When diverticula are associated with esophageal motility disorders, esophageal myotomy from the proximal extent of the diverticulum to the stomach should be combined with diverticu-lectomy. If diverticulectomy alone is performed, one can expect a high incidence of suture line rupture due to the same intralu-minal pressure that initially gave rise to the diverticulum. If the diverticulum is suspended to the prevertebral fascia of the tho-racic vertebra, a myotomy is begun at the neck of the diverticu-lum and extended across the LES. If the diverticulum is excised by dividing the neck, the muscle is closed over the excision site, and a myotomy is performed on the opposite esophageal wall, starting just above the level of the diverticulum or at the proximal extent of the spastic segment of the esophagus if high resolution motility is used. If complete, the myotomy will cross the LES, reducing distal esophageal peak pressure, and it will increase the likelihood that dysphagia will be replaced with GERD symp-toms. Increasingly, partial fundoplication (anterior or posterior) is performed after LES myotomy to decrease the frequency of disabling GERD developing after myotomy and diverticulec-tomy. When a large diverticulum is associated with a hiatal her-nia, then hiatal hernia repair is added. All these procedures may be performed with traditional or minimally invasive techniques.Midesophageal or traction diverticula were first described in the 19th century (Fig. 25-57). At that time, they were fre-quently noted in patients who had mediastinal LN involve-ment with tuberculosis. It was theorized that adhesions formed between the inflamed mediastinal nodes and the esophagus. By contraction, the adhesions exerted traction on the esophageal wall and led to a localized diverticulum (Fig. 25-58). This theory was based on the findings of early dissections, where adhesions between diverticula and LNs were commonly found. Other con-ditions associated with mediastinal lymphadenopathy, such as pulmonary fungal infections (e.g., aspergillosis), lymphoma, or sarcoid, may create traction esophageal diverticula after success-ful treatment. Rarely, when no underlying inflammatory pathol-ogy is identified, a motility disorder may be identified.Most midesophageal diverticula are asymptomatic and incidentally discovered during investigation for nonesophageal complaints. In such patients, the radiologic abnormality may Brunicardi_Ch25_p1009-p1098.indd 105901/03/19 6:04 PM 1060SPECIFIC CONSIDERATIONSPART II100%80%60%40%20%Normal volunteersPat, no dysphagiaPat, dysphagia0%Figure 25-59. Prevalence of effective contractions (i.e., peristaltic contractions with an amplitude >30 mmHg) during meal periods in individual normal volunteers, patients (Pat) without dysphagia, and patients with nonobstructive dysphagia.100%% Symptomatic10 cm5 cm0 cm80%60%40%20%0%Pre Rx17NEso. diameter% Retention0–24mo1725–48mo1649–72mo1473–120mo12Figure 25-60. Esophageal (Eso.) diameter, dysphagia, and esoph-ageal retention in patients with achalasia treated with myotomy and Nissen fundoplication, 10 years after treatment (Rx). (Data from Topart P, Deschamps C, Taillefer R, et al: Long-term effect of total fundoplication on the myotomized esophagus, Ann Thorac Surg. 1992 Dec;54(6):1046-1051.)be ignored. Patients with symptoms of dysphagia, regurgita-tion, chest pain, or aspiration, in whom a diverticulum is dis-covered, should be thoroughly investigated for an esophageal motor abnormality. Occasionally, a patient will present with a bronchoesophageal fistula manifested by a chronic cough on ingestion of meals. The diverticulum in such patients is most likely to have an inflammatory etiology.The indication for surgical intervention is dictated by the degree of symptomatic disability. Usually, midesophageal diverticula can be suspended due to their proximity to the spine. If a motor abnormality is documented, a myotomy should be performed as described for an epiphrenic diverticulum.OPERATIONS FOR ESOPHAGEAL MOTOR DISORDERS AND DIVERTICULALong Esophageal Myotomy for Motor Disorders of the Esophageal BodyA long esophageal myotomy is indicated for dysphagia caused by any motor disorder characterized by segmental or general-ized simultaneous waveforms in a patient whose symptoms are not relieved by medical therapy. Such disorders include diffuse and segmental esophageal spasm, vigorous or type 3 achalasia, and nonspecific motility disorders associated with a midor epiphrenic esophageal diverticulum. However, the decision to operate must be made by a balanced evaluation of the patient’s symptoms, diet, lifestyle adjustments, and nutritional status, with the most important factor being the possibility of improv-ing the patient’s swallowing disability. The symptom of chest pain alone is not an indication for a surgical procedure.The identification of patients with symptoms of dyspha-gia and chest pain who might benefit from a surgical myotomy is difficult. Ambulatory motility studies have shown that when the prevalence of “effective contractions” (i.e., peristaltic waveforms consisting of contractions with an amplitude above 30 mmHg) drops below 50% during meals, the patient is likely to experience dysphagia (Fig. 25-59). This would suggest that relief from the symptom can be expected with an improvement of esophageal contraction amplitude or amelioration of non-peristaltic waveforms. Prokinetic agents may increase esopha-geal contraction amplitude, but they do not alter the prevalence of simultaneous waveforms. Patients in whom the efficacy of esophageal propulsion is severely compromised because of a high prevalence of simultaneous waveforms usually receive little benefit from medical therapy. In these patients, a surgi-cal myotomy of the esophageal body can improve the patients’ dysphagia, provided the loss of contraction amplitude in the remaining peristaltic waveforms, caused by the myotomy, has less effect on swallowing function than the presence of the excessive simultaneous contractions. This situation is reached when the prevalence of effective waveforms during meals drops below 30% (i.e., 70% of esophageal waveforms are ineffective).In patients selected for surgery, preoperative high-resolution manometry is essential to determine the proximal extent of the esophageal myotomy. Most surgeons extend the myotomy distally across the LES to reduce outflow resistance. Consequently, some form of antireflux protection is needed to avoid gastroesophageal reflux if there has been extensive dissection of the cardia. In this situation, most authors prefer a partial, rather than a full, fundoplication, in order not to add back-resistance that will further interfere with the ability of the myotomized esophagus to empty (Fig. 25-60). If the symptoms of reflux are present preoperatively, 24-hour pH monitoring is required to confirm its presence.The procedure may be performed either open or via thoracoscopy. The open technique is performed through a left thoracotomy in the sixth intercostal space (Fig. 25-61). An incision is made in the posterior mediastinal pleura over the esophagus, and the left lateral wall of the esophagus is exposed. The esophagus is not circumferentially dissected unless necessary. A 2-cm incision is made into the abdomen through the parietal peritoneum at the midportion of the left crus. A tongue of gastric fundus is pulled into the chest. This exposes the GEJ and its associated fat pad. The latter is excised to give a clear view of the junction. A myotomy is performed through all muscle layers, extending distally over the stomach 1 to 2 cm below the GEJ, and proximally on the esophagus over the distance of the manometric abnormality. The muscle layer is dissected from the mucosa laterally for a distance of 1 cm. Care is taken to divide all minute muscle bands, particularly in the area of the GEJ. The gastric fundic tongue is sutured to the margins of the myotomy over a distance of 3 to 4 cm and replaced into the abdomen. This maintains separation of the muscle and acts as a partial fundoplication to prevent reflux.Brunicardi_Ch25_p1009-p1098.indd 106001/03/19 6:04 PM 1061ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Figure 25-61. Technique of long myotomy: A. Exposure of the lower esophagus through the left sixth intercostal space and incision of the mediastinal pleura in preparation for surgical myotomy. B. Location of a 2-cm incision made through the phrenoesophageal mem-brane into the abdomen along the midlateral border of the left crus. C. Retraction of tongue of gastric fundus into the chest through the previously made incision. D. Removal of the gastroesophageal fat pad to expose the gastroesophageal junction. E. A myotomy down to the mucosa is started on the esophageal body. F. Completed myotomy extending over the stomach for 1 cm. G. Reconstruction of the cardia after a myotomy, illustrating the position of the sutures used to stitch the gastric fundic flap to the margins of the myotomy. H. Reconstruction of the cardia after a myotomy, illustrating the intra-abdominal position of the gastric tongue covering the distal 4 cm of the myotomy.Brunicardi_Ch25_p1009-p1098.indd 106101/03/19 6:04 PM 1062SPECIFIC CONSIDERATIONSPART IIIf an epiphrenic diverticulum is present, it is excised by dividing the neck with a stapler sized for the thickness of the diverticulum (2.0to 4.8-mm staple leg length) followed by a closure of the muscle over the staple line, when possible. The myotomy is then performed on the opposite esophageal wall. If a midesophageal diverticulum is present, the myotomy is made so that it includes the muscle around the neck, and the diver-ticulum is suspended by attaching it to the paravertebral fascia of the thoracic vertebra above the level of the diverticular neck. Before performing any operation for an esophageal diverticu-lum, it is wise to endoscope the patient to wash all food and other debris from the diverticulum.The results of myotomy for motor disorders of the esopha-geal body have improved in parallel with the improved preop-erative diagnosis afforded by manometry. Previous published series report between 40% and 92% improvement of symptoms, but interpretation is difficult due to the small number of patients involved and the varying criteria for diagnosis of the primary motor abnormality. When myotomy is accurately done, 93% of the patients have effective palliation of dysphagia after a mean follow-up of 5 years, and 89% would have the procedure again, if it was necessary. Most patients gain or maintain rather than lose weight after the operation. Postoperative motility studies show that the myotomy reduces the amplitude of esophageal contractions to near zero and eliminates simultaneous peristaltic waves. If the benefit of obliterating the simultaneous waves exceeds the adverse effect on bolus propulsion caused by the loss of peristaltic waveforms, the patient’s dysphagia is likely to be improved by the procedure. If not, the patient is likely to continue to complain of dysphagia and to have little improvement as a result of the operation.The thoracoscopic technique may be performed through the left or right chest. There has been little experience gained with doing adequate operations (as described previously with the open exposure) through left thoracoscopy, so most surgeons will combine a right thoracoscopic long myotomy with an abdominal approach for Heller myotomy and partial fundopli-cation. These two procedures may be done at the same setting, by double positioning the patient, or they may be done at two operations. If this is the case, it is best to do the abdominal com-ponent first, as the esophageal outflow obstruction is the source of most of the symptoms. Performing abdominal myotomy (and diverticulectomy, if present) may be all that is required.Figure 25-61. (Continued )A new procedure, peroral endoscopic myotomy (POEM) allows a long myotomy to be performed from the lumen of the esophagus with an endoscope. This procedure is attractive for, at a minimum, those with type 3 achalasia (vigorous achalasia), where it is necessary to divide esopha-gogastric circular muscle on both sides of the diaphragm to the extent that might not be possible with laparoscopy or thoracoscopy alone. The POEM procedure is started by open-ing the esophageal mucosa several centimeters above the spastic segment with a needle–knife electrosurgery device passed through an endoscope. A long submucosal plane is developed with the endoscope, down to and below the LES. The circular muscle of the LES and the esophagus is divided with endoscopic electrosurgery all the way back until normal (nonspastic) esophagus is reached. The submucosal entry site in the esophagus is then closed with endoscopic clips. While the results of POEM are still accumulating, the procedure is attractive because it is extremely minimally invasive and can be done on an outpatient basis.Epiphrenic diverticula cannot be treated with POEM and are most frequently addressed with laparoscopic access, in combination with a laparoscopic division of the LES (Heller myotomy) (Fig. 25-62). If the diverticulum can be completely mobilized through the hiatus, it may be safely excised from below. The neck of the diverticulum is transected with a GIA stapler after passage of a 48F dilator. Not infrequently, the diverticulum is sufficiently large that access to the neck of the diverticulum across the hiatus is quite difficult. Addi-tionally, the inflammatory reaction to the diverticulum may further make the transhiatal dissection difficult. Under these circumstances, it is safer to perform the diverticulectomy through a right thoracoscopic approach either at the time of the initial procedure or at a later date, depending upon the frailty of the patient. Following diverticulectomy, it is critical that the esophageal staple line be treated with a great deal of care. Closure of the muscle over the staple line is preferable. Additionally, the patient is kept NPO or on clear liquids for 5 to 7 days, and a contrast study is obtained before advancing to a full liquid or “mushy food” diet. Solid foods are withheld for 2 weeks to decrease the likelihood of staple line leak. But-tressing or sealing the staple line with fibrin glue is also an attractive option.Brunicardi_Ch25_p1009-p1098.indd 106201/03/19 6:04 PM 1063ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Figure 25-62. A. Epiphrenic diverticula are situated above the lower esophageal sphincter on right side of esophagus. B. Stapler amputates neck of diverticulum. C. Muscle reapproximated over staple line, and Heller myotomy is performed.Myotomy of the Lower Esophageal Sphincter (Heller Myotomy)Second only to reflux disease, achalasia is the most common functional disorder of the esophagus to require surgical intervention. The goal of treatment is to relieve the functional outflow obstruction secondary to the loss of relaxation and compliance of the LES. This requires disrupting the LES muscle. When performed adequately (i.e., reducing sphincter pressure to <10 mmHg), and done early in the course of disease, LES myotomy results in symptomatic improvement with the occasional return of esophageal peristalsis. Reduction in LES resistance can be accomplished intraluminally by hydrostatic balloon dilation, which ruptures the sphincter muscle, by botulinum toxin injection, or by a surgical myotomy that cuts the sphincter. The difference between these three methods appears to be the greater likelihood of reducing sphincter pressure to <10 mmHg by surgical myotomy compared with hydrostatic balloon dilation. However, patients whose sphincter pressure has been reduced by hydrostatic balloon dilation to <10 mmHg have an outcome similar to those after surgical myotomy (Fig. 25-63). Botulinum toxin injection may achieve similar results, but it has a longer duration of action that may be measured in weeks or months, rather than years. Botulinum toxin injection may best be used as a diagnostic tool, when it is not clear whether a hypertensive LES is the primary cause of dysphagia. Responsiveness to botulinum toxin injection may predict a good response to Heller myotomy.The therapeutic decisions regarding the treatment of patients with achalasia center on four issues. The first issue is the question of whether newly diagnosed patients should be treated with pneumatic dilation or a surgical myotomy. Long-term follow-up studies have shown that pneumatic dilation Brunicardi_Ch25_p1009-p1098.indd 106301/03/19 6:05 PM 1064SPECIFIC CONSIDERATIONSPART II10.80.60.40.200122426LES < 10 mmHg0.530.23LES > 10 mmHg48Months% in remission60728496Figure 25-63. Prevalence of clinical remission in 122 patients stratified according to postdilatation lower esophageal sphincter (LES) pressures greater than or <10 mmHg. (Reproduced with per-mission from Ponce J, Garrigues V, Pertejo V, et al: Individual pre-diction of response to pneumatic dilation in patients with achalasia, Dig Dis Sci. 1996 Nov;41(11):2135-2141.)achieves adequate relief of dysphagia and pharyngeal regurgi-tation in 50% to 60% of patients (Fig. 25-64). Close follow-up is required, and if dilation fails, myotomy is indicated. For those patients who have a dilated and tortuous esophagus or an associ-ated hiatal hernia, balloon dilation is dangerous and surgery is the better option. The outcome of the one controlled random-ized study (38 patients) comparing the two modes of therapy suggests that surgical myotomy as a primary treatment gives better long-term results. Several randomized trials comparing laparoscopic cardiomyotomy with balloon dilation or botuli-num toxin injection have favored the surgical approach as well. 100908070605040%302010001234567Years89101112131415Pneumatic dilatation n = 122Pneumatic dilatation n = 54Myotomy + antireflux n = 22Myotomy n = 65Myotomy n = 81Figure 25-64. Summary of long-term studies reporting the proportion of patients with complete relief or minimal dysphagia (Stage 0–1) stratified according to type of treatment. (Data from: Ellis FH, Jr. Oesophagomyotomy for achalasia: a 22-year experience. Br J Surg. 1993;80:882; Goulbourne IA, Walbaum PR. Long-term results of Heller’s operation for achalasia. J Royal Coll Surg. 1985;30:101; Malthaner RA, Todd TR, Miller L, et al. Long-term results in surgically managed esophageal achalasia. Ann Thorac Surg. 1994;58:1343; Ponce J, Garrigues V, Pertejo V, et al. Individual prediction of response to pneumatic dilation in patients with achalasia. Dig Dis Sci. 1996;41:2135; Eckardt V, Aignherr C, Bernhard G. Predictors of outcome in patients with achalasia treated by pneumatic dilation. Gastroenterology. 1992;103:1732.)Although it has been reported that a myotomy after previous balloon dilation is more difficult, this has not been the experi-ence of these authors unless the cardia has been ruptured in a sawtooth manner. In this situation, operative intervention, either immediately or after healing has occurred, can be difficult. Sim-ilarly, myotomy after botulinum toxin injection has reported to be more difficult, but this is largely a function of the submucosal inflammatory response, which may be a bit unpredictable, and is most intense in the first 6 to 12 weeks after injection. It is impor-tant to wait at least 3 months after botulinum toxin injection to perform cardiomyotomy to minimize the risk of encountering dense inflammation.The second issue is the question of whether a surgical myotomy should be performed through the abdomen or the chest. Myotomy of the LES can be accomplished via either an abdominal or thoracic approach. In the absence of a previous upper abdominal surgery, most surgeons prefer the abdominal approach to LES myotomy as laparoscopy results in less pain and a shorter length of stay than thoracoscopy. In addition, it is a bit easier to ensure a long gastric myotomy when the approach is transabdominal.The third issue—and one that has been long debated—is the question of whether an antireflux procedure should be added to a surgical myotomy. Excellent results have been reported fol-lowing meticulously performed myotomy without an antireflux component. Retrospective studies, with long-term follow-up of large cohorts of patients undergoing Heller myotomy demon-strated that, after 10 years, more than 50% of patients had reflux symptoms without a fundoplication. In a recent randomized clin-ical trial, 7% of patients undergoing Dor fundoplication follow-ing LES myotomy had abnormal 24-hour pH probes, and 42% of patients with a myotomy only had abnormal reflux profiles. If an antireflux procedure is used as an adjunct to esophageal myotomy, a complete 360° fundoplication should be avoided. Rather, a 270° Belsey fundoplication, a Toupet posterior 180° fundoplication, or a Dor anterior 180° fundoplication should be used to avoid the long-term esophageal dysfunction secondary to the outflow obstruction afforded by the fundoplication itself.The fourth issue centers on whether or not a cure of this disease is achievable. Long-term follow-up studies after surgical myotomy have shown that late deterioration in results occurs after this procedure, regardless of whether an antireflux pro-cedure is done, and also after balloon dilation, even when the sphincter pressure is reduced to below 10 mmHg. It may be that, even though a myotomy or balloon rupture of the LES muscle reduces the outflow obstruction at the cardia, the underlying motor disorder in the body of the esophagus persists and dete-riorates further with the passage of time, leading to increased impairment of esophageal emptying. The earlier an effective reduction in outflow resistance can be accomplished, the better the outcome will be, and the more likely some esophageal body function can be restored.In performing a surgical myotomy of the LES, there are four important principles: (a) complete division of all circular and collar-sling muscle fibers, (b) adequate distal myotomy to reduce outflow resistance, (c) “undermining” of the muscularis to allow wide separation of the esophageal muscle, and (d) pre-vention of postoperative reflux. In the past, the drawback of a surgical myotomy was the need for an open procedure, which often deterred patients from choosing the best treatment option for achalasia. With the advent of minimally invasive surgi-cal techniques two decades ago, laparoscopic cardiomyotomy Brunicardi_Ch25_p1009-p1098.indd 106401/03/19 6:05 PM 1065ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25(Heller myotomy) has become the treatment of choice for most patients with achalasia.Open Esophageal MyotomyOpen techniques of distal esophageal myotomy are rarely used outside reoperations. In fact, primary procedures can almost always be successfully completed via laparoscopy. A modified Heller myotomy can be performed through a left thoracotomy incision in the sixth intercostal space along the upper border of the seventh rib. The esophagus and a tongue of gastric fun-dus are exposed as described for a long myotomy. A myotomy through all muscle layers is performed, extending distally over the stomach to 1 to 2 cm below the junction, and proximally on the esophagus for 4 to 5 cm. The cardia is reconstructed by suturing the tongue of gastric fundus to the margins of the myotomy to prevent rehealing of the myotomy site and to pro-vide reflux protection in the area of the divided sphincter. If an extensive dissection of the cardia has been done, a more for-mal Belsey repair is performed. The tongue of gastric fundus is allowed to retract into the abdomen. Traditionally, nasogastric drainage is maintained for 6 days to prevent distention of the stomach during healing. An oral diet is resumed on the seventh day, after a barium swallow study shows unobstructed passage of the bolus into the stomach without extravasation.In a randomized, long-term follow-up by Csendes and colleagues of 81 patients treated for achalasia, either by forceful dilation or by surgical myotomy, myotomy was associated with a significant increase in the diameter at the GEJ and a decrease in the diameter at the middle third of the esophagus on follow-up radiographic studies. There was a greater reduction in sphincter pressure and improvement in the amplitude of esophageal contractions after myotomy. After dilation, 13% of patients regained some peristalsis, compared with 28% after surgery. These findings were shown to persist over a 5-year follow-up period, at which time 95% of those treated with surgical myotomy were doing well. Of those who were treated with dilation, only 54% were doing well, while 16% required redilation, and 22% eventually required surgical myotomy to obtain relief.If simultaneous esophageal contractions are associated with the sphincter abnormality, the so-called vigorous achala-sia, then the myotomy should extend over the distance of the abnormal motility as mapped by the preoperative motility study. Failure to do this will result in continuing dysphagia and a dis-satisfied patient. The best objective evaluation of improvement in the patient following either balloon dilation or myotomy is a scintigraphic measurement of esophageal emptying time. A good therapeutic response improves esophageal emptying toward normal. However, some degree of dysphagia may per-sist despite improved esophageal emptying, due to disturbances in esophageal body function. When an antireflux procedure is added to the myotomy, it should be a partial fundoplication. A 360° fundoplication is associated with progressive retention of swallowed food, regurgitation, and aspiration to a degree that exceeds the patient’s preoperative symptoms.Laparoscopic CardiomyotomyMore commonly known as a laparoscopic Heller myotomy, after Ernst Heller, a German surgeon who described a “dou-ble myotomy” in 1913, the laparoscopic approach is similar to the Nissen fundoplication in terms of the trocar placement and exposure and dissection of the esophageal hiatus (Fig. 25-65). The procedure begins by division of the short gastric vessels in preparation for fundoplication. Exposure of the GEJ via removal of the gastroesophageal fat pad follows. The anterior vagus nerve is swept right laterally along with the fat pad. Once completed, the GEJ and distal 4 to 5 cm of esophagus should be bared of any overlying tissue, and generally follows dissection of the GEJ. A distal esophageal myotomy is performed. It is generally easiest to begin the myotomy 1 to 2 cm above the GEJ, in an area above that of previous botulinum toxin injections or balloon dilation. Either scissors or a hook-type electrocautery can be used to initiate the incision in the longitudinal and circu-lar muscle. Distally, the myotomy is carried across the GEJ and onto the proximal stomach for approximately 2 to 3 cm. After completion, the muscle edges are separated bluntly from the esophageal mucosa for approximately 50% of the esophageal circumference. An antireflux procedure follows completion of the myotomy. Either an anterior hemifundoplication augment-ing the angle of His (Dor) or posterior partial fundoplication (Toupet) can be performed. The Dor type fundoplication is slightly easier to perform, and it does not require disruption of the normal posterior gastroesophageal attachments (a theoretical advantage in preventing postoperative reflux).Per Oral Endoscopic Myotomy (POEM)The POEM procedure was developed in Japan. It is the ultimate minimally invasive myotomy as it requires no incisions through the skin. With the POEM procedure, a very effective myotomy is performed entirely from the lumen of the esophagus. The POEM procedure is started by opening the esophageal mucosa 10 cm above the lower esophageal sphincter with a needle–knife electrosurgery device passed through an endoscope. A long submucosal plane is developed with the endoscope, down to and below the LES. The circular muscle of the LES, above and below the gastroesophageal junction, is divided with endoscopic electrosurgery. The submucosal entry site in the esophagus is then closed with endoscopic clips. While the results of POEM are still accumulating, the procedure is attractive because it is extremely minimally invasive, and can be done on an outpatient basis. The major downside of POEM is that an effective antire-flux valve cannot be created, exposing the patient to a 40% to 50% risk of GERD post procedure.Outcome Assessment of the Therapy for AchalasiaCritical analysis of the results of therapy for motor disor-ders of the esophagus requires objective measurement. The use of symptoms alone as an endpoint to evaluate therapy for achalasia may be misleading. The propensity for patients to unconsciously modify their diet to avoid difficulty swallowing is underestimated, making an assessment of results based on symptoms unreliable. Insufficient reduction in outflow resis-tance may allow progressive esophageal dilation to develop slowly, giving the impression of improvement because the volume of food able to be ingested with comfort increases. A variety of objective measurements may be used to assess success, including LES pressure, esophageal baseline pressure, and scintigraphic assessment of esophageal emptying time. Esophageal baseline pressure is usually negative compared to gastric pressure. Given that the goal of therapy is to eliminate the outflow resistance of a nonrelaxing sphincter, measure-ments of improvements in esophageal baseline pressure and scintigraphic transit time may be better indicators of success, but these are rarely reported.Brunicardi_Ch25_p1009-p1098.indd 106501/03/19 6:05 PM 1066SPECIFIC CONSIDERATIONSPART IIFigure 25-65. A. Longitudinal muscle is divided. B. Mechanical disruption of lower esophageal sphincter muscle fibers. C. Myotomy must be carried across gastroesophageal junction. D. Gastric extension should equal 2 to 3 cm. E. Anterior (Dor) fundoplication is sutured to the diaphragmatic arch. F. Posterior (Toupet) fundoplication is sutured to cut edges of myotomy. EG jct = esophagogastric junction.Eckardt and associates investigated whether the outcome of pneumatic dilation in patients with achalasia could be pre-dicted on the basis of objective measurements. Postdilation LES pressure was the most valuable measurement for predict-ing long-term clinical response. A postdilatation sphincter pres-sure <10 mmHg predicted a good response. Approximately 50% of the patients studied had postdilatation sphincter pressures between 10 and 20 mmHg, with a 2-year remission rate of 71%. More important, 16 of 46 patients were left with a postdilatation sphincter pressure of >20 mmHg and had an unacceptable out-come. Overall, only 30% of patients dilated remained in symp-tomatic remission at 5 years.Bonavina and colleagues reported good to excellent results with transabdominal myotomy and Dor fundoplication in 94% of patients after a mean follow-up of 5.4 years. No operative mortality occurred in either of these series, attesting to the safety of the procedure. Malthaner and Pearson reported the long-term clinical results in 35 patients with achalasia, having a minimum follow-up of 10 years (Table 25-10). Twenty-two of these patients underwent primary esophageal myotomy and Belsey hemifundoplication at the Toronto General Hospital. Excellent to good results were noted in 95% of patients at 1 year, declining to 68%, 69%, and 67% at 10, 15, and 20 years, respectively. Two patients underwent early reoperation for an incomplete myotomy, and three underwent an esophagectomy for progressive disease. They concluded that there was a deterioration of the initially good results after surgical myotomy and hiatal repair for achalasia, which is due to late complications of gastroesophageal reflux.Ellis reported his lifetime experience with transthoracic short esophageal myotomy without an antireflux procedure. One hundred seventy-nine patients were analyzed at a mean follow-up of 9 years, ranging from 6 months to 20 years. Overall, 89% of patients were improved at the 9-year mark. He also observed that the level of improvement deteriorated with time, with excel-lent results (patients continuing to be symptom free) decreasing from 54% at 10 years to 32% at 20 years. He concluded that a short transthoracic myotomy without an antireflux procedure provides excellent long-term relief of dysphagia, and, contrary to Malthaner and Pearson’s experience, does not result in com-plications of gastroesophageal reflux. Both studies document nearly identical results 10 to 15 years following the procedure, and both report deterioration over time, probably due to progres-sion of the underlying disease. The addition of an antireflux procedure if the operation is performed transthoracically has no significant effect on the outcome.Brunicardi_Ch25_p1009-p1098.indd 106601/03/19 6:05 PM 1067ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Figure 25-65. (Continued )Table 25-10Reasons for failure of esophageal myotomyREASONAUTHOR, PROCEDURE (N)ELLIS, MYOTOMY ONLY (N = 81)GOULBOURNE, MYOTOMY ONLY (N = 65)MALTHANER, MYOTOMY + ANTIREFLUX (N = 22)Reflux4%5%18%Inadequate myotomy2%—9%Megaesophagus2%——Poor emptying4%3%—Persistent chest pain1%——Data from Malthaner RA, et al. Long-term results in surgically managed esophageal achalasia. Ann Thorac Surg. 1994;58:1343; Ellis FH, Jr. Oesophagomyotomy for achalasia: a 22-year experience. Br J Surg. 1993;80:882; and Goulbourne IA, et al. Long-term results of Heller’s operation for achalasia. J R Coll Surg Edinb. 1985;30:101.Brunicardi_Ch25_p1009-p1098.indd 106701/03/19 6:05 PM 1068SPECIFIC CONSIDERATIONSPART IIThe outcome of laparoscopic myotomy and hemifun-doplication has been well documented. Two reports of over 100 patients have documented relief of dysphagia in 93% of patients. Richter and coworkers reviewed published reports to date, including 254 patients with an average success rate of 93% at 2.5 years. Conversion to an open procedure occurs in 0% to 5% of patients. Complications are uncommon, occurring in <5% of patients. Intraoperative complications consist largely of mucosal perforation, and have been more likely to occur after botulinum toxin injection. The incidence of objective reflux dis-ease as evidenced by abnormal acid exposure is <10%.A number of randomized clinical trials in the past decade have compared the outcomes of laparoscopic Heller myotomy to pneumatic dilation and to botulinum toxin injection. In each of these trials, laparoscopic Heller myotomy and partial fun-doplication was superior to the alternative treatment. Lastly, a randomized clinical trial examining the need for fundoplica-tion following Heller myotomy demonstrated a great deal more reflux in patients without fundoplication, and no better swallow-ing in the Heller-only group. The best treatment for achalasia is a laparoscopic Heller myotomy and partial fundoplication. The role of POEM in the management of classic (nonspastic) achalasia is yet to be established.Esophageal Resection for End-Stage Motor Disorders of the EsophagusPatients with dysphagia and long-standing benign disease, whose esophageal function has been destroyed by the disease process or multiple previous surgical procedures, are best man-aged by esophagectomy. Fibrosis of the esophagus and cardia can result in weak contractions and failure of the distal esopha-geal sphincter to relax. The loss of esophageal contractions can result in the stasis of food, esophageal dilatation, regurgitation, and aspiration. The presence of these abnormalities signals end-stage motor disease. In these situations, esophageal replace-ment is usually required to establish normal alimentation. Before proceeding with esophageal resection for patients with end-stage benign disease, the choice of the organ to substitute for the esophagus (i.e., stomach, jejunum, or colon) should be considered. The choice of replacement is affected by a num-ber of factors, as described later in “Techniques of Esophageal Reconstruction.” If minimally invasive esophagectomy is to be performed, thoracoscopic dissection should be combined with abdominal dissection. Attempts at MIS transhiatal esophagec-tomy for the massively dilated esophagus may result in large volume bleeding from mediastinal vessels that become enlarged with esophageal dilation, and such bleeding must be directly controlled for hemostasis to be adequate and the operation to be safe.CARCINOMA OF THE ESOPHAGUSSquamous carcinoma accounts for the majority of esophageal carcinomas worldwide. Its incidence is highly variable, ranging from approximately 20 per 100,000 in the United States and Britain, to 160 per 100,000 in certain parts of South Africa and the Henan Province of China, and even 540 per 100,000 in the Guriev district of Kazakhstan. The environmental factors responsible for these localized high-incidence areas have not been conclusively identified, though additives to local foodstuffs (nitroso compounds in pickled vegetables and smoked meats) and mineral deficiencies (zinc and molybdenum) have been suggested. In Western societies, smoking and alcohol consumption are strongly linked with squamous carcinoma. Other definite associations link squamous carcinoma with long-standing achalasia, lye strictures, tylosis (an autosomal dominant disorder characterized by hyperkeratosis of the palms and soles), and human papillomavirus.Adenocarcinoma of the esophagus, once an unusual malig-nancy, is diagnosed with increasing frequency (Fig. 25-66) and now accounts for more than 50% of esophageal cancer in most Western countries. The shift in the epidemiology of esophageal cancer from predominantly squamous carcinoma seen in associ-ation with smoking and alcohol to adenocarcinoma in the setting of BE is one of the most dramatic changes that has occurred in the history of human neoplasia. Although esophageal carcinoma is a relatively uncommon malignancy, its prevalence is explod-ing, largely secondary to the well-established association among gastroesophageal reflux, BE, and esophageal adenocarcinoma. Although BE was once a nearly uniformly lethal disease, sur-vival has improved slightly because of advances in the under-standing of its molecular biology, screening and surveillance practices, improved staging, minimally invasive surgical tech-niques, and neoadjuvant therapy.Furthermore, the clinical picture of esophageal adenocar-cinoma is changing. It now occurs not only considerably more frequently but also in younger patients, and it is often detected at an earlier stage. These facts support rethinking the traditional approach of assuming palliation is appropriate in all patients. The historical focus on palliation of dysphagia in an elderly patient with comorbidities should change when dealing with a young patient with dependent children and a productive life ahead. The potential for cure becomes of paramount importance.The gross appearance resembles that of squamous cell car-cinoma. Microscopically, adenocarcinoma almost always origi-nates in Barrett’s mucosa and resembles gastric cancer. Rarely, it arises in the submucosal glands and forms intramural growths that resemble the mucoepidermal and adenoid cystic carcinomas of the salivary glands.The most important etiologic factor in the development of primary adenocarcinoma of the esophagus is a metaplastic columnar-lined or Barrett’s esophagus, which occurs in approxi-mately 10% to 15% of patients with GERD. When studied pro-spectively, the incidence of adenocarcinoma in a patient with BE is one in 100 to 200 patient-years of follow-up (i.e., for every 100 patients with BE followed for 1 year, one will develop adenocarcinoma). Although this risk appears to be small, it is at least 40 to 60 times that expected for a similar population without BE. This risk is similar to the risk for developing lung cancer in a person with a 20-pack-per-year history of smoking. Endoscopic surveillance for patients with BE is recommended for two reasons: (a) at present there is no reliable evidence that medical therapy removes the risk of neoplastic transformation, and (b) malignancy in BE is curable if detected at an early stage.Clinical ManifestationsEsophageal cancer generally presents with dysphagia, although increasing numbers of relatively asymptomatic patients are now identified on surveillance endoscopy, or present with nonspecific upper GI symptoms and undergo screening endoscopy. Extension of the primary tumor into the tracheobronchial tree can occur primarily with squamous cell carcinoma and can cause stridor, tracheoesophageal fistula, and resultant coughing, choking, and aspiration 6Brunicardi_Ch25_p1009-p1098.indd 106801/03/19 6:05 PM 1069ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25U.S. esophageal cancer incidence19851993199720012005Incidence per 100,00002520151051989NCI esophageal cancer research investment$21.8M$21.7M$21.6M srallod fo snoilliMilliBo snolod fsralFiscal year020032004200520062007252015105054321Esophageal cancer funding Total NCI budget $22.3M$4.8B$4.7B$4.7B$4.6B$4.8B$22.7MU.S. esophageal cancer mortalityMortality per 100,000198519931997200120050252015105White malesOverall rateAfrican American malesWhite femalesAfrican American females1989Figure 25-66. Incidence and mortality rate trends for esophageal cancer. NCI = National Cancer Institute. (Reproduced with permis-sion from the National Cancer Institute. Last updated September, 2008.)pneumonia. Rarely, severe bleeding from the primary tumor or from erosion into the aorta or pulmonary vessels occurs. Either vocal cord may be invaded, causing paralysis, but most commonly, paralysis is caused by invasion of the left recurrent laryngeal nerve by the primary tumor or LN metastasis. Systemic organ metastases are usually manifested by jaundice or bone pain. The situation is different in high-incidence areas where screening is practiced. In these communities, the most prominent early symptom is pain on swallowing rough or dry food. In patients that present with back pain at the time of esophageal cancer diagnosis, there is usually distant metastasis or celiac encasement.Dysphagia usually presents late in the natural history of the disease because the lack of a serosal layer on the esopha-gus allows the smooth muscle to dilate with ease. As a result, the dysphagia becomes severe enough for the patient to seek medical advice only when more than 60% of the esophageal circumference is infiltrated with cancer. Consequently, the dis-ease is usually advanced if symptoms herald its presence. Tra-cheoesophageal fistula may be present in some patients on their first visit to the hospital, and more than 40% will have evidence of distant metastases. With tumors of the cardia, anorexia and weight loss usually precede the onset of dysphagia. The physical signs of esophageal tumors are those associated with the pres-ence of distant metastases.General Approach to Esophageal CancerTherapy of esophageal cancer is dictated by the stage of the can-cer at the time of diagnosis. Put simply, one needs to determine if the disease is confined to the esophagus, (T1–T2, N0), locally advanced (T1–3, N1), or disseminated (any T, any N, M1). If cancer is confined to the esophagus, removal of the tumor with adjacent lymph nodes may be curative. Very early tumors con-fined to the mucosa (T in situ, T1a, intramucosal cancer) may be addressed with endoscopic treatment. When the tumor is locally aggressive, modern therapy dictates a multimodality approach in a surgically fit patient. Multimodality therapy is either che-motherapy followed by surgery or radiation and chemotherapy followed by surgery. When given before surgery, these treat-ments are referred to as neoadjuvant or induction therapy. For disseminated cancer, treatment is aimed at palliation of symp-toms. If the patient has dysphagia, as many do, the most rapid form of palliation is the endoscopic placement of an expandable esophageal stent. For palliation of GEJ cancer, radiation may be the first choice, as stents placed across the GEJ create a great deal of gastroesophageal reflux.Staging of Esophageal CancerChoosing the best therapy for an individual patient requires accurate staging. Staging starts with the history and physical. LN disease remote from the tumor, particularly in the cervi-cal region, may be palpable on neck examination and generally indicates cancer dissemination. This is often referred to as M1a disease, indicating that these patients should not be treated with therapy directed toward locally advanced cancer. Other meta-static LNs are rarely palpable but are equally ominous, espe-cially the umbilical LN in GEJ cancer.Computed tomographic (CT) scanning of the chest, abdo-men, and pelvis provides information on local invasion of the primary cancer, LN involvement, or disseminated disease. The most common sites of esophageal cancer metastases are lung, liver, and peritoneal surfaces, including the omentum and small bowel mesentery. If masses are identified that are Brunicardi_Ch25_p1009-p1098.indd 106901/03/19 6:05 PM 1070SPECIFIC CONSIDERATIONSPART IInot characteristic for cancer or are in a location that precludes resection with the cancer specimen, positron emission tomogra-phy (PET) scanning may be able to tell whether the masses are metabolically active (likely to be cancer) or not. A PET active focus corresponding to a mass on CT scan outside of the field of esophageal resection should be biopsied before resection is performed.The introduction of endoscopic ultrasound (EUS) has made it possible to identify patients who are potentially curable before surgical therapy. Using an endoscope, the depth of the wall penetration by the tumor and the presence of LN metasta-ses can be determined with 80% accuracy. A curative resection should be encouraged if EUS indicates that the tumor has not invaded adjacent organs (T4b), and/or fewer than six enlarged LNs are imaged. Thoracoscopic and laparoscopic staging of esophageal cancer may add benefit when the nature of enlarged LNs remote from the cancer cannot be determined or when advanced imaging systems (PET and high-resolution spiral CT) are not available.Occasionally, diagnostic laparoscopy and jejunostomy tube placement may precede induction chemoradiation in the patient with severe dysphagia and weight loss from a locally advanced cancer. In summary, esophageal cancer is diagnosed with endoscopic biopsy and is staged with CT scanning of the chest and abdomen, EUS, and PET scan for all patients with CT or EUS evidence of advanced disease (T2 or greater, N1-2 or NX). Experience with esophageal resection in patients with early stage disease has identified characteristics of esophageal cancer that are associated with improved survival. A number of studies suggest that only metastasis to LNs and tumor penetration of the esophageal wall have a significant and independent influence on prognosis. Factors known to be important in the survival of patients with advanced disease, such as cell type, degree of cellular differentiation, or location of tumor in the esophagus, have no effect on survival of patients who have undergone resection for early disease. Studies also showed that patients having five or fewer LN metastases have a better outcome. Using these data, Skinner developed the wall penetration, LN, and distant organ metastases system for staging.The wall penetration, LN, and distant organ metastases system differed somewhat from the previous efforts to develop a satisfactory staging criteria for carcinoma of the esophagus. Most surgeons agreed that the 1983 tumor, nodes, and metastasis system left much to be desired. In the third edition of the manual for Staging of Cancer of the American Joint Committee on Cancer (AJCC) in 1988, an effort was made to provide a finer discrimination between stages than had been contained in the previous edition in 1983. In 2016, further refinements of the staging system of esophageal cancer were approved by the AJCC, recognizing the difference in survival afforded by resection of limited LN disease adjacent to the tumor, compared to multilevel LN disease and positive LNs remote from the primary. Table 25-11 shows the AJCC definitions for the primary tumor, lymph nodes, distant metastasis, and overall staging schema for both squamous cell carcinoma and adenocarcinoma.Clinical Approach to Carcinoma of the Esophagus and CardiaThe selection of a curative vs. a palliative operation for cancer of the esophagus is based on the location of the tumor, the patient’s age and health, the extent of the disease, and preoperative stag-ing. Figure 25-67 shows an algorithm of the clinical decisions important in the selection of curative or palliative therapy.Tumor Location. The selection of surgical therapy for patients with carcinoma of the esophagus depends not only on the ana-tomic stage of the disease and an assessment of the swallowing capacity of the patient but also on the location of the primary tumor.It is estimated that 8% of the primary malignant tumors of the esophagus occur in the cervical portion (Fig. 25-68). They are almost always squamous cell cancer, with a rare adenocar-cinoma arising from a congenital inlet patch of columnar lining. These tumors, particularly those in the postcricoid area, repre-sent a separate pathologic entity for two reasons: (a) they are more common in females and appear to be a unique entity in this regard; and (b) the efferent lymphatics from the cervical esophagus drain completely differently from those of the tho-racic esophagus. The latter drain directly into the paratracheal and deep cervical or internal jugular LNs with minimal flow in a longitudinal direction. Except in advanced disease, it is unusual for intrathoracic LNs to be involved.Cervical esophageal cancer is frequently unresectable because of early invasion of the larynx, great vessels, or trachea. Radical surgery, including esophagolaryngectomy may occa-sionally be performed for these lesions, but the ensuing mor-bidity makes this a less than desirable approach in the face of uncertain cure. Thus, for most patients with cervical esophageal cancer, stereotactic radiation with concomitant chemotherapy is the most desirable treatment.Tumors that arise within the middle third of the esopha-gus are squamous carcinomas most commonly and are fre-quently associated with LN metastasis, which are usually in the thorax but may be in the neck or abdomen, and may skip areas in between. Although it is generally felt that individu-als with midthoracic cancer and abdominal LN metastases are incurable with surgery, there are some emerging data that suggest that cervical LN metastases, if isolated, can be resected with benefit. Generally, T1 and T2 cancers with-out LN metastases are treated with resection only, but there is more and more data to suggest that LN involvement or transmural cancer (T3) warrants treatment with neoadjuvant chemoradiation therapy followed by resection. Although some surgeons prefer a transhiatal esophagectomy for all tumor locations, most surgeons believe that resection of mid-esophageal cancer should be performed under direct vision with either thoracoscopy (video-assisted thoracic surgery [VATS]) or with thoracotomy.Tumors of the lower esophagus and cardia are usually adenocarcinomas. Unless preoperative and intraoperative stag-ing clearly demonstrate an incurable lesion, resection in con-tinuity with a LN dissection should be performed. Because of the propensity of GI tumors to spread for long distances sub-mucosally, long lengths of grossly normal GI tract should be resected. The longitudinal lymph flow in the esophagus can result in skip areas, with small foci of tumor above the primary lesion, which underscores the importance of a wide resection of esophageal tumors. Wong has shown that local recurrence at the anastomosis can be prevented by obtaining a 10-cm margin of normal esophagus above the tumor. Anatomic studies have also shown that there is no submucosal lymphatic barrier between the esophagus and the stomach at the cardia, and Wong has Brunicardi_Ch25_p1009-p1098.indd 107001/03/19 6:05 PM 1071ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Table 25-11American Joint Committee on Cancer (AJCC) Staging Schema for Esophageal CancerTXT0TisT1T1aT1bT2T3T4T4aT4bNXN0N1N2N3M0M1Primary tumor cannot be assessed.No evidence of primary tumor.High-grade dysplasia.Tumor invades lamina propria, muscularis mucosae, or submucosa.Tumor invades lamina propria or muscularis mucosae.Tumor invades submucosa.Tumor invades muscularis propria.Tumor invades adventitia.Tumor invades adjacent structures.Resectable tumor invading pleura, pericardium, or diaphragm.Unresectable tumor invading other adjacent structures, such as aorta, vertebral body, trachea, etc.Regional lymph nodes cannot be assessed.No regional lymph node metastasis.Metastases in 1–2 regional lymph nodes.Metastases in 3–6 regional lymph nodes.Metastases in ≥7 regional lymph nodes.No distant metastasis.Distant metastasis.SQUAMOUS CELL CARCINOMA Pathological (pTNM)When And And And And Then the stagepT is... pN is... M is... G is... location is... group is...Tis N0 M0 N/A Any 0T1a N0 M0 G1 Any IAT1a N0 M0 G2–3 Any IBT1a N0 M0 GX Any IAT1b N0 M0 G1–3 Any IBT1b N0 M0 GX Any IBT2 N0 M0 G1 Any IBT2 N0 M0 G2–3 Any IIAT2 N0 M0 GX Any IIAT3 N0 M0 G1–3 Lower IIAT3 N0 M0 G1 Upper/middle IIAT3 N0 M0 G2–3 Upper/middle IIBClinical (cTNM)When And And Then the cT is... cN is... M is... stage group is...Tis N0 M0 0T1 N0–1 M0 IT2 N0–1 M0 IIT3 N0 M0 IIT3 N1 M0 IIIT1–3 N2 M0 IIIT4 N0–2 M0 IVAAny T N3 M0 IVAAny T Any N M1 IVBPostneoadjuvant Therapy (ypTNM)When yp And yp And Then the stageT is... N is... M is... group is...T0–2 N0 M0 IT3 N0 M0 IIT0–2 N1 M0 IIIAT3 N1 M0 IIIBT0–3 N2 M0 IIIBT4a N0 M0 IIIBT4a N1–2 M0 IVAT4a NX M0 IVAT4b N0–2 M0 IVAAny T N3 M0 IVAAny T Any N M1 IVBClinical (cTNM)When And And Then the cT is... cN is... M is... stage group is...Tis N0 M0 0T1 N0 M0 IT1 N1 M0 IIAT2 N0 M0 IIBT3 N0 M0 GX Lower/upper/middle IIBT3 N0 M0 Any Location X IIBT1 N1 M0 Any Any IIBT1 N2 M0 Any Any IIIAT2 N1 M0 Any Any IIIAT2 N2 M0 Any Any IIIBT3 N1–2 M0 Any Any IIIBT4a N0–1 M0 Any Any IIIBT4a N2 M0 Any Any IVAT4b N0–2 M0 Any Any IVAAny T N3 M0 Any Any IVAAny T Any N M1 Any Any IVB(Continued)ADENOCARCINOMAT2 N1 M0 IIIT3 N0–1 M0 IIIT4a N0–1 M0 IIIT1–4a N2 M0 IVAT4b N0–2 M0 IVAAny T N3 M0 IVAAny T Any N M1 IVBBrunicardi_Ch25_p1009-p1098.indd 107101/03/19 6:05 PM 1072SPECIFIC CONSIDERATIONSPART IITable 25-11American Joint Committee on Cancer (AJCC) Staging Schema for Esophageal CancerPostneoadjuvant Therapy (ypTNM)When yp And yp And Then the stage T is... N is... M is... group is...T0–2 N0 M0 IT3 N0 M0 IIT0–2 N1 M0 IIIAT3 N1 M0 IIIBT0–3 N2 M0 IIIBT4a N0 M0 IIIBT4a N1–2 M0 IVAT4a NX M0 IVAT4b N0–2 M0 IVAAny T N3 M0 IVAAny T Any N M1 IVBUsed with the permission of the American College of Surgeons. Amin MB, Edge SB, Greene FL, et al. (Eds.) AJCC Cancer Staging Manual, 8th Ed. Springer New York, 2017.Pathological (pTNM)When And And And Then the stage pT is... pN is... M is... G is... group is...Tis N0 M0 N/A 0T1a N0 M0 G1 IAT1a N0 M0 GX IAT1a N0 M0 G2 IBT1b N0 M0 G1–2 IBT1b N0 M0 GX IBT1 N0 M0 G3 ICT2 N0 M0 G1–2 ICT2 N0 M0 G3 IIAT2 N0 M0 GX IIAT1 N1 M0 Any IIBT3 N0 M0 Any IIBT1 N2 M0 Any IIIAT2 N1 M0 Any IIIAT2 N2 M0 Any IIIBT3 N1–2 M0 Any IIIBT4a N0–1 M0 Any IIIBT4a N2 M0 Any IVAT4b N0–2 M0 Any IVAAny T N3 M0 Any IVAAny T Any N M1 Any IVB*Could include combined Rx and chemo neoadjuvant therapyprior to resection to increase resectability and potentialsurvival in patients 75 or under.Curative enbloc resectionIntraoperativestagingAgePhysiologicfitnessClinical stagingEndoscopicultrasoundPalliation75 yearsPalliation FEV1 1.25 Ejection fraction 40%PalliationRecurrent nerve paralysisHorner's syndromePersistent spinal painParalysis of diaphragmFistula formationMalignant pleural effusionEndoscopic tumor length 9 cmAbnormal esophageal axisMultiple enlarged nodes or distantorgan metastasis on CTMore than 20% weight lossLoss of appetite (relative)PalliationTransmural tumors with 4enlarged nodesPalliationUnresectable primaryCavitary spreadDistant metastasisExtension through mediastinal wallMultiple gross lymph node metastasesMicroscopic nodal metastasis at margins ofthe en bloc dissectionPalliative symptomsDysphagiaObstructionPain of ulcerationBleedingInfectionAnxietyRequirements for palliative transhiatal resection* Free of distant organ metastases Complete excision of primary tumor possibleNonsurgicalpalliationFigure 25-67. Algorithm for the evaluation of esophageal cancer patients to select the proper therapy: curative en bloc resection, palliative transhiatal resection, or nonsurgical palliation. CT = computed tomography; FEV1 = forced expiratory volume in 1 second. (Reproduced with permission from DeMeester TR: Esophageal carcinoma: current controversies, Semin Surg Oncol. 1997 Jul-Aug;13(4):217-233.)shown that 50% of the local recurrences in patients with esopha-geal cancer who are resected for cure occur in the intrathoracic stomach along the line of the gastric resection. Considering that the length of the esophagus ranges from 17 to 25 cm, and the length of the lesser curvature of the stomach is approximately 12 cm, a curative resection requires a cervical division of the esophagus and a >50% proximal gastrectomy in most patients with carcinoma of the distal esophagus or cardia.Age. Resection for cure of carcinoma of the esophagus in a patient older than 80 years is rarely indicated because of the additional operative risk and the shorter life expectancy. Despite this general guideline, octogenarians with a high-performance status and excellent cardiopulmonary reserve may be consid-ered candidates for esophagectomy, and recent case series have established its success in highly selected patients. It is in this group of patients that the lesser physiologic impact of minimally (Continued)Brunicardi_Ch25_p1009-p1098.indd 107201/03/19 6:05 PM 1073ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25LocationIncidenceCervicalUpperthoracicMiddlethoracicLowerthoracicCardia8%3%32%25%32%Figure 25-68. Incidence of carcinoma of the esophagus and cardia based on tumor location.induction chemoradiation therapy, more pronounced dysphagia and associated malnutrition should be addressed before the initiation of chemoradiation. A laparoscopic jejunostomy tube can be placed prior to induction therapy or at the time of esophagectomy. There are emerging data that 5 days’ pretreatment with immune-enhancing nutrition, rich in fish oils, decreases cardiac and other complications, following esophagectomy.Clinical Staging. Clinical factors that indicate an advanced stage of carcinoma and exclude surgery with curative intent are recurrent nerve paralysis, Horner’s syndrome, persistent spinal pain, paralysis of the diaphragm, fistula formation, and malig-nant pleural effusion. Factors that make surgical cure unlikely include a tumor >8 cm in length, abnormal axis of the esopha-gus on a barium radiogram, more than four enlarged LNs on CT, a weight loss more than 20%, and loss of appetite. Stud-ies indicate that there are several favorable parameters associ-ated with tumors <4 cm in length, there are fewer with tumors between 4 and 8 cm, and there are no favorable criteria for tumors >8 cm in length. Consequently, the finding of a tumor >8 cm in length should exclude curative resection; the finding of a smaller tumor should encourage an aggressive approach.Preoperative Staging With Advanced Imaging. For years, clinical staging, contrast radiography, endoscopy, and CT scan-ning formed the backbone of esophageal cancer staging. More recently, preoperative decision making is guided by endoscopic ultrasonography and PET scanning.EUS provides the most reliable method of determining depth of cancer invasion. In the absence of enlarged LNs, the degree of wall invasion dictates surgical therapy. If a small focus of esophageal cancer is confined to the mucosa, endoscopic mucosal resection (EMR) is a preferable option. If the tumor invades into the submucosa, without visible lymph node involvement, most individuals would suggest esophagectomy with LN dissection, as positive nodes can be found in 20% to 25% of those with cancer limited to the mucosa and submucosa. If EUS demonstrates spread through the wall of the esophagus, especially if LNs are enlarged, then induction chemoradiation therapy (neoadjuvant therapy) should be strongly considered. Lastly, when the EUS demonstrates invasion of the trachea, bronchus, aorta, or spine, then surgical resection is rarely indicated. If there is invasion into the pleura (T4a), then surgical resection can be considered in the absence of a malignant effusion. Thus, it can be seen that the therapy of esophageal cancer is largely driven by the findings of an endoscopic ultrasonography. It is difficult to provide modern treatment of esophageal cancer without access to this modality.PET scanning, usually combined with an axial CT scan (CTPET), usually is performed on patients with locally advanced cancer or questionable lesions on CT scan to deter-mine whether metastases are present. The PET scan uses the injection of radiolabeled deoxyglucose, which is taken up in metabolically active tissues such as cancer. PET-positive areas must be correlated with the CT scan findings to assess the sig-nificance of “hot spots.” CTPET scanning has been especially useful before the initiation of chemoradiation therapy. An early response to chemoradiotherapy, by PET scan, improves the prognosis whether or not resection is ultimately performed. Conversely, if a PET-avid tumor shows no change in metabolic activity after 2 weeks of induction chemoradiation therapy, it is unlikely that further chemoor radiation therapy will be of invasive surgery may reduce the morbidity and mortality associ-ated with open twoor three-field esophagectomy.Cardiopulmonary Reserve. Patients undergoing esophageal resection should have sufficient cardiopulmonary reserve to tol-erate the proposed procedure. The respiratory function is best assessed with the forced expiratory volume in 1 second, which ideally should be 2 L or more. Any patient with a forced expi-ratory volume in 1 second of <1.25 L is a poor candidate for thoracotomy because he or she has a 40% risk of dying from respiratory insufficiency within 4 years. In patients with poor pulmonary reserve, the transhiatal esophagectomy should be considered, as the pulmonary morbidity of this operation is less than is seen following thoracotomy. Clinical evaluation and electrocardiogram are not sufficient indicators of cardiac reserve. Echocardiography and dipyridamole thallium imaging provide accurate information on wall motion, ejection fraction, and myocardial blood flow. A defect on thallium imaging may require further evaluation with preoperative coronary angiogra-phy. A resting ejection fraction of <40%, particularly if there is no increase with exercise, is an ominous sign. In the absence of invasive testing, observed stair-climbing is an economical (albeit not quantitative) method of assessing cardiopulmonary reserve. Most individuals who can climb three flights of stairs without stopping will do well with two-field open esophagectomy, espe-cially if an epidural catheter is used for postoperative pain relief.Nutritional Status. The factor most predictive of postoperative complication is the nutritional status of the patient. Profound weight loss, more than 20 lb, associated with hypoalbuminemia (albumin <3.5 g/dL) is associated with a much higher rate of complications and mortality than patients who enter curative surgery in better nutritional condition. Because malnourished patients generally have locally advanced esophageal cancer, if not metastatic disease, one should consider the placement of a feeding tube before the beginning of induction chemoradiation therapy. Although mild amounts of dysphagia are improved by Brunicardi_Ch25_p1009-p1098.indd 107301/03/19 6:05 PM 1074SPECIFIC CONSIDERATIONSPART IIany benefit. These patients have a worse prognosis and may be referred for resection or palliation without incurring the morbid-ity or expense of a full course of chemoand radiation therapy.Palliation of Esophageal CancerPalliation of esophageal cancer is indicated for individuals with metastatic esophageal cancer or cancer invading adjacent organs (T4b) who are unable to swallow, or individuals with fistulae into the tracheobronchial tree. Aortic esophageal fistulas are extremely rare and nearly 100% lethal. Dysphagia as a result of esophageal cancer can be graded from grade I, eating normally, to grade VI, unable to swallow saliva (Table 25-12). Grades I to III often can be managed with radiation therapy, usually in combination with chemotherapy. When surgical resection is not anticipated in the future, this is termed definitive chemoradia-tion therapy and usually is palliative. Radiation dose is increased from 45 Gy to 60 Gy administered over 8 weeks, rather than the 4 weeks given for chemoradiation induction therapy. In 20% of patients, a complete response to chemoradiation therapy will not only palliate the symptoms but will also leave the patient with undetectable cancer of the esophagus. Although some of these patients are truly cured, cancer will recur in many either locally or systemically 1 to 5 years following definitive chemo-radiation. In a few patients, definitive chemoradiation will be successful in all sites but the esophagus. After a 12-month wait from initial treatment and no other sites of tumor detectable except the esophagus, some of these patients may be candidates for salvage esophagectomy.For individuals with dysphagia grades IV and higher, addi-tional treatment generally is necessary. The mainstay of therapy is in-dwelling esophageal stents. Covered removable stents may be used to seal fistulae or when stent removal becomes desir-able in the future. When large, locally invasive tumors or meta-static esophageal cancer precludes any future hope of resection, uncovered expandable metal stents are the treatment of choice. The major limitations to stenting exist in cancers at the GEJ. A stent placed across the GEJ will result in severe gastroesopha-geal reflux and heartburn that can be quite disabling. In cancers at this level, radiation therapy alone may be preferable. If feed-ing access is desirable, a laparoscopic jejunostomy is usually the procedure of choice.Surgical TreatmentThe surgical treatment of esophageal cancer is dependent upon the location of the cancer, the depth of invasion, LN metastases, the fitness of the patient for operation, and the culture and beliefs of the individuals and institutions in which the treatment is performed. In an ideal world, there would be a single, stage-specific method of treating esophageal cancer because the evidence would be unassailable and noncontroversial. Randomized clinical trials and meta-analyses would prove beyond a shadow of a doubt the value of surgery vs. nonoperative therapy and would dictate the type and extent of surgery that would optimally balance immediate morbidity and mortality with duration and quality of life conferred by the procedure and the perioperative management of the esophagectomy patient. Despite many noble attempts to establish this high level of evidence, many questions relating to the appropriate therapy of esophageal cancer remain. About the only area of complete agreement is that esophagectomy should not be performed if an R0 resection is not possible. In other words, if the surgeon does not believe he or she can remove all LNs invaded by cancer and provide a tumor-free radial margin and esophagus and stomach margins that are tumor free, then a resection should not be performed.Mucosally Based Cancer. In patients with BE, and especially those with high-grade dysplasia, subcentimeter nodules are frequently discovered. Nodules should be resected in entirety, as they often harbor adenocarcinoma. Five years ago, such resection was performed with a transhiatal esophagectomy, but more recently EMR offers another method for removing intramucosal cancer. In this clinical situation, EMR is typi-cally combined with EUS to rule out more invasive disease. EUS, however, is unable to differentiate between cancer that is confined to the mucosa (T1a) and that which invades the submu-cosa (T1b). Tumors invading the submucosa are not amenable to endoscopic mucosal resection because of the high-frequency (20–25%) concurrent finding of positive LNs, which cannot be removed without esophagectomy. On the other hand, intramu-cosal cancers have little risk of spreading to regional LNs. The current approach used involves performing EMR on all nodules identified in a field of Barrett’s esophagus, and then T staging is performed by histologic analysis. This approach dictates the need for future therapy such as esophagectomy.For this reason, small intramucosal carcinomas may be removed with EMR in the following manner. The area beneath the nodule is infiltrated with saline through a sclerotherapy needle. A specialized suction cap is mounted on the end of the endoscope, and the nodule is drawn up into the cap; a snare is then applied to resect the tissue. Alternatively, a rubber band can be delivered, and the snare can be used to resect above the level of the rubber band. This specimen is then removed and sent to pathology. As long as the tumor is found to be confined to the mucosa and all margins are negative, the resection is complete. A positive margin or involvement of the submucosa warrants esophagectomy. Most importantly, these patients are at high risk for developing small nodular carcinomas elsewhere in their Barrett’s segment, and routine surveillance on a 3to 6-month basis must be continued indefinitely. Alternatively, one can consider radiofrequency ablation of the remainder of the high-grade dysplasia after careful surveillance biopsy specimens demonstrate no further sign of cancer. This approach to the early esophageal cancer Table 25-12Functional grades of dysphagiaGRADEDEFINITIONINCIDENCE AT DIAGNOSIS (%)IEating normally11IIRequires liquids with meals21IIIAble to take semisolids but unable to take any solid food30IVAble to take liquids only40VUnable to take liquids, but able to swallow saliva7VIUnable to swallow saliva12Data from Takita H, Vincent RG, Caicedo V, et al. Squamous cell carcinoma of the esophagus: a study of 153 cases, J Surg Oncol. 1977;9(6):547-554.Brunicardi_Ch25_p1009-p1098.indd 107401/03/19 6:05 PM 1075ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25should not be used when there is any suspicion of mediastinal or abdominal lymphadenopathy. Although it is currently rare that EMR provides definitive therapy of small nodular esophageal cancers, this may become more of the norm as greater surveillance reveals earlier cancers and proficiency of the technique by surgeons and gastroenterologists increases.Minimally Invasive Transhiatal Esophagectomy.  Minimally invasive transhiatal esophagectomy is an increasingly popular procedure; however, the number of these operations performed around the world remains small. Mini-invasive surgery (MIS) transhiatal esophagectomy was first performed by Aureo DePaula in Brazil and has been modified and adopted by many individuals around the world. This operation combines the advantages of transhiatal esophagectomy at minimizing pulmonary complications with the advantages of laparoscopy (less pain, quicker rehabilitation). Several variations of MIS transhiatal esophagectomy have been developed. For the earliest lesions, such as high-grade dysplasia or intramucosal carcinoma, a vagal sparing procedure can be entertained. In such a procedure, the vagal trunks are separated from the esophagus at the level of the diaphragm and the lesser curvature dissection of the stomach allows the vagus and left gastric pedicle to remain intact. Clearly, this dissection, which hugs the stomach and esophagus, provides no LN staging and is thus inadequate for all high-grade dysplasia and intramucosal cancer.MIS transhiatal esophagectomy is usually performed through five or six small incisions in the upper abdomen and a transverse cervical incision for removing the specimen and performing the cervical esophagogastrostomy. To remove the esophagus from the posterior mediastinum, especially the area behind the pulmonary vessels and the tracheal bifurcation, which cannot be visualized even with a long laparoscope placed in the posterior mediastinum, it is preferred to use a vein stripping “inversion” technique (Fig. 25-69A). The details of this operation are too lengthy to include in this text, but include the laparoscopic creation of a neo-esophagus (gastric conduit) along the greater curvature of the stomach using the right gastroepiploic artery as the primary vascular pedicle. The conduit can be created through a mini-laparotomy or laparoscopically. A Kocher maneuver releases the duodenum, and a pyloroplasty may be performed (optional). Retrograde esophageal stripping is performed by dividing the esophagus below the GEJ and sliding a vein stripper from the neck down into the abdomen followed by an inversion of the esophagus in the posterior mediastinum and removal through the neck (Fig. 25-69B). This technique is reserved for patients with high-grade dysplasia. For small cancers at the GEJ, the esophagus can be stripped in an antegrade fashion by sliding the vein stripper down from the cervical incision and out the tail of the lesser curvature (Fig. 25-69C). The tail of the lesser curvature is pulled out a port site high in the epigastrium while the esophagus is inverted into itself. For GEJ cancers, a wide celiac access LN dissection, splenic artery, hepatic artery, and posterior mediastinal LN dissection can be performed as well or better than through a laparotomy. The gastric conduit is pulled up to the neck with a chest tube and anastomosed to the cervical esophagus in an end-to-side fashion using a surgical stapler or with a handsewn anastomosis. Complications of this technique are primarily limited to leak from the esophagogastric anastomosis, which is self-limited and usually heals within 1 to 3 weeks, spontaneously.Figure 25-69. A. Laparoscopic retrograde inversion. B. Laparo-scopic antegrade inversion. A silk suture holds the tunnel after the esophagus is removed. C. The esophageal conduit is returned to the neck after passing a chest tube down the tunnel and suturing the conduit to the chest tube.Brunicardi_Ch25_p1009-p1098.indd 107501/03/19 6:05 PM 1076SPECIFIC CONSIDERATIONSPART IIOpen Transhiatal Esophagectomy. Transhiatal esophagec-tomy, also known as blunt esophagectomy or esophagectomy without a thoracotomy, was first performed in 1933 by a British surgeon, but was popularized in the last quarter of the 20th century by Mark Orringer from the University of Michigan. Although this operation may violate many of the principles of cancer resec-tion, including extended radical LN dissection, this operation has performed as well as any of the more radical procedures in randomized trials, and in large database analyses. With transhia-tal esophagectomy, the elements of dissection are similar to that described in the section entitled Minimally Invasive Transhiatal Esophagectomy, including the creation of the gastric tube and the posterior mediastinal dissection through the hiatus. Because this dissection is performed with the fingertips rather than under direct vision with surgical instruments, it requires an enlargement of the diaphragmatic hiatus. The lower mediastinal LN basins can be resected as can the upper abdominal LNs, making this an attrac-tive option for GEJ cancers. The mediastinal LNs above the infe-rior pulmonary vein are not removed with this technique, but they rarely result in a point of isolated cancer recurrence.Of all procedures for esophageal cancer, this operation is the quickest to perform in experienced hands and lies in an intermedi-ate position between minimally invasive esophagectomy and the Ivor Lewis procedure with respect to complications and recovery.Minimally Invasive Twoand Three-Field Esophagectomy.  After a rocky start, minimally invasive esophagectomy using a thoracic dissection through VATS has become reasonably popular. In general, this operation is performed with an anastomosis created in the neck (three-field), but it may be performed with the anastomosis stapled in the high thorax (two-field). Both procedures will be described.With a minimally invasive three-field esophagectomy, the patient is placed in the left lateral decubitus position. Double lumen intubation is required. Videoscopic access to the thorax is obtained in the midaxillary line in the ninth intercostal space and an angled telescope illuminates the chest superiorly. A mini-thoracotomy at about the sixth intercostal space anteriorly allows introduction of conventional surgical instruments, and a high trocar allows retraction of the lung away from the esophagus. In a three-field approach, the esophagus is dissected along its length to include division of the azygos vein and harvesting of the LNs in the upper, middle, and lower posterior mediastinum. Hilar, and posterior mediastinal nodes are all removed and sent with the specimen or individually. The thoracic duct is divided at the level of the diaphragm and removed with the specimen.Following complete intrathoracic dissection, the patient is placed in the supine position and five laparoscopic ports are placed as with the MIS transhiatal esophagectomy. The abdominal portions of the operation are identical to those described previously in the section entitled “Minimally Invasive Transhiatal Esophagectomy,” and the gastric conduit is then sewn to the tip of the fully mobilized GEJ and lesser curvature sleeve. A feeding tube is placed, and the pyloroplasty may be performed laparoscopically. A transverse cervical incision and dissection between the sternocleidomastoid and the anterior strap muscles allows access to the cervical esophagus. Great care is made to avoid stretching the recurrent laryngeal nerve. The esophagus and proximal stomach is then pulled up into the neck with the gastric conduit following. Cervical anastomosis is then performed.The MIS transthoracic two-field esophagectomy is slightly different. In this operation, the abdominal portions of the operation are done first, including placement of the feeding tube, the creation of the conduit, and the sewing of the tip of the conduit to the fully dissected GEJ. The patient is then rolled into the left lateral decubitus position and, through right thoracoscopy, the esophagus is dissected and divided 10 cm above the tumor. Once freed, the specimen is pulled out through the mini-thoracotomy, and an end-to-end anastomosis stapler is introduced through the high corner of the gastric conduit and out a stab wound along the greater curvature. The anvil of the stapler is placed in the proximal esophagus and held with a purse-string, the stapler is docked, the anastomosis is created, and a gastrotomy is then closed with another firing of the GIA stapler. The three-field esophagectomy has the advantage of placing the anastomosis in the neck where leakage is unlikely to create a severe systemic consequence. On the other hand, placement of the anastomosis in the high chest minimizes the risks of injury to structures in the neck, particularly the recurrent laryngeal nerve. Although the leak of the intrathoracic anastomosis may be more likely to bear septic consequences, the incidence of leak is diminished. Other complications of this approach relate to pulmonary and cardiac status. In many series, the most common complication is pneumonia, the second is atrial fibrillation, and the third is anastomotic leak.Ivor Lewis (En Bloc) Esophagectomy. The theory behind radical transthoracic esophagectomy is that greater removal of LNs and periesophageal tissues diminishes the chance of a posi-tive radial margin and LN recurrence. Although there are no ran-domized data demonstrating this to be superior to other forms of esophagectomy, there are many retrospective data demonstrat-ing improved survival with greater numbers of LNs harvested. A recent study from Sloan-Kettering demonstrates a direct rela-tionship between the number of negative nodes harvested and long-term survival. Although such a survival advantage may be related to the completeness of resection, extended radical resec-tions may also be a surrogate for experienced surgeons working in great institutions. As a time-honored operation, there is no doubt that en bloc esophagectomy is the standard to which less radical techniques must be compared.Generally, this operation is started in the abdomen with an upper midline laparotomy and extensive LN dissection in and about the celiac access and its branches, extending into the porta hepatis and along the splenic artery to the tail of the pan-creas. All LNs are removed en bloc with the lesser curvature of the stomach. Unless the tumor extends into the stomach, recon-struction is performed with a greater curvature gastric tube. For GEJ cancers extending significantly into the gastric cardia or fundus, the proximal stomach is removed, and reconstruction is performed with an isoperistaltic section of left colon between the upper esophagus and the remnant stomach, or the colon is connected to a Roux-en-Y limb of jejunum, if total gastrectomy is necessary. In the majority of cases, colon interposition is unnecessary, and a gastric conduit is used.Following closure of the abdominal incision, the patient is placed in the left lateral decubitus position and an anterolateral thoracotomy is performed through the sixth intercostal space. The azygos vein is divided and the posterior mediastinum is entirely cleaned out to include the thoracic duct, all periaor-tic tissues, and all tissue in the upper mediastinum along the course of the current laryngeal nerves and in the peribronchial, Brunicardi_Ch25_p1009-p1098.indd 107601/03/19 6:05 PM 1077ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25hilar, and tracheal LN stations. The proximal stomach is pulled up into the thorax where a conduit is created (if not performed previously) and a handsewn or stapled anastomosis is made between the upper thoracic esophagus and the gastric conduit or transverse colon. Chest tubes are placed, and the patient is taken to the intensive care unit.Because this is the most radical of dissections, com-plications are most common, including pneumonia, respira-tory failure, atrial fibrillation, chylothorax, anastomotic leak, conduit necrosis, gastrocutaneous fistula, and, if dissection is too near the recurrent laryngeal nerves, hoarseness will occur with an increased risk of aspiration. Tracheobronchial injury resulting in fistulas between the bronchus and conduit may also occur, however rarely. Although this procedure and three-field esophagectomy are fraught with the highest complica-tion rate, the long-term outcome of this procedure provides the greatest survival in many single-center series and retrospective reviews.Three-Field Open Esophagectomy. Three-field open esoph-agectomy is very similar to a minimally invasive three-field except that all access is through open incisions. This proce-dure is preferred by certain Japanese surgeons and LN counts achieved through this kind of operation may run from 45 to 60 LNs. Most Western surgeons question the benefit of such radical surgery when it is hard to define a survival advantage. Nonetheless, high intrathoracic cancers probably deserve such an aggressive approach if cure is the goal.Salvage Esophagectomy. Salvage esophagectomy is the nomenclature applied to esophagectomy performed after failure of definitive radiation and chemotherapy. The most frequent scenario is one in which distant disease (bone, lung, brain, or wide LN metastases) renders the patient nonoperable at initial presentation. Then, systemic chemotherapy, usually with radiation of the primary tumor, destroys all foci of metastasis, as demonstrated by CT and CT-PET, but the primary remains present and symptomatic. Following a period of observation, to make sure no new disease will become evident, salvage esophagectomy is performed, usually with an open two-field approach. Surprisingly, the cure rate of salvage esophagectomy is not inconsequential. One in four patients undergoing this operation will be disease free 5 years later, despite the presence of residual cancer in the operative specimen. Because of the dense scarring created by radiation treatment, this procedure is the most technically challenging of all esophagectomy techniques.Comparative Studies of Esophagectomy TechniqueTransthoracic vs. Transhiatal Esophagectomy. There has been a great debate as to whether en bloc esophagectomy will provide a greater long-term benefit and cure rate in esophageal cancer than transhiatal esophagectomy. In a recent 7-year fol-low-up of a Dutch study addressing GEJ and lower esophageal cancers, there does not appear to be any benefit to the more extensive dissection despite higher morbidity and mortality. In a subgroup analysis of those with one to eight positive LNs, it did appear that the en bloc transthoracic resection may add to longevity. In another large database analysis of the Surveil-lance, Epidemiology, and End Results database, transthoracic and transhiatal esophagectomy were compared. In this study, the transhiatal esophagectomy had a greater long-term survival, but when adjusted by cancer stage, this survival benefit disap-peared. The mortality and morbidity after transhiatal esopha-gectomy appeared to be less. Suffice it to say that this debate over the best procedure for esophagectomy remains an open question.The role of the minimally invasive surgical procedures for a cancer cure will require further study and longer follow-up. It would appear from preliminary analysis that the transhiatal esophagectomy, like its open cousin, may be performed with less morbidity and mortality than the VATS procedure. Long-term survival analyses will require careful follow-up for at least 5 to 10 years after cancer treatment. A recent European multi-center randomized trial comparing open and minimally invasive approaches revealed a highly significant reduction in pulmo-nary complications in the patients who underwent the minimally invasive approach. There was no difference in procedure-related mortality between the approaches.Alternative TherapiesRadiation Therapy. Primary treatment with radiation ther-apy does not produce results comparable with those obtained with surgery. Currently, the use of radiotherapy is restricted to patients who are not candidates for surgery, and it is usually combined with chemotherapy. Radiation alone is used for pal-liation of dysphagia, but the benefit is short lived, lasting only 2 to 3 months. Furthermore, the length and course of treatment are difficult to justify in patients with a limited life expectancy. Radiation is effective in patients who have hemorrhage from the primary tumor.Adjuvant Chemotherapy. The proposal to use adjuvant che-motherapy in the treatment of esophageal cancer began when it became evident that most patients develop postoperative sys-temic metastasis without local recurrence. This observation led to the hypothesis that undetected systemic micrometasta-sis had been present at the time of diagnosis, and if effective systemic therapy was added to local regional therapy, survival should improve.Recently, this hypothesis has been supported by the obser-vation of epithelial tumor cells in the bone marrow in 37% of patients with esophageal cancer who were resected for cure. These patients had a greater prevalence of relapse at 9 months after surgery compared to those patients without such cells. Such studies emphasize that hematogenous dissemination of viable malignant cells occurs early in the disease, and that sys-temic chemotherapy may be helpful if the cells are sensitive to the agent. On the other hand, systemic chemotherapy may be a hindrance, because of its immunosuppressive properties, if the cells are resistant. Unfortunately, current technology is not able to test tumor cell sensitivity to chemotherapeutic drugs. This requires that the choice of drugs be made solely on the basis of their clinical effectiveness against grossly similar tumors.The decision to use preoperative rather than postopera-tive chemotherapy was based on the ineffectiveness of chemo-therapeutic agents when used after surgery, and animal studies suggesting that agents given before surgery were more effec-tive. The claim that patients who receive chemotherapy before resection are less likely to develop resistance to the drugs is unsupported by hard evidence. The claim that drug delivery is enhanced because blood flow is more robust before patients undergo surgical dissection is similarly flawed, due to the fact that if enough blood reaches the operative site to heal the wound or anastomosis, then the flow should be sufficient to Brunicardi_Ch25_p1009-p1098.indd 107701/03/19 6:05 PM 1078SPECIFIC CONSIDERATIONSPART IIdeliver chemotherapeutic drugs. There are, however, data sup-porting the claim that preoperative chemotherapy in patients with esophageal carcinoma can, if effective, facilitate surgical resection by reducing the size of the tumor. This is particularly beneficial in the case of squamous cell tumors above the level of the carina. Reducing the size of the tumor may provide a safer margin between the tumor and the trachea and allow an anastomosis to a tumor-free cervical esophagus just below the cricopharyngeus. Involved margin at this level usually requires a laryngectomy to prevent subsequent local recurrence.Preoperative Chemotherapy. Eight randomized prospec-tive studies of neoadjuvant chemotherapy vs. surgery alone have demonstrated mixed results. For adenocarcinomas of the distal esophagus and proximal stomach, preoperative neoadju-vant 5-fluorouracil (5-FU) and cisplatin chemotherapy has been shown to provide a survival advantage over surgery alone in a well-powered study from the United Kingdom (MRC trial). This trial is one of the few to include enough patients (800) to detect small differences. The trial had a 10% absolute survival benefit at 2 years for the neoadjuvant chemotherapy group. In a second trial from the United Kingdom (MAGIC trial) of distal esopha-geal and proximal gastric adenocarcinomas, the use of epirubi-cin in combination with cisplatin and 5-FU also demonstrated a survival advantage for the induction chemotherapy arm with 4 years median follow-up. As a result of these two trials, stan-dard treatment of locally advanced adenocarcinoma in Europe calls for neoadjuvant chemotherapy with one of these two regi-mens. Most failures are due to distant metastatic disease, under-scoring the need for improved systemic therapy. Postoperative septic and respiratory complications may be more common in patients receiving chemotherapy.Preoperative Combination Chemoand Radiotherapy.  Preoperative chemoradiotherapy using cisplatin and 5-FU in combination with radiotherapy has been reported by several investigators to be beneficial in both adenocarcinoma and squa-mous cell carcinoma of the esophagus. There have been 10 randomized prospective studies (Table 25-13). A recent meta-analysis of these trials demonstrates a 13% survival advantage for neoadjuvant chemoradiation therapy, which is more pro-nounced for patients with adenocarcinoma than for those with squamous carcinoma (Table 25-14). It was also observed that the benefit for chemotherapy alone (7%) was not as dramatic as for chemoradiotherapy used in the neoadjuvant setting. Addi-tionally, other work has demonstrated the importance of obtain-ing an R0 (tumor-free) resection as the most important variable determining long-term survival. Although there are no direct, randomized comparisons between chemotherapy and chemora-diation therapy, it appears that the addition of radiation may improve local response of the tumor and may allow a greater opportunity for the surgeon to obtain an R0 resection.The timing of surgery after chemoradiation induction is generally felt to be optimal between 6 and 8 weeks following the completion of induction therapy. Earlier than this time, active inflammation may make the resection hazardous, and the patients have not had time to recover fully from the chemoradia-tion. After 8 weeks, edema in the periesophageal tissue starts to turn to scar tissue, making dissection more difficult.With chemoradiation, the complete response rates for ade-nocarcinoma range from 17% to 24% (Table 25-15). No tumor is detected in the specimen after esophagectomy. Patients dem-onstrating a complete response to chemoradiation have a better survival rate than those without complete response, but distant failure remains common.At present, the strongest predictors of outcome of patients with esophageal cancer are the anatomic extent of the tumor at diagnosis and the completeness of tumor removal by surgical resection. After incomplete resection of an esophageal cancer, the 5-year survival rates are 0% to 5%. In contrast, after com-plete resection, independent of stage of disease, 5-year sur-vival ranges from 15% to 40%, according to selection criteria and stage distribution. The importance of early recognition and adequate surgical resection cannot be overemphasized. Figure 25-70 is a global algorithm for the management of esophageal carcinoma.SARCOMA OF THE ESOPHAGUSSarcomas and carcinosarcomas are rare neoplasms, account-ing for approximately 0.1% to 1.5% of all esophageal tumors. They present with the symptom of dysphagia, which does not differ from the dysphagia associated with the more common epithelial carcinoma. Tumors located within the cervical or high thoracic esophagus can cause symptoms of pulmonary aspiration secondary to esophageal obstruction. Large tumors originating at the level of the tracheal bifurcation can produce symptoms of airway obstruction and syncope by direct com-pression of the tracheobronchial tree and heart (Fig. 25-71). The duration of dysphagia and age of the patients affected with these tumors are similar to those with carcinoma of the esophagus.A barium swallow usually shows a large polypoid intralu-minal esophageal mass, causing partial obstruction and dilata-tion of the esophagus proximal to the tumor (Fig. 25-72). The smooth polypoid nature of the lesion, although not diagnostic, is distinctive enough to suggest the presence of a sarcoma rather than the more common ulcerating, stenosing carcinoma.Esophagoscopy commonly shows an intraluminal necrotic mass. When biopsy is attempted, it is important to remove the necrotic tissue until bleeding is seen on the tumor’s surface. When this is not done, the biopsy specimen will show only tis-sue necrosis. Even when viable tumor is obtained on biopsy, it has been these authors’ experience that it cannot be defini-tively identified as carcinoma, sarcoma, or carcinosarcoma on the basis of the histology of the portion biopsied. Biopsy results cannot be totally relied on to identify the presence of sarcoma, and it is often the polypoid nature of the lesion that arouses sus-picion that it may be something other than carcinoma.Polypoid sarcomas of the esophagus, in contrast to infil-trating carcinomas, remain superficial to the muscularis propria and are less likely to metastasize to regional LNs. In one series of 14 patients, local extension or tumor metastasis would have prevented a potentially curative resection in only five. Thus, the presence of a large polypoid tumor should not deter the surgeon from resecting the lesion.Sarcomatous lesions of the esophagus can be divided into epidermoid carcinomas with spindle cell features, such as car-cinosarcoma, and true sarcomas that arise from mesenchymal tissue, such as leiomyosarcoma, fibrosarcoma, and rhabdo-myosarcoma. Based on current histologic criteria for diagno-sis, fibrosarcoma and rhabdomyosarcoma of the esophagus are extremely rare lesions.Surgical resection of polypoid sarcoma of the esophagus is the treatment of choice because radiation therapy has little Brunicardi_Ch25_p1009-p1098.indd 107801/03/19 6:05 PM 1079ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Table 25-13Randomized trials of neoadjuvant chemoradiotherapy vs. surgery, or neoadjuvant chemotherapy vs. surgeryYEAR ACTIVATEDTREATMENT SCHEDULE (RADIOTHERAPY)TREATMENT SCHEDULE (CHEMOTHERAPY)CONCURRENT OR SEQUENTIALTUMOR TYPESAMPLE SIZEMEDIAN FOLLOWUP (MO)Chemoradiotherapy198335 Gy, 1.75 Gy/fraction over 4 wkTwo cycles: cisplatin 20 mg/m2 d 1–5; bleomycin 5 mg/m2 d 1–5SequentialSCC7818a198640 Gy, 2 Gy/fraction over 4 wkTwo cycles: cisplatin 100 mg/m2 d 1; 5-fluorouracil 1000 mg/m2 d 1–4ConcurrentSCC6912a198820 Gy, 2 Gy/fraction over 12 dTwo cycles: cisplatin 100 mg/m2 d 1; 5-fluorouracil 600 mg/m2 d 2–5, 22–25SequentialSCC8612a198945 Gy, 1.5 Gy/fraction over 3 wkTwo cycles: cisplatin 20 mg/m2 d 1–5; 5-fluorouracil 300 mg/m2 d 1–21; vinblastine 1 mg/m2 d 1–4ConcurrentSCC and adenocarcinoma10098198937 Gy, 3.7 Gy/fraction over 2 wkTwo cycles: cisplatin 80 mg/m2 d 0–2SequentialSCC29355199040 Gy, 2.7 Gy/fraction over 3 wkTwo cycles: cisplatin 75 mg/m2 d 7; 5-fluorouracil 15 mg/kg d 1–5ConcurrentAdenocarcinoma11324199040 Gy, 2.7 Gy/fraction over 3 wkTwo cycles: cisplatin 75 mg/m2 d 7; 5-fluorouracil 15 mg/kg d 1–5ConcurrentSCC6110199435 Gy, 2.3 Gy/fraction over 3 wkOne cycle: cisplatin 80 mg/m2 d 1; 5-fluorouracil 800 mg/m2 d 2–5ConcurrentSCC and adenocarcinoma25665200650.4 Gy, 1.8 Gy/fraction over 5.6 wkTwo cycles: cisplatin 60 mg/m2 d 1; 5-fluorouracil 1000 mg/m2 d 3–5ConcurrentSCC and adenocarcinoma5660199945.6 Gy, 1.2 Gy/fraction over 28 dTwo cycles: cisplatin 60 mg/m2 d 1; 5-fluorouracil 1000 mg/m2 d 3–5ConcurrentSCC10125Chemotherapy1982—Two cycles: cisplatin 120 mg/m2 d 1; vindesine 3 mg/m2 d 1, 8; bleomycin 10 U/m2 d 3–6—SCC39201983—Two cycles: cisplatin 20 mg/m2 d 1–5; bleomycin 5 mg/m2 d 1–5—SCC10618a1988c—Three cycles: cisplatin 20 mg/m2 d 1–5; 5-fluorouracil 1000 mg/m2 d 1–5—SCC46751988—Two cycles: cisplatin 100 mg/m2 d 1; bleomycin 10 mg/m2 d 3–8; vinblastine 3 mg/m2 d 1, 8—SCC4617a1989—Two cycles: cisplatin 100 mg/m2 d 1; 5-fluorouracil 1000 mg/m2 d 1–5—SCC147171990—Two cycles: cisplatin 80 mg/m2 d 1; etoposide 200 mg/m2 d 1–5—SCC16019a1990—Three cycles: cisplatin 100 mg/m2 1; 5-fluorouracil 1000 mg/m2 days 1–5—SCC and adeno-carcinoma467561992—Two cycles: cisplatin 100 mg/m2 d 1; 5-fluorouracil 1000 mg/m2 d 1–5—SCC96241992—Two cycles: cisplatin 80 mg/m2 d 1; 5-fluorouracil 1000 mg/m2 d 1–4—SCC and adeno-carcinoma80237aEstimated as median survival.bUnpublished thesis.cYear of activation not reported, but imputed.dOnly available as an abstract.SCC = squamous cell carcinoma.Reproduced with permission from Gebski V, Burmeister B, Smithers BM, et al: Survival benefits from neoadjuvant chemoradiotherapy or chemotherapy in oesophageal carcinoma: a meta-analysis, Lancet Oncol. 2007 Mar;8(3):226-234.Brunicardi_Ch25_p1009-p1098.indd 107901/03/19 6:05 PM 1080SPECIFIC CONSIDERATIONSPART IITable 25-14Results of the meta-analysis applied to effects of preoperative chemoradiotherapy and chemotherapy on 2-y survival for patients with various levels of riskRISK GROUP2-Y SURVIVAL RATE (%)EXPECTED 2-Y MORTALITYCONTROL (%)TREATEDa (%)ARR (%)NNTChemoradiotherapyHigh208064.815.27Medium356552.712.38Low505040.59.510ChemotherapyHigh208072.012.08Medium356558.56.515Low505045.05.020aBased on a 19% relative mortality reduction for those receiving concurrent chemoradiotherapy and a 10% relative mortality reduction for those receiving chemotherapy.ARR = absolute risk reduction; NNT = number needed to treat to prevent one death.Reproduced with permission from Gebski V, Burmeister B, Smithers BM, et al: Survival benefits from neoadjuvant chemoradiotherapy or chemotherapy in oesophageal carcinoma: a meta-analysis, Lancet Oncol. 2007 Mar;8(3):226-234.success and the tumors remain superficial, with local invasion or distant metastases occurring late in the course of the disease. As with carcinoma, the absence of both wall penetration and LN metastases is necessary for curative treatment, and surgi-cal resection is consequently responsible for the majority of the reported 5-year survivals. Resection also provides an excellent means of palliating the patient’s symptoms. The surgical tech-nique for resection and the subsequent restoration of the GI con-tinuity is similar to that described for carcinoma.In these authors’ experience, four of the eight patients with carcinosarcoma survived for 5 years or longer. Even though this number is small, it suggests that resection produces better Table 25-15Results of neoadjuvant therapy in adenocarcinoma of the esophagusINSTITUTIONYEARNO. OF PATIENTSREGIMENCOMPLETE PATHOLOGIC RESPONSE (%)SURVIVALMD Anderson199035P, E, 5-FU342% at 3 ySLMC199218P, 5-FU, RT1740% at 3 yVanderbilt199339P, E, 5-FU, RT1947% at 4 yMichigan199321P, VBL, 5-FU, RT2434% at 5 yMGH199416P, 5-FU042% at 4 yMGH199422E, A, P558% at 2 yA = doxorubicin; E = etoposide; 5-FU = 5-fluorouracil; MGH = Massachusetts General Hospital; P = cisplatin; RT = radiation therapy; SLMC = St. Louis University Medical Center; VBL = vinblastine.Reproduced with permission from Wright CD, Mathisen DJ, Wain JC, et al: Evolution of treatment strategies for adenocarcinoma of the esophagus and gastroesophageal junction, Ann Thorac Surg. 1994 Dec;58(6):1574-1578.results in epithelial carcinoma with spindle cell features than in squamous cell carcinoma of the esophagus. Similarly, with leiomyosarcoma of the esophagus, the same scattered reports exist with little information on survival. Of seven patients with leiomyosarcoma, two died from their disease—one in 3 months and the other 4 years and 7 months after resection. The other five patients were reported to have survived more than 5 years.It is difficult to evaluate the benefits of resection for leio-myoblastoma of the esophagus because of the small number of reported patients with tumors in this location. Most leiomyo-blastomas occur in the stomach, and 38% of these patients suc-cumb to the cancer in 3 years. Fifty-five percent of patients with extragastric leiomyoblastoma also die from the disease, within an average of 3 years. Consequently, leiomyoblastoma should be considered a malignant lesion and apt to behave like a leiomyosarcoma. The presence of nuclear hyperchromatism, increased mitotic figures (more than one per high-power field), tumor size larger than 10 cm, and clinical symptoms of longer than 6 months’ duration are associated with a poor prognosis.BENIGN TUMORS AND CYSTSBenign tumors and cysts of the esophagus are relatively uncom-mon. From the perspectives of both the clinician and the patholo-gist, benign tumors may be divided into those that are within the muscular wall and those that are within the lumen of the esophagus.Intramural lesions are either solid tumors or cysts, and the vast majority are leiomyomas. They are made up of varying por-tions of smooth muscle and fibrous tissue. Fibromas, myomas, fibromyomas, and lipomyomas are closely related and occur rarely. Other histologic types of solid intramural tumors have been described, such as lipomas, neurofibromas, hemangiomas, osteochondromas, granular cell myoblastomas, and glomus tumors, but they are medical curiosities.Intraluminal lesions are polypoid or pedunculated growths that usually originate in the submucosa, develop mainly into the lumen, and are covered with normal stratified squamous epi-thelium. The majority of these tumors are composed of fibrous tissue of varying degrees of compactness with a rich vascular supply. Some are loose and myxoid (e.g., myxoma and myxo-fibroma), some are more collagenous (e.g., fibroma), and some contain adipose tissue (e.g., fibrolipoma). These different types of tumor are frequently collectively designated fibrovascular Brunicardi_Ch25_p1009-p1098.indd 108001/03/19 6:05 PM 1081ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Barium swallow, endoscopyTumor staging(CT chest and abdomen,endoscopic ultrasonography)Late disease orsignificant comorbidityDistant organ metastasisImminent cardiac pulmonary or hepatic failureSevere debilityAdvanced diseaseSupportive careCurativeen bloc resectionPalliative surgeryLocal recurrenceNo metastasesComplete excisionpossibleUnresectable proximalor bleeding tumorLaser ablative therapyStentAirway fistula orunresectable primarytumor or localrecurrenceChemotherapyEarly diseaseTumor suspected notto be through the wall and/or less than8 lymph nodes involvedThrough the wall and multiplelymph node metastasisAdvanced diseaseChemoradiationPreoperative chemoradiation followed by en bloc resectionClinical evaluationTreatment failure orrecurrenceDistant metastasisNo local recurrenceFigure 25-70. Suggested global algorithm for the management of carcinoma of the esophagus. CT = computed tomography.polyps, or simply as polyps. Pedunculated intraluminal tumors should be removed. If the lesion is not too large, endoscopic removal with a snare is feasible.LeiomyomaLeiomyomas constitute more than 50% of benign esophageal tumors. The average age at presentation is 38, which is in sharp contrast to that seen with esophageal carcinoma. Leiomyomas are twice as common in males. Because they originate in smooth muscle, 90% are located in the lower two-thirds of the esophagus. They are usually solitary, but multiple tumors have been found on occasion. They vary greatly in size and shape. Actually, tumors as small as 1 cm in diameter and as large as 10 lb have been removed.Typically, leiomyomas are oval. During their growth, they remain intramural, having the bulk of their mass protruding toward the outer wall of the esophagus. The overlying mucosa is freely movable and normal in appearance. Dysphagia and pain are the most common complaints, the two symptoms occurring more frequently together than separately. Bleeding directly related to the tumor is rare, and when hematemesis or melena occur in a patient with an esophageal leiomyoma, other causes should be investigated.A barium swallow is the most useful method to demon-strate a leiomyoma of the esophagus (Fig. 25-73). In profile, the tumor appears as a smooth, semilunar, or crescent-shaped filling defect that moves with swallowing, is sharply demarcated, and is covered and surrounded by normal mucosa. Esophagoscopy should be performed to exclude the reported observation of a coexistence with carcinoma. The freely movable mass, which bulges into the lumen, should not be biopsied because of an increased chance of mucosal perforation at the time of surgical enucleation. Endoscopic ultrasound is also a useful adjunct in the workup of leiomyoma and provides detail related to the ana-tomic extent and relationship to surrounding structures.Despite their slow growth and limited potential for malig-nant degeneration, leiomyomas should be removed unless there are specific contraindications. The majority can be removed by simple enucleation. If, during removal, the mucosa is inadver-tently entered, the defect can be repaired primarily. After tumor removal, the outer esophageal wall should be reconstructed by closure of the muscle layer. The location of the lesion and the Brunicardi_Ch25_p1009-p1098.indd 108101/03/19 6:05 PM 1082SPECIFIC CONSIDERATIONSPART IIABFigure 25-71. A. Computed tomographic scan of a leiomyosarcoma (black arrow) that caused compression of the heart and symptoms of syncope. B. Surgical specimen of leiomyosarcoma shown in A with a pedunculated luminal lesion (white arrow) and a large extraesophageal component (black arrow). There was no evidence of lymph node metastasis at the time of operation.ABFigure 25-72. A. Barium swallow showing a large polypoid intraluminal esophageal mass causing partial obstruction and dilation of the proximal esophagus. B. Operative specimen showing 9-cm polypoid leiomyoblastoma.Brunicardi_Ch25_p1009-p1098.indd 108201/03/19 6:05 PM 1083ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25extent of surgery required will dictate the approach. Lesions of the proximal and middle esophagus require a right thoracotomy, whereas distal esophageal lesions require a left thoracotomy. Vid-eothoracoscopic and laparoscopic approaches are now frequently used. The mortality rate associated with enucleation is low, and success in relieving the dysphagia is near 100%. Large lesions or those involving the GEJ may require esophageal resection.Esophageal CystCysts may be congenital or acquired. Congenital cysts are lined wholly or partly by columnar ciliated epithelium of the respiratory type, by glandular epithelium of the gastric type, by squamous epithelium, or by transitional epithelium. In some, epithelial lining cells may be absent. Confusion over the embry-ologic origin of congenital cysts has led to a variety of names, such as enteric, bronchogenic, duplication, and mediastinal cysts. Acquired retention cysts also occur, probably as a result of obstruction of the excretory ducts of the esophageal glands.Enteric and bronchogenic cysts are the most common, and they arise as a result of developmental abnormalities dur-ing the formation and differentiation of the lower respiratory tract, esophagus, and stomach from the foregut. During its embryologic development, the esophagus is lined successively with simple columnar, pseudostratified ciliated columnar, and, finally, stratified squamous epithelium. This sequence probably accounts for the fact that the lining epithelium may be any or a combination of these; the presence of cilia does not necessarily indicate a respiratory origin.Cysts vary in size from small to very large, and they are usually located intramurally in the middleto lower-third of the esophagus. Their symptoms are similar to those of a leio-myoma. The diagnosis similarly depends on radiographic, endoscopic, and endosonographic findings. Surgical excision by enucleation is the preferred treatment. During removal, a fistulous tract connecting the cysts to the airways should be sought, particularly in patients who have had repetitive bron-chopulmonary infections.ESOPHAGEAL PERFORATIONPerforation of the esophagus constitutes a true emergency. It most commonly occurs following diagnostic or therapeutic pro-cedures. Spontaneous perforation, referred to as Boerhaave’s syndrome, accounts for only 15% of cases of esophageal per-foration, foreign bodies for 14%, and trauma for 10%. Pain is a striking and consistent symptom and strongly suggests that an esophageal rupture has occurred, particularly if located in the cervical area following instrumentation of the esophagus, or sub-sternally in a patient with a history of resisting vomiting. If sub-cutaneous emphysema is present, the diagnosis is almost certain.Spontaneous rupture of the esophagus is associated with a high mortality rate because of the delay in recognition and treat-ment. Although there usually is a history of resisting vomiting, in a small number of patients, the injury occurs silently, without any antecedent history. When the chest radiogram of a patient with an esophageal perforation shows air or an effusion in the pleural space, the condition is often misdiagnosed as a pneumo-thorax or pancreatitis. An elevated pleural amylase caused by the extrusion of saliva through the perforation may fix the diag-nosis of pancreatitis in the mind of an unwary physician. If the chest radiogram is normal, a mistaken diagnosis of myocardial infarction or dissecting aneurysm is often made.Spontaneous rupture usually occurs into the left pleural cavity or just above the GEJ. About 50% of patients have concomitant GERD, suggesting that minimal resistance to the transmission of abdominal pressure into the thoracic esophagus is a factor in the pathophysiology of the lesion. During vomiting, high peaks of intragastric pressure can be recorded, frequently exceeding 200 mmHg, but because extragastric pressure remains almost equal to intragastric pressure, stretching of the gastric wall is minimal. The amount of pressure transmitted to the esophagus varies considerably, depending on the position of the GEJ. When it is in the abdomen and exposed to intra-abdominal pressure, the pressure transmitted to the esophagus is much less than when it is exposed to the negative thoracic pressure. In the latter situation, the pressure in the lower esophagus will frequently equal intragastric pressure if the glottis remains closed. Cadaver studies have shown that when this pressure exceeds 150 mmHg, rupture of the esophagus is apt to occur. When a hiatal hernia is present and the sphincter remains exposed to abdominal pressure, the lesion produced is usually a Mallory-Weiss mucosal tear, and bleeding rather than perforation is the problem. This is due to the stretching of the supradiaphragmatic portion of the gastric wall. In this situation, the hernia sac represents an extension of the abdominal cavity, and the GEJ remains exposed to abdominal pressure.DiagnosisAbnormalities on the chest radiogram can be variable and should not be depended upon to make the diagnosis. This is because the abnormalities are dependent on three factors: (a) the time interval between the perforation and the radiographic examination, (b) the site of perforation, and (c) the integrity of the mediastinal pleura. Mediastinal emphysema, a strong indica-tor of perforation, takes at least 1 hour to be demonstrated and is present in only 40% of patients. Mediastinal widening second-ary to edema may not occur for several hours. The site of perfo-ration also can influence the radiographic findings. In cervical perforation, cervical emphysema is common and mediastinal emphysema rare; the converse is true for thoracic perforations. Figure 25-73. Barium esophagogram showing a classical, smooth, contoured, punched-out defect of a leiomyoma.Brunicardi_Ch25_p1009-p1098.indd 108301/03/19 6:05 PM 1084SPECIFIC CONSIDERATIONSPART IIFrequently, air will be visible in the erector spinae muscles on a neck radiogram before it can be palpated or seen on a chest radiogram (Fig. 25-74). The integrity of the mediastinal pleura influences the radiographic abnormality in that rupture of the pleura results in a pneumothorax, a finding that is seen in 77% of patients. In two-thirds of patients, the perforation is on the left side; in one-fifth, it is on the right side; and in one-tenth, it is bilateral. If pleural integrity is maintained, mediastinal emphy-sema (rather than a pneumothorax) appears rapidly. A pleural effusion secondary to inflammation of the mediastinum occurs late. In 9% of patients, the chest radiogram is normal.The diagnosis is confirmed with a contrast esophagram, which will demonstrate extravasation in 90% of patients. The use of a water-soluble medium such as Gastrografin is preferred. Of concern is that there is a 10% false-negative rate. This may be due to obtaining the radiographic study with the patient in the upright position. When the patient is upright, the passage of water-soluble contrast material can be too rapid to demonstrate a small perforation. The studies should be done with the patient in the right lateral decubitus position (Fig. 25-75). In this, the contrast material fills the entire length of the esophagus, allow-ing the actual site of perforation and its interconnecting cavities to be visualized in almost all patients.ManagementThe key to optimum management is early diagnosis. The most favorable outcome is obtained following primary closure of the perforation within 24 hours, resulting in 80% to 90% survival. Figure 25-76 is an operative photograph taken through a left thoracotomy of an esophageal rupture following a pneumatic dilation for achalasia. The most common location for the injury is the left lateral wall of the esophagus, just above the GEJ. Figure 25-74. Chest radiogram showing air in the deep muscles of the neck following perforation of the esophagus (arrow). This is often the earliest sign of perforation and can be present without evidence of air in the mediastinum.Figure 25-75. Radiographic study of a patient with a perforation of the esophagus using water-soluble contrast material. The patient is placed in the lateral decubitus position with the left side up to allow complete filling of the esophagus and demonstration of the defect.Figure 25-76. Left thoracotomy in a patient with an esophageal rupture at the gastroesophageal junction following forceful dila-tion of the lower esophagus for achalasia (the surgical clamp is on the stomach, and the Penrose drain encircles the esophagus). The injury consists of a mucosal perforation and extensive splitting of the esophageal muscle from just below the Penrose drain to the stomach.To get adequate exposure of the injury, a dissection similar to that described for esophageal myotomy is performed. A flap of stomach is pulled up and the soiled fat pad at the GEJ is removed. The edges of the injury are trimmed and closed pri-marily (Fig. 25-77). The closure is reinforced with the use of a pleural patch or construction of a Nissen fundoplication.Mortality associated with immediate closure varies between 8% and 20%. After 24 hours, survival decreases to <50%, and is not influenced by the type of operative therapy (i.e., drainage alone or drainage plus closure of the perforation). If the time delay before closing a perforation approaches 24 hours and the tissues are inflamed, division of the cardia and resection of the diseased portion of the esophagus are recommended. The remainder of the esophagus is mobilized, and as much normal esophagus as pos-sible is saved and brought out as an end cervical esophagostomy. In some situations, the retained esophagus may be so long that Brunicardi_Ch25_p1009-p1098.indd 108401/03/19 6:05 PM 1085ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25it loops down into the chest. The contaminated mediastinum is drained and a feeding jejunostomy tube is inserted. The recov-ery from sepsis is often immediate, dramatic, and reflected by a marked improvement in the patient’s condition over a 24-hour period. On recovery from the sepsis, the patient is discharged and returns on a subsequent date for reconstruction with a substernal colon interposition. Failure to apply this aggressive therapy can result in a mortality rate in excess of 50% in patients in whom the diagnosis has been delayed.Nonoperative management of esophageal perforation has been advocated in select situations. The choice of conserva-tive therapy requires skillful judgment and necessitates care-ful radiographic examination of the esophagus. This course of management usually follows an injury occurring during dila-tion of esophageal strictures or pneumatic dilations of achalasia. Conservative management should not be used in patients who have free perforations into the pleural space. Cameron proposed three criteria for the nonoperative management of esophageal perforation: (a) the esophagram must show the perforation to be contained within the mediastinum and drain well back into the esophagus (Fig. 25-78), (b) symptoms should be mild, and (c) there should be minimal evidence of clinical sepsis. If these Figure 25-77. The technique of closure of an esophageal perfora-tion through a left thoracotomy. A. A tongue of stomach is pulled up through the esophageal hiatus, and the gastroesophageal fat pad is removed; the edges of the mucosal injury are trimmed and closed using interrupted modified Gambee stitches. B. Reinforcement of the closure with a parietal pleural patch.conditions are met, it is reasonable to treat the patient with hyper-alimentation, antibiotics, and cimetidine to decrease acid secre-tion and diminish pepsin activity. Oral intake is resumed in 7 to 14 days, dependent on subsequent radiographic examinations.MALLORY-WEISS SYNDROMEIn 1929, Mallory and Weiss described four patients with acute upper GI bleeding who were found at autopsy to have mucosal tears at the GEJ. This syndrome, characterized by acute upper GI bleeding following vomiting, is considered to be the cause of up to 15% of all severe upper GI bleeds. The mechanism is similar to spontaneous esophageal perforation: an acute increase in intra-abdominal pressure against a closed glottis in a patient with a hiatal hernia.Mallory-Weiss tears are characterized by arterial bleeding, which may be massive. Vomiting is not an obligatory factor, as there may be other causes of an acute increase in intra-abdominal pressure, such as paroxysmal coughing, seizures, and retching. The diagnosis requires a high index of suspicion, par-ticularly in the patient who develops upper GI bleeding follow-ing prolonged vomiting or retching. Upper endoscopy confirms the suspicion by identifying one or more longitudinal fissures in the mucosa of the herniated stomach as the source of bleeding.In the majority of patients, the bleeding will stop sponta-neously with nonoperative management. In addition to blood replacement, the stomach should be decompressed and anti-emetics administered, as a distended stomach and continued vomiting aggravate further bleeding. A Sengstaken-Blakemore tube will not stop the bleeding, as the pressure in the balloon is not sufficient to overcome arterial pressure. Endoscopic injec-tion of epinephrine may be therapeutic if bleeding does not stop spontaneously. Only occasionally will surgery be required to stop blood loss. The procedure consists of laparotomy and high gastrotomy with oversewing of the linear tear. Mortality is uncommon, and recurrence is rare.Figure 25-78. Barium esophagogram showing a stricture and a contained perforation following dilation. The injury meets Cameron criteria: It is contained within the mediastinum and drawn back into the esophagus, the patient had mild symptoms, and there was no evidence of clinical sepsis. Nonoperative management was successful.Brunicardi_Ch25_p1009-p1098.indd 108501/03/19 6:05 PM 1086SPECIFIC CONSIDERATIONSPART IITable 25-16Endoscopic grading of corrosive esophageal and gastric burnsFirst degree: Mucosal hyperemia and edemaSecond degree: Limited hemorrhage, exudate ulceration, and pseudomembrane formationThird degree: Sloughing of mucosa, deep ulcers, massive hemorrhage, complete obstruction of lumen by edema, charring, and perforationTable 25-17Location of caustic injury (n = 62)Pharynx10%Esophagus70% Upper15% Middle65% Lower2% Whole18%Stomach20% Antral91% Whole9%Both stomach and esophagus14%CAUSTIC INJURYAccidental caustic lesions occur mainly in children, and, in general, rather small quantities of caustics are taken. In adults or teenagers, the swallowing of caustic liquids is usually deliberate, during a suicide attempt, and greater quantities are swallowed. Alkalis are more frequently swallowed accidentally than acids, because strong acids cause an immediate burning pain in the mouth.PathologyThe swallowing of caustic substances causes an acute and a chronic injury. During the acute phase, care focuses on con-trolling the immediate tissue injury and the potential for per-foration. During the chronic phase, the focus is on treatment of strictures and disturbances in pharyngeal swallowing. In the acute phase, the degree and extent of the lesion are dependent on several factors: the nature of the caustic substance, its con-centration, the quantity swallowed, and the time the substance is in contact with the tissues.Acids and alkalis affect tissue in different ways. Alkalis dissolve tissue, and therefore penetrate more deeply, while acids cause a coagulative necrosis that limits their penetration. Animal experiments have shown that there is a correlation between the depth of the lesion and the concentration of sodium hydroxide solution. When a solution of 3.8% comes into contact with the esophagus for 10 seconds, it causes necrosis of the mucosa and the submucosa but spares the muscular layer. A concentration of 22.5% penetrates the whole esophageal wall and into the periesophageal tissues. Cleansing products can contain up to 90% sodium hydroxide. The strength of esophageal contractions varies according to the level of the esophagus, being weakest at the striated muscle–smooth muscle interface. Consequently, clearance from this area may be somewhat slower, allowing caustic substances to remain in contact with the mucosa longer. This explains why the esophagus is preferentially and more severely affected at this level than in the lower portions.The lesions caused by lye injury occur in three phases. First is the acute necrotic phase, lasting 1 to 4 days after injury. During this period, coagulation of intracellular proteins results in cell necrosis, and the living tissue surrounding the area of necrosis develops an intense inflammatory reaction. Second is the ulcer-ation and granulation phase, starting 3 to 5 days after injury. During this period, the superficial necrotic tissue sloughs, leav-ing an ulcerated, acutely inflamed base, and granulation tissue fills the defect left by the sloughed mucosa. This phase lasts 10 to 12 days, and it is during this period that the esophagus is the weakest. Third is the phase of cicatrization and scarring, which begins the third week following injury. During this period, the previously formed connective tissue begins to contract, result-ing in narrowing of the esophagus. Adhesions between granulat-ing areas occur, resulting in pockets and bands. It is during this period that efforts must be made to reduce stricture formation.Clinical ManifestationsThe clinical picture of an esophageal burn is determined by the degree and extent of the lesion. In the initial phase, complaints consist of pain in the mouth and substernal region, hypersali-vation, pain on swallowing, and dysphagia. The presence of fever is strongly correlated with the presence of an esopha-geal lesion. Bleeding can occur, and, frequently, the patient vomits. These initial complaints disappear during the quiescent period of ulceration and granulation. During the cicatrization and scarring phase, the complaint of dysphagia reappears and is due to fibrosis and retraction, resulting in narrowing of the esophagus. Of the patients who develop strictures, 60% do so within 1 month, and 80% within 2 months. If dysphagia does not develop within 8 months, it is unlikely that a stricture will occur. Serious systemic reactions such as hypovolemia and acidosis resulting in renal damage can occur in cases in which the burns have been caused by strong acids. Respiratory com-plications such as laryngospasm, laryngoedema, and occasion-ally pulmonary edema can occur, especially when strong acids are aspirated.Inspection of the oral cavity and pharynx can indicate that caustic substances were swallowed, but does not reveal that the esophagus has been burned. Conversely, esophageal burns can be present without apparent oral injuries. Because of this poor correlation, early esophagoscopy is advocated to establish the presence of an esophageal injury. To lessen the chance of perfo-ration, the scope should not be introduced beyond the proximal esophageal lesion. The degree of injury can be graded according to the criteria listed in Table 25-16. Even if the esophagoscopy is normal, strictures may appear later. Radiographic examina-tion is not a reliable means to identify the presence of early esophageal injury, but it is important in later follow-up to iden-tify strictures. The most common locations of caustic injuries are shown in Table 25-17.TreatmentTreatment of a caustic lesion of the esophagus is directed toward management of both the immediate and late consequences of the injury. The immediate treatment consists of limiting the burn by administering neutralizing agents. To be effective, this must be done within the first hour. Lye or other alkali can be neutralized with half-strength vinegar, lemon juice, or orange juice. Acid can be neutralized with milk, egg white, or antacids. Sodium bicarbonate is not used because it generates carbon dioxide, Brunicardi_Ch25_p1009-p1098.indd 108601/03/19 6:05 PM 1087ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25which might increase the danger of perforation. Emetics are contraindicated because vomiting renews the contact of the caustic substance with the esophagus and can contribute to perforation if too forceful. Hypovolemia is corrected, and broad-spectrum antibiotics are administered to lessen the inflammatory reaction and prevent infectious complications. If necessary, a feeding jejunostomy tube is inserted to provide nutrition. Oral feeding can be started when the dysphagia of the initial phase has regressed.In the past, surgeons waited until the appearance of a stric-ture before starting treatment. Currently, dilations are started the first day after the injury, with the aim of preserving the esophageal lumen by removing the adhesions that occurred in the injured segments. However, this approach is controversial in that dilations can traumatize the esophagus, causing bleed-ing, and perforation, and there are data indicating that exces-sive dilations cause increased fibrosis secondary to the added trauma. The use of steroids to limit fibrosis has been shown to be effective in animals, but their effectiveness in human beings has not been established.Extensive necrosis of the esophagus frequently leads to perforation, and it is best managed by resection. When there is extensive gastric involvement, the esophagus is nearly always necrotic or severely burned, and total gastrectomy and near-total esophagectomy are necessary. The presence of air in the esopha-geal wall is a sign of muscle necrosis and impending perforation and is a strong indication for esophagectomy.Management of acute injury is summarized in the algo-rithm in Fig. 25-79. Some authors have advocated the use of an intraluminal esophageal stent (Fig. 25-80) in patients who are operated on and found to have no evidence of extensive esophagogastric necrosis. In these patients, a biopsy of the posterior gastric wall should be performed to exclude occult injury. If, histologically, there is a question of viability, a second-look operation should be done within 36 hours. If a stent is inserted, it should be kept in position for 21 days, and removed after a satisfactory barium esophagogram. Esopha-goscopy should be done, and if strictures are present, dilations initiated.Once the acute phase has passed, attention is turned to the prevention and management of strictures. Both antegrade dilation with a Hurst or Maloney bougie and retrograde dila-tion with a Tucker bougie have been satisfactory. In a series of 1079 patients, early dilations started during the acute phase gave excellent results in 78%, good results in 13%, and poor results in 2%. During the treatment, 55 patients died. In contrast, of 333 patients whose strictures were dilated when they became symptomatic, only 21% had excellent results, 46% good, and 6% poor, with three dying during the process. The length of time the surgeon should persist with dilation before consideration of esophageal resection is problematic. An adequate lumen should be re-established within 6 months to 1 year, with progressively longer intervals between dilations. If, during the course of treat-ment, an adequate lumen cannot be established or maintained (i.e., smaller bougies must be used), operative intervention should be considered. Surgical intervention is indicated when there is (a) complete stenosis in which all attempts from above and below have failed to establish a lumen, (b) marked irregu-larity and pocketing on barium swallow, (c) the development of a severe periesophageal reaction or mediastinitis with dilatation, (d) a fistula, (e) the inability to dilate or maintain the lumen above a 40F bougie, or (f) a patient who is unwilling or unable to undergo prolonged periods of dilation.Ingestion of caustic agentObservation24–48 hoursExploratorylaparotomySecond lookat 36 hoursIntraluminal esophageal stentPosterior gastric wall biopsyJejunostomy1° burn2° & 3° burnEsophagogastric resectionCervical esophagostomyJejunostomyResection of adjacent involved organsFull thicknessnecrosisof esophagusand stomachViableesophagusandstomachQuestionableesophagusandstomach Esophagoscopy(Within 12 hours)Figure 25-79. Algorithm summarizing the management of acute caustic injury.Figure 25-80. The use of an esophageal stent to prevent stricture. The stent is constructed from a chest tube and placed in the esopha-gus at the time of an exploratory laparotomy. A Penrose drain is placed over the distal end as a flap valve to prevent reflux. The stent is supported at its upper end by attaching it to a suction catheter that is secured to the nares. Continuous suction removes saliva and mucus trapped in the pharynx and upper esophagus.Brunicardi_Ch25_p1009-p1098.indd 108701/03/19 6:05 PM 1088SPECIFIC CONSIDERATIONSPART IIThe variety of abnormalities seen requires that creativity be used when considering esophageal reconstruction. Skin tube esophagoplasties are now used much less frequently than they were in the past, and are mainly of historical interest. Currently, the stomach, jejunum, and colon are the organs used to replace the esophagus, through either the posterior mediastinum or the retrosternal route. A retrosternal route is chosen when there has been a previous esophagectomy or there is extensive fibrosis in the posterior mediastinum. When all factors are considered, the order of preference for an esophageal substitute is (a) colon, (b) stomach, and (c) jejunum. Free jejunal grafts based on the supe-rior thyroid artery have provided excellent results. Whatever method is selected, it must be emphasized that these procedures cannot be taken lightly; minor errors of judgment or technique may lead to serious or even fatal complications.Critical in the planning of the operation is the selection of cervical esophagus, pyriform sinus, or posterior pharynx as the site for proximal anastomosis. The site of the upper anastomosis depends on the extent of the pharyngeal and cervical esophageal damage encountered. When the cervical esophagus is destroyed and a pyriform sinus remains open the anastomosis can be made to the hypopharynx (Fig. 25-81). When the pyriform sinuses are completely stenosed, a transglottic approach is used to perform an anastomosis to the posterior oropharyngeal wall (Fig. 25-82). This allows excision of supraglottic strictures and elevation and anterior tilting of the larynx. In both of these situations, the patient must relearn to swallow. Recovery is long and difficult and may require several endoscopic dilations—and often reop-erations. Sleeve resections of short strictures are not successful because the extent of damage to the wall of the esophagus can be greater than realized, and almost invariably the anastomosis is carried out in a diseased area.The management of a bypassed damaged esophagus after injury is problematic. If the esophagus is left in place, ulcer-ation from gastroesophageal reflux or the development of carcinoma must be considered. The extensive dissection neces-sary to remove the esophagus, particularly in the presence of marked periesophagitis, is associated with significant morbidity. Leaving the esophagus in place preserves the function of the Figure 25-82. Anastomosis of the bowel to the posterior orophar-ynx. The anastomosis is done through an inverted trapezoid incision above the thyroid cartilage (dotted line). A triangle-shaped piece of the upper half of the cartilage is resected. Closure of the oropharynx is done so that the larynx is pulled up (sagittal section).Figure 25-81. Anastomosis of the bowel to a preserved pyriform sinus. To identify the site, a finger is inserted into the free pyriform sinus through a suprahyoid incision (dotted line). This requires removing the lateral inferior portion of the thyroid cartilage as shown in cross-section.vagus nerves, and, in turn, the function of the stomach. On the other hand, leaving a damaged esophagus in place can result in multiple blind sacs and subsequent development of medias-tinal abscesses years later. Most experienced surgeons recom-mend that the esophagus be removed unless the operative risk is unduly high.ACQUIRED FISTULAThe esophagus lies in close contact with the membranous por-tion of the trachea and left bronchus, predisposing to the for-mation of fistula to these structures. Most acquired esophageal fistulas are to the tracheobronchial tree and secondary to either esophageal or pulmonary malignancy. Traumatic fistulas and those associated with esophageal diverticula account for the remainder. Fistulas associated with traction diverticula are usu-ally due to mediastinal inflammatory disease, and traumatic fistulas usually occur secondary to penetrating wounds, lye ingestion, or iatrogenic injury.These fistulas are characterized by paroxysmal cough-ing following the ingestion of liquids, and by recurrent or chronic pulmonary infections. The onset of cough immediately after swallowing suggests aspiration, whereas a brief delay (30–60 seconds) suggests a fistula.Spontaneous closure is rare, owing to the presence of malignancy or a recurrent infectious process. Surgical treat-ment of benign fistulas consists of division of the fistulous tract, resection of irreversibly damaged lung tissue, and closure of the esophageal defect. To prevent recurrence, a pleural flap should be interposed. Treatment of malignant fistulas is difficult, par-ticularly in the presence of prior irradiation. Generally, only palliative treatment is indicated. This can best be done by using a specially designed esophageal endoprosthesis that bridges and occludes the fistula, allowing the patient to eat. A salivary tube is also a good option for proximal esophageal fistulas. This tube has a proximal “lip” that rests on the cricopharyngeal muscle and thereby directs the saliva into the tube and past the fis-tula. Rarely, esophageal diversion, coupled with placement of a feeding jejunostomy, can be used as a last resort.Brunicardi_Ch25_p1009-p1098.indd 108801/03/19 6:05 PM 1089ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25of the internal mammary artery and the internal mammary or innominate vein. Removal of the sternoclavicular joint aids in performing the vascular and distal esophageal anastomosis (Fig. 25-83).Reconstruction After Total EsophagectomyNeither the intrathoracic stomach nor the intrathoracic colon functions as well as the native esophagus after an esophagogas-trectomy. The choice between these organs will be influenced by several factors, such as the adequacy of their blood supply and the length of resected esophagus that they are capable of bridging. If the stomach shows evidence of disease, or has been contracted or reduced by previous gastric surgery, the length available for esophageal replacement may not be adequate. The presence of diverticular disease, unrecognized carcinoma, or colitis prohibits the use of the colon. The blood supply of the colon is more affected by vascular disease than the blood supply of the stomach, which may prevent its use. Of the two, the colon provides the longest graft. The stomach can usually reach to the neck if the amount of lesser curvature resected does not interfere with the blood supply to the fundus. Gastric interposition has the advantage that only one anastomosis is required. On the other hand, there is greater potential for aspiration of gastric juice or stricture of the cervical anastomosis from chronic reflux when stomach is used for replacement.Following an esophagogastrectomy, patients may have discomfort during or shortly after eating. The most common symptom is a postprandial pressure sensation or a feeling of being full, which probably results from the loss of the gastric reservoir. This symptom is less common when the colon is used as an esophageal substitute, probably because the distal third of the stomach is retained in the abdomen and the interposed colon provides an additional reservoir function.King and Hölscher have reported a 40% and 50% inci-dence of dysphagia after reestablishing GI continuity with the stomach following esophagogastrectomy. This incidence is similar to Orringer’s results after using the stomach to replace the esophagus in patients with benign disease. More than one-half of the patients experienced dysphagia postoperatively; TECHNIQUES OF ESOPHAGEAL RECONSTRUCTIONOptions for esophageal substitution include gastric advance-ment, colonic interposition, and either jejunal free transfer or advancement into the chest. Rarely, combinations of these grafts will be the only possible option. The indications for esopha-geal resection and substitution include malignant and end-stage benign disease. The latter includes refluxor drug-induced stricture formation that cannot be dilated without damage to the esophagus, a dilated and tortuous esophagus secondary to severe motility disorders, lye-induced strictures, and multiple previous antireflux procedures. The choice of esophageal substitution has significant impact upon the technical difficulty of the procedure and influences the long-term outcome.Partial Esophageal ResectionDistal benign lesions, with preserved proximal esophageal func-tion, are best treated with the interposition of a segment of prox-imal jejunum into the chest and primary anastomosis. A jejunal interposition can reach to the inferior border of the pulmonary hilum with ease, but the architecture of its blood supply rarely allows the use of the jejunum proximal to this point. Because the anastomosis is within the chest, a thoracotomy is necessary.The jejunum is a dynamic graft and contributes to bolus transport, whereas the stomach and colon function more as a conduit. The stomach is a poor choice in this circumstance because of the propensity for the reflux of gastric contents into the proximal remaining esophagus following an intratho-racic esophagogastrostomy. It is now well recognized that this occurs and can lead to incapacitating symptoms and esophageal destruction in some patients. Short segments of colon, on the other hand, lack significant motility and have a propensity for the development of esophagitis proximal to the anastomosis.Replacement of the cervical portion of the esophagus, while preserving the distal portion, is occasionally indicated in cervical esophageal or head and neck malignancy, and follow-ing the ingestion of lye. Free transfer of a portion of jejunum to the neck has become a viable option and is successful in the majority of cases. Revascularization is achieved via use Figure 25-83. A. The portion of the thoracic inlet to be resected to provide space for a free jejunal graft and access to the internal mammary artery (shaded area). B. Cross-section showing the space available after resection of the sternoclavicular joint and one-half of the manubrium. (Reproduced with permission from Shields TW: General Thoracic Surgery, 3rd ed. Philadelphia, PA: Lea & Febiger; 1989.)Brunicardi_Ch25_p1009-p1098.indd 108901/03/19 6:06 PM 1090SPECIFIC CONSIDERATIONSPART IItwo-thirds of this group required postoperative dilation, and one-fourth had persistent dysphagia and required home dilation. In contrast, dysphagia is uncommon, and the need for dilation is rare following a colonic interposition. Isolauri reported on 248 patients with colonic interpositions and noted a 24% incidence of dysphagia 12 months after the operation. When it occurred, the most common cause was recurrent mediastinal tumor. The high incidence of dysphagia with the use of the stomach is prob-ably related to the esophagogastric anastomosis in the neck and the resulting difficulty of passing a swallowed bolus.Another consequence of the transposition of the stomach into the chest is the development of postoperative duodenogastric reflux, probably due to pyloric denervation, and adding a pyloroplasty may worsen this problem. Following gastric advancement, the pylorus lies at the level of the esophageal hiatus, and a distinct pressure differential develops between the intrathoracic gastric and intra-abdominal duodenal lumina. Unless the pyloric valve is extremely efficient, the pressure differential will encourage reflux of duodenal contents into the stomach. Duodenogastric reflux is less likely to occur following colonic interposition because there is sufficient intra-abdominal colon to be compressed by the abdominal pressure and the pylorus and duodenum remain in their normal intra-abdominal position.Although there is general acceptance of the concept that an esophagogastric anastomosis in the neck results in less post-operative esophagitis and stricture than one at a lower level, reflux esophagitis following a cervical anastomosis does occur, albeit at a lower rate than when the anastomosis is at a lower level. Most patients undergo cervical esophagogastrostomy for malignancy; thus, the long-term sequelae of an esophagogastric anastomosis in the neck are not of concern. However, patients who have had a cervical esophagogastrostomy for benign dis-ease may develop problems associated with the anastomosis in the fourth or fifth postoperative year that are severe enough to require anastomotic revision. This is less likely in patients who have had a colonic interposition for esophageal replace-ment. Consequently, in patients who have a benign process or a potentially curable carcinoma of the esophagus or cardia, a colonic interposition is used to obviate the late problems associ-ated with a cervical esophagogastrostomy. Colonic interposition for esophageal substitution is a more complex procedure than gastric advancement, with the potential for greater perioperative morbidity, particularly in inexperienced hands.Composite ReconstructionOccasionally, a combination of colon, jejunum, and stomach is the only reconstructive option available. This situation may arise when there has been previous gastric or colonic resection, when dysphagia has recurred after a previous esophageal resec-tion, or following postoperative complications such as ischemia of an esophageal substitute. Although not ideal, combinations of colon, jejunum, and stomach used to restore GI continuity function surprisingly well and allow alimentary reconstruction in an otherwise impossible situation.Vagal Sparing Esophagectomy With Colon InterpositionTraditional esophagectomy typically results in bilateral vagot-omy and its attendant consequences. It is likely that symptoms such as dumping, diarrhea, early satiety, and weight loss seen in 15% to 20% of patients postesophagectomy are at least in part, if not completely, due to vagal interruption. The technique of vagal sparing esophagectomy with colon interposition has been described in an effort to avoid the morbidities associated with standard esophagectomy.Through an upper midline abdominal incision, the right and left vagal nerves are identified, circled with a tape, and retracted to the right. A limited, highly selective proximal gas-tric vagotomy is performed along the cephalad 4 cm of the lesser curvature. The stomach is divided with an Endo-GIA stapler just below the GEJ. The colon is prepared to provide an interposed segment as previously described. A neck incision is made along the anterior border of the left sternocleidomastoid muscle, and the strap muscles are exposed. The omohyoid muscle is divided at its pulley, and the sternohyoid and sternothyroid muscles are divided at their manubrial insertion. The left carotid sheath is retracted laterally and the thyroid and trachea medially. The left inferior thyroid artery is ligated laterally as it passes under the left common carotid artery. The left recurrent laryngeal nerve is identified and protected. The esophagus is dissected circumfer-entially in an inferior direction, from the left neck to the apex of the right chest, to avoid injury to the right recurrent laryngeal nerve. The esophagus is divided at the level of the thoracic inlet, leaving about 3 to 4 cm of cervical esophagus. The proximal esophagus is retracted anteriorly and to the right with the use of two sutures to keep saliva and oral contents from contaminating the neck wound.Returning to the abdomen, the proximal staple line of the gastric division is opened, and the esophagus is flushed with povidone-iodine solution. A vein stripper is passed up the esophagus into the neck wound. The distal portion of the esophagus in the neck is secured tightly around the stripping cable with “endoloops” and an umbilical tape for a trailer. The tip of the stripper is exchanged for a mushroom head, and the stripper is pulled back into the abdomen, inverting the esopha-gus as it transverses the posterior mediastinum. This maneuver strips the branches of the esophageal plexus off the longitudi-nal muscle of the esophagus, preserving the esophageal plexus along with the proximal vagal nerves and the distal vagal nerve trunks. In patients with end-stage achalasia, only the mucosa is secured around the stripping cable, so that it alone is stripped and the dilated muscular wall of the esophagus, with its enriched blood supply, remains. The resulting medi-astinal tunnel, or in the case of achalasia the muscular tube, is dilated with a Foley catheter containing 90 mL of fluid in the balloon. The previously prepared interposed portion of the transverse colon is passed behind the stomach and up through the mediastinal tunnel into the neck. An end-to-end anastomo-sis is performed to the cervical esophagus using a single layer technique. The colon is pulled taut and secured to the left crus with four or five interrupted sutures. Five centimeters below the crura an opening is made in the mesentery adjacent to the colon along its mesenteric border, through which an Endo-GIA stapler is passed and the colon is divided. The proximal end, which is the distal end of the interposed colon, is anasto-mosed high on the posterior fundic wall of the stomach, using a triangular stapling anastomotic technique. This is done by stapling longitudinally the stomach and colon together with a 75-mm Endo-GIA stapler, spreading the base of the incision apart, and closing it with a T-55 stapler. Colonic continuity is reestablished by bringing the proximal right colon to the dis-tal staple line in the left colon and performing an end-to-end anastomosis using a double-layer technique.Brunicardi_Ch25_p1009-p1098.indd 109001/03/19 6:06 PM 1091ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Although conceptually appealing, preservation of vagal nerve integrity or the gastric reservoir function after vagal spar-ing esophagectomy only recently has been validated. Banki and associates compared patients undergoing vagal sparing esopha-gectomy to those with conventional esophagectomy and colon or gastric interposition. This study showed that vagal sparing esophagectomy preserved gastric secretion, gastric emptying, meal capacity, and body mass index, compared to esophagogas-trectomy with colon interposition or standard esophagectomy with gastric pull-up. Vagal sparing esophagectomy patients functioned, for the most part, similarly to normal subjects, allowing them to eat a normal meal, free of dumping or diarrhea. These results indicate that the vagal-sparing esophagectomy procedure does indeed preserve the vagal nerves, and it may be considered in the treatment of benign and early malignant lesions requiring esophagectomy.BIBLIOGRAPHYEntries highlighted in bright blue are key references.General ReferencesBalaji B, Peters JH. Minimally invasive surgery for esophageal motor disorders. Surg Clin North Am. 2002;82:763-782.Bremner CG, DeMeester TR, Bremner RM. Esophageal Motility Testing Made Easy. St. Louis: Quality Medical Publishing, 2001.Castel DW, Richter J, eds. The Esophagus. Boston: Little, Brown & Co., 1999.DeMeester SR, Peters JH, DeMeester TR. Barrett’s esophagus. Curr Probl Surg. 2001;38:549-640.Demeester SR, ed. Barrett’s esophagus. Problems in General Surgery. Vol. 18, no. 2. Hagerstown, MD: Lippincott Williams & Wilkins; 2001.DeMeester TR, Peters JH, Bremner CG, et al. Biology of gastro-esophageal reflux disease; pathophysiology relating to medical and surgical treatment. Annu Rev Med. 1999;50:469-506.Hunter JG, Pellagrini CA. Surgery of the esophagus. Surg Clin North Am. 1997;77:959-970.McFadyen BV, Arregui ME, Eubanks S, et al. Laparoscopic Surgery of the Abdomen. New York: Springer, 2003.Surgical AnatomyDaffner RH, Halber MD, Postlethwait RW, et al. CT of the esopha-gus. II. Carcinoma. AJR Am J Roentgenol. 1979;133:1051-1055.Gray SW, Rowe JS Jr, Skandalakis JE. Surgical anatomy of the gastroesophageal junction. Am Surg. 1979;45:575-587.Liebermann-Meffert D. The pharyngoesophageal segment: anat-omy and innervation. Dis Esophagus. 1995;8:242-251.Liebermann-Meffert D, Siewert JR. Arterial anatomy of the esopha-gus: a review of the literature with brief comments on clinical aspects. Gullet. 1992;2:3-10.Liebermann-Meffert DM, Meier R, Siewert JR. Vascular anat-omy of the gastric tube used for esophageal reconstruction. Ann Thorac Surg. 1992;54(6):1110-1115.Liebermann-Meffert DM, Walbrun B, Hiebert CA, et al. Recurrent and superior laryngeal nerves: a new look with implications for the esophageal surgeon. Ann Thorac Surg. 1999;67:217-223.PhysiologyBarlow AP, DeMeester TR, Ball CS, et al. The significance of the gastric secretory state in gastroesophageal reflux disease. Arch Surg. 1989;124:937-940.DeMeester TR, Lafontaine E, Joelsson BE, et al. The relation-ship of a hiatal hernia to the function of the body of the esophagus and the gastroesophageal junction. J Thorac Car-diovasc Surg. 1981;82(4):547-558.Helm JF, Dodds WJ, Pelc LR, Palmer DW, Hogan WJ, Teeter BC. Effect of esophageal emptying and saliva on clearance of acid from the esophagus. N Engl J Med. 1984;310:284-288.Joelsson BE, DeMeester TR, Skinner DB, LaFontaine E, Waters PF, O’Sullivan GC. The role of the esophageal body in the antire-flux mechanism. Surgery. 1982;92:417-424.Johnson LF, DeMeester TR. Evaluation of elevation of the head of the bed, bethanechol, and antacid foam tablets on gastroesopha-geal reflux. Dig Dis Sci. 1981;26:673-680.Kahrilas PJ, Dodds WJ, Hogan WJ. Effect of peristaltic dysfunc-tion on esophageal volume clearance. Gastroenterology. 1988;94:73-80.McCallum RW, Berkowitz DM, Lerner E. Gastric emptying in patients with gastroesophageal reflux. Gastroenterology. 1981;80:285-291.Mittal RK, Lange RC, McCallum RW. Identification and mecha-nism of delayed esophageal acid clearance in subjects with hiatus hernia. Gastroenterology. 1987;92:130-135.Rao SSC, Madipalli RS, Mujica VR, et al. Effects of age and gender on esophageal biomechanical properties and sensation. Am J Gastroenterol. 2003;98:1688-1695.Tseng D, Rizvi AZ, Fennerty MB, et al. Forty-eight-hour pH moni-toring increases sensitivity in detecting abnormal esophageal acid exposure. J Gastrointest Surg. 2005;9:1043-1051; discussion 1051.Zaninotto G, DeMeester TR, Schwizer W, et al. The lower esophageal sphincter in health and disease. Am J Surg. 1988;155:104-111.Assessment of Esophageal FunctionAdamek RJ, Wegener M, Weinbeck M, Gielen B. Long-term esoph-ageal manometry in healthy subjects: evaluation of normal values and influence of age. Dig Dis Sci. 1994;39:2069-2073.Barish CF, Castell DO, Richter JE. Graded esophageal balloon distention: a new provocative test for non-cardiac chest pain. Dig Dis Sci. 1986;31:1292-1298.Battle WS, Nyhus LM, Bombeck CT. Gastroesophageal reflux: diagnosis and treatment. Ann Surg. 1973;177:560-565.Bernstein IM, Baker CA. A clinical test for esophagitis. Gastroen-terology. 1958;34:760-781.DeMeester TR, Johnson LF, Joseph GJ, Toscano MS, Hall AW, Skinner DB. Patterns of gastroesophageal reflux in health and disease. Ann Surg. 1976;184(4):459-470.DeMeester TR, Wang CI, Wernly JA, et al. Technique, indications and clinical use of 24-hour esophageal pH monitoring. J Thorac Cardiovasc Surg. 1980;79:656-670.Dodds WJ. Current concepts of esophageal motor function: clinical implications for radiology. AJR Am J Roentgenol. 1977;128:549-561.Fein M, Fuchs KH, Bohrer T, et al. Fiberoptic technique for 24-hour bile reflux monitoring. Standards and normal values for gastric monitoring. Dig Dis Sci. 1996;41:216-225.Fuchs KH, DeMeester TR, Albertucci M. Specificity and sensitiv-ity of objective diagnosis of gastroesophageal reflux disease. Surgery. 1987;102:575-580.Iascone C, DeMeester TR, et al. Barrett’s esophagus: functional assessment, proposed pathogenesis, and surgical therapy. Arch Surg. 1983;118:543-549.Johnson LF, DeMeester TR. Development of 24-hour intra-esophageal pH monitoring composite scoring. J Clin Gastroenterol. 1986;8(suppl 1):52-58.Johnson LF, DeMeester TR. Twenty-four-hour pH monitoring of the distal esophagus: a quantitative measure of gastroesopha-geal reflux. Am J Gastroenterol. 1974;62(4):325-332.Kauer WK, Burdiles P, Ireland A, et al. Does duodenal juice reflux into the esophagus in patients with complicated GERD? Evaluation of a fiberoptic sensor for bilirubin. Am J Surg. 1995;169:98-103.Brunicardi_Ch25_p1009-p1098.indd 109101/03/19 6:06 PM 1092SPECIFIC CONSIDERATIONSPART IIKramer P, Hollander W. Comparison of experimental esopha-geal pain with clinical pain of angina pectoris and esophageal disease. Gastroenterology. 1955;29:719-743.Pandolfino JE, Richter JE, Ours T, et al. Ambulatory esophageal pH monitoring using a wireless system. Am J Gastroenterol. 2003;98:740-749.Reid BJ, Weinstein WM, Lewin KJ, et al. Endoscopic biopsy can detect high-grade dysplasia or early adenocarcinoma in Barrett’s esophagus without grossly recognizable neoplastic lesions. Gastroenterology. 1988;94(1):81-90.Schwizer W, Hinder RA, DeMeester TR. Does delayed gastric emp-tying contribute to gastroesophageal reflux disease? Am J Surg. 1989;157:74-81.Stein HJ, DeMeester TR, et al. Three-dimensional imaging of the LES in gastroesophageal reflux disease. Ann Surg. 1991;214:374-384.Tutuian R, Vela MF, Balaji NS, et al. Esophageal function test-ing with combined multichannel intraluminal impedance and manometry; multicenter study in healthy volunteers. Clin Gastroenterol Hepatol. 2003;1:174-183.Wickremesinghe PC, Bayrit PQ, Manfredi OL, et al. Quantitative evaluation of bile diversion surgery utilizing 99mTc HIDA scin-tigraphy. Gastroenterology. 1983;84:354-363.Gastroesophageal Reflux DiseaseAllison PR. Hiatus hernia: a 20 year retrospective survey. Ann Surg. 1973;178:273-276.Allison PR. Peptic ulcer of the esophagus. J Thorac Surg. 1946;15:308-317.Allison PR. Reflux esophagitis, sliding hiatus hernia and the anat-omy of repair. Surg Gynecol Obstet. 1951;92:419-431.Barlow AP, DeMeester TR, Ball CS, et al. The significance of the gastric secretory state in gastroesophageal reflux disease. Arch Surg. 1989;124:937-940.Bonavina L, DeMeester TR, McChesney L, Schwizer W, Albertucci M, Bailey RT. Drug-induced esophageal strictures. Ann Surg. 1987;206:173-183.Bremner RM, DeMeester TR, Crookes PF, et al. The effect of symp-toms and non-specific motility abnormalities on surgical therapy for gastroesophageal reflux disease. J Thorac Cardiovasc Surg. 1994;107:1244-1250.Castell DO. Nocturnal acid breakthrough in perspective: let’s not throw out the baby with the bathwater. Am J Gastroenterol. 2003;98:517-518.Chandrasoma P, Barrett N. So close, yet 50 years from the truth. J Gastrointest Surg. 1999;3:7-14.Clark GW, Ireland AP, Peters JH, Chandrasoma P, DeMeester TR, Bremner CG. Short segments of Barrett’s esophagus: a prevalent complication of gastroesophageal reflux disease with malignant potential. J Gastrointest Surg. 1997;1(2):113-122.DeMeester SR, Campos GM, DeMeester TR, et al. The impact of an antireflux procedure on intestinal metaplasia of the cardia. Ann Surg. 1998;228:547-556.DeMeester TR, Bonavina L, Albertucci M. Nissen fundoplication for gastroesophageal reflux disease: Evaluation of primary repair in 100 consecutive patients. Ann Surg. 1986;204:9-20.DeMeester TR, Bonavina L, Iascone C, Courtney JV, Skinner DB. Chronic respiratory symptoms and occult gastroesophageal reflux. Ann Surg. 1990;211:337-345.DeMeester SR, DeMeester TR. Columnar mucosa and intesti-nal metaplasia of the esophagus: Fifty years of controversy. Ann Surg. 2000;231:303-321.DeMeester TR, Johansson KE, Franze I, et al. Indications, surgical technique, and long-term functional results of colon interposi-tion or bypass. Ann Surg. 1988;208:460-474.Desai KM, Klingensmith ME, Winslow ER, et al. Symptomatic out-comes of laparoscopic antireflux surgery in patients eligible for endoluminal therapies. Surg Endosc. 2002;16:1669-1673.Donahue PE, Samelson S, Nyhus LM, et al. The floppy Nissen fun-doplication: effective long-term control of pathologic reflux. Arch Surg. 1985;120:663-668.Farrell TM, Richardson WS, Halkar R, et al. Nissen fundoplication improves gastric motility in patients with delayed gastric emp-tying. Surg Endosc. 2001;15:271-274.Farrell TM, Richardson WS, Trus TL, et al. Response of atypical symptoms of gastroesophageal reflux antireflux surgery. Br J Surg. 2001;88:1649-1652.Farrell TM, Smith CD, Metreveli RE, et al. Fundoplication provides effective and durable symptom relief in patients with Barrett’s esophagus. Am J Surg. 1999;178:18-21.Fass R. Epidemiology and pathophysiology of symptomatic gastroesophageal reflux disease. Am J Gastroenterol. 2003;98 (3 suppl):S2-S7.Fiorucci S, Santucci L, Chiucchiú, Morelli A. Gastric acidity and gastroesophageal reflux patterns in patients with esophagitis. Gastroenterology. 1992;103:855-861.Fletcher J, Wirz A, Young J, et al. Unbuffered highly acidic gas-tric juice exists at the gastroesophageal junction after a meal. Gastroenterology. 2001;121:775-783.Fuchs KH, DeMeester TR, Hinder RA, et al. Computerized iden-tification of pathologic duodenogastric reflux using 24-hour gastric pH monitoring. Ann Surg. 1991;213:13-20.Gerson LB, Shetler K, Triadafilopoulos G. Prevalence of Barrett’s esophagus in asymptomatic individuals. Gastroenterology. 2002;123:461-467.Gillen P, Keeling P, Byrne PJ, et al. Implication of duodenogastric reflux in the pathogenesis of Barrett’s oesophagus. Br J Surg. 1988;75:540-543.Graham DY. The changing epidemiology of GERD: geography and Helicobacter pylori. Am J Gastroenterol. 2003;98:1462-1470.Gurski RR, Peters JH, Hagen JA, et al. Barrett’s esophagus can and does regress following antireflux surgery: a study of prevalence and predictive features. J Am Coll Surg. 2003;196:706-712.Henderson RD, Henderson RF, Marryatt GV. Surgical management of 100 consecutive esophageal strictures. J Thorac Cardiovasc Surg. 1990;99:1-7.Hill LD, Kozarek RA, Kraemer SJ, et al. The gastroesophageal flap valve. In vitro and in vivo observations. Gastrointest Endosc. 1996;44(5):541-547.Hinder RA, Stein HJ, Bremner CG, et al. Relationship of a satisfac-tory outcome to normalization of delayed gastric emptying after Nissen fundoplication. Ann Surg. 1989;210:458-465.Hirota WK, Loughney TM, Lazas DJ, et al. Specialized intestinal metaplasia, dysplasia and cancer of the esophagus and esopha-gogastric junction: prevalence and clinical data. Gastroenterol-ogy. 1999;116(2):277-285.Hofstetter WA, Peters JH, DeMeester TR, et al. Long-term outcome of antireflux surgery in patients with Barrett’s esophagus. Ann Surg. 2001;234(4):532-538.Ireland AP, Clark GWB, DeMeester TR. Barrett’s esophagus: the significance of p53 in clinical practice. Ann Surg. 1997;225: 17-30.Isolauri J, Luostarinen M, Viljakka M, et al. Long-term compari-son of antireflux surgery versus conservative therapy for reflux esophagitis. Ann Surg. 1997;225:295-299.Jamieson JR, Hinder RA, DeMeester TR, et al. Analysis of 32 patients with Schatzki’s ring. Am J Surg. 1989;158:563-566.Johnson WE, Hagen JA, DeMeester TR, et al. Outcome of respira-tory symptoms after antireflux surgery on patients with gastro-esophageal reflux disease. Arch Surg. 1996;131:489-492.Kahrilas PJ. Diagnosis of symptomatic gastroesophageal reflux dis-ease. Am J Gastroenterol. 2003;98:S15-S23.Kahrilas PJ. Radiofrequency therapy of the lower esophageal sphincter for treatment of GERD. Gastrointest Endosc. 2003;57:723-731.Brunicardi_Ch25_p1009-p1098.indd 109201/03/19 6:06 PM 1093ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Kaul BK, DeMeester TR, Oka M, et al. The cause of dysphagia in uncomplicated sliding hiatal hernia and its relief by hiatal her-niorrhaphy: a roentgenographic, manometric, and clinical study. Ann Surg. 1990;211:406-410.Khaitan L, Ray WA, Holzman MD, et al. Health care utilization after medical and surgical therapy for gastroesophageal reflux disease. Arch Surg. 2003;138:1356-1361.Labenz J, Tillenburg B, Peitz U, et al. Helicobacter pylori augments the pH-increasing effect of omeprazole in patients with duode-nal ulcer. Gastroenterology. 1996;110:725-732.Lin KM, Ueda RK, Hinder RA, et al. Etiology and importance of alkaline esophageal reflux. Am J Surg. 1991;162:553-557.Little AG, Ferguson MK, Skinner DB. Reoperation for failed anti-reflux operations. J Thorac Cardiovasc Surg. 1986;91:511-517.Liu JY, Finlayson SRG, Laycock WS, et al. Determining the appro-priate threshold for referral to surgery for gastroesophageal reflux disease. Surgery. 2003;133:5-12.Lundell L, Miettinen P, Myrvold HE, et al. Long-term management of gastrooesophageal reflux disease with omeprazole or open antireflux surgery: results of a prospective randomized trial. Eur J Gastroenterol Hepatol. 2000;12:879-887.Marshall RE, Anggiansah A, Owen WJ. Bile in the esopha-gus: clinical relevance and ambulatory detection. Br J Surg. 1997;84:21-28.Morgenthal CB, Shane MD, Stival A, et al. The durability of laparo-scopic Nissen fundoplication: 11-year outcomes. J Gastrointest Surg. 2007;11:693-700.Narayani RI, Burton MP, Young GS. Utility of esophageal biopsy in the diagnosis of non-erosive reflux disease. Dis Esophagus. 2003;16:187-192.Nissen R. Eine einfache operation zur beeinflussung der refluxo-esophagitis. Schweiz Med Wochenschr. 1956;86:590-592.Nissen R. Gastropexy and fundoplication in surgical treatment of hiatus hernia. Am J Dig Dis. 1961;6:954-961.Oberg S, Johansson H, Wenner J, et al. Endoscopic surveillance of columnar lined esophagus: frequency of intestinal meta-plasia detection and impact of antireflux surgery. Ann Surg. 2001;234:619-626.Orlando RC. The pathogenesis of gastroesophageal reflux disease: the relationship between epithelial defense, dysmotility, and acid exposure. Am J Gastroenterol. 1997;92:3S-5S.Orringer MB, Skinner DB, Belsey RHR. Long-term results of the Mark IV operation for hiatal hernia and analyses of recur-rences and their treatment. J Thorac Cardiovasc Surg. 1972;63: 25-33.Parrilla P, Martinez de Haro LF, Ortiz A, et al. Long term results of a randomized prospective study comparing medical and sur-gical treatment in Barrett’s esophagus. Ann Surg. 2003;237: 291-298.Patti MG, Debas HT, Pellegrini CA. Esophageal manometry and 24-hour pH monitoring in the diagnosis of pulmonary aspiration secondary to gastroesophageal reflux. Am J Surg. 1992;163:401-406.Pearson FG, Cooper JD, Patterson GA, Ramirez J, Todd TR. Gastroplasty and fundoplication for complex reflux prob-lems. Ann Surg. 1987;206:473-481.Pelligrini CA, DeMeester TR, Johnson LF, et al. Gastroesophageal reflux and pulmonary aspiration: Incidence, functional abnor-mality, and results of surgical therapy. Surgery. 1979;86:110-119.Peters JH, Heimbucher J, Incarbone R, et al. Clinical and physi-ologic comparison of laparoscopic and open Nissen fundoplica-tion. J Am Coll Surg. 1995;180:385-393.Provenzale D, Kemp JA, Arora S, et al. A guide for surveillance of patients with Barrett’s esophagus. Am J Gastroenterol. 1994;89:670-680.Richter JE. Long-term management of gastroesophageal reflux disease and its complications. Am J Gastroenterol. 1997;92:30S-34S.Romagnuolo J, Meier MA, Sadowski DC. Medical or surgical ther-apy for erosive reflux esophagitis: Cost utility analysis using a Markov model. Ann Surg. 2002;236:191-202.Schwizer W, Hinder RA, DeMeester TR. Does delayed gastric emp-tying contribute to gastroesophageal reflux disease? Am J Surg. 1989;157:74-81.Shaker R, Castell DO, Schoenfeld PS, Spechler SJ. Nighttime heart-burn is an underappreciated clinical problem that impacts sleep and daytime function: the results of a Gallup survey conducted on behalf of the American Gastroenterologic Association. Am J Gastroenterol. 2003;98:1487-1493.Siewert JR, Isolauri J, Feussuer M. Reoperation following failed fundoplication. World J Surg. 1989;13:791-796.Smith CD, McClusky DA, Rajhad MA, Lederman AB, Hunter JG. When fundoplication fails: redo? Ann Surg. 2005;241(6):861-871.Sontag SJ, O’Connell S, Khandelwal S, et al. Asthmatics with gastroesophageal reflux: long term results of a randomized trial of medical and surgical antireflux therapies. Am J Gastroenterol. 2003;98(5):987-999.Spechler SJ, Department of Veterans Affairs Gastroesophageal Reflux Disease Study Group. Comparison of medical and sur-gical therapy for complicated gastroesophageal reflux disease in veterans. N Engl J Med. 1992;326:786-792.Spechler SJ, Lee E, Ahmen D. Long term outcome of medical and surgical therapies for gastroesophageal reflux disease: follow-up of a randomized controlled trial. JAMA. 2001;285: 2331-2338.Spivak H, Farrell TM, Trus TL, et al. Laparoscopic fundoplication for dysphagia and peptic esophageal stricture. J Gastrointest Surg. 1998;2:555-560.Stein HJ, Barlow AP, DeMeester TR, Hinder RA. Complications of gastroesophageal reflux disease: role of the LES, esopha-geal acid and acid/alkaline exposure, and duodenogastric reflux. Ann Surg. 1992;216(1):35-43.Stein HJ, Bremner RM, Jamieson J, DeMeester TR. Effect of Nissen fundoplication on esophageal motor function. Arch Surg. 1992;127:788-791.Terry M, Smith CD, Branum GD, et al. Outcomes of laparoscopic fundoplication for gastroesophageal reflux disease and parae-sophageal hernia: experience with 1000 consecutive cases. Surg Endosc. 2001;15:691-699.Terry ML, Vernon A, Hunter JG. Stapled-wedge Collis gastroplasty for the shortened esophagus. Am J Surg. 2004;188:195-199.Trus TL, Laycock WS, Waring JP, Branum GD, Hunter JG. Improvement in quality of life measures after laparo-scopic antireflux surgery. Ann Surg. 1999;229(3):331-336.Tseng D, Rizvi AZ, Fennerty MB, et al. Forty-eight-hour pH moni-toring increases sensitivity in detecting abnormal esophageal acid exposure. J Gastrointest Surg. 2005;9:1043-1052.Van Den Boom G, Go PM, Hameeetman W, et al. Cost effectiveness of medical versus surgical treatment in patients with severe or refractory gastroesophageal reflux disease in the Netherlands. Scand J Gastroenterol. 1996;31:1-9.Watson DI, Baigrie RJ, Jamieson GG. A learning curve for laparo-scopic fundoplication. Definable, avoidable, or a waste of time? Ann Surg. 1996;224:198-203.Wattchow DA, Jamieson GG, et al. Distribution of peptide-containing nerve fibers in the gastric musculature of patients undergoing sur-gery for gastroesophageal reflux. Ann Surg. 1992;290:153.Weston AP, Krmpotich P, Makdisi WF, et al. Short segment Barrett’s esophagus: clinical and histological features, associ-ated endoscopic findings, and association with gastric intestinal metaplasia. Am J Gastroenterol. 1996;91:981-986.Williamson WA, Ellis FH Jr, Gibb SP, et al. Effect of antireflux oper-ation on Barrett’s mucosa. Ann Thorac Surg. 1990;49:537-541.Wright TA. High-grade dysplasia in Barrett’s oesophagus. Br J Surg. 1997;84:760-766.Brunicardi_Ch25_p1009-p1098.indd 109301/03/19 6:06 PM 1094SPECIFIC CONSIDERATIONSPART IIZaninotto G, DeMeester TR, Bremner CG, Smyrk TC, Cheng Shih-Chuan. Esophageal function in patients with reflux-induced strictures and its relevance to surgical treatment. Ann Thorac Surg. 1989;47:362-370.Diaphragmatic HerniasBombeck TC, Dillard DH, Nyhus LM. Muscular anatomy of the gastroesophageal junction and role of the phrenoesophageal ligament. Ann Surg. 1966;164:643-654.Casbella F, Sinanan M, Horgan S, Pellegrini CA. Systematic use of gastric fundoplication in laparoscopic repair of paraesophageal hernias. Am J Surg. 1996;171:485-489.Dalgaard JB. Volvulus of the stomach. Acta Chir Scand. 1952;103:131-153.DeMeester TR, Lafontaine E, Joelsson BE, et al. The relation-ship of a hiatal hernia to the function of the body of the esophagus and the gastroesophageal junction. J Thorac Car-diovasc Surg. 1981;82:547-558.Eliska O. Phreno-oesophageal membrane and its role in the devel-opment of hiatal hernia. Acta Anat. 1973;86:137-150.Frantzides CT, Madan AK, Carlson MA, et al. A prospective, ran-domized trial of laparoscopic polytetrafluoroethylene (PTFE) patch repair vs simple cruroplasty for large hiatal hernia. Arch Surg. 2002;137:649-652.Fuller CB, Hagen JA, DeMeester TR, et al. The role of fundoplica-tion in the treatment of type II paraesophageal hernia. J Thorac Cardiovasc Surg. 1996;111:655-661.Gangopadhyay N, Perrone JM, Soper NJ, et al. Outcomes of lapa-roscopic paraesophageal hernia repair in elderly and high-risk patients. Surgery. 2006;140:491-498; discussion 498.Granderath FA, Schweiger UM, Kamolz T, Asche KU, Pointner R. Laparoscopic Nissen fundoplication with prosthetic hiatal clo-sure reduces postoperative intrathoracic wrap herniation: pre-liminary results of a prospective randomized functional and clinical study. Arch Surg. 2005;140:40-48.Hashemi M, Peters JH, DeMeester TR, et al. Laparoscopic repair of large type III hiatal hernia: objective follow-up reveals high recurrence rate. J Am Coll Surg. 2000;190:539-560.Kahrilas PJ, Wu S, Lin S, Pouderoux P. Attenuation of esopha-geal shortening during peristalsis with hiatus hernia. Gastro-enterology. 1995;109(6):1818-1825.Kleitsch WP. Embryology of congenital diaphragmatic hernia. I. Esophageal hiatus hernia. Arch Surg. 1958;76:868-873.Mattar SG, Bowers SP, Galloway KD, et al. Long-term outcome of laparoscopic repair of paraesophageal hernia. Surg Endosc. 2002;16:745-749.Menguy R. Surgical management of large paraesophageal hernia with complete intrathoracic stomach. World J Surg. 1988;12:415-422.Myers GA, Harms BA, Sarling JR. Management of paraesopha-geal hernia with a selective approach to antireflux surgery. Am J Surg. 1995;170:375-380.Oddsdottir M, Franco AL, Laycock WS, et al. Laparoscopic repair of paraesophageal hernia: New access, old technique. Surg Endosc. 1995;9:164-168.Oelschlager BK, Pellegrini CA, Hunter J, et al. Biologic pros-thesis reduces recurrence after laparoscopic paraesophageal hernia repair: a multicenter, prospective, randomized trial. Ann Surg. 2006;244(4):481-490.Patti MG, Goldberg HI, Arcerito M, Bortolasi L, Tong J, Way LW. Hiatal hernia size affects LES function, esophageal acid exposure, and the degree of mucosal injury. Am J Surg. 1996;171(1):182-186.Pierre AF, Luketich JD, Fernando HC, et al. Results of laparo-scopic repair of giant paraesophageal hernias: 200 consecutive patients. Ann Thorac Surg. 2002;74:1909-1915.Skinner DB, Belsey RH. Surgical management of esophageal reflux and hiatus hernia: long-term results with 1030 patients. J Thorac Cardiovasc Surg. 1967;53:33-54.Stylopoulos N, Gazelle GS, Ratner DW. Paraesophageal hernias: operation or observation. Ann Surg. 2002;236:492-500.Trus TL, Bax T, Richardson WS, et al. Complications of lapa-roscopic paraesophageal hernia repair. J Gastrointest Surg. 1997;1(3):221-227; discussion 228.Wo JM, Branum GD, Hunter JG, et al. Clinical features of type III (mixed) paraesophageal hernia. Am J Gastroenterol. 1996;91:914-916.Miscellaneous Esophageal LesionsBurdick JS, Venu RP, Hogan WJ. Cutting the defiant lower esopha-geal ring. Gastrointest Endosc. 1993;39:616-619.Burt M, Diehl W, Martini N, et al. Malignant esophagorespiratory fistula: management options and survival. Ann Thorac Surg. 1991;52:1222-1228.Chen MYM, Ott DJ, Donati DL. Correlation of lower esophageal mucosal ring and LES pressure. Dig Dis Sci. 1994;39:766-769.D’Haens G, Rutgeerts P, Geboes K, et al. The natural history of esophageal Crohn’s disease. Three patterns of evolution. Gastrointest Endosc. 1994;40:296-300.Eckhardt VF, Kanzler G, Willems D. Single dilation of symptom-atic Schatzki rings. A prospective evaluation of its effectiveness. Dig Dis Sci. 1992;37:577-582.Klein HA, Wald A, Graham TO, et al. Comparative studies of esophageal function in systemic sclerosis. Gastroenterology. 1992;102:1551-1556.Mathisen DJ, Grillo HC, Wain JC, et al. Management of acquired nonmalignant tracheoesophageal fistula. Ann Thorac Surg. 1991;52:759-765.Poirier NC, Taillefer R, Topart P, Duranceau A. Antireflux opera-tions in patients with scleroderma. Ann Thorac Surg. 1994; 58:66-72.Soudah HC, Hasler WL, Owyang C. Effect of octreotide on intesti-nal motility and bacterial overgrowth in scleroderma. N Engl J Med. 1991;325:1461-1467.Toskes PP. Hope for the treatment of intestinal scleroderma (Letter to the Editor). N Engl J Med. 1991;325:1508.Wilcox CM, Straub RF. Prospective endoscopic characterization of cytomegalovirus esophagitis in AIDS. Gastrointest Endosc. 1994;40:481-484.Motility Disorders of the Pharynx and EsophagusAchem SR, Crittenden J, Kolts B, et al. Long-term clinical and manometric follow-up of patients with nonspecific esophageal motor disorders. Am J Gastroenterol. 1992;87:825-830.Andreollo NA, Earlam RJ. Heller’s myotomy for achalasia: is an added antireflux procedure necessary? Br J Surg. 1987;74:765-769.Anselmino M, Perdikis G, Hinder RA, et al. Heller myotomy is superior to dilatation for the treatment of early achalasia. Arch Surg. 1997;132:233-240.Bianco A, Cagossi M, Scrimieri D, et al. Appearance of esopha-geal peristalsis in treated idiopathic achalasia. Dig Dis Sci. 1986;90:978-983.Bonavina L, Nosadinia A, Bardini R, Baessato M, Peracchia A. Primary treatment of esophageal achalasia: long-term results of myotomy and Dor fundoplication. Arch Surg. 1992;127:222-226.Chen LQ, Chughtau T, Sideris L, et al. Long term effects of myotomy and partial fundoplication for esophageal achalasia. Dis Esophagus. 2002;15:171-179.Code CF, Schlegel JF, Kelley ML, et al. Hypertensive gastroesopha-geal sphincter. Mayo Clin Proc. 1960;35:391-399.Cook IJ, Blumbergs P, Cash K, Jamieson GG, Shearman DJ. Struc-tural abnormalities of the cricopharyngeus muscle in patients with pharyngeal (Zenker’s) diverticulum. J Gastroenterol Hepatol. 1992;7:556-562.Brunicardi_Ch25_p1009-p1098.indd 109401/03/19 6:06 PM 1095ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25Cook IJ, Gabb M, Panagopoulos V, et al. Pharyngeal (Zenker’s) diverticulum is a disorder of upper esophageal sphincter open-ing. Gastroenterology. 1992;103:1229-1235.Csendes A, Braghetto I, Henríquez A, Cortés C. Late results of a prospective randomized study comparing forceful dilata-tion and oesophagomyotomy in patients with achalasia. Gut. 1989;30(3):299-304.DeMeester TR, Johansson KE, Franze I, et al. Indications, surgical technique, and long-term functional results of colon interposi-tion or bypass. Ann Surg. 1988;208:460-474.DeMeester TR, Lafontaine E, et al. The relationship of a hia-tal hernia to the function of the body of the esophagus and the gastroesophageal junction. J Thorac Cardiovasc Surg. 1981;82:547-558.Eckardt V, Aignherr C, Bernhard G. Predictors of outcome in patients with achalasia treated by pneumatic dilation. Gastroenterology. 1992;103(6):1732-1738.Ekberg O, Wahlgren L. Dysfunction of pharyngeal swallowing: a cineradiographic investigation in 854 dysphagial patients. Acta Radiol Diagn. 1985;26:389-395.Ellis FH. Long esophagomyotomy for diffuse esophageal spasm and related disorders: An historical overview. Dis Esophagus. 1998;11:210-214.Ellis FH Jr. Oesophagomyotomy for achalasia: a 22-year experi-ence. Br J Surg. 1993;80:882-885.Evander A, Little AG, et al. Diverticula of the mid and lower esoph-agus. World J Surg. 1986;10:820-828.Ferguson TB, Woodbury JD, Roper CL. Giant muscular hypertro-phy of the esophagus. Ann Thorac Surg. 1969;8:209-218.Foker JE, Ring WE, Varco RL. Technique of jejunal interposi-tion for esophageal replacement. J Thorac Cardiovasc Surg. 1982;83:928-933.Gutschow CA, Hamoir M, Rombaux P, et al. Management of pha-ryngoesophageal (Zenker’s) diverticulum: which technique? Ann Thorac Surg. 2002;74:1677-1682.Hirano I, Tatum RP, Shi G, et al. Manometric heterogene-ity in patients with idiopathic achalasia. Gastroenterology. 2001;120:789-798.Jeansonne LO, White BC, Pilger KE, et al. Ten-year follow-up of laparoscopic Heller myotomy for achalasia shows durability. Surg Endosc. 2007;21:1498-1502.Jobe BA, Kim CY, Minjarez RC, et al. Simplifying minimally invasive transhiatal esophagectomy with the inversion approach: Lessons learned from the first 20 cases. Arch Surg. 2006;141:857-865; discussion 865.Kahrilas PJ, Logemann JA, Lin S, Ergun GA. Pharyngeal clearance during swallowing: a combined manometric and videofluoro-scopic study. Gastroenterology. 1992;103(1):128-136.Kostic S, Kjellin A, Ruth M, et al. Pneumatic dilation or laparo-scopic cardiomyotomy in the management of newly diagnosed idiopathic achalasia. Results of a randomized controlled trial. World J Surg. 2007;31:470-478.Lam HG, Dekker W, Kan G, et al. Acute noncardiac chest pain in a coronary care unit. Gastroenterology. 1992;102:453-460.Mellow MH. Return of esophageal peristalsis in idiopathic achala-sia. Gastroenterology. 1976;70:1148-1151.Meshkinpour H, Haghighat P, Meshkinpour A. Quality of life among patients treated for achalasia. Dig Dis Sci. 1996;41(2):352-356.Migliore M, Payne H, Jeyasingham K. Pathophysiologic basis for operation on Zenker’s diverticulum. Ann Thorac Surg. 1994;57:1616-1621.Moser G, Vacariu-Granser GV, Schneider C, et al. High incidence of esophageal motor disorders in consecutive patients with glo-bus sensation. Gastroenterology. 1991;101:1512-1521.Moses PL, Ellis LM, Anees MR, et al. Antineural antibodies in idiopathic achalasia and gastro-oesophageal reflux disease. Gut. 2003;52:629-636.Nehra D, Lord RV, DeMeester TR, et al. Physiologic basis for the treatment of epiphrenic diverticulum. Ann Surg. 2002;235: 346-354.Oelschlager BK, Chang L, Pellegrini CA. Improved outcome after extended gastric myotomy for achalasia. Arch Surg. 2003;138(5):490-495.O’Rourke RW, Seltman AK, Chang EY, et al. A model for gastric banding in the treatment of morbid obesity: the effect of chronic partial gastric outlet obstruction on esophageal physiology. Ann Surg. 2006;244:723-733.Patti MG, Fisichella PM, Peretta S, et al. Impact of minimally invasive surgery on the treatment of esophageal achalasia: a decade of change. J Am Coll Surg. 2003;196:698-703.Pellegrini C, Wetter LA, Patti M, et al. Thoracoscopic esophagomy-otomy: initial experience with a new approach for the treatment of achalasia. Ann Surg. 1992;216:291-299.Peters JH. An antireflux procedure is critical to the long-term out-come of esophageal myotomy for achalasia. J Gastrointest Surg. 2001;5:17-20.Peters JH, Kauer WK, Ireland AP, et al. Esophageal resection with colon interposition for end-stage achalasia. Arch Surg. 1995;130:632-636.Ponce J, Garrigues V, Pertejo V, et al. Individual prediction of response to pneumatic dilation in patients with achalasia. Dig Dis Sci. 1996;41:2135-2141.Richards WO, Torquati A, Holzman MD, et al. Heller myotomy versus Heller myotomy with Dor fundoplication for acha-lasia: a prospective randomized double-blind clinical trial. Ann Surg. 2004;240(3):405-412; discussion 412-415.Shoenut J, Duerksen D. A prospective assessment of gastroesoph-ageal reflux before and after treatment of achalasia patients: pneumatic dilation versus transthoracic limited myotomy. Am J Gastroenterol. 1997;92:1109-1112.Spechler S, Castell DO. Classification of oesophageal motility abnormalities. Gut. 2001;49:145-151.Streitz JM, Jr, Glick ME, Ellis FH, Jr. Selective use of myotomy for treatment of epiphrenic diverticula: manometric and clinical analysis. Arch Surg. 1992;127:585-588.Vaezi MF, Baker ME, Achkar E, et al. Timed barium oesophogram: better predictor of long term success after pneumatic dilation in achalasia than symptom assessment. Gut. 2002;50:765-770.Verne G, Sallustio JE, Eaker EY. Anti-myenteric neuronal antibod-ies in patients with achalasia: a prospective study. Dig Dis Sci. 1997;42:307-313.Williams RB, Grehan MJ, Andre J, et al. Biomechanics, diagnosis, and treatment outcome in inflammatory myopathy presenting as oropharyngeal dysphagia. Gut. 2003;52:471-478.Zaninotto G, Annese V, Costantini M, et al. Randomized controlled trial of botulinum toxin versus laparoscopic Heller myotomy for esophageal achalasia. Ann Surg. 2004;239:364-370.Zhao X, Pasricha PJ. Botulinum toxin for spastic GI disorders: a systematic review. Gastrointest Endosc. 2003;57:219-235.Carcinoma of the EsophagusAkiyama H. Surgery for carcinoma of the esophagus. Curr Probl Surg. 1980;17:53-120.Akiyama H, Tsurumaru M. Radical lymph node dissection for cancer of the thoracic esophagus. Ann Surg. 1994;220(3):364-372.Altorki N, Skinner D. Should en-bloc esophagectomy be the standard of care for esophageal carcinoma? Ann Surg. 2001;234:581-587.Badwe RA, Sharma V, Bhansali MS, et al. The quality of swallow-ing for patients with operable esophageal carcinoma: a ran-domized trial comparing surgery with radiotherapy. Cancer. 1999;85:763-768.Baker JW, Jr, Schechter GL. Management of paraesophageal cancer by blunt resection without thoracotomy and reconstruction with stomach. Ann Surg. 1986;203:491-499.Brunicardi_Ch25_p1009-p1098.indd 109501/03/19 6:06 PM 1096SPECIFIC CONSIDERATIONSPART IIBiere SS, van Berge Henegouwen MI, Maas KW, et al. Minimally invasive open oesophagectomy for patient with oesophageal cancer: a multicenter, open-label, randomized controlled trial. Lancet. 2012;19:1887-1892.Blazeby JM, Williams MH, et al. Quality of life measurement in patients with oesophageal cancer. Gut. 1995;37:505-508.Borrie J. Sarcoma of esophagus: surgical treatment. J Thorac Surg. 1959;37:413-426.Cameron AJ, Ott BJ, Payne WS. The incidence of adenocarci-noma in columnar-lined (Barrett’s) esophagus. N Engl J Med. 1985;313:857-859.Chang AC, Ji H, Birkmeyer NJ, et al. Outcomes after transhiatal and transthoracic esophagectomy for cancer. Ann Thorac Surg. 2008;85:424-429.Chang EY, Morris CD, Seltman AK, et al. The effect of antireflux surgery on esophageal carcinogenesis in patients with Barrett’s esophagus: a systematic review. Ann Surg. 2007;246:11-21.Clark GWB, Peters JH, Hagen JA, et al. Nodal metastases and recurrence patterns after en-bloc esophagectomy for adenocar-cinoma. Ann Thorac Surg. 1994;58:646-654.Clark GW, Smyrk TC, Burdiles P, et al. Is Barrett’s metapla-sia the source of adenocarcinomas of the cardia? Arch Surg. 1994;129:609-614.Collin CF, Spiro RH. Carcinoma of the cervical esophagus: chang-ing therapeutic trends. Am J Surg. 1984;148:460-466.Corley DA, Kerlikowske K, Verma R, et al. Protective association of aspirin/NSAIDs and esophageal cancer: a systematic review and meta-analysis. Gastroenterology. 2003;124:47-56.Cunningham D, Allum WH, Stenning SP, et al. Perioperative chemotherapy versus surgery alone for resectable gastro-esophageal cancer. N Engl J Med. 2006;6;355(1):11-20.Dallal HJ, Smith GD, Grieve DC, et al. A randomized trial of thermal ablative therapy versus expandable metal stents in the palliative treatment of patients with esophageal carcinoma. Gastrointest Endosc. 2001;54:549-557.DeMeester TR, Skinner DB. Polypoid sarcomas of the esophagus. Ann Thorac Surg. 1975;20:405-417.Duhaylongsod FG, Wolfe WG. Barrett’s esophagus and adenocarci-noma of the esophagus and gastroesophageal junction. J Thorac Cardiovasc Surg. 1991;102:36-42.Ell C, May A, Gossner L, et al. Endoscopic mucosal resection of early cancer and high grade dysplasia in Barrett’s esophagus. Gastroenterology. 2001;118:670-677.Ellis FH, Heatley GJ, Krosna MJ, et al. Esophagogastrectomy for carcinoma of the esophagus and cardia: a comparison of find-ings and results after standard resection in three consecutive 8 year time intervals, using improved staging criteria. J Thorac Cardiovasc Surg. 1997;113:836.Frenken M. Best palliation in esophageal cancer; surgery, stenting, radiation, or what? Dis Esophagus. 2001;14:120-123.Fujita H, Kakegawa T, Yamana H, et al. Mortality and morbidity rates, postoperative course, quality of life, and prognosis after extended radical lymphadenectomy for esophageal cancer. Ann Surg. 1995;222:654-662.Gebski V, Burmeister B, Smithers BM, et al. Survival benefits from neoadjuvant chemoradiotherapy or chemotherapy in oesophageal carcinoma: a meta-analysis. Lancet. 2007;8(3): 226-234.Greenstein AJ, Litle VR, Swanson SJ, et al. Effect of the num-ber of lymph nodes sampled on postoperative survival of lymph node-negative esophageal cancer. Cancer. 2008;112: 1239-1246.Hagen JA, DeMeester SR, Peters JH, Chandrasoma P, DeMeester TR. Curative resection for esophageal adenocarcinoma analy-sis of 100 en bloc esophagectomies. Ann Surg. 2001;234(4): 520-531.Hofstetter W, Swisher SG, Correa AM, et al. Treatment outcomes of resected esophageal cancer. Ann Surg. 2002;236:376-385.Hulscher JB, Van Sandick JW, de Boer AG, et al. Extended transthoracic resection compared with limited transhiatal resection for adenocarcinoma of the esophagus. N Engl J Med. 2002;347(21):1662-1669.Iijima K, Henrey E, Moriya A, et al. Dietary nitrate generates poten-tially mutagenic concentrations of nitric oxide at the gastro-esophageal junction. Gastroenterology. 2002;122:1248-1257.Ikeda M, Natsugoe S, Ueno S, et al. Significant host and tumor related factors for predicting prognosis in patients with esopha-geal carcinoma. Ann Surg. 2003;238:197-202.Jankowski JA, Wight NA, Meltzer SJ, et al. Molecular evolution of the metaplasia-dysplasia-adenocarcinoma sequence in the esophagus. Am J Pathol. 1999;154:965-973.Jobe BA, Kim CY, Minjarez RC, et al. Simplifying minimally invasive transhiatal esophagectomy with the inversion approach: lessons learned from the first 20 cases. Arch Surg. 2006;141:857-865; discussion 865.Johansson J, DeMeester TR, Hoger JA, et al. En bloc is supe-rior to transhiatal esophagectomy for T3 N1 adenocarci-noma of the distal esophagus and GE junction. Arch Surg. 2004;139:627-633.Kaklamanos IG, Walker GR, Ferry K, et al. Neoadjuvant treatment for resectable cancer of the esophagus and the gastroesophageal junction: a meta-analysis of randomized clinical trials. Ann Surg Oncol. 2003;10:754-761.Kelsen DP, Winter KA, Gunderson LL, et al. Long-term results of RTOG trial 8911 (USA Intergroup 113): a random assign-ment trial comparison of chemotherapy followed by surgery compared with surgery alone for esophageal cancer. J Clin Oncol. 2007;25(24):3719-3725.Krasna MJ, Reed CE, Nedzwiecki D, et al. CALBG 9380: a prospec-tive trial of the feasibility of thoracoscopy/laparoscopy in stag-ing esophageal cancer. Ann Thorac Surg. 2001;71:1073-1079.Kirby JD. Quality of life after esophagectomy: the patients’ per-spective. Dis Esophagus. 1999;12:168-171.Lagergren J, Bergstrom R, Lindgren A, Nyrén O. Symptomatic gastroesophageal reflux as a risk factor for esophageal adenocarcinoma. N Engl J Med. 1999;340(11):825-831.Lavin P, Hajdu SI, Foote FW, Jr. Gastric and extragastric leiomyo-blastomas. Cancer. 1972;29:305-311.Law SYK, Fok M, Wong J. Pattern of recurrence after oesopha-geal resection for cancer: clinical implications. Br J Surg. 1996;83(1):107-111.Law SYK, Fok M, et al. A comparison of outcomes after resec-tion for squamous cell carcinomas and adenocarcinomas of the esophagus and cardia. Surg Gynecol Obstet. 1992;175:107-112.Law S, Kwong DL, Kwok KF, et al. Improvement in treatment results and long term survival of patients with esophageal cancer: impact of chemoradiation and change in treatment strategy. Ann Surg. 2003;238:339-347.Lerut T, Coosemans W, Van Raemdonck D, et al. Surgical treat-ment of Barrett’s carcinoma. Correlations between morpho-logic findings and prognosis. J Thorac Cardiovasc Surg. 1994;107:1059-1066.Leuketich JD, Alvelo-Rivera M, Buenaventura PO, et al. Mini-mally invasive esophagectomy: outcomes in 222 patients. Ann Surg. 2003;238(4):486-494.Levine DS, Reid BJ. Endoscopic diagnosis of esophageal neo-plasms. Gastrointest Clin North Am. 1992;2:395-413.Lewis I. The surgical treatment of carcinoma of the esophagus with special reference to a new operation for the growths of the mid-dle third. Br J Surg. 1946;34:18-31.Logan A. The surgical treatment of carcinoma of the esophagus and cardia. J Thorac Cardiovasc Surg. 1963;46:150-161.Manner H, May A, Pech O, et al. Early Barrett’s carcinoma with “low-risk” submucosal invasion: long-term results of endo-scopic resection with a curative intent. Am J Gastroenterol. 2008;103:2589-2597.Brunicardi_Ch25_p1009-p1098.indd 109601/03/19 6:06 PM 1097ESOPHAGUS AND DIAPHRAGMATIC HERNIACHAPTER 25McCort JJ. Esophageal carcinosarcoma and pseudosarcoma. Radiology. 1972;102:519-524.Medical Research Council Oesophageal Working Party. Surgi-cal resection with or without preoperative chemotherapy in oesophageal cancer: a randomized controlled trial. Lancet. 2002;359:1727-1733.Naunheim KS, Petruska PJ, et al. Preoperative chemotherapy and radiotherapy for esophageal carcinoma. J Thorac Cardiovasc Surg. 1992;103:887-893.Nicks R. Colonic replacement of the esophagus. Br J Surg. 1967; 54:124-128.Nigro JJ, Hagen JA, DeMeester TR, et al. Occult esophageal ade-nocarcinoma: extent of disease and implications for effective therapy. Ann Surg. 1999;230:433-438.Omloo JM, Lagarde SM, Hulscher JB, et al. Extended transtho-racic resection compared with limited transhiatal resection for adenocarcinoma of the mid/distal esophagus: Five year survival of a randomized clinical trial. Ann Surg. 2007;246(6):992-1000.Orringer MB, Marshall B, Iannettoni MD. Transhiatal esopha-gectomy: clinical experience and refinements. Ann Surg. 1999;230:392.Orringer MB, Marshall B, Chang AC, et al. Two thousand tran-shiatal esophagectomies: changing trends, lessons learned. Ann Surg. 2007;246(3):363-372; discussion 372-374.Ott K, Herrmann K, Lordick F, et al. Early metabolic response evaluation by fluorine-18 fluorodeoxyglucose positron emis-sion tomography allows in vivo testing of chemosensitivity in gastric cancer: long-term results of a prospective study. Clin Cancer Res. 2008;14:2012-2018.Pacifico RJ, Wang KK, Wongkeesong LM, et al. Combined endo-scopic mucosal resection and photodynamic therapy versus esophagectomy for management of early adenocarcinoma of the esophagus. Clin Gastroenterol Hepatol. 2003;1:252-257.Pera M, Cameron AJ, Trastek VF, Carpenter HA, Zinsmeister AR. Increasing incidence of adenocarcinoma of the esoph-agus and esophagogastric junction. Gastroenterology. 1993;104(2):510-513.Pera M, Trastek VF, Carpenter HA, Allen MS, Deschamps C, Pairolero PC. Barrett’s esophagus with high-grade dysplasia: an indication for esophagectomy? Ann Thorac Surg. 1992;54:199-204.Pera M, Trastek VF, Carpenter HA, et al. Influence of pancreatic and biliary reflux on the development of esophageal carcinoma. Ann Thorac Surg. 1993;55:1386-1392.Peters JH, Clark GWB, Ireland AP, Chandrasoma P, Smyrk TC, DeMeester TR. Outcome of adenocarcinoma arising in Barrett’s esophagus in endoscopically surveyed and non-surveyed patients. J Thorac Cardiovasc Surg. 1994;108(5):813-821.Peters JH, Hoeft SF, Heimbucher J, et al. Selection of patients for cura-tive or palliative resection of esophageal cancer based on preopera-tive endoscopic ultrasound. Arch Surg. 1994;129:534-539.Peters JH. Surgical treatment of esophageal adenocarcinoma: con-cepts in evolution. J Gastrointest Surg. 2002;6:518.Rasanen JV, Sihvo EIT, Knuuti J, et al. Prospective analysis of accuracy of proton emission tomography, computed tomogra-phy and endoscopic ultrasonography in staging of adenocarci-noma of the esophagus and esophagogastric junction. Ann Surg Oncol. 2003;10:954-960.Ravitch M. A Century of Surgery. Philadelphia: Lippincott; 1981:56.Reed CE. Comparison of different treatments for unresectable esophageal cancer. World J Surg. 1995;19:828.Reid BJ, Weinstein WM, Kewin KJ, et al. Endoscopic biopsy can detect high-grade dysplasia or early adenocarcinoma in Barrett’s esophagus without grossly recognizable neoplastic lesions. Gastroenterology. 1988;94(1):81-90.Ribeiro U, Jr, Posner MC, Safatle-Ribeiro AV, Reynolds JC. Risk factors for squamous cell carcinoma of the oesophagus. Br J Surg. 1996;83:1174-1185.Rice TW, Boyce GA, Sivall MV. Esophageal ultrasound and the preoperative staging of carcinoma of the esophagus. J Thorac Cardiovasc Surg. 1991;101:536-543.Rice TW, Rusch VW, Ishwaran H, et al. Cancer of the esopha-gus and esophagogastric junction: data-driven staging for the seventh edition of the American Joint Committee on Cancer/International Union Against Cancer Cancer Staging Manuals. Cancer. 2010;15:3763-3773.Robertson CS, Mayberry JF, Nicholson JA. Value of endoscopic surveillance in the detection of neoplastic changes in Barrett’s esophagus. Br J Surg. 1988;75:760-763.Rösch T, Lorenz R, et al. Endosonographic diagnosis of submuco-sal upper gastrointestinal tract tumors. Scand J Gastroenterol. 1992;27:1-8.Rosenberg JC, Budev H, Edwards RC. Analysis of adenocarci-noma in Barrett’s esophagus utilizing a staging system. Cancer. 1985;55:1353-1360.Ruol A, Portale G, Castoro C, et al. Effects of neoadjuvant ther-apy on perioperative morbidity in elderly patients undergo-ing esophagectomy for esophageal cancer. Ann Surg Oncol. 2007;14:3243-3250.Skinner DB, Dowlatshahi KD, DeMeester TR. Potentially curable carcinoma of the esophagus. Cancer. 1982;50:2571-2575.Skinner DB, Little AG, Ferguson MK, Soriano A, Staszak VM. Selection of operation for esophageal cancer based on staging. Ann Surg. 1986;204:391-401.Smithers BM, Cullinan M, Thomas JM, et al. Outcomes from salvage esophagectomy post definitive chemoradiotherapy compared with resection following preoperative neoadjuvant chemoradiotherapy. Dis Esophagus. 2007;20:471-477.Sonnenberg A, Fennerty MB. Medical decision analysis of chemo-prevention against esophageal adenocarcinoma. Gastroenterol-ogy. 2003;124:1758-1766.Streitz JM, Jr, Ellis FH, Jr, Gibb SP, et al. Adenocarcinoma in Barrett’s esophagus. Ann Surg. 1991;213:122-125.Turnbull AD, Rosen P, Goodner JT, et al. Primary malignant tumors of the esophagus other than typical epidermoid carcinoma. Ann Thorac Surg. 1973;15:463-473.Urschel JD, Ashiku S, Thurer R, et al. Salvage or planned esophagectomy after chemoradiation for locally advanced esophageal cancer: a review. Dis Esophagus. 2003;16:60-65.Vigneswaran WT, Trastek VK, Pairolero PC, et al. Extended esoph-agectomy in the management of carcinoma of the upper tho-racic esophagus. J Thorac Cardiovasc Surg. 1994;107:901-907.Walsh TN, Noonan N, Hollywood D, Kelly A, Keeling N, Hennessy TP. A comparison of multimodal therapy and surgery for esophageal adenocarcinoma. N Engl J Med. 1996;335:462-467.Watson WP, Pool L. Cancer of the cervical esophagus. Surgery. 1948;23:893.Benign Tumors and CystsBardini R, Segalin A, Ruol A, et al. Videothoracoscopic enucleation of esophageal leiomyoma. Am Thorac Surg. 1992;54:576-577.Bonavina L, Segalin A, Rosati R, Pavanello M, Peracchia A. Surgical therapy of esophageal leiomyoma. J Am Coll Surg. 1995;181:257-262.Esophageal PerforationBrewer LA III, Carter R, Mulder GA, Stiles QR. Options in the management of perforations of the esophagus. Am J Surg. 1986;152:62-69.Bufkin BL, Miller JI, Jr, Mansour KA. Esophageal perfora-tion. Emphasis on management. Ann Thorac Surg. 1996;61: 1447-1451.Chang C-H, Lin PJ, Chang JP, et al. One-stage operation for treat-ment after delayed diagnosis of thoracic esophageal perforation. Ann Thorac Surg. 1992;53:617-620.Brunicardi_Ch25_p1009-p1098.indd 109701/03/19 6:06 PM 1098SPECIFIC CONSIDERATIONSPART IIEngum SA, Grosfeld JL, West KW, et al. Improved survival in chil-dren with esophageal perforation. Arch Surg. 1996;131:604-611.Gouge TH, Depan HJ, Spencer FC. Experience with the Grillo pleural wrap procedure in 18 patients with perforation of the thoracic esophagus. Ann Surg. 1989;209:612-617.Jones WG II, Ginsberg RJ. Esophageal perforation: a continuing challenge. Ann Thorac Surg. 1992;53:534-543.Pate JW, Walker WA, Cole FH, Jr, Owen EW, Johnson WH. Spontaneous rupture of the esophagus: a 30-year experience. Ann Thorac Surg. 1989;47:689-692.Reeder LB, DeFilippi VJ, Ferguson MK. Current results of therapy for esophageal perforation. Am J Surg. 1995;169:615-617.Salo JA, Isolauri JO, Heikkilä LJ, et al. Management of delayed esophageal perforation with mediastinal sepsis. Esopha-gectomy or primary repair? J Thorac Cardiovasc Surg. 1993;106:1088-1091.Sawyer R, Phillips C, Vakil N. Shortand long-term outcome of esophageal perforation. Gastrointest Endosc. 1995;41:130-134.Segalin A, Bonavina L, Lazzerini M, De Ruberto F, Faranda C, Peracchia A. Endoscopic management of inveterate esophageal perforations and leaks. Surg Endosc. 1996;10:928-932.Weiman DS, Walker WA, Brosnan KM, Pate JW, Fabian TC. Noniat-rogenic esophageal trauma. Ann Thorac Surg. 1995;59:845-849.Whyte RI, Iannettoni MD, Orringer MB. Intrathoracic esophageal perforation. The merit of primary repair. J Thorac Cardiovasc Surg. 1995;109:140-144.Caustic InjuryAnderson KD, Rouse TM, Randolph JG. A controlled trial of cor-ticosteroids in children with corrosive injury of the esophagus. N Engl J Med. 1990;323:637-640.Ferguson MK, Migliore M, Staszak VM, Little AG. Early evaluation and therapy for caustic esophageal injury. Am J Surg. 1989;157:116-120.Lahoti D, Broor SL, Basu PP, Gupta A, Sharma R, Pant CS. Corro-sive esophageal strictures. Predictors of response to endoscopic dilation. Gastrointest Endosc. 1995;41:196-200.Popovici Z. About reconstruction of the pharynx with colon in extensive corrosive strictures. Kurume Med J. 1989;36:41-47.Sugawa C, Lucas CE. Caustic injury of the upper gastrointesti-nal tract in adults: a clinical and endoscopic study. Surgery. 1989;106:802-806.Wu M-H, Lai W-W. Surgical management of extensive corro-sive injuries of the alimentary tract. Surg Gynecol Obstet. 1993;177:12-16.Zargar SA, Kochhar R, Mehta S, Mehta SK. The role of fiberoptic endoscopy in the management of corrosive ingestion and modi-fied endoscopic classification of burns. Gastrointest Endosc. 1991;37:165-169.Techniques of Esophageal ReconstructionAkiyama H. Esophageal reconstruction. Entire stomach as esopha-geal substitute. Dis Esophagus. 1995;8:7-9.Banki F, Mason RJ, DeMeester SR, et al. Vagal sparing esopha-gectomy: a more physiologic alternative. Ann Surg. 2002; 236:324-336.Burt M, Scott A, Williard WC, et al. Erythromycin stimu-lates gastric emptying after esophagectomy with gastric replacement. A randomized clinical trial. J Thorac Cardiovasc Surg. 1996;111:649-654.Cheng W, Heitmiller RF, Jones BJ. Subacute ischemia of the colon esophageal interposition. Ann Thorac Surg. 1994;57:899-903.DeMeester TR, Johansson KE, Franze I, Eypasch E, Lu CT, McGill JE, Zaninotto G. Indications, surgical technique, and long-term functional results of colon interposition or bypass. Ann Surg. 1988(4);208:460-474.DeMeester TR, Kauer WK. Esophageal reconstruction. The colon as an esophageal substitute. Dis Esophagus. 1995;8:20-29.Dexter SPL, Martin IG, McMahon MJ. Radical thoracoscopic esophagectomy for cancer. Surg Endosc. 1996;10:147-151.Ellis FH, Jr, Gibb SP. Esophageal reconstruction for complex benign esophageal disease. J Thorac Cardiovasc Surg. 1990; 99:192-199.Finley RJ, Lamy A, Clifton J, et al. Gastrointestinal function fol-lowing esophagectomy for malignancy. Am J Surg. 1995; 169:471-475.Fok M, Cheng SW, Wong J. Pyloroplasty versus no drainage in gas-tric replacement of the esophagus. Am J Surg. 1991;162:447-452.Gossot D, Cattan P, Fritsch S. Can the morbidity of esophagec-tomy be reduced by the thoracoscopic approach? Surg Endosc. 1995;9:1113-1115.Honkoop P, Siersema PD, Tilanus HW, Stassen LP, Hop WC, van Blankenstein M. Benign anastomotic strictures after tran-shiatal esophagectomy and cervical esophagogastrostomy. Risk factors and management. J Thorac Cardiovasc Surg. 1996;111(6):1141-1148.Liebermann-Meffert DMI, Meier R, Siewert JR. Vascular anatomy of the gastric tube used for esophageal reconstruction. Ann Thorac Surg. 1992;54:1110-1115.Maier G, Jehle EC, Becker HD. Functional outcome following oesophagectomy for oesophageal cancer. A prospective mano-metric study. Dis Esophagus. 1995;8:64-69.Naunheim KS, Hanosh J, Zwischenberger J, et al. Esophagectomy in the septuagenarian. Ann Thorac Surg. 1993;56(4):880-884.Nishihra T, Oe H, Sugawara K, et al. Esophageal reconstruction. Reconstruction of the thoracic esophagus with jejunal pedicled segments for cancer of the thoracic esophagus. Dis Esophagus. 1995;8:30-39.Peters JH, Kronson J, Bremner CG, et al. Arterial anatomic con-siderations in colon interposition for esophageal replacement. Arch Surg. 1995;130:858-863.Stark SP, Romberg MS, Pierce GE, et al. Transhiatal versus trans-thoracic esophagectomy for adenocarcinoma of the distal esophagus and cardia. Am J Surg. 1996;172:478-482.Valverde A, Hay JM, Fingerhut A, et al. Manual versus mechani-cal esophagogastric anastomosis after resection for carcinoma. A controlled trial. French Associations for Surgical Research. Surgery. 1996;120:476-483.Watson T, DeMeester TR, Kauer WK, Peters JH, Hagen JA. Esoph-agectomy for end stage benign esophageal disease. J Thorac Cardiovasc Surg. 1998;115(6):1241-1247.Wu M-H, Lai W-W. Esophageal reconstruction for esophageal strictures or resection after corrosive injury. Ann Thorac Surg. 1992;53:798-802.Brunicardi_Ch25_p1009-p1098.indd 109801/03/19 6:06 PM
StomachRobert E. Roses and Daniel T. Dempsey 26chapterThe stomach stores and facilitates the digestion and absorption of ingested food and helps regulate appetite. Treatable dis-eases of the stomach are common, and it is accessible and rela-tively forgiving of surgical manipulation. To provide accurate diagnosis and rational treatment, the physician must under-stand gastric anatomy, physiology, and pathophysiology; this includes a sound understanding of the mechanical, secretory, and endocrine processes by which the stomach accomplishes its important functions and a familiarity with the common benign and malignant gastric disorders. Important historical milestones1-6 that influenced the contemporary understand-ing of gastric disease and surgical therapy are summarized in Table 26-1.ANATOMYAnatomic Relationships and Gross MorphologyThe stomach is the most proximal abdominal organ of the diges-tive tract (Fig. 26-1).7 The part of the stomach attached to the esophagus is called the cardia. Just proximal to the cardia at the gastroesophageal (GE) junction is the anatomically indistinct but physiologically demonstrable lower esophageal sphincter. At the distal end, the readily apparent pyloric sphincter con-nects the stomach to the proximal duodenum. The stomach is relatively fixed at these points, but the majority of the stomach is quite mobile with the shorter lesser curvature on the right and the longer greater curvature on the left.The superior-most part of the stomach is the distensible fundus, bounded superiorly by the diaphragm and laterally by the spleen. The angle of His is where the fundus meets the left side of the GE junction. Generally, the inferior extent of the fun-dus is considered to be the horizontal plane of the GE junction, where the body (corpus) of the stomach begins. The body of the stomach contains most of the parietal (oxyntic) cells, some of which are also present in the cardia and fundus. At the angularis incisura, the lesser curvature turns rather abruptly to the right, marking the anatomic beginning of the antrum, which comprises the distal 25% to 30% of the stomach.Anatomy 1099Anatomic Relationships and Gross Morphology / 1099Arterial and Venous Blood Supply / 1100Lymphatic Drainage / 1100Innervation / 1101Histology / 1102Physiology 1105Acid Secretion / 1105Pepsinogen Secretion / 1108Intrinsic Factor / 1108Gastric Mucosal Barrier / 1109Gastric Hormones / 1109Gastric Motility and Emptying / 1110Diagnosis of Gastric Disease 1115Signs and Symptoms / 1115Diagnostic Tests / 1115Helicobacter Pylori Infection 1117Peptic Ulcer Disease 1120Pathophysiology and Etiology / 1121Clinical Manifestations / 1123Diagnosis / 1123Complications / 1124Medical Treatment of Peptic Ulcer Disease / 1125Surgical Treatment of Peptic Ulcer Disease / 1127Bleeding Peptic Ulcer / 1131Operation for Bleeding Peptic Ulcer / 1133Perforated Peptic Ulcer / 1134Obstructing Peptic Ulcer / 1136Intractable or Nonhealing Peptic Ulcer / 1136Zollinger-Ellison Syndrome / 1136Stress Gastritis and Stress Ulcer 1137Atrophic Gastritis 1138Malignant Neoplasms of  the Stomach 1139Adenocarcinoma / 1139Pathology / 1143Gastric Lymphoma / 1149Gastrointestinal Stromal Tumor / 1149Gastric Neuroendocrine Tumors / 1151Benign Gastric Neoplasms 1152Leiomyoma / 1152Lipoma / 1152Gastroparesis / 1152Massive Upper Gastrointestinal Bleeding / 1152Isolated Gastric Varices / 1153Hypertrophic Gastropathy (Ménétrier’s Disease) / 1153Watermelon Stomach (Gastric Antral Vascular Ectasia) / 1154Dieulafoy’s Lesion / 1154Bezoars/Diverticula / 1154Foreign Bodies / 1154Mallory-Weiss Syndrome / 1155Volvulus / 1155Gastrostomy 1155Postgastrectomy Problems 1156Dumping Syndrome / 1156Diarrhea / 1157Gastric Stasis / 1157Bile Reflux Gastritis and Esophagitis / 1158Roux Syndrome / 1158Gallstones / 1159Weight Loss / 1159Anemia / 1159Bone Disease / 1159Laparoscopic Gastric  Operations 1159Brunicardi_Ch26_p1099-p1166.indd 109901/03/19 7:11 PM 1100The liver, colon, spleen, pancreas, and occasionally the kidney, abut the stomach (Fig. 26-2). The left lateral segment of the liver usually obscures part of the anterior stomach. Infe-riorly, the stomach is attached to the transverse colon by the gastrocolic omentum. The lesser curvature is tethered to the liver by the hepatogastric ligament, also referred to as the lesser omentum or pars flaccida. Posterior to the stomach is the lesser omental bursa and the pancreas.Arterial and Venous Blood SupplyThe stomach is the most richly vascularized portion of the ali-mentary tube with ample blood flow and a dense intramural vascular anastomotic network. The large majority of the gastric blood supply is from the celiac axis via four named arteries (Fig. 26-3). The left and right gastric arteries form an anasto-motic arcade along the lesser gastric curvature, and the right and left gastroepiploic arteries form an arcade along the greater gastric curvature. The left gastric artery is consistently the larg-est artery to the stomach and usually arises directly from the celiac trunk and divides into an ascending and descending branch along the lesser gastric curvature. Approximately 20% of the time, the left gastric artery supplies an aberrant vessel that travels in the gastrohepatic ligament (lesser omentum) to the left side of the liver. Rarely, this is the only arterial blood supply to this part of the liver (replaced left hepatic artery), and inadvertent ligation may lead to clinically significant hepatic ischemia. The more common smaller accessory left hepatic artery may be ligated without significant consequences.The second largest artery to the stomach is the right gas-troepiploic artery, which consistently arises from the gastro-duodenal artery behind the first portion of the duodenum. The left gastroepiploic artery arises from the splenic artery, and, together with the right gastroepiploic artery, forms the rich gastroepiploic arcade along the greater curvature. The right gastric artery usually arises from the hepatic artery near the pylorus and hepatoduodenal ligament and runs proximally along the distal stomach. In the fundus along the proximal greater curvature, the short gastric arteries and veins arise from the splenic circulation. There also may be additional vascular branches to the proximal stomach from the phrenic and splenic circulation.The veins draining the stomach generally parallel the arteries. The left gastric (coronary vein) and right gastric veins usually drain into the portal vein, though occasionally the coro-nary vein drains into the splenic vein. The right gastroepiploic vein drains into the superior mesenteric vein near the inferior border of the pancreatic neck, and the left gastroepiploic vein drains into the splenic vein.The richness of the gastric blood supply and its many anastomotic connections have important clinical implications. At least two of the four named gastric arteries may be occluded or ligated without inducing gastric ischemia. This is done rou-tinely when the stomach is mobilized and pedicled on the right gastric and right gastroepiploic vessels to reach into the neck as an esophageal replacement (see Chapter 25) or during sleeve gastrectomy for weight loss when the gastroepiploic arcade is interrupted proximally and distally prior to gastric resection (see Chapter 27). Following radical subtotal gastrectomy dur-ing which the right and left gastric arteries and both gastroepi-ploic arteries are all ligated, the gastric remnant is adequately supplied by short gastric arteries as long as the splenic artery is patent and intact. Angiographic control of gastric bleeding from a deep ulcer or tumor often requires embolization of more than one feeding artery. Because of the rich venous interconnections in the stomach, a transjugular intrahepatic portosystemic shunt (TIPSS) can effectively decompress esophagogastric varices in patients with portal hypertension.8,9Lymphatic DrainageGenerally speaking, the gastric lymphatics parallel the blood vessels (Fig. 26-4).10 The cardia and medial half of the corpus commonly drain to nodes along the left gastric and celiac axis. The lesser curvature side of the antrum usually drains to the right gastric and pyloric nodes, while the greater curvature half of the distal stomach drains to the nodes along the right gas-troepiploic chain. The proximal greater curvature side of the stomach usually drains into nodes along the left gastroepiploic or splenic hilum. The nodes along both the greater and lesser Key Points1 Whenever testing suggests Helicobacter pylori infec-tion, treatment should be initiated and eradication confirmed.2 Lifelong acid suppression should be considered in any patient admitted to a hospital because of peptic ulcer dis-ease. Acid suppressive medication may be equivalent to sur-gical vagotomy in preventing recurrent peptic ulcer or ulcer complications.3 If possible, gastric resection for peptic ulcer is avoided in the asthenic or high-risk patient.4 Though less common in the United States, gastric cancer is a major cause of cancer-related morbidity and mortality worldwide.5 Diagnostic laparoscopy with peritoneal lavage should be considered in the evaluation of clinical stage 2 and 3 patients with gastric cancer.6 Multimodality therapy for gastric cancer, including resec-tion in combination with perioperative chemotherapy or adjuvant chemoradiotherapy is associated with a survival advantage compared to surgery alone.7 Most patients with primary gastric lymphoma can be treated without gastric resection.8 Localized gastrointestinal stromal tumors of the stomach are treated with full thickness excision. Adjuvant (or neo-adjuvant) imatinib is indicated for higher-risk lesions.9 Gastric neuroendocrine tumors may arise in the presence (types 1 and 2) or absence (type 3) of hypergastrinemia. Type 3 gastric neuroendocrine tumors should usually be treated with subtotal gastrectomy and regional lymphadenectomy.10 Roux-en-Y gastrojejunostomy with a large (>50%) proxi-mal gastric remnant should be avoided because marginal ulceration and/or gastric stasis (Roux syndrome) may become problematic.Brunicardi_Ch26_p1099-p1166.indd 110001/03/19 7:11 PM 1101STOMACHCHAPTER 26curvature commonly drain into the celiac nodal basin. There is a rich anastomotic network of lymphatics that drain the stomach, often in a somewhat unpredictable fashion. Thus, a tumor aris-ing in the distal stomach may give rise to positive lymph nodes in the splenic hilum. The rich intramural plexus of lymphatics and veins accounts for the fact that there can be microscopic evi-dence of malignant cells in the gastric wall at a resection margin that is several centimeters away from palpable malignant tumor. It also helps explain the not infrequent finding of positive lymph nodes, which may be many centimeters away from the primary tumor, with closer nodes that are uninvolved.Not surprisingly, extensive and meticulous lymphadenec-tomy is considered by many surgeons to be an important part of an operation for gastric cancer. Surgeons and pathologists have numbered the primary and secondary lymph node groups to which the stomach drains (see Fig. 26-4).11,12Innervation13The vagus nerves provide the extrinsic parasympathetic innerva-tion to the stomach, and acetylcholine is the most important neu-rotransmitter. From the vagal nucleus in the floor of the fourth cerebral ventricle, the vagus traverses the neck in the carotid sheath and enters the mediastinum, where it gives off the recur-rent laryngeal nerve and divides into several branches around the esophagus. These branches come together again above the esophageal hiatus and form the left (anterior) and right Table 26-1Historic milestones in gastric surgeryDATEEVENTDATEEVENT350 b.c.– 201 a.d. 1363 1586 1600–1700 16881737 1833 1869 1875 1879 1880 1880 1881 1884 1885Existence of gastric ulceration was acknowledged by Diocles of Carystos (350 b.c.), Celsus, and Galen (131–201 a.d.).Guy de Chauliac describes closure of gastric wound.Marcellus Donatus of Mantua describes gastric ulcer at autopsy.Reports of surgeons cutting stomach to remove foreign bodies.Muralto describes duodenal ulcer at autopsy.Morgagni describes both gastric and duodenal ulcer at autopsy.William Beaumont reports data recorded during his care of Alexis St. Martin who developed a gastric fistula from a left upper quadrant musket wound.Maury reportedly performs feeding gastrostomy to palliate esophageal stricture following consultation with Samuel D. Gross.Sidney Jones in London publishes the first successful gastrostomy for feeding.Paen performed distal gastrectomy and gastroduodenostomy. The patient died 5 d later.Rydygier resected a distal gastric cancer, and the patient died 12 h later.Billroth resects distal gastric cancer and performs gastroduodenostomy (Billroth I). Patient Therese Heller recovers and survives 4 mo.Anton Wolfler performs loop gastrojejunostomy to palliate an obstructing distal gastric cancer.Rydygier reports an unsuccessful gastrojejunostomy for benign gastric outlet obstruction.Billroth performs a successful distal gastrectomy and gastrojejunostomy (Billroth II) for gastric cancer.1886188818921902 1891–1913 1920–1950 1943 1952 1953 1955 1957 1980–2000 1990–current 1995–current2000–currentHeineke performs pyloroplasty.Mikulicz performs similar operation.Jaboulay describes bypassing the intact pylorus with gastroduodenostomy.Finney from Baltimore describes pyloroplasty technique.Different techniques of gastrostomy are described by Witzel (1891), Stamm (1894), and Janeway (1913).Subtotal gastrectomy grows popular as an operation for peptic ulcer. Von Haberer and Finsterer proponents.Dragstedt and Owen describe transthoracic truncal vagotomy to treat peptic ulcer disease. By the early 1950s, it is well recognized that some patients developed gastric stasis after this procedure, and transabdominal truncal vagotomy and drainage (pyloroplasty or gastrojejunostomy) become a standard ulcer operation.Farmer and Smithwick describe good results with truncal vagotomy and hemigastrectomy for peptic ulcer.Edwards and Herrington (Nashville) describe truncal vagotomy and antrectomy for peptic ulcer.Zollinger and Ellison describe the eponymous syndrome.Griffith and Harkins (Seattle) describe parietal cell vagotomy (highly selective vagotomy) for the elective treatment of peptic ulcer disease.Japanese surgeons and other surgical groups from East Asia demonstrate that more aggressive lymphadenectomy may improve survival in patients with gastric cancer.Evolving role of laparoscopic techniques in the treatment of surgical gastric disease.Dramatic increase in bariatric operations.Development of natural orifice translumenal endoscopic surgery, such as transgastric appendectomy and peroral pyloromyotomy.Development of robotic gastrectomy.Brunicardi_Ch26_p1099-p1166.indd 110101/03/19 7:11 PM 1102SPECIFIC CONSIDERATIONS PART II(posterior) vagal trunks (mnemonic LARP). Near the GE junc-tion the anterior vagus sends a branch (or branches) to the liver in the gastrohepatic ligament, and continues along the lesser curvature as the anterior nerve of Latarjet (Fig. 26-5). Simi-larly, the posterior vagus sends branches to the celiac plexus and continues along the posterior lesser curvature. The nerves of Latarjet send segmental branches to the body of the stomach before they terminate near the angularis incisura as the “crow’s foot,” sending branches to the antropyloric region. There may be additional branches to the distal stomach and pylorus that travel near the right gastric and/or gastroepiploic arteries. In 50% of patients, there are more than two vagal nerves at the esophageal hiatus. The branch that the posterior vagus sends to the posterior fundus is termed the criminal nerve of Grassi. This branch typically arises above the esophageal hiatus and is easily missed during truncal or highly selective vagotomy (HSV). Vagal fibers originating in the brain synapse with neu-rons in Auerbach’s myenteric plexus and Meissner’s submu-cosal plexus. In the stomach, the vagus nerves affect secretion (including acid), motor function, and mucosal bloodflow and cytoprotection. They also play a role in appetite control and per-haps even mucosal immunity and inflammation.14,15 Most of the axons contained in the vagal trunks are afferent (i.e., carrying stimuli from the viscera to the brain).The extrinsic sympathetic nerve supply to the stomach originates at spinal levels T5 through T10 and travels in the splanchnic nerves to the celiac ganglion. Postganglionic sympa-thetic nerves then travel from the celiac ganglion to the stomach along the blood vessels.Neurons in the myenteric and submucosal plexuses consti-tute the intrinsic nervous system of the stomach. There may be more intrinsic gastric neurons than extrinsic neurons, but their function is poorly understood.The characterization of the vagus as the cholinergic system and the sympathetic system as the adrenergic system of innerva-tion is a misleading oversimplification. Although acetylcholine is an important neurotransmitter mediating vagal function, and epinephrine is important in the sympathetic nerves, both sys-tems (as well as the intrinsic neurons) have various and diverse neurotransmitters, including cholinergic, adrenergic, and pepti-dergic (e.g., substance P and somatostatin).HistologyThere are four distinct layers of the gastric wall: mucosa, sub-mucosa, muscularis propria, and serosa (Fig. 26-6).7 The inner layer of the stomach is the mucosa, which is lined with colum-nar epithelial cells of various types. Beneath the basement mem-brane of the epithelial cells is the lamina propria, which contains connective tissue, blood vessels, nerve fibers, and inflammatory cells. Beneath the lamina propria is a thin muscle layer called the muscularis mucosa, the deep boundary of the mucosal layer of the gut. The epithelium, lamina propria, and muscularis mucosa constitute the mucosa (Fig. 26-7).16 The epithelium of the gastric mucosa is columnar glandular. Scanning electron micrographs show a smooth mucosal carpet punctuated by the openings of the gastric glands or units. The gastric glands are lined with different types of epithelial cells, depending upon their loca-tion in the stomach (Fig. 26-8 and Table 26-2).17,18 There are also endocrine cells present in the gastric glands. Progenitor or stem cells in the isthmus and base of the glands differentiate and BodyFundusEsophagusCardiaPylorusDuodenumPyloric antrum Lessercurvature GreatercurvatureFigure 26-1. Anatomic regions of the stomach. (Reproduced with permission from Zuidema GD, Yeo CJ: Shackelford’s Surgery of the Alimentary Tract, 5th ed. Vol. II. Philadelphia, PA: Elsevier/Saunders; 2002.)Figure 26-2. Anatomic relationships of the stomach. (Reproduced with permission from Zuidema GD, Yeo CJ: Shackelford’s Surgery of the Alimentary Tract, 5th ed. Vol. II. Philadelphia, PA: Elsevier/Saunders; 2002.)Liver (left lobe) Celiac trunk(splenic, gastric, hepatic)Gastrohepatic omentum Stomach(posterior wall)SpleenPancreasTransverse colonLesser omental spaceGastrocolic ligamentRight kidneyHepatoduodenal ligamentGallbladderT lictBrunicardi_Ch26_p1099-p1166.indd 110201/03/19 7:11 PM 1103STOMACHCHAPTER 26replenish sloughed cells on a regular basis. Genetic studies show that there are several different subpopulations of stem cells in the gastric glands and that during conditions of stress even chief cells exhibit the plasticity required to regenerate other types of gastric epithelial cells.19 Throughout the stomach, the luminal carpet consists primarily of mucus-secreting surface epithelial cells (SECs) that extend down into the gland pits for variable distances. These cells also secrete bicarbonate and play an important role in protecting the stomach from injury due to acid, pepsin, and/or ingested irritants. In fact, all epithelial cells of the stomach (except the endocrine cells) contain carbonic anhydrase and are capable of producing bicarbonate.In the cardia, the gastric glands are branched and secrete primarily mucus and bicarbonate, and little acid. In the fundus and body, the glands are more tubular, and the pits are deep. Parietal and chief cells are common in these glands (Fig. 26-9). Histamine-secreting enterochromaffin-like (ECL) cells and somatostatin-secreting D cells are also found. Parietal cells Figure 26-3. Arterial blood supply to the stomach. a. = artery; v. = vein. (Reproduced with permission from Zuidema GD, Yeo CJ: Shackelford’s Surgery of the Alimentary Tract, 5th ed. Vol. II. Philadelphia, PA: Elsevier/Saunders; 2002.)StomachCeliac a.Short gastric arteries(vasa brevia)SpleenDescending colonPancreasDuodenumTransverse colonPylorusSup. pancreatic duodenal a.Abdominal AortaInferior pancreatic duodenal a.Hepatic a.Left gastric a.Branchesto greateromentumSplenic a. & v.L. gastroepiploic a. Sup. mesenteric a. & v. Inferior mesenteric a.Ileocolic a.Jejunum21534a4b6128971011Figure 26-4. Lymph node stations draining the stomach according to the Japanese Research Society for Gastric Cancer. Stations 3 to 6 are commonly removed with D1 gastrectomy. Stations 1, 2, and 7 to 12 are commonly removed with D2 gastrectomy. (Reproduced with permis-sion from Hermanek P, Hutter RVP, Sobin LH, et al: TNM Atlas: Illustrated Guide to the TNM/pTNM Classification of Malignant Tumours, 4th ed. Berlin: Springer-Verlag; 1997.)Brunicardi_Ch26_p1099-p1166.indd 110301/03/19 7:11 PM 1104SPECIFIC CONSIDERATIONS PART IIRight vagus n.Hepatic br. left vagusCeliac br. rt. vagusNerve of LaterjetPyloric br.Left vagus n.Figure 26-5. Vagal innervation of the stomach. br. = branch; n. = nerve; rt. = right. (Reproduced with permission from Menguy R: Surgery of Peptic Ulcer. Philadelphia, PA: Elsevier/Saunders; 1976.)Surface epitheliumGastric pitsLymphoid noduleLamina propria mucosaSubmucosaSmooth muscle layersSerosaMuscularis mucosaeFigure 26-6. Layers of the gastric wall. (Reproduced with permis-sion from Fawcett DW: Bloom and Fawcett’s Textbook of Histology, 11th ed. Philadelphia, PA: Elsevier/Saunders; 1986.)Figure 26-7. Gastric mucosa. (Used with permission from Emma Furth, MD.)Brunicardi_Ch26_p1099-p1166.indd 110401/03/19 7:11 PM 1105STOMACHCHAPTER 26secrete acid and intrinsic factor into the gastric lumen, and bicarbonate into the intercellular space. They have a character-istic ultrastructural appearance with secretory canaliculi (deep invaginations of the surface membrane) and cytoplasmic tubulo-vesicles containing the acid-producing apparatus H+/K+-ATPase (proton pump) (see Fig. 26-9). There are numerous mitochon-dria; in fact, the parietal cell is the most mitochondria-rich cell in the body. When the parietal cell is stimulated, the cytoplasmic tubulovesicles fuse with the membrane of the secretory cana-liculus; when acid production ceases, the process is reversed. Arguably, parietal cells produce the only truly essential sub-stance made by the stomach (i.e., intrinsic factor). Parietal cells tend to occupy the midportion of the gastric glands found in the corpus of the stomach.Chief cells (also called zymogenic cells) secrete pep-sinogen I, which is maximally activated at a pH of 2.5. They tend to be clustered toward the base of the gastric glands and have a low columnar shape. Ultrastructurally, chief cells have the characteristics of protein-synthesizing cells: basal granular endoplasmic reticulum, supranuclear Golgi apparatus, and api-cal zymogen granules (Fig. 26-10). When stimulated, the chief cells produce two immunologically distinct proenzyme forms of pepsinogen: predominantly pepsinogen I and some pepsinogen II, most of which is produced by SECs. These proenzymes are activated in an acidic luminal environment.In the antrum, the gastric glands are again more branched and shallow, parietal cells are rare, and gastrin-secreting G cells and somatostatin-secreting D cells are present. A variety of hormone-secreting cells are present in various proportions throughout the gastric mucosa (Fig. 26-11).20 Histologic analy-sis suggests that in the normal stomach, 13% of the epithelial cells are oxyntic (parietal) cells, 44% are chief (zymogenic) cells, 40% are mucous cells, and 3% are endocrine cells. In gen-eral, the antrum produces gastrin but not acid, and the proximal stomach produces acid but not gastrin. The border between the corpus and antrum migrates proximally with age (especially on the lesser curvature side of the stomach).Deep to the muscularis mucosa is the submucosa, which is rich in branching blood vessels, lymphatics, collagen, vari-ous inflammatory cells, and nerve fibers and ganglion cells of Meissner’s autonomic submucosal plexus. The collagen-rich submucosa gives strength to GI anastomoses. The mucosa and submucosa are folded into the grossly visible gastric rugae, which tend to flatten out as the stomach becomes distended.Below the submucosa is the thick muscularis propria (also referred to as the muscularis externa), which consists of an incomplete inner oblique layer, a complete middle circular layer (continuous with the esophageal circular muscle and the circular muscle of the pylorus), and a complete outer longitudinal layer (continuous with the longitudinal layer of the esophagus and duodenum). Within the muscularis propria is the rich network of autonomic ganglia and nerves that make up Auerbach’s myen-teric plexus. Specialized pacemaker cells, the interstitial cells of Cajal (ICC), also are present.The outer layer of the stomach is the serosa, also known as the visceral peritoneum. This layer provides significant tensile strength to gastric anastomoses. When tumors originating in the mucosa penetrate and breach the serosa, microscopic or gross peritoneal metastases are common, presumably from shedding of tumor cells that would not have occurred if the serosa had not been penetrated. In this way, the serosa may be thought of as an outer envelope of the stomach.PHYSIOLOGYThe stomach stores food and facilitates digestion through a variety of secretory and motor functions. Important secretory functions include the production of acid, pepsin, intrinsic factor, mucus, and a variety of GI hormones. Important motor func-tions include food storage (receptive relaxation and accommo-dation), grinding and mixing, controlled emptying of ingested food, and periodic interprandial “housekeeping.”Acid SecretionHydrochloric acid in the stomach hastens both the physical and (with pepsin) the biochemical breakdown of ingested food. In an acidic environment, pepsin and acid facilitate proteolysis. Gastric acid also inhibits the proliferation of ingested patho-gens, which protects against both infectious gastroenteritis and intestinal bacterial overgrowth and helps to maintain a healthy gastrointestinal microbiome.21 Long-term acid suppression with proton pump inhibitors (PPIs) has been associated with an Surface mucous cellsParietal cellsMucous neck cellsArgentaffin cellChief cellsGastric pitIsthmusNeckBaseFigure 26-8. Mammalian gastric gland from the body of the stom-ach. (Reproduced with permission from Ito S, Winchester RJ: The fine structure of the gastric mucosa in the bat, J Cell Biol. 1963 Mar;16(3):541-577.)Brunicardi_Ch26_p1099-p1166.indd 110501/03/19 7:11 PM 1106SPECIFIC CONSIDERATIONS PART IIincreased risk of community-acquired Clostridium difficile coli-tis and other gastroenteritis, presumably because of the absence of this protective germicidal barrier.22,23Parietal Cell. The parietal cell is stimulated to secrete acid (Fig. 26-12) when one or more of three membrane receptor types is stimulated by acetylcholine (from vagally stimulated enteric neurons), gastrin (from G cells), or histamine (from ECL cells).7,24,25 The enzyme H+/K+-ATPase is the parietal cell proton pump. It is stored within the intracellular tubulovesicles and is the final common pathway for gastric acid secretion. When the parietal cell is stimulated, there is a cytoskeletal rearrangement and fusion of the tubulovesicles with the apical membrane of the secretory canaliculus. The heterodimer assembly of the enzyme subunits into the microvilli of the secretory canalicu-lus results in acid secretion, with extracellular potassium being exchanged for cytosolic hydrogen. Although electroneutral, this is an energy-requiring process because the hydrogen is secreted against a gradient of at least 1 million-fold, which explains why the parietal cell is packed with energy producing mito-chondria. During acid production, potassium and chloride are also secreted into the apical secretory canaliculus through sepa-rate channels, providing potassium to exchange for H+ via the H+/K+-ATPase, and chloride to accompany the secreted hydrogen. At the basolateral membrane, the combined activity of various SCMTVFigure 26-9. Ultrastructural features of the parietal (oxyntic) cell. SC = secretory canaliculus; M = mitochondria; TV = tubulovesicle. (Reproduced with permission from Ming S-C, Goldman H: Pathol-ogy of the Gastrointestinal Tract, 2nd ed. Baltimore, MD: Williams & Wilkins; 1998.)ZGGAGERFigure 26-10. Ultrastructural features of the chief (zymogenic) cell. GA = Golgi apparatus; GER = granular endoplasmic reticu-lum; ZG = zymogen granule. (Reproduced with permission from Ming S-C, Goldman H: Pathology of the Gastrointestinal Tract, 2nd ed. Baltimore, MD: Williams & Wilkins; 1998.)Table 26-2Epithelial cells of the stomachCELL TYPEDISTINCTIVE ULTRASTRUCTURAL FEATURESMAJOR FUNCTIONSSurface-foveolar mucous cellsApical stippled granules up to 1 μm in diameterProduction of neutral glycoprotein and bicarbonate to form a gel on the gastric luminal surface; neutralization of hydrochloric acidaMucous neck cellHeterogeneous granules 1–2 μm in diameter dispersed throughout the cytoplasmProgenitor cell for all other gastric epithelial cells; glycoprotein production; production of pepsinogens I and IIOxyntic (parietal) cellSurface membrane invaginations (canaliculi); tubulovesicle structures; numerous mitochondriaProduction of hydrochloric acid; production of intrinsic factor; production of bicarbonateChief cellModerately dense apical granules up to 2 μm in diameter; prominent supranuclear Golgi apparatus; extensive basolateral granular endoplasmic reticulumProduction of pepsinogens I and II, and of lipaseCardiopyloric mucous cellMixture of granules like those in mucous neck and chief cells; extensive basolateral granular endoplasmic reticulumProduction of glycoprotein; production of pepsinogen IIEndocrine cellsSee Figure 26-11 aBicarbonate is probably produced by other gastric epithelial cells in addition to surface-foveolar mucous cells.Reproduced with permission from Ming S-C, Goldman H: Pathology of the Gastrointestinal Tract, 2nd ed. Baltimore, MD: Williams & Wilkins; 1998.Brunicardi_Ch26_p1099-p1166.indd 110601/03/19 7:11 PM 1107STOMACHCHAPTER 26cotransporters and ion exchangers accomplishes intracellular pH regulation and electrolyte homeostasis.24The normal human stomach contains approximately 1 billion parietal cells, and total gastric acid production is pro-portional to parietal cell mass. Almost all of the parietal cells are in the proximal 2/3 stomach, though there are some parietal cells found in gastric antral glands. The potent acid-suppressing PPI drugs irreversibly interfere with the function of the H+/K+-ATPase molecule. These agents must be incorporated into the activated enzyme to be effective and thus work best when taken before or during a meal (when the parietal cell is stimulated). When PPI therapy is stopped, acid secretory capability gradu-ally returns (within days) as new H+/K+-ATPase is synthesized.Gastrin, acetylcholine, and histamine stimulate the parietal cell to secrete hydrochloric acid (see Fig. 26-12). Gastrin binds to type B cholecystokinin (CCK2) receptors on ECL cells and stimulates ECL cell histamine release, which binds to H2 recep-tors on the parietal cell. This stimulates adenylatecyclase (via a G-protein–linked mechanism) and increases cAMP which acti-vates protein kinases, leading to increased levels of phospho-proteins and activation of the proton pump. Gastrin also binds to CCK2 receptors on the parietal cell, but this is less important for acid secretion than the gastrin effect on ECL cells. Acetyl-choline from intrinsic neurons binds to M3 muscarinic recep-tors on the parietal cell, which (like gastrin binding to CCK2 receptors) stimulates phospholipase C via a G-protein–linked mechanism leading to increased production of inositol trispho-sphate from membrane bound phospholipids. Inositol trisphos-phate stimulates the release of calcium from intracellular stores, which leads to activation of protein kinases and activation of H+/K+-ATPase. Somatostatin released from mucosal D cells in the antral and oxcyntic mucosa in response to luminal acid binds to SSTR2 receptors on parietal cells and inhibits acid release directly. Somatostatin also inhibits acid secretion in a paracrine fashion, binding to nearby ECL cells in the oxcyntic mucosa and decreasing histamine release, and binding to nearby antral G cells to inhibit gastrin release.26Physiologic Acid Secretion.27 Food ingestion is the physi-ologic stimulus for acid secretion (Fig. 26-13). The acid secre-tory response that occurs after a meal is traditionally described Oxyntic mucosaOther3%D19%G49%EC29%Other14%D26%EC25%ECL35%Pyloric mucosaFigure 26-11. Endocrine cells of the stomach—proportion by site. D = d cell (somatostatin); EC = enterochromaffin cell; ECL = enterochromaffin-like cell (histamine); G = g cell (gastrin). (Repro-duced with permission from Feldman M, Friedman LS, Sleisenger MH, et al: Sleisenger and Fordtran’s Gastrointestinal and Liver Disease, 7th ed. Philadelphia, PA: Elsevier/Saunders; 2002.)Adenylate cyclaseATPHistamineInterstitiumLumenSomatostatinGi proteinGs proteinIP3PIP2Ca++K+ channelK+ClchannelCl-H+K+CCK8 receptorM3 receptorH+/K+-ATPaseGs proteinActivation ofother kinasescAMPActivatesprotein kinasesGastrinAcetylcholinePLCSomatostatinreceptorH2 receptorGs proteinFigure 26-12. Control of acid secretion in the parietal cell. ATP = adenosine triphosphate; cAMP = cyclic adenosine monophosphate; CCK = cholecystokinin; H2 = histamine 2; IP3 = inositol trisphosphate; PIP2 = phosphatidylinositol 4,5-bisphosphate; PLC = phospholipase C. (Reproduced with permission from Zuidema GD, Yeo CJ: Shackelford’s Surgery of the Alimentary Tract, 5th ed. Vol. II. Philadelphia, PA: Elsevier/Saunders; 2002.)Brunicardi_Ch26_p1099-p1166.indd 110701/03/19 7:11 PM 1108SPECIFIC CONSIDERATIONS PART IIin three phases: cephalic, gastric, and intestinal.28,29 The cephalic or vagal phase begins with the thought, sight, smell, and/or taste of food. These stimuli activate several cortical and hypotha-lamic sites (e.g., tractus solitarius, dorsal motor nucleus, and dorsal vagal complex), and signals are transmitted to the stom-ach by the vagal nerves which stimulate enteric submucosal neurons. Acetylcholine is released, leading to stimulation acid secretion from parietal cells. Vagal stimulation also leads to gas-trin release from antral G cells via CGRP, and sensitizes ECL cells to gastrin.30,31 Although the acid secreted per unit of time in the cephalic phase is greater than in the other two phases, the cephalic phase is shorter. Thus, the cephalic phase accounts for no more than 30% of total acid secretion in response to a meal. Sham feeding (chewing and spitting) stimulates gastric acid secretion only via the cephalic phase, and it results in acid secretion that is about half of that seen in response to IV penta-gastrin or histamine.When food reaches the stomach, the gastric phase of acid secretion begins. This phase lasts until the stomach is empty and accounts for about 60% of the total acid secretion in response to a meal. The gastric phase of acid secretion has several compo-nents. Amino acids and small peptides directly stimulate antral G cells to secrete gastrin, which is carried in the bloodstream to the ECL and parietal cells, stimulating acid secretion in an endo-crine fashion. In addition, proximal gastric distention stimulates acid secretion via a vagovagal reflex arc, which is mitigated by truncal or highly selective vagotomy (HSV). Antral disten-tion also stimulates antral gastrin secretion. Finally, ongoing cephalic vagal input stimulates gastrin release, which in turn stimulates histamine release from ECL cells and acid secretion.The intestinal phase of gastric secretion is poorly under-stood. It is thought to be mediated by a hormone released from the proximal small bowel mucosa in response to luminal chyme. This phase starts when gastric emptying of ingested food begins, and it continues as long as nutrients remain in the proximal small intestine. It accounts for about 10% of meal-induced acid secretion.Interprandial basal acid secretion is 2 to 5 mEq hydrochlo-ric acid per hour, about 10% of maximal acid output (MAO), and it is greater at night. Basal acid secretion probably contrib-utes to the relatively low bacterial counts found in the stomach. Basal acid secretion is reduced 75% to 90% by vagotomy or continuous H2-receptor blockade.The pivotal role that ECL cells play in the regulation of gastric acid secretion is emphasized in Fig. 26-13. The acid stimulatory effect of gastrin is largely mediated by histamine released from mucosal ECL cells. H2-receptor knockout mice do not secrete acid in response to gastrin.24 This explains why the H2-receptor antagonists (H2RAs) are effective inhibitors of acid secretion, even though histamine is only one of three parietal cell stimulants. The mucosal D cell, which releases somatosta-tin, is also an important regulator of acid secretion. Somatostatin inhibits histamine release from ECL cells and gastrin release from antral G cells. The function of D cells can be inhibited by Helicobacter pylori infection, resulting in an exaggerated acid secretory response (see “Helicobacter pylori Infection”).Proton pump inhibitors are potent suppressors of gastric acid secretion. This results in hypergastrinemia and conse-quent ECL stimulation. In patients on long-term PPI (median 5.5 years), the degree of hypergastrinemia does not appear to correlate with the length of treatment.32 Chronic PPI use has been associated with ECL hyperplasia and type 1 gastric neuro-endocrine tumor, but so far there has been no evidence linking these agents to malignant gastric epithelial or neuroendocrine tumors. Gastrin levels return to normal within a few days of PPI cessation, but during this time, some patients may experience gastric hyperacidity and dyspeptic symptoms, which may lead to difficulty in getting patients off the medication.33,34 This is less likely to occur with short-term PPI use and may be amelio-rated by PPI dose tapering and/or initiation of H2 blockers prior to PPI cessation.Pepsinogen SecretionThe most potent physiologic stimulus for pepsinogen secre-tion from chief cells is food ingestion; acetylcholine is the most important mediator. Somatostatin inhibits pepsinogen secre-tion. Pepsinogen I is produced by chief cells in acid producing glands, whereas pepsinogen II is produced by chief cells and by SECs in both acid producing and gastrin producing (i.e., antral) glands. Pepsinogen is cleaved to the active pepsin enzyme in an acidic environment and is maximally active at pH 2.5, and inactive at pH >5, although pepsinogen II may be activated over a wider pH range than pepsinogen I. Pepsin catalyzes the hydro-lysis of proteins and is denatured at alkaline pH. Serum levels of pepsinogen I and II are increased in helicobacter gastritis, so elevated pepsinogen I and II levels and positive helicobacter serology are presumptive evidence of active helicobacter infec-tion. Longstanding helicobacter infection may lead to atrophic gastritis, suggested by decreased pepsinogen I/II ratio (from chief cell loss) and hypergastriemia (from parietal cell loss and hypochlorhydria).35Intrinsic FactorActivated parietal cells secrete intrinsic factor in addition to hydrochloric acid. Presumably the stimulants are similar, but MealVagusD-cellECLcellParietal cellGastrinSomatostatinHistamine++++–––++++AcetylcholineG-cellFigure 26-13. Physiologic control of acid secretion. ECL = enterochromaffin-like. (Reproduced with permission from Zuidema GD, Yeo CJ: Shackelford’s Surgery of the Alimentary Tract, 5th ed. Vol. II. Philadelphia, PA: Elsevier/Saunders; 2002.)Brunicardi_Ch26_p1099-p1166.indd 110801/03/19 7:11 PM 1109STOMACHCHAPTER 26acid secretion and intrinsic factor secretion may not be linked. Intrinsic factor binds to luminal vitamin B12, and the complex is absorbed in the terminal ileum via mucosal receptors. Vitamin B12 deficiency can be life threatening, and patients with total gastrectomy or pernicious anemia (i.e., patients with no pari-etal cells) require B12 supplementation by a nonenteric route. Some patients develop vitamin B12 deficiency following gastric bypass, presumably because there is insufficient intrinsic fac-tor present in the small proximal gastric pouch and oral B12 intake may be decreased. Under normal conditions, a signifi-cant excess of intrinsic factor is secreted, and acid-suppressive medication does not appear to inhibit intrinsic factor production and release.Gastric Mucosal BarrierThe stomach’s durable resistance to autodigestion by caustic hydrochloric acid and active pepsin is intriguing. Some of the important elements of gastric barrier function and cytoprotection are listed in Table 26-3.36,37 When these defenses break down, ulceration occurs. A variety of factors are important in maintain-ing an intact gastric mucosal layer.38 The mucus and bicarbonate secreted by SECs form an unstirred mucous gel with a favorable pH gradient. Cell membranes and tight junctions prevent hydro-gen ions from gaining access to the interstitial space. Hydrogen ions that do break through are buffered by the alkaline tide cre-ated by basolateral bicarbonate secretion from stimulated pari-etal cells. Any sloughed or denuded SECs are rapidly replaced by migration of adjacent cells, a process known as restitution. Mucosal blood flow plays a crucial role in maintaining a healthy mucosa, providing nutrients and oxygen for the cellular func-tions involved in cytoprotection. During acid secretion, there is a tremendous gradient favoring the movement of hydrogen ions from the lumen to the interstitium. This “back-diffused” hydrogen is buffered and rapidly removed by the rich blood supply. When “barrier breakers” such as bile or aspirin lead to increased back-diffusion of hydrogen ions from the lumen into the lamina propria and submucosa, there is a protective increase in mucosal blood flow. If this protective response is blocked, gross ulceration can occur. Important mediators of these protec-tive mechanisms include prostaglandins, nitric oxide, intrinsic nerves, and peptides (e.g., calcitonin gene-related peptide, gas-trin-releasing peptide [GRP], gastrin, and heat shock proteins). Sucralfate acts locally to enhance mucosal defenses. Protec-tive reflexes involve afferent sensory neurons, and they can be blocked by the application of topical anesthetics to the gastric mucosa, or the experimental destruction of the afferent sensory nerves. In addition to these local defenses, there are important protective factors in saliva, duodenal secretions, and pancreatic or biliary secretions.Gastric Hormones13,39The stomach is quite an elegant endocrine organ. It is the source of important peptides which work in an autocrine (EGF and surface epithelial cells, TGF and parietal cells), paracrine (somatostatin), endocrine (gastrin), and/or neurocrine (ghrelin) fashion.Gastrin. Gastrin is produced by antral G cells and is the major hormonal stimulant of acid secretion during the gastric phase predominantly via an endocrine effect on histamine generating ECL cells and to a lesser extent via a direct effect on parietal cells. A variety of molecular forms exist: big gastrin (34 amino acids; G34), little gastrin (17 amino acids; G17), and mini-gastrin (14 amino acids; G14). The large majority of gastrin released by the human antrum is G17. The biologically active pentapeptide sequence at the C-terminal end of gastrin is identical to that of CCK. Luminal peptides and amino acids are the most potent stimulants of gastrin release, and luminal acid is the most potent inhibitor of gastrin secretion. The latter effect is predominantly mediated in a paracrine fashion by somatostatin released from antral D cells. Gastrin-stimulated acid secretion is significantly blocked by H2 antagonists, suggesting that the principal media-tor of gastrin-stimulated acid production is histamine from mucosal ECL cells and not direct stimulation of parietal cells by gastrin (see Fig. 26-13). In fact, chronic hypergastrinemia is associated with hyperplasia of gastric ECL cells and, rarely, gastric type I gastric neuroendocrine tumors (type I gastric car-cinoid). Gastrin is trophic to gastric parietal cells and to other GI mucosal cells including gastric stem cells. It also is a regulator of gastric cellular proliferation, migration, invasion, apoptosis and angiogenesis.40 Mucosal biopsies of the gastric body from patients with gastrinoma show a thick mucosa with excess pari-etal cells, while similar biopsies in patients years after antrec-tomy (i.e., low gastrin state) show thin mucosa and decreased parietal cells. In animal studies, gastrin administration has been shown to stimulate the growth of established colon cancers and to cause pancreatic acinar cell hyperplasia.41 Important causes of hypergastrinemia include pernicious anemia, acid-suppressive medication, gastrinoma, retained antrum following distal gas-trectomy and Billroth II surgery, and vagotomy.42,43Ghrelin. Ghrelin, first described in 1999, is a small peptide that is produced mainly in the stomach.44,45 It is produced by specialized P/D1 endocrine cells in gastric oxyntic glands. Ninety percent of the body’s ghrelin stores are in the stomach and duodenum. Ghrelin is a potent secretagogue of pituitary growth hormone and a weak secretogogue for ACTH and pro-lactin. It appears to be a major orexigenic regulator of appetite. Ghrelin crosses the blood brain barrier and stimulates appetite via hypothalamic receptors. It also stimulates appetite periph-erally by stimulating vagal afferent fibers in the gastric wall. Table 26-3Important components and mediators of mucosal defenses in the stomachComponentsMucous barrierBicarbonate secretionEpithelial barrier Hydrophobic phospholipids Tight junctions RestitutionMicrocirculation (reactive hyperemia)Afferent sensory neuronsMediatorsProstaglandinsNitric oxideEpidermal growth factorCalcitonin gene-related peptideHepatocyte growth factorHistamineGastrin-releasing peptideBrunicardi_Ch26_p1099-p1166.indd 110901/03/19 7:11 PM 1110SPECIFIC CONSIDERATIONS PART IIWhen ghrelin is elevated, appetite is stimulated, and when it is suppressed, appetite is decreased. Typically, ghrelin levels are elevated before a meal and decreased postprandially. Levels are high during starvation and decreased during hyperglycemia. Obesity and insulin resistance is associated with low ghrelin levels, but resection of the primary source of this hormone (i.e., the stomach) may partly account for the anorexia and weight loss seen in some patients following gastric resection including sleeve gastrectomy (Fig. 26-14).46-48 The effect of RYGBP on ghrelin physiology is controversial. This very effective weight loss procedure has been shown by some investigators to be asso-ciated with suppression of plasma ghrelin levels (and appetite) in humans (Fig. 26-15A).49,50Other groups have failed to show a significant decrease in ghrelin levels following gastric bypass but have found such decreases following sleeve gastrectomy, another effective weight loss operation (Fig. 26-15B).50 Possibly, subtle differ-ences in operative technique, patient selection, or experimental (including assay) conditions account for the disparate results of studies on the effect of bariatric surgery on ghrelin levels in obese patients. Interestingly the two common metabolites of ghrelin have different physiologic effects: acyl-ghrelin increases gastric emptying and appetite while deacyl ghrelin decreases gastric emptying and induces satiety.51 Obviously appetite con-trol is complex with redundant and overlapping orexigenic and anorexigenic pathways and signals.39,52Somatostatin. Somatostatin is produced by D cells located throughout the gastric mucosa. The predominant form in humans is somatostatin 14, though somatostatin 28 is present as well. The major stimulus for somatostatin release is antral acidification; acetylcholine from vagal nerve fibers inhibits its release. Somatostatin inhibits acid secretion from parietal cells and gastrin release from G cells. It also decreases histamine release from ECL cells. The proximity of the D cells to these target cells suggests that the primary effect of somatostatin is mediated in a paracrine fashion, but an endocrine (i.e., blood-stream) effect also is possible.Gastrin-Releasing Peptide. GRP is the mammalian equiva-lent of bombesin, a hormone discovered more than two decades ago in an extract of skin from a frog. In the antrum, GRP stimu-lates both gastrin and somatostatin release by binding to recep-tors on the G and D cells. There are nerve terminals ending near the mucosa in the gastric body and antrum, which are rich in GRP immunoreactivity. When GRP is given peripherally, it stimulates acid secretion, but when it is given centrally into the cerebral ventricles of animals, it inhibits acid secretion, appar-ently via a pathway involving the sympathetic nervous system.Leptin. Leptin is a protein primarily synthesized in adipocytes. It is also made by chief cells in the stomach, the main source of leptin in the GI tract.39,53 Leptin works at least in part via vagally mediated pathways to decrease food intake in animals. Not surprisingly, leptin, a satiety signal hormone, and ghrelin, a hunger signal hormone, are both synthesized in the stomach, an organ increasingly recognized as central to the mechanisms of appetite control.39,52Autocrine Proteins. Gastric surface epithelial cells secrete a variety of proteins that are important regulators of SEC health, including trefoil factor family proteins and heat shock pro-teins.38 Parietal cells may also be influenced by molecules they secrete including transforming growth factor-α.Gastric Motility and EmptyingGastric motor function has several purposes.43,54-56 Interprandial motor activity clears the stomach of undigested debris, sloughed cells, and mucus. When feeding begins, the stomach relaxes to accommodate the meal. Regulated motor activity then breaks down the food into small particles and controls the output into the duodenum. The stomach accomplishes these functions by coordinated smooth muscle relaxation and contraction of the various gastric segments (proximal, distal, and pyloric). Smooth muscle myoelectric potentials are translated into muscular activity, which is modulated by extrinsic and intrinsic innerva-tion and hormones. The mechanisms by which gastric distention is translated into a neurohormonal satiety signal have only been partially elucidated.39,52Intrinsic Gastric Innervation. The extrinsic parasympa-thetic and sympathetic gastric innervation was discussed pre-viously in “Innervation.” The intrinsic innervation consists of ganglia and nerves that constitute the enteric nervous system (Fig. 26-16).57 There are a variety of neurotransmitters that effect gastric smooth muscle; these are generally grouped as excitatory (augment muscular activity) and inhibitory (decrease muscular activity). Important excitatory neurotransmitters include acetylcholine, the tachykinins, substance P, and neu-rokinin A. Important inhibitory neurotransmitters include nitric oxide (NO) and vasoactive intestinal peptide (VIP). Serotonin has been shown to modulate both contraction and relaxation. A variety of other molecules affect motility, including GRP, hista-mine, neuropeptide Y, norepinephrine, and endogenous opioids.Specialized cells in the muscularis propria also are impor-tant modulators of GI motility. These cells, called interstitial cells of Cajal, are distinguishable histologically from neurons and myocytes and appear to amplify both cholinergic excitatory 300200Plasma ghrelin (fmol/mL)100NormalcontrolsGastrectomizedpatients0*Figure 26-14. Ghrelin levels are decreased after gastrectomy. (Reproduced with permission from Ariyasu H, Takaya K, Tagami T, et al: Stomach is a major source of circulating ghrelin, and feed-ing state determines plasma ghrelin-like immunoreactivity levels in humans, J Clin Endocrinol Metab. 2001 Oct;86(10):4753-4758.)Brunicardi_Ch26_p1099-p1166.indd 111001/03/19 7:11 PM 1111STOMACHCHAPTER 26Figure 26-15. A and B. Ghrelin secretion after bariatric surgery. Some investigators have suggested that ghrelin secretion is dramatically decreased after gastric bypass. Other groups have shown statistically insig-nificant changes in ghrelin levels after gastric bypass, (RYGBP) but significant decreases after sleeve gastrectomy (SG). A. green = gastric bypass; blue = obese controls; red = normal weight controls; B. blue = fasting; pink = postprandial. B. Top = RYGBP; B bottom = SG. (A, Repro-duced with permission from Cummings DE, Weigle DS, Frayo RS, et al: Plasma ghre-lin levels after diet-induced weight loss or gastric bypass surgery, N Engl J Med. 2002 May 23;346(21):1623-1630. B, Reproduced with permission from Karamanakos SN, Vagenas K, Kalfarentzos F, et al: Weight loss, appetite suppression, and changes in fasting and postprandial ghrelin and peptide-YY levels after Roux-en-Y gastric bypass and sleeve gastrectomy: A prospec-tive, double blind study, Ann Surg. 2008 Mar;247(3):401-407.)Plasma ghrelin level (pg/mL)Detection limitTime6 a.m.8 a.m.10 a.m.noon2 p.m.4 p.m.6 p.m.8 p.m.10 p.m.080100200300400500600700800BreakfastLunchDinnerA1200P = 0.06P = 0.15P = 0.16P = 0.13P = 0.01P = 0.03P = 0.01P = 0.0310008006004002000PreGhrelin (pg/mL)Ghrelin (pg/mL)3Time (months)Time (months)612Pre36129008007006005004003002001000Band nitrergic inhibitory input to the smooth muscle of the stom-ach and intestine.58 They are thought to be the cell of origin for gastrointestinal stromal tumors (GISTs), which are the most common mesenchymal neoplasms in the GI tract.Segmental Gastric Motility.13,58,59 In general, the proximal stomach serves a short-term food storage function and helps regulate basal intragastric tone, and the distal stomach mixes and grinds the food. The pylorus helps the latter process when Brunicardi_Ch26_p1099-p1166.indd 111101/03/19 7:11 PM 1112SPECIFIC CONSIDERATIONS PART IIclosed, facilitating retropulsion of the solid food bolus back into the body of the stomach for additional breakdown. The pylorus opens intermittently to allow metered emptying of liquids and small solid particles into the duodenum.Most of the motor activity of the proximal stomach con-sists of slow tonic contractions and relaxations, lasting up to 5 minutes. This activity is the main determinant of basal intra-gastric pressure, an important determinant of liquid empty-ing. Rapid phasic contractions may be superimposed on the slower tonic motor activity. When food is ingested, intragastric pressure falls as the proximal stomach relaxes. This proximal relaxation is mediated by two important vagovagal reflexes: receptive relaxation and gastric accommodation. Receptive relaxation refers to the reduction in gastric tone associated with the act of swallowing. This occurs before the food reaches the stomach and can be reproduced by mechanical stimulation of the pharynx or esophagus. Gastric accommodation refers to the proximal gastric relaxation associated with distention of the stomach.60 Accommodation is mediated through stretch recep-tors in the gastric wall and does not require esophageal or pha-ryngeal stimulation. Initially, as the meal enters the stomach, there is a drop in intragastric pressure mediated by nitric oxide. As the meal progresses, the intragastric pressure rises, parallel with the onset of satiety. Interestingly, satiety does not seem to be associated with any specific level of intragastric pressure. Obese patients have a delayed onset of satiety, so an obvious hypothesis to be tested is that a pharmacologic-induced increase in gastric tone leads to increased satiety and decreased food intake in this patient group.60 Because receptive relaxation and accommodation are mediated by afferent and efferent vagal fibers, they are significantly altered by truncal and highly selec-tive vagotomy. Both these operations result in decreased gastric compliance, shifting the volume/pressure curve to the left. Pre-sumably for any given amount of food ingested, the intragastric pressure is higher, and perhaps in some patients the onset of satiety is sooner. This may be one explanation for weight loss associated with vagotomy,61 and it also helps explain acceler-ated liquid gastric emptying postvagotomy, which likely con-tributes to dumping symptoms in some patients.NO and VIP are the principal mediators of proximal gas-tric relaxation. But a variety of other agents increase proximal gastric relaxation and compliance, including dopamine, gastrin, CCK, secretin, GRP, and glucagon. Proximal gastric tone also is decreased by duodenal distention, colonic distention, and ileal perfusion with glucose (ileal brake).The distal stomach breaks up solid food and is the main determinant of gastric emptying of solids. Slow waves of myo-electric depolarization sweep down the distal stomach at a rate of about three per minute. These waves originate from the proxi-mal gastric pacemaker, high on the greater curvature.62 The pac-ing cells appear to be the interstitial cells of Cajal, which have been shown to have a similar function in the small intestine and colon. Most of these myoelectric waves are below the thresh-old for smooth muscle contraction in the quiescent state and thus are associated with negligible changes in pressure. Neural and/or hormonal input, which increases the plateau phase of the action potential, can trigger muscle contraction, resulting in a peristaltic wave associated with the electrical slow wave and of the same frequency (three per minute) (Fig. 26-17). There are measurable abnormalities in gastric slow wave activity in disor-ders of gastric motility such as gastroparesis, but reliable elec-trogastrogaphy to aid in the diagnosis and management of these problems is not yet a clinical reality. It is likely that implantable gastric pacemakers benefit some patients with gastroparesis by favorably impacting this myoelectric coupling, normalizing gas-tric slow wave patterns.During fasting, distal gastric motor activity is controlled by the migrating motor complex (MMC), the “gastrointesti-nal housekeeper” (Fig. 26-18). The purported function of the MMC is to sweep along any undigested food, debris, sloughed cells, and mucus after the fed phase of digestion is complete. The MMC lasts approximately 100 minutes (longer at night, shorter during daytime) and is divided into four phases. Phase I (about half the length of the entire cycle) is a period of relative motor inactivity. High-amplitude muscular contractions do not occur in phase I of the MMC. Phase II (about 25% of the entire MMC cycle) consists of some irregular, high-amplitude, gener-ally nonpropulsive contractions. Phase III, a period of intense, Figure 26-16. Enteric nervous sys-tem. (Reproduced with permission from Friedman SL, McQuaid KR, Grendell JH: Current Diagnosis and Treatment in Gastroenterology, 2nd ed. New York, NY: McGraw-Hill Education; 2003.)Parasympathetic (vagal) nerveMesenteryPerivascular sympathic nerveMuscularis externa (longitudinal)Muscularis externa (circular)Subepethelial plexusMuscularis mucosaSubmucosaVillusIntestinal lumenDeep muscularis plexusSerosaTertiary branchSecondary branchGanglionSubmucosal plexusMyenteric plexusBrunicardi_Ch26_p1099-p1166.indd 111201/03/19 7:11 PM 1113STOMACHCHAPTER 26regular (about three per minute), propulsive contractions, only lasts about 5 to 10 minutes. Most phase III complexes of the GI MMC begin in the stomach, and the frequency approximates that of the myoelectric gastric slow wave. Phase IV is a transi-tion period.Neurohormonal control of the MMC is poorly understood, but it appears that different phases are regulated by different mechanisms. For example, vagotomy abolishes phase II of the gastric MMC but has little influence on phase III that persists even in the autotransplanted stomach, totally devoid of extrinsic neural input. This suggests that phase III is regulated by intrin-sic nerves and/or hormones. Indeed, the initiation of phase III of the MMC in the distal stomach corresponds temporally to elevation in serum levels of motilin, a hormone produced in the duodenal mucosa. Resection of the duodenum abolishes dis-tal gastric phase III in dogs, and resection of the duodenum in humans (e.g., with pancreaticoduodenectomy, the Whipple pro-cedure) commonly results in early postoperative delayed gastric emptying. There are clearly motilin receptors on gastric smooth muscle and nerves. Other modulators of gastric MMC activ-ity include NO, endogenous opioids, intrinsic cholinergic and adrenergic nerves, and duodenal pH. The onset of MMC phase III signals the return of hunger in humans, but oddly ghrelin, a major orexigenic hormone, appears to have little to do with phase III.63Feeding abolishes the MMC and leads to the fed motor pattern. The fed motor pattern of gastric activity starts within 10 minutes of food ingestion and persists until all the food has left the stomach. The neurohormonal initiator of this change is unknown, but CCK and the vagus appear to play some role since sham feeding transiently induces antral motor activity resembling the fed motor pattern which is blocked by the CCK receptor antagonist loxiglumide. Gastric motility during the fed pattern resembles phase II of the MMC, with irregular but con-tinuous phasic contractions of the distal stomach. During the fed state, about half of the myoelectric slow waves are associated with strong higher frequency distal gastric contractions. Some are prograde and some are retrograde, serving to mix and grind the solid components of the meal. The magnitude of gastric con-tractions and the duration of the pattern are influenced by the consistency and composition of the meal.The pylorus functions as an effective regulator of gastric emptying and an effective barrier to duodenogastric reflux. Bypass, transection, or resection of the pylorus may lead to uncontrolled gastric emptying of food and the dumping syn-drome (see “Postgastrectomy Problems”). Pyloric dysfunction IntracellularrecordingTensionQuiescentStimulated0 mv0 5 g -70 1122Figure 26-17. The relationship between intracellular electrical activity and muscle cell contraction. Note that contractile activity is always associated with electrical activity, but the converse is not so. During mechanical quiescence, there are regular depolarizations that do not reach threshold. In the stimulated state, the threshold for contraction is reached, and motor activity is demonstrable. (Reproduced with permission from Kim CH, Malagelada JR: Electrical activity of the stomach: clinical implications, Mayo Clin Proc. 1986 Mar;61(3):205-210.)Figure 26-18. Migrating motor complex, the fasting pattern of GI activity. During phase III of the migrating motor complex, effective peri-staltic waves progress from the stomach to the distal small intestine. (Reproduced with permis-sion from Rees WD, Malagelada JR, Miller LJ, et al: Human interdigestive and postprandial gas-trointestinal motor and gastrointestinal hormone patterns, Dig Dis Sci. 1982 Apr;27(4):321-329.)AntrumProximal duodenumDistal duodenumJejunum1 min100 mm Hg100 mm Hg100 mm Hg100 mm HgPhase IIPhase IIIPhase IVPhase IBrunicardi_Ch26_p1099-p1166.indd 111301/03/19 7:11 PM 1114SPECIFIC CONSIDERATIONS PART IIor disruption may also result in uncontrolled entry of duode-nal contents into the stomach. Perfusion of the duodenum with lipids, glucose, amino acids, hypertonic saline, or hydrochloric acid results in closure of the pylorus and decreased transpylo-ric flow. Ileal perfusion with fat has the same effect. A variety of neurohumoral pathways are involved with these physiologic responses, and there is evidence that different pathways may be involved for different stimuli.The pylorus is readily apparent grossly as a thick ring of muscle and connective tissue. The density of nerve tissue in the pyloric smooth muscle is several folds higher than in the antrum, with increased numbers of neurons staining positive for substance P, neuropeptide Y, VIP, and galanin. Interstitial cells of Cajal are closely associated with pyloric myocytes, and the myoelectric slow wave of the pylorus has the same frequency as that seen in the distal stomach. The motor activity of the pylo-rus is both tonic and phasic. During phase III of the MMC, the pylorus is open as gastric contents are swept into the duodenum. During the fed phase, the pylorus is closed most of the time. It relaxes intermittently, usually in synchronization with lower-amplitude, minor antral contractions. The higher-amplitude, more major antral contractions are usually met with a closed pylorus, facilitating retropulsion and further grinding of food.Modulation of pyloric motor activity is complex. There is evidence for both inhibitory and excitatory vagal pathways. Some contractile vagal effects are mediated by opioid pathways because they are blocked by naloxone. Electrical stimulation of the duodenum causes the pylorus to contract, whereas electrical stimulation of the antrum causes pyloric relaxation. Nitric oxide is an important mediator of pyloric relaxation. Other molecules that may play a physiologic role in controlling pyloric smooth muscle include serotonin, VIP, prostaglandin E1, and galanin (pyloric relaxation); and histamine, CCK, and secretin (pyloric contraction).Gastric Emptying.13 The control of gastric emptying is com-plex. In general, liquid emptying is faster than solid emptying. Osmolarity, acidity, caloric content, nutrient composition, and particle size are important modulators of gastric emptying. Stimulation of duodenal osmoreceptors, glucoreceptors, and pH receptors clearly inhibits gastric emptying by a variety of neurohumoral mechanisms. CCK has been consistently shown to inhibit gastric emptying at physiologic doses (Fig. 26-19). Recently, it has been noted that the anorexigenic hormone leptin, secreted largely by fat but also by gastric mucosa, inhib-its gastric emptying, perhaps through the same pathway as CCK (which also has properties of a satiety hormone). The orexigenic hormone ghrelin has the opposite effect.Liquid Emptying. The gastric emptying of water or isotonic saline follows first-order kinetics, with a half emptying time around 12 minutes. Thus, if one drinks 200 mL of water, about 100 mL enters the duodenum by 12 minutes, whereas if one drinks 400 mL of water, about 200 mL enters the duodenum by 12 minutes. This emptying pattern of liquids is modified consid-erably as the caloric density, osmolarity, and nutrient composi-tion of the liquid changes (Fig. 26-20). Up to an osmolarity of about 1 M, liquid emptying occurs at a rate of about 200 kcal per hour. Duodenal osmoreceptors and hormones (e.g., secretin and VIP) are important modulators of liquid gastric emptying. Generally, liquid emptying is delayed in the supine position.Traditionally, liquid emptying has been attributed to the activity of the proximal stomach, but it is probably more complicated than previously thought. Clearly, receptive relax-ation and gastric accommodation play a role in gastric empty-ing of liquids. Patients with a denervated (e.g., vagotomized), resected, or plicated (e.g., fundoplication) proximal stomach have decreased gastric compliance and may show accelerated gastric emptying of liquids.Some observations suggest an active role for the distal stomach in liquid emptying. For instance, even if the proximal intragastric pressure is lower than duodenal pressure, normal gastric emptying of liquids can occur. Also, diabetic patients CCK (µg/kg)0.25Low-fat dietHight-fat diet0102030405060700.51.02.0% Suppression of gastric emptyingFigure 26-19. Cholecystokinin (CCK) inhibits gastric emptying. (Reproduced with permission from Covasa M, Ritter RC: Adapta-tion to high-fat diet reduces inhibition of gastric emptying by CCK and intestinal oleate, Am J Physiol Regul Integr Comp Physiol. 2000 Jan;278(1):R166-R170.)7006005004003001002000Residual gastric volume (mL)Time (min)806040200Figure 26-20. Nutrient composition and caloric density affect liquid gastric emptying. Glucose solution (purple circles), the least calorically dense, emptied the fastest. Other more calorically dense solutions, such as milk protein (green triangles) and pep-tide hydrolysates (red circles and blue triangles), emptied slower. (Reproduced with permission from Calbet JA, MacLean DA. Role of caloric content on gastric emptying in humans, J Physiol. 1997 Jan 15;498 (Pt 2):553-559.)Brunicardi_Ch26_p1099-p1166.indd 111401/03/19 7:11 PM 1115STOMACHCHAPTER 26may have normal proximal gastric motor function and pro-foundly delayed gastric emptying of liquids. Indeed, antral contractile activity does correlate with liquid gastric emptying, and this distal gastric activity appears to vary with the nutrient composition and caloric content of the liquid meal. Depend-ing on the circumstances, distal gastric motor activity can pro-mote or inhibit gastric emptying of liquids. Distal gastrectomy and pyloric stenting both obviously interfere with distal gastric motor activity, and both accelerate the initial rapid phase of liq-uid gastric emptying.Solid Emptying. Normally, the half-time of solid gastric emp-tying is less than 2 hours. Unlike liquids, which display an initial rapid phase followed by a slower linear phase of emptying, sol-ids have an initial lag phase during which little emptying of sol-ids occurs. It is during this phase that much of the grinding and mixing occurs. A linear emptying phase follows, during which the smaller particles are metered out to the duodenum. Solid gastric emptying is a function of meal particle size, caloric con-tent, and composition (especially fat). When liquids and solids are ingested together, the liquids empty first. Solids are stored in the fundus and delivered to the distal stomach at constant rates for grinding. Liquids also are sequestered in the fundus, but they appear to be readily delivered to the distal stomach for early emptying. The larger the solid component of the meal, the slower the liquid emptying. Patients bothered by dumping syn-drome are advised to limit the amount of liquid consumed with the solid meal, taking advantage of this effect. Three prokinetic (metoclopramide, erythromycin, domperidone) may be used to treat delayed gastric emptying. Typical doses and mechanism of action are shown in Table 26-4.DIAGNOSIS OF GASTRIC DISEASESigns and SymptomsThe most common symptoms of gastric disease are pain, weight loss, early satiety, and anorexia. Nausea, vomiting, bloating, and anemia also are frequent complaints. Several of these symptoms (pain, bloating, nausea, and early satiety) are often described by physicians as dyspepsia, synonymous with the common nonmedical term indigestion. Common causes of dyspepsia include gastroesophageal reflux disease (GERD), helicobacter gastritis, and other disorders of the stomach, gallbladder, and pancreas. Although none of the aforementioned symptoms alone is specific for gastric disease, when elicited in the con-text of a careful history and physical examination, they point to a differential diagnosis, which can be refined with certain tests. Early endoscopy should be considered in patients present-ing with recent onset of alarm symptoms (weight loss, anemia, dysphagia, vomiting) particularly those over 55 years of age (Table 26-5).Diagnostic TestsEsophagogastroduodenoscopy. Esophagogastroduodenos-copy (EGD) is a safe and accurate outpatient procedure per-formed under conscious sedation.64 Smaller flexible scopes with excellent optics and a working channel are easily passed trans-nasally in the unsedated patient. Following an 8-hour fast, the flexible scope is advanced under direct vision into the esopha-gus, stomach, and duodenum. The fundus and GE junction are inspected by retroflexing the scope. To rule out cancer with a high degree of accuracy, all patients with gastric ulcer diag-nosed on upper GI series or found at EGD should have multiple biopsy specimens of the base and rim of the lesion. Brush cytol-ogy also should be considered. Gastritis should be biopsied both for histologic examination and assessment (see discussion on gastritis in “Helicobacter Pylori Infection”) and for a tissue ure-ase test and histologic evaluation to rule out the presence of H pylori. If Helicobacter infection is detected, it should be treated because of the etiologic association with peptic ulcers, mucosa-associated lymphoid tissue (MALT), and gastric cancer; in addition, eradication may ameliorate symp-toms. The most serious complications of EGD are perforation (which is rare, but can occur anywhere from the cervical esoph-agus to the duodenum), aspiration, and respiratory depression from excessive sedation. Although EGD is a more sensitive test than double-contrast upper GI series, these modalities should be considered complementary rather than mutually exclusive.Barium Upper GI Study. Plain abdominal X-rays may be helpful in the diagnosis of gastric perforation (pneumoperi-toneum) or delayed gastric emptying (large air-fluid level). Double-contrast upper GI series may be better than EGD at elucidating gastric diverticula, fistula, tortuosity, stricture loca-tion, and size or morphology of hiatal hernia.65 Although there are radiologic characteristics of ulcers that suggest the pres-ence or absence of malignancy, gastric ulcers always require adequate biopsy.Computed Tomographic Scanning and Magnetic Resonance Imaging. Usually, significant gastric disease can be diag-nosed without these sophisticated imaging studies. However, one or the other should be part of the routine staging work-up for patients with a malignant gastric tumor. Magnetic resonance imaging (MRI) may prove clinically useful as a quantitative test for gastric emptying, and it may even hold some promise for the 1Table 26-4Drugs that accelerate gastric emptyingAGENTTYPICAL ADULT DOSEMECHANISM OF ACTIONMetoclopramide10 mg PO four times a dayDopamine antagonistErythromycin250 mg PO four times a dayMotilin agonistDomperidone10 mg PO four times a dayDopamine antagonistTable 26-5Alarm symptoms that indicate the need for upper endoscopyAge >55 years with new onset dyspepsiaUnintentional weight lossPersistent or recurrent vomitingProgressive dysphagiaRecent onset odynophagiaUnexplained iron deficiency anemia or GI bleedingPalpable abdominal mass or lymphadenopathyFamily history of upper gastrointestinal cancerBrunicardi_Ch26_p1099-p1166.indd 111501/03/19 7:11 PM 1116SPECIFIC CONSIDERATIONS PART IIanalysis of myoelectric derangements in patients with gastropa-resis. Virtual gastroscopy using multi detector CT scan or MRI is not yet widely used, but these techniques may prove useful for screening and staging of gastric disease66-68 (Fig. 26-21). CTA or MRA is useful in evaluating the blood supply to the stomach after endovascular treatment of aortic and/or visceral arterial disease or in patients with previous upper abdominal operation in whom gastric conduit construction is contemplated, e.g., with esophagectomy.Arteriography can be helpful in the occasional poor-risk patient with exsanguinating gastric hemorrhage, in the patient with occult gastric bleeding, or when CTA or MRA is inconclu-sive in delineating vascular anatomy.Endoscopic Ultrasound. Endoscopic ultrasound (EUS) is useful in the evaluation and management of gastric mass lesions.69-71 Local staging of gastric adenocarcinoma with EUS is quite accurate, and this modality can be used to plan therapy. At many centers, patients with transmural and/or node positive adenocarcinoma of the stomach are considered for preoperative (neoadjuvant) chemoradiation therapy. EUS is the best way to clinically stage these patients locoregion-ally. Suspicious nodes can be sampled with EUS-guided endoscopic needle biopsy. Malignant tumors that are confined to the mucosa on EUS may be amenable to endoscopic muco-sal resection (EMR). EUS also can be used to assess tumor response to chemotherapy. Submucosal masses are commonly discovered during routine EGD. Large submucosal masses should be resected unless benign pathology is a certainty, but observation may be appropriate for some small submucosal masses (e.g., lipoma or leiomyoma). There are endoscopic characteristics of benign and malignant mesenchymal tumors, and thus, EUS can provide reassurance, but no guarantee, that small lesions under observation are probably benign. Thus, EUS-guided needle biopsy should be considered. Submucosal varices also can be assessed by EUS.Gastric Secretory Analysis. Analysis of gastric acid output requires gastric intubation, and it is performed infrequently nowadays. This test may be useful in the evaluation of patients with hypergastrinemia, including the Zollinger-Ellison syn-drome (ZES), patients with refractory ulcer or GERD, and patients with recurrent ulcer after operation. Historically, gas-tric analysis was performed most commonly to test for the ade-quacy of vagotomy in postoperative patients with recurrent or persistent ulcer. Now this can be done by assessing peripheral ABCDFigure 26-21. Conventional double-contrast barium study (A) shows a focal protruding mass (arrow) on the gastric fundus. Axial com-puted tomographic scan (B) also shows a protruding polyp (arrow). The three-dimensional computed tomographic gastrographic images in the transparent (C) mode shows an elevated lesion on the gastric fundus (arrow). Photograph of the total gastrectomy specimen (D) shows a well-demarcated polypoid mass (arrow); this lesion was confirmed as early gastric carcinoma type I on microscopic examination (not shown). (Reproduced with permission from Shin KS, Kim SH, Han JK, et al: Three-dimensional MDCT gastrography compared with axial CT for the detection of early gastric cancer, J Comput Assist Tomogr. 2007 Sep-Oct;31(5):741-749.)Brunicardi_Ch26_p1099-p1166.indd 111601/03/19 7:11 PM 1117STOMACHCHAPTER 26pancreatic polypeptide levels in response to sham feeding.72 A 50% increase in pancreatic polypeptide within 30 minutes of sham feeding suggests intact vagal function.Normal basal acid output (BAO) is greater than 5 mEq/h. MAO is the average of the two final stimulated 15-minute periods and is usually 10 to 15 mEq/h. Peak acid output is defined as the highest of the four stimulated periods. Patients with a gastrinoma commonly have a high BAO, often above 30 mEq/h, but consistently above 15 mEq/h unless there has been previous vagotomy or gastric resection. In patients with gastrinoma, the ratio of BAO to MAO exceeds 0.6. Normal acid output in the patient prescribed acid-suppressive medica-tion usually means that the patient is noncompliant. To assess acid-secretory capacity in the absence of medication effect, H2 blockers and PPIs should be withheld for several days before gastric analysis.Scintigraphy. The standard scintigraphic evaluation of gastric emptying involves the ingestion of a test meal with one or two isotopes and scanning the patient under a gamma camera. A curve for gastric emptying is plotted, and the half-time is calcu-lated. Normal standards exist at each facility. Duodenogastric reflux can be quantitated by the IV administration of hepato-biliary iminodiacetic acid (HIDA scan), which is concentrated and excreted by the liver into the duodenum. Software allows a semiquantitative assessment of how much of the isotope refluxes into the stomach. Positron emission tomography (PET) scan or CT/PET scan is useful in staging certain patients with gastric malignancy.Tests for Helicobacter pylori. A variety of tests can help the clinician to determine whether the patient has active H pylori infection.73 The predictive value (positive and negative) of any of these tests when used as a screening tool depends on the prevalence of H pylori infection in the screened population. A positive test is quite accurate in predicting H pylori infection, but a negative test can be unreliable. Thus, in the appropriate clinical setting, treatment for H pylori should be initiated on the basis of a positive test, but not necessarily withheld if the test is negative. Helicobacter infection should be treated when the diagnosis is made and eradication is confirmed.A positive serologic test is presumptive evidence of active infection if the patient has never been treated for H pylori. Histologic examination of gastric mucosal biopsy using special stains is the gold standard test for helicobacter infection. Other sensitive tests include commercially available rapid urease tests, which assay for the presence of urease in mucosal biopsy speci-mens (strong presumptive evidence of infection). Urease is an omnipresent enzyme in H pylori strains that colonize the gas-tric mucosa. The carbon labeled urea breath test has become the standard test to confirm eradication of H pylori following appropriate treatment.74 In this test, the patient ingests urea labeled with nonradioactive 13C or 14C. The labeled urea is acted upon by the urease present in the H pylori and converted into ammonia and carbon dioxide. The radiolabeled carbon dioxide is excreted from the lungs and can be detected in the expired air (Fig. 26-22). It also can be detected in a blood sample. The fecal antigen test also is quite sensitive and specific for active H pylori infection and may also be used to confirm cure after treatment. Helicobacter culture may be useful to assess antimi-crobial resistance in persistently recalcitrant cases.Antroduodenal Motility Testing and Electrogastrography.  Antroduodenal motility testing and electrogastrography (EGG) are performed in specialized centers and may be useful in the evaluation of the occasional patient with dyspeptic symptoms. EGG consists of the transcutaneous recording of gastric myo-electric activity. Antroduodenal motility testing is done with a tube placed transnasally or transorally into the distal duodenum. There are pressure-recording sensors extending from the stom-ach to the distal duodenum. The combination of these two tests together with scintigraphy provides a thorough assessment of gastric motility.HELICOBACTER PYLORI INFECTIONOver 50% of people worldwide are infected with Helicobacter pylori.75,76 Infection with H pylori is a chronic disease and does not resolve spontaneously without specific treatment. World-wide, H pylori–induced gastritis accounts for 80% to 90% of all gastritis. Chronic gastritis associated with H pylori is the most important risk factor for peptic ulcer and gastric adeno-carcinoma. Successful H pylori treatment largely eliminates recurrent peptic ulcer in infected patients, and eradication of H pylori worldwide would eliminate most cases of gastric Figure 26-22. Labeled urea breath test to detect Helicobacter infection. (Repro-duced with permission from Walsh JH, Peterson WL. The treatment of Helico-bacter pylori infection in the management of peptic ulcer disease, N Engl J Med. 1995 Oct 12;333(15):984-991.)[13C] urea13CO2 (µmol)Positive breathurea testUreaseBloodHours1213CO2 in breathNH2NH22NH3+CO2H2O + 13C = 0Negative breathurea testBrunicardi_Ch26_p1099-p1166.indd 111701/03/19 7:11 PM 1118SPECIFIC CONSIDERATIONS PART IIadenocarcinoma, a major cause of cancer death worldwide.77 Helicobacter pylori infection is also associated with MALT lymphoma, dyspepsia, hyperplastic gastric polyps, and even immune thrombocytopenic purpura.Human beings are the only reservoir for H pylori. Infection is presumed to occur by oral ingestion of the bacterium, which dramatically alters the gastric microbiome.78 In helicobacter-infected individuals, 90% of gastric bacteria are helicobacter, whereas in helicobacter-negative patients 90% of gastric bac-teria are a combination of firmicutes, actinobacteria, bacte-roidetes, proteobacteria, and fusobacteria. The prevalence of H pylori infection varies among populations and is strongly cor-related with socioeconomic conditions. In developing countries, H pylori infection usually occurs in childhood, and over 80% of adults are infected. Reinfection after curative treatment is common. Infection rates are lower in industrialized countries, and the prevalence of infection in the United States has been declining since the second half of the 19th century as hygiene and sanitation have improved. Nonetheless, H pylori infection is predicted to remain endemic in the United States for the next century. Family members of infected individuals and healthcare workers are at increased risk of infection.With specialized flagella and a rich supply of urease, H pylori is uniquely equipped for survival in the hostile envi-ronment of the stomach.[79-81] Helicobacter strains that lack either flagella or urease are nonpathogenic. The pathogenesis of helicobacter infection involves survival in the acidic gastric lumen, flagellated movement from the lumen across the mucus layer to the surface epithelial cell, adhesion to the surface epi-thelial cell, and toxin production. Up to 15% of the protein in a Helicobacter organism is composed of cytoplasmic urease that converts periplasmic urea into CO2 and ammonia. This buffers the surrounding acid, allowing the bacteria to survive the inimical luminal environment until it can burrow deeply into the surface mucus, propelled by its flagella (Fig. 26-23). H pylori typically does not invade the surface epithelial cell layer. Rather, it triggers a host immune response by attach-ing to gastric epithelial cells. Important Helicobacter adhesins mediating surface cell injury include neutrophil activating pro-tein A, heat shock protein 60, and sialic acid–binding adhesin. Helicobacter-produced toxins include vacuolating cytotoxin A and cag A (cytotoxin-associated gene A). The initial inflammatory response to Helicobacter infection is characterized by recruit-ment of neutrophils, followed sequentially by T and B lympho-cytes, plasma cells, and macrophages (Fig. 26-24). The resultant chronic gastric inflammation in affected individuals is charac-terized by enhanced mucosal expression of multiple cytokines and the presence of reactive oxygen and nitrogen species, and long-term infection is associated with mucosal cell DNA damage and chromosomal instability and increased apopto-sis (Fig. 26-25).80,81 The net effect is a weakening of mucosal defenses. The mechanism by which the helicobacter organism avoids recognition and destruction by the mucosal immune sys-tem is a topic of interest and active research.82Acute H pylori infection causes a nonerosive pangastritis that is invariably followed by the development of chronic gastritis. Chronic antral gastritis with sparing of the proximal stomach occurs in about 10% of infected patients, and this pre-disposes to peptic ulcer disease (PUD). The other 90% of Heli-cobacter-infected patients develop chronic inflammation of the proximal stomach (corpus dominant gastritis), which can lead to gastric cancer in about 1% to 3% of this group.Figure 26-23. Helicobacter pylori closely adherent to the cell membrane (top), and spiral-shaped H pylori attached to epithelial surface and surrounding microvilli (bottom). In the image on the bottom, the bacterial flagella can be seen arising from the upper pole of the bacterium. (Reproduced with permission from Mertz HR, Walsh JH: Peptic ulcer pathophysiology, Med Clin North Am. 1991 Jul;75(4):799-814.)H pylori infection is the major cause of peptic ulceration. Patients with H pylori infection and antral gastritis are three and one-half times more likely to develop PUD than patients without H pylori infection. Up to 90% of patients with duode-nal ulcers, and at least 70% of patients with gastric ulcers, have H pylori infection. It is clear from multiple randomized prospec-tive studies that curing H pylori infection dramatically alters the natural history of PUD, decreasing the recurrent ulcer rate from more than 75% in patients treated with a course of acid-suppressive therapy alone (in whom H pylori is not eradicated) to less than 20% in patients treated with a course of antibacterial therapy (Fig. 26-26).83In patients with duodenal ulcer caused by helicobacter, the associated antral gastritis leads to relative hypergastrinemia by depleting antral somatostatin, the primary inhibitor of antral gastrin release. H pylori infection is associated with decreased Brunicardi_Ch26_p1099-p1166.indd 111801/03/19 7:11 PM 1119STOMACHCHAPTER 26levels of somatostatin, decreased somatostatin messenger RNA production, and fewer somatostatin-producing D cells. The mechanism of decreased antral somatostatin synthesis and release may be related to (a) antral alkalinization due to heli-cobacter urease (acid in the antrum releases somatostatin); (b) toxic cytokine effect on antral D cells; and/or (c) Helicobacter production of N-α-methylhistamine, an H3 receptor agonist, which binds H3 receptors on the antral D cell and decreases somatostatin release.84 Since the gastritis does not involve the oxcyntic mucosa, hypergastrinemia leads to hyperacidity and parietal cell hyperplasia. The acid hypersecretion and the antral gastritis are thought to lead to antral epithelial metaplasia in the postpyloric duodenum. This duodenal metaplasia allows H pylori to colonize the duodenal mucosa, and this is where the duodenal ulcer occurs. In fact, in patients with gastric metapla-sia of the duodenum, the risk of developing a duodenal ulcer increases 50-fold. When H pylori colonizes the duodenum, there is a significant decrease in acid-stimulated duodenal bicarbonate release. When H pylori infection is successfully treated, acid secretory physiology tends to normalize. Relapse of duodenal ulcer after eradication of H pylori may signal reinfection of the gastric mucosa by the organism.Many patients with antral dominant helicobacter gastritis never develop duodenal ulcer, and some patients with peptic ulcer do not have Helicobacter. This obviously suggests that there are other important pathogenetic factors involved in peptic ulcer. And even in the presence of active H pylori infection, strong acid suppression usually heals peptic ulcer, an observa-tion consistent with the old dictum “no acid, no ulcer.” But suc-cessful helicobacter treatment eliminates ulcer recurrence and the need for long-term PPI. And long-term PPI in patients with active Helicobacter infection may lead to corpus predominant gastritis, which leads to atrophic gastritis and increases the risk of gastric cancer. Thus, Helicobacter infection should be treated and eradication confirmed.Testing for H pylori infection should be performed in patients with peptic ulcer, gastritis, significant dyspepsia, MALT lymphoma, and early gastric cancer.85 Noninvasive methods for diagnosis of H pylori infection include the urea breath test, serology, and detection of stool antigen. The urea breath test has a sensitivity and specificity of greater than 90% and is useful for initial diagnosis of infection and for follow-up after eradication therapy since it is positive only in the presence of active infection. The stool antigen test is another noninvasive test to detect active H pylori infection, but it is recommended that only locally validated tests be used.86 Because H pylori induces a strong immunologic response, serological testing is useful but may not be as accurate as the urea breath test or the stool antigen test, and a positive serology persists after eradica-tion of H pylori infection, so serology is not useful to confirm successful treatment of Helicobacter infection. H pylori infec-tion can also be diagnosed by histologic evaluation of gastric biopsies and/or the rapid urease test on fresh biopsies. Culture of H pylori is not routine and is usually reserved for recurrent infection and for antibiotic sensitivity testing when second-line therapy has failed. All tests for H pylori have a false negative rate. Empiric Helicobacter treatment can be considered despite negative tests if clinical likelihood of infection is high, e.g., a compliant nonsmoking, non–NSAID-consuming patient facing operation for nonhealing peptic ulcer or a patient with unex-plained gastritis.Patients with a positive test should be treated and eradi-cation confirmed. Spontaneous cure without treatment is very rare. It is important to note that none of the therapeutic regimens reported to date cure H pylori infection in 100% of patients. To be effective, antimicrobial drugs must be combined with gas-tric acid secretion inhibitors or bismuth salts. The Maastricht V/Florence Consensus Report87 provides current recommenda-tions for diagnosis and treatment of H pylori infection in various clinical scenarios, including recommendations for areas with high metronidazole and clarithromycin resistance.87,88 Ideally, a treatment regimen is chosen with 90% effectiveness. Treat-ment failure requires an alternative course of therapy. Failure to eradicate infection after two tries should prompt Helicobacter culture and sensitivity testing and referral to a specialist. With assiduous treatment, Helicobacter eradication can be achieved in nearly every patient. Patients with atrophic gastritis require endoscopic surveillance (see discussion of gastritis later in this Figure 26-24. Model of Helico-bacter effects on duodenal ulcer pathogenesis. (Reproduced with per-mission from Feldman M, Friedman LS, Sleisenger MH, et al: Sleisenger and Fordtran’s Gastrointestinal and Liver Disease, 7th ed. Philadelphia, PA: Elsevier/Saunders; 2002.)Multiple factors (smoking, ageat acquisition of infection)Somatostatin/gastrindysregulationAcquisition of H pyloriDuodenum ulcerationIncreased acidsecretionGastric metaplasiain duodenumDuodenum bicarbonate secretionInflammation (Duodenitis)Chronic H pyloriinfection in stomachH pylori colonization in duodenumBrunicardi_Ch26_p1099-p1166.indd 111901/03/19 7:11 PM 1120SPECIFIC CONSIDERATIONS PART IIchapter) because the same sequence of inflammation to meta-plasia to dysplasia to carcinoma, that is well known to occur in the esophagus from reflux-induced inflammation (and in the colon from inflammatory bowel disease), is now increasingly well recognized to occur in the stomach with Helicobacter-induced gastritis. Helicobacter also clearly has an etiologic role in the development of gastric lymphoma.PEPTIC ULCER DISEASEPeptic ulcers are focal defects in the gastric or duodenal mucosa that extend into the submucosa or deeper. They may be acute or chronic and, ultimately, are caused by an imbalance between mucosal defenses and acid/peptic injury (Fig. 26-27).89,90 Peptic ulcer remains a common outpatient diagnosis, but the number of Figure 26-25. Pathogen-host interactions in the pathogenesis of Helicobacter pylori infection. ICAM = intercellular adhesion molecule-1; IFN-γ = interferon-γ; LPS = lipopolysaccharide; NF-κB = nuclear factor κB; PAI = pathogenicity island; PMN = polymorphonuclear neutrophil; TNF-α = tumor necrosis factor-α; VCAM = vascular cell adhesion molecule. (Used with permission from Manuel Amieva, Stanford University.)cag+H pyloristraincag-PAI-encodedsecretoryapparatusMultiple adhesions:BabA (binds tolewis B), AIpA,AlpB, HopZPhospholipaseA2Alterationsin mucousglycoproteinsGastricepithelialcellFlagellaMucusActinpolymerizationCagAphosphorylationVacAApoptosisDisruption of epithelialbarrierFasexpressionUreaseLPSPorinsInterleukin-8CagAMacrophageInterleukin-12Th 1 cellTh 2 cellB cellCytokine-inducedchanges in gastric physiologyTh 0 cellICAM and VCAMexpressionPMN recruitmentInterleukin-8Chemotacticinterleukin-8 gradienton proteoglycanscaffoldingNeutrophilT cellB cellBlood vesselNF-˜ B AP-1 GRO-°ENA-78T-cell and B-cellextravasationINF-˛ TNF-°Interleukin-1˙MHC II, B7-1,and B7-2expressionAnti-H+/K+-ATPaseantibodiesBrunicardi_Ch26_p1099-p1166.indd 112001/03/19 7:11 PM 1121STOMACHCHAPTER 26physician visits, hospital admissions, and elective operations for PUD has decreased steadily and dramatically over the past four decades. Interestingly, the start of these trends all predated the widespread use of acid suppression, or highly selective vagot-omy. The incidence of emergency surgery and the death rate associated with peptic ulcers has not decreased nearly so dra-matically. These epidemiologic changes probably represent the net effect of several factors, including (beneficially) decreased prevalence of H pylori infection, better medical therapy, and increased outpatient management and (detrimentally) the use of NSAIDs and aspirin (with and without ulcer prophylaxis) in an aging population with multiple risk factors.Figure 26-26. Helicobacter treatment dramatically decreases the recurrence rate of duodenal and gastric ulcer. (Reproduced with permission from Peek RM, Blaser MJL: Pathophysiology of Helico-bacter pylori-induced gastritis and peptic ulcer disease, Am J Med. 1997 Feb;102(2):200-207.)Figure 26-27. Balance of aggressive and defensive factors in the gastric mucosa. (Reproduced with permission from Suerbaum S, Michetti P: Helicobacter pylori infection, N Engl J Med. 2002 Oct 10;347(15):1175-1186.)PUD is one of the most common GI disorders in the United States with a prevalence of about 2%, and a lifetime cumulative prevalence of about 10%, peaking around age 70 years.91 The costs of PUD, including lost work time and productivity, are estimated to be above $8 billion per year in the United States. In 1998, approximately 1.5% of all Medicare hospital costs were spent treating PUD, and the crude mortal-ity rate for peptic ulcer was 1.7 per 100,000 individuals. Using the National Inpatient Sample, it can be estimated that the mortality rate in patients hospitalized in 2006 with duodenal ulcer was 3.7% compared to 2.1% for gastric ulcer,92 and the age adjusted hospitalization rate was 56.5 per 100,000, down 21% from the previous decade. Recent studies have shown an increase in the rates of hospitalization and mortality in elderly patients for the peptic ulcer complications of bleeding and perforation.93 This may be due in part to the increasingly com-mon use of NSAIDs and aspirin in this elderly cohort, many of whom also have H pylori infection.Pathophysiology and EtiologyA variety of factors may contribute to the development of PUD. Although it is now recognized that the large majority of duode-nal and gastric ulcers are caused by H pylori infection (see previ-ous discussion on H pylori) and/or NSAID use20,94 (Fig. 26-28), the final common pathway to ulcer formation is acid-peptic injury of the gastroduodenal mucosal barrier. Acid suppression heals both duodenal and gastric ulcers and prevents recurrence if continued. In general, H pylori predisposes to ulceration, both by acid hypersecretion and by compromise of mucosal defense mechanisms. NSAID use causes ulcers predominantly by com-promise of mucosal defenses. Duodenal ulcer was traditionally viewed as a disease of increased acid-peptic action on the duo-denal mucosa, whereas gastric ulcer was viewed as a disease of weakened mucosal defenses. An increased understanding of peptic ulcer pathophysiology has blurred this overly simplistic distinction. Clearly, weakened mucosal defenses play a role in both duodenal and gastric ulcers, and acid hypersecretion may result in a duodenal or gastric ulcer in the setting of normal mucosal defenses.Elimination of H pylori infection or NSAID use is important for optimal ulcer healing, and perhaps is even more important in preventing ulcer recurrence and/or complications. A variety of other diseases are known to cause peptic ulcer, including ZES (gastrinoma), antral G-cell hyperfunction and/or hyperplasia, systemic mastocytosis, trauma, burns, and major physiologic stress. Other causative agents include drugs (all NSAIDs, aspirin, and cocaine), smoking, and psychologic stress. In the United States, probably more than 90% of serious peptic ulcer complications can be attributed to H pylori infec-tion, NSAID use, and/or cigarette smoking.Acid Secretion and Peptic Ulcer. A variety of abnormalities related to mucosal acid exposure have been described in patients with duodenal ulcer (Fig. 26-29).95 Although duodenal ulcer patients as a group have a higher mean BAO and mean MAO compared to normal controls, many duodenal ulcer patients have basal and peak acid outputs in the normal range, and there is no correlation between acid secretion and the severity of the ulcer disease. As a group, duodenal ulcer patients produce more acid than normal controls in response to any known acid secre-tory stimulus. Although they usually have normal fasting serum gastrin levels, DU patients often produce more gastric acid at AcidPepsinNSAIDsH pyloriAggressionDefenseRepairBicarbonateBlood flowMucusCell junctionsApical resistanceRestitutionMucoid capProliferationGrowth factors0%10%20%30%40%50%60%70%80%90%100%Duodenal ulcerrecurrenceGastric ulcerrecurrenceRanitidine +antibioticsRanitidine aloneBrunicardi_Ch26_p1099-p1166.indd 112101/03/19 7:11 PM 1122SPECIFIC CONSIDERATIONS PART IIany given dose of gastrin than controls. Considering that many duodenal ulcer patients do produce excessive gastric acid, it has been argued that a “normal” fasting gastrin level in these patients is inappropriately high, and that there is an impaired feedback mechanism, especially in light of the apparently increased sensitivity of the parietal cell mass to gastrin. Many of these long-standing observations now seem reasonable in light of recently gained understanding of the perturbations in acid and gastrin secretion associated with H pylori infection. Some patients with duodenal ulcer also have increased rates of gastric emptying that deliver an increased acid load per unit of time to the duodenum. Finally, the buffering capacity of the duodenum in many patients with duodenal ulcer is compromised due to decreased duodenal bicarbonate secretion and duodenal gastric metaplasia.In patients with gastric ulcer, acid secretion is vari-able. Currently, five types of gastric ulcer are described, although the original Johnson classification contained three types (Fig. 26-30).96 The most common, Johnson type I gas-tric ulcer, is typically located near the angularis incisura on the lesser curvature, close to the border between antral and corpus mucosa. Patients with type I gastric ulcer usually have normal or decreased acid secretion. Type II gastric ulcer is associ-ated with active or quiescent duodenal ulcer disease, and type III gastric ulcer is prepyloric ulcer disease. Both type II and type III gastric ulcers are associated with normal or increased gastric acid secretion and surgically are treated similar to duode-nal ulcer. Type IV gastric ulcers occur near the GE junction, and acid secretion is normal or below normal. Type V gastric ulcers are medication induced and may occur anywhere in the stomach. Patients with gastric ulcers may have weak mucosal defenses that permit an abnormal amount of injurious acid back-diffusion into the mucosa. Duodenogastric reflux may play a role in weakening the gastric mucosal defenses, and a variety of components in duodenal juice, including bile, lysolecithin, and pancreatic juice, have been shown to cause injury and inflam-mation in the gastric mucosa. NSAIDs and aspirin have similar effects. Although chronic gastric ulcer usually is associated with surrounding gastritis, it is unproven that the latter leads to the former.Nonsteroidal Anti-Inflammatory Drugs in Peptic Ulcer Disease. Chronic use of NSAIDs (including aspirin) increases the risk of peptic ulcer disease about fivefold and upper GI bleeding at least twofold.97-100 Complications of PUD (specifi-cally hemorrhage and perforation) are much more common in patients taking NSAIDs. More than half of patients who present with peptic ulcer hemorrhage or perforation report the recent use of NSAIDs, including aspirin. Many of these patients remain asymptomatic until they develop these life-threatening complications.Figure 26-29. Frequency of physiologic abnormali-ties in patients with duodenal ulcer (DU). HCO3 = bicarbonate; MAO = maximal acid output. (Reproduced with permission from Yamada T, Alpers DH, Laine L, et al: Textbook of Gastroenterology, 4th ed. Philadelphia, PA: Lippincott Williams & Wilkins; 2003.)2550751000Approximate % of DU patientsPathophysiologic abnormalities in DUvary in frequencyNocturnal acid secretionpH inhibition of gastrin releaseGastric emptyingPentagastrin-stimulated MAODaytime acid secretionDuodenal acid loadDuodenal HCO3 secretionFigure 26-28. “Causes” of peptic ulcer disease. Z.E. = Zollinger-Ellison syndrome. (Data from Graham DY, Lew GM, Klein PD, et al. Effect of treatment of Helicobacter pylori infec-tion on the long-term recurrence of gas-tric or duodenal ulcer. A randomized, controlled study, Ann Intern Med. 1992 May 1;116(9):705-708.)Conditions associated with peptic ulcerNSAIDuseNone knownZ.E., otherH. pyloriinfectionNSAIDuseNone knownZ.E., otherH. pyloriinfectionDuodenalGastricBrunicardi_Ch26_p1099-p1166.indd 112201/03/19 7:12 PM 1123STOMACHCHAPTER 26The overall risk of significant serious adverse GI events in patients taking NSAIDs is more than three times that of con-trols (Table 26-6). This risk increases to five times in patients more than age 60 years old. In elderly patients taking NSAIDs, the likelihood that they will require an operation related to a GI complication is 10 times that of the control group, and the risk that they will die from a GI cause is about four and one-half times higher. This problem is put into perspective when one realizes that approximately 20 million patients in the United States take NSAIDs on a regular basis; perhaps even more regularly take aspirin. Persons who take NSAIDs also have a higher hospitalization rate for serious GI events than those who do not.Factors that clearly put patients at increased risk for NSAID-induced GI complications include age >60, prior GI event, high NSAID dose, concurrent steroid intake, and con-current anticoagulant intake. Proton pump inhibitors have been shown to significantly decrease upper GI bleeding risk in patients on chronic warfarin, low dose aspirin, and/or antiplate-let agents.101-103 ANY patient taking NSAIDs or aspirin who has one or more of these risk factors should receive concomitant acid suppressive medication,104 preferably PPI (Table 26-7). High-dose H2 blockers have been shown to be somewhat less effective than PPIs in preventing GI complications in these high-risk patients on antiplatelet therapy, but clearly, they are better than no acid suppression.105Smoking, Stress, and Other Factors. Epidemiologic studies suggest that smokers are about twice as likely to develop PUD as nonsmokers. Smoking increases gastric acid secretion and duodenogastric reflux. Smoking decreases both gastroduodenal prostaglandin production and pancreaticoduodenal bicarbonate production. These observations may be related, and any or all could explain the observed association between smoking and PUD.Although difficult to measure, both physiologic and psy-chologic stress undoubtedly play a role in the development of peptic ulcer in some patients.106 In 1842, Curling described duodenal ulcer and/or duodenitis in burn patients. Decades later, Cushing described the appearance of acute peptic ulcer-ation in patients with head trauma (Cushing’s ulcer). Even the ancients recognized the undeniable links between PUD and stress. Patients still present with ulcer complications (bleeding, perforation, and obstruction) that are seemingly exacerbated by stressful life events. The use of crack cocaine has been linked to juxtapyloric peptic ulcers with a propensity to perforate. Alco-hol is commonly mentioned as a risk factor for PUD, but con-firmatory data are lacking.Clinical ManifestationsMore than 90% of patients with PUD complain of abdominal pain. The pain is typically nonradiating, burning in quality, and located in the epigastrium. The mechanism of the pain is unclear. Patients with duodenal ulcer often experience pain 2 to 3 hours after a meal and at night. Two-thirds of patients with duodenal ulcers will complain of pain that awakens them from sleep. The pain of gastric ulcer more commonly occurs with eating and is less likely to awaken the patient at night. A history of PUD, use of NSAIDs, over-the-counter antacids, or antisecretory drugs is suggestive of the diagnosis. Other signs and symptoms include nausea, bloating, weight loss, stool positive for occult blood, and anemia. Duodenal ulcer is about twice as common in men compared to women, but the incidence of gastric ulcer is similar in men and women. On average, gastric ulcer patients are older than duodenal ulcer patients, and the incidence is increasing in the elderly, perhaps because of increasing NSAID and aspirin.DiagnosisIn the young patient with dyspepsia and without alarm symp-toms, it may be appropriate to initiate empirical PPI therapy for PUD without upper endoscopy or upper GI series. NSAIDs and aspirin should be stopped if the patient is taking these drugs, and Helicobacter should be ruled out with testing and treated if pres-ent. It is prudent to discuss with the patient the small possibility of an alternative diagnosis, including malignancy, even if symp-toms improve with the initiation of empiric therapy. Patients with persistent dyspepsia, and those who cannot stop NSAIDs or aspirin for health reasons should have an upper endoscopy, and all patients, regardless of age, should have this study if any alarm symptoms (see Table 26-5) are present. A double-contrast upper GI X-ray study may be useful. Once an ulcer has been confirmed endoscopically or radiologically, obvious possible causes (Helicobacter, NSAIDs, gastrinoma, cancer) should always be considered. All gastric ulcers should be adequately biopsied, and any sites of gastritis should be biopsied to rule out H pylori, and for histologic evaluation. Additional testing for H pylori may be indicated. It is reasonable to test all peptic IIIIIIIVVNSAID-inducedAcid hypersecretionFigure 26-30. Modified Johnson classification for gastric ulcer. I. Lesser curve, incisura. II. Body of stomach, incisura + duodenal ulcer (active or healed). III. Prepyloric. IV. High on lesser curve, near gastroesophageal junction. V. Medication-induced (NSAID/acetylsalicylic acid), anywhere in stomach. (Reproduced with permission from Cameron JL: Current Surgical Therapy, 9th ed. Philadelphia, PA: Elsevier/Mosby; 2008.)Brunicardi_Ch26_p1099-p1166.indd 112301/03/19 7:12 PM 1124SPECIFIC CONSIDERATIONS PART IIulcer patients and those with nonulcer dyspepsia for H pylori (Table 26-8). A baseline serum gastrin level to rule out gastri-noma should be considered if the peptic ulcer is unusual (distal duodenal or jejunal) or if the patient is Helicobacter and NSAID negative.ComplicationsThe three most common complications of PUD, in decreas-ing order of frequency, are bleeding, perforation, and obstruction.92,94,107 Most peptic ulcer–related deaths in the United States are due to bleeding. Inhospital mortality and length of stay can be predicted by the AIMS65 score,108 with a score of 0 predicting negligible mortality and a score of 5 predicting a 30% inhospital mortality. Bleeding peptic ulcers are by far the most common cause of upper GI bleeding in patients admitted to a hospital (Fig. 26-31).109,110 Patients with a bleeding peptic ulcer typically present with melena and/or hematemesis. Naso-gastric aspiration is usually confirmatory of upper GI bleeding. Abdominal pain is quite uncommon. Shock may be present, necessitating aggressive resuscitation and blood transfusion. Table 26-7Patients taking NSAIDs or aspirin need concomitant acid suppressing medication if any of the following risk factors are present• Age over 60 years• History of acid/peptic disease• Concurrent steroid intake• Concurrent anticoagulant intake• High-dose or chronic NSAID use• High-dose or chronic aspirin use >325 mg/dayTable 26-8Indications for diagnosis and treatment of Helicobacter pyloriEstablished• Active peptic ulcer disease (gastric or duodenal ulcer)• Confirmed history of peptic ulcer disease (not previously treated for H pylori)• Gastric mucosa-associated lymphoid tissue lymphoma (low grade)• After endoscopic resection of early gastric cancer• Uninvestigated dyspepsia (depending on H pylori prevalence)Controversial• Nonulcer dyspepsia• Gastroesophageal reflux disease• Persons using NSAIDs• Unexplained iron deficiency anemia• Populations at higher risk for gastric cancerReproduced with permission from Chey WD, Wong BC; Practice Parameters Committee of the American College of Gastroenterology: American College of Gastroenterology guideline on the management of Helicobacter pylori infection, Am J Gastroenterol. 2007 Aug;102(8):1808-1825.Table 26-6Hospitalization rates for GI events with and without NSAID use in selected large populationsANNUALIZED INCIDENCEb THERAPIES USEDCLINICAL UPPER GI EVENTScCOMPLICATED UPPER GI EVENTSdSTUDYaNSAID CONTROLSTUDY DRUGSCONTROLSTUDY DRUGCONTROLSTUDY DRUGMUCOSANSAIDs (n = 4439)Misoprostol 200 μg four times a day + NSAID (n = 4404)3.1%1.6%1.5%0.7%CLASSIbuprofen 800 mg three times a day, diclofenac 75 mg twice a day (n = 3987)Celecoxib 400 mg twice a day (n = 3995)3.5%2.1%1.5%0.8%   (No aspirine: 2.9%)1.4%1.3%0.4%VIGORNaproxen 500 mg twice a day (n = 4047)Rofecoxib 50 mg four times a day (n = 4029)4.5%2.1%1.4%0.6%aMUCOSA and VIGOR trials included only rheumatoid arthritis patients; CLASS trial included osteoarthritis (73%) and rheumatoid arthritis (27%).bIncidence for MUCOSA trial represents doubling of results provided at 6 months (although median follow-up was <6 months). Incidences for VIGOR and CLASS trials represent rates per 100 patient-years, although VIGOR median follow-up was 9 months, and CLASS data include only the first 6 months of the study.cIncludes perforations, obstructions, bleeding, and uncomplicated ulcers discovered on clinically indicated work-up.dIncludes perforation, obstruction, bleeding (documented due to ulcer or erosions in MUCOSA and CLASS; major bleeding in VIGOR).e21% of patients in CLASS study were taking low-dose aspirin.Note: All differences between controls and study drugs were significant except clinical upper GI events in overall CLASS study (P = .09).Reproduced with permission from Laine L: Approaches to nonsteroidal anti-inflammatory drug use in the high-risk patient, Gastroenterology 2001 Feb;120(3):594-606.Brunicardi_Ch26_p1099-p1166.indd 112401/03/19 7:12 PM 1125STOMACHCHAPTER 26Early endoscopy is important to diagnose the cause of the bleed-ing and to assess the need for hemostatic therapy.Three-fourths of the patients who come to the hospital with bleeding peptic ulcer will stop bleeding if given acid sup-pression and nothing by mouth. However, one fourth will con-tinue to bleed or will rebleed after an initial quiescent period, and virtually all the mortalities (and all the operations for bleeding) occur in this group. This group can be fairly well delineated based on clinical factors related to the magnitude of the hemorrhage, comorbidities, age, and endoscopic find-ings. Shock, hematemesis, transfusion requirement exceeding four units in 24 hours, and certain endoscopic stigmata (active bleeding or visible vessel) define this high-risk group. Risk stratification tools have proven useful in predicting rebleed-ing and death, and in identifying a low risk cohort. As can be seen in Table 26-9, the maximal Blatchford score is 23, and the maximal Rockall score is 11. The former does not use endoscopic criteria and may be better in identifying the low-risk cohort. Studies have shown that a Blatchford score of 1 or less, or a Rockall score of 2 or less, identifies patients who are very unlikely to be suffering from life-threatening upper GI bleeding. The shorter modified Blatchford score may be just as useful (BUN, Hgb, pulse, BP; maximal score 16).111 High-risk patients benefit from endoscopic therapy to stop the bleeding, while low-risk patients with low-risk lesions can be promptly discharged and treated as outpatients. The most common endoscopic hemostatic modalities used are injection with epinephrine and electrocautery. In a case with exposed vessel, mechanical hemostasis using clips is useful to control the bleeding.112 Biopsy should be performed to evaluate for H pylori infection. Persistent bleeding or rebleeding after endo-scopic therapy is an indication for repeat endoscopic treatment. Surgery should be considered after two endoscopic failures. Elderly patients and patients with multiple comorbidities do not tolerate repeated episodes of hemodynamically significant hemorrhage, and they may benefit from early elective opera-tion after initially successful endoscopic treatment, especially if they have a high-risk ulcer.Planned surgery under controlled circumstances often yields better outcomes than emergent surgery. Deep bleeding ulcers on the posterior duodenal bulb or lesser gastric curvature are high-risk lesions because they often erode large arteries less amenable to nonoperative treatment, and early operation should be considered.Perforated peptic ulcer usually presents as an acute abdo-men. The patient can often give the exact time of onset of the excruciating abdominal pain. Initially, a chemical peritonitis develops from the gastric and/or duodenal secretions, but within hours a bacterial peritonitis supervenes. The patient is in obvi-ous distress, and the abdominal examination shows peritoneal signs. Usually, marked involuntary guarding and rebound ten-derness is evoked by a gentle examination. Upright chest X-ray shows free air in about 80% of patients (Fig. 26-32). Once the diagnosis has been made, the patient is given analgesia and antibiotics, resuscitated with isotonic fluid, and taken to the operating room. Fluid sequestration into the third space of the inflamed peritoneum can be impressive, so preoperative fluid resuscitation is mandatory. Sometimes, the perforation has sealed spontaneously by the time of presentation, and surgery can be avoided if the patient is doing well. Nonoperative man-agement is appropriate only if there is objective evidence that the leak has sealed (i.e., radiologic contrast study), and in the absence of clinical peritonitis.Gastric outlet obstruction occurs in no more than 5% of patients with PUD. It is usually due to duodenal or prepyloric ulcer disease, and it may be acute (from inflammatory swelling and peristaltic dysfunction) or chronic (from cicatrix). Patients typically present with nonbilious vomiting and may have pro-found hypokalemic hypochloremic metabolic alkalosis and dehydration. Pain or discomfort is common. Weight loss may be prominent, depending on the duration of symptoms. A succus-sion splash may be audible with stethoscope placed in the epi-gastrium. Initial treatment is nasogastric suction, IV hydration and electrolyte repletion, and acid suppression. The diagnosis is confirmed by endoscopy. Most patients admitted to the hospital nowadays with obstructing ulcer disease require intervention, either balloon dilation or operation. Cancer must be ruled out because most patients who present with the symptoms of gastric outlet obstruction will have a pancreatic, gastric, or duodenal malignancy.Medical Treatment of Peptic Ulcer DiseasePPIs are the mainstay of medical therapy for PUD, but high-dose H2RAs and sucralfate are also quite effective. Patients hospitalized for ulcer complications should receive high-dose intravenous PPI and, when discharged, should be considered for lifelong PPIs unless the definitive cause is eliminated or a definitive operation performed. Peptic ulcer patients should stop smoking and avoid alcohol and NSAIDs (including aspirin). Patients who require NSAIDs or aspirin to treat other medical conditions should always take concomi-tant PPIs or high dose H2 receptor blockers. Testing for H pylori infection is performed, and if it is found, it should be treated with one of several acceptable regimens (Table 26-10).113 If initial H pylori testing is negative and ulcer symptoms per-sist, an empirical trial of anti–H pylori therapy is reasonable since false-negative H pylori tests are not uncommon. Gener-ally, acid suppression can be stopped after 3 months if the ulcerogenic stimulus (e.g., H pylori, NSAIDs, or aspirin) has been removed. However, long-term maintenance PPI therapy should be considered in all patients admitted to hospital with ulcer complications, all high-risk patients on NSAIDs or aspi-rin (the elderly or debilitated), and all patients requiring anti-coagulation or antiplatelet agents or those with a history of recurrent ulcer or bleeding. Consideration should also be given to maintenance PPI therapy in refractory smokers with a history of peptic ulcer. Sucralfate acts locally on mucosal defects and is well tolerated, and occasionally it is useful as a supplement to acid suppression.2Peptic ulcer40%24%6%4%6%5%10%5%No obvious causeOtherNeoplasmErosive diseaseMallory-Weiss syndromeOesophagitisVaricesFigure 26-31. Causes of upper GI bleeding. (Reproduced with permission from Dallal HJ, Palmer KR: ABC of the upper gastro-intestinal tract: Upper gastrointestinal haemorrhage, BMJ. 2001 Nov 10;323(7321):1115-1117.)Brunicardi_Ch26_p1099-p1166.indd 112501/03/19 7:12 PM 1126SPECIFIC CONSIDERATIONS PART IITable 26-9Risk-stratification tools for upper gastrointestinal hemorrhageaA. BLATCHFORD SCORE AT PRESENTATIONPOINTS Systolic blood pressure   100–109 mmHg1  90–99 mmHg2  <90 mmHg3 Blood urea nitrogen   6.5–7.9 mmol/L2  8.0–9.9 mmol/L3  10.0–24.9 mmol/L4  ≥25 mmol/L6 Hemoglobin for men   12.0–12.9 g/dL1  10.0–11.9 g/dL3  <10.0 g/dL6 Hemoglobin for women   10.0–11.9 g/dL1  <10.0 g/dL6 Other variables at presentation   Pulse ≥100 beats/min1  Melena1  Syncope2  Hepatic disease2  Cardiac failure2 B. ROCKALL SCOREVARIABLEPOINTSAge <60 y 60–79 y ≥80 y012Shock Heart rate >100 beats/min Systolic blood pressure <100 mmHg12Coexisting illness Ischemic heart disease, congestive heart failure, other major illness Renal failure, hepatic failure, metastatic cancer23Endoscopic diagnosis No lesions observed, Mallory-Weiss syndrome Peptic ulcer, erosive disease, esophagitis Cancer of the upper GI tract012Endoscopic stigmata of recent hemorrhage Clean base ulcer, flat pigmented spot Blood in upper GI tract, active bleeding, visible vessel, clot02aPanel A shows the values used in the Blatchford risk-stratification score, which ranges from 0 to 23, with higher scores indicating higher risk. Panel B shows the Rockall score, with point values assigned for each of three clinical variables (age and the presence of shock and coexisting illnesses) and two endoscopic variables (diagnosis and stigmata of recent hemorrhage). The complete Rockall score ranges from 0 to 11, with higher scores indicating higher risk. Patients with a clinical Rockall score (Age + Shock + Coexisting illness) of 0 or a complete Rockall score of 2 or less are considered to be at low risk for rebleeding or death.Reproduced with permission from Gralnek IM, Barkun AN, Bardou M: Management of acute bleeding from a peptic ulcer, N Engl J Med. 2008 Aug 28;359(9):928-937.COMPLETE ROCKALL SCORECLINICAL ROCKALL SCOREBrunicardi_Ch26_p1099-p1166.indd 112601/03/19 7:12 PM 1127STOMACHCHAPTER 26Surgical Treatment of Peptic Ulcer DiseaseThe indications for surgery in PUD are (in order of decreasing frequency) perforation, obstruction, bleeding, and intractabil-ity or nonhealing.114,115 Gastric cancer must always be consid-ered in patients with gastric ulcer or gastric outlet obstruction. Today, most patients undergoing emergent operation have simple patch of a perforated ulcer or oversewing of a bleed-ing ulcer.[92] Simultaneous performance of vagotomy either truncal or highly selective is increasingly uncommon, probably due to surgeon unfamiliarity with the procedure and reliance on postoperative PPIs to decrease acid secretion. But even in the current era, vagotomy may improve outcomes in emergency ulcer surgery.116-118 Before denying the stable low-risk patient a highly selective vagotomy or truncal vagotomy and drainage as an adjunct to simple patch or oversew, the surgeon should con-sider that many patients having emergency operation for peptic ulcer will not take long-term PPI, do not have Helicobacter, or will continue to smoke or take NSAIDs.Unfortunately, the data from many excellent randomized clinical trials evaluating elective operation for peptic ulcer over the last several decades may be irrelevant to most patients pre-senting for ulcer surgery today.114 The large majority of these excellent studies were done in the pre-PPI, pre-Helicobacter, pre-NSAID era, and focused on elective operation for intracta-ble disease, an unusual indication for operation nowadays. Thus, today’s surgeon should take great care in applying this literature to inform surgical decision making.Traditionally, the vast majority of peptic ulcers were treated by a variant of one of the three basic operations: parietal cell vagotomy, also called highly selective vagotomy (HSV) or proximal gastric vagotomy, vagotomy and drainage (V+D), and vagotomy and distal gastrectomy. Recurrence rates are lowest but morbidity highest with the latter procedure, while the oppo-site is true for HSV (Table 26-11).114,115HSV severs the vagal nerve supply to the proximal two-thirds of the stomach, where essentially all the parietal cells are located, and preserves the vagal innervation to the antrum and pylorus and the remaining abdominal viscera (Fig. 26-33). Thus, the operation decreases total gastric acid secretion by about 75%, and GI side effects are rare. Elective HSV has largely been supplanted by long-term PPI treatment, but the operation, which has a learning curve, may still be useful in the patient (elective or emergent) who is noncompliant with, intolerant of, or cannot afford medical treatment. Historically, HSV has not performed particularly well for type II (gastric and duodenal) and type III (prepyloric) gastric ulcer, perhaps because of hypergastrinemia caused by gastric outlet obstruction and persistent antral stasis. Figure 26-32. Pneumoperitoneum on upright chest X-ray in patient with perforated ulcer.Table 26-10Helicobacter pylori therapies (10–14 days)Clarithromycin triple therapy standard or double dose PPI twice a day clarithromycin 500 mg twice a day amoxicillin 1 g twice a day; or metronidazole 500 mg three times a dayMetronidazole triple therapy standard or double dose PPI twice a day metronidazole 500 mg twice a day amoxicillin 1 g twice a dayLevofloxacin triple therapy standard dose PPI twice a day amoxicillin 1 g twice a day levofloxacin 500 mg dailySequential therapy standard or double dose PPI (10–14 days) amoxicillin 1 g twice a day (5–7 days); then clarithromycin 500 mg twice a day and metronidazole 500 mg twice a day (5–7 days)Bismuth quadruple therapy (commonly used when above regimens fail to eradicate H pylori) standard dose PPI twice a day bismuth subsalicylate 300 mg four times a day tetracycline 500 mg four times a day metronidazole 250 mg four times a dayPPI = proton pump inhibitor.Table 26-11Clinical results of surgery for duodenal ulcer PARIETAL CELL VAGOTOMYTRUNCAL VAGOTOMY AND PYLOROPLASTYTRUNCAL VAGOTOMY AND ANTRECTOMYOperative mortality rate (%)0<11Ulcer recurrence rate (%)5–155–15<2Dumping (%) Mild<51010–15 Severe011–2Diarrhea (%) Mild<52520 Severe021–2Reproduced with permission from Mulholland MW, Debas HT: Chronic duodenal and gastric ulcer, Surg Clin North Am. 1987 Jun;67(3):489-507.Brunicardi_Ch26_p1099-p1166.indd 112701/03/19 7:12 PM 1128SPECIFIC CONSIDERATIONS PART IIThe Taylor procedure, a straightforward laparoscopic operation, consists of a posterior truncal vagotomy and anterior seromy-otomy (but anterior HSV is probably equivalent), and it is an attractive and simple alternative to HSV with similar results.Truncal vagotomy and pyloroplasty, and truncal vagot-omy and gastrojejunostomy are the paradigmatic vagotomy and drainage procedures. HSV may be substituted for truncal vagotomy. The advantage of V + D is that it can be performed safely and quickly by the experienced surgeon. The main dis-advantages are the side effect profile (10% of patients have significant dumping and/or diarrhea). During truncal vagotomy (Fig. 26-34), care must be taken not to perforate the esophagus, a potentially lethal complication. Intraoperative frozen sec-tion confirmation of at least two vagal trunks is prudent; addi-tional vagal trunks are common. Unlike HSV, V + D is widely accepted as a successful definitive operation for complicated PUD. It has been described as a useful part of the operative treatment for bleeding duodenal and gastric ulcer, perforated duodenal and gastric ulcer, and obstructing duodenal and gastric (types II and III) ulcer. When applied to gastric ulcer, the ulcer should be excised or biopsied.Truncal vagotomy denervates the antropyloric mechanism, and therefore, some sort of procedure is necessary to ablate or bypass the pylorus. Gastrojejunostomy is a good choice in patients with gastric outlet obstruction or a severely diseased proximal duodenum. The anastomosis is done between the proximal jejunum and the most dependent portion of the greater gastric curvature, in either an antecolic or retrocolic fashion (Fig. 26-35). Marginal ulceration is a potential complication. 6–8cm 7cmFigure 26-33. Highly selective vagotomy. (Reproduced with per-mission from Zinner MJ Schwartz SI, Ellis H: Maingot’s Abdominal Operations, 10th ed. Vol. I. Stamford, CT: Appleton & Lange; 1997.)Resected segmentResected segmentCeliac branchHepatic branchFigure 26-34. Truncal vagotomy. (Reproduced with permission from Zollinger RM Jr, Zollinger RM Sr: Zollinger’s Atlas of Surgi-cal Operations, 8th ed. New York, NY: McGraw-Hill Education; 2003.)Figure 26-35. Retrocolic gastrojejunostomy. Note meso-colon sutured to stomach (b, c, d). (Reproduced with per-mission from Zuidema GD, Yeo CJ: Shackelford’s Surgery of the Alimentary Tract, 5th ed. Vol. II. Philadelphia, PA: Elsevier/Saunders; 2002.)Suture reinforcing the angleMesocolonbcdStomachJejunumBrunicardi_Ch26_p1099-p1166.indd 112801/03/19 7:12 PM 1129STOMACHCHAPTER 26Mechanical complications are also possible such as afferent or efferent loop obstruction, internal hernia, and intussusception. Pyloroplasty is useful in patients who require a pyloroduo-denotomy to deal with the ulcer complication (e.g., posterior bleeding duodenal ulcer), in those with limited or focal scarring in the pyloric region, or when gastrojejunostomy is technically difficult. The most commonly performed pyloroplasty is the Heineke-Mikulicz type (Fig. 26-36). Other occasionally use-ful techniques include the Finney (Fig. 26-37) and the Jaboulay pyloroplasties (Fig. 26-38). These more extensive pyloroplasty techniques may make subsequent distal gastric resection more difficult and/or hazardous.Although vagotomy and antrectomy (V + A) is associated with a very low ulcer recurrence rate and is applicable to many patients with complicated PUD (e.g., bleeding duodenal and gastric ulcer, obstructing peptic ulcer, nonhealing gastric ulcer, and recurrent ulcer), V + A has a higher operative mortality risk (compared with HSV or V + D), and is irreversible. Fol-lowing antrectomy, GI continuity may be reestablished with a Billroth I gastroduodenostomy (Fig. 26-39) or a Billroth II loop gastrojejunostomy (Fig. 26-40). Since antrectomy routinely leaves a 60% to 70% gastric remnant, routine reconstruction as a Roux-en-Y gastrojejunostomy should be avoided (Fig. 26-41). Although the Roux-en-Y operation is an excellent procedure for keeping duodenal contents out of the stomach and esophagus, in the presence of a large gastric remnant, this reconstruction will predispose to marginal ulceration and/or gastric stasis.V + A should be avoided in hemodynamically unsta-ble patients, and in patients with extensive inflammation and/or scarring of the proximal duodenum, because secure MucosaPylorusAntrumGambee stitchCBDAFigure 26-36. A through D. Heineke-Mikulicz pyloroplasty. (Reproduced with permission from Zinner MJ: Atlas of Gastric Surgery. New York, NY: Elsevier/Churchill Livingstone; 1992.)Brunicardi_Ch26_p1099-p1166.indd 112901/03/19 7:12 PM 1130SPECIFIC CONSIDERATIONS PART IIanastomosis (Billroth I) or duodenal closure (Billroth II) may be difficult.Distal gastrectomy without vagotomy (usually about a 50% gastrectomy to include the ulcer) has traditionally been the procedure of choice for type I gastric ulcer. The addition of vagotomy should be considered for type II and III gastric ulcers (because the pathophysiology is more analogous to duodenal ulcer), or if the patient is believed to be at increased risk for recurrent ulcer, or perhaps even if Billroth II reconstruction is contemplated (to decrease the chance of marginal ulcer). Subto-tal gastrectomy (75% distal gastrectomy) without vagotomy is rarely used to treat PUD today, although it was the most popular ulcer operation at the middle of the last century.Pylorus preserving gastrectomy (PPG) was first reported as a surgical option for gastric ulcer that could minimize both dumping and duodenogastric reflux. Though not widely adopted for this indication, in some centers PPG is considered a good minimally invasive surgical option for early gastric cancer.119,120Choice of Operation for Peptic Ulcer. The choice of opera-tion for the individual patient with PUD depends on a variety of factors, including the type of ulcer (duodenal, gastric, recurrent, or marginal), the indication for operation, and the condition of the patient. Other important considerations are intra-abdominal factors (duodenal scarring/inflammation, adhesions, or difficult exposure), the ulcer diathesis status of the patient, the surgeon’s experience and personal preference, whether H pylori infection is present, the need for NSAID therapy, previous treatment, and the likelihood of future compliance with treatment. Table 26-12 shows the surgical options for managing various aspects of PUD. Stomach Stom.AB DC Approximation suture PylorusInvertedincisionGallbladderDuodenumConnellthrough & throughsuture (1st ant. tier)Duod.Cushingseromuscularsuture (2nd ant. tier)Posteriorthrough &through sutureFigure 26-37. A through D. Finney pyloroplasty. ant. = anterior; Duod. = duodenum; Stom. = stomach. (Reproduced with permission from Zuidema GD: Shackelford’s Surgery of the Alimentary Tract, 4th ed. Philadelphia, PA: Elsevier/Saunders; 1996.)Brunicardi_Ch26_p1099-p1166.indd 113001/03/19 7:12 PM 1131STOMACHCHAPTER 26In general, resective procedures have a lower ulcer recurrence rate, but a higher morbidity and mortality rate (see Table 26-11) compared to nonresective ulcer operations. Because ulcer recur-rence often is related to H pylori and/or NSAIDs, it is usually managed adequately without reoperation. Thus, gastric resection to minimize recurrence in duodenal ulcer disease is usually not justified; resection for gastric ulcer remains the standard because of the risk of cancer. Clearly, the modern trend in peptic ulcer operation could be described as “less is more.”121,122Bleeding Peptic UlcerBleeding is the most common cause of ulcer-related death, but only rarely do patients with bleeding gastric or duodenal ulcer require operation today. The success of endoscopic treatment and medical therapy for bleeding PUD has resulted in the selec-tion of a small subgroup of high-risk patients for today’s sur-geon. It is likely that patients currently coming to operation for bleeding PUD are at higher risk for a poor outcome than ever before. The surgical options for treating bleeding PUD include suture ligation of the bleeder; suture ligation and definitive non-resective ulcer operation (HSV or V + D); and gastric resection (usually, including vagotomy and ulcer excision). Gastric ulcer requires biopsy if not resected.The management of bleeding peptic ulcer is summarized in the algorithm provided in Fig. 26-42. All patients admitted to the hospital with bleeding peptic ulcer should be adequately Stomach Stom.AB DCPylorusInvertedincisionGallbladderDuodenumConnellthrough & throughsuture (1st ant. tier)Duod.Cushingseromuscularsuture (2nd ant. tier)Posteriorthrough &through sutureFigure 26-38. A through D. Jaboulay pyloroplasty. ant. = anterior; Duod. = duodenum; Stom. = stomach. (Reproduced with permission from Zuidema GD: Shackelford’s Surgery of the Alimentary Tract, 4th ed. Philadelphia, PA: Elsevier/Saunders; 1996.)Brunicardi_Ch26_p1099-p1166.indd 113101/03/19 7:12 PM 1132SPECIFIC CONSIDERATIONS PART IIresuscitated and started on IV PPI.125 Most patients will stop bleeding with these measures alone, but about 25% will continue to bleed or will rebleed in hospital. It is important to identify this high-risk group early with clinical and endoscopic parameters because, essentially, all the deaths from bleeding ulcer occur in this group. Surgical consultation is mandatory, and endoscopic hemostatic therapy (cautery, epinephrine injection, clipping) is indicated and usually successful in these high-risk patients.126 Indications for operation include massive hemorrhage unre-sponsive to initial endoscopic control, recurrent hemorrhage ABCFigure 26-40. A through C. Billroth II antecolic gastrojejunostomy. (Reproduced with permission from Zinner MJ Schwartz SI, Ellis H: Maingot’s Abdominal Operations, 10th ed. Vol. I. Stamford, CT: Appleton & Lange; 1997.)Figure 26-39. A and B. Billroth I gastroduo-denostomy. (Reproduced with permission from Zinner MJ: Atlas of Gastric Surgery. New York, NY: Elsevier/Churchill Livingstone; 1992.)ABBrunicardi_Ch26_p1099-p1166.indd 113201/03/19 7:12 PM 1133STOMACHCHAPTER 26requiring multiple transfusions after two attempts at endoscopic control, ongoing hemorrhage and transfusion with limited availability of blood for transfusion or lack of availability of a therapeutic endoscopist, early rehospitalization for bleeding ulcer, and concurrent indications for surgery such as perforation or obstruction. Patients with massive bleeding from high-risk lesions (e.g., posterior duodenal ulcer with erosion of gastroduo-denalartery, or lesser curvature gastric ulcer with erosion of left gastric artery or branch) should be considered for operation as should those presenting in shock, those requiring more than four units of blood in 24 hours or eight units of blood in 48 hours, and those with ulcers >2 cm in diameter. The mortality rate for surgery for bleeding peptic ulcer is around 20%. Angiography and embolization may be useful in some patients.Operation for Bleeding Peptic Ulcer (Fig. 26-43)The two operations most commonly used for bleeding duode-nal ulcer are oversewing of the ulcer with or without vagotomy and drainage,121 or V + A. Oversewing alone results in a higher rebleeding rate but a lower operative mortality rate than defini-tive operation. When the mortality for reoperation for rebleed-ing is considered, the overall mortality is probably comparable for the two approaches. Patients who are in shock or medically unstable should not have gastric resection.An initial pyloromyotomy incision allows access to the bleeding posterior duodenal ulcer, and an expeditious Kocher maneuver allows the surgeon to control the hemorrhage with the left hand if necessary. Heavy suture material on a stout needle is used to place figure-of-eight sutures or a U-stitch to secure the bleeding vessel at the base of the posterior duodenal ulcer. Multiple sutures are usually necessary. Once the surgeon is unequivocally convinced that hemostasis is secure, a pyloro-plasty can be performed. If the patient is stable, vagotomy may be considered if the surgeon is experienced and the vagotomy straightforward. If the patient is not a high operative risk and V + A is selected, smaller duodenal ulcers are resected with the specimen; larger bleeding duodenal ulcers must often be left behind in the duodenal stump. In this situation, suture hemo-stasis must be attained and a secure duodenal closure accom-plished. The anterior wall of the open duodenum can be sutured to either the proximal or distal lip of the posterior ulcer once the bleeding vessel has been sutured. The duodenal closure can be buttressed with omentum and the duodenum should be decompressed, either with a lateral duodenostomy or retrograde tube via the proximal jejunum or well secured nasogastric tube secured with tip well into afferent limb. Right upper quadrant closed suction peritoneal drainage is important. Use of a feed-ing jejunostomy is also considered. A Billroth II anastomosis reestablishes gastrointestinal continuity.The initial management of bleeding gastric ulcers and the indications for operation are similar to those for bleeding duodenal ulcer. These lesions tend to occur in older and/or medically complicated patients, and this fact may increase the operative risk. However, experience shows that planned surgery in a resuscitated patient results in a better operative survival rate than emergent operation in a patient who has rebled and is in shock. Distal gastric resection to include the bleeding ulcer is the procedure of choice for bleeding gastric ulcer. Second best is V + D with oversewing and biopsy of the ulcer to rule out cancer. Oversewing of the bleeder and biopsy followed by long-term acid suppression is a reasonable alternative in high-risk or unstable patients.50 to 60 cm< 50% gastricremnantFigure 26-41. Roux-en-Y gastrojejunostomy. (Reproduced with permission from Ritchie WP, Steele G, Dean RH: General Surgery. Philadelphia, PA: Lippincott Williams & Wilkins; 1995.)Table 26-12Surgical options in the treatment of duodenal and gastric ulcerINDICATIONDUODENALGASTRICBleeding1. Oversewa2. Oversew, V + D3. V + A1. Oversew and biopsya2. Oversew, biopsy, V + D3. Distal gastrectomybPerforation1. Patcha2. Patch, HSV3. Patch, V + D1. Biopsy and patcha2. Wedge excision, V + D3. Distal gastrectomybObstruction1. HSV + GJ2. V + A1. Biopsy; HSV + GJ2. Distal gastrectomybIntractability/nonhealing1. HSVb2. V + D3. V + A1. HSV and wedge excision2. Distal gastrectomyaUnless the patient is in shock or moribund, a definitive procedure should be considered.bOperation of choice in low-risk patient.GJ = gastrojejunostomy; HSV = highly selective vagotomy; V + A = vagotomy and antrectomy; V + D = vagotomy and drainage.Brunicardi_Ch26_p1099-p1166.indd 113301/03/19 7:12 PM 1134SPECIFIC CONSIDERATIONS PART IIPerforated Peptic Ulcer (Fig. 26-44)Perforation is the second most common complication of peptic ulcer, but nowadays it is a much more common indication for operation than bleeding. As with bleeding ulcer, NSAID and/or aspirin use have been inextricably linked with perforated PUD, especially in the elderly population.61 Surgery is almost always indicated for ulcer perforation, although occasionally nonsurgi-cal treatment can be used in the stable patient without peritoni-tis in whom radiologic studies document a sealed perforation. Patients with acute perforation and GI blood loss (either chronic or acute) should be suspected of having a second ulcer or a GI cancer.The options for surgical treatment of perforated duode-nal ulcer are simple patch closure, patch closure and HSV, or patch closure and V + D. Simple patch closure, currently the most commonly performed operation for perforated peptic ulcer, is the procedure of choice in patients with hemodynamic instability and/or exudative peritonitis signifying a perforation >24 hours old. In stable patients without longstanding perfo-ration, particularly those with chronic symptoms or failure of medical treatment, the addition of HSV should be considered. Vagotomy and drainage is also an acceptable definitive opera-tion for perforated duodenal ulcer, but occasionally side effects are disabling, and if gastrojejunostomy has been performed, Hospital admissionBleeding peptic ulcerBleeding recursin hospitalO.R.20% high risk80% Low riskBleeding stopsDischargeBleeding recursBleeding persists>4 PRBC transfused/24hDeep ulcer eroding big vesselHemodynamic instabilityHemostatic Rx unavailableEndoscopic hemostatic RxConsult surgeonResuscitateContinuous IV PPI dripEGDLifelong acid suppressionTest + Rx H. pyloriAvoid NSAIDs/ASA if possibleYesShock?NoYesTransfusion?NoYesActive bleeding on EGD?NoYesVisible vessel on EGD?NoYesAbnormal PT, PTT, or platelets?NoFigure 26-42. Algorithm for the treatment of bleeding peptic ulcer. ASA = acetylsalicylic acid; EGD = esophagogastroduodenoscopy; O.R. = operating room; PPI = proton pump inhibitor; PRBC = unit of packed red blood cells; PT = prothrombin time; PTT = partial throm-boplastin time; Rx = treatment.Brunicardi_Ch26_p1099-p1166.indd 113401/03/19 7:12 PM 1135STOMACHCHAPTER 26Operation for bleeding peptic ulcerYesYesNoGastric ulcerDuodenal ulcerType 1,2,3Distal gastrectomy**Hemodynamically unstable?OrHigh operative risk?Csendes procPauchet procKelling-Madlener proc(see text)*Add lifelong PPI**Add TV for type 2 + 3Oversew + TV/DOversew + TV/ABMI < 21? ordifficult duodenum?Type 4RebleedRebleedDuodenal ulcer*Gastric ulcer*1) Bx and oversew2) Wedge resectionOversewNoFigure 26-43. Algorithm for operation for bleeding peptic ulcer. BMI = body mass index; Bx = biopsy; PPI = proton pump inhibitor; proc = procedure; TV = truncal vagotomy; TV/A = truncal vagotomy and antrectomy; TV/D = truncal vagotomy and drainage.Operation for Perforated Peptic UlcerYesPatch + HSV,orPatch + TV/DWedge resection and TV/D or HSVOrDistal gastrectomy including perforation*** Duodenal ulcer* Gastric ulcer* PatchBx + PatchOrWedge resectionChronic ulcer HX?OrPerforation on RX?OrNSAIDs/ASA necessary? Gastric ulcer* Duodenal ulcer* Hemodynamically unstable?OrHigh operative risk?OrPerforation >24 hours * In all patients, test and treat for H pylori, and if vagotomy not performed (most patients today) consider lifelong PPI. ** Avoid truncal vagotomy and avoid gastrectomy if BMI<21 *** Consider adding vagotomy for type II and type III gastric ulcerNoNoYes**Figure 26-44. Algorithm for operation for perforated peptic ulcer. ASA = acetylsalicylic acid; BMI = body mass index; Bx = biopsy; HSV = highly selective vagotomy; Hx = history; PPI = proton pump inhibitor; Rx = treatment; TV/D = truncal vagotomy and drainage.Brunicardi_Ch26_p1099-p1166.indd 113501/03/19 7:12 PM 1136SPECIFIC CONSIDERATIONS PART IImarginal ulcer can be life-threatening. In the United States and Western Europe, there is clearly a trend away from definitive operation for perforated duodenal ulcer.92,121In the stable patient without multiple operative risk fac-tors, perforated gastric ulcers are best treated by distal gastric resection. Vagotomy is usually added for type II and III gastric ulcers. Patch closure with biopsy; or local excision and closure; or biopsy, closure, truncal vagotomy, and drainage are alter-native operations in the unstable or high-risk patient, or in the patient with a perforation in an inopportune location. All perfo-rated gastric ulcers, even those in the prepyloric position, should be biopsied if they are not removed at surgery.Obstructing Peptic UlcerAcute ulcers associated with obstruction due to edema and/or motor dysfunction may respond to intensive antisecretory ther-apy and nasogastric suction. But most patients with significant obstruction from chronic ulceration will require some sort of more substantial intervention. Endoscopic balloon dilation can often transiently improve obstructive symptoms, but many of these patients ultimately fail and come to operation.123The standard operation for obstructing PUD is vagotomy and antrectomy. Alternatively, vagotomy and gastrojejunos-tomy should be considered if a difficult duodenal stump is anticipated with resection. HSV and gastrojejunostomy may be comparable to V + A for obstructing ulcer disease,124 and this procedure is appealing because it can be done laparoscopically and does not complicate future resection, if needed. However, potentially curable gastric or duodenal cancers can be missed with this approach.Intractable or Nonhealing Peptic UlcerIntractability should be an unusual indication for peptic ulcer operation nowadays. The patient referred for surgical evaluation because of intractable PUD should raise red flags for the sur-geon: Maybe the patient has a missed cancer; maybe the patient is noncompliant (not taking prescribed PPI, still taking NSAIDs, still smoking); maybe the patient has Helicobacter despite the presence of a negative test or previous treatment. Because acid secretion can be totally blocked and H pylori eradicated with modern medication, the question remains: “Why does the patient have a persistent ulcer diathesis?” The surgeon should review the differential diagnosis of nonhealing ulcer before any consideration of operative treatment (Table 26-13).Surgical treatment should be considered in patients with nonhealing or intractable PUD who have multiple recurrences, large ulcers (>2 cm), complications (obstruction, perforation, or hemorrhage), or suspected malignancy. Definitive operation, particularly gastric resection, should be considered most cau-tiously in the thin or marginally nourished individual.It is important that the surgeon not fall into the trap of per-forming a large, irreversible operation on these patients, based on the unproven theory that if all other methods have failed to heal the ulcer, a large operation is required. Although there are good data in the surgical literature suggesting that the major-ity of patients do well after the larger elective ulcer operations, most of these data are several decades old and may not be par-ticularly relevant to the modern patient.114 Candidates for ulcer operation today are different than those of 30 to 50 years ago. One might argue that current medical care has healed the typical peptic ulcers, and that patients presenting with true intractabil-ity or nonhealing will be more difficult to treat and are likely to have chronic problems after a major ulcer operation.If surgery is necessary, a lesser operation may be preferable. It is prudent to avoid truncal vagotomy and/or distal gastrectomy as the initial elective operation for intractable peptic ulcer in the thin or asthenic patient. Alternatives for intractable duo-denal ulcer include HSV with or without gastrojejunostomy (reversible drainage operation). In patients with nonhealing gas-tric ulcer, wedge resection with HSV should be considered in thin or frail patients. Otherwise, distal gastrectomy (to include the ulcer) is recommended. It is unnecessary to add a vagotomy in patients with type I or type IV (juxta-esophageal) gastric ulcers because they are usually associated with acid hyposecretion. Type IV gastric ulcers may be difficult to resect as part of a distal gas-trectomy, and a variety of surgical techniques have been described to treat these more proximal lesions (Fig. 26-45).Zollinger-Ellison Syndrome127-129ZES is caused by the hypersecretion of gastrin, typically by a duodenal or pancreatic neuroendocrine tumor (i.e., gastrinoma). Most cases (80%) are sporadic, but 20% are inherited. The inherited or familial form of gastrinoma is associated with mul-tiple endocrine neoplasia type I (MEN I), which is characterized by parathyroid, pituitary, and pancreatic (or duodenal) tumors. Gastrinoma is the most common islet cell tumor in patients with MEN I. Patients with MEN I usually have multiple gastrinomas, and surgical cure is usually not achievable; sporadic gastrino-mas are more often solitary and are more often amenable to surgical cure. About 50% to 60% of gastrinomas are malignant, with lymph node, liver, or other distant metastases at operation. Five-year survival in patients presenting with metastatic disease is approximately 40%. More than 90% of patients with sporadic, completely resected gastrinoma will be cured.The most common symptoms of ZES are epigastric pain, GERD, and diarrhea. More than 90% of patients with gastri-noma have peptic ulcers. Most ulcers are in a typical location (proximal duodenum), but atypical ulcer location (distal duo-denum, jejunum, or multiple ulcers) should prompt an evalu-ation for gastrinoma. Gastrinoma also should be considered in the differential diagnosis of recurrent or refractory peptic ulcer, secretory diarrhea, gastric rugal hypertrophy, esophagi-tis with stricture, bleeding or perforated ulcer, familial ulcer, peptic ulcer with hypercalcemia, and gastric neuroendocrine tumor (carcinoid). The majority of patients with ZES have been symptomatic for several years before definitive diagnosis and, 3Table 26-13Differential diagnosis of intractability or nonhealing peptic ulcer diseaseCancer Gastric Pancreatic DuodenalPersistent Helicobacter pylori infection Tests may be false-negative Consider empiric treatmentNoncompliant patient Failure to take prescribed medication Surreptitious use of NSAIDsMotility disorderZollinger-Ellison syndromeBrunicardi_Ch26_p1099-p1166.indd 113601/03/19 7:12 PM 1137STOMACHCHAPTER 26in general, patients with ZES and MEN1 are diagnosed in their 20s and 30s, while those with sporadic ZES more typically are diagnosed in their 40s and 50s.ZES is an important element in the differential diagnosis of hypergastrinemia (Fig. 26-46). All patients with gastrinoma have an elevated gastrin level, and hypergastrinemia in the pres-ence of elevated BAO strongly suggests gastrinoma. Patients with gastrinoma usually have a BAO >15 mEq/h or >5 mEq/h if they have had a previous procedure for peptic ulcer. Acid secre-tory medications should be held for several days before gastrin measurement, because acid suppression may falsely elevate gas-trin levels. Causes of hypergastrinemia can be divided into those associated with hyperacidity and those associated with hypo-acidity (see Fig. 26-46). The diagnosis of ZES is confirmed by the secretin stimulation test. An IV bolus of secretin (2 U/kg) is given, and gastrin levels are checked before and after injection. An increase in serum gastrin of 200 pg/mL or greater suggests the presence of gastrinoma. Patients with gastrinoma should have serum calcium and parathyroid hormone levels determined to rule out MEN1 and, if present, parathyroidectomy should be considered before resection of gastrinoma.About 80% of primary tumors are found in the gastrinoma triangle (Fig. 26-47), and many tumors are small (<1 cm), mak-ing preoperative localization difficult. Transabdominal ultra-sound is quite specific, but not very sensitive. CT will detect most lesions >2 cm in size, and MRI is comparable. EUS is more sensitive than noninvasive imaging tests, but it still misses many smaller lesions or lesions in inaccessible locations (e.g., the pan-creatic tail). Somatostatin receptor scintigraphy (the octreotide scan) or Gallium-68 dotatate PET/CT are sensitive and specific when the pretest probability of gastrinoma is high and may iden-tify sites of regional or distant metastatic disease (Fig. 26-48). Angiographic localization studies are infrequently performed for gastrinoma. Both diagnostic angiography and transhepatic selective venous sampling of the portal system have been sup-planted by selective arterial secretin infusion, which helps to localize the tumor as inside or outside the gastrinoma triangle. This study too, is rarely performed given increasing availability of endoscopic ultrasonography and accurate nuclear medicine imaging.All patients with sporadic (nonfamilial) gastrinoma should be considered for surgical exploration. The lesions can be located in over 90% of patients, and a majority are cured by extirpation of the gastrinoma.130,131 A thorough intraoperative exploration of the gastrinoma triangle and pancreas is essential, but other sites (i.e., liver, stomach, small bowel, mesentery, and pelvis) should be evaluated as part of a thorough intra-abdom-inal evaluation to find the primary tumor, which is most often solitary and often in the duodenal wall. The duodenum and pan-creatic head should be extensively mobilized and intraoperative ultrasound should be utilized. Intraoperative EGD with transil-lumination may be considered. If the tumor cannot be located, longitudinal duodenotomy with inspection and palpation of the duodenal wall is performed. Lymph nodes from the portal, peri-pancreatic, and celiac drainage basins should be removed. Abla-tion or resection of hepatic metastases when identified should be considered.The management of gastrinoma in patients with MEN I is controversial because patients are infrequently cured by opera-tion. Acid hypersecretion in patients with gastrinoma can always be managed with high-dose PPIs. Highly selective vagotomy may make management easier in some patients and should be considered in those with surgically untreatable or unresectable gastrinoma. Gastrectomy for ZES is not indicated.STRESS GASTRITIS AND STRESS ULCERStress gastritis is a peculiar entity that has all but disappeared from the clinical (if not endoscopic) lexicon, largely due to bet-ter critical care and acid suppression or cytoprotective agents (e.g., sucralfate) in the intensive care unit (ICU). Stress gastritis and stress ulcer are probably due to inadequate gastric mucosal Figure 26-45. Operations for gastric ulcer. (Reproduced with permission from Feldman M, Sharschmidt BF, Sleisenger MH: Slei-senger and Fordtran’s Gastrointestinal and Liver Disease: Pathophysiology/Diagnosis/ Management 6th ed. Philadelphia, PA: Elsevier/Saunders; 1998.)Ulcer excisionAntrectomyPauchet procedureKelling-MadlenerprocedureCsendes procedure(Roux reconstruction)Csendes procedureBrunicardi_Ch26_p1099-p1166.indd 113701/03/19 7:12 PM 1138SPECIFIC CONSIDERATIONS PART IIblood flow during periods of intense physiologic stress. Ade-quate mucosal blood flow is important to maintain the mucosal barrier and to buffer any back-diffused hydrogen ions. When blood flow is inadequate, these processes fail and mucosal breakdown occurs. Modern intensive care, with emphasis on adequate tissue perfusion and oxygenation, has undoubtedly decreased the severity of gastric mucosal injury seen in the ICU today. Although it is still common to see small mucosal ero-sions when performing upper endoscopy in the ICU, it is rare for these lesions to coalesce into the larger bleeding erosions that plagued the ICU patient 30 to 50 years ago. The rationale for routine acid suppression in the ICU, supported by excellent data from clinical trials and the laboratory, is that less mucosal injury will be caused in the potentially weakened gastric mucosa if there is less luminal acid.132 There are some studies suggest-ing that routine acid suppression leads to overgrowth of gastric bacteria, which increases the incidence and/or severity of aspira-tion pneumonia in the ICU.133,134 Nevertheless, acid suppression, particularly in the severely ill patient, remains an important part of clinical pathways in most ICUs.135 In the extraordinarily rare patient requiring operation today for hemorrhagic stress gastri-tis, the surgical options include V + D with oversewing of the major bleeding lesions, or near total gastrectomy. Angiographic embolization and endoscopic hemostatic treatment should be considered as well.ATROPHIC GASTRITISAtrophic gastritis is characterized by atrophy or disappearance of gastric glands and loss of parietal and chief cells. The most common cause is chronic H pylori infection, particularly in the corporal distribution (as opposed to the antral distribution which is more typically associated with peptic ulcer disease). Auto-immune destruction of cells (pernicious anemia) and chemical irritation (e.g., bile reflux) can also result in atrophic gastritis. Some patients with atrophic gastritis develop intestinal meta-plasia in the gastric mucosa that may progress to dysplasia and then to gastric cancer. Numerous cofactors have been impli-cated, including diet, altered gastric microbiome, genetics, and hypergastrinemia. Patients with atrophic gastritis are at risk for Elevated serum gastrin(off PPI + H2RA)Measure BAO and gastric pHSecretin stimulation testBAO > 10 mEq/hpH <2BAO lowpH > 2Previous GI surgery• Vagotomy?• Massive SB resectionAtrophicgastritisPerniciousanemiaRenal insuffNoYesConfirm with EGD/Bxtest/treat H pylorigive B12Significant elevation in serumgastrin in response to IV secretin?G-cell +/or ECLcell hyperplasiaLoop GJ with antralalkalinizationTakedown GJOrTV and AConsider TV+ antrectomyRetained antrum on“duodenal stump”Resect retained antrumOrConvert B2 to B1AntralstasisS/P gastrectomy B2Confirm with EGD + BxConsider resectionZollinger-EllisonsyndromeOctreotide scanR/O MEN-1Figure 26-46. Algorithm for diagnosis and management of hypergastrinemia. BAO = basal acid output; B1 = Billroth 1; B2 = Billroth 2; Bx = biopsy; ECL = enterochromaffin-like; EGD = esophagogastroduodenoscopy; GJ = gastrojejunostomy; H2RA = histamine 2 receptor antagonist; insuff = insufficiency; MEN1 = multiple endocrine neoplasia type I; PPI = proton pump inhibitor; R/O = rule out; SB = small bowel; S/P = status post; TV = truncal vagotomy; TV and A = truncal vagotomy and antrectomy.Brunicardi_Ch26_p1099-p1166.indd 113801/03/19 7:12 PM 1139STOMACHCHAPTER 26gastric cancer and should undergo periodic endoscopic surveil-lance. Metaplastic atrophic gastritis and dysplastic atrophic gastritis in particular, are markers of increased risk for gastric cancer. Patients with high grade dysplasia may benefit from gas-trectomy. Cancer risk is related to the extent of the atrophic gas-tritis and intestinal metaplasia, and grading systems have been developed to stratify cancer risk based on endoscopic findings. Two such systems are the operative link on gastritis assessment (OLGA) and the operative link on gastric intestinal metaplasia (OLGIM) assessment.136,137 These systems define the severity (“stage”) of atrophic gastritis based on the histologic grading of at least five gastric biopsies (lesser and greater curve antrum; Figure 26-47. Gastrinoma triangle. (Reproduced with permission from Ritchie WP, Steele G, Dean RH: General Surgery. Philadelphia, PA: Lippincott Williams & Wilkins; 1995.)Figure 26-48. Positive gallium-68 dotatate scan in patient with gastrinoma.Table 26-14Types of gastric tumorsMalignant tumors Carcinoma Lymphoma Gastrointestinal stromal tumor (GIST) Neuroendocrine tumorBenign tumors Hyperplastic polyp Adenomatous polyp Leiomyoma Lipoma Schwannoma Hetrotopic pancreaslesser and greater curve corpus; angularis incisura). Since pathol-ogists are more likely to agree on the histological diagnosis of intestinal metaplasia than they are on atrophic gastritis, the latter tool (OLGIM) may be more useful in stratifying gastric cancer risk. Patients stratified as stage 3 or 4 gastritis and those with pernicious anemia may benefit from surveillance endoscopy every 3 years. Serum markers are also useful in helping to iden-tify patients with atrophic gastritis who usually have increased serum gastrin and iron deficiency due to parietal cell loss and hypochlorhydria or achlorhydria; decreased pepsinogen I levels due to chief cell loss; and B12 deficiency due to parietal cell loss and concomitant loss of intrinsic factor.MALIGNANT NEOPLASMS OF THE STOMACHThe most common primary malignant gastric neoplasm is adeno-carcinoma (95%); lymphoma and GIST account for most of the remaining cases (Table 26-14). Other rare primary malignancies include neuroendocrine tumor, angiosarcoma, carcinosarcoma, and squamous cell carcinoma. Occasionally the stomach is a site of hematogenous metastasis from other sites (e.g., melanoma or breast cancer). Malignant tumors from adjacent organs may also invade the stomach by direct extension (e.g., colon or pancreas) or by peritoneal dissemination (e.g., ovary or appendiceal).AdenocarcinomaEpidemiology. Gastric cancer is the fourth most common can-cer type and the second leading cause of cancer death world-wide. Over the past century, there has been a dramatic decrease in the incidence of gastric cancer in most Western industrialized countries (Fig. 26-49). This decrease has been largely in the so-called intestinal form rather than in the diffuse form of gastric cancer. In Asia and Eastern Europe, gastric cancer remains a leading cause of cancer death. In 2017 in the United States, approximately 28,000 new cases of stomach cancer were diagnosed (17,750 in men and 10,250 in women), and 10,960 deaths will be attributed to this disease (6720 in men and 4240 in women).138 The estimated 5-year survival rate is 27%, up from about 15% in 1975.In general, gastric cancer is a disease of the elderly, and it is twice as common in blacks as in whites. In younger patients, tumors are more often of the diffuse variety and tend to be large, aggressive, and poorly differentiated, sometimes involving the entire stomach (linitis plastic). Gastric cancer has a higher inci-dence in groups of lower socioeconomic status.4Brunicardi_Ch26_p1099-p1166.indd 113901/03/19 7:12 PM 1140SPECIFIC CONSIDERATIONS PART IIEtiology. Gastric cancer is more common in patients with per-nicious anemia, blood group A, or a family history of gastric cancer. When patients migrate from a high-incidence region to a low-incidence region, the risk of gastric cancer decreases in the subsequent generations born in the new region. This strongly suggests an environmental influence on the development of gas-tric cancer. Environmental factors appear to be more important in the pathogenesis of the intestinal form of gastric cancer com-pared to the diffuse form. The commonly accepted risk factors for gastric cancer are listed in Table 26-15.Diet and Drugs A diet high in pickled, salted, or smoked food is found in many regions of high gastric cancer risk. Dietary nitrates have been implicated as a possible cause of gastric cancer. Gastric bacteria (more abundant in the achlorhydric stomach of patients with atrophic gastritis, a risk factor for gastric cancer) convert nitrate into nitrite, a known carcinogen. A diet high in fresh fruits and vegetables and rich in vitamin C and E has been shown to decrease the risk of gastric cancer. The reduced consumption of nitrate-rich preserved foods seen with the widespread availability of refrigeration has been sug-gested as a cause of the dramatic decrease in gastric cancer seen in North America and Western Europe over the last century. Eastern AsiaCentral and Eastern EuropeLess developed regionsWorldMore developed regionsSouth AmericaWestern AsiaCentral AmericaSouthern EuropePolynesiaSouth-Central AsiaCaribbeanWestern EuropeMelanesiaSouth-Eastern AsiaNorthern EuropeSouthern AfricaAustralia/New ZealandEastern AfricaNorthern AmericaMiddle AfricaNorthern AfricaWestern AfricaMicronesia40302010010203040FemaleMaleIncidenceMortalityFigure 26-49. Gastric cancer incidence and death rates per 100,000 population in men and women, in different regions and countries. (Reproduced with permission from The Global Cancer Observatory All Rights Reserved, September, 2018.)Table 26-15Factors increasing or decreasing the risk of gastric cancerIncrease risk Family history Diet (high in nitrates, salt, fat) Familial polyposis Gastric adenomas Hereditary nonpolyposis colorectal cancer Helicobacter pylori infection  Atrophic gastritis, intestinal metaplasia, dysplasia Previous gastrectomy or gastrojejunostomy (>10 y ago) Tobacco use Ménétrier’s diseaseDecrease risk Aspirin Diet (high fresh fruit and vegetable intake) Vitamin CBrunicardi_Ch26_p1099-p1166.indd 114001/03/19 7:12 PM 1141STOMACHCHAPTER 26Tobacco use probably increases the risk of stomach cancer, and alcohol use probably has no effect. Regular aspirin use may be protective.Helicobacter pylori80,139 The risk of gastric cancer in patients with chronic H pylori infection is increased about threefold. Compared to uninfected patients, patients with a history of gas-tric ulcers are more likely to develop gastric cancer (incidence ratio 1.8, 95% confidence interval 1.6–2.0), and patients with a history of duodenal ulcers are at decreased risk for gastric can-cer (incidence ratio 0.6, 95% confidence interval 0.4–0.7). This may be due to the fact that some patients develop antral-pre-dominant disease (predisposing to duodenal ulcer and somehow protecting against gastric cancer), while other patients develop corpus-predominant gastritis, resulting in hypochlorhydria and somehow predisposing to gastric ulcer and gastric cancer (Fig. 26-50).10 The theoretical sequence for development of gas-tric adenocarcinoma is diagrammed in Fig. 26-51.10,80 Recently, it has been demonstrated that bone marrow-derived stem cells play a key role in the pathogenesis of gastric adenocarcinoma in patients with chronic H pylori infection.80 However, it must be recognized that gastric adenocarcinoma is a multifactorial dis-ease. Not all patients with gastric cancer have H pylori, and there are some geographic areas with a high prevalence of chronic H pylori infection and a low prevalence of gastric cancer (the “African enigma”). Finally, H pylori–infected patients seem to be at decreased risk for the development of adenocarcinoma of the distal esophagus and cardia region.140 Perhaps corporeal gas-tritis decreases acid secretion, creating a less damaging refluxate and thus reducing the risk for Barrett’s esophagus, the precursor lesion for these tumors.Epstein-Barr Virus About 10% of gastric adenocarcinomas carry the EBV virus. Recently it has been suggested that EBV infection is a late step in gastric carcinogenesis, since EBV tran-scripts are present in cancer cells but not in the metaplastic cells of precursor epithelium.141Genetic Factors A variety of genetic abnormalities have been described in gastric cancer (Table 26-16). Most gastric can-cers are aneuploid. The most common genetic abnormalities in sporadic gastric cancer affect the p53 and COX-2 genes. Over two-thirds of gastric cancers have deletion or suppression of the important tumor-suppressor gene p53. Additionally, approxi-mately the same proportion have overexpression of COX-2. In the colon, tumors with upregulation of this gene have suppressed apoptosis, more angiogenesis, and higher metastatic potential. Gastric tumors that overexpress COX-2 are more aggressive. Recently, a germline mutation in the CDH1 gene encoding E-cadherin was shown to be associated with hereditary diffuse gastric cancer. Prophylactic total gastrectomy should be consid-ered in patients with these mutations.142Premalignant Conditions of the Stomach Figure 26-52 shows the prevalence of some premalignant conditions associated with the development of early gastric cancer in a series of 1900 cases from Tokyo. By far the most common precancerous lesion is atrophic gastritis. There is a growing appreciation of the impor-tant influence of the chronic inflammatory milieu on the genome of mucosal cells. Chronic inflammation leads to both genetic Acute pangastritisChronic pangastritisDecreased acidGastric cancerChronic antral gastritisDecreased SSTIncreased gastrinIncreased acidDUFigure 26-50. Helicobacter, gastritis, and the pathogenesis of duo-denal ulcer (DU) or gastric cancer.Figure 26-51. Gastric carcinogenesis. (Reproduced with permission from Yamada T, Alpers DH, Laine L, et al: Textbook of Gastroenterology, 4th ed. Philadelphia, PA: Lippincott Williams & Wilkins; 2003.)NormalDysplasiaCancerIntestinal metaplasiaAtrophic gastritisChronic superficial gastritisH pyloriDiet low in vitamin C, EHigh-salt dietBrunicardi_Ch26_p1099-p1166.indd 114101/03/19 7:12 PM 1142SPECIFIC CONSIDERATIONS PART IIand epigenetic changes in mucosal cells, which in the stomach leads to the development of gastritis-associated cancer.143,144Polyps Benign gastric polyps are classified as neoplastic (ade-noma and fundic gland polyps) or nonneoplastic (hyperplastic polyp, inflammatory polyp, hamartomatous polyp).145 In general, inflammatory and hamartomatous polyps have little or no malig-nant potential. Fundic gland polyps, commonly seen in patients on long-term PPI therapy, are not premalignant, but in patients with familial adenomatous polyposis (FAP), dysplasia in these lesions is not uncommon, and there are numerous reports of gas-tric cancer arising in a background of fundic gland polyposis in this setting. Hyperplastic polyps usually occur in the setting of chronic inflammation. Large hyperplastic polyps (>2 cm) may harbor dysplasia or carcinoma in situ, and gastric cancer may develop remote from the hyperplastic polyp in an area of associ-ated chronic inflammation. Gastric adenomas are premalignant. Patients with familial adenomatous polyposis (FAP) have a high prevalence of gastric adenomatous polyps (about 50%), and are 10 times more likely to develop adenocarcinoma of the stomach than the general population.146 Screening EGD is indicated in these families. Patients with hereditary nonpolyposis colorectal cancer may also be at risk for gastric cancer.147Atrophic Gastritis Chronic atrophic gastritis (Fig. 26-53) is by far the most common precursor for gastric cancer, particularly the intestinal subtype (see Fig. 26-52). The prevalence of atro-phic gastritis is higher in older age groups, but it is also com-mon in younger people in areas with a high incidence of gastric cancer. In many patients, H pylori is critical in the pathogenesis of atrophic gastritis. Correa described three distinct patterns of chronic atrophic gastritis: autoimmune (involves the acid-secreting proximal stomach), hypersecretory (involving the distal stomach), and environmental (involving multiple random areas at the junction of the oxyntic and antral mucosa).139Intestinal Metaplasia Gastric carcinoma often occurs in an area of intestinal metaplasia, and the risk of gastric cancer is proportional to the extent of intestinal metaplasia of the gastric mucosa. These observations suggest that intestinal metaplasia is a precursor lesion to gastric cancer. There are different pathologic subtypes of intestinal metaplasia in the stomach, based upon the histologic and biochemical characteristics of the changed muco-sal glands. In the complete type of intestinal metaplasia, the glands are lined with goblet cells and intestinal absorptive cells Table 26-16Genetic abnormalities in gastric cancerABNORMALITIESGENEAPPROXIMATE FREQUENCY %Deletion/suppressionp53FHITAPCDCCE-cadherin60–70605050<5Amplification/overexpressionCOX-2HGF/SFVEGFc-metAIB-1β-catenink-samrasc-erb B-27060504540252010–155–7Microsatellite instability 25–40DNA aneuploidy 60–75Reproduced with permission from Feldman M, Friedman LS, Sleisenger MH, et al: Sleisenger and Fordtran’s Gastrointestinal and Liver Disease, 7th ed. Philadelphia, PA: Elsevier/Saunders; 2002.1900 CasesPrecancerouslesionNumber of casesHyperplasticpolypAdenomaChronic ulcerAtrophicgastritisVerrucousgastritisStomachremnantAberrantpancreas10471318022620Total 19000.532.470.6894.841.370.110100%Figure 26-52. Precancerous lesions of the stomach.Figure 26-53. Chronic atrophic gastritis. (Used with permission from Kristen Stashek, MD.)Brunicardi_Ch26_p1099-p1166.indd 114201/03/19 7:12 PM 1143STOMACHCHAPTER 26(Fig. 26-54). These cells are indistinguishable histologically and biochemically from their small bowel counterparts. There is evi-dence that eradication of H pylori infection leads to significant regression of intestinal metaplasia and improvement in atrophic gastritis. Treatment of H pylori is mandatory for patients with these pathologic findings and H pylori infection.Benign Gastric Ulcer Although once considered a premalig-nant condition, it is likely that the older literature addressing gastric ulcers was confounded by the inclusion of inadequately biopsied ulcers s as “benign,” when, in fact, they were malig-nant. Regardless, all gastric ulcers should be viewed as malig-nant until proven otherwise with adequate biopsy and follow-up.Gastric Remnant Cancer It has long been recognized that stomach cancer can develop in the gastric remnant following subtotal gastrectomy. The extent of risk is controversial, but the phenomenon is real. Most tumors develop >10 years follow-ing the initial operation, and they usually arise in an area of chronic gastritis, metaplasia, and dysplasia. This is often near the anastomosis, but many of these tumors are quite large at pre-sentation. Bile or alkali reflux gastritis has been implicated as a precursor, and the greatest number of cases have been reported following Billroth II gastroenterostomy where some transit of pancreatic and biliary secretions through the stomach is obli-gate. Although Roux-en-Y anastomosis has been suggested to be protective, this hypothesis remains unproven. Stage for stage, the prognosis for gastric stump cancer is similar to that of other proximal gastric cancers.148Other Premalignant States Mutations in the E-cadherin gene (CDH1) are associated with hereditary diffuse gastric cancer (HDGC). HDGC is an autosomal dominant trait with a high degree of penetrance. Indeed, the lifetime risk of gastric cancer in individuals with pathogenic germline mutations is 70% (in men) and 56% (in women).149 CDH1 is a tumor-suppressor gene and a second somatic hit is required for tumorigenesis. The median age at diagnosis of gastric cancer is 38 years. Presentation with clini-cally significant gastric cancer in this setting is associated with a grave prognosis. Increasing recognition of HDGC has afforded the opportunity for early recognition of pathogenic mutations in relatives of individuals with index cases and utilization of prophy-lactic or early total gastrectomy.142 Multifocal intramucosal carci-noma is a frequent finding on putative prophylactic gastrectomy specimens, even in patients without a preoperative diagnosis of carcinoma, affirming the role of early intervention. Surgery should be conducted with the aim of complete extirpation of the stomach to squamous lined esophagus proximally and normal duodenal mucosa distally. Mutation-carrying females are also at increased risk of breast cancer, most often lobular carcinomas, and should be carefully monitored.Up to 10% of gastric cancer cases appear to be familial without a clear-cut genetic diagnosis. First-degree relatives of patients with gastric cancer have a twoto threefold increased risk of developing the disease. Patients with hereditary nonpol-yposis colorectal cancer have a 10% risk of developing gastric cancer, predominantly the intestinal subtype. The mucous cell hyperplasia of Ménétrier’s disease is generally considered to carry a 5% to 10% risk of adenocarcinoma. Periodic surveil-lance EGD is prudent in all the aforementioned conditions. The glandular hyperplasia associated with gastrinoma is not prema-lignant, but ECL hyperplasia and/or carcinoid tumors can occur.PathologyDysplasia It is generally accepted that gastric dysplasia is the universal precursor to gastric adenocarcinoma. Patients with severe dysplasia should be considered for gastric resection if the abnormality is widespread or multifocal, or EMR if the severe dysplasia is localized. Patients with mild dysplasia should be followed with endoscopic biopsy surveillance, and Helicobacter eradication.Early Gastric Cancer Early gastric cancer is defined as adeno-carcinoma limited to the mucosa (T1a) and submucosa (T1b) of the stomach. The entity is common in Asia, where the higher frequency of gastric cancer justified adoption of aggressive surveillance programs. Approximately 10% of patients clini-cally staged with early gastric cancer will have lymph node metastases. There are several subtypes of early gastric cancer (Table 26-17 and Fig. 26-55). Approximately 70% of early gas-tric cancers are well differentiated, and 30% are poorly differen-tiated. The overall cure rate with adequate gastric resection and lymphadenectomy is 95%. In some Japanese centers, 50% of the gastric cancers treated are early stage (compared to less than 20% of resected gastric adenocarcinomas in the United States). Selected patients with early gastric cancer can be treated with endoscopic resection.150Table 26-17Macroscopic types of superficial gastric cancerType 0-I (protruding)aPolypoid tumorsType 0-II (superficial)Tumors with or without minimal elevation or depression relative to the surrounding mucosa Type 0-IIaSlightly elevated tumors (superficial elevated) Type 0-IIbTumors without elevation or depression (superficial flat) Type 0-IIcSlightly depressed tumors (superficial depressed)Type 0-III (excavated)Tumors with deep depressionaTumors with less than 3-mm elevation are usually classified as–IIa, with more elevated tumors being classified as 0-I.Figure 26-54. Complete intestinal metaplasia of the stomach. Note intestinal type crypts lined with goblet cells and intestinal absorptive cells. (Used with permission from Kristen Stashek, MD.)Brunicardi_Ch26_p1099-p1166.indd 114301/03/19 7:12 PM 1144SPECIFIC CONSIDERATIONS PART IIGross Morphology and Histologic Subtypes Gastric cancer has been subdivided into four morphologic subtypes: polypoid, fungating, ulcerative, and scirrhous. The first two are character-ized by a largely intraluminal mass. Polypoid tumors are not ulcerated; fungating tumors are predominantly intraluminal with ulceration. In the latter two gross subtypes, the bulk of the tumor mass is confined to the wall of the stomach. Ulcerative tumors are self-descriptive. Scirrhous tumors infiltrate the entire thickness of the stomach and cover a very large surface area, commonly involve the entire stomach and have a particularly poor prognosis. Although these latter lesions may be technically resectable with total gastrectomy, it is common for both the esophageal and duodenal margins of resection to show micro-scopic evidence of tumor infiltration; distant metastasis, overt or occult, is frequent and death from recurrent disease within 6 months is common. Palliative chemotherapy may prolong median survival.151The location of the primary tumor in the stomach is essen-tial in planning an operation. Several decades ago, the large majority of gastric cancers were in the distal stomach. Recently, there has been a proximal migration of tumors, so currently, the distribution is closer to 40% distal, 30% middle, and 30% proximal.Histology The most important prognostic indicators in gastric cancer are both histologic: lymph node involvement and depth of tumor invasion. Tumor grade (degree of differentiation: well, moderately, or poorly) is also important prognostically.There are several histologic classifications of gastric cancer. The World Health Organization recognizes several histologic types (Table 26-18). The Japanese classification is similar but more detailed. The commonly used Lauren classifi-cation separates gastric cancers into intestinal type (53%), dif-fuse type (33%), and unclassified (14%). The intestinal type is associated with chronic atrophic gastritis, severe intestinal meta-plasia, and dysplasia, and tends to be less aggressive than the diffuse type. The diffuse type of gastric cancer is more likely to be poorly differentiated and is associated with younger patients and proximal tumors. The Ming classification also is useful and easy to remember, with only two types—expanding (67%) and infiltrative (33%).Recently, the significance of human epidermal growth factor receptor-2 (HER2) was reported in patients with gastric cancer. In breast cancer, overexpression of HER2 has been reported in 15% to 25% of cases, and it is well recognized as an unfavorable prognostic factor. The development of molecular targeted agents such as trastuzumab has improved the survival of HER2-positive patients. Likewise, in gastric cancer, HER2 overexpression has been reported in 13% to 30% of patients. HER2 targeting with trastuzumab resulted in improved survival in patients with stage IV gastric cancer, and immunohistochem-istry (IHC) staining for HER2 should be performed in recurrent or metastatic cases.152 Expression of other growth receptors in gastric cancer have been characterized as well, including HER1 (epidermal growth factor rector) and HER3. The latter is associ-ated with poor prognosis, but efforts to target these receptors for therapeutic benefit are still exploratory.153Pathologic Staging Ultimately, prognosis is related to patho-logic stage. The most widespread system for staging of gastric cancer is the tumor-node-metastasis (TNM) staging system based on depth of tumor invasion, extent of lymph node metastases, and presence of distant metastases. This system was developed by the American Joint Committee on Cancer and the International Union Against Cancer, and it has under gone several modifications since it was originally conceived (Table 26-19).Clinical Manifestations. Most patients who are diagnosed with gastric cancer in the United States have advanced stage III or IV disease at the time of diagnosis. The most common symp-toms are weight loss and decreased food intake due to anorexia and early satiety. Abdominal pain (usually not severe and often ignored) is also common. Other symptoms include nausea, vomit-ing, and bloating. Acute GI bleeding is somewhat unusual (5%), but chronic occult blood loss is common and manifests as iron Type IIaType IType IIBType IIcType IIIExcavatedDepressedFlatElevatedProtrudedFigure 26-55. Pathologic types of early gastric cancer. (Repro-duced with permission from Fenoglio-Preiser CM, Noffsinger AE, Belli J, et al: Pathologic and phenotypic features of gastric cancer, Semin Oncol. 1996 Jun;23(3):292-306.)Table 26-18World Health Organization histologic typing of gastric cancerAdenocarcinoma Papillary adenocarcinoma Tubular adenocarcinoma Mucinous adenocarcinoma Signet-ring cell carcinomaAdenosquamous carcinomaSquamous cell carcinomaSmall cell carcinomaUndifferentiated carcinomaOthersReproduced with permission from Ming S-C, Goldman H: Pathology of the Gastrointestinal Tract, 2nd ed. Baltimore, MD: Williams & Wilkins; 1998.Brunicardi_Ch26_p1099-p1166.indd 114401/03/19 7:12 PM 1145STOMACHCHAPTER 26deficiency anemia and heme-positive stool. Dysphagia is com-mon if the tumor involves the cardia of the stomach. Paraneoplas-tic syndromes such as Trousseau’s syndrome (thrombophlebitis), acanthosis nigricans (hyperpigmentation of the axilla and groin), or peripheral neuropathy are rarely present.Physical examination typically is normal. Other than signs of weight loss, specific positive physical findings usually indi-cate incurability. A focused examination in a patient in whom gastric cancer is a likely part of the differential diagnosis should include an examination of the neck, chest, abdomen, and rectum. Cervical, supraclavicular (on the left referred to as Virchow’s node), and axillary lymph nodes may be enlarged, and can be sampled with fine-needle aspiration cytology. Malignant pleural effusions or ascites, or aspiration pneumonitis may be present. An abdominal mass may indicate a large (usually T4) primary tumor, liver metastases, or carcinomatosis (including Kruken-berg’s tumor of the ovary). A palpable umbilical nodule (Sister Joseph’s nodule) is pathognomonic of advanced disease. Rec-tal exam may reveal heme-positive stool and hard nodularity extraluminally and anteriorly, indicating so-called drop metas-tases, or rectal shelf of Blumer in the pouch of Douglas.Diagnostic Evaluation. Distinguishing between peptic ulcer and gastric cancer on clinical grounds alone can be difficult. Patients over the age of 55 years who have new-onset dyspep-sia as well as all patients with dyspepsia and alarm symptoms (weight loss, recurrent vomiting, dysphagia, evidence of GI bleeding, or anemia) or with a family history of gastric cancer should undergo prompt upper endoscopy and biopsy if a muco-sal lesion is noted. Essentially, all patients in whom gastric can-cer is part of the differential diagnosis should have endoscopy and biopsy. If suspicion for cancer is high and the biopsy is negative, the patient should be reendoscoped and more aggres-sively biopsied. In some patients with gastric tumors, upper GI series can be helpful in planning treatment. Although a good double-contrast barium upper GI examination is sensitive for gastric tumors (up to 75% sensitive), in most centers, endos-copy has become the gold standard for the diagnosis of gastric malignancy. In addition, recent advances in endoscopy have contributed to the earlier diagnosis of gastric cancer. Magnify-ing endoscopy with narrow-band imaging (NBI) has undergone technological improvements and can observe the microvascu-lar architecture of the mucosa and microsurface pattern of the lesion. Magnifying endoscopy with NBI has been reported to be accurate and reliable in the diagnosis of early gastric cancer.154Preoperative staging of gastric cancer is best accomplished with abdominal/pelvic CT scanning with IV and oral contrast. MRI is probably comparable. The best way to stage the tumor locally is via EUS, which gives fairly accurate (80%) informa-tion about the depth of tumor penetration into the gastric wall, and can usually show enlarged (>5 mm) perigastric and celiac lymph nodes. However, there are limitations to tumor staging with EUS. It is highly operator dependent and may underes-timate lymph node involvement because normal-sized nodes (<5 mm) can harbor metastases. EUS is most accurate in distin-guishing early gastric cancer (T1) from more advanced tumors.Positron Emission Tomography Scanning Whole-body PET scanning derives its power from the preferential accumulation of positron-emitting 18F-fluorodeoxy glucose in tumor com-pared to nontumor cells. It is most useful in the evaluation of distant metastasis in gastric cancer, but it can also be useful in locoregional staging. PET scan is accurate when combined with spiral CT (PET-CT)155 and should be considered before major surgery in patients with particularly high-risk or locally advanced tumors.Staging Laparoscopy and Peritoneal Cytology Laparoscopy has emerged as a valuable adjunct to gastric cancer staging, par-ticularly in patients with more substantial tumors. This modality allows for rapid identification of macrosopic peritoneal metas-tases. Peritoneal lavage identifies an additional subset of patients with microscopic dissemination. The prognostic 5Table 26-19AJCC Staging Classification for 8th EditionsAJCC 8TH EDITIONSTAGETNMIAT1N0M0IBT2N0M0T1N1M0IIAT3N0M0T2N1M0T1N2M0IIBT4aN0M0T3N1M0T2N2M0T1N3aM0IIIAT4bN1M0T4aN1M0T4aN2M0T3N2M0T2N3aM0IIIBT4bN1M0T4bN2M0T4aN3aM0T3N3aM0T2N3bM0T1N3bM0IIICT4bN3aM0T4bN3bM0T4aN3bM0T3N3bM0IVAny TAny NM1T1 Tumor invades lamina propria, muscularis mucosa, or submucosa, T2 Tumor invades muscularis propria, T3 Tumor penetrates subserosal connective tissue without invasion of visceral peritoneum or adjacent structures, T4a Tumor invades serosa (visceral peritoneum), T4b: Tumor invades adjacent structures, N0 No regional lymph node metastasis, N1 Metastasis in 1-2 regional lymph nodes, N2: Metastasis in 3-6 regional lymph nodes, N3: Metastasis in 7 or more regional lymph nodes, N3a: Metastasis in 7-15 regional lymph nodes N3b: Metastasis in 16 or more regional lymph nodes, M0 No distant metastasis, M1 Distant metastasis.Used with the permission of the American College of Surgeons. Amin MB, Edge SB, Greene FL, et al. (Eds.) AJCC Cancer Staging Manual, 8th Ed. Springer New York, 2017.Brunicardi_Ch26_p1099-p1166.indd 114501/03/19 7:12 PM 1146SPECIFIC CONSIDERATIONS PART IIsignificance of the latter has been established by several investigators.156,157 Gastrectomy should be deferred in patients with positive peritoneal cytology without obvious peritoneal metastases. Patients with gastric cancer who undergo R0 resec-tion (i.e., no gross residual disease) and are found to have posi-tive peritoneal cytology (no gross carcinomatosis) have a much poorer prognosis than those with negative cytology (median survival 14.8 months vs. 98.5 months).156 Stand-alone laparos-copy may influence management in up to 36% of cases and is increasingly advocated to allow appropriate initial treatment selection. The yield is likely highest in patients with T3 or T4 tumors, proximal tumors, or evidence of regional nodal involve-ment158; such patients may benefit from neoadjuvant therapy, and laparoscopy should be offered prior to initiation of treat-ment. Systemic therapy is the cornerstone of therapy for patients with Stage IV disease and surgery is generally reserved for pal-liation of symptoms (e.g., an obstructing distal tumor) in patients with metastases identified during laparoscopy.Treatment. Surgical resection is the only potentially curative treatment for gastric cancer,159 and most patients with clini-cally resectable locoregional disease should undergo gastrec-tomy. The goals of curative surgical treatment are resection of all tumor (i.e., R0 resection and adequate lymphadenectomy to afford accurate staging and provide locoregional control. Gener-ally, the surgeon strives for a grossly negative margin of at least 5 cm, although an evidence base for this is lacking and recent retrospective analyses have suggested that more conservative resections may be adequate.160 Conversely, complete resection of diffuse tumors sometimes proves challenging, and wider gross margins guided by frozen section are sometimes appro-priate. Prior to extending the resection on the basis of a positive frozen section margin, the surgeon should determine whether the microscopic tumor cells are within the wall or on the serosal. The latter may indicate incurable disseminated disease, render-ing additional resection proximally or distally moot, particularly when it makes the anastomosis or stump closure more difficult or hazardous.More than 15 resected lymph nodes are required for ade-quate staging, a relevant marker of quality of care.161,162 Thera-peutic nihilism should be avoided, and in the low-risk patient, an aggressive attempt to resect all tumor should be made. The primary tumor may be resected en bloc with adjacent involved organs (e.g., distal pancreas, transverse colon, or spleen) during the course of curative gastrectomy. Palliative gastrectomy may be indicated in the rare patient with incurable disease, but most patients presenting with stage IV gastric cancer can be managed without major operation.163Extent of Gastrectomy The standard operation for gastric cancer is radical subtotal gastrectomy. Unless required for R0 resection, total gastrectomy confers no additional survival ben-efit and may have adverse nutritional or quality-of-life conse-quences and higher perioperative morbidity and mortality.164 Subtotal gastric resection typically entails ligation of the left and right gastric and gastroepiploic arteries at their origins, as well as the en bloc removal of the distal 2/3 of the stomach, includ-ing the pylorus and 2 cm of duodenum, the greater and lesser omentum, and all associated lymphatic tissue (Fig. 26-56). In the absence of involvement by direct extension, the spleen and pancreatic tail are not removed.Reconstruction is usually by Billroth II gastrojejunostomy or Roux-en-Y gastrojejunostomy. The former is associated with shorter operative time and precludes roux limb stasis. The lat-ter mitigates bile reflux and, therefore, may be associated with better quality of life long term. In East Asia, especially Japan, Billroth-I gastroduodenostomy is frequently performed after distal gastrectomy. Billroth-I gastroduodenostomy consists of one anastomosis (which is usually straightforward and keeps the duodenum in the food stream). In the United States, traditional surgical teaching eschews gastroduodenostomy following gas-tric cancer resection because of the possibility of anastomotic recurrence and obstruction. A risk of remnant carcinoma attrib-uted to bile reflux has been invoked in support of Roux-en-Y reconstruction over Billroth II or I. Strong evidence linking reconstruction approach to long-term oncologic outcome is lacking.Total gastrectomy with Roux-en-Y esophagojejunostomy may be required for R0 resection (Fig. 26-57) and is frequently the optimal operation for patients with proximal gastric adeno-carcinoma. The construction of a jejunal pouch is associated with superior nutritional recovery in some but not all reports, and is a consideration.102 Proximal subtotal gastric resection, Gastroepiploicvs.ABDuodenumTransverse colonTumorLiverStomachStomachJejunumTransverse colonPancreasFigure 26-56. A and B. Radical subtotal gastrectomy. vs. = vessels. (Reproduced with permission from Daly JM, Cady B, Low DW: Atlas of Surgical Oncology. St. Louis, MO: Elsevier/Mosby-Year Book; 1993.)Brunicardi_Ch26_p1099-p1166.indd 114601/03/19 7:13 PM 1147STOMACHCHAPTER 26a technically feasible alternative to total gastrectomy for some proximal gastric tumors, requires esophagogastrostomy to a denervated distal gastric remnant, and functional outcomes are generally poor.165 Pyloroplasty in this setting virtually guar-antees bile esophagitis, and if the pylorus is left intact, gastric emptying may be problematic. An isoperistaltic jejunal intero-sition (Henley loop) between the esophagus and antrum may mitigate some of the adverse symptoms associated with this operation but adds additional complexity.Extent of Lymphadenectomy The 3rd edition of Japanese classification of gastric carcinoma defines lymph node sta-tions on the basis of anatomic landmarks. Lymph node stations 1 to 12 and 14V are classified as regional and metastasis to any other lymph nodal stations constitute distant disease (M1) (see Fig. 26-4). So-called D1 lymphadenectomy in distal gastrec-tomy requires the dissection of stations 1, 3, 4sb, 4d, 5, 6, and 7. Additional resection of stations 8a, 9, 11p, and 12a constitute D2 lymphadenectomy. D1 lymphadenectomy in total gastrec-tomy requires dissection of stations 1 through 7; D2 lymph-adenectomy includes stations 8a to 12a as well. The operation most commonly performed in the United States for gastric cancer is a D1 resection and involves removal of the primary tumor with perigastric nodes. The standard operation for gastric cancer in Asia and specialized U.S. centers is D2 gastrectomy, which involves a more extensive lymphadenectomy (removal of the D1 and D2 nodes). In addition to the tissue removed in a D1 resection, D2 gastrectomy includes the superior peritoneum overlying the mesocolon and, selectively, the pancreas, as well as nodes along the common hepatic and splenic arteries, and the celiac axis. Splenectomy and distal pancreatectomy are not routinely performed because this has been shown to increase the morbidity and mortality of the operation.166,167The purported survival advantage of D2 gastrectomy in gastric cancer is illustrated in Table 26-20, which shows the 5-year survival rates for gastric cancer stratified by pathologic stage for the United States and Japan. Randomized prospective trials have not confirmed this survival advantage. Two stud-ies showed increased operative mortality with D2 gastrectomy, but the most recent study did not (Table 26-21).166,168,169 With extended lymphadenectomy, much of the morbidity and mor-tality is attributable to performance of splenectomy and distal pancreatectomy, which are no longer routinely included as part of the D2 gastrectomy. Because D2 lymphadenectomy in total gastrectomy requires the dissection of station 10 (i.e., splenic hilar lymph nodes) splenectomy is still selectively performed, particularly for locally advanced fundic tumors.Longer-term follow-up from the Dutch lymphdenectomy trial demonstrating a disease-specific survival advantage with D2 dissection170 as well as recognition that pancreas and spleen preserving dissection can be performed with low morbidity169 have provided momentum for increased utilization of D2 gas-trectomy at high-volume centers in the United States and Europe. Some experts have argued that the D2 operation affords better staging and informs more rational decision-making regarding multimodality therapy. Without question, D2 provides a bet-ter yield of evaluable nodes. Given the frequent inadequacy of lymph node evaluation with gastrectomy in the United States and the association with poorer outcomes, greater attention to the conduct of the operation and pathologic specimen evaluation is clearly desirable. Whether better outcomes after more exten-sive dissection are an epiphenomenon of improved pathologic staging, or a function of therapeutic benefit, remains unclear.Chemotherapy and Radiation for Gastric Cancer The actu-arial 5-year survival rates for resected gastric adenocarcinoma stages I, II, and III in the United States are approximately 75%, 50%, and 25%, respectively. Because most surgical patients have stage II disease or greater, adjuvant therapy is indicated in the majority of patients who undergo initial resection. Adjuvant chemotherapy alone has not proven effective, at least in studies from Europe and the United States.171 Several studies from Table 26-20Gastric cancer 5-year survival and operative mortality in the United States and Japan MARUYAMA (JAPAN), 1971–1985AMERICAN COLLEGE OF SURGEONS, 1982–1987MEMORIAL SLOAN KETTERING, 1985–1994No. patients317618,365675Stage I91%50%84%Stage II72%29%61%Stage III44%13%29%Stage IV9%3%25%Operative mortality1%7%3%60 cmFigure 26-57. Reconstruction after total gastrectomy. Jejunal pouch (not shown here) should be considered. (Reproduced with permission from Zinner MJ: Atlas of Gastric Surgery. New York, NY: Elsevier/Churchill Livingstone; 1992.)Brunicardi_Ch26_p1099-p1166.indd 114701/03/19 7:13 PM 1148SPECIFIC CONSIDERATIONS PART IIJapan and Korea have indicated a survival advantage with adju-vant chemotherapy after D2 gastrectomy.172-174 The discordance between outcomes in Asia and those from the United States and Europe have been attributed to differences in disease biology or treatment approaches. Proponents of the latter suggest that D2 lymphadenectomy provides sufficient locoregional control and that chemotherapy alone has efficacy after optimal surgery. A preferred adjuvant approach in the United States incorpo-rates chemotherapy and radiation based on the results of the Intergroup trial. This prospective randomized study of adju-vant treatment with chemotherapy (5-fluorouracil and leucovo-rin) and radiation (4500 cGy) demonstrated a survival benefit in resected patients with stage II and III adenocarcinoma of the stomach.175 Only 10% of patients entered in the study actually had D2 gastrectomy, and most (54%) had less than an adequate D1 gastrectomy. Because adequacy of lymphadenectomy has been correlated with survival, particularly in patients with stage III gastric cancer, it has been suggested that the benefits of adjuvant chemoradiation shown in this study would be vitiated by a more extensive operation.Neoadjuvant chemotherapy has emerged as a viable alter-native to adjuvant chemoradiotherapy in Europe and the United States. Theoretical advantages of this approach include more consistent completion of multimodality therapy, downstaging, earlier treatment of micrometastatic disease, and the ability to gauge response at the in situ tumor. The MAGIC trial, a random-ized controlled trial comparing perioperative epirubicin, cispla-tin, and 5-flourouracil to surgery alone demonstrated a survival advantage and supported this approach in patients with at least stage II disease.176 A subset of patients with very symptomatic tumors may not be eligible for this approach, and the perception that systemic therapy is an ineffective detour for patients who require locoregional control with surgery is sometimes hard to overcome. Regardless, neoadjuvant approaches are increasingly utilized, and even more rigorous regimens incorporating radio-therapy or targeted agents have been explored, sometimes with promising outcomes.177Recent clinical trials from Asia suggest the potential ben-efit of adjuvant chemotherapy after D2 lymphadenectomy in patients with advanced gastric cancer. These trials compared surgery alone and surgery plus adjuvant chemotherapy including oral fluoropyrimidines in resected advanced gastric cancer.172,173 A study from the Japan Clinical Oncology Group showed a 69% overall 5-year survival rate in patients with clinically curable T2b, T3, and T4 gastric cancer, treated with D2 gastrectomy alone.178 A subsequent trial from Korea demonstrated a survival advantage with adjuvant capecitabine and oxaliplatin after D2 gastrectomy compared to D2 gastrectomy alone.173 It is uncer-tain whether this approach can be translated to patients in the United States.Although the prognosis of metastatic or recurrent gastric cancer is poor, systemic chemotherapy provides a significant survival benefit over the best supportive care.179,180 Agents that have shown activity against gastric cancer include 5-fluorouracil (5-FU), cisplatin, doxorubicin, methotrexate, taxanes, and camptothecin. Until recently, 5-FU–based chemotherapy, especially in combination with platinums, played a key role in the treatment for the unresectable gastric cancer as well as several types of cancer, such as colon and lung. In the 1990s, the introduction of novel anticancer agents such as camptoth-ecin, taxanes, third-generation platinums, and new oral fluo-ropyrimidines, improved the prognosis of unresectable gastric cancer.179,180It is likely that targeted molecular agents will have an increasing role in treating gastric cancer. Recently, Trastu-zumab, a humanized molecular antibody reactive against the extracellular domain of HER2, increased the effectiveness of cytotoxic chemotherapy in patients with HER2 over-expressing advanced gastric cancer.152 Other large trials are ongoing. Deter-mination of HER2 gene amplification status may have prognos-tic significance.181Endoscopic Resection182 The shortand long-term morbidity associated with gastrectomy and the relatively infrequent dis-semination of superficial (i.e., T1) tumors to regional nodes have compelled exploration of endoscopic resection for selected lesions. Numerous East Asian centers have demonstrated that some patients with early gastric cancer are adequately treated with endoscopic mucosal resection (EMR). EMR is most appro-priate for patients in whom the probability of lymph node metas-tasis is low. According to the Japanese treatment guidelines for gastric cancer, EMR is a standard treatment for well differenti-ated gastric cancer confined to the mucosa (T1a), measuring less than 2 cm and without signs of ulceration. Such lesions are associated with a negligible risk of lymph node metastasis. 6Table 26-21Randomized trials comparing D1 and D2 gastrectomy for gastric cancerAUTHORSNUMBER OF PATIENTSTYPE OF SURGERYPOSTOPERATIVE COMPLICATIONSPOSTOPERATIVE MORTALITY5 YEAR SURVIVALBonenkamp et al.711D125445  D2431047Cuschieri et al.400D1286.535  D2461333Degiuli et al.267D1123   D217.92.2 Data from Bonenkamp JJ, Hermans J, Sasako M, et al. Extended lymph node dissection for gastric cancer. N Engl J Med. 1999;340:908; Cuschieri A, Fayers P, Fielding J, et al. Postoperative morbidity and mortality after D1 and D2 resections for gastric cancer: preliminary results of the MRC randomized controlled surgical trial. The Surgical Cooperative Group. Lancet. 1996;347:995; and Degiuli M, Sasako M, Ponti A, et al. Morbidity and mortality in the Italian Gastric Cancer Study Group randomized clinical trial of D1 versus D2 resection for gastric cancer. Br J Surg. 2010;97:5.Brunicardi_Ch26_p1099-p1166.indd 114801/03/19 7:13 PM 1149STOMACHCHAPTER 26En bloc resection is required to evaluate margins for confirma-tion of complete resection. The development of endoscopic submucosal dissection (ESD) allows en bloc resection of larger tumors. This has increased the feasibility of endoscopic resec-tion of larger lesions (<3 cm) at experienced centers. If patho-logic evaluation of the resected specimen does not demonstrate ulceration, penetration of the muscularis mucosae, or lymphatic invasion, the risk of lymph node metastases is less than 1%. Even the occasional patient with higher risk stigmata may be managed endoscopically, particularly in the presence of comor-bidities that preclude safe operation.Screening for Gastric Cancer. In Japan, it clearly has been shown that patients participating in gastric cancer screening pro-grams have a significantly decreased risk of dying from gastric cancer. Thus, screening is effective in a high-risk population. Screening the general population in the United States (a low-risk country) is probably not justified, but patients clearly at risk for gastric cancer probably should have periodic endoscopy and biopsy. This includes patients with familial adenomatous polyposis, hereditary nonpolyposis colorectal cancer, gastric adenomas, Ménétrier’s disease, intestinal metaplasia or dyspla-sia, and remote gastrectomy or gastrojejunostomy.Gastric LymphomaGastric lymphomas generally account for about 4% of gastric malignancies. Over half of patients with non-Hodgkin’s lym-phoma have involvement of the GI tract. The stomach is the most common site of primary GI lymphoma, and over 95% are non-Hodgkin’s type. Most are B-cell type, thought to arise in mucosa associated lymphoid tissue (MALT), although most high-grade gastric lymphomas are without any characteristics of the low-grade MALT neoplasm.183 About half of gastric lym-phomas are histologically low grade, and about half are high grade. Interestingly, the normal stomach is relatively devoid of lymphoid tissue. However, in the setting of chronic gastritis, the stomach acquires MALT, which can undergo malignant degen-eration. Again, H pylori is thought to be the culprit. In popula-tions with a high incidence of gastric lymphoma, there is a high incidence of H pylori infection; patients with gastric lymphoma also usually have H pylori infection.184Low-grade MALT lymphoma, essentially a monoclonal proliferation of B cells, presumably arises from a background of chronic gastritis associated with H pylori. These relatively innocuous tumors then undergo degeneration to high-grade lymphoma, which is the usual variety seen by the surgeon. Remarkably, when the H pylori is eradicated and the gastritis improves, the low-grade MALT lymphoma often disappears. Thus, low-grade MALT lymphoma is not a surgical lesion. Careful follow-up is necessary particularly in those lesions with a t(11:18) translocation, thought to be a risk factor for a more aggressive MALT lesion. If low-grade lymphoma per-sists after H pylori eradication, radiation should be consid-ered for disease clinically confined to the stomach (stage I), while chemotherapy with or without radiation is used for more advanced lesions (Fig. 26-58).Patients with high-grade gastric lymphoma require aggres-sive oncologic treatment for cure and present with many of the same symptoms as gastric cancer patients. However, systemic symptoms such as fever, weight loss, and night sweats occur in about 50% of patients with gastric lymphoma. The tumors may bleed and/or obstruct. Lymphadenopathy and/or organomegaly suggest systemic disease. Diagnosis is by endoscopy and biopsy. Much of the tumor may be submucosal, and an assiduous attempt at biopsy is necessary. Primary lymphoma is usually nodular with enlarged gastric folds. A diffusely infiltrative pro-cess akin to linitis plastica is more suggestive of secondary gas-tric involvement by lymphoma. A diligent search for extragastric disease is necessary before the diagnosis of localized primary gastric lymphoma is made. This includes EUS; CT scanning of the chest, abdomen, and pelvis; and bone marrow biopsy. Most patients with high-grade gastric lymphoma are currently treated with chemotherapy and radiation, without surgical resection. Treatment-related perforation or bleeding is an unusual but recognized complication. For disease limited to the stomach and regional nodes, radical subtotal D2 gastrectomy may be performed, especially for bulky tumors with bleeding and/or obstruction. Palliative gastrectomy for tumor complica-tions also has a role. Certainly, a multidisciplinary team should be involved in managing patients with primary gastric lymphoma.Gastrointestinal Stromal TumorGISTs arise from interstitial cells of Cajal (ICC) and are dis-tinct from leiomyoma and leiomyosarcoma, which arise from smooth muscle.185,186 Prognosis in patients with GIST tumors depends on tumor size, location, and mitotic count. Metasta-sis, when it occurs, is typically by the hematogenous route. Virtually all GISTs should be resected along with a margin of normal tissue. Most GISTs (and almost no smooth muscle tumors) express c-KIT (CD117) or the related PDGF receptor A, as well as CD34; almost all smooth muscle tumors (and almost no GISTs) express actin and desmin. These markers can often be detected on specimens obtained by fine-needle aspiration187 and are useful in differentiating between GIST and smooth muscle tumor histopathologically. Lesions that are definitively leiomyoma by histopathologic criteria can be observed if small and asymptomatic. Larger or symptomatic gastric leiomyomas are adequately treated by enucleation or wedge resection. Lesions that are definitively GIST or leio-myosarcoma are best treated by resection with negative mar-gins. Most equivocal lesions should be resected provided that the patient has a reasonable operative risk.Two-thirds of all GISTs occur in the stomach and have a more favorable prognosis than do GISTs occurring in other locations. Epithelial cell stromal GIST is the most common cell type arising in the stomach, and cellular spindle type is the next most common. The glomus tumor type is seen only in the stom-ach. Smaller lesions are usually found incidentally, although they occasionally may ulcerate and cause bleeding. Larger lesions may produce symptoms of weight loss, abdominal pain, fullness, early satiety, and bleeding. An abdominal mass may be palpable. Metastasis is by the hematogenous route, most often to liver.Diagnosis is by endoscopy and biopsy, although the inter-pretation of the latter may be problematic. When performed, a transluminal (i.e., endoscopic) approach to biopsy is preferred to a percutaneous one, to avoid to the potential for fragmenta-tion and peritoneal seeding. A nondiagnostic biopsy does not preclude resection of a suspicious appearing lesion. Metastatic workup entails CT of the abdomen, and pelvis (chest X-ray suf-fices in lieu of CT of the chest for most patients). Most GISTs are solitary. Local resection with clear margins is adequate sur-gical treatment but is sometimes impractical for larger prepy-loric or pyloric channel tumors, or those near the GE junction. 7Brunicardi_Ch26_p1099-p1166.indd 114901/03/19 7:13 PM 1150SPECIFIC CONSIDERATIONS PART IITrue invasion of adjacent structures by the primary tumor is occasionally seen with larger more aggressive lesions. If safe, en bloc resection of involved surrounding organs is appropriate to remove all tumor.The risk of tumor recurrence or metastasis behavior has been stratified into four groups according to the tumor size and mitotic count.110 Very low risk is defined by size <2 cm and <5 mitoses/50 HPF (high-power field). Low risk is defined by size 2 to 5 cm and <5 mitoses/50 cm. Intermediate risk is defined by size <5 cm and 6 to 10 mitoses/50 HPF or size 5 to 10 cm and >5 mitoses/50 HPF. High risk is defined by size >5 cm and >5 mitoses/50HPF, size >10 cm regardless of mitotic rate or >10 mitoses/50 HPF regardless of size. As mentioned, stomach lesions are associated with lower risk than are tumors in other locations. Classification based on tumor location, size, and mitotic rate have been proposed to evaluate the risk of recurrence and metastasis and role for adjuvant therapy.188 In an effort to further refine risk stratification, a number of nomo-grams have been introduced incorporating tumor features. These tools draw upon and are subject to the limitations of the institu-tional data from which they are derived, but they are sometimes helpful in counseling patients.Mutations in the oncodriver c-kit and PDGFRA are pres-ent in a majority of GISTs. This has been exploited through the use of imatinib (Gleevec), a tyrosine kinase inhibitor. Sev-eral clinical trials in a metastatic disease setting demonstrated marked improvements in median survival from 9 months to greater than 5 years.189 These striking results not only estab-lished imatinib as the primary therapy for metastatic GIST, but they also compelled broader efforts to target solid tumors with small molecule inhibitors. Notably, up to 50% of treated patients develop resistance to imatinib by 2 years, and several Low-grade (indolent) MALTLymphoma persistsStage IIChemo** + XRT*Stage IXRT**XRT: external beam radiation therapy, approximately 30 Gy with 10 Gy boost**Chemo: chemotherapy regimens include chlorambucil, fludarabinel,and cyclosphosphamide, vincristine, prednisone (COP) +/– rituximabClose follow-upNo residual diseaseResidual diseaseFurther chemotherapy*Chemo: chemotherapy regimen usually cyclophosphamide,doxorobicin, vincristine, prednisone (CHOP) +/– rituximab**XRT: external beam radiation, approximately 30 Gy with 10 Gy boostFollow-upLymphoma regressionHigh-grade (aggressive)SurgeryStage IVChemo* +/– XRT**Stage I, II, IIIChemo* + XRT**Stage III or IVLymph node involvementt(11:18) translocationConfined to gastric wallNo t(11:18) translocationH pylori eradication therapyand chemo** +/– XRT*H pylori eradication therapyRe-evaluate at 3–6 monthsH pylori eradication therapyRe-evaluate at 12 monthsFigure 26-58. Algorithm for the treatment of gastric lymphoma. MALT = mucosa-associated lymphoid tissue. (Reproduced with permission from Yoon SS, Coit DG, Portlock CS, et al. The diminishing role of surgery in the treatment of gastric lymphoma, Ann Surg. 2004 Jul;240(1):28-37.)Brunicardi_Ch26_p1099-p1166.indd 115001/03/19 7:13 PM 1151STOMACHCHAPTER 26second-line agents have been utilized for patients with refrac-tory disease, most notable sunitinib.The efficacy of imatinib as adjuvant therapy for high risk GIST has been demonstrated in two randomized clinical trials, ACOSOG Z9001 and SSG XVIII.190,191 The former trial randomized patients to 1 year of adjuvant imatinib or pla-cebo and showed an improvement in recurrence-free survival with imatinib. The latter trial demonstrated an overall survival advantage with 3 years compared to 1 year of therapy. Imatinib is now recommended in high risk groups as an adjuvant therapy, for three years or longer. Preoperative therapy with imatinib may be indicated in selected patients with larger lesions that may be more difficult to completely resect or require multivis-ceral resection.Molecular profiling has been embraced with growing rec-ognition that specific tumor subtypes are insensitive to imatinib. Patients with PDGFRA D842V mutations, for example, do not respond to imatinib.192 Management of metastatic GIST is prin-cipally medical, but surgery has a selected role. An algorithm for the treatment of patients with metastatic GIST is shown in Fig. 26-59.Gastric Neuroendocrine Tumors193,194Compared to neuroendocrine tumors of the midgut and hind-gut, neuroendcorine tumors of the stomach are rare. Gastric neuroendocrine tumors comprise about 1% of all neuroen-docrine tumors and less than 2% of gastric neoplasms. They arise from gastric enterochromaffin-like (ECL) cells and may have malignant potential. The apparent incidence of gastric neuroendocrine tumors is increasing, perhaps related to increased detection or the increasing use of acid suppres-sive medication. The latter may cause hypergastrinemia, and gastrin has a recognized trophic effect on gastric ECL cells. Nomenclature remains a point of confusion; carcinoid and well-differentiated neuroendocrine tumor (NET) are synony-mous according to WHO classification.Gastric neuroendocrine tumors are classified into one of three different types. Type I is the most common, account-ing for about 75% of cases. Type I lesions occur in patients with chronic hypergastrinemia secondary to pernicious anemia or atrophic gastritis. These lesions occur more frequently in women, are often multiple and small, and have low malignant potential (<5% metastasize). The role of long-term acid sup-pression with resultant hypergastrinemia in the pathogenesis of type I gastric carcinoids is unclear. Type II gastric neuroendo-crine tumors are associated with MEN1 and ZES. These lesions also tend to be small and multiple, but they have a somewhat higher malignant potential than type I lesions (10% metasta-size). Type II lesions are more common in the setting of MEN1; they are quite uncommon in patients with sporadic ZES. The constellation of gastric acidity, hypergastrinemia, and gastric neuroendocrine tumors suggests gastrinoma until proven other-wise. Type III gastric neuroendocrine tumors are sporadic. They are most often solitary (usually >2 cm) and occur more com-monly in men. They are not associated with hypergastrinemia. Most patients have regional nodal or distant metastases at the time of diagnosis, and some present with symptoms of carcinoid syndrome.Gastric neuroendocrine tumors are usually diagnosed with endoscopy and biopsy. The type can be determined based upon clinical context, patient history, the presence or absence of atro-phic gastric mucosa, gastric pH and gastrin level. Some tumors are submucosal and may be quite small. They are often confused with heterotopic pancreas or small leiomyomas. Biopsy may be difficult because of the submucosal location, and EUS can be helpful in defining the size and depth of the lesion. Plasma 8Metastatic or recurrent GISTRepeat imaging in 1 to 3 monthsResponsive/Stable diseaseResectableConsidersurgeryContinueimatinibUnresectableConsidersurgeryDose escalation toimatinib 400 mg bidSunitinibRegorafenibClinical trialUnifocalMultifocalProgressive diseaseImatinib 400 mg four times a day in all KIT, non-D842V PDGFRA mutations,and WT GIST Consider 400 mg twice a day in exon 9 KIT mutationsConsider clinical trial in PDGFRA D842V mutationsFigure 26-59. Algorithm for the treatment of malignant gastrointestinal stromal tumor. (Reproduced with permission from Balachandran VP, DeMatteo RP: Gastrointestinal stromal tumors: who should get imatinib and for how long? Adv Surg. 2014;48:165-183.)Brunicardi_Ch26_p1099-p1166.indd 115101/03/19 7:13 PM 1152SPECIFIC CONSIDERATIONS PART IIchromogranin A levels are frequently elevated. CT scan and octreotide or gallium dotatate scans are useful for staging.Type I and II patients with numerous diminutive lesions can be followed with serial endoscopy. Small lesions con-fined to the mucosa (typically type I or type II lesions) less than 1 cm may be treated endoscopically with EMR if there are only a few lesions (<5). Occasionally a slightly larger lesion (1–2 cm) necessitate local surgical excision. Larger lesions and type III lesions should be removed by D1 or D2 gastrectomy. Antrectomy to mitigate gastric secretion in type I patients with refractory growing lesions was invoked as a viable treatment strategy in the past, but it is rarely indicated.Survival is excellent for node-negative patients (>90% 5-year survival); node-positive patients have a 50% 5-year sur-vival. Gastrinoma should be resected if located in patients with type II carcinoid. The 5-year survival for patients with type I gastric carcinoid is close to 100%; for patients with type III lesions, the 5-year survival is less than 50%. Somatostatin ana-logue therapy may delay progression of metastatic disease. Sur-gical debulking may have a role in selected patients with limited metastatic disease.BENIGN GASTRIC NEOPLASMSLeiomyomaThe typical leiomyoma is submucosal and firm. If ulcerated, it has an umbilicated appearance and may bleed. Histologically, these lesions appear to be of smooth muscle origin. Lesions <2 cm are usually asymptomatic and benign. Larger lesions may cause symptoms such as bleeding, obstruction, or pain. Asymp-tomatic lesions <2 cm may be carefully observed or enucleated if fine-needle aspiration and immune markers confirm smooth muscle tumor; larger lesions and symptomatic lesions should be removed by wedge resection (often possible laparoscopically). When lesions thought to be leiomyoma are observed rather than resected, the patient should be made aware of their presence and the small possibility for malignancy.LipomaLipomas are benign submucosal fatty tumors that are usually asymptomatic, found incidentally on upper GI series or EGD. Endoscopically, they have a characteristic appearance; there also is a characteristic appearance on EUS. Excision is unnec-essary unless the patient is symptomatic.GastroparesisGastric motility disorders include delayed gastric emptying (gastroparesis), rapid gastric emptying, and motor and sensory abnormalities (e.g., functional dyspepsia). Surgically relevant secondary disorders of gastric motility (e.g., dumping, gastric stasis, and Roux syndrome) are discussed under Postgastrec-tomy Problems. Gastroparesis is the most surgically relevant primary disorder of gastric motility.195,196Most patients with primary gastroparesis present with nausea, vomiting, bloating, early satiety, and/or abdominal pain. Eighty percent of these patients are women; some are diabetic. Postprandial vomiting significantly complicates the management of blood glucose in the latter group, predispos-ing to hypoglycemia following preprandial insulin. In patients with gastroparesis, it is important to rule out mechanical gastric outlet obstruction, and small-bowel obstruction. An upper GI series may suggest slow gastric emptying and relative atony, 9or it may be normal. EGD may show bezoars or retained food but is frequently normal. Gastric emptying scintigraphy shows delayed solid emptying, and often delayed liquid emptying. Gastroparesis can be a manifestation of a variety of problems (Table 26-22). Medical treatment includes promotility agents, antiemetics, and, perhaps, botulinum injection into the pylorus.If the diabetic gastroparetic patient is not a candidate for pancreas transplant, both gastrostomy (for decompression) and jejunostomy tubes (for feeding and prevention of hypo-glycemia) can be helpful in managing these patients. Other surgical options include implantation of a gastric pacemaker, pyloroplasty or peroral endoscopic pyloromyotmy (particularly in patients responsive to pyloric Botox injection), and gastric resection.197 Generally, gastric resection should be done only after other therapeutic options have been exhausted.Massive Upper Gastrointestinal BleedingAlthough there are arbitrary definitions of “massive” upper GI bleeding put forth, perhaps the most practical definition in the current era would be acute GI bleeding proximal to the ligament of Treitz, which requires blood transfusion. In multiple series, the stomach and proximal duodenum are by far the most com-mon sources of pathology associated with this diagnosis.109,198 Table 26-22Etiology of gastroparesisIdiopathicEndocrine or metabolic Diabetes mellitus Thyroid disease Renal insufficiencyAfter gastric surgery After resection After vagotomyCentral nervous system disorders Brain stem lesions Parkinson’s diseasePeripheral neuromuscular disorders Myotonia dystrophica Duchenne muscular dystrophyConnective tissue disorders Scleroderma Polymyositis/dermatomyositisInfiltrative disorders Lymphoma AmyloidosisDiffuse gastrointestinal motility disorder Chronic intestinal pseudo-obstructionMedication-inducedElectrolyte imbalance Potassium, calcium, magnesiumMiscellaneous conditions Infections (especially viral) Paraneoplastic syndrome Ischemic conditions Gastric ulcerReproduced with permission from Parkman HP, Harris AD, Krevsky B, et al: Gastroduodenal motility and dysmotility: an update on techniques available for evaluation, Am J Gastroenterol. 1995 Jun;90(6):869-892.Brunicardi_Ch26_p1099-p1166.indd 115201/03/19 7:13 PM 1153STOMACHCHAPTER 26The most common causes of acute upper GI bleeding in emer-gency department or hospitalized patients are peptic ulcer, gastri-tis, Mallory-Weiss syndrome, and esophagogastric varices. Less common causes include benign or malignant neoplasm, angio-dysplasia, Dieulafoy’s lesion, portal gastropathy, Ménétrier’s disease, and watermelon stomach. Arterioenteric fistula should always be considered in the patient who has an aortic graft or who has undergone repair of a visceral artery aneurysm.The most important issues in the early hospital manage-ment of patients with acute upper GI bleeding are resuscita-tion and risk stratification. Large-bore IV access and Foley catheterization is accomplished, and nasogastric intubation is considered. Risk stratification is essentially accomplished by answering the following questions:a. What is the magnitude and acuity of the hemorrhage? Hy-potension, tachycardia, oliguria, low hematocrit, pallor, al-tered mentation, and/or hematemesis suggest a large blood loss that has occurred over a short period of time. This is a high-risk situation.b. Does the patient have significant chronic disease, particu-larly lung, liver, kidney, and/or heart disease, which com-promises physiologic reserve? If yes, this is a high-risk situation.c. Is the patient anticoagulated, or immunosuppressed? If yes, this is a high-risk situation.d. On endoscopy, is the patient bleeding from varices, or is there active bleeding, or is there a visible vessel, or is there a deep ulcer overlying a large vessel (e.g., posterior duode-nal ulcer overlying the gastroduodenal artery)? Could the patient be bleeding from an arterio-enteric fistula? If yes, this is a high-risk situation.When judged to be low risk, most patients will stop bleed-ing with supportive treatment and IV PPI. Selected patients may be discharged from the emergency department and managed on an outpatient basis.If the patient is deemed to be high risk based on one or more of the aforementioned questions, then the following should be done immediately:1. Type and cross-match for transfusion of blood products.2. Admit to ICU or monitored bed in specialized unit.3. Consult surgeon.4. Consult gastroenterologist.5. Start intravenous PPI.6. Perform upper endoscopy within 12 hours, after resuscita-tion and correction of coagulopathy. Endoscopic hemosta-sis should be considered in most high-risk patients with acute upper GI bleeding.Although the surgeon should be involved early in the hos-pital course of all high-risk patients with acute upper GI bleed-ing, most of these patients will be adequately managed without operation. Mucosal lesions can usually be controlled with endo-scopic hemotherapy and medical management. Occasionally, arteriography can be helpful.199 Operation for bleeding ulcer is discussed previously (see “Operation for Bleeding Peptic Ulcer” and Fig. 26-43).Isolated Gastric VaricesIsolated gastric varices are those that occur in the absence of esophageal varices and are classified as type I (fundic) or type II (distal to fundus including proximal duodenum).200 The presence of isolated gastric varices is usually associated with portal hyper-tension or splenic vein thrombosis. Although there is a significant bleeding risk from isolated gastric varices on long-term follow-up, there is no indication for the routine application of prophylactic measures.Patients with acute upper GI bleeding from isolated gas-tric varices should be considered high risk. Although data are limited, octreotide and/or vasopressin infusion may decease bleeding, if tolerated. Balloon tamponade with a Sengstaken-Blakemore tube may provide temporary control of exsanguinat-ing hemorrhage from type isolated gastric varices, but if this is used, endotracheal intubation for airway protection is prudent. Endoscopic treatment with sclerotherapy or varix ligation is less successful than in esophageal varices but should be con-sidered. Interventional radiology should be consulted and bal-loon-occluded retrograde transvenous obliteration considered. A transjugular intrahepatic portosystemic shunt (TIPSS) may be useful if there is nonsegmental portal hypertension. If the patient has splenic vein thrombosis and left-sided (sinistral) or segmental portal hypertension, splenectomy is quite effective in controlling bleeding from isolated gastric varices. The operative mortality is 5%. Liver transplantation should always be consid-ered in the cirrhotic patient.Hypertrophic Gastropathy (Ménétrier’s Disease)There are two clinical syndromes characterized by epithelial hyperplasia and giant gastric folds: ZES and Ménétrier’s dis-ease. The latter is characteristically associated with protein-losing gastropathy and hypochlorhydria. There are large rugal folds in the proximal stomach, and the antrum is usu-ally spared. Mucosal biopsy shows diffuse hyperplasia of the surface mucus-secreting cells and usually decreased parietal cells (Fig. 26-60). It has recently been suggested that Méné-trier’s disease is caused by local overexpression of transform-ing growth factor-α in the gastric mucosa, which stimulates the epidermal growth factor receptor, a receptor tyrosine kinase, on gastric SECs. This results in the selective expan-sion of surface mucous cells in the gastric body and fundus. A few patients with this unusual disease have been successfully Figure 26-60. Mucosal biopsy in Ménétrier’s disease. (Repro-duced with permission from Ming S-C, Goldman H: Pathology of the Gastrointestinal Tract, 2nd ed. Baltimore, MD: Williams & Wilkins; 1998.)Brunicardi_Ch26_p1099-p1166.indd 115301/03/19 7:13 PM 1154SPECIFIC CONSIDERATIONS PART IItreated with the epidermal growth factor receptor blocking monoclonal antibody cetuximab.201Most patients with Ménétrier’s disease are middle-aged men who present with epigastric pain, weight loss, diarrhea, and hypoproteinemia. There may be an increased risk of gastric cancer. Sometimes, the disease regresses spontaneously. Occa-sionally it is associated with H pylori infection, and the disease improves with helicobacter eradication. Total gastrectomy may be indicated for bleeding, severe hypoproteinemia, or cancer.Watermelon Stomach (Gastric Antral Vascular Ectasia)The parallel red stripes atop the mucosal folds of the distal stomach give this rare entity its sobriquet. Histologically, gas-tric antral vascular ectasia (GAVE) is characterized by dilated mucosal blood vessels that often contain thrombi, in the lamina propria. Mucosal fibromuscular hyperplasia and hyalinization often are present (Fig. 26-61). The histologic appearance can resemble portal hypertensive gastropathy, but the latter usually affects the proximal stomach, whereas watermelon stomach pre-dominantly affects the distal stomach. β-Blockers and nitrates, useful in the treatment of portal hypertensive gastropathy, are ineffective in patients with gastric antral vascular ectasia. Patients with GAVE are usually elderly women with chronic GI blood loss requiring transfusion. Most have an associated autoimmune connective tissue disorder, and at least 25% have chronic liver disease. Nonsurgical treatment options include estrogen and progesterone, and endoscopic treatment with the neodymium yttrium-aluminum garnet (Nd:YAG) laser or argon plasma coagulator.202 Antrectomy may be required to control blood loss, and this operation is quite effective but carries increased morbidity in this elderly patient group. Patients with portal hypertension and antral vascular ectasia should be consid-ered for transjugular intrahepatic portosystemic shunt (TIPSS).Dieulafoy’s LesionDieulafoy’s lesion is a congenital arteriovenous malformation characterized by an unusually large tortuous submucosal artery. If this artery is eroded, impressive pulsatile bleeding may occur. To the endoscopist or surgeon, this appears as a stream of arte-rial blood emanating from what appears grossly to be a normal gastric mucosa. The lesion typically occurs in middle-aged or elderly men and may be more common in patients with liver disease.203 Patients typically present with upper GI bleeding, which may be intermittent, and endoscopy can miss the lesion if it is not actively bleeding. Treatment options include endoscopic hemostatic therapy, angiographic embolization, or operation. At surgery, the lesion may be oversewn or resected.Bezoars/DiverticulaBezoars are concretions of indigestible matter that accumulate in the stomach. Trichobezoars are composed of swallowed hair (Fig. 26-62). Phytobezoars are composed of vegetable matter and, in the United States, are usually seen in association with gastroparesis or gastric outlet obstruction. They also are asso-ciated with persimmon ingestion. Most commonly, bezoars produce obstructive symptoms, but they may cause ulceration and bleeding. Diagnosis is suggested by upper GI series and confirmed by endoscopy. Treatment options include enzyme therapy (papain, cellulase, or acetylcysteine), endoscopic dis-ruption and removal, or surgical removal.Gastric diverticula are usually solitary and may be con-genital or acquired. Congenital diverticula are true diverticula and contain a full coat of muscularis propria, whereas acquired diverticula (perhaps caused by pulsion) usually have a negli-gible outer muscle layer. Most gastric diverticula occur in the posterior cardia or fundus (Fig. 26-63) and are usually asymp-tomatic. However, they can become inflamed and may produce pain or bleeding. Perforation is rare. Asymptomatic diverticula do not require treatment, but symptomatic lesions should be removed. This can often be done laparoscopically.Foreign BodiesIngested foreign bodies are usually asymptomatic. Small coins usually pass through the GI tract without difficulty. Sharp or Figure 26-62. Trichobezoar forming cast of stomach and duode-num; removed from 15-year-old girl. (Reproduced with permission from DeBakey M, Ochsner A: Bezoars and concretions, Surgery. 1938;Dec;4:934.)Figure 26-61. Gastric antral vascular ectasia (watermelon stom-ach). (Reproduced with permission from Godlman H, Hayek J, Federman M: Gastrointestinal Mucosal Biopsy. New York, NY: Churchill Livingstone; 1996.)Brunicardi_Ch26_p1099-p1166.indd 115401/03/19 7:13 PM 1155STOMACHCHAPTER 26large objects in the stomach should be removed. This can usu-ally be done endoscopically, with an overtube technique. Rec-ognized dangers include aspiration of the foreign body during removal and rupture of drug-containing bags in “body packers.” Both complications can be fatal. Surgical removal is recom-mended in body packers who ingest drug parcels for smuggling and in patients with large jagged objects that cannot be safely removed endoscopically. Corrosive objects (i.e., batteries) should be removed promptly usually endoscopically. Ingested magnets should be removed unless they are small and singular and without other ingested metal objects.Mallory-Weiss SyndromeThe Mallory-Weiss lesion is a longitudinal tear in the mucosa of the GE junction.204 It is presumably caused by forceful vom-iting and/or retching, and it is commonly seen in alcoholics. It presents with upper GI bleeding, often with hematemesis. Endoscopy confirms the diagnosis and may be useful in con-trolling the bleeding, but 90% of patients stop bleeding sponta-neously. Other options to control the bleeding include balloon tamponade, angiographic embolization, or selective infusion of vasopressin, systemic vasopressin, and operation. Surgical treat-ment consists of oversewing the bleeding lesion through a long gastrotomy.VolvulusGastric volvulus is a twist of the stomach that usually occurs in association with a large hiatal hernia. It also can occur in patients with an unusually mobile stomach without hiatal hernia. Typically, the stomach twists along its long axis (organoaxial volvulus), and the greater curvature flips up (Fig. 26-64C). If the stomach twists around the transverse axis, it is called mesentero-axial rotation (Fig. 26-64A and Fig. 26-64B). Often, volvulus is a chronic condition that can be surprisingly asymptomatic. In these instances, expectant nonoperative management is typi-cally advised, especially in the elderly. The risk of strangulation and infarction has been overestimated in asymptomatic patients. Symptomatic patients should be considered for operation, espe-cially if the symptoms are severe and/or progressive. Patients may present with symptoms of pain and pressure related to the intermittently distending and poorly emptying twisted stomach. Pressure on the lung may produce dyspnea, pressure on the peri-cardium may produce palpitations, and pressure on the esopha-gus may produce dysphagia. Symptoms are often relieved with vomiting or passage of a nasogastric tube. Gastric infarction is a surgical emergency, and the patient can be moribund. Gastric necrosis may be extensive or focal. Elective operation for gas-tric volvulus usually involves reduction of the stomach and gas-tropexy with or without repair of hiatal hernia. Gastropexy alone should be considered for high-risk patients since it can nearly always be performed laparoscopically and may be surprisingly effective in relieving mechanical symptoms.GASTROSTOMYA gastrostomy is performed either for alimentation or for gastric drainage/decompression. Gastrostomy may be done percutane-ously, laparoscopically, or via open technique.205,206 Currently, percutaneous endoscopic gastrostomy is the most common method used. The open techniques include the Stamm method (Fig. 26-65), the Witzel method (Fig. 26-66), and the Janeway method. The Janeway gastrostomy, designed to create a per-manent nondraining gastric stoma that can be intermittently intubated, is more complicated than the other open techniques, and is rarely necessary. By far the most common surgical tech-nique is the Stamm gastrostomy, which can be performed open or laparoscopically.Complications of gastrostomy include infection, dis-lodgment, leakage with peritonitis, and aspiration pneumonia. Although gastrostomy tubes usually do prevent tense gastric dil-atation, they may not adequately drain the stomach, especially when the patient is bedridden, and they cannot always be relied upon to prevent pulmonary aspiration of gastric contents.ABCFigure 26-64. A through C. Gastric volvulus. (Reproduced with permission from Buchanan J: Volvulus of the stomach, Br J Surg. 1930;July;18(69):99-112.)Figure 26-63. Upper GI contrast study showing a diverticulum of the stomach. (Used with permission from Marc Levine, MD.)Brunicardi_Ch26_p1099-p1166.indd 115501/03/19 7:13 PM 1156SPECIFIC CONSIDERATIONS PART IIPOSTGASTRECTOMY PROBLEMS207Dumping SyndromeDumping is a phenomenon caused by the destruction or bypass of the pyloric sphincter.208 However, other factors undoubtedly play a role because dumping can occur after operations that pre-serve the pylorus, such as parietal cell vagotomy. Also, an appro-priate stimulus may provoke dumping symptoms, even in some patients who have not undergone surgery. Clinically significant dumping occurs in 5% to 10% of patients after pyloroplasty, pyloromyotomy, or gastrectomy, and consists of a constellation of postprandial symptoms ranging in severity from annoying to disabling. The symptoms are thought to be the result of the abrupt delivery of a hyperosmolar load into the small bowel due to ablation of the pylorus or decreased gastric compliance. Typi-cally, 15 to 30 minutes after a meal, the patient becomes dia-phoretic, weak, light-headed, and tachycardic. These symptoms may be ameliorated by recumbence or saline infusion. Crampy abdominal pain is not uncommon, and diarrhea often follows. This is referred to as early dumping and should be distinguished from postprandial (reactive) hypoglycemia, also called late dumping, which usually occurs later (2–3 hours following a meal) and is relieved by the administration of sugar. A variety Figure 26-65. Stamm gastrostomy. (Reproduced with permission from Zuidema GD, Yeo CJ: Shackelford’s Surgery of the Alimentary Tract, 5th ed. Vol. II. Philadelphia, PA: Elsevier/Saunders; 2002.)Figure 26-66. A through F. Witzel gastros-tomy. (Reproduced with permission from Zuidema GD, Yeo CJ: Shackelford’s Sur-gery of the Alimentary Tract, 5th ed. Vol. II. Philadelphia, PA: Elsevier/Saunders; 2002.)Brunicardi_Ch26_p1099-p1166.indd 115601/03/19 7:13 PM 1157STOMACHCHAPTER 26of hormonal aberrations have been observed in early dumping, including increased serum levels of VIP, CCK, neurotensin, peripheral hormone peptide YY, renin-angiotensin-aldosterone, and decreased atrial natriuretic peptide. Late dumping is associ-ated with hypoglycemia and hyperinsulinemia.Medical therapy for the dumping syndrome consists of dietary modification and somatostatin analogue (octreotide). Often, symptoms improve if the patient avoids liquids during meals. Hyperosmolar liquids (e.g., milk shakes) may be particu-larly troublesome. There is some evidence that adding dietary fiber compounds at mealtime may improve the syndrome. If dietary manipulation fails, the patient is started on octreotide, 100 μg subcutaneously twice daily. This can be increased up to 500 μg twice daily if necessary. The long-acting depot octreo-tide preparation is useful. Octreotide not only ameliorates the abnormal hormonal pattern seen in patients with dumping symptoms, but it also promotes restoration of a fasting motility pattern in the small intestine (i.e., restoration of the MMC). The α-glucosidase inhibitor acarbose may be particularly helpful in ameliorating the symptoms of late dumping.Only a very small percentage of patients with dumping symptoms ultimately require surgery. Most patients improve with time (months and even years), dietary management, and medication. Therefore, the surgeon should not rush to reoper-ate on the patient with dumping symptoms. Multidisciplinary nonsurgical management must be optimized first. Before reop-eration, a period of inhospital observation is useful to define the severity of the patient’s symptoms and patient compliance with prescribed dietary and medical therapy.The results of remedial operation for dumping are variable and unpredictable. There are a variety of surgical approaches, none of which work consistently well. Addition-ally, there is not a great deal of experience reported in the literature with any of these methods and long-term follow-up is rare. Patients with disabling refractory dumping after gas-trojejunostomy can be considered for simple takedown of this anastomosis provided that the pyloric channel is patent. The reversed intestinal segment is rarely used today—and rightly so. This operation interposes a 10-cm reversed segment of intestine between the stomach and the proximal small bowel. This slows gastric emptying, but often leads to obstruction, requiring reoperation. Isoperistaltic interposition (Henley loop) has not been successful in ameliorating severe dumping over the long term. The Roux-en-Y gastrojejunostomy is asso-ciated with delayed gastric emptying, probably on the basis of disordered motility in the Roux limb. Taking advantage of this disordered physiology, surgeons have used this operation successfully in the management of the dumping syndrome. Although this is probably the procedure of choice in the small group of patients requiring operation for severe dumping fol-lowing gastric resection, gastric stasis may result, particularly if a large gastric remnant is left. In the presence of significant gastric acid secretion, marginal ulceration is common after both jejunal interposition and Roux-en-Y procedures; thus, concomitant vagotomy and hemigastrectomy should be con-sidered. The theoretical possibility of treating postpyloroplasty dumping with a Roux-en-Y to the proximal duodenum (the duodenal switch, a potentially reversible operation) has not yet been reported (Fig. 26-67). Because pyloric ablation seems to be the dominant factor in the etiology of dumping, it is not sur-prising that conversion of Billroth II to Billroth I anastomosis has not been successful in the treatment of dumping.DiarrheaDiarrhea following gastric surgery may be the result of trun-cal vagotomy, dumping, or malabsorption. Truncal vagotomy is associated with clinically significant diarrhea in 5% to 10% of patients. It occurs soon after surgery and usually is not associ-ated with other symptoms, a fact that helps to distinguish it from dumping. The diarrhea may be a daily occurrence, or there may be significant periods of relatively normal bowel function. The symptoms tend to improve over the months and years after the index operation. The cause of postvagotomy diarrhea is unclear. Possible mechanisms include intestinal dysmotility and accel-erated transit, bile acid malabsorption, rapid gastric emptying, and bacterial overgrowth. The latter problem is facilitated by decreased gastric acid secretion and (even small) blind loops. Although bacterial overgrowth can be confirmed with the hydrogen breath test, a simpler test is an empirical trial of oral antibiotics. Some patients with postvagotomy diarrhea respond to cholestyramine, while in others codeine or loperamide may be useful. Octreotide should also be tried. Another theoretical cause of diarrhea following gastric surgery is fat malabsorption due to acid inactivation of pancreatic enzymes or poorly coor-dinated mixing of food and digestive juices. This can be con-firmed with a qualitative test for fecal fat and treated with acid suppression. Postvagotomy diarrhea usually does not respond to treatment with pancreatic enzymes. In the rare patient who is debilitated by postvagotomy diarrhea unresponsive to medical management, operation might be considered, but outcomes can be problematic. The operation of choice is probably a 10-cm reversed jejunal interposition placed in continuity 100 cm distal to the ligament of Treitz. Another option is the onlay antiperi-staltic distal ileal graft. Both operations can cause obstructive symptoms and/or bacterial overgrowth.209Gastric Stasis210,211Gastric stasis following surgery on the stomach may be due to a problem with gastric motor function or caused by an obstruc-tion. The gastric motility abnormality could have been preexist-ing and unrecognized by the operating surgeon. Alternatively, Figure 26-67. Duodenal switch operation. (Reproduced with per-mission from Hinder RA: Duodenal switch: a new form of pancreati-cobiliary diversion, Surg Clin North Am. 1992 Apr;72(2):487-499.)Brunicardi_Ch26_p1099-p1166.indd 115701/03/19 7:13 PM 1158SPECIFIC CONSIDERATIONS PART IIit may be secondary to deliberate or unintentional vagotomy, or resection of the dominant gastric pacemaker. An obstruction may be mechanical (e.g., anastomotic stricture, efferent limb kink from adhesions or constricting mesocolon, or a proximal small-bowel obstruction) or functional (e.g., retrograde peristal-sis in a Roux limb). Gastric stasis presents with vomiting (often of undigested food), bloating, epigastric pain, and weight loss.The evaluation of a patient with suspected postoperative gastric stasis includes EGD, upper GI and small bowel series, gastric emptying scan, and gastric motor testing. Endoscopy shows gastritis and retained food or bezoar. The anastomosis and efferent limb should be evaluated for stricture or narrow-ing. A dilated efferent limb suggests chronic stasis, either from a motor abnormality (e.g., Roux syndrome) or mechanical small bowel obstruction (e.g., chronic adhesion). If the problem is thought to be primarily a disorder of intrinsic motor func-tion, newer techniques such as EGG and GI manometry should be considered, but chronic distal mechanical obstruction may result in disordered motility in the proximal organ confounding interpretation.Once mechanical obstruction has been ruled out, medi-cal treatment is successful in most cases of motor dysfunction following previous gastric surgery. This consists of dietary modification and promotility agents. Intermittent oral antibiotic therapy may be helpful in treating bacterial overgrowth, with its attendant symptoms of bloating, flatulence, and diarrhea.Gastroparesis following V + D may be treated with subto-tal gastrectomy but simple loop gastrojejunoctomy (GJ) should be tried if previous drainage was pyloroplasty. Billroth II anas-tomosis with Braun enteroenterostomy may be preferable to Roux-en-Y reconstruction after subtotal gastrectomy for gas-tric stasis, but bile reflux can still occur. Initial operation for gastric stasis is often associated with persistent gastric empty-ing problems that may subsequently require near-total or total gastrectomy, a nutritionally unattractive option. Delayed gastric emptying following ulcer surgery (V + D or V + A) may rep-resent an anastomotic stricture (often due to recurrent ulcer) or proximal small bowel obstruction. Recurrent ulcer may respond to medical therapy with PPI and abstinence from NSAIDs, aspi-rin, and smoking. And if necessary, endoscopic dilation is occa-sionally helpful. However, when associated with symptomatic gastric stasis, reoperation is often necessary. Gastroparesis fol-lowing subtotal gastric resection is best treated with near-total (95%) or total gastric resection and Roux-en-Y reconstruction. If total gastrectomy is performed, a jejunal reservoir should be considered. Gastric pacing is promising, but it has not achieved widespread clinical usefulness in the treatment of postoperative gastric atony.Bile Reflux Gastritis and EsophagitisMost patients who have undergone ablation or resection of the pylorus have bile in the stomach on endoscopic examination, along with some degree of gross or microscopic gastric inflam-mation. Therefore, attributing postoperative symptoms to bile reflux is problematic because most asymptomatic patients have bile reflux too. However, it is generally accepted that a small subset of patients have bile reflux gastritis syndrome. These patients present with nausea, bilious vomiting, and epigastric pain, and quantitative evidence of excess enterogastric reflux. Curiously, symptoms often develop months or years after the index operation. The differential diagnosis includes afferent or efferent loop obstruction, gastric stasis, and small-bowel obstruction. Plain abdominal X-rays, upper endoscopy, upper GI series, abdominal CT scan, and gastric emptying scans are helpful in evaluating these possibilities.Bile reflux may be quantified with gastric analysis or esophageal impedance testing or with scintigraphy (bile reflux scan). Typically, enterogastric reflux is greatest after Billroth II gastrectomy or gastrojejunostomy, and least after vagotomy and pyloroplasty, with Billroth I gastrectomy giving intermediate values. Patients who are well into the abnormal range of bile reflux may be considered for remedial surgery if symptoms are severe. Remedial surgery will eliminate the bile from the vomi-tus and may improve the patient’s pain, but it is quite unusual to render these patients completely asymptomatic, especially if they are narcotic dependent.Bile reflux gastritis after distal gastric resection may be treated by one of the following options: Roux-en-Y gastroje-junostomy; interposition of a 40-cm isoperistaltic jejunal loop between the gastric remnant and the duodenum (Henley loop); Billroth II gastro jejunostomy with Braun enteroenterostomy; total gastrectomy with Roux esophagojejunostomy. To mini-mize reflux of bile into the stomach or the esophagus, the Roux limb should be at least 45 cm long (preferably 60 cm). The Braun enteroenterostomy should be placed at a similar distance from the stomach. Excessively long limbs may be associated with obstruction or malabsorption. All of these operations can result in marginal ulceration on the jejunal side of the gastrojeju-nostomy and thus are combined with a generous distal gastrec-tomy. If this has already been done at a previous operation, the Roux or Braun operations may be attractively simple. Whether truncal vagotomy should be considered to decrease the risk of marginal ulceration is controversial because acid-suppressing medications may be equally effective. In addition, the benefits of decreased acid secretion following vagotomy may be out-weighed by problems with vagotomy-associated dysmotility in the gastric remnant. The Roux operation may be associated with an increased risk of emptying problems compared to the other two options, but controlled data are lacking. Patients with debilitating bile reflux after gastrojejunostomy can be consid-ered for simple takedown of this anastomosis provided that the pyloric channel is open.Primary bile reflux gastritis (i.e., no previous operation) is rare, and may be treated with the duodenal switch operation, essentially an end-to-end Roux-en-Y to the proximal duodenum (see Fig. 26-68). The Achilles’ heel of this operation is, not sur-prisingly, marginal ulceration. Thus, it should be combined with highly selective vagotomy, and/or long-term acid suppressive medication.Bile gastritis or esophagitis is a recognized complication after esophagogastrectomy with or without pyloroplasty. This can be effectively treated by division of the duodenum immedi-ately distal to the pylorus with drainage of the prepyloric antrum into a Roux limb. Preservation of the right gastroepiploic pedi-cal is important. Proximal subtotal gastrectomy with esophago-antral anastomosis should be avoided, but when performed, the pylorus should be left intact.Roux SyndromeA subset of patients who have had distal gastrectomy and Roux-en-Y gastrojejunostomy will have great difficulty with gastric emptying in the absence of mechanical obstruc-tion. These patients present with vomiting, epigastric pain, and weight loss. This clinical scenario has been labeled the Brunicardi_Ch26_p1099-p1166.indd 115801/03/19 7:13 PM 1159STOMACHCHAPTER 26Roux syndrome. Endoscopy may show retained food or bezoars, dilation of the gastric remnant, and/or dilation of the Roux limb. Anastomotic inflammation and stricture from mar-ginal ulceration is a confounding finding. An upper GI series confirms these findings and may show delayed gastric empty-ing. This is better quantified by a gastric emptying scan, which always shows delayed solid emptying and may show delayed liquid emptying as well.GI motility testing shows abnormal motility in the Roux limb, with much of the propulsive activity toward, rather than away from, the stomach.212 Gastric motility also may be abnor-mal. Presumably, the disordered motility in the Roux limb occurs in all patients with this operation. Why only a subset develops the Roux syndrome is unclear. Perhaps patients with disordered gastric motility are at most risk. The disorder seems to be more common in patients with a generous gastric remnant. Truncal vagotomy also has been implicated.Medical treatment consists of promotility agents. Surgi-cal treatment consists of paring down the gastric remnant. Care should be taken to preserve adequate blood supply to the new gastric pouch. If the left gastric artery is intact, a vertically ori-ented lesser curvature based pouch (similar to gastric bypass) with excision of the fundus can be considered. If gastric motility is severely disordered, 95% gastrectomy or total gastrectomy should be considered. The Roux limb should be resected if it is dilated and flaccid, unless doing so puts the patient at risk for short bowel.GallstonesGallstone formation following gastric surgery generally is thought to be secondary to vagal denervation of the gallblad-der with attendant gallbladder dysmotility and stasis. Although prophylactic cholecystectomy is not justified with most gas-tric surgery, it should be considered if the gallbladder appears abnormal, especially if subsequent cholecystectomy is likely to be difficult. If preoperative evaluation reveals sludge or gall-stones, or if intraoperative evaluation reveals stones, incidental cholecystectomy should be considered.Weight LossWeight loss is common in patients who have had a vagotomy and/or gastric resection. The degree of weight loss tends to par-allel the magnitude of the operation. It may be insignificant in the obese but devastating in the asthenic patient. The surgeon should always consider the possible nutritional consequences before performing a gastric resection for benign disease in a thin patient. The causes of weight loss after gastric surgery generally fall into one of two categories: altered dietary intake or malabsorption. If a stool stain for fecal fat is negative, it is likely that decreased caloric intake is the cause. This is the most common cause of weight loss after gastric surgery, and it may be due to small stomach syndrome, postoperative gastroparesis, anorexia due to loss of ghrelin, or self-imposed dietary modifi-cation because of dumping and/or diarrhea. Consultation with an experienced dietitian may prove invaluable.AnemiaIron absorption takes place primarily in the proximal GI tract, and it is facilitated by an acidic environment. Intrinsic factor, essential for the enteric absorption of vitamin B12, is made by the parietal cells of the stomach. Vitamin B12 bioavailability also is facilitated by an acidic environment. Folate-rich vegetables may be poorly tolerated if gastric emptying is delayed or if 10gastric capacity is limited. Since iron, B12, and folate play vital roles in hematopoiesis, it is easy to understand why patients who have had a gastric operation are at risk for anemia. Ane-mia is the most common metabolic side effect in patients who have had a gastric bypass for morbid obesity. It also occurs in up to one-third of patients who have had a vagotomy and/or gastric resection. Iron deficiency is the most common cause, but vitamin B12 or folate deficiency also occurs, even in patients who have not had total gastrectomy. Of course, patients who have had a total gastrectomy will all develop B12 deficiency with-out some type of regular nonenteral vitamin B12 administration. Gastric bypass patients should be given oral iron supplements and monitored for iron, B12, and folate deficiency. Patients who have had a vagotomy and/or gastrectomy should be similarly monitored with periodic determination of hematocrit, red blood cell indices, iron and transferrin levels, B12, and folate levels. Marginal nutrient status should be corrected with oral and/or parenteral supplementation.Bone DiseaseGastric surgery sometimes disturbs calcium and vitamin D metabolism. Calcium absorption occurs primarily in the duo-denum, which is bypassed with gastrojejunostomy. Fat mal-absorption may occur because of blind loop syndrome and bacterial overgrowth or because of inefficient mixing of food and digestive enzymes. This can significantly affect the absorp-tion of vitamin D, a fat-soluble vitamin. Both abnormalities of calcium and vitamin D metabolism can contribute to metabolic bone disease in patients following gastric surgery. The prob-lems usually manifest as pain and/or fractures many years after the index operation. Musculoskeletal symptoms should prompt a study of bone density. Dietary supplementation of calcium and vitamin D may be useful in preventing these complications. Routine skeletal monitoring of patients at high-risk (e.g., elderly males and females and postmenopausal females) may prove useful in identifying skeletal deterioration that may be slowed or stopped with appropriate treatment after gastric surgery.LAPAROSCOPIC GASTRIC OPERATIONSThe most common laparoscopic gastric operations performed today are for GERD and obesity. However, all conventional gastric operations can be performed with minimal access techniques.213 Some are more technically challenging (e.g., partial or total gastric resection) are of debatable advantage over conventional open approaches. Certainly, highly selective vagotomy, vagotomy and gastrojejunostomy, and gastrostomy lend themselves to a minimal access approach. Laparoscopic local excision is often feasible for GI stromal tumors, leiomyo-mas, or gastric diverticula. Difficult to access lesions near the GE junction or pylorus may be removed through an anterior gastrotomy; more recent approaches utilizing transgastric ports or combined laparoscopic and endoscopic approaches show promise in allowing removal of practically any small gastric lesion with limited incisions.In Japan and Korea, laparoscopic and robotic assisted approaches have been applied increasingly in the manage-ment of gastric cancer.214,215 Indeed, laparoscopic subtotal gas-trectomy has supplanted the traditional open operation as the preferred operation for patients with earlier stage tumors, and laparocopic total gastrectomy for proximal tumors is performed with regularity and excellent outcomes. The Asian experience Brunicardi_Ch26_p1099-p1166.indd 115901/03/19 7:13 PM 1160SPECIFIC CONSIDERATIONS PART IIhas firmly established the feasibility of safe laparoscopic D2 gastrectomy. Translation of this experience to the United States, however, is not easily accomplished. Studies from Asia suggest that expertise in the laparoscopic approach require upwards of 40 cases, a challenging baseline given the much lower incidence of gastric cancer in the United States.216-219 A more advanced spectrum of disease and higher mean BMI in Western coun-tries are additional barriers to widespread implementation of laparoscopic resection for gastric cancer. Notwithstanding, several high volume centers in the United States have reported excellent outcomes after laparoscopic gastrectomy. As robotic technology that facilitates dissection and anastomosis with articulated instrumentation and enhanced visualization becomes increasingly ubiquitous, the pendulum will likely swing toward increasing utilization of minimal access approaches for all gas-tric operations.220REFERENCESEntries highlighted in bright blue are key references. 1. Beaumont W. Experiments and Observations on the Gastric Juice and the Physiology of Digestion. Plattsburgh: PP Allen; 1833. 2. Wangensteen OH, Wangensteen SD. Gastric surgery. In: The Rise of Surgery. Minneapolis: University of Minnesota Press; 1978. 3. Herrington JL. Historical aspects of gastric surgery. In: Scott HW, Jr, Sawyers JL, eds. Surgery of the Stomach, Duodenum, and Small Intestine. 2nd ed. Boston: Blackwell; 1992. 4. Dragstedt LR. Vagotomy for the gastroduodenal ulcer. Ann Surg. 1945;122:973-989. 5. Zollinger RM, Ellison EH. Primary peptic ulcerations of the jejunum associated with islet cell tumors of the pancreas. Ann Surg. 1955;142:709-728. 6. Flora ED, Wilson TG, Martin IJ, et al. A review of natural orifice translumenal endoscopic surgery (NOTES) for intraab-dominal surgery: experimental models, techniques, and appli-cability to the clinical setting. Ann Surg. 2008;247:583-602. 7. Mercer DW, Liu TH, Castaneda A. Anatomy and physiology of the stomach. In: Zuidema GD, Yeo CJ, eds. Shackelford’s Surgery of the Alimentary Tract. 5th ed. Vol 2. Philadelphia: WB Saunders; 2002:3. 8. Warren WD, Zeppa R, Fomon JJ. Selective trans-splenic decompression of gastroesophageal varices by distal spleno-renal shunt. Ann Surg. 1967;166:437-455. 9. Orringer MB, Marshall B, Chang AC, et al. Two thousand transhiatal esophagectomies: changing trends, lessons learned. Ann Surg. 2007;246:363-372. 10. Leung WK, et al. Tumors of the stomach. In: Yamada T, et al, eds. Textbook of Gastroenterology. 4th ed. Philadelphia: Lip-pincott, Williams & Wilkins; 2003:1416. 11. Japanese Gastric Cancer Association. Japanese classifications of gastric carcinoma: 3rd English edition. Gastric Cancer. 2011;14:101-112. 12. Jansen EPM, Boot H, Verheij M, van de Velde CJ. Opti-mal locoregional treatment in gastric cancer. J Clin Oncol. 2005:23:4509-4517. 13. Johnson LR, ed. Physiology of the Gastrointestinal Tract. 5th ed. New York: Elsevier; 2012. 14. Browning KN, Verheijden S, Boeckxstaens GE. The vagus nerve in appetite regulation, mood, and intestinal inflamma-tion. Gastroenterology. 2017;152(4):730-744. 15. Matteoli G, Boeckxstaens GE. The vagal innervation of the gut and immune homeostasis. Gut. 2013;62(8):1214-1222. 16. Fawcett DW, Jensh R. In: Bloom and Fawcett: Concise Histol-ogy. 2nd ed. Oxford University Press: London. 17. Ashley SW, Evoy D, Daly JM. Stomach. In: Schwartz SI, ed. Principles of Surgery. 7nd ed. New York:McGraw-Hill; 1999:1181. 18. Antonioli DA, Madara JL. Functional anatomy of the gas-trointestinal tract. In: Ming S-C, Goldman H, eds. Pathology of the Gastrointestinal Tract. 2nd ed. Baltimore: Williams & Wilkins; 1998:13. 19. Aloia L, McKie MA, Huch M. Cellular plasticity in the adult liver and stomach. J Physiol. 2016;594(17):4815-4825. 20. Feldman M. Gastric secretion. In: Feldman M, ed. Sleisenger and Fordtran’s Gastrointestinal and Liver Disease. 7nd ed. Philadelphia: Saunders; 2002;715. 21. Minalyan A, Gabrielyan L, Scott D, Jacobs J, Pisegna JR. The gastric and intestinal microbiome: role of proton pump inhibi-tors. Curr Gastroenterol Rep. 2017;19(8):42. 22. Loo VG, Bourgault AM, Poirier L, et al. Host and pathogen factors for Clostridium Difficile infection and colonization. N Engl J Med. 2011;365:1693-1703. 23. Canani RB, Terrin G. Gastric acidity inhibitors and the risk of intestinal infections. Curr Opin Gastroenterol. 2010;26:31-35. 24. Kopic S, Murek M, Geibel JP. Revisiting the parietal cell. Am J Physiol Cell Physiol. 2010;298:C1-C10. 25. Wolfe MM, Soll AH. The physiology of gastric acid secretion. N Engl J Med. 1988;319:1707-1715. 26. Schubert ML. Physiologic, pathophysiologic, and pharmaco-logic regulation of gastric acid secretion. Curr Opin Gastro-enterol. 2017;33(6): pp. 430-438. 27. Schubert ML, Peura DA. Control of gastric acid secretion in health and disease. Gastroenterology. 2008;134(7):1842-1860. 28. Lloyd KCK, Debas HT. Hormonal and neural regulation of gastric acid secretion. In: Johnson LR, ed. Physiology of the Gastrointestinal Tract. 3rd ed. New York: Raven; 1993. 29. Del Valle J, Todisco A. Gastric secretion. In: Yamada T, et al, eds. Textbook of Gastroenterology. 4nd ed. Philadelphia: Lippincott, Williams & Wilkins; 2003:266. 30. Norlén P, Ericsson P, Kitano M, Ekelund M, Håkanson R. The vagus regulates histamine mobilization from rat stomach ECL cells by controlling their sensitivity to gastrin. J Physiol. 2005;564(pt 3):895-905. 31. Holst JJ, Knuhtsen S, Orskov C, et al. GRP nerves in pig antrum: role of GRP in vagal control of gastrin secretion. Am J Physiol. 1987;253(5 pt 1):G643-G649. 32. Helgadottir H, Metz DC, Yang YX, Rhim AD, Björnsson ES. The effects of long-term therapy with proton pump inhibitors on meal stimulated gastrin. Dig Liver Dis. 2014;46(2):125-130. 33. Lodrup AB, Reimer C, Bytzer P. Systematic review: symptoms of rebound acid hypersecretion following proton pump inhibi-tor treatment. Scand J Gastroenterol. 2013;48(5):515-522. 34. Boyce M, et al. Randomised trial of the effect of a gastrin/CCK2 receptor antagonist on esomeprazole-induced hyper-gastrinaemia: evidence against rebound hyperacidity. Eur J Clin Pharmacol. 2017;73(2):129-139. 35. Agreus L, et al. Rationale in diagnosis and screening of atro-phic gastritis with stomach-specific plasma biomarkers. Scand J Gastroenterol. 2012;47(2):136-147. 36. Wallace JL. Prostaglandins, NSAIDs, and gastric mucosal pro-tection: why doesn’t the stomach digest itself? Physiol Rev. 2008;88:1547-1565. 37. Choi SR, Lee SA, Kim YJ, et al. Role of heat shock proteins in gastric inflammation and ulcer healing. J Physiol Pharmacol. 2009;60:5-17. 38. Yandrapu H, Sarosiek J. Protective factors of the gastric and duodenal mucosa: an overview. Curr Gastroenterol Rep. 2015;17(6):24. 39. Cummings DE, Overduin J. Gastrointestinal regulation of food intake. J Clin Invest. 2007;117(1):13-23. 40. Dimaline R, Varro A. Novel roles of gastrin. J Physiol. 2014;592(14):2951-2958.Brunicardi_Ch26_p1099-p1166.indd 116001/03/19 7:13 PM 1161STOMACHCHAPTER 26 41. Bartfeld S, et al. In vitro expansion of human gastric epithelial stem cells and their responses to bacterial infection. Gastroen-terology. 2015;148(1):126-136 e6. 42. Winsett OE, et al. Gastrin stimulates growth of colon cancer. Surgery. 1986;99(3):302-307. 43. Johnson LR. The trophic action of gastrointestinal hormones. Gastroenterology. 1976;70(2):278-288. 44. Murray CD, Kamm MA, Bloom SR, et al. Ghrelin for the gastroenterologist: history and potential. Gastroenterology. 2003;125:1492-1502. 45. Muller TD, et al. Ghrelin. Mol Metab. 2015;4(6):437-460. 46. Ariyasu H, Takaya K, Tagami T, et al. Stomach is a major source of circulating ghrelin, and feeding state determines plasma ghrelin-like immuno reactivity levels in humans. J Clin Endocrinol Metab. 2001;86:4753-4758. 47. Anderson B, et al. The impact of laparoscopic sleeve gastrec-tomy on plasma ghrelin levels: a systematic review. Obes Surg. 2013;23(9):1476-1480. 48. Steinert RE, et al. Ghrelin, CCK, GLP-1, and PYY(3-36): secretory controls and physiological roles in eating and glycemia in health, obesity, and after RYGB. Physiol Rev. 2017;97(1):411-463. 49. Cummings DE, Weigle DS, Frayo RS, et al. Plasma ghrelin levels after diet-induced weight loss or gastric bypass surgery. N Engl J Med. 2002;346:1623-1630. 50. Karamanakos SN, Vagenas K, Kalfarentzos F, et al. Weight loss, appetite suppression, and changes in fasting and post-prandial ghrelin and peptide-YY levels after Roux-en-Y gas-tric bypass and sleeve gastrectomy: a prospective, double blind study. Ann Surg. 2008;247:401. 51. Delhanty PJ, Neggers SJ, and van der Lely AJ. Mechanisms in endocrinology: ghrelin: the differences between acyland des-acyl ghrelin. Eur J Endocrinol. 2012;167(5):601-608. 52. Badman MK, Flier JS. The gut and energy balance: visceral allies in the obesity wars. Science. 2005;307(5717):1909-1914. 53. Bado A, et al. The stomach is a source of leptin. Nature. 1998;394(6695):790-793. 54. Sanjeevi A. Gastric motility. Curr Opin Gastroenterol. 2007;23:625. 55. Parkman HP, Jones MP. Tests of gastric neuromuscular func-tion. Gastroenterology. 2009;136:1526-1543. 56. Hasler WL. Physiology of gastric motility and gastric empty-ing. In: Yamada T, et al, eds. Textbook of Gastroenterology. 4nd ed. Philadelphia: Lippincott, Williams & Wilkins; 2003:195. 57. Chial HJ, Camilleri M. Motility disorders of the stomach and small intestine. In: Friedman SL, McQuaid KR, Grendell JH, eds. Current Diagnosis and Treatment in Gastroenterology. 2nd ed. New York:McGraw-Hill; 2003:355. 58. Sanders KM, Koh SD, Ro S, Ward SM. Regulation of gastro-intestinal motility—insights from smooth muscle biology. Nat Rev Gastroenterol Hepatol. 2012;9:633-645. 59. Deloose E, Janssen P, Depoortere I, Tack J. The migrating motor complex—control mechanisms and its role in health and disease. Nat Rev Gastroenterol Hepatol. 2012;9:271-285. 60. Vanden Berghe P, et al. Contribution of different triggers to the gastric accommodation reflex in humans. Am J Physiol Gastrointest Liver Physiol. 2009;297(5):G902-G906. 61. Berthoud HR. The vagus nerve, food intake and obesity. Regul Pept. 2008;149(1-3):15-25. 62. Cheng LK. Slow wave conduction patterns in the stomach: from Waller’s foundations to current challenges. Acta Physiol (Oxf). 2015;213(2):384-393. 63. Tack J, et al. Motilin-induced gastric contractions signal hun-ger in man. Gut. 2016;65(2):214-224. 64. Marks JM, Ponsky JL. Diagnostic and therapeutic endoscopy of the stomach and small bowel. In: Yeo CJ, et al, eds. Shack-elford’s Surgery of the Alimentary Tract. 6nd ed. Philadelphia: Saunders; 2007. 65. Levine MS, Rubesin SE, Laufer I. Barium studies in modern radiology: do they have a role? Radiology. 2009;250(1):18-22. 66. Furukawa K, Miyahara R, Itoh A, et al. Diagnosis of the inva-sion depth of gastric cancer using MDCT with virtual gastros-copy: comparison with staging with endoscopic ultrasound. AJR Am J Roentgenol. 2011;197:867-875. 67. Chen CY, Hsu JS, Wu DC, et al. Gastric cancer: preopera-tive local staging with 3D multidetector row CT—correlation with surgical and histopathologic results. Radiology. 2007; 242:472-482. 68. Shin KS, Kim SH, Han JK, et al. Three-dimensional MDCT gastrography compared with axial CT for the detection of early gastric cancer. J Comput Assist Tomogr. 2007;31: 741-749. 69. Caddy GR, Chen RY. Current clinical applications of endo-scopic ultrasound. ANZ J Surg. 2007;77:101-111. 70. Power DG, Schattner MA, Gerdes H, et al. Endoscopic ultrasound can improve the selection for laparoscopy in patients with localized gastric cancer. J Am Coll Surg. 2009;208:173-178. 71. Jones DB. Role of endoscopic ultrasound in staging upper gastrointestinal cancers. ANZ J Surg. 2007;77:166-172. 72. Balaji NS, Crookes PF, Banki F, et al. A safe and noninvasive test for vagal integrity revisited. Arch Surg. 2002;137:954-958. 73. Vaira D, Gatta L, Ricci C, Miglioli M. Review article: diagno-sis of Helicobacter pylori infection. Aliment Pharmacol Ther. 2002;16:105-113. 74. Walsh JH, Peterson WL. The treatment of Helicobacter pylori infection in the management of peptic ulcer disease. N Engl J Med. 1995;333:984-991. 75. Kao CY, Sheu BS, Wu JJ. Helicobacter pylori infection: an overview of bacterial virulence factors and pathogenesis. Biomed J. 2016;39(1):14-23. 76. Hooi JKY, et al. Global prevalence of Helicobacter pylori infection: systematic review and meta-analysis. Gastroenter-ology. 2017;153(2):420-429. 77. Graham DY. Helicobacter pylori update: gastric cancer, reliable therapy, and possible benefits. Gastroenterology. 2015;148(4):719-731 e3. 78. Noto JM, Peek RM, Jr. The gastric microbiome, its interaction with Helicobacter pylori, and its potential role in the progres-sion to stomach cancer. PLoS Pathog. 2017;13(10):e1006573. 79. Blaser MJ, Atherton JC. Helicobacter pylori persistence: biol-ogy and disease. J Clin Invest. 2004;113:321-333. 80. Fox JG, Wang TC. Inflammation, atrophy, and gastric cancer. J Clin Invest. 2007;117(1):60-69. 81. McColl KE. Clinical practice. Helicobacter pylori infection. N Engl J Med. 2010;362:1597-1604. 82. Bedoui S, Kupz A, Wijberg OL, et al. Different bacterial pathogens, different strategies, yet the aim is the same: eva-sion of intestinal dendritic cell recognition. J Immunol. 2010;184:2237-2242. 83. Graham DY, Lew GM, Klein PD, et al. Effect of treatment of Helicobacter pylori infection on the long-term recurrence of gastric or duodenal ulcer: arandomized controlled study. Ann Intern Med. 1992;116:705-708. 84. McColl K, et al. Symptomatic benefit from eradicating Heli-cobacter pylori infection in patients with nonulcer dyspepsia. N Engl J Med. 1998;339(26):1869-1874. 85. Atkinson NS, Braden B. Helicobacter pylori infection: diag-nostic strategies in primary diagnosis and after therapy. Dig Dis Sci. 2016;61(1):19-24. 86. Burucoa C, et al. Comparative evaluation of 29 commer-cial Helicobacter pylori serological kits. Helicobacter. 2013;18(3):169-179. 87. Malfertheiner P, et al. Management of Helicobacter pylori infection—the Maastricht V/Florence Consensus Report. Gut. 2017;66(1):6-30.Brunicardi_Ch26_p1099-p1166.indd 116101/03/19 7:13 PM 1162SPECIFIC CONSIDERATIONS PART II 88. Shiota S, et al. Antibiotic resistance of Helicobacter pylori among male United States veterans. Clin Gastroenterol Hepa-tol. 2015;13(9):1616-1624. 89. Holle GE. Pathophysiology and modern treatment of ulcer dis-ease. Int J Mol Med. 2010;25(4):483-491. 90. Leong RW. Differences in peptic ulcer between the East and the West. Gastroenterol Clin North Am. 2009;38(2):363-379. 91. Brock J, Sauaia A, Ahnen D, et al. Process of care and out-comes for elderly patients hospitalized with peptic ulcer disease: results from a quality improvement project. JAMA. 286:1985-1993. 92. Yang YR, Richter JE, Dempsey DT. Trends and outcomes of hospitalizations for peptic ulcer disease in the United States 1993-2006. Ann Surg. 2010;251:51-58. 93. Feinstein LB, et al. Trends in hospitalizations for peptic ulcer disease, United States, 1998-2005. Emerg Infect Dis. 2010;16(9):1410-1418. 94. Spechler SJ. Peptic ulcer disease and its complications. In: Feldman M, ed. Sleisinger and Fordtran’s Gastrointestinal and Liver Disease. 7nd ed. Philadelphia: Saunders; 2002. 95. Del Valle J, Chey WD, Scheiman JM. Acid peptic disorders. In: Yamada T, et al, eds. Textbook of Gastroenterology. 4nd ed. Philadelphia: Lippincott, Williams & Wilkins; 2003:1321. 96. Fisher WE, Brunicardi FC. Benign gastric ulcer. In: Cameron JL, ed. Current Surgical Therapy. 9nd ed. Philadelphia: Mosby Elsevier; 2008:81. 97. Laine L. Approaches to nonsteroidal anti-inflamma-tory drug use in the high-risk patient. Gastroenterology. 2001;120:594-606. 98. Lanas A. A review of the gastrointestinal safety data—a gastroenterologist’s perspective. Rheumatology. 2010;49: ii3-ii10. 99. Kawasaki K, et al. Low-dose aspirin and non-steroidal anti-inflammatory drugs increase the risk of bleeding in patients with gastroduodenal ulcer. Dig Dis Sci. 2015;60(4):1010-1015. 100. Mora S, Manson JE. Aspirin for primary prevention of ath-erosclerotic cardiovascular disease: advances in diagnosis and treatment. JAMA Intern Med. 2016;176(8):1195-1204. 101. Vaduganathan M, et al. Proton-pump inhibitors reduce gas-trointestinal events regardless of aspirin dose in patients requiring dual antiplatelet therapy. J Am Coll Cardiol. 2016;67(14):1661-1671. 102. Vaduganathan M, et al. Efficacy and safety of proton-pump inhibitors in high-risk cardiovascular subsets of the COGENT trial. Am J Med. 2016;129(9):1002-1005. 103. Ray WA, et al. Association of proton pump inhibitors with reduced risk of warfarin-related serious upper gastrointestinal bleeding. Gastroenterology. 2016;151(6):1105-1112 e10. 104. Abraham NS, Hlatky MA, Antman EM, et al: ACCF/ACG/AHA Expert consensus document on the concomitant use of proton pump inhibitors and thienopyridines: a focused update of the ACCF/ACG/AHA 2008 consensus document on reduc-ing the gastrointestinal risks of antiplatet therapy and NSAID use. Circulation. 2010;122:2619-2633. 105. Chan FK, et al. Similar efficacy of proton-pump inhibitors vs H2-receptor antagonists in reducing risk of upper gastrointes-tinal bleeding or ulcers in high-risk users of low-dose aspirin. Gastroenterology. 2017;152(1):105-110 e1. 106. Hsu CC, et al. Depression and the risk of peptic ulcer disease: a nationwide population-based study. Medicine (Baltimore). 2015;94(51):e2333. 107. Blatchford O, Murray WR. A risk score to predict need for treatment for upper gastrointestinal hemorrhage. Lancet. 2000;356:1318-1321. 108. Saltzman JR, et al. A simple risk score accurately predicts in-hospital mortality, length of stay, and cost in acute upper GI bleeding. Gastrointest Endosc. 2011;74(6):1215-1224. 109. Dallal HJ, Palmer KR. ABC of the upper gastrointes-tinal tract: upper gastrointestinal haemorrhage. BMJ. 2001;323:1115-1117. 110. Laine L. Upper gastrointestinal bleeding due to a peptic ulcer. N Engl J Med. 2016;375(12):1197-1198. 111. Cheng DW, et al. A modified Glasgow Blatchford Score improves risk stratification in upper gastrointestinal bleed: a prospective comparison of scoring systems. Aliment Pharma-col Ther. 2012;36(8):782-789. 112. Lo CC, et al. Comparison of hemostatic efficacy for epineph-rine injection alone and injection combined with hemoclip therapy in treating high-risk bleeding ulcers. Gastrointest Endosc. 2006;63(6):767-773. 113. Chey WD, Wong BCY. Practice Parameters Committee of the American College of Gastroenterology. American College of Gastroenterology guideline on the management of Helicobacter pylori infection. Am J Gastroenterol. 2007;102: 1808-1825. 114. Harbison SP, Dempsey DT. Peptic ulcer disease. Curr Probl Surg. 2005;42(6):346-454. 115. Mulholland MW, Debas HT. Chronic duodenal and gastric ulcer. Surg Clin North Am. 1987;67:489-507. 116. Schroder VT, et al. Vagotomy/drainage is superior to local oversew in patients who require emergency surgery for bleed-ing peptic ulcers. Ann Surg. 2014;259(6):1111-1118. 117. Wu SC, et al. Acid-reducing vagotomy is associated with reduced risk of subsequent ischemic heart disease in com-plicated peptic ulcer: An Asian population study. Medicine (Baltimore). 2016;95(50):e5651. 118. Lagoo J, Pappas TN, Perez A. A relic or still relevant: the nar-rowing role for vagotomy in the treatment of peptic ulcer dis-ease. Am J Surg. 2014;207(1):120-126. 119. Maki T, Shiratoti T, Hatafuku T, et al. Pyrolus-preserving gas-trectomy as an improved operation for gastric ulcer. Surgery. 1967;61:838-842. 120. Morita S, Katai H, Saka T, et al. Outcome of pyrolus-pre-serving gastrectomy for early gastric cancer. Br J Surg. 2008;95:1131-1135. 121. Gilliam AD, Speake WJ, Lobo DN, et al. Current practice of emergency vagotomy and Helicobacter pylori eradication for complicated peptic ulcer in the United Kingdom. Br J Surg. 2003;90:88-90. 122. Reuben BC, Neumayer LA. Variations reported in sur-gical practice for bleeding duodenal ulcers. Am J Surg. 2006;192:e42-e45. 123. Yusuf TE, Brugge WR. Endoscopic therapy of benign pyloric stenosis and gastric outlet obstruction. Curr Opin Gastroen-terol. 2006;22:570-573. 124. Csendes A, Maluenda F, Braghetto I, et al. Prospective ran-domized study comparing three surgical techniques for the treatment of gastric outlet obstruction secondary to duodenal ulcer. Am J Surg. 1993;166:45-49. 125. Lau JYW, Sung JJY, Lee KKC, et al. Effect of intravenous omeprazole on recurrent bleeding after endoscopic treatment of bleeding peptic ulcers. N Engl J Med. 2000;343:310-316. 126. Lau JY, Sung JJ, Lam YH, et al. Endoscopic retreatment com-pared with surgery in patients with recurrent bleeding after initial endoscopic control of bleeding ulcers. N Engl J Med. 1999;340:751-756. 127. Fendrich V, Langer P, Waldmann J, et al. Management of spo-radic and multiple endocrine neoplasia type 1 gastrinomas. Br J Surg. 2007;94:1331-1341. 128. Dolan JP, Norton JA: Zollinger-Ellison Syndrome, in Yeo CJ, et al (eds). Shackelford’s Surgery of the Alimentary Tract, 6th ed. Philadelphia: Saunders/Elsevier, 2007, p. 862. 129. Orlando LA, Lenard L, Orlando RC: Chronic hypergastrinemia: causes and consequences. Dig Dis Sci. 2007;52:2482-2489.Brunicardi_Ch26_p1099-p1166.indd 116201/03/19 7:13 PM 1163STOMACHCHAPTER 26 130. Fraker DL, et al. Surgery in Zollinger-Ellison syndrome alters the natural history of gastrinoma. Ann Surg. 1994;220(3): 320-328; discussion 328-330. 131. Norton JA, et al. Surgery increases survival in patients with gastrinoma. Ann Surg. 2006;244(3):410-419. 132. Alhazzani W, Alenezi F, Jaeschke RZ, et al. Proton pump inhibitors versus histamine 2 receptor antagonists for stress ulcer prophylaxis in critically ill patients: a systematic review and meta-analysis. Crit Care Med. 2013;41:693-705. 133. Sasabuchi Y, et al. Risks and benefits of stress ulcer pro-phylaxis for patients with severe sepsis. Crit Care Med. 2016;44(7):e464-e469. 134. Barletta JF, et al. Stress ulcer prophylaxis. Crit Care Med. 2016;44(7):1395-1405. 135. Marik PE, Vasu T, Hirani A, et al. Stress ulcer prophylaxis in the new millennium: a systematic review and meta-analysis. Crit Care Med. 2010;38:2222-2228. 136. Isajevs S, et al. Gastritis staging: interobserver agreement by applying OLGA and OLGIM systems. Virchows Arch. 2014;464(4):403-407. 137. Nam JH, et al. OLGA and OLGIM stage distribution accord-ing to age and Helicobacter pylori status in the Korean popula-tion. Helicobacter. 2014;19(2):81-89. 138. The American Cancer Society. Cancer Facts and Figures 2017; pg 4, Table 1. Cancer.org. https://www.cancer.org/content/dam/cancer-org/research/cancer-facts-and-statistics/annual-cancer-facts-and-figures/2017/cancer-facts-and-figures-2017 .pdf Accessed 1-1-2018. 139. Correa P, Houghton J. Carcinogenesis of Helicobacter pylori. Gastroenterology. 2007;133(2):659-672. 140. McColl KE, Watabe H, Derakhshan MH. Role of gastric atrophy in mediating negative association between Heli-cobacter pylori infection and reflux oesophagitis, Barrett’s oesophagus and oesophageal adenocarcinoma. Gut. 2008;57: 721-723. 141. ZurHausen A, van Rees BP, van Beek J, et al. Epstein-Barr virus in gastric carcinomas and gastric stump carci-nomas: alate event in gastric carcinogenesis. J Clin Pathol. 2004;57:487-491. 142. Norton JA, Ham CM, Dam JV, et al. CDH1 truncating muta-tions in the E-cadherin gene: an indication for total gastrec-tomy to treat hereditary diffuse gastric cancer. Ann Surg. 2007;245:873-879. 143. Chiba T, et al. Chronic inflammation and gastric cancer devel-opment (in Japanese). Nihon Rinsho. 2012;70(10):1694-1698. 144. Chiba T, Marusawa H, Ushijima T. Inflammation-associated cancer development in digestive organs: mechanisms and roles for genetic and epigenetic modulation. Gastroenterol-ogy. 2012;143(3):550-563. 145. Park DY, Lauwers GY. Gastric polyps: classification and man-agement. Arch Pathol Lab Med. 2008;132(4):633-640. 146. Shimoyama S, Aoki F, Kawahara M, et al. Early gastric cancer development in a familial adenomatous polyposis patient. Dig Dis Sci. 2004;49(2):260-265. 147. Gylling A, Abdel-Rahman WM, Juhola M, et al. Is gastric cancer part of the tumour spectrum of hereditary non-pol-yposis colorectal cancer? A molecular genetic study. Gut. 2007;56:926-933. 148. Schaefer N, Sinning C, Standop J, et al. Treatment and prog-nosis of gastric stump carcinoma in comparison with primary proximal gastric cancer. Am J Surg. 2007;194:63-67. 149. van der Post RS, et al. Hereditary diffuse gastric cancer: updated clinical guidelines with an emphasis on germline CDH1 mutation carriers. J Med Genet. 2015;52(6):361-374. 150. Ono H. Early gastric cancer: diagnosis, pathology, treatment techniques, and treatment outcomes. Eur J Gastroenterol Hep-atol. 2006;18:863-866. 151. Pyrhonen S, Kuitunen T, Nyandoto P, Kouri M. Randomised comparison of fluorouracil, epidoxorubicin, and methotrex-ate (FEMTX) plus supportive care with supportive care alone in patients with non-resectable gastric cancer. Br J Cancer. 1995;71:587-591. 152. Bang YJ, Van Cutsem E, Feyereislova A, et al. Transtuzumab in combination with chemotherapy versus chemotherapy alone for treatment of HER2-positive advanced gastric or gas-troesophageal junction cancer (TOGA): a phase 3 open label randomized controlled trial. Lancet. 2010;376:687-697. 153. Begnami MD, Fuduka E, Fregnani JH, et al. Prognostic impli-cations of altered human epidermal growth factor receptors (HERs) in gastric carcinomas: HER2 and HER3 are predictors of poor outcome. J Clin Oncol. 2011;29(22):3030-3036. 154. Li HY, Dai J, Xue HB, et al. Application of magnifying endoscopy with narrow band imaging in diagnosing gas-tric lesions: a prospective study. Gastrointestinal Endosc. 2012;76:1124-1132. 155. Chen J, Cheong JH, Yun MJ, et al. Improvement in preopera-tive staging of gastric adenocarcinoma with positron emission tomography. Cancer. 2005;103:2383-2390,2005. 156. Wong J, Coit D. Detection of gastric cancer peritoneal metas-tases by peritoneal lavage: current limitations and future per-spectives. Surgery. 2012;152:1-4. 157. Ikoma N, Blum M, Chiang YJ, et al. Yield of staging lapa-roscopy and lavage cytology for radiologically occult peri-toneal carcinomatosis of gastric cancer. Ann Surg Oncol. 2016;23(13):4332-4337. 158. Sarela AI, Lefkowitz R, Brennan MF, et al. Selection of patients with gastric adenocarcinoma for laparoscopic stag-ing. Am J Surg. 2006;191:134-138. 159. Dicken BJ, Bigam DL, Cass C, Mackey JR, Joy AA, Hamilton SM. Gastric adenocarcinoma: review and considerations for future directions. Ann Surg. 2005;241(1):27-39. 160. Squires MH 3rd, Kooby DA, Poultsides GA, et al. Is it time to abandon the 5-cm margin rule during resection of distal gastric adenocarcinoma? A multi-institution study of the U.S. Gastric Cancer Collaborative. Ann Surg Oncol. 2015;22(4):1243-1251. 161. Coburn NG, Swallow CJ Kiss A, Law C. Significant regional variation in adequacy of lymph node assessment and survival in gastric cancer. Cancer. 2006;107(9):2143-2151. 162. Datta J, Lewis RS, Jr, Mamtni R, et al. Implications of inad-equate lymph node staging in resectable gastric cancer: a contemporary analysis using the National Cancer Data Base. Cancer. 2014;120(18):2855-2865. 163. Saidi RF, ReMine SG, Dudrick PS, et al. Is there a role for palliative gastrectomy in patients with stage IV gastric cancer? World J Surg. 2006;30:21-27. 164. Bozzetti F, Marubini E, Bonfantai G, Gennari L. Subtotal versus total gastrectomy for gastric cancer: five-year survival rates in a multicenter randomized Italian trial. Italian Gastroin-testinal Tumor Study Group. Ann Surg. 1999;230(2):170-178. 165. Karanicolas PJ, Graham D, Gönen DM, Strong VE, Ben-nan MF, Coit DG. Quality of life after gastrectomy for adenocarcinoma: a prospective cohort study. Ann Surg. 2013;257(6):1039-1046. 166. Bonenkamp JJ, Hermans J, Sasako M, et al. Extended lymph node dissection for gastric cancer. N Engl J Med. 1999;340:908-914. 167. Bartlett EK, Roses RE, Kelz RR, Drebin JA, Fraker DL, Karakousis GC. Morbidity and mortality after total gastrec-tomy for gastric malignancy using the American College of Surgeons National Surgical Quality Improvement Program database. Surgery. 2014;156(2):298-304. 168. Cuschieri A, Fayers P, Fielding J, et al. Postoperative morbid-ity and mortality after D1 and D2 resections for gastric can-cer: preliminary results of the MRC randomised controlled Brunicardi_Ch26_p1099-p1166.indd 116301/03/19 7:13 PM 1164SPECIFIC CONSIDERATIONS PART IIsurgical trial. The Surgical Cooperative Group. Lancet. 1996;347:995-999. 169. Degiuli M, Sasako M, Ponti A, et al. Randomized clinical trial comparing survival after D1 or D2 gastrectomy for gastric can-cer. Br J Surg. 2014;101(2):23-31. 170. Songun I, Putter H, Kranenbarg EM, Sasako M, van de Velde CJ. Surgical treatment of gastric cancer: 15-year follow-up results of the randomised nationwide Dutch D1D2 trial. Lan-cet Oncol. 2010;11(5):439-449. 171. GASTRIC (Global Advanced/Adjuvant Stomach Tumor Research International Collaboration) Group; Paoletti X, Oba K, Burzykowski T, et al. Benefit of adjuvant chemo-therapy for resectable gastric cancer: a meta-analysis. JAMA. 2010;303(17):1729-1737. 172. Sasako M, et al. Five-year outcomes of a randomized phase III trial comparing adjuvant chemotherapy with S-1 versus surgery alone in stage II or III gastric cancer. J Clin Oncol. 2011;29:4387-4393. 173. Noh SH, Adjuvant capecitabine plus oxaliplatin for gastric cancer after D2 gastrectomy (CLASSIC): 5-year follow-up of an open-label, randomised phase 3 trial. Lancet Oncol. 2014;15(12):1389-1396. 174. Park SH, Sohn TS, Lee J, et al. Phase III trial to compare adjuvant chemotherapy with capecitabine and cisplatin ver-sus concurrent chemoradiotherapy in gastric cancer: final report of the adjuvant chemoradiotherapy in stomach tumors trial, including survival and subset analyses. J Clin Oncol. 2015;33(28):3130-3136. 175. Macdonald JS, Smalley SR, Benedetti J, et al. Chemoradio-therapy after surgery compared with surgery alone for adeno-carcinoma of the stomach or gastroesophageal junction. N Engl J Med. 2001;345:725-730. 176. Cunningham D, Allum WH, Stenning SP, et al. Perioperative chemotherapy versus surgery alone for resectable gastroesoph-ageal cancer. N Engl J Med. 2006;355(1):11-20. 177. Ajani JA, Winter K, Okawara GS, et al. Phase II trial of preoperative chemoradiation in patients with localized gas-tric adenocarcinoma (RTOG 9904): quality of combined modality therapy and pathologic response. J Clin Oncol. 2006;24(24):3953-3958. 178. Sasako M, Sano T, Yamamoto S, et al. D2 lymphadenectomy alone or with para-aortic nodal dissection for gastric cancer. N Engl J Med. 2008;359:453-462. 179. VanCutsem E, Moiseyenko VM, Tjulandin S, et al. Phase III study of docetaxel and cisplatin plus fluorouracil compared with cisplatin and fluorouracil as first-line chemotherapy for advanced gastric cancer: areport of the V325 study group. J Clin Oncol. 2006;24:4991-4997. 180. Cunningham D, Starling N, Rao S, et al. Capecitabine and oxaliplatin for advanced esophagogastric cancer. N Engl J Med. 2008;358(1):36-46. 181. Gomez-Martin C, Garralda E, Echerri MJ. HER2/neu testing for anti-HER2 based therapies in patients with unresectable and/or metastatic gastric cancer. J Clin Path. 2012;65:751-757. 182. Baptista V, Singh A, Wassef W. Early gastric cancer: an update on endoscopic management. Curr Opin Gastroenterol. 2012;28(6):629-635. 183. Yoon SS, Coit DG, Portlock CS, et al. The diminishing role of surgery in the treatment of gastric lymphoma. Ann Surg. 2004;240:28-37. 184. Farinha P, Gascoyne RD. Helicobacter pylori and MALT lym-phoma. Gastroenterology. 2005;128:1579-1605. 185. Gold JS, DeMatteo RP. Combined surgical and molecular therapy: the gastrointestinal stromal tumor model. Ann Surg. 2006;244(2):176-184. 186. Rubin BP, Heinrich MC, Corless CL. Gastrointestinal stromal tumour. Lancet. 2007;369:1731-1741. 187. Stelow EB, Murad FM, Debol SM, et al. A limited immuno-cytochemical panel for the distinction of subepithelial gastro-intestinal mesenchymal neoplasms sampled by endoscopic ultrasound-guided fine-needle aspiration. Am J Clin Pathol. 2008;129:219-225. 188. Miettinen M, Lasota J. Gastrointestinal stromal tumors: Pathology and prognosis at different sites. Semin Diagn Pathol. 2006;23:70-83. 189. Heinrich MC. Kinase mutations and imatinib response in patients with metastatic gastrointestinal stromal tumor. J Clin Oncol. 2003;21(23):4342-4349. 190. Dematteo RP, Ballman KV, Antonescu CR, et al. Adjuvant imatinib mesylate after resection of localised, primary gas-trointestinal stromal tumour: a randomised, double-blind, placebo-controlled trial. Lancet. 2009;373(9669):1097-1104. 191. Joensuu H, Eriksson M, Sunby Hall K, et al. One vs three years of adjuvant imatinib for operable gastrointestinal stromal tumor: a randomized trial. JAMA. 2012;307(12):1265-1272. 192. Balachandran VP, DeMatteo RP. Adjuvant imatinib for GIST: the pie is shrinking. Ann Surg Oncol. 2014;21(11):3365-3366. 193. Raut CP, Kulke MH, Glickman JN, et al. Carcinoid tumors. Curr Probl Surg. 2006;43:383-450. 194. Perren A, Couvelard A, Scoazec JY, et al. ENETS consensus guidelines for the standards of care in neuroendocrine tumors: pathology: diagnosis and prognostic stratification. Neuroendo-crinology. 2017;105(3):196-200. 195. Parkman HP, Hasler WL, Fisher RS. American Gastroen-terological Association technical review on the diagnosis and treatment of gastroparesis. Gastroenterology. 2004;127: 1592-1622. 196. Yin J, Chen JD. Implantable gastric electrical stimulation: ready for prime time? Gastroenterology. 2008;134:665-667. 197. Zehetner J, Ravari F, Ayazi S, et al. Minimally invasive surgi-cal approach for the treatment of gastroparesis. Surg Endosc. 2013;27(1):61-66. 198. Cappell MS, Friedel D. Initial management of acute upper gas-trointestinal bleeding-from initial evaluation to gastrointestinal endoscopy. Med Clin North Am. 2008;92:491-509. 199. Dempsey DT, Burke DR, Reilly RS, McLean GK, Rosato EF. Angiography in poor-risk patients with massive nonvariceal upper gastrointestinal bleeding. Am J Surg. 1990;159:282-286. 200. Zaman A. Portal hypertension related bleeding-management of difficult cases. Clin Liver Dis. 2006;10:353-370. 201. Coffey RJ, Washington MK, Corless CL, et al. Ménétrier dis-ease and gastrointestinal stromal tumors: hyperproliferative disorders of the stomach. J Clin Invest. 2007;117:70. 202. Sebastian S, O’Morain CA, Buckley MJ. Current therapeutic options for gastric antral vascular ectasia. Aliment Pharmacol-Ther. 2003;18:157-165. 203. Akhras J, Patel P, Tobi M. Dieulafoy’s lesion-like bleeding: an under-recognized cause of upper gastrointestinal hemor-rhage in patients with advanced liver disease. Dig Dis Sci. 2007;52:722-726. 204. Harbison SP, Dempsey DT. Mallory-Weiss syndrome, in Cam-eron JL, ed. Current Surgical Therapy. 9nd ed. Philadelphia: Mosby; 2008. 205. Schrag SP, Sharma R, Jaik NP, et al. Complications related to percutaneous endoscopic gastrostomy (PEG) tubes. A comprehensive clinical review. J Gastrointestin Liver Dis. 2007;16:407-418. 206. McClave SA. Critical care nutrition: getting involved as a gastrointestinal endoscopist. J Clin Gastroenterol. 2006;40:870-890. 207. Dempsey DT. Reoperative gastric surgery and postgastrec-tomy syndromes. In: Zuidema GD, Yeo CJ, eds. Shackelford’s Surgery of the Alimentary Tract. 5nd ed. Vol 2. Philadelphia: Saunders; 2002:161.Brunicardi_Ch26_p1099-p1166.indd 116401/03/19 7:13 PM 1165STOMACHCHAPTER 26 208. Ukleja A. Dumping syndrome: pathophysiology and treat-ment. Nutr Clin Pract. 2005;20:517-525. 209. Cuschieri A. Postvagotomy diarrhea: is there a place for surgi-cal management? Gut. 1990;31:245-246. 210. Forster-Barthell AW, Murr MM, Nitecki S, et al. Near-total completion gastrectomy for severe postvagotomy gastric stasis: analysis of early and long-term results in 62 patients. J Gastrointest Surg. 1999;3:15-21. 211. Jones MP, Maganti K. A systematic review of surgical therapy for gastroparesis. Am J Gastroenterol. 2003;98: 2122-2129. 212. Van der Milje HC, Kleibeuker JH, Limburg AJ, et al. Mano-metric and scintigraphic studies of the relation between motility disturbances in the Roux limb and the Roux-en-Y syndrome. Am J Surg. 1993;166:11-17. 213. Farrell TM, Hunter JG. Laparoscopic surgery of the stomach and duodenum. In: Zuidema GD, Yeo CJ, eds. Shackelford’s Surgery of the Alimentary Tract. 5nd ed. Vol 2. Philadelphia: Saunders; 2002:202. 214. Lee J, Kim W. Clinical experience of 528 laparoscopic gas-trectomies on gastric cancer in a single institution. Surgery. 2013;153(5):611-618. 215. Zeng YK, Yang ZL, Peng JS, et al. Laparoscopy-assisted ver-sus open distal gastrectomy for early gastric cancer. Ann Surg. 2012;256:39-52. 216. Kim HG, Park JH, Jeong SH, et al. Totally laparoscopic distal gastrectomy after learning curve completion: comparison with laparoscopy-assisted distal gastrectomy. J Gastric Cancer. 2013;13(1):26-33. 217. Moon JS, et al. Lessons learned from a comparative analy-sis of surgical outcomes of and learning curves for lap-aroscopy-assisted distal gastrectomy. J Gastric Cancer. 2015;15(1):29-38. 218. Kim HH, Han SU, Kim MC, et al. Long-term results of laparo-scopic gastrectomy for gastric cancer: a large-scale case-con-trol and case-matched Korean multicenter study. J Clin Oncol. 2014;32(7):627-633. 219. Jung DH, Son SY, Park YS, et al. The learning curve asso-ciated with laparoscopic total gastrectomy. Gastric Cancer. 2016;19(1):264-272. 220. Suda K, Uyama I, Kitagawa Y. Technology beats the cur-rent standard: is robotic gastrectomy becoming the standard treatment option for gastric cancer? : “Surgical outcomes after open, laparoscopic, and robotic gastrectomy for gas-tric cancer,” by Kim, Hyuong-Il, et al. Ann Surg Oncol. 2017;24(7):1755-1757.Brunicardi_Ch26_p1099-p1166.indd 116501/03/19 7:13 PM
Brunicardi_Ch26_p1099-p1166.indd 116601/03/19 7:13 PMThis page intentionally left blankThe Surgical Management of ObesityAnita P. Courcoulas and Philip R. Schauer 27chapterINTRODUCTIONDespite the global pandemic of obesity, there has been little progress in nonsurgical treatment approaches, especially among patients with severe obesity. In addition, the evidence base for bariatric procedures has grown rapidly over the last 10 years, yielding important shortand long-term data on the safety and efficacy of the surgical treatment for obesity and related metabolic disorders. Therefore, the approach for patients con-sidering bariatric and metabolic surgery has now shifted to a well-informed and shared decision-making process as there are significant tradeoffs between the potential risks and benefits of these procedures.1HistoryDuring the 1950s, operations were first performed to treat severe hyperlipidemia with associated obesity.2 These were ileocolic bypass operations to limit absorption and were associated with severe nutritional complications and liver failure postopera-tively. A more modest jejunoileal bypass was performed next, also a malabsorptive operation, but it bypassed only a portion of the small intestine. Complications after this procedure included severe diarrhea, electrolyte disturbances, protein-calorie malnu-trition, renal stones, and liver failure.In 1969, Mason and Ito performed the first gastric bypass, describing a loop of jejunum connected to a transverse proximal gastric pouch.3 Bile reflux esophagitis was severe postopera-tively, causing Griffin and colleagues to describe the Roux-en-Y modification of the gastric bypass in 1977.4 The gastric pouch was also altered from transverse to vertical using the upper lesser curvature at this time (Fig. 27-1).In 1980, Mason5 first performed the vertical banded gastroplasty (VBG), which was a restrictive procedure using a stapled proximal gastric pouch of the upper lesser curvature of the stomach with a restrictive band for its outlet to the rest of the stomach. This operation produced excellent initial weight loss (50% of excess weight or more) with low mor-bidity and mortality. It rapidly became the most commonly performed bariatric operation in the United States during the 1980s. However, by the early 1990s, it became clear that patients who underwent VBG modified their diets to high-calorie soft foods and liquids and some regained weight.6 A significant incidence of stenosis at the cuff and staple line Introduction1167History / 1167State of the Field / 1169The Disease of Obesity1169Overview / 1169U.S. Prevalence of Obesity / 1170Causes of Obesity / 1170Concurrent Medical and Social Problems / 1170Medical Management of Obesity1171Lifestyle Intervention / 1171Pharmacotherapy / 1172Barriers to Treatment / 1173Candidates for Bariatric Surgery1173Indications / 1173Contraindications / 1173Mechanism of Action of Bariatric and Metabolic Surgery1175Overview / 1175Mechanisms of Bariatric Surgery (Weight Loss) / 1175Mechanisms of Metabolic Surgery (Diabetes Improvement) / 1177Preoperative Issues1177Preoperative Preparation / 1177Anesthesiology Issues / 1179Enhanced Recovery After Surgery / 1179Special Equipment and Infrastructure / 1180Bariatric Surgical Procedures1180Laparoscopic Roux-en-Y Gastric Bypass / 1180Laparoscopic Sleeve Gastrectomy / 1185Laparoscopic Adjustable Gastric Banding / 1187Biliopancreatic Diversion and Duodenal Switch / 1189Investigational Bariatric Procedures / 1190Follow-Up and Postoperative Care1191Results of Bariatric Surgery1192Short-Term Outcomes / 1192Effectiveness of Bariatric Surgery Compared to Nonsurgical Treatment / 1193Longer-Term Studies / 1193Other Studies / 1198Comparisons Between Procedures / 1199Resolution of Specific Comorbid Conditions / 1199Results of Surgery for Diabetes (Metabolic Surgery) / 1200Complications of Bariatric Surgery1203Surgical Complications / 1203Nonsurgical Complications / 1204Reoperative (Revision and Conversion) Bariatric Surgery1205Introduction / 1205Principles and Preoperative Evaluation / 1205Treatment for Insufficient Weight Loss or Weight Regain / 1206Treatment of Surgical Complications / 1206Special Issues in Bariatric Surgery1207Bariatric Procedures in Adolescents / 1207Cost Effectiveness / 1207Quality Assurance / 1207Plastic Surgery After Weight Loss / 1208Future Important Questions1209Brunicardi_Ch27_p1167-p1218.indd 116723/02/19 2:20 PM 1168JejunoilealBypassGastricBypassHorizontalGastroplastyAdjustable GastricBandingVertical BandedGastroplastyRoux-en-Y gastricBypassBPD with DuodenalSwitchBiliopancreaticDiversionSleeveGastrectomyMalabsorptiveRestrictiveBoth50s60s70s80s90sdisruptions was also problematic.7 Long-term weight loss was poor,8 and by the 1990s in the United States, Roux-en-Y gastric bypass (RYGB) became the procedure of choice for bariatric surgery.In the meantime, in Italy Scopinaro had developed and pop-ularized the biliopancreatic diversion (BPD) in the early 1980s.9 This procedure was also modified to include duodenal switch (DS),10 the only major malabsorptive operation currently in use.The laparoscopic approach to bariatric surgery became available in the 1990s, and Belachew performed the first laparo-scopic adjustable gastric banding (LAGB) operation in 1994.11 Wittgrove and Clark performed the first laparoscopic RYGB the same year.12 LAGB was commonly performed in Europe and Australia during the late 1990s, and in 2001 it was approved for use in the United States. Sleeve gastrectomy (SG) as a primary bariatric operation has grown rapidly in use since 2008.Figure 27-1. History of bariatric surgery. (Reproduced with permission from Arterburn DE, Courcoulas AP: Bariatric surgery for obesity and metabolic condi-tions in adults, BMJ. 2014 Aug 27;349:g3961.)Key Points1 Sixty-five percent of the world’s population live in countries where overweight and obesity are linked to more deaths than underweight and malnutrition. Obesity is the second leading cause of preventable death in adults in the United States.2 There is an ongoing major shift in procedure utilization with the sleeve gastrectomy and Roux-en-Y gastric bypass being the two most common procedures, worldwide.3 The former classification of bariatric operations as either “restrictive” or “malabsorptive” is being replaced by knowl-edge from investigation into the more basic physiologic and metabolic mechanisms responsible for the effects of bariatric surgery.4 Patients who develop a bowel obstruction after laparoscopic gastric bypass require surgical and not conservative therapy due to the high incidence of internal hernias and the potential for bowel infarction.5 Malabsorptive operations are highly effective in producing durable weight loss and metabolic improvements but have higher surgical complication rates and considerable nutri-tional side effects. Patients undergoing such procedures require complete follow-up and appropriate nutritional supplements.6 Large, longer-term observational studies of bariatric surgery have shown durable weight loss, diabetes remission, lipid improvements, and improved survival with bariatric surgery. Still unclear are specific preand postoperative predictors of those outcomes, long-term complications, microvascular and macrovascular events, mental health outcomes, and costs.7 High quality data have clearly established that bariatric pro-cedures are more effective than medical or lifestyle interven-tions for inducing weight loss and initial remission of type 2 diabetes, even in less obese patients. Randomized clinical trials showed greater weight loss and type 2 diabetes mellitus remission following bariatric surgery compared with nonsur-gical treatments.8 The incidence of complications after bariatric surgery varies from 4% to over 25% and depends on the duration of follow-up, the definition of complication used, the type of bariatric procedure performed, and individual patient characteristics.9 Emerging areas in bariatric surgery include the use of inter-mediate weight loss devices, adolescent bariatric surgery, and the increase in the need for revision and conversion bar-iatric procedures.Brunicardi_Ch27_p1167-p1218.indd 116823/02/19 2:20 PM 1169THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 2780p < 0.0017060Relative Procedure Utilization (%)504030201002006200720082009Year of Procedure2010201120122013Adjustable Gastric BandingRoux-en-Y Gastric BypassSleeve GastrectomyDuodenal SwitchFigure 27-2. Changes in bariatric procedure utilization. (Reproduced with permission from Reames BN, Finks JF, Bacal D, et al: Changes in bariatric surgery procedure use in Michigan, 2006-2013, JAMA. 2014 Sep 3;312(9):959-961.)State of the FieldThere has been an ongoing major shift in bariatric procedures both in the United States and worldwide13 with the rapid adop-tion of the laparoscopic sleeve gastrectomy and the simultane-ous decreasing utilization of the laparoscopic adjustable gastric banding procedure (Fig. 27-2). International trends in the utiliza-tion of bariatric surgical procedures have also been published. These show that the total number of bariatric surgical procedures performed in 2014 was 579,517. The three most commonly per-formed procedures in the world were SG at 46%, followed by RYGB (40%), and LAGB (7%). The annual percentage changes from 2013 show an increased utilization of SG and a decreased use of RYGB in the United States, Canada, Europe, and Asia and Pacific countries. In Central and South America, however, the use of SG decreased, and RYGB was most commonly used.14Extension of the indication from bariatric surgery for weight loss to metabolic surgery to treat type 2 diabetes (T2DM) even in patients with less than severe obesity has been another more recent development, driven by the availability of more level 1 data.15,16Also, considerable effort is now being devoted to the study of the basic physiologic mechanisms underlying weight loss and, perhaps more importantly, the resolution of comorbid medical problems associated with obesity. Despite the classic “restric-tive” and “malabsorptive” anatomic conceptualizations of bar-iatric surgical procedures (see Fig. 27-1), there is much ongoing research in animal and human models towards understanding the specific underlying mechanisms of action, which may be more physiologic in nature.17 Some of the potential candidates for the mechanisms of action of bariatric procedures include alterations in ghrelin, leptin, glucagon-like peptide-1 (GLP-1), cholecystokinin, peptide YY (PYY), gut microbiota, and bile acids. In the future, bariatric procedures will not be described by anatomic surgical similarities but by how they affect key physiological variables, which will provide greater mechanistic insight into how the procedures actually work.THE DISEASE OF OBESITYOverviewWorldwide obesity has more than doubled since 1980. In 2014, 39% of adults age 18 years and over (38% of men and 40% of women) were overweight, and 13% of the world’s adult population (11% of men and 15% of women) were obese. In 2014, an estimated 41 million children under the age of 5 years were overweight or obese.18 Overweight and obesity are now on the rise in lowand middle-income countries, particularly in urban settings. Currently, 65% of the world’s population live in countries where overweight and obesity are linked to more deaths than underweight and malnutrition. Obesity is the second leading cause of preventable death in adults in the United States, after tobacco use.19The degrees of obesity are defined by body mass index (BMI = weight [kg]/height [m]2), which correlates body weight with height. The World Health Organization international clas-sification of overweight and obesity is shown in Table 27-1. It should be noted that for Asian populations, classifications remain the same as the international classification, but the pub-lic health action points for interventions are set at a lower BMI threshold. For children, age needs to be considered when defin-ing overweight and obesity, so for children age 5 to 19 years, 1Table 27-1The international classification of adult overweight and obesity according to body mass index (BMI)CLASSIFICATIONBMI (kg/m2)PRINCIPAL CUTOFF POINTSADDITIONAL CUTOFF POINTSaNormal range 18.50–24.99 18.50–22.9923.00–24.99Overweight≥25.00≥25.00 Preobese 25.00–29.99 25.00–27.4927.50–29.99 Obese≥30.00≥30.00  Obese class I 30.00–34.99 30.00–32.4932.50–34.99  Obese class II 35.00–39.99 35.00–37.4937.50–39.99  Obese class III≥40.00≥40.00aFor Asian populations, classifications remain the same as the international classification, but public health action points for interventions are set at 23, 27.5, 32.5, and 37.5 kg/m.2Data from WHO, 1995, WHO, 2000 and WHO 2004.Brunicardi_Ch27_p1167-p1218.indd 116923/02/19 2:20 PM 1170SPECIFIC CONSIDERATIONSPART IIoverweight is BMI-for-age greater than 1 standard deviation above the World Health Organization (WHO) growth reference median, and obesity is greater than 2 standard deviations above the WHO growth reference median.The fundamental cause of obesity and overweight is an energy imbalance between calories consumed and calories expended. Globally, there has been an increased intake of energy-dense foods that are high in fat and a decrease in physi-cal inactivity due to the increasingly sedentary nature of many forms of work, changing modes of transportation, and increas-ing urbanization. These changes in dietary and physical activ-ity patterns are the result of both societal and environmental changes associated with development. There is also a dearth of supportive policies to counteract these forces in sectors such as health, agriculture, transport, urban planning, environment, food processing, marketing, and education. Obesity as a disease was recognized by the American Medical Association in 2013. It is multifactorial in its etiology, and the components of the disease likely include a combination of both environmental and genetic factors.U.S. Prevalence of ObesityAccording to the 2013–2014 National Health and Nutrition Examination Survey (NHANES) data, in the United States the overall age-adjusted prevalence of obesity was 37.7% (95% confidence interval [CI], 35.8–39.7%); among men, it was 35.0% (95% CI, 32.8–37.3%); and among women, it was 40.4% (95% CI, 37.6–43.3%). The corresponding prevalence of class III obesity overall was 7.7% (95% CI, 6.2–9.3%); among men, it was 5.5% (95% CI, 4.0–7.2%); and among women, it was 9.9% (95% CI, 7.5–12.3%). Changes over the decade from 2005 through 2014, adjusted for age, race, smoking status, and education, showed significantly increas-ing trends among women for overall obesity and for class III obesity, but not among men.20For children in the United States, obesity is defined as a BMI at or above the sex-specific 95th percentile, and extreme obesity is defined as a BMI at or above 120% of the sexspecific 95th percentile on the U.S. Centers for Disease Control and Prevention (CDC) BMI-for-age growth charts. In the most recent NHANES study of U.S. children and adolescents age 2 to 19 years, the prevalence of obesity from 2011 to 2014 was 17.0%, and extreme obesity was 5.8%.21Causes of ObesityBoth genetic and environmental factors contribute to the devel-opment of obesity. Not everyone exposed to the prevailing envi-ronment becomes obese, suggesting that genetic mechanisms are operating at the individual level. Estimates vary, but twin, family, and adoption studies show that the rate of heritability of BMI is high, ranging from 40% to 70%.22,23 Eleven rare and monogenic forms of obesity are now recognized, including a deficiency of the leptin and melanocortin-4 receptors, which are expressed in the hypothalamus and are involved in regulating energy homeostasis.24 Heterozygous mutations in the melano-cortin-4 receptor gene are currently the most common cause of monogenic obesity, causative in 2% to 5% of children with severe obesity.Genes and environment interact in a complex process that regulates energy balance and weight. Reducing food intake or increasing physical activity leads to a negative energy bal-ance and a cascade of compensatory adaptive mechanisms that preserve vital functions and are associated with reductions in resting energy expenditure, food preoccupation, and many other changes that depend on the amount and duration of caloric restriction. There is also a counterregulatory increase in appetite and food intake that limits the degree of expected weight loss that is associated with interventions such as exercise programs.22Individuals with obesity have excessive adipose cells, both in size and number. The number of such cells often is deter-mined early in life; adult-onset obesity is largely a product of increase in adipose cell size. Weight gain results from increase in both adipose cell size and number. Adipose tissue may be deposited in large quantities in the subcutaneous layer of the abdominal wall or the viscera. Generally, males tend to have central visceral fat distribution, whereas females more often have a peripheral fat distribution. Central or visceral fat distri-bution is associated with metabolic diseases such as diabetes, hypertension, and the metabolic syndrome.Concurrent Medical and Social ProblemsRaised BMI is a major risk factor for diseases such as cardio-vascular disease (mainly heart disease and stroke), which were the leading cause of death in 2012, diabetes, osteoarthritis, some cancers (including endometrial, breast, ovarian, prostate, liver, gallbladder, kidney, and colon).18 The risk for these conditions increases with increases in BMI. Childhood obesity is asso-ciated with a higher chance of obesity, premature death, and disability in adulthood. In addition to increased future risks, children with obesity experience sleep apnea, increased risk of fractures, hypertension, early markers of cardiovascular disease, insulin resistance, and psychological effects.The severely obese patient typically presents with multiple chronic and weight-related problems or comorbidities/comorbid conditions. These include degenerative joint disease, low back pain, hypertension, obstructive sleep apnea, gastroesophageal reflux disease (GERD), cholelithiasis, T2DM, dyslipidemia, asthma, hypoventilation syndrome of obesity, right-sided heart failure, migraine headaches, pseudotumor cerebri, venous stasis ulcers, deep venous thrombosis (DVT), fungal skin rashes, skin abscesses, stress urinary incontinence, infertility, dysmenorrhea, depression, and large abdominal wall hernias.There are anatomical, metabolic, and physiological effects of obesity through which this excess adiposity leads to disease risk factors and chronic diseases themselves (Fig. 27-3).22 Subcu-taneous adipose tissue holds most of the stored lipid at a variety of anatomical sites while visceral adipose tissue is a smaller storage compartment with omental and mesenteric fat mechanistically linked to some of the metabolic disturbances and adverse con-sequences outcomes associated with obesity.25,26 Adipose tissue surrounds and compresses the renal parenchyma and may contrib-ute to the hypertension frequently observed in patients who are obese.27 Obesity is frequently accompanied by an increase in pha-ryngeal soft tissues, which can lead to obstructive sleep apnea.28 Excess adiposity also imposes a significant mechanical load on joints, making it a risk factor for the development of osteoarthri-tis.29 An increase in intraabdominal pressure likely accounts for the elevated risks of gastroesophageal reflux disease (GERD), Barrett’s esophagus, and esophageal adenocarcinoma among those with obesity.30 Chronic overactivity of the sympathetic ner-vous system is present in some patients with obesity and may contribute to pathophysiological processes, including high blood pressure.27 Obesity is also associated with an increased preva-lence of mood, anxiety, and other psychiatric disorders, especially Brunicardi_Ch27_p1167-p1218.indd 117023/02/19 2:20 PM 1171THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27ä Adiposity˜ Lipid production˜ Activity ofthe sympatheticnervous system˜ Activity of therenin–angiotensin–aldosterone systemMechanical stress˜ Adipokine synthesis˜ Adipose tissuemacrophages and otherinflammatory cells˜ Proinflammatorycytokines˜ Pharyngealsoft tissue˜ Mechanicalload on joints˜ Intraabdominalpressure˜ InsulinType 2 diabetesNonalcoholicfatty liver diseaseSteatohepatitisCirrhosisCoronaryartery diseaseObstructivesleep apneaOsteoarthritisGastroesophagealreflux diseaseBarrett’s esophagusEsophagealadenocarcinomaCongestive heart failureStrokeChronic kidney diseaseImpaired insulinsignaling and˜ insulin resistanceLipotoxicityDyslipidemiaSystemic andpulmonaryhypertensionRenalcompressionHydrolysis oftriglyceridesRelease offree fatty acidsFigure 27-3. Pathways through which obesity leads to major risk factors and common chronic diseases. Common chronic diseases are shown in red boxes. The dashed arrows indicate an indirect association. (Reproduced with permission from Heymsfield SB, Wadden TA: Mechanisms, Pathophysiology, and Management of Obesity, N Engl J Med. 2017 Jan 19;376(3):254-266.)among persons with severe obesity and in those seeking bariatric surgery.31-33 Decreased quality of life also results due to severe obesity. Most patients seeking surgical treatment of severe obe-sity do so because of the medical issues they face from comorbid conditions or the decreased quality of life they are experiencing as a result of severe obesity.MEDICAL MANAGEMENT OF OBESITYTreatments should be aligned with the severity of obesity, asso-ciated comorbid conditions, and the individual’s functional limitations. There are guidelines available to evaluate an indi-vidual’s health risks and potential treatment options.34,35 Three main treatment options exist with sufficient evidence-based support: lifestyle intervention, pharmacotherapy, and bariatric surgery.Lifestyle InterventionLifestyle interventions designed to modify eating behaviors and physical activity are the first option for weight manage-ment, given their low cost and low risk.35 Behavioral therapy, the core of any lifestyle intervention, provides patients with techniques for adopting dietary and activity recommendations. Among these recommendations are regular recording of food intake, physical activity, and weight. Patients review their progress approximately weekly with a trained interventionist Brunicardi_Ch27_p1167-p1218.indd 117123/02/19 2:20 PM 1172SPECIFIC CONSIDERATIONSPART II01020304050Percentage of Participants6070809010010%5%High-lntensityLifestyleInterventionPharmacotherapyInterventionLook AHEADDPPTeixeira, et aI.PlaceboOrlistatLorcaserinLiraglutidePhentermine-topiramateNaltrexone-bupropionFigure 27-4. 22Percent weight loss at 1 year with intensive lifestyle interventions or pharmacotherapy combined with lower level lifestyle. Shown are the percentages of participants in randomized, controlled trials who had weight loss of at least 5% or at least 10% of their initial weight at 1 year after intensive lifestyle intervention or pharmacotherapy that typically was combined with lower-intensity lifestyle. Percentages shown are cumulative; the percentage of participants who lost at least 5% of their initial weight includes the percentage who lost at least 10%. Additional data on the percentage of participants with weight loss at 1 year of at least 15% of their initial weight were available for the Look AHEAD36 study (16%), the DPP39 trial (11%), liraglutide40 (14%), phentermine–topiramate (32%), and naltrexone–bupropion (14%). (Reproduced with permis-sion from Heymsfield SB, Wadden TA: Mechanisms, Pathophysiology, and Management of Obesity, N Engl J Med. 2017 Jan 19;376(3):254-266.)who provides support and encouragement, help setting goals, and problem-solving instructions.35 This type of comprehen-sive program results in a mean weight loss of 5% to 8%, and approximately 60% to 65% of patients lose 5% or more of initial weight. The Look AHEAD study randomized 5145 adults with obesity to either an intensive lifestyle intervention (ILI) or to a diabetes support group and education group (DSE) to assess the impact on weight loss, T2DM, and cardiovascular outcomes. At 1 year, the intensive intervention group lost an average of 8.6% initial weight compared to 0.7% in the support and educa-tion group. As shown in Fig. 27-4, 68% of participants in the Look AHEAD study lost at least 5% of their initial weight, and 37% of these participants lost at least 10%. Also at 1 year, par-ticipants undergoing the more intensive program experienced improved cardiovascular risk factors and glycemic control.36At 4 years, participants in the intensive intervention group experienced more weight loss (−6.15% ILI compared to −0.88% DSE), better glycemic control, fitness, and an improvement in cardiovascular risk factors.37 Nevertheless, the beneficial clinical effects of the improved weight loss achieved with intensive lifestyle intervention did not reduce morbidity and mortality associated with cardiovascular disease after 9.6 years when the Look AHEAD study was stopped due to futility for that primary endpoint.38 Figure 27-4 shows a comparison of several lifestyle intervention trials (Look AHEAD, the Diabetes Prevention Program [DPP] trial,39 and the trial reported by Teixeira et al40) for >5% and >10% weight loss outcomes. These trials, specifically, were selected because they were judged to be good quality by the Guidelines (2013) for the Management of Overweight and Obesity in Adults and because the trial data were reported as categorical weight loss. Categorical weight loss data from the DPP trial were provided by the DPP Research Group to the authors of the review.22In summary, multidisciplinary lifestyle intervention and weight-management programs are viable and potentially cost-effective treatment options in overweight or obese patients with or without T2DM. Such approaches, however, often fail to achieve durable weight loss of more than 5% to 10%, so they are not effective enough for the severely obese. Importantly, lifestyle and medical approaches do not appear to improve car-diovascular outcomes in studies so far. Thus, further research is needed to evaluate the role for current medical and lifestyle therapeutic regimens for obesity and T2DM, including compari-sons to surgical interventions. Certainly, and at the very least, these approaches are important adjuncts to bariatric surgery.PharmacotherapyMedications may be considered as an adjunct to lifestyle modi-fication in adults who have a BMI of 30 or higher or a BMI of 27 to 29 with at least one obesity-related condition.41 Phar-macotherapy and lifestyle intervention together lead to addi-tive weight losses and should be used together and may also be helpful in facilitating the maintenance of reduced weight.34,41,42 Phentermine, the most widely prescribed weight-management medication in the United States, is a sympathomimetic amine that was approved by the FDA in 1959 for short-term use of fewer than 3 months long.41 There are now five newer FDA-approved medications for long-term weight management that include three single drugs and two combination drugs. In 1-year pivotal trials, total weight losses for the three single therapies (orlistat, lorcaserin, and liraglutide), the effects of which are mediated by different mechanisms, ranged from 5.8% to 8.8% of initial body weight.41,43-45 The two combination medications (phentermine–topiramate and naltrexone–bupropion) include drugs that act on neural weight-loss mechanisms.46,47 In 1-year pivotal trials, total weight loss for these combination drugs ranged from 6.4% to 9.8% of initial body weight.These medications, when prescribed with lifestyle inter-ventions, produce additional weight loss relative to placebo ranging from approximately 3% of initial weight for orlistat and lorcaserin to 9% for the higher-dose phentermine plus topi-ramate–extended release at 1 year. The proportion of patients achieving clinically meaningful (at least 5%) weight loss ranges from 37% to 47% for lorcaserin, 35% to 73% for orlistat, and 67% to 70% for higher-dose phentermine plus topiramate–extended release. All three of these medications produce greater improvements in cardiometabolic risk factors than placebo, Brunicardi_Ch27_p1167-p1218.indd 117223/02/19 2:20 PM 1173THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27but none has been shown to reduce cardiovascular morbid-ity or mortality. There is limited data for the long-term safety and efficacy of these medications, and some of these drugs may increase heart rate43 or attenuate expected blood pressure reductions.47 In addition, completed trials of hard cardiovascular disease outcomes (heart attack and stroke) in patients treated with these medications have yet to be published, except in the case of liraglutide.43 Figure 27-4 shows a comparison of weight loss outcomes for these medications. The median percentages of participants who had a weight loss of at least 5% or 10% with each of five medications approved for long-term weight man-agement are from a meta-analysis by Khera et al.48In summary, medications approved for long-term obesity treatment, when used as an adjunct to lifestyle intervention, lead to greater mean weight loss and an increased likelihood of achieving clinically meaningful 1-year weight loss compared to placebo.42 Yet weight loss medications are underutilized, likely due to several factors. First, patients are often disappointed by moderate weight loss. Second, there are requirements to pay a substantial portion of costs, which may lead to short-term rather than longer-term use. Third, there remain concerns about medi-cation safety. Finally, weight regain is common after termina-tion of drug treatment, which is discouraging to both patients and their providers.22,42Barriers to TreatmentOnly a small fraction of patients for whom these medical treat-ments or bariatric surgery are indicated actually pursue and receive them. Past studies have estimated that 1% or fewer of those people with severe obesity who could consider bariatric surgery ever do so. Barriers to general obesity care include the slow recognition among providers that obesity requires long-term management, inadequate physician training in nutrition and obesity, limited reimbursement for the full range of treat-ments, lack of more effective and accessible lifestyle programs, and limited referrals of patients with severe obesity to expe-rienced surgeons.22 Lack of knowledge about the more recent outcomes of bariatric surgery may also play a contributing role.CANDIDATES FOR BARIATRIC SURGERYIndicationsThere has been significant procedure evolution over the last several years indicating an ongoing major shift in bariatric procedures both in the United States and worldwide13 (Fig. 27-5). According to a 2016 report from the American Society of Metabolic and Bariatric Surgery (ASMBS), the two most common procedures in the United States are RYGB and SG, accounting for approximately 25% to 30% and 50% to 60%, respectively, of annual cases.49,50 The utilization of LAGB has declined dramatically to under 10% of cases, and the malabsorptive procedure BPD with or without DS is utilized in less than 1% to 2% of cases (see Fig. 27-2). All of these procedures were defined by the Centers for Medicare & Medicaid Services (CMS) as standard approved procedures, noting that SG coverage is based on the discretion of regional carriers throughout the United States.The indications for performing bariatric surgery in class II and class III obesity still remain as described in the National Institutes of Health (NIH) Consensus Conference of 1991, and a summary of the broad selection criteria are shown in Table 27-2.51 In 2016, the second Diabetes Surgery Summit (DSS-II) published guidelines indicating that metabolic surgery 2should also be considered for patients with T2DM and BMI of 30 to 34.9 kg/m2 (class I obesity) if blood sugar is inadequately controlled despite optimal medication treatment.16 In addition, these guidelines recommended that the BMI threshold for metabolic surgery (surgery for diabetes as the indication) should be reduced by 2.5 kg/m2 for Asian populations at risk.The NIH criteria for bariatric surgery do not set guidelines or limits for age, and surgical practice varies widely. The pediatric obesity epidemic is both increasing and also driving the adult epidemic, and a growing proportion of younger patients are potentially eligible for bariatric surgery. For young patients, there are concerns about assent to surgery and compliance with and adherence to postoperative lifestyle changes, but there are also some emerging data that suggest intervening earlier in the disease process may lead to improved reversal of comorbid conditions compared to adults.52 In addition, there is a longer period of postoperative benefit in terms of improved quality of life and prevention of or reduction in the emotional, social, and physical consequences of obesity (see “Bariatric Procedures in Adolescents”). Alternatively, older patients are more likely to have more numerous and debilitating comorbid conditions and thus have an immediate benefit in quality of life but not necessarily enhanced longevity. There is also some concern that recovery from potential complications is impaired in patients over the age of 65. Most studies in older patients have focused on RYGB and older restrictive procedures with limited follow-up. The results of more recent studies in older patients are generally equivocal in terms of any increased risk of morbidity and mortality or any difference in weight outcomes compared to younger adults.53-55 One study has shown that the older patient population, especially those few patients older than age 70 undergoing bariatric surgery, did have an increased risk of mortality and morbidity after RYGB.56 Also, a 2016 study from the Utah Obesity group found that RYGB is protective against mortality even for older patients and also reduces the age-related increase in mortality observed in severely obese individuals not undergoing surgery.57ContraindicationsMedical issues that preclude patients from being good surgi-cal candidates include American Society of Anesthesiologists (ASA) class IV disease of a nature that makes surgical therapy extraordinarily high risk. Psychological instability or the inabil-ity to understand the implications of the proposed operation and what changes will result from it in terms of the patient’s life-style are also contraindications. Known and documented active drug or alcohol addiction is a contraindication to surgery (see Table 27-2). Tobacco use should be completely avoided by bar-iatric patients at all times, and smoking cessation should occur 6 weeks prior to surgery. After surgery smoking increases risks of poor wound healing, anastomotic ulcers, and impaired health.58 A poorly controlled eating disorder, especially bulimia, is also a contraindication to surgery. Nonambulatory status is a relative contraindication to surgery and is associated with increased sur-gical risk,59 especially if the obesity is so severe that the patient cannot normally do self-care or would not likely be able to do so after surgery. In addition to excessive morbidity, the placement of these individuals in care facilities postoperatively for recovery is often impossible due to their size and limitations of physical ability. Finally, lack of sufficient social support or an extremely poor or unsupportive home environment can be contraindications to surgical care, since such environmental factors are important to optimize outcomes once discharged from the hospital.Brunicardi_Ch27_p1167-p1218.indd 117323/02/19 2:20 PM 1174SPECIFIC CONSIDERATIONSPART IIABCDEFGHFigure 27-5. Bariatric surgery procedure evolution. A. Horizontal gastroplasty; B. vertical banded gastroplasty; C. Roux-en-Y gastric bypass; D. transected Roux-en-Y gastric bypass; E. laparoscopic adjustable gastric band; F. biliopancreatic diversion; G. biliopancreatic diversion with duodenal switch; H. vertical sleeve gastrectomy. (Modified with permission from Arterburn DE, Courcoulas AP: Bariatric surgery for obesity and metabolic conditions in adults, BMJ. 2014 Aug 27;349:g3961.)Brunicardi_Ch27_p1167-p1218.indd 117423/02/19 2:20 PM 1175THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27Table 27-2Patient selection criteria for bariatric surgeryFACTORCRITERIAWeight (adults)BMI ≥40 kg/m2 with no comorbid conditionsBMI ≥35 kg/m2 with obesity-associated comorbidityWeight loss historyFailure of previous nonsurgical attempts at weight reduction, including nonprofessional programsCommitmentExpectation that patient will adhere to postoperative careFollow-up visits with physician(s) and team membersRecommended medical management, including use of dietary supplementsInstructions regarding any recommended procedures or testsContraindications/exclusionsProhibitive surgical risk, ASA IVReversible endocrine or other disorders that can cause obesityCurrent drug or alcohol misuseUncontrolled, severe psychiatric illnessUncontrolled, severe bulimiaLack of comprehension of risks, benefits, expected outcomes, alternatives, and lifestyle changesData from Mechanick JI, Youdim A, Jones DB, et al: Clinical practice guidelines for the perioperative nutritional, metabolic, and nonsurgical support of the bariatric surgery patient—2013 update: cosponsored by American Association of Clinical Endocrinologists, The Obesity Society, and American Society for Metabolic & Bariatric Surgery, Obesity (Silver Spring). 2013 Mar;21 Suppl 1:S1-S27.MECHANISM OF ACTION OF BARIATRIC AND METABOLIC SURGERYOverviewThere is not yet a clear understanding as to how various bariatric procedures exert their effects on weight loss, metabolism, and glycemic control. Much effort is currently being devoted to gaining a better understanding of these specific mechanisms. A review of what is known from published animal and human studies about mechanisms related the three most common surgical proce-dures is shown in Fig. 27-6.17 A few interim, summary statements can be drawn from this available data. First, neither LRYGB nor SG can be thought of as primarily “restrictive procedures,” and there are changes in behavior and physiology that likely help to maintain the new reduced body weight that are not observed after nonsurgically induced weight loss. LAGB appears to be more dependent on gastric restriction as both the behavioral changes and changes in gut hormone secretion are much less dramatic. Second, both LRYGB and SG are associated with metabolic improvements that are different from those that are caused by weight loss alone, and these mechanisms remain under current active study. For LAGB, the metabolic effects are mostly due to the impact of the resulting weight loss. This growing understanding of the physiol-ogy of these procedures points away from the older, classic 3anatomic classifications of “restrictive” versus “malabsorptive” procedures. This new conceptual approach has important implica-tions for future studies of how bariatric surgery exerts its effects. Earlier hypotheses for the mechanism of action of LRYGB have been classified into either the “foregut hypothesis” or “hindgut hypothesis.”60 The foregut hypothesis states that improvements after LRYGB come from the bypassing of the upper small intestine that results in the reduction of nutrient-dependent hormonal actions that would normally impair glucose tolerance.61 The hindgut hypothesis states instead that the key events are the result of more rapid delivery of nutrients to the distal small intestine causing effects such as increased GLP-1/PYY secretion and the ileal brake.62 Now, the more recently recognized and common metabolic effects of SG and LRYGB may indicate directions for study away from this foregut/hindgut distinction, as the SG does not bypass the foregut or induce nutrients further down in the intestine.Mechanisms of Bariatric Surgery (Weight Loss)Certainly, one component mechanism by which RYGB pro-duces weight loss is related to reduced caloric intake and malab-sorption brought about by a smaller gastric volume and bypass of the proximal small bowel, so weight loss following LAGB and SG may be explained, at least in part and early on, by gas-tric restriction63 and resulting reduced food intake. Aside from anatomic changes induced by surgery, there are also changes in physiology that may affect food preferences and energy expen-diture. Gastric emptying and insulin sensitivity increases follow-ing RYGB and SG.63 Functional magnetic resonance imaging has demonstrated a decreased neuronal activation of the food reward-related centers in response to high-calorie foods follow-ing RYGB.64 Neural signaling may be altered and stretch sensi-tive vagal endings in the new pouch and Roux limb, resulting in a feeling of early satiety.65 Hormonal changes are also evi-dent, and in a number of studies looking at the effect of RYGB on ghrelin levels, results are conflicting. Changes in intestinal microbiota is another area of active study.66 Individuals with obesity have different gut flora compared to nonobese subjects. The Firmicutes (mainly Lactobacillus and Clostridium species) to Bacteroidetes ratio (Bacteroides or Prevotella species) is elevated in obese subjects. Following gastric bypass, the Fir-micutes group decrease while Bacteroides/Prevotella increase at 3 and 6 months intervals.67 Bacteria transplant provides some of the benefits of gastric bypass surgery without the surgery.68 It has also been shown that administering oral lactobacillus post-RYGB leads to increased weight loss; this indicates benefits of changing gut microbiota to induce weight loss.69Serum bile acid levels also increase following gastric bypass.70 Gastric bypass diverts undiluted bile acids to the distal bowel. Bile acids activate protein-coupled receptor TGR5 pres-ent in L cells responsible for GLP-1 secretion. They also activate FXR (farsenoid-X receptor) in the jejunum, which regulates lipid and glucose metabolism.71 Furthermore, bile acids lead to rapid clearance of triglycerides.72 Bariatric surgery alters bile acid enterohepatic circulation in favor of weight loss and resolution of nonalcoholic steatohepatitis (NASH).73 Ryan et al demonstrated in a study on mice that the therapeutic value of SG is not limited to mechanical restriction but to an increase in circulating bile acids and associated changes to gut microbiota.74 Hollanda et al studied two cohorts of patients: those who lost more than 50% of their excess weight compared to those who did not. This group suggested that ghrelin and GLP-1 may be mediators of success-ful weight loss as those levels increased, while PYY and GLP-2, Brunicardi_Ch27_p1167-p1218.indd 117523/02/19 2:20 PM 1176SPECIFIC CONSIDERATIONSPART IILRYGBLAGBSGLipidElevated HDLReduced triglyceridesReduced total cholesterol, LDLElevated HDLReduction in triglycerides not as dramatic as LRYGB or SGElevated HDLReduced triglyceridesGlucose homeostasisImproved fasting blood glucose and insulin sensitivity, prior to weight lossImprovements are slower and not as dramatic as after SG or LRYGBImproved fasting blood glucose and insulin sensitivity, prior to weight lossRole of gastric restrictionHas not yet been directly testedFailure of band leads to less gastric restriction and less weight lossGastric restriction is not the critical factor preventing hyperphagiaGastric emptyingFew published studiesNo overall change in gastric emptying rate; Emptying rate of proximal pouch created by band is enhancedMost papers show increaseEnergy expenditureControversialNot reportedUnchanged, but only reported in one studyLeptinCirculating leptin levels lower than expected for body weightChanges to leptin sensitivity not testedPlasma leptin reduced, as expected for body weight; Changes to leptin sensitivity not testedCirculating leptin levels lower than expected for body weight; Body weight changes not driven by changes to leptin sensitivityGhrelinReduced total ghrelin; Controversial, but no change in acyl-ghrelin levelsIncreased circulating ghrelinReduced total ghrelin; Contro-versial, but no change in acyl-ghrelin levelsCCKNo changeNo changeNot measuredGLP=1 (postprandial)Weight loss-independent postprandial increaseIncreased circulating GLP-1 but much less than RYGB or SGWeight loss-independent increase comparable to LRYGBPYY (postprandial)Increased postprandial PYY levels; Reduced body weight loss in PYY knockout miceNo changeIncreased postprandial PYY levels, comparable to levels after LRYGBBile acidsIncreased plasma bile acidsNot reportedIncreased plasma bile acidsDiet changeDecreased fat intake, more fruits and vegetablesDecrease bread intake and increase in caloric liquids; Greater fat intake and fewer fruits/vegetables than RYGBDecreased fat intake, similar to LRYGBFood IntoleranceSome dumping syndrome, usually well-tolerated More persistent and problematic than LRYGB; Mainly vomitingLittle or noneFigure 27-6. Mechanisms of effect: comparison of LRYGB, LAGB, and SG. (Reproduced with permission from Stefater MA, Wilson-Pérez HE, Chambers AP, et al: All bariatric surgeries are not created equal: insights from mechanistic comparisons, Endocr Rev. 2012 Aug;33(4):595-622.)Brunicardi_Ch27_p1167-p1218.indd 117623/02/19 2:20 PM 1177THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27gut mass and hypertrophy (citrulline), and the bile acid effect on fibroblast growth factor-19 (FGF-19) appear to have no effect on weight loss.75 In summary, there exists a complex relationship between dietary changes, bile flow changes, altered hormonal milieu and the gut microbiota that is not yet completely well characterized as it relates to weight loss after bariatric surgery.Mechanisms of Metabolic Surgery (Diabetes Improvement)Understanding the basic mechanism(s) of diabetes improvement following bariatric surgery is an important area of intensive study. Recently published data on worldwide trends in diabetes indicate that the number of adults with diabetes has increased from 108 million in 1980 to 422 million in 2014,76 the major-ity with T2DM. In the United States, diabetes is the number two cause of hospitalizations in adults age 18 years or older, accounting for approximately 11% of all hospital admissions. With no medical cure, the natural course of diabetes is charac-terized by progressive β-cell failure and development of micro-vascular and macrovascular complications, leading to renal failure, blindness, amputation, and death due to cardiovascular disease (CVD). Bariatric surgery has been renamed metabolic surgery for T2DM treatment and has emerged as an effective tool for control of hyperglycemia.77-86More than 20 years ago Pories et al found that bariatric surgery rapidly normalized blood glucose levels in people with obesity and T2DM, and 10 years later the majority remained dis-ease free.87 He suggested that caloric restriction played a role but that there were likely other factors such as proximal intestinal nutrient exclusion, rapid distal gut nutrient delivery, and the role of gut hormones that would require further investigation. The findings of T2DM improvement and remission after bariatric surgery have now been widely replicated by others, and there is evidence that bariatric surgery prevents or delays incident cases of T2DM. Much work has been done to investigate these spe-cific physiological mechanisms underlying the beneficial gly-cemic effects of bariatric surgery, but they remain incompletely understood. Candidate hypotheses include changes in bile acid metabolism, nutrient sensing and glucose utilization, intestinal adaptation, incretins, possible anti-incretin(s), and the intestinal microbiome. These physiologic and molecular changes lead to reduced hepatic glucose production, increased glucose uptake in tissues, improved insulin sensitivity, and enhanced β-cell func-tion. A schematic of these potential mechanisms of improved glycemic control is shown in Fig. 27-7.It is likely that several of these individual factors, acting together and with different impact based on the specific surgical pro-cedure, are responsible for postoperative glycemic improvement. Work in this area is actively ongoing, and genomic, metabolomic, and gut microbiome studies will likely enhance the understanding of these changes. This may potentially lead to identifying novel pathways and potential therapeutic targets to replace bariatric pro-cedures by equally effective, but less invasive, new treatments for obesity-related T2DM. In other words, understanding mechanisms of glycemic improvement after bariatric surgery may allow for the development of treatments to “bypass the bypass.”88PREOPERATIVE ISSUESPreoperative PreparationPatient selection for surgery should be based on a multidisci-plinary team approach. All patients should undergo preoperative evaluation for obesity-related comorbidities and causes of obe-sity, with special attention directed to factors that could affect candidacy for bariatric surgery89 (Table 27-3).The preoperative assessment of the patient for bariatric surgery must include input from the nutritionist as an important independent evaluation. Careful assessment of the patient’s eat-ing habits, knowledge, self-awareness, and insight are important. An estimation of the patient’s motivation to change eating habits is important. The nutritionist should have at least one assessment session with the patient and an educational session preoperatively once the decision to proceed with surgery has been determined. The operation to be performed requires specific nutritional counseling and education. Psychological assessment is required by most programs and many insurance carriers with a goal of identifying potential contraindications to surgical intervention, such as poorly controlled psychiatric illness or active substance abuse, and identifying strategies to help with long-term weight management.90 There are published recommendations regarding the content of a mental health evaluation for bariatric surgery,91-93 but no consensus guidelines have been published. These evalua-tions are carried out by interview and questionnaires, which rely on clinical interviews including tests of personality or psycho-pathological conditions.94 More comprehensive evaluations also assess bariatric surgery knowledge, weight history, lifestyle hab-its, and potential barriers.91,92 Psychological assessment in clinical practice may be inaccurate compared to independent evaluations for research purposes, as patients present themselves in the most favorable light in order to gain access to surgery.95Obstructive sleep apnea (OSA) is prevalent in over 90% of bariatric surgery candidates with approximately one-third undiagnosed.96-101 The Epworth Sleepiness Scale, a standard set of questions evaluating daytime sleepiness, is often used as a screening tool for OSA.38 As OSA is associated with increased risk of mortality102 (and in bariatric surgery patients, with adverse outcomes),59 routine preoperative screening with polysomnog-raphy should be considered.103 In addition, standard preopera-tive management of obese patients with OSA using continuous positive airway pressure (CPAP) is recommended.104 Asthma and hypoventilation syndrome of obesity are other significant pulmonary diseases often requiring preoperative management. Hypoventilation syndrome of obesity is defined as resting arte-rial partial pressure of oxygen less than 55 mmHg and partial pressure of carbon dioxide greater than 47 mmHg, with accom-panying pulmonary hypertension and polycythemia. Pulmonary consultation is indicated for patients with hypoventilation syn-drome. Postoperative intensive care unit hospitalization, rarely used after bariatric surgery, may be indicated for these patients.Preoperative weight loss can reduce liver volume/size and may help improve the technical aspects of surgery in those people with extreme central obesity and an enlarged liver, and it is sometimes utilized as a practice-specific recommendation or requirement. Ten percent total body weight loss (TBWL) with energy-restricted diets has been associated with a reduction in hepatic volume,105 variable perceived and measured improved facility in operative technique,106,107 variable effects on short-term108-112 complication rates, and weight loss. Cirrhosis113 has been associated with poor outcomes following bariatric surgery, including progression to liver transplantation.114Preoperative glycemic control should be optimized using diet, physical activity, and medications, as needed. Reasonable targets for preoperative glycemic control include a hemoglo-bin A1c value of 6.5% to 7.0% or less, a fasting blood glucose Brunicardi_Ch27_p1167-p1218.indd 117723/02/19 2:20 PM 1178SPECIFIC CONSIDERATIONSPART IIlevel of ≤110 mg/dL, and a 2-hour postprandial blood glucose concentration of ≤140 mg/dL.115 More liberal preoperative targets with higher A1c should be considered in patients with advanced comorbid conditions or long-standing diabetes where lower targets are not attainable. For patients with active GERD on medication, a preoperative screening upper endoscopy to rule out Barrett’s esophagus and to rule out intrinsic lesions of the stomach or duodenum is recommended. This is especially true for patients planning LRYGB, where the distal stomach and duodenum will be precluded from easy inspection postop-eratively. In addition, the presence of Barrett’s esophagus is a contraindication to SG, which is a reflux-inducing operation. The presence of a hiatal hernia detected on preoperative esoph-agogastroduodenoscopy will alert the surgeon for the need to perform intraoperative repair.Patients with a history of DVT or cor pulmonale should undergo a diagnostic evaluation for DVT. A prophylactic vena caval filter may present a greater risk than benefit in patients A Immediate impact of surgeryB Potential mediators/mechanismsC Effect on glucose homeostasisCaloric restritctionImproved ˜-cell function/functional ˜-cell massAltered bile acid/ FGF-19 signalingReduced hepatic and pancreatic triglyceridesRYGBRYGBSGReduced hepatic glucose productionIncreased glucose utilizationIncreased glucose effectivenessImproved insulin sensitivityAltered microbiomeReduced glucotoxicityWeight lossAltered GI nutrient-sensingAltered gut hormonesAltered neural signalingRapid emptying of nutrients into the small intestineIntestinal adaptation/Reprogramming of intestinal glucoseRYGBSGEnhanced nutrient/bile delivery to the mid/distal jejunum and ileumRYGBSGSGExclusion of the duodenum and proximal jejunum and ileumRYGBRemoval of the stomach fundusSGFigure 27-7. Schematic of potential mechanisms of improved glycemic control after LRYGB and SG. A. Immediate effects of RYGB and SG due to anatomical changes. B. Potential mediators/mechanisms involved. Cross talk occurs among these factors. C. Effects on glucose homeostasis. (Reproduced with permission from Batterham RL, Cummings DE: Mechanisms of Diabetes Improvement Following Bariatric/Metabolic Surgery, Diabetes Care. 2016 Jun;39(6):893-901.)Brunicardi_Ch27_p1167-p1218.indd 117823/02/19 2:20 PM 1179THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27with a history of prior pulmonary embolism (PE) or DVT given the risks of filter-related complications including thrombosis. The overall risk of venous thromboembolism (VTE) after sur-gery is 0.42%, and over 70% of these events occur after hospital discharge, most within 30 days after surgery.116 The risk of VTE is greater in patients undergoing RYGB than in those undergoing LAGB and is more frequent following open surgery. Patients with a VTE event tend to be male, older, and have higher BMIs; they are also more likely to have a history of VTE.116 The risk of VTE is greater in patients with an inferior vena cava filter (hazard ratio [HR] 7.66, 95% CI 4.55–12.91),116 and there is evidence suggest-ing that prophylactic inferior vena caval (IVC) filter placement before bariatric surgery does not prevent PE and may lead to addi-tional morbidity, which may outweigh its use.117,118Candidates for bariatric surgery should avoid pregnancy preoperatively and for 12 to 18 months postoperatively and Table 27-3Preoperative checklist for bariatric surgery• Complete for History & Physical (H&P) (obesity-related comorbidities, causes of obesity, weight/BMI, weight loss history, commitment, and exclusions related to surgical risk)• Routine labs (including fasting blood glucose and lipid panel, kidney function, liver profile, lipid profile, urine analysis, prothrombin time/INR, blood type, CBC)• Nutrient screening with iron studies, B12 and folic acid (RBC folate, homocysteine, methylmalonic acid optional), and 25-vitamin D (vitamins A and E optional); consider more extensive testing in patients undergoing malabsorptive procedures based on symptoms and risks• Cardiopulmonary evaluation with sleep apnea screening (ECG, CXR, echocardiography if cardiac disease or pulmonary hypertension suspected; DVT evaluation if clinically indicated)• GI evaluation (H pylori screening in high-prevalence areas; gallbladder evaluation and upper endoscopy if clinically indicated)• Endocrine evaluation (A1c with suspected or diagnosed prediabetes or diabetes); TSH with symptoms or increased risk of thyroid disease; androgens with PCOS suspicion (total/bioavailable testosterone, DHEAS, D4-androstenedione); screening for Cushing’s syndrome if clinically suspected (1 mg overnight dexamethasone test, 24-hour urinary free cortisol, 11 PM salivary cortisol)• Clinical nutrition evaluation by registered dietician• Psychosocial-behavioral evaluation• Document medical necessity for bariatric surgery• Informed consent• Provide relevant financial information• Continue efforts for preoperative weight loss• Optimize glycemic control• Pregnancy counseling• Smoking cessation counseling• Verify cancer screening by primary care physicianReproduced with permission from Mechanick JI, Youdim A, Jones DB, et al: Clinical practice guidelines for the perioperative nutritional, metabolic, and nonsurgical support of the bariatric surgery patient—2013 update: cosponsored by American Association of Clinical Endocrinologists, The Obesity Society, and American Society for Metabolic & Bariatric Surgery, Obesity (Silver Spring). 2013 Mar;21 Suppl 1:S1-S27.women who become pregnant after bariatric surgery should be counseled and monitored for appropriate weight gain, nutri-tional supplementation, and for fetal health.119 All women of reproductive age should be counseled on contraceptive choices following bariatric surgery as utilization, absorption, and effec-tiveness are inconsistent.120,121 Patients should be provided with educational materials and access to preoperative educational sessions. Multimedia tools for patient education and consent show promise for improving understanding.122-124 There should be a thorough and dynamic consent discussion regarding the risks and benefits, procedural options, and the need for long-term follow-up and vitamin supplementation (including costs required to maintain appropriate follow-up). Consent should include the experience of the surgeon with the specific proce-dure and whether the program participates in national quality improvement initiatives and certification.Anesthesiology IssuesTwo major challenges that face the anesthesiologist when per-forming a general anesthetic for the severely obese patient are vascular access and airway management. Fiberoptic laryngos-copy is often used for the most difficult class IV or even class III airways should standard laryngoscopy be determined to provide an inadequate view. Videotelescopic intubation systems are suc-cessfully used as well. Significant preoxygenation for 3 minutes or longer prior to intubation is used for the severely obese patient to provide a longer safe duration for intubation should difficul-ties be encountered. However, desaturation must be immediately addressed with reestablishment of oxygenated ventilation because this patient group does not tolerate any prolonged desaturation without potential adverse cardiopulmonary consequences.The anesthesiologist must also manage alterations in car-diopulmonary function from the use of a pneumoperitoneum during laparoscopic bariatric procedures. These include the effects of carbon dioxide absorption on required minute venti-lation, the potential for bradyarrhythmias, and the potential for decreased systemic pH with longer procedures in patients with preexisting cardiopulmonary disease. Arterial monitoring of the latter group of patients may be necessary by the anesthesiology team, and a radial arterial line is standard for such patients.125 Drug pharmacokinetics differ in severely obese patients as well. Changes in volume of distribution include smaller-than-normal fraction of total body water, greater adipose tissue content, altered protein binding, and increased blood volume. Possible changes in renal function and hepatic function must be consid-ered when administering drugs. Specific anesthetic drug meta-bolic alterations in the severely obese include a larger volume distribution of thiopentone, resulting in a prolonged effect of the drug. Calculation of the dosage should be done by lean body weight. Benzodiazepines also exhibit a prolonged elimination phase, causing prolongation of their effects. Increased pseudo-cholinesterase activity is present in the severely obese patient, requiring increased dosages of pancuronium. Enflurane metab-olism is increased over the average-sized person, requiring a lower dosage of this agent.Enhanced Recovery After SurgeryEnhanced recovery after surgery (ERAS) protocols have been initiated in bariatric surgery and have demonstrated promise to decrease surgical morbidity. Additionally, a recent meta-analy-sis has identified a significant decrease in length of stay (stan-dard mean difference = −2.40 [−33.89, −0.89], P = 0.002).126 In 2016, the ERAS Society published evidence-based guidelines Brunicardi_Ch27_p1167-p1218.indd 117923/02/19 2:20 PM 1180SPECIFIC CONSIDERATIONSPART IIfor perioperative care in bariatric surgery.127 The guidelines include recommendations in preoperative, intraoperative, and postoperative care. These include shorter acting and lower absorption anesthetic agents and opioid minimization as impor-tant intraoperative recommendations.Special Equipment and InfrastructureThe special needs of the bariatric patient and program extend from the entry to the hospital and clinic, to the operating room, and throughout the inpatient and outpatient experience. The program needs infrastructure and support at all levels including support staff, physicians and surgeons, administrators, program directors, psychologists, and nutritionists. The physical plant needs to include extra-wide doorways, special seating, a scale that weighs up to 800 lb (363 kg), larger patient gowns, large blood pressure cuffs, and floor-mounted toilets. In the operat-ing room, the table must accommodate 600 to 800 lb (272 to 363 kg) and must position in steep reverse Trendelenburg posi-tion. Larger lower extremity compression devices, extra padding, safety belts, and a footboard are required. An angled (30° or 45°) telescope, extra-long graspers and staplers, and a liver retractor system are all standard equipment. Staff sensitivity training for the care of the obese as well as regular education about the com-plications of bariatric surgery are program requirements.BARIATRIC SURGICAL PROCEDURESVBG shown in Figs. 27-1 and 27-5, although still listed as one of the approved operations for the surgical treatment of severe obesity based on the NIH Consensus Conference of 1991,51 is not currently performed due to poor long-term weight loss and technical complications, so it is of historic interest only, and the surgical technique will not be described here.8 The other procedures described in this section will be articulated using a laparoscopic approach as that is the dominant method. RYGB, BPD, and DS may still be performed by some surgeons using an open approach, but this has now become the exception. In this text LRYGB will refer specifically to RYGB performed by the laparoscopic approach, while RYGB will indicate proce-dures performed by the open approach or by both approaches as is the case for many studies of outcomes. Minimization of the morbidity of the open incision, especially incisional hernias and wound complications, as well as earlier hospital discharge and lower 30-day complication rates have all been clearly shown to favor using a laparoscopic approach when feasible.128-130 Lapa-roscopy begins with the safe creation of a pneumoperitoneum, often a difficult step in the bariatric patient. A tracheostomy hook can be inserted through a trocar-sized incision to elevate the fascia in the left subcostal region to facilitate the insertion of a Veress needle into an appropriate location for pneumoperi-toneum creation. The use of a Hasson approach for creating a pneumoperitoneum in the bariatric population may be limited by the thick body wall. In the patient with an extremely thick body wall, extra-long trocar ports can be used for laparoscopic surgery. The pneumoperitoneum pressure that is used when per-forming bariatric surgical procedures is generally in the 15 to 18 mmHg range. A high-flow insufflator is mandatory to main-tain the pneumoperitoneum for adequate and safe visualization.When an open surgical approach is used for any of these procedures, an upper midline incision with table mounted retrac-tors is the most commonly used approach. The robotic approach to bariatric procedures is also now utilized with purported Figure 27-8. Configuration of laparoscopic gastric bypass. (Reprinted with permission from Cleveland Clinic Center for Medi-cal Art & Photography © 2005-2009. All Rights Reserved.)advantages of reduction of the use of the open technique, improved surgical, length of stay, cost outcomes, and potentially improving ergonomics and resultant surgeon fatigue and injury. A meta-analysis involving 27 studies and over 25,000 patients concluded that there were no significant differences between robotic bariatric surgery and laparoscopic bariatric surgery with respect to overall complications, length of stay, reoperation, conversion, and mortality.131 Another study utilizing Univer-sity Consortium data demonstrated no difference in hospital mortality, major complications, readmissions, or length of stay between the robotic and laparoscopic approach.132 In both stud-ies, robotic surgery did increase significantly operative time and hospital costs (>20%) compared to laparoscopic approaches. As yet, larger prospective cohort studies and/or randomized trials have not yet been published, so the role of this technique is still to be defined and further studies are needed.133,134Laparoscopic Roux-en-Y Gastric BypassBackground and Patient Selection. Figure 27-8 depicts the configuration of the LRYGB. It is an appropriate operation for consideration for most patients eligible for bariatric surgery. Relative contraindications specifically for LRYGB include pre-vious gastric surgery, previous antireflux surgery, severe iron deficiency anemia, distal gastric or duodenal lesions that require ongoing future surveillance, and Barrett’s esophagus with severe Brunicardi_Ch27_p1167-p1218.indd 118023/02/19 2:20 PM 1181THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 275mm5mm12mm12mm5mm5mmFigure 27-9. Port scheme for laparoscopic gastric bypass. (Reprinted with permission from Cleveland Clinic Center for Medi-cal Art & Photography © 2005-2009. All Rights Reserved.)dysplasia. The major feature of the operation is a proximal gas-tric pouch of small size (<20 mL) that is totally separated from the distal residual stomach. A Roux limb of proximal jejunum is brought up and anastomosed to the pouch. The pathway of that limb can be anterior to the colon and stomach, posterior to both, or posterior to the colon and anterior to the stomach. The length of the biliopancreatic limb from the ligament of Treitz to the distal enteroenterostomy is 20 to 50 cm, and the length of the Roux limb is 75 to 150 cm.Creating the proximal gastric pouch by totally dividing it from the distal stomach is superior to simply stapling and par-titioning the stomach, since the latter is associated with a high incidence of staple line breakdown.135 The size of the proximal gastric pouch must be small to create adequate restriction and should be based on the lesser curvature of the stomach to pre-vent dilation over time. Length of the Roux limb was associated with higher short-term weight loss for longer length limbs,136 but this difference becomes less meaningful on long-term follow-up and has not been demonstrated in more recent studies.137 Gastric pouch size and caliber of the gastrojejunostomy have not, in any studies, been shown to be related to weight loss. The gas-trojejunal anastomosis can be constructed in a variety of ways, including hand sewn techniques and linear and circular staplers. Smaller diameter circular staplers are associated with a higher incidence of postoperative stenosis, and linear stapling is asso-ciated with a lower incidence of stenosis compared to circular stapling.138,139Technique. The operation generally is performed using five ports plus a liver retractor as shown in Fig. 27-9. Both the sur-geon, who stands on the patient’s right, and the first assistant, who stands on the patient’s left, have two ports for instruments. The telescope requires a port, usually in the supraumbilical region. The assistant’s ports are in the left subcostal and flank areas, while the surgeon may have both ports in the right upper quadrant or one on each side of the camera. Division of the proximal jejunum at 40 to 50 cm distal to the ligament of Tre-itz is performed with the linear stapler, using a vascular stapler cartridge. Further division of the mesentery at that location is performed either with the stapler or harmonic scalpel, such that adequate mobilization of the Roux limb is achieved. A Pen-rose drain or a marking suture is placed on the proximal Roux limb for identification and facilitation of advancement to the Figure 27-10. Creating Roux limb during laparoscopic gastric bypass.gastric pouch (Fig. 27-10). The length of the Roux limb (usually 100–150 cm) to be created is measured. A jejunojejunostomy is then created to the proximal end of the biliopancreatic limb at the previously determined location along the Roux limb. A side-to-side stapled anastomosis is performed (Fig. 27-11). Either singleor double-fired staple technique (the latter using a stapler Brunicardi_Ch27_p1167-p1218.indd 118123/02/19 2:20 PM 1182SPECIFIC CONSIDERATIONSPART IIFigure 27-12. Passage of Roux limb. (Reprinted with permission from Cleveland Clinic Center for Medical Art & Photography © 2005-2009. All Rights Reserved.)321Figure 27-13. Creation of gastric pouch for laparoscopic Roux-en-Y gastric bypass. (Reprinted with permission from Cleveland Clinic Center for Medical Art & Photography © 2005-2009. All Rights Reserved.)Figure 27-11. Enteroenterostomy of lapa-roscopic Roux-en-Y gastric bypass.fired in each direction) is used. The stapler defect is optimally closed with sutures but can be closed with a stapler if great care is taken not to narrow the lumen of the alimentary tract at this location. Once the stapler defect is closed, the mesenteric defect is then also closed with running permanent suture.Passage of the Roux limb toward the stomach is now per-formed. If an antecolic route is to be used, the end of the Roux limb is brought up so as to confirm its ability to reach the stom-ach (Fig. 27-12). If a retrocolic route is to be used, a defect is made in the transverse colon mesentery just to the left and slightly above the ligament of Treitz. The proximal end of the Roux limb is placed into the retrogastric space. The left lobe of the liver is now retracted using any one of several retractor types. The patient is moved to a reverse Trendelenburg posi-tion. The harmonic scalpel divides the peritoneum in the area of the angle of His, and then it is used to open an area along the lesser curvature of the stomach approximately 3 cm down from the gastroesophageal junction. Another approach for creating access to the lesser curvature of the stomach is to use a white or gray load (vascular load) of the stapler and divide the lesser curvature vessels up to the surface of the stomach. Then a blue load of the stapler is fired one time transversely from the lesser curvature side partially across the stomach, followed by mul-tiple subsequent firings of the stapler upward in the direction of the angle of His, to completely separate the proximal gastric pouch from the remainder of the stomach (Fig. 27-13). Option-ally, use of an Ewald tube passed by the anesthesiologist and maneuvered to lie against the lesser curvature of the proximal stomach can help calibrate the pouch size.Once the pouch is created, the Roux limb is brought up to the proximal gastric pouch. For the linear stapled anastomosis, the proximal end of the Roux limb is aligned with the distal gastric pouch end, and the sides of the organs are sutured together to maintain their side-by-side position. A stapler is introduced through a gastrotomy and an enterotomy for the two legs of the stapler, and the anastomosis is created (Fig. 27-14). The stapler defect is closed with sutures and often reinforced with a second Brunicardi_Ch27_p1167-p1218.indd 118223/02/19 2:21 PM 1183THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27Figure 27-14. Gastrojejunostomy in laparoscopic Roux-en-Y gastric bypass. (Reprinted with permission from Cleveland Clinic Center for Medical Art & Photography © 2005-2009. All Rights Reserved.)Figure 27-15. Oral passage of EEA circular stapler to create gastrojejunostomy for laparoscopic Roux-en-Y gastric bypass. (Reprinted with permission from Cleveland Clinic Center for Medical Art & Photography © 2005-2009. All Rights Reserved.)step of the operation involves suture closure of all mesenteric defects using permanent suture.Alternatively, a completely hand-sewn gastrojejunostomy can be created using two layers of absorbable suture to anasto-mose an approximately 1-cm gastrotomy and enterotomy. The circular anastomosis technique is another approach to complete the gastrojejunostomy and is also a particularly useful technique for “salvage” anastomosis if the gastric pouch is very small and/or high. This is done through placement of the anvil of the sta-pler through the anterior wall of the proximal gastric pouch. This is accomplished by pulling the anvil transorally via an endoscopically placed guidewire (Fig. 27-15), making a gas-trotomy in the pouch that is later closed, or making a gastrotomy in the lower stomach before completing gastric division to cre-ate the pouch, allowing the anvil to be placed into the lumen of the stomach and then be brought through the anterior stomach in an area that is subsequently included in the proximal gastric pouch (Fig. 27-16).Procedure-Specific Complications. Mortality after LRYGB is now consistently less than 0.5% in most large reported series. Data from several national data sets/studies find a mortal-ity rate of approximately 0.3%, 0.14%, and 0.2% at 30 days overall.59,140 Overall morbidity after LRYGB has also been low. In the Longitudinal Assessment of Bariatric Surgery (LABS) study, a composite endpoint including death, deep-vein throm-bosis or venous thromboembolism, reintervention, or failure to be discharged by 30 days after surgery occurred in 4.8% of those who had undergone LRYGB.59 In the national database of the ASMBS, morbidity alone was 14.87% for 30,864 gas-tric bypass procedures.141 Complications that do occur after LRYGB include a 0.3% incidence of anastomotic leak,142 0.33% layer of sutures. The gastrojejunostomy may be tested for secu-rity by using either methylene blue injected under pressure through the Ewald tube or a flexible upper endoscopy intraop-eratively to test for air leakage from the anastomosis. The final Brunicardi_Ch27_p1167-p1218.indd 118323/02/19 2:21 PM 1184SPECIFIC CONSIDERATIONSPART IIFigure 27-16. Transgastric passage of circular EEA stapler to create gastrojejunostomy for laparoscopic Roux-en-Y gastric bypass. (Reproduced with permission from Schauer PR, Schirmer BD, Brethauer S: Minimally Invasive Bariatric Surgery. New York, NY: Springer; 2007.)Figure 27-17. Obstruction of contrast at enteroenterostomy with small bowel obstruction from internal hernia after laparoscopic Roux-en-Y gastric bypass.incidence of venous thromboembolism,143 a 3% to 5% incidence of wound infections or problems,140 a 3% to 15% incidence of marginal ulcers,144 an approximately 7% incidence of bowel obstruction,145 a 4% incidence of postoperative transfusion,146 and a 1% to 19% incidence of anastomotic stenosis,139 based on the type of anastomosis created. Postoperative nutritional complications after LRYGB include a 66% incidence of iron deficiency, a 5% incidence of iron deficiency anemia, a 50% incidence of vitamin B12 deficiency,147 and an at least 15% incidence of vitamin D deficiency,148 which usually is pres-ent preoperatively. Both early and late dumping occur in an unspecified number of postoperative cases, as the symptoms are difficult to document and overlap with other problems such as hypoglycemia.Several complications that are specific to LRYGB must be emphasized. One of the most important is small bowel obstruction. This complication must be treated differently than in the average general surgery patient, whose complication is usually from adhesions and often will resolve with conserva-tive, nonoperative therapy. Patients who have had LRYGB who present with obstructive symptoms generally require surgical therapy on an emergent basis. This is because the etiology of the bowel obstruction after LRYGB is often an internal hernia from inadequate or nonclosure of the mesenteric defects by the sur-geon at the time of operation. Thus, treatment for these patients differs from most patients with small bowel obstruction. One of the most important points of this chapter is to emphasize to gen-eral surgeons to be aware of the need to emergently operate on patients after LRYGB who present with small bowel obstruc-tion. Currently, centers that perform small bowel transplantation are seeing patient referral for that procedure after small bowel obstruction after LRYGB, where patients developed infarction of most of the bowel from an internal hernia and have short gut syndrome.149 Other patients, for whom surgery is delayed and the bowel infarcts, do not survive. When the surgeon does encounter bowel obstruction after LRYGB, he or she can expect to see proximally dilated bowel. Cutoff of passage of contrast on CT scan at the enteroenterostomy is particularly suggestive of this diagnosis (Fig. 27-17). The surgical treatment of this particular problem can, if addressed early in the course of the obstruction, be treated laparoscopically. The surgeon must place a trocar for the telescope low enough in the abdomen to ade-quately survey most of the small intestine. The cecum and ter-minal ileum are identified, and the bowel is followed retrograde from the terminal ileum to determine the anatomy. Often much of the small bowel is herniated through a mesenteric defect, and only this technique allows the surgeon to reliably identify the bowel and decompress it appropriately. If the bowel is viable, 4Brunicardi_Ch27_p1167-p1218.indd 118423/02/19 2:21 PM 1185THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27suturing the mesenteric defect is all that is needed for treatment. It should be emphasized that either an antecolic or retrocolic placement of the Roux limb can result in this complication, as internal hernias can arise from either approach.Marginal ulcers are another complication relatively specific to LRYGB. The patient presents with pain in the epigastric region that is not altered by eating. Diagnosis is by endoscopy. Treatment is medical with proton pump inhibitors, which are effective in 90% of cases. Only those with a gastrogastric fistula to the distal stomach, severe stenosis of the lumen of the gastrojejunostomy, or acute perforation require surgical therapy. Treatment of a perforated marginal ulcer is a laparoscopic Graham patch. Stenosis of the gastrojejunostomy has been reduced by the use of the linear stapling technique.138 Stenosis symptoms usually appear from 6 to 12 weeks postoperatively, but less commonly can occur later. Diagnosis is by upper endoscopy. Treatment is circumferential balloon dilatation. Resolution normally occurs with one to two treatments. Less than 10% of patients require reoperation, and those are almost always associated with concurrent marginal ulcers.150In the immediate postoperative period, anastomotic leak is the single serious complication after RYGB, either open or laparoscopic. Careful vigilance and a high index of suspicion for this problem are important since its presentation may be insidi-ous and the patient’s demise, if untreated, may be sudden and complete. Tachycardia, tachypnea, fever, and oliguria are the most common symptoms that should arouse suspicion for this problem. The treatment is surgical, except in rare circumstances where a drain is already in place, no hemodynamic or clinical deterioration is present, and the leak is contained.151 Usual surgi-cal treatment involves repair as feasible, drainage, and creation of a reliable feeding access through a distal Stamm gastrostomy.In the first few hours or day after surgery, hematemesis indicates bleeding from the gastrojejunostomy unless proven otherwise. The dangers to the patient include aspiration, life-threatening hemorrhage, or more commonly intraluminal hematoma of the Roux limb and enteroenterostomy, which then causes an obstruction of the biliopancreatic limb leading to distal gastric staple line rupture.152 In fact, any obstructive symptoms in the first few weeks after surgery or any signs of obstruction of the biliopancreatic limb on postoperative swallow studies due to stenosis of the enteroenterostomy require imme-diate surgical intervention to prevent rupture of the distal gastric staple line. Some reports show that percutaneous decompres-sion of the distal stomach can help to ameliorate the problem,153 but operative therapy to decompress the stomach and treat the obstruction is first-line therapy.Laparoscopic Sleeve GastrectomyBackground and Patient Selection. SG was originally introduced as the first of a two-stage operative treatment for patients with super obesity (BMI >60 kg/m2).154,155 Its currently utilization is as a primary single-stage operation, but the pos-sibility of a second-stage treatment remains, especially for the super obese patients, depending on the effectiveness of it as the primary operation. In addition, patients who have longstanding severe GERD may not be good candidates for SG as GERD is worsened by the anatomical configuration of the SG. Barrett’s esophagus is also a contraindication for performing SG, since the potential for future esophageal dysplasia and the need for an available intact stomach for esophageal reconstruction outweigh the potential advantages of the procedure.Figure 27-18. Port scheme for laparoscopic sleeve gastrectomy.Technique. The patient is positioned supine, with foot sup-port to allow reverse Trendelenburg positioning. The surgeon stands to the patient’s right along with the camera driver, while the assistant stands to the patient’s left. Port placement may vary, but a recommended port placement schema is shown in Fig. 27-18. The 15-mm port, helpful for removal of the stomach, is located in either the camera (just to the patient’s left of the umbilicus) or surgeon’s right hand (right upper quadrant near the midline) location. The other of these ports is a 12-mm port. The assistant has two 5-mm ports available in the left upper quadrant laterally, and the surgeon’s left-hand port is a 5-mm port more lateral and superior in the right upper quadrant. A liver retractor is placed in the epigastric region.The operation begins by devascularizing the greater curva-ture of the stomach, beginning 3 to 5 cm proximal to the pylorus. The division of all vessels adjacent to the greater curvature is continued up to the left crus of the diaphragm. A complete mobilization of the fundus in this area and division of posterior fibrous attachments to the antrum and body of the stomach are then performed such that the stomach is attached solely by the lesser curvature blood supply and the pyloric and esophageal regions. Stapled division of the stomach now follows. The first firing of the stapler occurs from the point of devascularization of the greater curvature at an angle pointing toward a point about 2 cm lateral to the incisura. The antrum of the stomach is at its thickest here, and so it is important to be certain the stapler load used is sufficiently large enough to allow good approximation and closure of the divided stomach. Two staple firings are performed, which takes the gastric division to past the incisura. After the first staple firing, some surgeons will engage the anesthesiologist to pass a 32to 40-French bougie and position it along the lesser curvature of the stomach. This bougie then serves as a guide for further gastric division. Alter-natively, some surgeons will insert the endoscope instead of the bougie as a guide for gastric division. It can also be used to test for air leaks, bleeding, or obstruction as it is withdrawn after gastric division. Dividing the stomach adjacent to the bougie or endoscope will produce the desired diameter of the gastric sleeve. It is most important not to narrow the stomach lumen at the incisura. During the second and third firing of the stapler to divide the stomach, it is critical to confirm by visualization of both the anterior and posterior surfaces of the stomach that the incisura area is not narrowed. By the third firing of the stapler, usually the angle of the gastric division is now pointed directly toward the angle of His, parallel to the bougie (Fig. 27-19). Brunicardi_Ch27_p1167-p1218.indd 118523/02/19 2:21 PM 1186SPECIFIC CONSIDERATIONSPART IIFigure 27-20. Completed sleeve gastrectomy. (Reprinted with permission from Cleveland Clinic Center for Medical Art & Photography © 2005-2009. All Rights Reserved.)Figure 27-19. Performing sleeve gastrectomy. (Reprinted with permission from Cleveland Clinic Center for Medical Art & Photography © 2005-2009. All Rights Reserved.)At this point, changing staple loads to lower staple height is advisable.Once the stomach is completely divided up to the angle of His, the staple line is inspected for hemostasis and integ-rity. Some surgeons will reinforce the staple line with a but-tress material, while others will invaginate the staple line with a running serosa to serosa suture. Some surgeons will exchange the bougie at this point for a 32-French Ewald tube and per-form a methylene blue leak test. Alternatively, if an endoscope is used, it is withdrawn with insufflation, and the staple line is inspected for air leaks while submerged in saline. The speci-men is removed through the 15-mm trocar site, usually with only slight enlargement of the site. Figure 27-20 shows the com-pleted operation. Controversy still exists as to the optimal size of the bougie used during the procedure and the relative utility of methods used to oversew or reinforce the staple line.Procedure-Specific Complications. The major factor unique to SG is that it creates a high-pressure gastric tube. This increased intraluminal pressure places the staple line at risk for leakage and increased risk for GERD. As noted previ-ously, controversy exists about both bougie size and staple line reinforcement/oversew as they relate to clinical outcomes. One summary of the literature shows that the stenosis rate is lower if a 40-French bougie is used, and the leak rate may also be lower without compromising weight loss.156 However, individual insti-tutional experiences with smaller-sized bougies have shown the potential for good weight loss and no increased incidence of stenosis.157 Another controversial area is that of staple line rein-forcement with staple buttressing material or reinforcement with oversewing.158 The overall bleeding rate for the staple line after SG is generally cited as about 2% in collected series.159 There have been no studies that have shown a definitive decrease in this bleeding rate with the use of buttress materials; however, a panel of experts has voiced support for a decreased incidence of bleeding from the staple line if buttress material is used.158 One meta-analysis did show that there is evidence to suggest buttress materials may decrease the staple line leak rate.160 Other prospective randomized studies have failed to show a benefit of buttress materials for leak prevention.161 A more recent study of over 180,000 SG procedures in the Metabolic and Bariat-ric Surgery Accreditation and Quality Improvement Program (MBSAQIP) national database showed that staple line rein-forcement cases were associated with higher leak rates (0.96% vs. 0.65%, odds ratio [OR] 1.20 95% CI 1.00–1.43) and lower bleeding rates (0.75% vs. 1.00%, OR 0.74 95% CI 0.63–0.86) compared to no reinforcement, at the patient level.162 At this time, there is no preponderance of data to support one approach as being superior to others for both staple line bleeding or leak rates. Given this state of the literature, a surgeon should con-sider the risks, benefits, and costs of these surgical techniques and utilize those that, in their hands, minimize morbidity while maximizing clinical outcomes.If there is a relative obstruction or stenosis of the sleeve, which most often occurs at the incisura because of narrowing there during formation of the sleeve, pressure above the level of the obstruction will be even more elevated and create an increased risk for staple line leak. Leaks of the proximal staple line are the most frequent type seen after SG and often are felt to be related to increased intraluminal pressure distally. They may also be related to stapling too close to the angle of His, with resultant instability of the tissue directly adjacent to the esophagus in this area. It is important not to staple too close to the angle of His during the final stapling division portion of the stomach so as to not further weaken the staple line in this area. Proximal staple line leaks may also present as late leaks, 6 weeks to months following the procedure. Late leaks are rare Brunicardi_Ch27_p1167-p1218.indd 118623/02/19 2:21 PM 1187THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27Figure 27-21. Laparoscopic adjustable band overall scheme. (Reprinted with permission from Cleveland Clinic Center for Medi-cal Art & Photography © 2005-2009. All Rights Reserved.)following other bariatric procedures, but are seen with SG, and index of suspicion should remain high.Distal staple line leaks are different from proximal staple line leaks and are usually associated with earlier presentation and related to mechanical failure of the staple line to securely approximate the thicker distal gastric tissue. These leaks are more amenable to successful repair with a reoperation, whereas proximal leaks may not improve with oversewing at a reopera-tion unless the mechanics of the relative distal obstruction and high intraluminal pressure of the sleeve are also treated. Endo-scopic intervention to dilate stenotic areas as well may be bene-ficial in the setting of a stenosis with or without a proximal leak. Care must be taken by the endoscopist to not excessively dilate the tract beyond the original size of the bougie used. Another factor that may influence stenosis at the incisura is that there may be a relative twisting of the stomach at this location, with the antrum being partially twisted away from the upper por-tion of the sleeve. Endoscopic treatment can help straighten and markedly alleviate the obstruction in such cases. Thus, relatively early endoscopic intervention is appropriate in the patient with a stenosis at the incisura. One study has shown that endoscopic dilation is usually successful in treating stenosis after SG, with a mean of 1.6 dilatations being done an average of 48 days postoperatively.163The patient with the proximal gastric staple line leak because of mechanical factors may experience persistence of the leak for months. Nonsurgical treatment with drainage and stenting can be used initially. Some now advocate for conver-sion of the patient with a longstanding leak after SG to a RYGB to provide a low-pressure anastomosis above the site of the ste-nosis.164,165 Similarly, persistent stenosis of the sleeve despite conservative therapy and endoscopic dilatation also is an indica-tion for conversion to RYGB.Laparoscopic Adjustable Gastric BandingBackground and Patient Selection. LAGB involves place-ment of an inflatable silicone ring around the proximal stom-ach. The band is attached to a reservoir system that allows adjustment of the tightness of the band. This reservoir system is accessed through a subcutaneously placed port, similar in concept to ports used for chemotherapy via central venous catheters. Figure 27-21 shows the LAGB apparatus in place. Patients who have had previous upper gastric surgery, such as a Nissen fundoplication, and those with severe GERD are rela-tively poor candidates for LAGB due to altered proximal gastric anatomy interfering with proper band placement or worsening of GERD symptoms. Two major types of bands have been used for this procedure. The original Lap-Band has been used most frequently. The Swedish Band, remarketed as the Realize Band in the United States, is slightly wider and larger in circumfer-ence than the Lap-Band but is no longer being manufactured. The port systems have differences as to profile and methods of attachment to the fascia.Technique. Port placement for LAGB has varied among sur-geons. Usually some combination of two ports for the surgeon’s hands, one or two for the assistant, a port for the telescope, and a liver retractor site are needed. With the patient placed in reverse Trendelenburg position, the procedure begins with division of the peritoneum at the angle of His and then division of the gas-trohepatic ligament in its avascular area (the pars flaccida) to expose the base of the right crus of the diaphragm. If a hia-tal hernia is present, it must be repaired at this point, using a Figure 27-22. Grasper being passed through under stomach to grasp tubing during placement. (Reprinted with permission from Cleveland Clinic Center for Medical Art & Photography © 2005-2009. All Rights Reserved.)standard posterior esophageal dissection to expose the crura and perform suture repair. A grasper is inserted along the base of the anterior surface of the diaphragmatic crura, from right to left, emerging at the angle of His in the area of the divided peri-toneum (Fig. 27-22). The device is then used to pull the band Brunicardi_Ch27_p1167-p1218.indd 118723/02/19 2:21 PM 1188SPECIFIC CONSIDERATIONSPART IIABunderneath the posterior surface of the gastroesophageal junc-tion. This technique, by passing the band through some fibrous tissue in this plane, serves to anchor the band more securely posteriorly. During the initial years of band placement, a ret-rogastric location of the posterior half of the band in the free space of the lesser sac caused an unacceptably high incidence of slippage and prolapse of the band. The adoption of the pars flaccida technique decreased the incidence of such slippage.166Once the band is passed around the proximal stomach, it is locked into its ring configuration through its own self-locking mechanism. This involves the tubing end being passed through the orifice of the buckle for the Lap-Band and the suture on the end of the flanged end of the band site being passed through for the Realize Band. Once the band is securely locked in place, the buckle portion of the band is located on the lesser curvature of the stomach (Fig. 27-23A,B). Now the anterior surface of the fundus and proximal stomach is imbricated over the band using several sutures (Fig. 27-24). The tubing of the band system is brought out through the desired site for placement of the port portion of the system. Usually this is a trocar site near the upper abdomen or xiphoid region to place the port most superficially such that it can be palpated postoperatively. The port is secured Figure 27-23. A. Lap-Band in place around stomach. (Reprinted with permission from Cleveland Clinic Center for Medical Art & Photography © 2005-2009. All Rights Reserved.) B. RealizeT (Swedish) Band around stomach.to the anterior abdominal wall fascia. Access to the port for subsequent addition of fluid to the band system is percutane-ously achieved using a Huber or noncutting type needle. The band is initially placed empty of fluid, except priming, in most circumstances.Procedure-Specific Complications. The complications that may occur after LAGB include gastric prolapse, band slippage, band erosion, and port and tubing complications. In addition, failure to lose clinically significant weight is more common fol-lowing this procedure compared to others. Acute gastric pro-lapse is the most common emergent complication that requires reoperation after LAGB. Acute, severe pain with immediate dysphagia, vomiting, and inability to take oral food or liquid is the typical presentation. Vomiting may predispose or exac-erbate this problem. Either anterior or posterior prolapse may occur.167 The initial evaluation for prolapse involves obtaining a plain film radiograph. If the band is in a horizontal position instead of its normal oblique position, prolapse must be strongly suspected. Initial treatment for an acute or chronic prolapse is to remove all the fluid from the system. This often allows reduc-tion of the prolapse and resolution of symptoms. If symptoms do not resolve after this, an upper gastrointestinal (UGI) series Brunicardi_Ch27_p1167-p1218.indd 118823/02/19 2:21 PM 1189THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27Figure 27-24. Stomach imbricated over band.is indicated, and if prolapse persists, then reoperation laparo-scopically to reduce the prolapse and resuture the band in place is indicated. Chronic gastric prolapse is more subtle. The band retains its normal oblique angle, but there is symmetric dilation of the gastric pouch above the band. These are initially managed with fluid removal and monitoring of symptoms. Follow-up evaluation can be performed in 4 to 8 weeks, and if the chronic prolapse resolves on UGI, slow refilling of the band may begin.Band erosion is uncommon, reported in 1% to 2% of most series. The patient usually develops either a port site infection or systemic fever and a low-grade abdominal inflammatory sepsis. Endoscopy can be diagnostic, visualizing the white band mate-rial within the stomach. The presence of otherwise unexplained free air on computed tomography (CT) scan should alert the surgeon to this diagnosis as well. Laparoscopic removal of the band is indicated, with repair of the gastric perforation. Often the perforation is already sealed by an inflammatory process, but if not, appropriate management of a gastric perforation must be followed.167Port and tubing problems occur in at least 5% to 15% of patients undergoing LAGB. These require revision of the port/tubing system due to perforation, leaking, or kinking of the tub-ing or turning of the port such that access to the surface of the port for adding fluid is precluded. Usually a procedure under local anesthesia is all that is required to repair or realign the tub-ing or port. The incidence of band removal for patient dissatisfac-tion or lack of weight loss has been difficult to assess completely, but this number is increasing annually. Angrisani et al168 reported a 40.9% incidence of band removal after 10-year follow-up. In the Longitudinal Assessment of Bariatric Surgery (LABS) study, 18 subsequent reoperations occurred for every 100 participants with LAGB who were followed up for 3 years.169 Overall, these numbers are expected to increase as follow-up increases.Biliopancreatic Diversion and Duodenal SwitchBackground and Patient Selection. BPD was first described by, and remains championed by, Scopinaro in Italy.9 The operation, which is shown in Fig. 27-25, involves resection of the distal half to two-thirds of the stomach and creation of an alimentary tract of the most distal 200 cm of ileum, which is anastomosed to the stomach. The biliopancreatic limb is anastomosed to the alimentary tract at approximately 100 cm proximal to the ileocecal valve. This operation is limited in its utilization due to both technical difficulty and the significant percentage of nutritional complications that arise postoperatively.One early problem with BPD was the development of a high incidence of marginal ulcers postoperatively. Hess and Figure 27-25. Diagram of biliopancreatic diversion. (Reprinted with permission from Cleveland Clinic Center for Medical Art & Photography © 2005-2009. All Rights Reserved.)Brunicardi_Ch27_p1167-p1218.indd 118923/02/19 2:21 PM 1190SPECIFIC CONSIDERATIONSPART IIHess10 and Marceau and colleagues170 separately described the adaptation of the DS operation, originally proposed by DeMeester and colleagues171 for treatment of bile reflux gastri-tis, to replace the gastric portion of the BPD. This procedure was originally called BPD with DS. For ease of description, it is now simply called the duodenal switch (DS) (Fig. 27-26). Currently, BPD and DS represent together less than 1% to 2% of bariatric operations performed in the United States. Patients who undergo either BPD or DS must be prepared for the consequences of a malabsorptive operation. Frequent and large-quantity bowel movement after any large amount of oral intake is common. Also, patients must agree to close follow-up and a large number of vitamin and mineral supplements to avoid nutritional prob-lems. Given the increased incidence of postoperative nutritional and other complications, BPD and DS usually are recommended only for patients who have higher BMIs or for patients who have failed another operation for weight loss or metabolic control. Contraindications to the procedure include geographic distance from the surgeon, lack of financial means to afford supplements, and preexisting calcium, iron, or other nutrient deficiencies.Technique. The technique for BPD and DS is the same for the open and the laparoscopic approach, and they are very techni-cally challenging operations.172 The BPD operation begins with performance of a distal subtotal gastrectomy with a residual 200-mL gastric pouch. The terminal ileum is identified and divided 250 cm proximal to the ileocecal valve. The distal end of that divided ileum is then anastomosed to the stom-ach, creating a 2to 3-cm stoma. The proximal end of the ileum is then anastomosed side-to-side to the terminal ileum Figure 27-26. Diagram of duodenal switch. (Reprinted with permission from Cleveland Clinic Center for Medical Art & Photography © 2005-2009. All Rights Reserved.)approximately 100 cm proximal to the ileocecal valve. Prophy-lactic cholecystectomy is performed due to the high incidence of gallstone formation with the malabsorption of bile salts.The DS procedure differs from the BPD procedure only in the proximal gut portion of the operation. Instead of a distal gas-trectomy, resection of all the stomach except for a narrow lesser curvature tube of the stomach (SG) is performed. The diam-eter of this tube is calibrated with a bougie of 32to 40-French size. The duodenum is them divided in its first portion, leaving an approximately 2-cm length of duodenum intact beyond the pylorus. This end of the duodenum is then anastomosed to the distal 250 cm of ileum. This anastomosis is often done in an end-to-end fashion with a circular stapler. This is the most dif-ficult portion of the DS procedure, and leak rates are slightly higher than with other anastomoses. The distal bowel configura-tion and cholecystectomy are similar to BPD.Procedure-Specific Complications. Complications that occur after BPD include those seen after RYGB, where intestinal anastomoses and gastric division create potential problems with bleeding and leakage. Scopinaro and col-leagues173 reported GI obstruction in 1.2%, wound infections in 1.2%, and marginal ulcers in 2.8% of patients. However, others found the incidence of marginal ulcer to be higher after BPD, leading to the adoption of the DS. Preservation of the pylorus reduces the incidence of dumping (poorly quantitated in most series) after BPD. The duodenoileostomy of DS also has a very low rate of stomal ulcer, unlike the gastroileostomy of BPD.Nutritional complications are by far the most frequent and concerning after both of these operations, particularly on long-term follow-up. Scopinaro and colleagues173 reported a protein malnutrition rate of 7%, iron deficiency anemia rate of less than 5%, and bone demineralization at 5 years of 53%. Other prob-lems that may arise include alopecia from inadequate protein absorption, night blindness from a lack of vitamin A, and gall-stones if the gallbladder is not removed. However, of all these nutritional complications, protein-calorie malnutrition is the most severe and life-threatening. When it is diagnosed, the treat-ment is parenteral nutrition. Two episodes of required parenteral nutrition are usually considered adequate indication to lengthen the “common channel” of ileum—the ileum between the ileo-ileostomy of the biliopancreatic limb to the alimentary tract and the ileocecal valve. The amount of length that the surgeon should increase the common channel is poorly documented.Investigational Bariatric ProceduresThere is continuous evolution of the approaches to and proce-dures for bariatric surgery. The goals of this dynamic process are to minimize risk, reduce invasiveness, and maximize clini-cal effectiveness. This same benefit-risk approach/paradigm has also been adopted by the FDA for the design of clinical trials for obesity devices to help facilitate product development and approval.174 In the past, a variety of medical devices to assist with weight reduction have been studied, but only a few have been commercially available. In 2012, to address the need for more intermediate treatment options with devices, the FDA initiated a new paradigm based on a benefit-risk determina-tion to suggest appropriate levels of benefit for devices with different risk levels. In other words, it became more feasible to trial less invasive obesity treatment devices, as the threshold for weight loss was lower if the risk of the device or procedure was lower as well. Since that time, several new devices have been approved. These intermediate devices are intended to provide 5Brunicardi_Ch27_p1167-p1218.indd 119023/02/19 2:21 PM 1191THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27tools in the middle of the spectrum of care between lifestyle modification and bariatric surgery and are offered to people with BMIs between 30 and 40 kg/m2.The vagus nerve is known to play a role in satiety, metabo-lism, and autonomic control in the upper gastrointestinal tract. Studies have been conducted to determine the efficacy of vagal nerve block therapy with a treatment device that consistently delivers at least 12 hours of therapy a day and a sham control device that has no possibility of delivering therapy. A laparo-scopic abdominal procedure is performed to attach two elec-trodes to the anterior and posterior vagal trunks at the level of the gastroesophageal junction. Customized electrodes are placed around the nerves and then secured with sutures. These electrodes are then connected to a transcutaneously recharge-able neuroregulator placed in a subcutaneous pocket on the thoracic side wall. Published results show modest weight loss in the vagal nerve blockade group of 9.2% compared to 6.0% TBWL in the sham group at 12 months and 8.8% and 3.8% TBWL in vagal nerve blockade and sham groups, respectively, at 18 months.175,176 More weight loss was sustained through 18 months in the vagal blockade group, and the device was shown to be safe, as there was a low rate of serious complications.Endoscopically placed intragastric balloons (IGBs) are once again an option for overweight and obese patients with a BMI greater than 27 kg/m2. The original Garren-Edwards bub-ble (GEB) from the late 1980s was an endoscopically placed and removed balloon filled with 220 mL of air that was left in the stomach for 3 months. Adverse events related to the GEB reported in the medical literature included small-bowel obstruc-tion secondary to unplanned deflation, gastric ulcers with GI hemorrhage, and gastric perforation, so its use was abandoned. A multidisciplinary conference that followed recommended that future IGBs should (a) be effective at promoting weight loss, (b) be filled with liquid (not air), (c) be capable of adjustment to various sizes, (d) have a smooth surface with low ulcerogenic and obstructive potential, (e) contain a radiopaque marker, and (f) be constructed of durable materials.177Newer IGBs have undergone evaluation and approval by the FDA. These include both a single and a double lumen bal-loon, both placed endoscopically and filled with saline.178,179 Results from these two pivotal trials show weight losses of 7.6% and 10.2% TBWL at 6 months in the device group that exceeded weight loss in the control or sham groups. There were some early removals in 9% to 18% of subjects for failure to tolerate symptoms, early deflations without migration in 6%, and gastric ulcers in 10%. The precise role for these devices is yet to be determined, and they must be paired with a diet and exercise plan to maximize effectiveness. Repeat or sequential balloon therapy may be effective in enhancing and sustaining weight loss, and it is being studied in Europe. Finally, ensuring proper follow-up is important to reduce adverse events related to ulcers, spontaneous deflation, or migration of the balloon.An endoscopically placed percutaneous gastrostomy tube is approved for weight loss. It facilitates drainage of approxi-mately 30% of the calories consumed in a meal, in conjunction with lifestyle counseling. In a randomized trial, participants lost 12.1% ± 9.6% TBWL compared to 3.5% ± 6.0% TBWL in the lifestyle-only control group. The most frequent complication was abdominal pain and discomfort in the perioperative period and peristomal granulation tissue and peristomal irritation in the postoperative period. Serious adverse events were reported in 3.6% of participants in the device group.180A duodenal-jejunal bypass liner is an endoscopic device that mimics the duodenal-jejunal exclusion component of an RYGB and is undergoing trials in the United States. Prior studies assessing the efficacy of the DJBL have shown modest weight loss and improvements in glycemic control. There are associated adverse events of migration, obstruction, and epigas-tric pain. One study demonstrated a high (29%) early device removal rate due to these events.181 A more recent meta-analy-sis showed that the DJBL was associated with significant mean differences in TBWL for the device (12.6%) compared with lifestyle modification. The mean differences in glycated hemo-globin and fasting plasma glucose among subjects with T2DM in this meta-analysis did not reach statistical significance.182Various endoscopic and endoluminal procedures are also being utilized as less invasive approaches for bariatric surgi-cal procedures. These include procedures to decrease gastric pouch size and to limit gastrojejunostomy anastomotic size after “failed” LRYGB.183 Overall, reports have been disappointing for effectiveness. Gastric plication is also being approached both laparoscopically and endoscopically to mimic results of an SG but without requiring stapling or gastric resection. Fur-ther studies with long-term safety and efficacy data are required before these investigational procedures can be considered for routine clinical use.FOLLOW-UP AND POSTOPERATIVE CAREPostoperative follow-up is required following bariatric surgery to detect and treat postoperative shortand longer-term complications. Weight regain, internal hernias, ulcerations, and important nutrient deficiencies can occur years after bariatric surgery. These specific problems are detailed in the “Procedure-Specific Complications” and overall “Complications” sections. The frequency of follow-up varies by surgical procedure and to some extent by surgical practice, but continues, hopefully, for life. Postoperative follow-up is defined as short-term (0–2 years), medium (2–5 years), and long term (≥5 years). Recommendations are that at least 75% of patients are followed for 5 years for LAGB, SG, and LRYGB operations, and 90% are followed closely for 5 years and longer if they have malabsorptive operations (BPD and DS). Although a clinical follow-up system may be in place, it still requires patient compliance, which is generally low for long-term follow-up. In a systematic review, Puzziferri et al also identified that less than 3% of bariatric studies included >80% long-term follow-up.184 Vigorous efforts can help to improve follow-up, but these require significant staffing and funding. In the NIH-funded prospective, longitudinal bariatric study, more complete follow-up data and weight measurements were obtained for 79% of RYGB patients in the longer term with the use of these resources.169The goals of short-term follow-up are to maximize care of the patient in the postoperative period; assist in adjustment to new eating, exercise, and lifestyle patterns; be on the alert for and treat postoperative complications; and recommend measures to limit such complications. The goals of long-term follow-up are similar, but focus more on weight regain, the man-agement of comorbid condition relapse, and the emergence of recurrent depression, substance and alcohol misuse, and nutri-tional complications. Vitamin and mineral supplements must be taken regularly for life, including oral supplements for iron, calcium, and vitamin B12 and a multivitamin. Evidence indicates that vitamin and mineral deficiencies, including deficiencies of Brunicardi_Ch27_p1167-p1218.indd 119123/02/19 2:21 PM 1192SPECIFIC CONSIDERATIONSPART IITable 27-4Recommended postoperative nutritional monitoringRECOMMENDATIONLAGBSGLRYGBBPD/DSBone density (DXA)a at 2 yearsYesYesYesYes24 hour urinary calcium excretion at 6 months and annuallyYesYesYesYesVitamin B12 annually (methylmalonic acid and homocysteine optional) then every 3–6 months if supplementedYesYesYesYesFolic acid (red blood cell folic acid optional), iron studies, vitamin D, intact parathyroid hormoneNoNoYesYesVitamin A initially and every 6–12 months thereafterNoNoOptionalYesCopper, zinc, and selenium evaluation with specific findingsNoNoYesYesThiamine evaluation with specific findingsYesYesYesYesaDXA = dual energy X-ray absorptiometry; LAGB = laparoscopic adjustable gastric banding; SG = sleeve gastrectomy; LRYGB = laparoscopic Roux-en-Y gastric bypass; BPD/DS = biliopancreatic diversion with duodenal switch.Data from Mechanick JI, Youdim A, Jones DB, et al: Clinical practice guidelines for the perioperative nutritional, metabolic, and nonsurgical support of the bariatric surgery patient—2013 update: cosponsored by American Association of Clinical Endocrinologists, The Obesity Society, and American Society for Metabolic & Bariatric Surgery, Obesity (Silver Spring). 2013 Mar;21 Suppl 1:S1-S27.calcium, vitamin D, iron, zinc, and copper, are common after bariatric surgery.185 Guidelines suggest screening patients for iron, vitamin B12, folic acid, and vitamin D deficiencies preop-eratively, as well.89 Patients should also be given daily nutri-tional supplementation postoperatively, including two adult multivitamin plus mineral supplements (each containing 18 mg of iron, 400 to 800 µg of folic acid, and 50 mg of thiamine), 1200 to 1500 mg of elemental calcium (1800 to 2400 mg for BPD/DS), at least 3000 IU of vitamin D, and vitamin B12, the dose of which varies by route of administration. In addition, all patients should undergo annual screening for specific deficien-cies (Table 27-4).Objective data that should be obtained after all bariatric operations include weight loss, change in BMI, resolution or improvement in medical comorbidities, and any complications that occur. Assessment of quality of life can help gauge effi-cacy as well, with the Short Form-36 (SF36) questionnaire being one frequently used example. In a retrospective review based on the bariatric outcomes longitudinal database (BOLD) dataset by Spaniolas et al, the effect of postoperative follow-up on 12-month weight loss was studied in 51,081 patients. Com-plete follow-up was independently associated with excess weight loss ≥50% and total weight loss ≥30%.186 To identify the relationship between regular follow-up and resolution of comorbidities, the same group studied a cohort of 46,381 patients (31% RYGB patients) who had minimum of 12-month follow-up. After adjusting for baseline characteristics, the group determined that complete follow-up in the first year after RYGB was independently associated with a higher rate of improvement or remission of comorbid conditions (T2DM, hypertension, and dyslipidemia).187 Frequent and protocolized band adjustments and postoperative support individual/group sessions were shown to be important for longer-term outcomes following LAGB.188 Finally, the 12-month postoperative visit, which coincides with the plateauing of weight loss for most procedures, presents an opportunity to intervene while bariat-ric surgery patients are still engaged. Engaging patients and the use of technology to maintain contact with a medical pro-vider are important tools to maintain follow-up after bariatric surgery.RESULTS OF BARIATRIC SURGERYShort-Term OutcomesThe short-term (1–2 year) outcomes for bariatric surgical pro-cedures are shown in Table 27-5, which summarizes of the majority of the literature from 2009 to 2017. Average 30-day mortality is low (<1.0%) for all procedures except BPD/DS. Mortality after LRYGB is now consistently less than 0.3% to 0.5% in most large reported series.59,140 Morbidity varies by procedure, but it is the lowest for LAGB, followed by SG and then LRYGB, and highest for the malabsorptive procedure BPD/DS. In the Longitudinal Assessment of Bariatric Sur-gery (LABS) study, a composite endpoint including death, deep-vein thrombosis or venous thromboembolism, reinter-vention, or failure to be discharged by 30 days after surgery occurred in 4.8% of those who had undergone LRYGB.59 Short-term results of the SG have been reported from large national databases. These data show that SG is positioned between LAGB and LRYGB for efficacy of weight loss and resolution of comorbid medical problems and for morbidity and mortality.140 Few longer-term results with SG have been published.189,190In the past, large institutional series of LAGB results have been published from centers in Europe and Australia, showing better results for weight loss than those that have been observed in the United States (13–22% TBWL) (see Table 27-5). Weight loss results with BPD or DS are both excellent and comparable but come with higher surgical morbidity. The results from malabsorptive procedures are also very durable for the small percentage of people who undergo them. One 18-year follow-up study after BPD showed a mean excess weight loss of 70% persisting for that duration of time.173 Although most of the results of BPD or DS are after open operations, one report of laparoscopic DS at an experienced center showed that for 40 patients with an average BMI of 60 kg/m2 the mean hospital stay was 4 days, average operation room time was 3.5 hours, and mean excess weight loss at 9 months was 58%.191 Buchwald and colleagues showed that the average weight loss after BPD and DS in the literature was over 70%, with a mortality rate of 1.1%, a complication rate of 27% to 33%, and a nutritional complication rate of 40% to 77%192 (see Table 27-5).Brunicardi_Ch27_p1167-p1218.indd 119223/02/19 2:21 PM 1193THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27Table 27-5Short-term bariatric surgical outcomes OUTCOMEa ALLSURGICAL PROCEDURELRYGBSGLAGBBPD/DS% Mortality 30-day<1.0%0.3–0.5%0.11%0.05%1.1%% Morbidity 30-dayNA, depends on procedure12–21%3–6%2–4%27–33%% Total body weight loss (TBWL)NA, depends on procedure31–36%25–30%13–22%36–38%% Excess body weight loss (EBWL)NA, depends on procedure48–77%(mean, 68%)49–81%29–50%>70%% Diabetes remission77%60–80%60%35%75%% Dyslipidemiab remission70%63–91%72–82%78%80%% Hypertension remission62%61–81%60–92%43%60%, few reports% Sleep apnea remissionc84%80%80%68%80%aOutcomes are the averages found in the literature at 1 to 2 years postoperatively, unless otherwise noted.bDenotes any component lipid remission.cDenotes clinical remission as repeat sleep studies are uncommonly performed.Further detail on surgical morbidity for each procedure is addressed in both the “Procedure-Specific Complications” and overall “Complications” sections.Effectiveness of Bariatric Surgery Compared to Nonsurgical TreatmentThe following section summarizes important findings of studies that compare bariatric procedures with nonsurgical management of obesity. The results of these studies concerning remission from T2DM will be discussed in more detail in “Results of Surgery for Diabetes.” A systematic review and meta-analysis by Gloy summarized all randomized controlled trials (RCTs) that compared bariatric surgery with nonsurgical treatments for obesity.193 The review analyzed 11 trials comprising nearly 800 people with a BMI of 30 to 52. These studies generally focused on cohorts with T2DM and 1 to 2 years of follow-up. They pro-vided good evidence of the effectiveness of bariatric procedures, including LRYGB,78-80 LAGB,77,194 BPD,79 and SG.78 These pro-cedures resulted in greater short-term (1–2 years) weight loss (mean difference −26 kg; 95% CI −31 to −21; P <0.001) and greater remission of T2DM (complete case analysis relative risk of remission: 22.1, 3.2–154.3; P = 0.002; conservative analysis: 5.3, 1.8–15.8; P = 0.003) compared with various nonsurgical treatments.77-80,194 After this meta-analysis, two additional RCTs were published that show similar short-term results for both weight loss and T2DM.83,84In addition, serum triglycerides and high-density lipoproteins were significantly reduced by bariatric procedures, but blood pressure and other lipoproteins were not (although some studies showed reduced medication use for these conditions).193 The Gloy review also noted a lack of evidence from RCTs beyond 2 years for mortality, cardiovascular diseases, and adverse events. Another systematic review by Maggard-Gibbons focused on weight loss and glycemic control in class I obese (BMI 30–34.9) adults with T2DM and identified three RCTs with results similar to those seen in class II (BMI 35–39.9) and severely obese populations. However, the review also noted a lack of longer-term studies in people with class I obesity.195Longer-Term StudiesA summary of studies with long-term outcomes are shown in Table 27-6. The following section describes these studies and other larger studies that have contributed data to the growing body of evidence with respect to some short-term and now much longer-term outcomes.Swedish Obese Subjects Study. Much of what is currently known about the long-term results of bariatric surgery come from the Swedish Obese Subjects (SOS) study, which was initi-ated in 1987 as a prospective trial of 2010 subjects undergo-ing bariatric surgery compared to a usual care control group (n = 2037) that were matched on 18 clinical and demographic variables. The most common bariatric procedure performed in SOS was the VBG (68%), followed by gastric banding (19%), and RYGB (13%). Follow-up rates are high and reported at 99% for some endpoints (including mortality). The SOS investiga-tors have published widely on health outcomes beyond 10 years and up to 20 years, including: weight loss, mortality, T2DM remission and incidence, cardiovascular events, incident cancer, psychosocial outcomes, and health care use and costs. Weight loss among surgical subjects in SOS was greater than in con-trol subjects (mean changes in body weight at 2, 10, 15, and 20 years were −23%, −17%, −16%, and −18% in the surgery group and 0%, 1%, −1%, and −1% in the control group). After 15 years, the mean percent weight loss by procedure type was 27 + 12% for RYGB, 18 + 11% for VBG, and 13 + 14% for gastric banding.The SOS study also showed major improvements in obesityrelated comorbidities. In the surgical group, there was a 72% remission of T2DM after 2 years (OR for remission: 8.4) and 36% durable remission after 10 years (OR for remission: 3.5). In spite of the considerable relapse of T2DM over time, bariatric surgery was associated with a lower incidence of myocardial infarction and other T2DM complications. The SOS study dem-onstrated that bariatric surgery also reduced the risk of incident T2DM by 96%, 84%, and 78% after 2, 10, and 15 years among subjects without the condition at baseline. The SOS study also 6Brunicardi_Ch27_p1167-p1218.indd 119323/02/19 2:21 PM 1194SPECIFIC CONSIDERATIONSPART IITable 27-6Long-term studies of bariatric surgery outcomesaAUTHORSTUDY DESIGNPOPULATIONS AND PROCEDURESFOLLOW-UP DURATIONPUBLISHED OUTCOMESMORTALITY AND SURVIVALLIMITATIONSSjöström et al,196-201 2004, 2007, 2009, and 2012 (Swedish Obese Subjects study [SOS])Prospective observational with matched controls2010 Surgical cases (13% RYGB; 19% banding; 68% VBG) and 2037 matched controls10–20 years, depending on the reportSurgery was associated with: greater weight loss at 2 years (–23% vs. 0%) and at 20 y (–18% vs. –1%)16; greater remission of T2DM after 2 y (OR for remission, 8.4; P <.001) and 10 y (OR, 3.5; P <.001); lower incidence of T2DM (HR, 0.17; P <.001)Bariatric surgery treatment: 16 years, 29% lower risk of death from any cause (hazard ratio 0.71, 0.54 to 0.92; P = 0.01) vs. usual care; common causes of death: myocardial infarction (HR, 0.71; P = .02), stroke (HR, 0.66; P = .008), and cancer (in women only; HR, 0.58; P <.001)Not randomized; includes mostly procedures (87%) that are no longer in use; involves patients from a single country with little racial/ethnic diversityAdams et al,202 2007 (Utah Mortality study)Retrospective observational with matched controls7925 RYGB cases and 7925 weight-matched controlsMean, 7.1 yearsOnly mortality outcomes reportedBariatric surgery treatment: average 7.1 years post treatment, 40% reduction in all cause mortality (hazard ratio HR 0.60, 0.45 to 0.67; P <0.001), 49% (HR 0.51, 0.36 to 0.73; P <0.001), and 92% (HR 0.08, 0.01 to 0.47; P = 0.005), cardiovascular mortality, and T2DM mortality, respectivelyNot randomized; matching based on self-reported height and weight from driver’s license database; includes only RYGB procedures; patients from a single stateAdams et al,203,204 2012, 2017 (Utah Obesity study)Prospective observational with two matched control groups418 RYGB cases; 417 bariatric-surgery seekers who did not undergo operation (control 1); 321 population-based matched controls (control 2)6 years, 12 years6 years: RYGB group lost 27.7% body weight compared with 0.2% weight gain in control group 1 and 0% change in control group 2; T2DM remission in 62% of RYGB patients and 8% and 6% in each of the control groups (P <.001); incident T2DM was observed in 2% of RYGB patients but 17% and 15% of each of the control groups at 6 years (P <.001); surgery associated with greater improvements in blood pressure, cholesterol, and quality of life (P <.01)Deaths at 6 years: 12 (2.8%), 14 (3.3%), and 3 (0.93%) for bariatric surgery, control 1, and control 2, respectivelyNot randomized; includes only RYGB procedures; patients from a single stateBrunicardi_Ch27_p1167-p1218.indd 119423/02/19 2:21 PM 1195THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 2712 years: RYGB 26.9% body weight loss, 2.0% and 0.9% in control groups 1, 2, respectively; T2DM remission in 51% RYGB group; odds ratio for the incidence T2DM 0.08 (95% CI, 0.03 to 0.24) for RYGB vs. control group 1 and 0.09 (95% CI, 0.03 to 0.29) RYGB vs. control group 2 (P <0.001 for both comparisons); RYGB group had higher remission rates and lower incidence rates of hypertension and dyslipidemia than did control group 1 (P <0.05 for all comparisons).Maciejewski et al,205-208 2011, 2012, 2015, 2016 (Department of Veterans Affairs)Retrospective observational with matched controls847 to 1787 to 2500 surgical cases and their matched controls6.7 yearsPatients undergoing RYGB lost 28.6% (95% CI, 19.5%–37.6%) of their baseline weight at 10 years, whereas nonsurgical matches lost 7.3% (95% CI, 1.4%–13.3%) of their baseline weight at 10 years. Patients undergoing RYGB lost 21% (95% CI, 11%–31%) more of their baseline weight at 10 years than nonsurgical matches. A total of 405 of 564 patients undergoing RYGB (71.8%) had more than 20% body weight loss and 224 of 564 (39.7%) had more than 30% estimated weight loss at 10 years.At 4 years, patients undergoing LRYGB lost 27.5% (95% CI, 23.8%–31.2%) of their baseline weight, patients undergoing LAGB lost 10.6% (95% CI, 0.6%–20.6%), and patients undergoing SG lost 17.8% (95% CI, 9.7%–25.9%).Surgery was not significantly associated with lower health expenditures 3 years after the procedure, in first study.First study, in 2011, bariatric surgery not significantly associated with reduced mortality.Later study, at the end of 14 years, 263 deaths in the surgical group (mean follow-up, 6.9 years) and 1277 deaths in control group (mean follow-up, 6.6 years). Mortality rates were 2.4% at 1 year, 6.4% at 5 years, and 13.8% at 10 years for surgical patients; for matched control patients, 1.7% at 1 year, 10.4% at 5 years, and 23.9% at 10 years. Significantly lower mortality after 1 to 5 years (HR, 0.45 [95% CI, 0.36–0.56]) and 5 to 14 years (HR, 0.47 [95% CI, 0.39–0.58]).Not randomized; includes older (mean age, 55 years), primarily male (74%) veterans; mortality studies mostly RYGB procedures(Continued)Brunicardi_Ch27_p1167-p1218.indd 119523/02/19 2:21 PM 1196SPECIFIC CONSIDERATIONSPART IICourcoulas et al,59,169 2009, 2013, 2017 (Longitudinal Assessment of Bariatric Surgery [LABS])Prospective observational4776 in LABS-1, 30 day safety study and 2458 in LABS-2, effectiveness study (70.7% RYGB; 24.8% LAGB; and 5% other procedures)30 days, 3 years, 7 years3 year: 31.5% for RYGB and 15.9% for LAGB; T2DM remission in 67.5% of RYGB cases and 28.6% for LAGB; incidence of T2DM was 0.9% after RYGB and 3.2% after LAGB. Dyslipidemia remission in 61.9% RYGB cases and 27.1% AGB cases; HTN remission in 38.2% RYGB cases and 17.4% AGB cases; other procedures’ results not reported7 year: 28.4% for RYGB and 14.9% for LAGB; T2DM remission in 60.2% of RYGB cases and 20.3% for LAGB30 days: 0.3% overall; 0% LAGB, 0.2% LRYGB, and 2.1% open RYGB.3 years: 0.9 per 300 person-years for TYGB and 0.8 per 300 person-years for LAGB, i.e., number of events if 100 people were followed for 3 years7 years: 3.7 per 700 person-years for RYGB and 2.7 per 700 person years for LAGB, i.e., number of events if 100 people were followed for 7 yearsNot randomized; lacks nonsurgical control population; primarily RYGB and LAGB procedures; high follow-up rates (>80% for weight) but some not in-personArterburn et al,212,213 2013 (HMO Research Network)1. Retrospective observational2. Retrospective observational with matched controls4434 RYGB cases with T2DM1395 cases; 72% RYGB, 2% SG, 4% LAGB, 13% otherMedian, 3.1 years2 years68% of patients (95% CI, 66–70) experienced an initial T2DM remission within 5 years after RYGB; among these, 35.1% (95% CI, 32–38) redeveloped T2DM within 5 years; median duration of T2DM remission, 8.3 yearsBariatric cases higher T2DM remission rates [73.7% (95% CI: 70.6, 76.5)] vs. controls [6.9% (95%CI: 6.9, 7.1)]. Bariatric cases lower relapse rates T2DM than controls (adjusted HR: 0.19; 95% CI: 0.15–0.23)Not reportedNo higher risk of death in control vs. bariatric within 2 years (adjusted HR = 0.54; 95% CI: 0.22 to 1.23).1. Not randomized; lacks nonsurgical control population; only RYGB procedures2. Not randomized, electronic medical record data, small number SGCarlin et al,215 2013 (Michigan Bariatric Surgery Collaborative)Prospective observational8847 to 35,477, varies depending on publication30 days to 3 years, varies depending on publicationComplication rates for SG (6.3%) were significantly lower than for RYGB (10.0%; P <.001) but higher than LAGB (2.4%; P <.001). Excess body weight loss at 1 year was 13% lower for SG (60%) than for RYGB (69%; P <.001) but was 77% higher for SG than for LAGB (34%; P <.001).Not reportedNot randomized; lacks nonsurgical control; patients from a single stateaData from Courcoulas AP, Yanovski SZ2, Bonds D, et al: Long-term outcomes of bariatric surgery: a National Institutes of Health symposium, JAMA Surg. 2014 Dec;149(12):1323-1329.Table 27-6Long-term studies of bariatric surgery outcomesa (Continued)AUTHORSTUDY DESIGNPOPULATIONS AND PROCEDURESFOLLOW-UP DURATIONPUBLISHED OUTCOMESMORTALITY AND SURVIVALLIMITATIONSBrunicardi_Ch27_p1167-p1218.indd 119623/02/19 2:21 PM 1197THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27found that bariatric surgery was associated with a reduced inci-dence of fatal or nonfatal cancer among women but not in men. Finally, at 16 years follow-up, surgery was associated with a 29% lower risk of death (the primary endpoint of the study) from any cause compared to usual care, with the most common causes of death being cancer and myocardial infarction196-201 (see Table 27-6).Utah Obesity Studies. Another important long-term obser-vational study performed in Utah from 1984 to 2002 included 7925 people who had undergone RYGB and 7925 weight, age, and sex matched controls. This study showed a 40% reduction in all-cause mortality (hazard ratio 0.60, 0.45 to 0.67; P <0.001) and a 49% (0.51, 0.36 to 0.73; P <0.001) and 92% (0.08, 0.01 to 0.47; P = 0.005) reduction in death from cardiovascular disease and death related to T2DM, respectively, at an average of 7.1 years later.202A separate ongoing prospective Utah Obesity Study involving over 400 RYGB cases and two nonrandomized, matched control groups—each with over 400 and 300 severely obese subjects (one group were people seeking surgery that did not undergo operation; the other was a population-based severely obese control group)—has found that the surgery group lost 27.7% of their initial body weight compared to 0.2% weight gain in control group 1 (surgery seekers), and 0% change in control group 2 (population-based control) at 6 years. Diabetes was in remission in 62% of RYGB patients and only 8% and 6% in each of the control groups, while incident T2DM was observed in 2% of RYGB patients and in 17% and 15% of the control groups at 6 years.203 The 12-year follow-up results were also recently published and showed long-term durability of weight loss and effective remission and prevention of T2DM, hypertension, and dyslipidemia after RYGB.204 Follow-up rates in this study were high at over 90% at 12 years. The mean per-cent change from baseline in body weight in the RYGB group was −26.9% at 12 years compared to −2.0% and 0.9% in each of the two control groups. There was remission of T2DM in 43 of 84 patients (51%) at 12 years. The OR for the incidence of T2DM at 12 years was 0.08 (95% CI, 0.03–0.24) for the RYGB group versus control group 1 and 0.09 (95% CI, 0.03–0.29) for the RYGB group versus control group 2 (P <0.001 for both comparisons). The RYGB group had higher remission rates and lower incidence rates of hypertension and dyslipidemia than did control group 1 (P <0.05 for all comparisons) (see Table 27-6).Veteran’s Administration Study. A retrospective obser-vational study involving 847 U.S. veterans who were older and more high risk than in typical bariatric studies, found no significant association between bariatric surgery and survival compared to usual care at mean 6.7 years follow-up.205 When matched to control subjects, the outpatient, inpatient, and total expenditures were higher for bariatric surgical cases in the 3 years leading up to the procedure and then went back to the lower cost levels of nonsurgical controls in 3 years after the procedure. The conclusion from this study was that bariatric surgery did not appear to be associated with reduced health care expenditures 3 years after the procedure.206In a follow-up retrospective cohort study, 2500 U.S. veterans (74% men) who underwent bariatric surgery (74% gastric bypass, 15% sleeve gastrectomy, 10% adjustable gastric banding, and 1% other) were matched to 7462 control patients. The primary outcome was all-cause mortality. In this study, surgical patients (n = 2500) had a mean age of 52 years and a mean BMI of 47. Matched control patients (n = 7462) had a mean age of 53 years and a mean BMI of 46. At the end of the 14-year study period, there were a total of 263 deaths in the surgical group (mean follow-up, 6.9 years) and 1277 deaths in the matched control group (mean follow-up, 6.6 years). Mor-tality rates were 2.4% at 1 year, 6.4% at 5 years, and 13.8% at 10 years for surgical patients; for matched control patients, 1.7% at 1 year, 10.4% at 5 years, and 23.9% at 10 years. So, in this later study, there was significantly lower all-cause mortal-ity at longer follow-up. 207Ten-year weight change in 1787 veterans who underwent RYGB compared to controls, and separately, 4-year weight change in veterans who underwent RYGB (n = 1785), SG (n = 379), and AGB (n = 246) were reported. Patients undergo-ing RYGB lost 21% more of their baseline weight at 10 years than nonsurgical matches. A total of 405 of 564 patients under-going RYGB (71.8%) had more than 20% weight loss, and 224 of 564 (39.7%) had more than 30% weight loss at 10 years com-pared with 134 of 1247 (10.8%) and 48 of 1247 (3.9%), respec-tively, for nonsurgical matches. At 4 years, patients undergoing LRYGB lost 27.5% of their baseline weight, patients undergo-ing LAGB lost 10.6%, and patients undergoing SG lost 17.8%. Patients undergoing RYGB lost 16.9% more of their baseline weight than patients undergoing AGB and 9.7% more than patients undergoing SG208 (see Table 27-6).The Longitudinal Assessment of Bariatric Surgery Study. The Longitudinal Assessment of Bariatric Surgery (LABS-1) study, a multicenter observational surgical cohort, prospectively assessed 30-day safety among 4776 severely obese patients who underwent a first bariatric surgical procedure (25% AGB, 62% laparoscopic RYGB, 9% open RYGB, and 3% another procedure) between 2005 and 2007.59 The 30-day mortality in the LABS study was 0.3% for all procedures with a major adverse outcome rate (a predefined composite endpoint that included death, venous thromboembolism, reintervention [percutaneous, endoscopic, or operative], or failure to be discharged from the hospital in 30 days) of 4.1%. These results did vary by procedure and approach, with no mortality in the 1198 patients who had undergone LAGB, 0.2% of the 2975 patients who had undergone LRYGB, and 2.1% of the 437 patients who had undergone open RYGB. Similarly, the rate of adverse outcomes (morbidity) occurred in 4.1% of patients overall; 1.0% for LAGB, 4.8% for LRYGB, and 7.8% for open RYGB.59 The Longitudinal Assessment of Bariatric Surgery (LABS-2) study is another large prospective multicenter observational bariatric cohort study that was not randomized and did not include a nonsurgical control group. LABS-2 assessed weight change and comorbid conditions in 2458 participants (1738 RYGB—both open and laparoscopic, 610 LAGB, and 110 other procedures) recruited between 2005 and 2009 who were followed for 7 years.169,209 At baseline, 33% had diabetes, 63% had dyslipidemia, and 68% had hypertension. In the LABS-2 cohort, median weight change was 31.5% for RYGB and 15.9% for adjustable gastric banding after 3 years, with much variability in response to each surgical treatment. Remission of T2DM was noted in 67% and 28% of those who had undergone RYGB and LAGB, respectively. The incidence T2DM was 0.9% and 3.2%, respectively, over the 3 years169 (see Table 27-6). LABS-2 looked at both preand postoperative predictors of weight change and found that very few of many baseline variables studied (Black race, T2DM) were associated Brunicardi_Ch27_p1167-p1218.indd 119723/02/19 2:21 PM 1198SPECIFIC CONSIDERATIONSPART IIwith 3-year weight change, and the effects were small overall. Postoperatively, for RYGB only, three behaviors explained most of the variability (16%) in 3-year weight change: weekly self-weighing, continuing to eat when feeling full more than once a week, and eating continuously during the day. If a person started weekly self-weighing, stopped eating when feeling full, and stopped eating continuously during the day, they lost 14% more weight than those who made no positive changes (38.8% vs. 24.6% TBWL).210,211At 7 years of follow-up, in LABS, data completeness for weight was high (83%), and the median weight change was 28.4% for RYGB and 14.9% for LAGB. Weight regain between years 3 and 7 was 3.9% of baseline weight for RYGB and 1.4% for LAGB, but 75% of RYGB participants maintained at least 20% total body weight loss, and 50% of LAGB participants maintained at least 16% through 7 years. Remission of T2DM was reported in 60.2% of RYGB cases and 20.3% for LAGB. Mortality was reported as 3.7 per 700 person-years for RYGB and 2.7 per 700 person years for LAGB, i.e., number of events if 100 people were followed for 7 years. Reoperations were also much more common after LAGB compared to RYGB at 7 years (see Table 27-6).HMO Research Network. Arterburn and colleagues have leveraged the integrated health network system to study bariatric outcomes using the electronic health/medical record. They studied clinical predictors of diabetes remission and relapse among patients undergoing gastric bypass. Theirs was a retrospective cohort study of adults with uncontrolled or medication-controlled T2DM who underwent gastric bypass in three integrated health care delivery systems in the United States. Remission and relapse events were defined by diabetes medication use and clinical laboratory measures of glycemic control. Of 4434 adults with T2DM who underwent RYGB, 68.2% (95% CI, 66% and 70%) experienced an initial complete diabetes remission within 5 years after surgery. Among these, 35.1% (95% CI, 32% and 38%) relapsed back to T2DM within 5 years. The median duration of their remission was 8.3 years. Predictors of incomplete remission and relapse were poor preoperative glycemic control, insulin use, and longer diabetes duration212 (see Table 27-6).In a second study, they compared rates of diabetes remission, relapse, and all-cause mortality at 2 years between severely obese adults with T2DM who underwent bariatric surgery or received usual medical care. There were 1395 adults with T2DM who had bariatric surgery and 62,322 who did not. Most procedures were RYGB (72.0% laparoscopic; 8.2% open); 4.4% were gastric banding, 2.4% were sleeve gastrectomy, and 13.2% were other procedures. At 2 years, bariatric subjects experienced significantly higher diabetes remission rates (73.7% [95% CI: 70.6, 76.5]) compared to nonsurgical subjects (6.9% [95% CI: 6.9, 7.1]). Age, site, duration of diabetes, hemoglobin A1c level, and intensity of diabetes medication treatment were significantly associated with remission. Bariatric subjects also experienced lower relapse rates than nonsurgical subjects (adjusted HR: 0.19; 95% CI: 0.15–0.23) with no higher risk of death (adjusted HR: 0.54; 95% CI: 0.22–1.30) (see Table 27-6).213 This group also studied short-term comparative effectiveness outcomes between procedures (LRYGB and LAGB) and found that LRYGB resulted in much greater weight loss than LAGB but had a higher risk of short-term complications and long-term subsequent hospitalizations.214Michigan Bariatric Surgery Collaborative. The Michigan Bariatric Surgery Collaborative is a statewide consortium of hospitals and surgeons that maintains an externally audited prospective clinical registry. The comparative effectiveness of SG, LRYGB, and LAGB procedures was studied in this data-set. Nearly 3000 SG patients with equal numbers of RYGB and LAGB patients were matched on 23 baseline characteristics. Outcomes assessed included 30-day complications, weight loss, quality of life, and comorbid remission up to 3 years after bar-iatric surgery. Overall complication rates for SG (6.3%) were significantly lower than for RYGB (10%) but higher than for LAGB (2.4%). Serious complication rates were similar for SG (2.4%) and LRYGB (2.5%) but higher than for LAGB (1.0%). Excess body weight loss at 1 year was 13% lower for SG (60%) than for RYGB (69%), but was 77% higher for SG than for LAGB (34%). Remission of comorbid conditions was similar between SG and LRYGB215 (see Table 27-6).This group also developed a risk prediction model for seri-ous 30-day complications after bariatric surgery. Overall, 2.5% of patients experienced a serious complication. Significant risk factors included prior venous thromboembolism (OR 1.90, CI 1.41–2.54); mobility limitations (OR 1.61, CI 1.23–2.13); coro-nary artery disease (OR 1.53, CI 1.17–2.02); age over 50 (OR 1.38, CI 1.18–1.61); pulmonary disease (OR 1.37, CI 1.15–1.64); male gender (OR 1.26, CI 1.06–1.50); smoking history (OR 1.20, CI 1.02–1.40); and procedure type.216 Further, to assess the rela-tionship between IVC filter insertion and complications while controlling for differences in baseline patient characteristics and medical venous thromboembolism prophylaxis, this group pub-lished an additional study, and 35,477 patients from 32 hospitals in Michigan were included. Patients receiving IVC filters had higher rates of pulmonary embolism, deep vein thrombosis, venous thromboembolism, serious complications, and death.217Recently, this group has also been evaluating the effect of surgical skill and operative technique on complications follow-ing bariatric surgery.218,219Other StudiesMetabolic and Bariatric Surgery Quality Improvement Pro-gram (MBASQIP). This is a prospective, multi-institutional, national database that has been used to compare SG to RYGB and LAGB. The study from 2011 was short term and compared 30-day, 6-month, and 1-year outcomes including morbidity and mortality, readmissions, and reoperations as well as reduction in BMI and weight-related comorbid conditions. The findings were that SG has higher risk-adjusted morbidity, readmission and reop-eration/intervention rates compared to LAGB, but lower reopera-tion/intervention rates compared to RYGB either laparoscopic or open. There were no differences in mortality. Reduction in BMI and most of the weight-related comorbidities after SG was also between LAGB and RYGB rates.140A later study addressed the impact of various SG techniques on short-term (30-day) outcomes. Using the MBSAQIP data reg-istry, 189,477 SG operations that were performed at over 700 cen-ters in the United States were analyzed. Cases in which staple line reinforcement was used were associated with higher leak rates and lower bleeding rates. Bougie size ≥38 French was associated with significantly lower leak rates compared to <38 French.162 Longer-term data will eventually be available from this national dataset, but the completeness of follow-up has not yet been determined.Geisinger Health System. This is an electronic medical record database in a large rural integrated health system. They Brunicardi_Ch27_p1167-p1218.indd 119823/02/19 2:21 PM 1199THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27have published long-term results (7–12 years) of the percent-age of TBWL and preoperative predictors for LRYGB in approximately 700 patients. Over 200 preoperative clinical fac-tors were studied. At a median of 9.3 postoperative years fol-lowing surgery, the mean (SD) percentage TBWL was 22.5% (13.1%). Preoperative insulin use, history of smoking, and use of 12 or more medications before surgery were associated with greater long-term weight loss; 6.8%, 2.8%, and 3.1%, respec-tively. Preoperative hyperlipidemia, older age, and higher body mass index were associated with poorer long-term weight loss (−2.8%, −8.8%, and −4.1%, respectively). Again, there were only a few preoperative clinical factors associated with differ-ences in long-term weight loss after RYGB.220This group also developed a method to predict the probability of T2DM remission after RYGB surgery on the basis of preop-erative clinical criteria in a retrospective cohort study. Over 200 clinical variables were used to identify independent predictors of remission within 5 years and to produce a score (DiaRem) to assess this likelihood. Records were available for 690 patients in the pri-mary cohort, of whom 463 (63%) had achieved partial or com-plete T2DM remission. Four preoperative clinical variables were included in the final model: insulin use, age, HbA1c concentration, and type of antidiabetic drugs. The DiaRem score was developed from that, and it ranges from 0 to 22 with the proportion of patients achieving remission being highest for the lowest scores.221Comparisons Between ProceduresThere have been many systematic reviews of bariatric surgery attempting to summarize and quantify differences in the efficacy and safety of the different surgical procedures. A major challenge in summarizing this literature from the last 10 years is the fact that no single randomized trial has included all of the most com-mon procedures (RYGB, LAGB, SG, and BPD/DS), so infer-ence must be made through pooled analysis of data from many disparate randomized and non-randomized studies of bariatric surgery with different lengths and completeness of follow-up. There are also no studies that have examined differences in long-term survival, incident cardiovascular events, and quality of life across bariatric procedures.1 Still one of the most compre-hensive systematic reviews by Buchwald included 136 studies and a total of 22,094 bariatric patients. Only 5 of the included studies were randomized trials (28 non-RCTs and 101 uncon-trolled case series) and the review did not include any data on the SG procedure, so will need to be updated. This review found a strong trend towards different weight loss outcomes across procedures: weighted mean percentage of excess weight loss (%EWL) 50% for LAGB; 68% for RYGB; 69% for VBG; and 72% for BPD/DS. The rate of T2DM remission also appeared to differ across procedures: 48% for LAGB; 84% for RYGB; 72% for VBG; and 99% for BPD/DS. A similar pattern of dis-ease remission was observed for dyslipidemia, hypertension, and obstructive sleep apnea, with the greatest rates of remission observed among BPD/DS patients, followed by RYGB patients, with the least disease remission among LAGB patients.192There is still ongoing debate regarding the comparative effectiveness of the three most common procedures currently in use: LRYGB, SG, and LAGB. Several other systematic reviews have concluded that LRYGB is more effective for weight loss than LAGB; however, there have been only two small RCTs with follow-up at 4 and 5 years addressing this issue specifically.65,222,223 There is evolving data from a number of smaller RCTs to examine differences between LRYGB, LAGB, and SG for comorbidity improvement (addressed in “Results of Surgery for Diabetes”), but systematic reviews of nonrandomized studies indicate greater remission of T2DM, dyslipidemia, hypertension, and sleep apnea with LRYGB compared to LAGB. Two recent systematic reviews have compared the outcomes of the SG with other procedures.224,225 One review identified 15 RCTs involving 1191 patients. The percent excess body weight loss (%EBWL) ranged from 49% to 81% for SG, from 62% to 94% for LRYGB, and from 29% to 48% for LAGB, with a follow-up ranging from 6 months to 3 years. The T2DM remission rate ranged from 27% to 75% for SG vs. 42% to 93% for RYGB. The second review only compared SG to RYGB and identified 6 RCTs and two nonrandomized controlled studies with follow-up ranging from 3 months to 2 years. They found that LRYGB achieved significantly greater improvement in BMI than SG (1.8 kg/m2) and greater improvements in metabolic factors. Longer-term comparative effectiveness data on SG are still needed, but the effectiveness of the SG procedure, again, appears to be positioned between the LRYGB and LAGB procedures.Resolution of Specific Comorbid ConditionsBariatric surgery can improve and induce remission of many obesity-related comorbid conditions. Nevertheless, the remis-sion rates can decline over time due to relapse of disease, and as follow-up lengthens, complete and more longer-term follow-up data is needed in some areas.Cardiovascular Disease. A recent systematic review of long-term cardiovascular risk factor reduction after bariatric surgery involved 73 studies and 19,543 subjects with a mean age of 42 years; 76% of subjects were female, and 44%, 24%, and 44% had baseline hypertension, diabetes, and hyperlipidemia, respectively.226 At a mean follow-up of 57.8 months, the aver-age excess weight loss for all bariatric procedures was 54%, and remission/improvement was 63% for hypertension, 73% for T2DM, and 65% for hyperlipidemia. Echocardiographic results from 713 subjects showed statistically significant improve-ments in hemodynamics. There are no long-term RCTs com-paring bariatric surgery with nonsurgical medical treatment of obesity that specifically evaluate cardiovascular endpoints and cardiovascular mortality. However, 12 cohort-matched studies comparing bariatric surgery with nonsurgical controls have been reviewed.227 Collectively, all but two of these studies support a reduced cardiovascular event rate and all-cause mortality rate conferred by bariatric surgery. Of these studies, the Swedish Obesity Subjects (SOS) study still has the longest outcomes.Gastroesophageal Reflux Disease. Patients with obesity and GERD have a higher chance of failing to obtain symptomatic relief from standard antireflux surgery. The recurrence of symp-toms is higher, likely due to a higher incidence of wrap hernia-tion into the mediastinum and other mechanical failure of the fundoplication, which in turn is likely affected by the increased intra-abdominal pressure of the obese condition. The patient with a BMI over 35 kg/m2 who has GERD has a better chance of symptom improvement by undergoing LRYGB, which is effective for the treatment of GERD.228,229 LRYGB creates such a small gastric pouch that it has a very limited volume for acid production. LAGB may worsen or may improve GERD but to a considerably lesser extent than RYGB. A prospective analysis of 558 consecutive SG (n = 200) and LRYGB (n = 358) patients demonstrated significantly improved subjective GERD symp-toms in the bypass cohort when compared to the SG patients at Brunicardi_Ch27_p1167-p1218.indd 119923/02/19 2:21 PM 1200SPECIFIC CONSIDERATIONSPART II1 year.230 Studies show that SG can increase GERD symptoms postoperatively.Obstructive Sleep Apnea. A systematic review of 13,900 patients (69 studies) showed significant improvement or reso-lution of sleep apnea in more than 75% of bariatric surgery patients.231 Comparison of outcomes between procedures dem-onstrated the most benefit with BPD and RYGB and the least with LAGB. However, a randomized control trial comparing the effect of medical and surgical weight loss (LAGB) on sleep apnea found no significant difference in apnea events despite major differences in weight loss. The findings suggested that much of the improvement achieved was in the mild to moderate weight loss range, with little benefit of further weight loss.232Asthma. Another pulmonary symptom that commonly occurs in severely obese patients is asthma. Dixon and colleagues233 studied 23 asthmatic patients who underwent bariatric surgery and found a significant improvement in asthma control (e.g., forced expiratory volume in 1 second, forced vital capacity), asthma-related quality of life, and responsiveness to methacholine. Boulet and colleagues234 found similar results in their cohort of 12 patients with asthma who experienced significant weight loss after bariatric surgery.Nonalcoholic Fatty Liver Disease.  Nonalcoholic Fatty Liver Disease (NAFLD) is a metabolically related problem associated with obesity. The disease is a spectrum of liver abnormalities including steatosis, steatohepatitis, fibrosis, and cirrhosis of the liver. It is estimated that 20% of U.S. adults have NAFLD, largely because of the high incidence of obesity. NAFLD is present in an estimated 85% of patients with severe obesity.235 Although further research is needed to accurately assess the role of bariatric surgery as a potential treatment for NAFLD, there are some reports that support its use. A systematic review of the available literature found many retrospective and prospective observational cohort studies, but no RCTs or case-control series.236Musculoskeletal Disease. Degenerative joint disease and low back pain are among the most common complaints and asso-ciated comorbid problems in the severely obese population. A prospective cohort of 50 obese females age 20 to 74 years were followed for 1 year after LRYGB using the timed-get-up-and-go (TGUG) and health survey SF-36.237 The results showed a significant improvement in musculoskeletal function and likely enhanced ability to progress in rehabilitation. Patients with osteoarthritis of the neck, shoulder, spine, hip, knee, ankle, wrist, and hand have been shown to have improved or resolved joint pain after bariatric surgery. Reduction in BMI values of 6.2 to 14.7 kg/m2 has corresponded with back and knee pain resolution in 5% to 100% of patients, whereas pain severity was reduced in 31% to 94% of patients depending on the joint and study.238The LABS-2 Study published data on pain and physical function in over 2200 participants. At year 1, clinically mean-ingful improvements were shown in 57.6% of participants for bodily pain, 76.5% for physical function, and 59.5% for walk time. Additionally, among participants with severe knee or dis-ability (633), or hip pain or disability (500) at baseline, approxi-mately three-fourths experienced joint-specific improvements in knee pain (77.1%) and in hip function (79.2%). But between year 1 and year 3, rates of improvement significantly decreased for both bodily pain and for physical function.239Quality of Life. Few long-term studies have assessed the impact of bariatric surgery on overall quality of life. However, three studies of 6 to 10 years’ duration suggest that bariatric pro-cedures are associated with greater improvements in overall and obesity specific measures of quality of life compared to medical treatment or care.240-242 Physical functioning aspects of quality of life seem to be more responsive to bariatric procedures than mental health domains, although more research is needed, espe-cially in patients with less severe (class 1) obesity.Results of Surgery for Diabetes (Metabolic Surgery)Based on an abundance of recent observational studies and RCTs, bariatric surgery is increasingly used with the primary intent to treat T2DM or metabolic disease, hence the term meta-bolic surgery.243 Observational, nonrandomized studies first demonstrated profound improvements in hyperglycemia and other cardiovascular risk factors following metabolic surgery that were followed by RCTs. Resolution or remission of T2DM is typically defined as becoming “nondiabetic” with normal HbA1c, without medications. One meta-analysis (2009) of 19 mostly observational studies (n = 4,070 patients) reported an overall T2DM remission rate of 78% after bariatric surgery with 1 to 3 years follow-up.244 The patients all had BMI >35 and gen-erally early/mild T2DM that likely increased remission rates. In the Swedish Obese Subjects study, the remission rate follow-ing surgery was 72% at 2 years and 36% at 10 years compared with 21% and 13%, respectively, for the nonsurgical controls (P <.001).201 Metabolic surgery was also significantly more effective than nonsurgical treatment in preventing new onset cases of T2DM, with a relative risk reduction of 78%.A more recent systematic review (2012) evaluated long-term cardiovascular risk reduction after bariatric surgery in 73 studies and 19,543 patients.226 At a mean follow-up of 57.8 months, the average excess weight loss for all procedures was 54%, and rates of remission or improvement were 63% for hyper-tension, 73% for T2DM, and 65% for hyperlipidemia. Results from 12 cohort-matched, nonrandomized studies comparing bariatric surgery vs. nonsurgical controls demonstrated reduced cardiovascular events and death (30–88% reduction) in patients with and without T2DM.227 One of these studies involving male veterans, who were mostly at high cardiovascular risk, reported a 42% reduction in mortality at 10 years compared with medical therapy.207 Similarly, in the Swedish Obese Subjects study, the mortality rate from cardiovascular disease in the bariatric surgical group was lower than for control patients (adjusted hazard ratio, 0.47; P = .002).201 For patients with T2DM in this study, surgery was associated with a 50% reduction in microvascular complica-tions (41.8 per 1000 person-years for control patients and 20.6 per 1000 person-years in the surgery group; hazard ratio, 0.44; P <.001).245 These observational, nonrandomized studies provide evidence that metabolic surgery is superior to medical manage-ment alone in improving glycemic control, reducing cardiovascu-lar risk factors, and lowering long-term morbidity and mortality of T2DM, yet supporting RCTs have been lacking until recently.During the past 10 years, 11 such RCTs have been published including 794 patients in total (Table 27-7).16,77-83,85,86,246-253 These RCTs included obese patients with T2DM (n = 794; range 38–150 patients per study) with follow-up from 6 months to 5 years (Fig. 27-27). All common metabolic surgical procedures were represented including LRYGB (9 studies), LAGB (5 studies), SG (2 studies), and BPD (1 study). T2DM severity varied significantly from mild (mean HbA1c 7.7%, <2-year onset, no insulin)253,77 to severe (mean HbA1c 9.3%, duration 8.3 years, 48% on insulin).78 The BMI ranged from 25 to 53 kg/m2, with 11 of 12 studies including patients with BMI <35 kg/m2, also called class 1 obesity. Age, sex, and ethnic background were similar, 7Brunicardi_Ch27_p1167-p1218.indd 120023/02/19 2:21 PM 1201THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27Table 27-7Metabolic surgery randomized controlled trials for type 2 diabetes (n = 794)aSTUDYBMI (kg/m2), % OF PATIENTSDESIGNNO. OF PATIENTS RANDOMIZEDFOLLOW-UP (MONTHS)REMISSION CRITERIA*OUTCOME (REMISSION OR CHANGE IN HbA1C)Dixon77<35, 22%LAGB vs. control6024HbA1c <6.2%73% vs. 13%, P <0.001Schauer78,246,252<35, 36%RYGB vs. SG vs. control15060HbA1c ≤6.0%22% vs. 15% vs. 0, P<0.05Mingrone79,82>35, 100%RYGB vs. BPD vs. control6060HbA1c ≤6.5%42% vs. 68% vs. 0, P = 0.003Ikramuddin 80,247<35, 59%RYGB vs. control12024HbA1c <6%44% vs. 9%, P <0.001Liang248<35, 100%RYGB vs. control10112HbA1c <6.5%**90% vs. 0 vs. 0, P <0.0001Halperin83<35, 34%RYGB vs. control3812HbA1c <6.5%58% vs. 16%, P = 0.03Courcoulas84,86<35, 43%RYGB vs. LAGB vs. control6936HbA1c <6.5%40% vs. 29% vs. 0, P = 0.004Wentworth250≤30, 100%LAGB vs. control5124Fasting blood glucose <7.0 mmol/L52% vs. 8%, P = 0.001Parikh251<35, 100%Bariatric surgery (RYGB, LAGB, SG) vs. control576HbA1c <6.5%65% vs. 0, P = 0.0001Ding85<35, 34%LAGB vs. control4512HbA1c <6.5%***33% vs. 23%, P = 0.46Cummings81<35, 25%RYGB vs. control4312HbA1c <6.0%60% vs. 5.9%, P = 0.002*Remission defined as reaching HbA1c value without medication, unless otherwise specified**Remission not precisely defined, extrapolated***On or off medicationsReproduced with permission from Schauer PR, Mingrone G2, Ikramuddin S, et al: Clinical Outcomes of Metabolic Surgery: Efficacy of Glycemic Control, Weight Loss, and Remission of Diabetes, Diabetes Care. 2016 Jun;39(6):902-911.although three studies80,247,248 included a significant number of Asian patients. For most studies, the primary endpoint was remission, defined as an HbA1c target at or below 6.0% to 6.5% without use of diabetes medications.Overall, these RCTs showed that surgery was signifi-cantly more effective than medical treatment in reaching remission and glycemic control (P <.05) (Fig. 27-27). The one exception showing no superiority of surgery involved gastric banding and resulted in a diabetes remission for LAGB vs. medical treatment of 33% and 23%, respectively (P >0.05).85 Overall, surgery decreased HbA1c by 2% to 3.5%, whereas medical treatment lowered it by 1% to 1.5%, as seen in Fig. 27-28. Most of these studies also showed superiority of surgery over medical treatment in achieving secondary endpoints such as weight loss, remission of metabolic syn-drome, reduction in diabetes and cardiovascular medications, and improvement in triglycerides, lipids, and quality of life. Results were mixed in terms of improvements in systolic and diastolic blood pressure or low-density lipoproteins after sur-gery vs. medical treatment, but many studies did show a cor-responding reduction in medication usage.Although previous guidelines and payer coverage policies had limited metabolic surgery to severely obese patients (BMI ≥35 kg/m2), nearly all RCTs showed that the surgical procedures, especially LRYGB and SG, were equally effective in patients with BMI 30 to 35 kg/m2. This is particularly important given that many patients with T2DM have a BMI <35 kg/m2. The effect of surgery in these patients with a lower class of obesity is also durable out to at least 5 years.243,252None of these RCTs were sufficiently powered to detect differences in macrovascular or microvascular complications or death, especially at the relatively short follow-up, and no such differences have been detected thus far. Four of the RCTs from Pittsburgh, Seattle, Boston, and Cleveland have combined their patient populations in a pooled study to assess 10-year out-comes. This study, Alliance of Randomized Trials of Medicine vs. Metabolic Surgery (ARMMS), aims to identify long-term risks and benefits of metabolic surgery.The evidence, as previously summarized, was the basis for newly established international guidelines on the role of metabolic surgery in treating T2DM. In 2015, the 2nd Diabetes Surgery Summit (DSS-II) Consensus Conference generated Brunicardi_Ch27_p1167-p1218.indd 120123/02/19 2:21 PM 1202SPECIFIC CONSIDERATIONSPART IIParikh 2014 (RYGB/LAGB/SG) [6 mo; 6.5% off meds] (18)Courcoulas 2014 (RYGB/LAGB) [12 mo; 6.5% off meds] (14)Ding 2015 (LAGB) [12 mo; 6.5%] (22)Halperin 2014 (RYGB) [12 mo; 6.5% off meds] (15)Ikramuddin 2013 (RYGB) [12 mo; 7.0%] (13)Liang 2013 (RYGB) [12 mo; 7.0% off meds] (16)Schauer 2012 (RYGB/SG) [12 mo; 6.0%] (12)Cummings 2016 (RYGB) [12 mo; 6.5% off meds] (23)Dixon 2008 (LAGB) [24 mo; 6.2% off meds] (10)Ikramuddin 2015 (RYGB) [24 mo; 7.0%] (21)Mingrone 2012 (RYGB/BPD) [24 mo; 6.5% off meds] (11)Wentworth 2014 (LAGB) [24 mo; 7.0%] (17)Courcoulas 2015 (RYGB/LAGB) [36 mo; 6.5% off meds] (24)Schauer 2014 (RYGB/SG) [36 mo; 6.0%] (19)Mingrone 2015 (RYGB/BPD) [60 mo; 6.5% off meds] (20)Fixed-Effects ModelStudy (Operation) [Follow-Up; HbA1c end point]WeightPeto, Fixed, 95% CIPolo Odds Ratios131861128283492226341214271920411819573199152960402337973862400531100148020002417221957704117265920251440154664.5%5.1%3.9%4.4%12.5%8.4%10.4%3.4%6.7%11.8%6.4%4.9%4.0%8.7%4.9%100.0%21.15 [5.85, 76.51]7.51 [2.24, 25.21]1.68 [0.42, 6.66]5.82 [1.59, 21.39]3.72 [1.72, 8.04]86.76 [33.89, 222.08]6.39 [2.74, 14.88]11.48 [2.63, 50.13]10.83 [3 .79, 30.96]4.25 [1.92, 9.38]30.08 [10.28, 88.06]8.11 [2.37, 27.84]6.44 [1.65, 25.21]5.73 [2.28, 14.42]8.44 [2.46, 29.01]8.45 [6.44, 11.10]SurgeryGlyc. Endp. NMedical/LifestyleGlyc. Endp. NHeterogeneity: Chi2 = 45 .43, df = 14 (P < 0.0001); I2 = 69%Test for overall effect: Z = 15.36 (P < 0.00001)FavorsMedical/Lifestyle0.0010.11011000FavorsSurgeryIncreasing Length of Follow-UpFigure 27-27. Glycemic endpoints of RCTs by length of follow-up. Forest plot of Peto odds ratios (ORs) of main glycemic end points, as defined in each trial, from published RCTs of bariatric/metabolic surgery compared with medical/lifestyle treatments for diabetes with data arranged in order of increasing length of follow-up. (Reproduced with permission from Cummings DE, Cohen RV: Bariatric/Metabolic Surgery to Treat Type 2 Diabetes in Patients With a BMI <35 kg/m2, Diabetes Care. 2016 Jun;39(6):924-933.)Brunicardi_Ch27_p1167-p1218.indd 120223/02/19 2:21 PM 1203THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27Patients WithType 2 DiabetesObeseBMI ˙30 kg/m2or ˙27.5 for AsiansNonobeseBMI <30 kg/m2or <27.5 for AsiansClass III ObeseBMI ˙40 kg/m2or ˙37.5 for AsiansClass II ObeseBMI 35.0–39.9 kg/m2or 32.5–37.4 for AsiansClass I ObeseBMI 30.0–34.9 kg/m2or 27.5–32.4 for AsiansClass II ObeseWith PoorGlycemic ControlRecommendMetabolic SurgeryConsiderMetabolic SurgeryNonsurgicalTreatmentClass II ObeseWith AdequateGlycemic ControlClass I ObeseWith PoorGlycemic ControlClass I ObeseWith AdequateGlycemic ControlExpedited Assessment for Metabolic SurgeryOptimal Lifestyle and Medical RxOptimal Lifestyle and Medical Rx (including injectable meds and insulin)Figure 27-29. Algorithm for the treatment of type 2 diabetes as recommended by the 2nd Diabetes Surgery Summit. (Reproduced with permission from Rubino F, Nathan DM, Eckel RH, et al: Metabolic Surgery in the Treatment Algorithm for Type 2 Diabetes: A Joint Statement by International Diabetes Organizations, Diabetes Care. 2016 Jun;39(6):861-877.)20–2–4–6Change in HbA1cMean baselineBMI 35 kg/m2Mean baselineBMI >35 kg/m2Wentworth 2014Liang 2013Parikh 2014Ikramuddin 2013Courcoulas 2014Courcoulas 2014Halperin 2014Ding 2015Dixon 2008Schauer 2012Schauer 2012Cummings 2016Mingrone 2012Mingrone 2012SurgeryMedical/LifestyleFigure 27-28. Change in baseline HbA1c in each of the 11 RCTs. (Reproduced with permission from Rubino F, Nathan DM, Eckel RH, et al: Metabolic Surgery in the Treatment Algorithm for Type 2 Diabetes: A Joint Statement by International Diabetes Organiza-tions, Diabetes Care. 2016 Jun;39(6):861-877.)guidelines that were endorsed by more than 50 diabetes and medical organizations.16 The recommendations include patient selection, preoperative evaluation, choice of procedure, postop-erative follow-up, and indications for surgery. According to the DSS-II guidelines, metabolic surgery should be recommended to treat T2DM in patients with class III obesity (BMI ≥40 kg/m2) regardless of glycemic control and in those with class II obesity (BMI 35.0–39.9 kg/m2) when hyperglycemia is inad-equately controlled by lifestyle and optimal medical therapy (Fig. 27-29). Surgery should also be considered for patients with T2DM and BMI 30.0 to 34.9 kg/m2 if hyperglycemia is inadequately controlled despite optimal treatment with either oral or injectable medications. These BMI thresholds should be reduced by 2.5 kg/m2 for Asian patients. The new treatment algorithm from DSS-II incorporates appropriate use of all three treatment modalities: lifestyle intervention, drug therapy, and surgery (see Fig. 27-29).16 The 2017 Standards of Care for Dia-betes from the American Diabetes Association include those key indications in its recommendations for metabolic surgery, as well.COMPLICATIONS OF BARIATRIC SURGERYSurgical ComplicationsNone of the surgical procedures are without risks. The periop-erative mortality for the average patient is low (<0.5%) and declining, but can vary significantly across sub-groups with perioperative mortality rates of 2.0% or higher in some patient populations.1 The incidence of complications after the various surgical procedures varies from 4% to over 25% and depends on the definition of complication used, the type of bariatric procedure performed, and patient characteristics216,254,255 (see Table 27-5).8Brunicardi_Ch27_p1167-p1218.indd 120323/02/19 2:21 PM 1204SPECIFIC CONSIDERATIONSPART IIIn the 11 RCTs (794 patients) that have compared bariatric surgery to nonsurgical treatment, rates of adverse events were higher among surgical subjects, with follow-up up to 5 years for two of the studies and up to 2 to 3 years for others.82,252,256 There were very few cardiovascular events or deaths in either the surgical or the nonsurgical groups, and the most common adverse events after surgery were iron deficiency anemia (15% with intestinal bypass operations) and reoperations (8%). These RCTs were not large enough to compare safety between pro-cedure types, and most of the comparative data on procedure-to-procedure complications has and will come from larger observational studies.The 30-day mortality in the LABS Study was 0.3% for all procedures with a major adverse outcome rate (a predefined composite endpoint that included; death, venous thromboembo-lism, reintervention [percutaneous, endoscopic, or operative], or failure to be discharged from the hospital in 30 days) of 4.1%.59 Major predictors of an increased risk of complications in LABS were a history of venous thromboembolism, a diagnosis of obstructive sleep apnea, impaired functional status defined as inability to walk 300 feet (91 m), extreme BMI, and undergo-ing an RYGB by the open technique. Other large observational studies, such as SOS, have shown higher rates of complications, with 14.5% having at least one nonfatal complication over the first 90 days, including pulmonary complications, vomiting, wound infection, hemorrhage, and anastomotic leak. However, the SOS included mostly open and VBG procedures, which are rarely performed today. Despite these older procedures and tech-niques, the 90-day mortality rate in SOS was low at 0.25%.196In a 2007 meta-analysis of 361 studies, mostly nonran-domized observational studies involving over 85,000 patients, Buchwald and colleagues reported important differences in ≤30-day mortality across different laparoscopic bariatric pro-cedures: 0.06% for LAGB; 0.21% for VBG; 0.16% for RYGB; and 1.11% for BPD/DS.257 This review also found significantly higher mortality for open procedures compared with those per-formed laparoscopically. A U.S. study of over 300,000 patients in 12 states examined in-hospital complications before and after implementation of the CMS national policy restricting insurance coverage for bariatric surgery to “centers of excellence.” The study found no significant differences in complications before and after the policy was implemented, and overall complication rates were 7% to 8% with 3.3% to 3.6% being serious, including a 1% reoperation rate during both time periods.1,258 A clinically useful prognostic risk score was also developed and validated in 9382 patients to predict 90-day mortality after LRYGB surgery using five clinical characteristics: BMI ≥50 kg/m2, male sex, hypertension, known risk factor for pulmonary embolism, and age ≥45 years. Patients with 4 to 5 of these characteristics are at much higher risk of death (4.3%) by 90 days than those with 0 to 1 characteristics (0.26%).259-261 A systematic review of 15 RCTs of SG found no deaths in just under 800 patients but a 9.2% mean complication rate (range 0–18%).224 In the American College of Surgeons Bariatric Surgery Network database, mor-tality 30 days after SG was 0.11%, positioning its overall com-plication profile between that for LAGB (0.05%) and RYGB (0.14%). The 30-day complication rate was similarly positioned at 5.6% for SG, 1.4% LAGB, and 5.9% for RYGB.140An established problem now is the frequent rate of reop-eration, particularly among LAGB patients. In O’Brien and col-leagues’ prospective cohort of 3227 LAGB patients, revisional procedures occurred in 1116 (35%) and were performed for the following reasons: proximal enlargement (26%), port and tubing problems (21%), and erosion (3.4%). The need for revision due to proximal enlargement decreased dramatically over a 17-year period from 40% to 6.4% as the surgical technique evolved; however, the band was ultimately removed in 5.6% of all indi-viduals.262 Other long-term cohorts suggest that LAGB removal rates may be as high as 50%. The O’Brien systematic review of long-term studies indicates that the rate of revisional surgery for LRYGB may be similar to LAGB (22% revision for LRYGB, range 8% to 38%; 26% revision for LAGB, range of 8% to 60%). However, in the LABS Study, there was a higher rate of revision and reoperation for LAGB as compared to RYGB at both 3 and 7 years of follow-up.169 In general, more long-term data with more complete follow-up with standardized defini-tions and reporting of complications are needed to compare reoperation and complication rates of all bariatric procedures.Nonsurgical ComplicationsPostgastric bypass hypoglycemia (PGBH) in a relatively uncommon but particularly challenging problem that affects an unknown number of patients in the longer term. Prevalence rates in the literature vary from 1% to 11%, depending on the defini-tion.263,264 Hypoglycemia is characterized by documentation of Whipple’s triad (including both autonomic and neuroglycopenic symptoms or signs), at the time of a plasma glucose concentration <55 mg/dL with resolution of symptoms and signs after glucose administration. During these episodes, plasma insulin levels are inappropriately high, indicating dysregulation of β-cell function. When it was initially described in patients who had undergone partial pancreatectomy, nesidioblastosis was found in the speci-mens that are characterized by hyperplasia and/or dysplasia of the pancreatic islets.265 It was initially thought to be endogenous hyperinsulinemia from increased β-cell mass hyperfunctioning islet cells; however, the current thinking is that the recalcitrant symptoms of hyperinsulinemic hypoglycemia after RYGB are related to the anatomic and physiologic changes and not from an inherent change in β-cell mass. One candidate mediator of increased insulin secretion in PGBH is GLP-1, a peptide released from intestinal neuroendocrine L-cells in response to meals. Consistent with this hypothesis, postprandial GLP-1 levels are increased by over tenfold in post-RYGB patients, are higher in those with hyperinsulinemic hypoglycemia and neuroglyco-penia, and correlate inversely with postprandial glucose lev-els.266 PGBH needs to be distinguished from other forms of hypoglycemia such as other functional β-cell disorders such as noninsulinoma pancreatogenous hypoglycemia, insulinoma, reactive hypoglycemia, or early or late dumping syndrome. It is possible that PGBH is a spectrum of hypoglycemia with late dumping being on the end of the spectrum that is more respon-sive to dietary changes alone while more severe PGBH can be associated with severe symptoms.263 First-line therapeutic approaches to PGBH include medical nutrition therapy aimed at reducing intake of high glycemic index carbohydrates and premeal treatment with acarbose. Additional therapies that may be considered include octreotide, diazoxide, calcium channel blockers, GLP-1 receptor antagonists, and providing nutrition solely through a gastrostomy tube placed into the bypassed duo-denum. Reversal of gastric bypass is not uniformly successful, suggesting the importance of underlying genetics and/or com-pensatory mechanisms that may persist after surgical reversal.266 Finally, although pancreatic resection was initially employed for patients with life-threatening hypoglycemia, this procedure Brunicardi_Ch27_p1167-p1218.indd 120423/02/19 2:21 PM 1205THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27is not uniformly successful in remitting hypoglycemia and should not be considered for the majority of patients, who can experience improvement in their symptoms with a combination of medical approaches. A 2017 American Society of Metabolic and Bariatric Surgery (ASMBS) position statement provides a comprehensive summary of this topic and also recommends this multimodal medical approach.267There is data to suggest that babies born to women follow-ing bariatric surgery are at risk for certain complications. In a Swedish study, bariatric surgery was originally associated with reduced risks of gestational diabetes and excessive fetal growth, shorter gestation, and an increased risk of small-for-gestational-age infants. In a later follow-up report, this same group reported a significant association between a history of bariatric surgery and an increased risk of preterm birth and spontaneous preterm birth, in particular.119,268There is also emerging data from observational studies that some bariatric procedures may be associated with a greater long-term risk of substance and alcohol use disorders, suicide, and nutritional deficiencies. Pharmacokinetic studies indicate that after LRYGB and SG, the anatomic changes lead to very rapid absorption of alcohol and marked increases in blood alco-hol concentrations for a single small.269,270 In the SOS study, RYGB was associated with increased alcohol consumption and an increase in alcohol abuse events (HR: 4.9) over 20 years.196 Similarly in the LABS study, alcohol use disorders were found to be more common in the second postoperative year (9.6%) in those undergoing RYGB compared to before surgery (7.6%). Risk factors for alcohol use disorders included male gender, younger age, and preoperative smoking or alcohol use.271 At 7-year follow-up in LABS, there was a progressive and sig-nificant increase over time in the prevalence of regular alcohol consumption for both RYGB and LAGB. In addition, alcohol use disorders, illicit drug use, and treatment for substance use disorders, increased over the 7-year period for RYGB only.272 Overall, these rates were high, with 20% of RYGB participants reporting incident alcohol use disorder symptoms within 5 years of surgery.In addition, there may be an increased risk for suicide273-275 following bariatric surgery, although the etiology is unclear and the data is varied and complex to interpret.276 The Utah mortality study showed a 58% increase in all non–disease-related causes of death in the RYGB group compared to the matched control population, including a small but significant increase in suicides, accidents, and intentional poisonings.202 Similar findings were observed in the second Utah Obesity Study.203 An observational study using Pennsylvania state data found that suicide rates were 13.7 per 10,000 among men and 5.2 per 10,000 among women among postbariatric surgery patients in Pennsylvania over 10 years, which were both significantly higher than age and sex-matched rates in the United States. In addition, the majority (70%) of these deaths occurred in the first 3 years following surgery when clinical follow-up is incomplete.277Finally, there is evidence that vitamin and micronutrient deficiencies are common following bariatric surgery including calcium, vitamin D, iron, zinc, and copper, and others. Guide-lines suggest that all patients should be screened for deficiencies preoperatively as some deficiencies predate the surgical pro-cedure (see “Follow-Up Postoperative Care”). After surgery, patients must be provided daily nutritional supplementation and undergo routine long-term monitoring for deficiencies (see Table 27-4). Data continue to suggest that the prevalence of micronutrient deficiencies is increasing, while monitoring is decreasing. Aside from these recommendations, there is insuf-ficient evidence currently regarding optimal dietary and nutri-tional management following bariatric procedures, including how to treat some of the specific complications of bariatric operations such as chronic nausea and vomiting, hypoglyce-mic episodes, failed weight loss, and anastomotic ulcers and strictures.1,278-280REOPERATIVE (REVISION AND CONVERSION) BARIATRIC SURGERYIntroductionSurgical treatments for chronic diseases such as obesity often require additional or revisional surgical procedures when the primary procedure did not sufficiently treat the underly-ing disease. This is true in joint replacements when treating osteo-arthritis, coronary-artery bypass graft surgeries when treating coronary artery disease, and bariatric surgery in the treatment of obesity.281 Additionally, we suspect that obesity is a heteroge-neous disorder282 and is therefore being treated with a variety of procedures with different mechanisms of action.63 Given this, it is not surprising that some patients are “treatment failures” with respect to improvements in weight, comorbidities, and quality of life. Also, older bariatric surgical procedures such as the jejunal-ileal bypass, the VBG, and early gastric bypass procedures (which utilized a horizontal and/or partitioned stomach) require revision because of a higher complication rate.283,284 Initial bariatric sur-gery cases have averaged greater than 150,000 cases per year for the last 15 years.285 For these reasons, reoperative bariatric sur-gery has become increasingly prevalent over the last decade. Despite its increasing prevalence, there are challenges in assess-ing the frequency and effectiveness of these procedures. Reopera-tive bariatric surgery has been difficult to categorize meaningfully and to quantify due to the multiple procedure codes, many with little specificity. Reports in the literature range from 5% to 50% depending on the primary procedure.283Multiple retrospective, as well as case-matched and case-controlled studies of revisional bariatric surgery, demonstrate they are effective with benefits to weight loss and overall health,281,283 although this is not without some controversy. The literature supports reoperative bariatric surgery in two situa-tions: treatments of insufficient weight loss or weight regain and the treatment of acute and chronic complications.281,285 There are many revisional procedures and approaches that are effective. There is no data-driven evidence to guide in the selection of which patient will benefit most from revisional bariatric surgery. Additionally, there is no evidence-based consensus as to which revisional surgical approach is most optimal in any given situa-tion.283 Currently, there is also little evidence as to which bariat-ric surgical procedure will be efficacious for any specific given patient.286,287Principles and Preoperative EvaluationAs with any other decisions for surgery, revisional or addi-tional bariatric surgery requires evaluating the risks and the benefits of the procedure for specific patient situations. It has been observed that the weight loss following revisional pro-cedures is less than with a primary procedure.288 Reoperations in general are associated with morbidity and mortality that is higher than with primary bariatric procedures281,288,289 but are acceptably low if careful selection of patients is coupled with 9Brunicardi_Ch27_p1167-p1218.indd 120523/02/19 2:21 PM 1206SPECIFIC CONSIDERATIONSPART IIadequate surgeon experience.281,290 Reoperative bariatric surgery should be undertaken by experienced bariatric surgeons in cen-ters with the wide range of medical resources to manage these complex patients.281 In some situations, it is reasonable to con-sider a two-stage or an open vs. laparoscopic approach.285 When evaluating a patient for revisional bariatric surgery, it is most important to establish clearly the reason for revision.283,291 Is the issue a surgical complication, insufficient weight loss, or weight regain? Is there a discernable anatomic cause for the patient’s symptoms (e.g., abdominal pain, nausea, vomiting, heartburn or reflux, nutritional deficiency)? In situations of noninitial weight loss or weight regain, what is the best justification that can be made? Are there behavioral, or other nonsurgical modifications that might significantly help to attain further weight loss? Will the patient be able to set into place the behavioral modification required of the revisional surgical approach? With consideration for revision, it is reasonable to place less emphasis on absolute weight loss and focus on the comorbidity and quality of life states. A comprehensive preoperative evaluation is required to fully answer these and other questions.The preoperative evaluation for bariatric surgical revision should include• Review of the initial surgical operative note to understand the exact initial procedure• Anatomic evaluation of the GI track utilizing upper gastroin-testinal endoscopy and radiology to identify known bariatric surgical complications• An extensive nutritional evaluation• A behavioral health evaluation with a focus on the adaption to the initial bariatric procedure and potential adaptation to a revisional procedure• A full medical evaluation to determine the patient’s suitability to undergo anesthesia and a surgical procedure288,291The results from these evaluations are used to formulate a hypothesis to explain the patient’s symptoms and outcome from the initial procedure and to assess their suitability for and the potential benefits from the potential revisional surgical options. It will come down to a risk-benefit discussion between the sur-geon, other members of the multidisciplinary support team, and the patient.281Treatment for Insufficient Weight Loss or Weight RegainVertical Banded Gastroplasty. Reversal of VBG is associ-ated with significant weight gain. Revision of the VBG to a re-VBG was associated with poor outcomes.292 VBGs have been safely converted with open and laparoscopic approaches to RYGB and SG.293-295 Conversion of VBG to BPD/DS pro-cedures has limited data with higher leak rate and mortality.296Adjustable Gastric Band. There are increasing reports of LAGB failure and disappointing weight loss over the last decade.289,297,298 Removal of the band without an additional bar-iatric procedure has been associated with significant weight regain.289 Repositioning or replacement of the band is techni-cally possible; however, the long-term weight loss outcomes are mixed.299-301 When converting an LAGB to another bariatric pro-cedure, there is some evidence to suggest possibly fewer com-plications with a two-step approach when significant adhesions or a thick gastric capsule are present. This two-step approach would include removal of the band, allowing 3 to 6 months for gastric tissue healing, and then completing the conver-sion.302,303 However, one-stage conversions have been reported with acceptable outcomes.297 Good outcomes have been dem-onstrated with conversion of LAGBs to SG, RYGB, and BPD/DS.285,297 Several investigators advocate that a failed restrictive bariatric surgery due to poor weight loss should include a revi-sion option with a malabsorptive component.285Sleeve Gastrectomy. Approximately 5% to 10% of primary SG procedures have been reported to require revision for poor weight loss outcomes.304,305 The literature supports conversion to RYGB and BPD/DS.306 There is controversy regarding resleeve gastrectomy.307,308Roux-en-Y Gastric Bypass. Approximately, 10% to 20 % of patients after a primary RYGB will have inadequate weight loss or weight regain at 2 years, and a subset of these will require a revisional surgical procedure.309 Options for revision include banding over the Roux-en-Y bypass, gastric pouch and gas-trojejunal revisions, RYGB limb lengthening, and conversion to a duodenal switch.281,285 Each of these options has strengths and weaknesses in specific situations. Endoscopic revisions to reduce the gastric pouch and/or gastrojejunal stomal size have been shown to arrest weight gain with short-term weight loss, but the studies have been small and are noncontrolled.Treatment of Surgical ComplicationsVertical Banded Gastroplasty. Several complications have been indications for revision/conversion of VBGs: wide outlet, pouch dilation, staple line erosion, stoma stenosis, band erosion, band dehiscence, and GERD. Most often conversion is under-taken, and VBGs have been safely converted to RYGB.281,285Adjustable Gastric Band. The following LAGB complica-tions may require additional or revisional surgery: early band obstruction, severe or chronic gastric prolapse or symmetrical gastroesophageal dilatation, band erosion, port and tubing prob-lems, severe or persistent esophageal dysmotility, or psycho-logical intolerance to restriction of band. The literature supports repair of tubing and port problems and revision of LAGB to SG, RYGB, BPD/DS in oneor two-stage revisional operations.285,297Sleeve Gastrectomy. Complications that may require a revi-sional procedure after sleeve gastrectomy are staple line leaks, sleeve stricture and sleeve dilatation, and gastroesophageal reflux. Obstruction due to stricture usually at the angularis inci-sura will require first-line treatment of endoscopic dilation and may require a revision to a RYGB. Staple line leaks are ini-tially controlled with endoscopic stenting or drainage. Acute and chronic leaks may develop into fistulous disease and require conversion to RYGB. Persistent gastroesophageal reflux may also require conversion to RYGB.281,285Roux-en-Y Gastric Bypass. Several complications after pri-mary RYGB have been demonstrated as indications for revi-sional surgery: gastric pouch dilatation, gastrojejunostomy dilation/stricture, marginal ulcers, bowel loss due to internal hernia or volvulus, roux stasis syndrome, gastrogastric fistu-las, anastomotic structures or ulcers, and metabolic/endocrine derangements. These require a revision focused on the mecha-nism of the complication. Reversal of an RYGB is reserved for severe instances of intractable nausea/vomiting, extreme weight loss and malnutrition, metabolic abnormalities, nonhealing ulceration or leaks, and patient choice. It has been performed rarely, and case reports indicate successful resolution of endo-crine, metabolic, and nutritional abnormalities with improved Brunicardi_Ch27_p1167-p1218.indd 120623/02/19 2:21 PM 1207THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27metabolic parameters. However, 50% to 88% of patients have been reported to regain significant weight.281,285Biliopancreatic Diversion With Duodenal Switch. Acute complications are similar to RYGB and treated the same. The most severe chronic complication is protein-calorie malnutri-tion, and incidence ranges from 1% to 6%. Management is meticulous nutritional evaluation and nutritional and pancreatic enzyme support, with surgery as a fall back if weight and pro-tein stores are not stabilized. Surgery would entail lengthening the common channel and is rarely necessary.281SPECIAL ISSUES IN BARIATRIC SURGERYBariatric Procedures in AdolescentsThe major controversy with regard to adolescents undergoing bariatric surgery includes the general aversion to subjecting an adolescent to surgery as well as the concern for the second-ary side effects of bariatric surgery on remaining growth and development. Clearly the younger the patient, the more relevant the latter concern becomes. Bariatric surgery in adolescents has been performed more frequently, with only 800 cases a year in 2003 increasing to 1600 cases in 2009, but overall rates are much lower than in adults.310,311 Much of the clinical outcomes data have been extrapolated from the adult literature, and more evidence is needed to demonstrate whether weight loss is dura-ble over time, the impact on obesity-related conditions such as T2DM, hypertension, and others, and how often patients experi-ence shortand longer-term complications.A meta-analysis involving 131 adolescents undergoing bariatric surgery demonstrated a 17.8 to 22.3 kg/m2 decrease in BMI after RYGB.312 They also observed improvement of hyper-tension in more than half the patients and sleep apnea resolution in all 131 patients. There were four mortalities in this cohort, but only one of them was potentially associated with the pro-cedure (Clostridium difficile colitis 9 months after operation). Morbidity in the adolescent literature ranges from 0% to 38%. The most common complication in the meta-analysis was nutri-ent deficiencies. The ASMBS pediatric guidelines suggest using BMI criteria similar to the adult population but with some modi-fications to comorbidity thresholds.313 They recommend con-sidering surgery in patients with a BMI of 35 kg/m2 or greater with major comorbidities (e.g., T2DM, severe nonalcoholic fatty liver disease, OSA) or a BMI of ≥40 kg/m2 or greater with minor comorbidities (e.g., hypertension, dyslipidemia, insulin resistance). One more recent multicenter, prospective study of bariatric surgery in adolescents, the Teen-Longitudinal Assess-ment of Bariatric Surgery (Teen-LABS) study, is following 242 adolescent patients for at least 10 years, who underwent bariatric surgery at 5 academic centers.314 Fifty-one percent of adolescents had four or more major comorbid conditions before surgery. LRYGB, SG, and LAGB were performed in 66%, 28%, and 6% of patients, respectively. There were no deaths during the initial hospitalization or within 30 days of operation; major complications such as reoperation were reported in 19 patients (8%). Minor complications such as dehydration were reported in 15%. All reoperations and 85% of readmissions in the 30-day period were related to the bariatric surgery.315 Three-year follow-up data on the Teen-LABS cohort reported a mean weight loss of 28% for LRYGB and 26% for SG. Remission of T2DM occurred in 95% of participants who had had the con-dition before surgery, remission of abnormal kidney function occurred in 86%, remission of prediabetes in 76%, remission of elevated blood pressure in 74%, and remission of dyslipidemia in 66%. Rates of improvements in comorbid conditions, includ-ing T2DM, occurred at higher rates than in adults. Hypofer-ritinemia was found in 57% of the participants, and 13% of the participants had undergone one or more additional intraabdomi-nal procedures at 3 years.52 So despite the clinically significant improvements in weight, diabetes, cardiometabolic health, and weight-related quality of life that were observed at 3 years fol-lowing surgery, the reoperation and micronutrient risks warrant longer observation and further study.Cost EffectivenessIn a Canadian study, including five systematic reviews, two eco-nomic evaluations, two reviews of guidelines, and six primary evidence-based guidelines, the cost effectiveness for the use of bariatric surgery in adolescents was reviewed.316 The limited available evidence suggested superior weight loss, resolution of comorbidities compared to nonsurgical interventions, and potential superior weight loss with RYGB compared to other procedures. Cost-effectiveness data was lacking, but limited evidence suggested that bariatric surgery was cost effective several years after intervention, but not immediately.316 A U.S. cost-effectiveness analysis of bariatric surgery in adolescents has been published. In addition to the cost of the surgery, peri-operative mortality, complications, and quality of life improve-ment were included in the modelled analysis. By the fifth year of follow-up, bariatric surgery was found to be cost effective in adolescent patients when compared to a cohort of patients with obesity who had not undergone surgery.317For adults, the overall impact of bariatric surgery to reduce expenditures sufficiently to achieve cost savings continues to be debated. In a Canadian matched cohort study prior to the laparoscopic era, it was shown that bariatric surgery decreases long-term direct healthcare costs and the initial costs of surgery can be amortized over 3.5 years.318 In two observational studies, bariatric surgery was shown to be cost saving over a relatively short period of time.319,320 In more recent observational studies, including the large SOS study and another an analysis of 30,000 single payor enrollees in the United States, show no evidence of overall cost savings.206,321,322In general, review of the evidence to date suggests that outpatient costs, including pharmacy costs, are significantly reduced after bariatric surgery. However, long-term inpatient hospital costs are increased or unchanged in those who have undergone bariatric surgery compared with matched nonsurgi-cal patients, so no long-term net cost benefit is achieved. Other modeled cost effectiveness studies are consistent with these results as well.323,324 So it is likely that bariatric procedures are cost effective, but do not produce cost savings, compared with nonsurgical treatments.Quality AssuranceBetween 1998 and 2003, with emergence of the laparoscopic technique for bariatric surgery, there was rapid increase in the number bariatric surgical procedures performed. With bariatric surgeons becoming accustomed to laparoscopic techniques and laparoscopic surgeons learning bariatric procedures and patient care, there were realistic concerns regarding the safety of bar-iatric surgery.325 In 2004, ASMBS utilized the volume-outcome concept of centers of excellence and developed the first bar-iatric surgical accreditation program, ASMBS-Center of Excel-lence (COE). In 2005, the American College of Surgeons (ACS) initiated the ACS Bariatric Surgery Center Network (BSCN). Brunicardi_Ch27_p1167-p1218.indd 120723/02/19 2:21 PM 1208SPECIFIC CONSIDERATIONSPART IIThese accreditation programs verified that bariatric surgery centers had the infrastructure and equipment to care for the morbidly obese, experienced and qualified surgeons and staff, appropriate preand postoperative processes in place, and reported outcome data on all surgical cases.325In 2012, these two bariatric surgical accreditations merged into a single unified program, the Metabolic and Bar-iatric Surgery Accreditation and Quality Improvement Program (MBSAQIP). The MBSAQIP has continued to grant accredita-tion only after a rigorous review process during which a center proves that it can maintain certain physical resources, human resources, and standards of practice.326 Additionally, prospec-tive outcome data is collected at the clinical center and validated based on standardized definitions and submitted to the quality improvement program. Centers receive back risk-stratified anal-ysis of their data as a means to compare with the national statis-tics/standards and are then required to utilize the data in quality improvement projects at their center. This newer focus on qual-ity improvement over centers of excellence will likely continue to improve the quality of bariatric surgery in the United States. Recently, in a systematic review, bariatric facility accreditation by this program has been associated with improved outcomes (length of stay, mortality, morbidity).327Plastic Surgery After Weight LossPatients who have undergone bariatric surgery are often left with skin and subcutaneous tissue deformities. Additional prob-lems include skin rashes and maceration under folds in the pan-nus, thighs, and breasts; body odor; and poorly fitting clothes. Excess skin can also be a limiting factor in exercise and sexual activity. Plastic and reconstructive surgery is now a part of the continuum of care for bariatric surgery patients. Reconstructive surgery requires careful preoperative planning and is based on the patient’s deformities and priorities. Timing of plastic and reconstructive surgery is typically deferred until weight sta-bility at approximately 1 to 2 years postoperatively to ensure improved healing. Excess tissue of the lower torso is the most common area for which patients undergo surgical intervention and a standard abdominoplasty is typically performed. More radical body contouring can include a circumferential abdomi-noplasty and lower body lift.328,329 This procedure involves excision of tissue from the buttocks and lateral thighs, with skin undermining down the thighs. Circumferential abdomino-plasty removes redundant skin of the lower abdomen, flattens the abdomen, and incorporates the lower body lift. It requires central undermining to the xiphoid and minimal lateral under-mining of the superior flap. The central abdominal fascia often requires imbrication. If simultaneous abdominal hernia repair is performed, this performs the function of fascial imbrication by creating a repair with some degree of fascial tension. The closure of the superior flap to the inferior skin edge incorporates lateral tension to narrow the waist and advance the anterolateral thighs. Medial thighplasty also may be needed for patients with significant excess medial thigh skin.Mid-back and epigastric deformity, along with sagging breasts, are corrected with an upper body lift. The upper body lift is a reverse abdominoplasty, removal of mid-torso excessive skin, and reshaping of the breasts. For highly selected individu-als, and with a well-organized team, a single-stage total body lift, which includes a circumferential abdominoplasty, lower body lift, medial thighplasty, an upper body lift, and breast reshap-ing, can be performed safely in under 8 hours (Figs. 27-30 and 27-31).330 Increasing numbers of patients are seeking these cor-rective procedures, and data about the results is evolving. There Figure 27-30. Preoperative frontal, right lateral, and left anterior oblique views of a 36-year-old, 150-lb (68-kg) 5'6" woman who lost 120 lb (54 kg) 2 years after laparoscopic Roux-en-Y bypass procedure. She desired a one-stage total body lift and bilateral brachioplasties, which were performed in the manner described in the text. (Used with permission from Dennis Hurwitz, MD, Clinical Professor of Plastic Surgery, University of Pittsburgh.)Brunicardi_Ch27_p1167-p1218.indd 120823/02/19 2:21 PM 1209THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27Figure 27-31. Frontal, right lateral, and left anterior oblique views 6 weeks after surgery for the woman in Fig. 27-24. The scars indicate the circumferential abdominoplasty, lower body lift, upper body lift, breast reshaping, and autoaugmentation through a keyhole pattern and bilateral brachioplasties. All redundant skin has been removed, leaving well-positioned scars and feminine features. (Used with permission from Dennis Hurwitz, MD, Clinical Professor of Plastic Surgery, University of Pittsburgh.)is a hypothesis that if body image is improved with corrective surgery, that weight maintenance in the longer-term may also be positively affected. Several matched controlled studies suggest that plastic surgery after bariatric surgery may improve long-term weight loss results.328,331FUTURE IMPORTANT QUESTIONSThe volume and quality of literature in the field of bariatric sur-gery has grown tremendously in the last 10 years. High-quality evidence now shows that bariatric surgical procedures result in greater weight loss than nonsurgical treatments, improved sur-vival, and are more effective at inducing remission of T2DM in people with obesity. More information is still needed about the long-term durability of comorbid health improvements and long-term complications after each of the different bar-iatric surgical procedures. In addition, the underlying specific mechanism(s) of action for both bariatric and metabolic surgery is still incompletely understood. Future knowledge will come from translational human studies, the ongoing longer-term stud-ies and data registries, randomized studies comparing surgical to nonsurgical treatments, integrated health care systems data, and national “big data” networks. The following are some of the high-priority questions that future research will address.• What are the specific mechanisms of action responsible for weight loss and the T2DM response to bariatric surgical procedures?• What patient level factors can predict success with weight loss, health improvements, and cost savings after bariatric surgical procedures? Understanding preand postsurgery predictors will help to tailor an individual’s treatment.• Is bariatric surgery more effective than nonsurgical care for the longer-term treatment of T2DM in people with less severe obesity (class 1 obesity, BMI <35)?• With more standardized reporting of complications across bariatric studies, what are the long-term complication rates after different bariatric procedures?• What is the effect of bariatric surgery on long-term microvas-cular and macrovascular event rates?• What are the reproductive and mental health outcomes includ-ing risk for self-harm and suicide, alcohol use disorders, sub-stance abuse, and other risk-taking behaviors?REFERENCESEntries highlighted in bright blue are key references. 1. Arterburn DE, Courcoulas AP. Bariatric surgery for obesity and metabolic conditions in adults. BMJ. 2014;349:g3961. 2. Kremen AJ, Linner JH, Nelson CH. An experimental evalua-tion of the nutritional importance of proximal and distal small intestine. Ann Surg. 1954;140(3):439-448. 3. Mason EE, Ito C. Gastric bypass. Ann Surg. 1969;170(3): 329-339. 4. Griffen WO Jr, Young VL, Stevenson CC. A prospective comparison of gastric and jejunoileal bypass procedures for morbid obesity. Ann Surg. 1977;186(4):500-509. 5. Mason EE. Vertical banded gastroplasty for obesity. Arch Surg. 1982;117(5):701-706. 6. Brolin RE, Robertson LB, Kenler HA, Cody RP. Weight loss and dietary intake after vertical banded gastroplasty and Roux-en-Y gastric bypass. Ann Surg. 1994;220(6):782-790. 7. Waaddegaard P, Clemmesen T, Jess P. Vertical gastric banding for morbid obesity: a long-term follow-up study. Eur J Surg. 2002;168(4):220-222.Brunicardi_Ch27_p1167-p1218.indd 120923/02/19 2:21 PM 1210SPECIFIC CONSIDERATIONSPART II 8. Balsiger BM, Poggio JL, Mai J, Kelly KA, Sarr MG. Ten and more years after vertical banded gastroplasty as pri-mary operation for morbid obesity. J Gastrointest Surg. 2000;4(6):598-605. 9. Scopinaro N, Gianetta E, Civalleri D, Bonalumi U, Bachi V. Bilio-pancreatic bypass for obesity: II. Initial experience in man. Br J Surg. 1979;66(9):618-620. 10. Hess DS, Hess DW. Biliopancreatic diversion with a duodenal switch. Obes Surg. 1998;8(3):267-282. 11. Belachew M, Legrand MJ, Defechereux TH, Burtheret MP, Jacquet N. Laparoscopic adjustable silicone gastric band-ing in the treatment of morbid obesity. A preliminary report. Surg Endosc. 1994;8(11):1354-1356. 12. Wittgrove AC, Clark GW, Tremblay LJ. Laparoscopic gastric bypass, Roux-en-Y: preliminary report of five cases. Obes Surg. 1994;4(4):353-357. 13. Reames BN, Finks JF, Bacal D, Carlin AM, Dimick JB. Changes in bariatric surgery procedure use in Michigan, 2006-2013. JAMA. 2014;312(9):959-961. 14. Angrisani L, Santonicola A, Iovino P, et al. Bariatric surgery and endoluminal procedures: IFSO worldwide survey 2014. Obes Surg. 2017;27(9):2279-2289. 15. Shimizu H, Timratana P, Schauer PR, Rogula T. Review of metabolic surgery for type 2 diabetes in patients with a BMI <35 kg/m2. J Obes. 2012;2012:147256. 16. Rubino F, Nathan DM, Eckel RH, et al. Metabolic surgery in the treatment algorithm for type 2 diabetes: a joint statement by international diabetes organizations. Diabet Care. 2016;39(6):861-877. This paper summarizes the most recent Diabetes Surgery Summit (DSS-II) conclusions for which three rounds of Delphi-like questionnaires were used to measure consensus for 32 data-based conclusions. Based on the evidence, bariatric/metabolic surgery was recommended to treat Type 2 diabetes in patients with Class III obesity (BMI≥40 kg/m2) and in those with Class II obesity (BMI 35.0-39.9 kg/m2) when hyperglycemia is inadequately controlled by lifestyle and optimal medical therapy. Surgery should also be considered for patients with T2D and BMI 30.0-34.9 kg/m2 (Class I obesity) if hyperglycemia is inadequately controlled despite optimal medical treatment. 17. Stefater MA, Wilson-Perez HE, Chambers AP, Sandoval DA, Seeley RJ. All bariatric surgeries are not created equal: insights from mechanistic comparisons. Endocr Rev. 2012;33(4):595-622. This paper is a review of what is known from published animal and human studies about the underlying basic mechanisms of effect of each of 3 most common surgical procedures. This review forms the basis of why research has shifted away from anatomic characterizations of the bariatric procedures as either “restrictive” or “malabsorptive” in nature, towards the physiology of common metabolic changes. 18. World Health Organization. Obesity and overweight. Avail-able at: http://www.who.int/mediacentre/factsheets/fs311/en/. Accessed June 13, 2018. 19. Mokdad AH, Marks JS, Stroup DF, Gerberding JL. Actual causes of death in the United States, 2000. JAMA. 2004;291(10):1238-1245. 20. Flegal KM, Kruszon-Moran D, Carroll MD, Fryar CD, Ogden CL. Trends in obesity among adults in the United States, 2005 to 2014. JAMA. 2016;315(21):2284-2291. 21. Ogden CL, Carroll MD, Lawman HG, et al. Trends in obesity prevalence among children and adolescents in the United States, 1988-1994 through 2013-2014. JAMA. 2016;315(21):2292-2299. 22. Heymsfield SB, Wadden TA. Mechanisms, pathophysiology, and management of obesity. N Engl J Med. 2017;376(3):254-266. 23. Bray MS LR, McCaffery JM, et al. NIH working group report—using genomic information to guide weight management: from universal to precision treatment. Obesity (Silver Spring). 2016;24(1):14-22. 24. Pigeyre M, Yazdi FT, Kaur Y, Meyre D. Recent progress in genetics, epigenetics and metagenomics unveils the pathophysiology of human obesity. Clin Sci. 2016;130(12): 943-986. 25. Shen W, Wang Z, Punyanita M, et al. Adipose tissue quanti-fication by imaging methods: a proposed classification. Obes Res. 2003;11(1):5-16. 26. Tchkonia T, Thomou T, Zhu Y, et al. Mechanisms and meta-bolic implications of regional differences among fat depots. Cell Metab. 2013;17(5):644-656. 27. Hall JE, da Silva AA, do Carmo JM, et al. Obesity-induced hypertension: role of sympathetic nervous system, leptin, and melanocortins. J Biol Chem. 2010;285(23):17271-17276. 28. Ashrafian H, Toma T, Rowland SP, et al. Bariatric surgery or non-surgical weight loss for obstructive sleep apnoea? A systematic review and comparison of meta-analyses. Obes Surg. 2015;25(7):1239-1250. 29. Goldring MB, Otero M. Inflammation in osteoarthritis. Curr Opin Rheumatol. 2011;23(5):471-478. 30. Hampel H, Abraham NS, El-Serag HB. Meta-analysis: obesity and the risk for gastroesophageal reflux disease and its com-plications. Ann Intern Med. 2005;143(3):199-211. 31. Berkowitz RI, Fabricatore AN. Obesity, psychiatric status, and psychiatric medications. Psychiatr Clin North Amer. 2011;34(4):747-764. 32. Mitchell JE, Selzer F, Kalarchian MA, et al. Psychopathology before surgery in the longitudinal assessment of bariatric surgery-3 (LABS-3) psychosocial study. Surg Obes Relat Dis. 2012;8(5):533-541. 33. Wadden TA, Sarwer DB. Behavioral assessment of candidates for bariatric surgery: a patient-oriented approach. Obesity. 2006;14(suppl 2):53S-62S. 34. Garvey WT, Mechanick JI, Brett EM, et al. American Association of Clinical Endocrinologists and American College of Endocrinology comprehensive clinical practice guidelines for medical care of patients with obesity. Endocr Pract. 2016;22(suppl 3):1-203. 35. American College of Cardiology/American Heart Association Task Force on practice guidelines OEP. Expert panel report: guidelines (2013) for the management of overweight and obesity in adults. Obesity. 2014;22(suppl 2):S41-S410. 36. Look ARG, Pi-Sunyer X, Blackburn G, et al. Reduction in weight and cardiovascular disease risk factors in individuals with type 2 diabetes: one-year results of the look AHEAD trial. Diabet Care. 2007;30(6):1374-1383. 37. Look ARG, Wing RR. Long-term effects of a lifestyle intervention on weight and cardiovascular risk factors in individuals with type 2 diabetes mellitus: four-year results of the Look AHEAD trial. Arch Intern Med. 2010;170(17): 1566-1575. 38. Look ARG, Wing RR, Bolin P, et al. Cardiovascular effects of intensive lifestyle intervention in type 2 diabetes. N England J Med. 2013;369(2):145-154. 39. Knowler WC, Barrett-Connor E, Fowler SE, et al. Reduction in the incidence of type 2 diabetes with lifestyle intervention or metformin. N England J Med. 2002;346(6):393-403. 40. Teixeira PJ, Silva MN, Coutinho SR, et al. Mediators of weight loss and weight loss maintenance in middle-aged women. Obesity. 2010;18(4):725-735. 41. Apovian CM, Aronne LJ, Bessesen DH, et al. Pharmacological management of obesity: an Endocrine Society clinical practice guideline. J Clin Endocrinol Metab. 2015;100(2): 342-362. 42. Yanovski SZ, Yanovski JA. Long-term drug treatment for obesity: a systematic and clinical review. JAMA. 2014; 311(1):74-86.Brunicardi_Ch27_p1167-p1218.indd 121023/02/19 2:21 PM 1211THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27 43. Pi-Sunyer X, Astrup A, Fujioka K, et al. A randomized, controlled trial of 3.0 mg of liraglutide in weight management. N England J Med. 2015;373(1):11-22. 44. Davidson MH, Hauptman J, DiGirolamo M, et al. Weight control and risk factor reduction in obese subjects treated for 2 years with orlistat: a randomized controlled trial. JAMA. 1999;281(3):235-242. 45. Smith SR, Weissman NJ, Anderson CM, et al. Multicenter, placebo-controlled trial of lorcaserin for weight management. N England J Med. 2010;363(3):245-256. 46. Gadde KM, Allison DB, Ryan DH, et al. Effects of low-dose, controlled-release, phentermine plus topiramate combination on weight and associated comorbidities in overweight and obese adults (CONQUER): a randomised, placebo-controlled, phase 3 trial. Lancet. 2011;377(9774):1341-1352. 47. Apovian CM, Aronne L, Rubino D, et al. A randomized, phase 3 trial of naltrexone SR/bupropion SR on weight and obesity-related risk factors (COR-II). Obesity. 2013;21(5):935-943. 48. Khera R, Murad MH, Chandar AK, et al. Association of pharmacological treatments for obesity with weight loss and adverse events: a systematic review and meta-analysis. JAMA. 2016;315(22):2424-2434. 49. ASMBS. Estimate of bariatric surgery numbers, 2011-2016. Available at: https://asmbs.org/resources/estimate-of-bariatric-surgery-numbers. Accessed June 13, 2018. 50. Ponce J, DeMaria EJ, Nguyen NT, Hutter M, Sudan R, Morton JM. American Society for Metabolic and Bariatric Surgery estimation of bariatric surgery procedures in 2015 and surgeon workforce in the United States. Surg Obes Relat Dis. 2016;12(9):1637-1639. 51. NIH conference. Gastrointestinal surgery for severe obesity. Consensus Development Conference Panel. Ann Intern Med. 1991;115(12):956-961. 52. Inge TH, Courcoulas AP, Jenkins TM, et al. Weight loss and health status 3 years after bariatric surgery in adolescents. N England J Med. 2016;374(2):113-123. 53. Giordano S, Victorzon M. Laparoscopic Roux-en-Y gastric bypass is effective and safe in over 55-year-old patients: a comparative analysis. World J Surg. 2014;38(5):1121-1126. 54. Giordano S, Victorzon M. Bariatric surgery in elderly patients: a systematic review. Clin Interv Aging. 2015;10:1627-1635. 55. Casillas RA, Kim B, Fischer H, Zelada Getty JL, Um SS, Coleman KJ. Comparative effectiveness of sleeve gastrectomy versus Roux-en-Y gastric bypass for weight loss and safety outcomes in older adults. Surg Obes Relat Dis. 2017; 13(9):1476-1483. 56. Flum DR, Salem L, Elrod JA, Dellinger EP, Cheadle A, Chan L. Early mortality among Medicare beneficiaries undergoing bar-iatric surgical procedures. JAMA. 2005;294(15):1903-1908. 57. Davidson LE, Adams TD, Kim J, et al. Association of patient age at gastric bypass surgery with long-term all-cause and cause-specific mortality. JAMA. 2016;151(7):631-637. 58. Mechanick JI, Youdim A, Jones DB, et al. Clinical practice guidelines for the perioperative nutritional, metabolic, and nonsurgical support of the bariatric surgery patient—2013 update: cosponsored by American Association of Clinical Endocrinologists, the Obesity Society, and American Soci-ety for Metabolic & Bariatric Surgery. Surg Obes Relat Dis. 2013;9(2):159-191. 59. Flum DR, Belle SH, King WC, et al. Perioperative safety in the longitudinal assessment of bariatric surgery. N England J Med. 2009;361(5):445-454. This is a 30 day safety paper from the Longitudinal Assessment of Bariatric Surgery (LABS-1) study. It is a definitive paper on the morbidity and mortality of bariatric surgery from a multi-center and carefully studied cohort of patients undergoing bariatric surgery. The 30-day mortality was 0.3% for all procedures with a major adverse outcome rate [a pre-defined composite endpoint that included; death, venous thromboembolism, re-intervention (percutaneous, endoscopic, or operative), or failure to be discharged from the hospital in 30 days] of 4.1%. 60. Cummings BP, Strader AD, Stanhope KL, et al. Ileal inter-position surgery improves glucose and lipid metabolism and delays diabetes onset in the UCD-T2DM rat. Gastroenterology. 2010;138(7):2437-2446, 2446 e2431. 61. Rubino F, Gagner M, Gentileschi P, et al. The early effect of the Roux-en-Y gastric bypass on hormones involved in body weight regulation and glucose metabolism. Ann Surg. 2004;240(2):236-242. 62. Strader AD, Vahl TP, Jandacek RJ, Woods SC, D’Alessio DA, Seeley RJ. Weight loss through ileal transposition is accompa-nied by increased ileal hormone secretion and synthesis in rats. Am J Physiol Endocrinol Metab. 2005;288(2):E447-E453. 63. Madsbad S, Dirksen C, Holst JJ. Mechanisms of changes in glucose metabolism and bodyweight after bariatric surgery. Lancet Diabetes Endocrinol. 2014;2(2):152-164. 64. Ochner CN, Stice E, Hutchins E, et al. Relation between changes in neural responsivity and reductions in desire to eat high-calorie foods following gastric bypass surgery. Neuroscience. 2012;209:128-135. 65. Chakravarty PD, McLaughlin E, Whittaker D, et al. Compari-son of laparoscopic adjustable gastric banding (LAGB) with other bariatric procedures; a systematic review of the ran-domised controlled trials. Surgeon. 2012;10(3):172-182. 66. Liou AP, Paziuk M, Luevano JM, Jr., Machineni S, Turnbaugh PJ, Kaplan LM. Conserved shifts in the gut microbiota due to gastric bypass reduce host weight and adiposity. Sci Transl Med. 2013;5(178):178ra141. 67. Sweeney TE, Morton JM. The human gut microbiome: a review of the effect of obesity and surgically induced weight loss. JAMA Surg. 2013;148(6):563-569. 68. Jones N. Gut-microbe swap helps mice shed weight. Bacte-ria transplant provides some of the benefits of gastric bypass surgery without the surgery. Nature. 2013 Mar. doi:10.1038/nature.2013.12688. JNG-mshmswBtpsotbogbswtsNM. 69. Woodard GA, Encarnacion B, Downey JR, et al. Probiotics improve outcomes after Roux-en-Y gastric bypass surgery: a prospective randomized trial. J Gastro Surg. 2009;13(7):1198-1204. 70. Kohli R, Bradley D, Setchell KD, Eagon JC, Abumrad N, Klein S. Weight loss induced by Roux-en-Y gastric bypass but not laparoscopic adjustable gastric banding increases circulating bile acids. J Clin Endocrinol Metab. 2013;98(4): E708-E712. 71. Porez G, Prawitt J, Gross B, Staels B. Bile acid receptors as targets for the treatment of dyslipidemia and cardiovascular disease. J Lipid Res. 2012;53(9):1723-1737. 72. De Giorgi S, Campos V, Egli L, et al. Long-term effects of Roux-en-Y gastric bypass on postprandial plasma lipid and bile acids kinetics in female non diabetic subjects: a cross-sectional pilot study. Clin Nutr. 2015;34(5):911-917. 73. Kohli R, Myronovych A, Tan BK, et al. Bile acid signaling: mechanism for bariatric surgery, cure for NASH? Digest Dis. 2015;33(3):440-446. 74. Ryan KK, Tremaroli V, Clemmensen C, et al. FXR is a molecular target for the effects of vertical sleeve gastrectomy. Nature. 2014;509(7499):183-188. 75. Hollanda A et al. Variability of weight loss results with Roux-en-Y gastric bypass, Editorial comment. Surgery for Obesity and Related Diseases. 2014; 10: 814-821.. 76. Collaboration NCDRF. Worldwide trends in diabetes since 1980: a pooled analysis of 751 population-based studies with 4.4 million participants. Lancet. 2016;387(10027): 1513-1530. 77. Dixon JB, O’Brien PE, Playfair J, et al. Adjustable gastric banding and conventional therapy for type 2 diabetes: a randomized controlled trial. JAMA. 2008;299(3):316-323.Brunicardi_Ch27_p1167-p1218.indd 121123/02/19 2:21 PM 1212SPECIFIC CONSIDERATIONSPART II 78. Schauer PR, Kashyap SR, Wolski K, et al. Bariatric surgery versus intensive medical therapy in obese patients with diabetes. N Engl J Med. 2012;366(17):1567-1576. 79. Mingrone G, Panunzi S, De Gaetano A, et al. Bariatric surgery versus conventional medical therapy for type 2 diabetes. N Engl J Med. 2012;366(17):1577-1585. 80. Ikramuddin S, Korner J, Lee WJ, et al. Roux-en-Y gastric bypass vs intensive medical management for the control of type 2 diabetes, hypertension, and hyperlipidemia: the Diabetes Surgery Study randomized clinical trial. JAMA. 2013;309(21):2240-2249. 81. Cummings DE, Arterburn DE, Westbrook EO, et al. Gastric bypass surgery vs intensive lifestyle and medical intervention for type 2 diabetes: the CROSSROADS randomised controlled trial. Diabetologia. 2016;59(5):945-953. 82. Mingrone G, Panunzi S, De Gaetano A, et al. Bariatric-metabolic surgery versus conventional medical treatment in obese patients with type 2 diabetes: 5 year follow-up of an open-label, single-centre, randomised controlled trial. Lancet. 2015;386(9997):964-973. This is a randomized clinical trial comparing gastric bypass, biliopancreatic diversion, and medical treatment for the treatment of type 2 diabetes in people with obesity. It is only one of 2 randomized studies addressing this question with 5 year follow up, at this time. 83. Halperin F, Ding SA, Simonson DC, et al. Roux-en-Y gastric bypass surgery or lifestyle with intensive medical management in patients with type 2 diabetes: feasibility and 1-year results of a randomized clinical trial. JAMA Surg. 2014;149(7): 716-726. 84. Courcoulas AP, Goodpaster BH, Eagleton JK, et al. Surgical vs medical treatments for type 2 diabetes mellitus: a randomized clinical trial. JAMA Surg. 2014;149(7):707-715. 85. Ding SA, Simonson DC, Wewalka M, et al. Adjustable gastric band surgery or medical management in patients with type 2 diabetes: a randomized clinical trial. J Clin Endocrinol Metab. 2015;100(7):2546-2556. 86. Courcoulas AP, Belle SH, Neiberg RH, et al. Three-year outcomes of bariatric surgery vs lifestyle intervention for type 2 diabetes mellitus treatment: a randomized clinical trial. JAMA Surg. 2015;150(10):931-940. 87. Pories WJ, Swanson MS, MacDonald KG, et al. Who would have thought it? An operation proves to be the most effective therapy for adult-onset diabetes mellitus. Ann Surg. 1995;222(3):339-350; discussion 350-332. 88. Saeidi N, Meoli L, Nestoridi E, et al. Reprogramming of intes-tinal glucose metabolism and glycemic control in rats after gastric bypass. Science. 2013;341(6144):406-410. 89. Mechanick JI, Youdim A, Jones DB, et al. Clinical practice guidelines for the perioperative nutritional, metabolic, and nonsurgical support of the bariatric surgery patient—2013 update: cosponsored by American Association of Clini-cal Endocrinologists, The Obesity Society, and American Society for Metabolic & Bariatric Surgery. Obesity. 2013;21(suppl 1):S1-S27. This is a comprehensive set of guidelines for the perioperative care of the bariatric surgery patient with references to much of the current literature sup-porting these recommendations. 90. Pull CB. Current psychological assessment practices in obesity surgery programs: what to assess and why. Curr Opin Psychiatry. 2010;23(1):30-36. 91. Heinberg LJ, Ashton K, Windover A. Moving beyond dichotomous psychological evaluation: the Cleveland Clinic Behavioral Rating System for weight loss surgery. Surg Obes Relat Dis. 2010;6(2):185-190. 92. Greenberg I, Sogg S, F MP. Behavioral and psychological care in weight loss surgery: best practice update. Obesity. 2009;17(5):880-884. 93. Mahony D. Psychological assessments of bariatric sur-gery patients. Development, reliability, and exploratory factor analysis of the PsyBari. Obes Surg. 2011;21(9): 1395-1406. 94. Fabricatore AN, Crerand CE, Wadden TA, Sarwer DB, Krasucki JL. How do mental health professionals evaluate candidates for bariatric surgery? Survey results. Obes Surg. 2006;16(5):567-573. 95. Mitchell JE, Steffen KJ, de Zwaan M, Ertelt TW, Marino JM, Mueller A. Congruence between clinical and research-based psychiatric assessment in bariatric surgical candidates. Surg Obes Relat Dis. 2010;6(6):628-634. 96. Rasmussen JJ, Fuller WD, Ali MR. Sleep apnea syndrome is significantly underdiagnosed in bariatric surgical patients. Surg Obes Relat Dis. 2012;8(5):569-573. 97. Kolotkin RL, LaMonte MJ, Walker JM, Cloward TV, Davidson LE, Crosby RD. Predicting sleep apnea in bariatric surgery patients. Surg Obes Relat Dis. 2011;7(5):605-610. 98. Daltro C, Gregorio PB, Alves E, et al. Prevalence and severity of sleep apnea in a group of morbidly obese patients. Obes Surg. 2007;17(6):809-814. 99. Palla A, Digiorgio M, Carpene N, et al. Sleep apnea in mor-bidly obese patients: prevalence and clinical predictivity. Respiration. 2009;78(2):134-140. 100. Sareli AE, Cantor CR, Williams NN, et al. Obstructive sleep apnea in patients undergoing bariatric surgery—a tertiary cen-ter experience. Obes Surg. 2011;21(3):316-327. 101. Lee YH, Johan A, Wong KK, Edwards N, Sullivan C. Prevalence and risk factors for obstructive sleep apnea in a multiethnic population of patients presenting for bariatric surgery in Singapore. Sleep Med. 2009;10(2):226-232. 102. Marshall NS, Wong KK, Liu PY, Cullen SR, Knuiman MW, Grunstein RR. Sleep apnea as an independent risk factor for all-cause mortality: the Busselton Health Study. Sleep. 2008;31(8):1079-1085. 103. Schumann R, Jones SB, Cooper B, et al. Update on best practice recommendations for anesthetic perioperative care and pain management in weight loss surgery, 2004-2007. Obesity. 2009;17(5):889-894. 104. Fritscher LG, Mottin CC, Canani S, Chatkin JM. Obesity and obstructive sleep apnea-hypopnea syndrome: the impact of bariatric surgery. Obes Surg. 2007;17(1):95-99. 105. Fris RJ. Preoperative low energy diet diminishes liver size. Obes Surg. 2004;14(9):1165-1170. 106. Edholm D, Kullberg J, Haenni A, et al. Preoperative 4-week low-calorie diet reduces liver volume and intrahepatic fat, and facilitates laparoscopic gastric bypass in morbidly obese. Obes Surg. 2011;21(3):345-350. 107. Van Nieuwenhove Y, Dambrauskas Z, Campillo-Soto A, et al. Preoperative very low-calorie diet and operative outcome after laparoscopic gastric bypass: a randomized multicenter study. Arch Surg. 2011;146(11):1300-1305. 108. Alvarado R, Alami RS, Hsu G, et al. The impact of preoperative weight loss in patients undergoing laparoscopic Roux-en-Y gastric bypass. Obes Surg. 2005;15(9):1282-1286. 109. Alami RS, Morton JM, Schuster R, et al. Is there a benefit to preoperative weight loss in gastric bypass patients? A prospective randomized trial. Surg Obes Relat Dis. 2007;3(2): 141-145; discussion 145-146. 110. Frutos MD, Morales MD, Lujan J, Hernandez Q, Valero G, Parrilla P. Intragastric balloon reduces liver volume in super-obese patients, facilitating subsequent laparoscopic gastric bypass. Obes Surg. 2007;17(2):150-154. 111. Collins J, McCloskey C, Titchner R, et al. Preoperative weight loss in high-risk superobese bariatric patients: a computed tomography-based analysis. Surg Obes Relat Dis. 2011;7(4):480-485.Brunicardi_Ch27_p1167-p1218.indd 121223/02/19 2:21 PM 1213THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27 112. Becouarn G, Topart P, Ritz P. Weight loss prior to bariatric surgery is not a pre-requisite of excess weight loss outcomes in obese patients. Obes Surg. 2010;20(5):574-577. 113. Mosko JD, Nguyen GC. Increased perioperative mortality following bariatric surgery among patients with cirrhosis. Clin Gastroenterol Hepatol. 2011;9(10):897-901. 114. Geerts A, Darius T, Chapelle T, et al. The multicenter Belgian survey on liver transplantation for hepatocellular failure after bariatric surgery. Transplant Proc. 2010;42(10):4395-4398. 115. Handelsman Y, Bloomgarden ZT, Grunberger G, et al. American association of clinical endocrinologists and American college of endocrinology—clinical practice guidelines for developing a diabetes mellitus comprehensive care plan—2015. Endocr Pract. 2015;21(suppl 1):1-87. 116. Winegar DA, Sherif B, Pate V, DeMaria EJ. Venous thromboembolism after bariatric surgery performed by Bariatric Surgery Center of Excellence Participants: analysis of the Bariatric Outcomes Longitudinal Database. Surg Obes Relat Dis. 2011;7(2):181-188. 117. Birkmeyer NJ, Share D, Baser O, et al. Preoperative placement of inferior vena cava filters and outcomes after gastric bypass surgery. Ann Surg. 2010;252(2):313-318. 118. Rowland SP, Dharmarajah B, Moore HM, et al. Inferior vena cava filters for prevention of venous thromboembolism in obese patients undergoing bariatric surgery: a systematic review. Ann Surg. 2015;261(1):35-45. 119. Johansson K, Cnattingius S, Naslund I, et al. Outcomes of pregnancy after bariatric surgery. N Engl J Med. 2015;372(9): 814-824. 120. Kominiarek MA, Jungheim ES, Hoeger KM, Rogers AM, Kahan S, Kim JJ. American Society for Metabolic and Bariatric Surgery position statement on the impact of obesity and obesity treatment on fertility and fertility therapy Endorsed by the American College of Obstetricians and Gynecologists and the Obesity Society. Surg Obes Relat Dis. 2017;13(5):750-757. 121. Gosman GG, King WC, Schrope B, et al. Reproductive health of women electing bariatric surgery. Fertil Steril. 2010;94(4):1426-1431. 122. Eggers C, Obliers R, Koerfer A, et al. A multimedia tool for the informed consent of patients prior to gastric banding. Obesity. 2007;15(11):2866-2873. 123. Arterburn DE, Westbrook EO, Bogart TA, Sepucha KR, Bock SN, Weppner WG. Randomized trial of a video-based patient decision aid for bariatric surgery. Obesity. 2011;19(8):1669-1675. 124. Arterburn D, Flum DR, Westbrook EO, et al. A population-based, shared decision-making approach to recruit for a ran-domized trial of bariatric surgery versus lifestyle for type 2 diabetes. Surg Obes Relat Dis. 2013;9(6):837-844. 125. Sutton D, Spiekermann BF, Bogdonoff DL, Leisure GS, Mathes DD, eds. Perioperative Care: Anesthesia, Medicine and Surgery. 1st ed. St. Louis: Mosby; 1998:547-558. 126. Pisarska M, Malczak P, Major P, Wysocki M, Budzynski A, Pedziwiatr M. Enhanced recovery after surgery protocol in oesophageal cancer surgery: systematic review and meta-analysis. PloS One. 2017;12(3):e0174382. 127. Thorell A, MacCormick AD, Awad S, et al. Guidelines for perioperative care in bariatric surgery: enhanced recovery after surgery (ERAS) society recommendations. World J Surg. 2016;40(9):2065-2083. 128. Nguyen NT, Goldman C, Rosenquist CJ, et al. Laparoscopic versus open gastric bypass: a randomized study of outcomes, quality of life, and costs. Ann Surg. 2001;234(3):279-289; discussion 289-291. 129. Hutter MM, Randall S, Khuri SF, Henderson WG, Abbott WM, Warshaw AL. Laparoscopic versus open gastric bypass for morbid obesity: a multicenter, prospective, risk-adjusted analysis from the National Surgical Quality Improvement Program. Ann Surg. 2006;243(5):657-662; discussion 662-656. 130. Lujan JA, Frutos MD, Hernandez Q, et al. Laparoscopic versus open gastric bypass in the treatment of morbid obesity: a ran-domized prospective study. Ann Surg. 2004;239(4):433-437. 131. Li K, Zou J, Tang J, Di J, Han X, Zhang P. Robotic versus laparoscopic bariatric surgery: a systematic review and meta-analysis. Obes Surg. 2016;26(12):3031-3044. 132. Villamere J, Gebhart A, Vu S, Nguyen NT. Utilization and outcome of laparoscopic versus robotic general and bariatric surgical procedures at academic medical centers. Surg Endosc. 2015;29(7):1729-1736. 133. Ayloo SM, Addeo P, Buchs NC, Shah G, Giulianotti PC. Robot-assisted versus laparoscopic Roux-en-Y gastric bypass: is there a difference in outcomes? World J Surg. 2011;35(3):637-642. 134. Economopoulos KP, Theocharidis V, McKenzie TJ, Sergentanis TN, Psaltopoulou T. Robotic vs. laparoscopic roux-en-y gastric bypass: a systematic review and meta-analysis. Obes Surg. 2015;25(11):2180-2189. 135. MacLean LD, Rhode BM, Nohr CW. Late outcome of isolated gastric bypass. Ann Surg. 2000;231(4):524-528. 136. Brolin RE, Kenler HA, Gorman JH, Cody RP. Long-limb gas-tric bypass in the superobese. A prospective randomized study. Ann Surg. 1992;215(4):387-395. 137. Choban PS, Flancbaum L. The effect of Roux limb lengths on outcome after Roux-en-Y gastric bypass: a prospective, ran-domized clinical trial. Obes Surg. 2002;12(4):540-545. 138. Schirmer BD Lee SK, Northup CJ, et al. Gastrojejunal anastomosis stenosis is lower using linear rather than circular stapling during Roux-en-Y gastric bypass. Presented at SAGES 2006 scientific session, April 2006. 139. Gonzalez R, Lin E, Venkatesh KR, Bowers SP, Smith CD. Gastrojejunostomy during laparoscopic gastric bypass: analy-sis of 3 techniques. Arch Surg. 2003;138(2):181-184. 140. Hutter MM, Schirmer BD, Jones DB, et al. First report from the American College of Surgeons Bariatric Surgery Center Network: laparoscopic sleeve gastrectomy has morbidity and effectiveness positioned between the band and the bypass. Ann Surg. 2011;254(3):410-420; discussion 420-412. 141. DeMaria EJ, Pate V, Warthen M, Winegar DA. Baseline data from American Society for Metabolic and Bariatric Surgery— designated Bariatric Surgery Centers of Excellence using the Bariatric Outcomes Longitudinal Database. Surg Obes Relat Dis. 2010;6(4):347-355. 142. Masoomi H, Kim H, Reavis KM, Mills S, Stamos MJ, Nguyen NT. Analysis of factors predictive of gastrointestinal tract leak in laparoscopic and open gastric bypass. Arch Surg. 2011;146(9):1048-1051. 143. Finks JF, English WJ, Carlin AM, et al. Predicting risk for venous thromboembolism with bariatric surgery: results from the Michigan Bariatric Surgery Collaborative. Ann Surg. 2012;255(6):1100-1104. 144. Gumbs AA, Duffy AJ, Bell RL. Incidence and management of marginal ulceration after laparoscopic Roux-Y gastric bypass. Surg Obes Relat Dis. 2006;2(4):460-463. 145. Parakh S, Soto E, Merola S. Diagnosis and management of internal hernias after laparoscopic gastric bypass. Obes Surg. 2007;17(11):1498-1502. 146. Nguyen NT, Rivers R, Wolfe BM. Early gastrointestinal hemorrhage after laparoscopic gastric bypass. Obes Surg. 2003;13(1):62-65. 147. Aarts EO, van Wageningen B, Janssen IM, Berends FJ. Prevalence of anemia and related deficiencies in the first year following laparoscopic gastric bypass for morbid obesity. J Obes. 2012;2012:193705. 148. Clements RH, Yellumahanthi K, Wesley M, Ballem N, Bland KI. Hyperparathyroidism and vitamin D deficiency after Brunicardi_Ch27_p1167-p1218.indd 121323/02/19 2:21 PM 1214SPECIFIC CONSIDERATIONSPART IIlaparoscopic gastric bypass. Am Surg. 2008;74(6):469-474; discussion 474-465. 149. Abu-Elmagd KM, Costa G, McMichael D, et al. Autologous reconstruction and visceral transplantation for management of patients with gut failure after bariatric surgery: 20 years of experience. Ann Surg. 2015;262(4):586-601. 150. Vance PL, de Lange EE, Shaffer HA, Jr., Schirmer B. Gastric outlet obstruction following surgery for morbid obesity: efficacy of fluoroscopically guided balloon dilation. Radiology. 2002;222(1):70-72. 151. Thodiyil PA, Yenumula P, Rogula T, et al. Selective nonoperative management of leaks after gastric bypass: lessons learned from 2675 consecutive patients. Ann Surg. 2008;248(5):782-792. 152. Awais O, Raftopoulos I, Luketich JD, Courcoulas A. Acute, complete proximal small bowel obstruction after laparoscopic gastric bypass due to intraluminal blood clot formation. Surg Obes Relat Dis. 2005;1(4):418-422; discussion 422-413. 153. Hamoui N, Crookes PF, Kaufman HS. Percutaneous gastric drainage as a treatment for small bowel obstruction after gastric bypass. Obes Surg. 2007;17(10):1411-1412. 154. Gumbs AA, Gagner M, Dakin G, Pomp A. Sleeve gastrectomy for morbid obesity. Obes Surg. 2007;17(7):962-969. 155. Almogy G, Crookes PF, Anthone GJ. Longitudinal gastrectomy as a treatment for the high-risk super-obese patient. Obes Surg. 2004;14(4):492-497. 156. Parikh M, Issa R, McCrillis A, Saunders JK, Ude-Welcome A, Gagner M. Surgical strategies that may decrease leak after laparoscopic sleeve gastrectomy: a systematic review and meta-analysis of 9991 cases. Ann Surg. 2013;257(2):231-237. 157. Rawlins L, Rawlins MP, Brown CC, Schumacher DL. Sleeve gastrectomy: 5-year outcomes of a single institution. Surg Obes Relat Dis. 2013;9(1):21-25. 158. Rosenthal RJ, International Sleeve Gastrectomy Expert Panel, Diaz AA, et al. International Sleeve Gastrectomy Expert Panel consensus statement: best practice guidelines based on experience of >12,000 cases. Surg Obes Relat Dis. 2012;8(1):8-19. 159. Brethauer SA, Hammel JP, Schauer PR. Systematic review of sleeve gastrectomy as staging and primary bariatric procedure. Surg Obes Relat Dis. 2009;5(4):469-475. 160. Choi YY, Bae J, Hur KY, Choi D, Kim YJ. Reinforcing the staple line during laparoscopic sleeve gastrectomy: does it have advantages? A meta-analysis. Obes Surg. 2012;22(8):1206-1213. 161. Albanopoulos K, Alevizos L, Flessas J, et al. Reinforcing the staple line during laparoscopic sleeve gastrectomy: prospective randomized clinical study comparing two different techniques. Preliminary results. Obes Surg. 2012;22(1):42-46. 162. Berger ER, Clements RH, Morton JM, et al. The impact of different surgical techniques on outcomes in laparoscopic sleeve gastrectomies: the first report from the Metabolic and Bariatric Surgery Accreditation and Quality Improvement Program (MBSAQIP). Ann Surg. 2016;264(3):464-473. 163. Parikh A, Alley JB, Peterson RM, et al. Management options for symptomatic stenosis after laparoscopic vertical sleeve gastrectomy in the morbidly obese. Surg Endosc. 2012;26(3):738-746. 164. Carter CO, Fernandez AZ, McNatt SS, Powell MS. Conversion from gastric bypass to sleeve gastrectomy for complications of gastric bypass. Surg Obes Relat Dis. 2016;12(3):572-576. 165. Praveenraj P, Gomes RM, Kumar S, et al. Management of gastric leaks after laparoscopic sleeve gastrectomy for morbid obesity: a tertiary care experience and design of a management algorithm. J Minim Access Surg. 2016;12(4):342-349. 166. Dargent J. Laparoscopic adjustable gastric banding: lessons from the first 500 patients in a single institution. Obes Surg. 1999;9(5):446-452. 167. Allen JW, Lagardere AO, Schirmer BD, Brethauer SA, eds. Minimally Invasive Bariatric Surgery. New York: Springer; 2007:205-212. 168. Angrisani L, Cutolo PP, Formisano G, Nosso G, Vitolo G. Laparoscopic adjustable gastric banding versus Roux-en-Y gastric bypass: 10-year results of a prospective, randomized trial. Surg Obes Relat Dis. 2013;9(3):405-413. 169. Courcoulas AP, Christian NJ, Belle SH, et al. Weight change and health outcomes at 3 years after bariatric surgery among individuals with severe obesity. JAMA. 2013;310(22):2416-2425. This is a 3-year outcomes paper from the Longitudinal Assessment of Bariatric Surgery (LABS-2) effectiveness study. This is a multi-center, longitudinal study of over 2500 people undergoing both gastric bypass and laparoscopic gastric banding. Results in this report are 3-year weight and health (including type 2 diabetes) outcomes. This paper highlights the variable weight trajectories following bariatric surgery. 170. Marceau P, Hould FS, Simard S, et al. Biliopancreatic diversion with duodenal switch. World J Surg. 1998;22(9):947-954. 171. DeMeester TR, Fuchs KH, Ball CS, Albertucci M, Smyrk TC, Marcus JN. Experimental and clinical results with proximal end-to-end duodenojejunostomy for pathologic duodenogastric reflux. Ann Surg. 1987;206(4):414-426. 172. Sudan R, Bennett KM, Jacobs DO, Sudan DL. Multifactorial analysis of the learning curve for robot-assisted laparoscopic biliopancreatic diversion with duodenal switch. Ann Surg. 2012;255(5):940-945. 173. Scopinaro N, Gianetta E, Adami GF, et al. Biliopancreatic diversion for obesity at eighteen years. Surgery. 1996;119(3): 261-268. 174. Lerner H, Whang J, Nipper R. Benefit-risk paradigm for clinical trial design of obesity devices: FDA proposal. Surg Endosc. 2013;27(3):702-707. 175. Ikramuddin S, Blackstone RP, Brancatisano A, et al. Effect of reversible intermittent intra-abdominal vagal nerve blockade on morbid obesity: the ReCharge randomized clinical trial. JAMA. 2014;312(9):915-922. 176. Shikora SA, Wolfe BM, Apovian CM, et al. Sustained weight loss with vagal nerve blockade but not with sham: 18-month results of the ReCharge trial. J Obes. 2015;2015:365604. 177. Schapiro M, Benjamin S, Blackburn G, et al. Obesity and the gastric balloon: a comprehensive workshop. Tarpon Springs, Florida, March 19-21, 1987. Gastrointest Endosc. 1987;33(4):323-327. 178. Courcoulas A, Abu Dayyeh BK, Eaton L, et al. Intragastric balloon as an adjunct to lifestyle intervention: a randomized controlled trial. Int J Obes. 2017;41(3):427-433. 179. Ponce J, Woodman G, Swain J, et al. The REDUCE pivotal trial: a prospective, randomized controlled pivotal trial of a dual intragastric balloon for the treatment of obesity. Surg Obes Relat Dis. 2015;11(4):874-881. 180. Thompson CC, Abu Dayyeh BK, Kushner R, et al. Percutaneous gastrostomy device for the treatment of class II and class III obesity: results of a randomized controlled trial. Am J Gastroenterol. 2017;112(3):447-457. 181. Quezada N, Munoz R, Morelli C, et al. Safety and efficacy of the endoscopic duodenal-jejunal bypass liner prototype in severe or morbidly obese subjects implanted for up to 3 years. Surg Endosc. 2018;32(1):260-267. 182. Rohde U, Hedback N, Gluud LL, Vilsboll T, Knop FK. Effect of the EndoBarrier Gastrointestinal Liner on obesity and type 2 diabetes: a systematic review and meta-analysis. Diabet Obes Metab. 2016;18(3):300-305. 183. Eid GM, McCloskey CA, Eagleton JK, Lee LB, Courcoulas AP. StomaphyX vs a sham procedure for revisional surgery to reduce regained weight in Roux-en-Y gastric bypass patients: Brunicardi_Ch27_p1167-p1218.indd 121423/02/19 2:21 PM 1215THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27a randomized clinical trial. JAMA Surg. 2014;149(4): 372-379. 184. Puzziferri N, Roshek TB, 3rd, Mayo HG, Gallagher R, Belle SH, Livingston EH. Long-term follow-up after bariatric surgery: a systematic review. JAMA. 2014;312(9):934-942. 185. Gletsu-Miller N, Wright BN. Mineral malnutrition following bariatric surgery. Adv Nutr. 2013;4(5):506-517. 186. Spaniolas K, Kasten KR, Celio A, Burruss MB, Pories WJ. Postoperative follow-up after bariatric surgery: effect on weight loss. Obes Surg. 2016;26(4):900-903. 187. Schwoerer A, Kasten K, Celio A, Pories W, Spaniolas K. The effect of close postoperative follow-up on co-morbidity improvement after bariatric surgery. Surg Obes Relat Dis. 2017;13(8):1347-1352. 188. Weichman K, Ren C, Kurian M, et al. The effectiveness of adjustable gastric banding: a retrospective 6-year U.S. follow-up study. Surg Endosc. 2011;25(2):397-403. 189. Ignat M, Vix M, Imad I, et al. Randomized trial of Roux-en-Y gastric bypass versus sleeve gastrectomy in achieving excess weight loss. Br J Surg. 2017;104(3):248-256. 190. Peterli R, Wolnerhanssen BK, Vetter D, et al. Laparoscopic sleeve gastrectomy versus roux-y-gastric bypass for morbid obesity-3-year outcomes of the prospective randomized Swiss Multicenter Bypass Or Sleeve Study (SM-BOSS). Ann Surg. 2017;265(3):466-473. 191. Ren CJ, Patterson E, Gagner M. Early results of laparoscopic biliopancreatic diversion with duodenal switch: a case series of 40 consecutive patients. Obes Surg. 2000;10(6):514-523; discussion 524. 192. Buchwald H, Avidor Y, Braunwald E, et al. Bariatric surgery: a systematic review and meta-analysis. JAMA. 2004;292(14):1724-1737. 193. Gloy VL, Briel M, Bhatt DL, et al. Bariatric surgery versus non-surgical treatment for obesity: a systematic review and meta-analysis of randomised controlled trials. BMJ. 2013;347:f5934. 194. O’Brien PE, Dixon JB, Laurie C, et al. Treatment of mild to moderate obesity with laparoscopic adjustable gastric banding or an intensive medical program: a randomized trial. Ann Intern Med. 2006;144(9):625-633. 195. Maggard-Gibbons M, Maglione M, Livhits M, et al. Bariatric surgery for weight loss and glycemic control in nonmorbidly obese adults with diabetes: a systematic review. JAMA. 2013;309(21):2250-2261. 196. Sjostrom L. Review of the key results from the Swedish Obese Subjects (SOS) trial—a prospective controlled intervention study of bariatric surgery. J Intern Med. 2013;273(3): 219-234. 197. Carlsson LM, Peltonen M, Ahlin S, et al. Bariatric surgery and prevention of type 2 diabetes in Swedish obese subjects. N Engl J Med. 2012;367(8):695-704. This is a very long term outcome paper from the Swedish Obese Subjects (SOS) study, that addresses very long term outcomes of bariatric surgery for the treatment and prevention of type 2 diabetes. 198. Sjostrom L, Peltonen M, Jacobson P, et al. Bariatric surgery and long-term cardiovascular events. JAMA. 2012;307(1):56-65. 199. Sjostrom L, Gummesson A, Sjostrom CD, et al. Effects of bariatric surgery on cancer incidence in obese patients in Sweden (Swedish Obese Subjects Study): a prospective, controlled intervention trial. Lancet Oncol. 2009;10(7):653-662. 200. Sjostrom L, Narbro K, Sjostrom CD, et al. Effects of bariatric surgery on mortality in Swedish obese subjects. N Engl J Med. 2007;357(8):741-752. 201. Sjostrom L, Lindroos AK, Peltonen M, et al. Lifestyle, diabetes, and cardiovascular risk factors 10 years after bariatric surgery. N Engl J Med. 2004;351(26):2683-2693. 202. Adams TD, Gress RE, Smith SC, et al. Long-term mortality after gastric bypass surgery. N Engl J Med. 2007;357(8): 753-761. 203. Adams TD, Davidson LE, Litwin SE, et al. Health benefits of gastric bypass surgery after 6 years. JAMA. 2012;308(11): 1122-1131. 204. Adams TD, Davidson LE, Litwin SE, et al. Weight and metabolic outcomes 12 years after gastric bypass. N Engl J Med. 2017;377(12):1143-1155. This is the longest term paper to date from the Utah Obesity study which compares gastric bypass to 2 different control groups for weight and health outcomes, including type 2 diabetes. 205. Maciejewski ML, Livingston EH, Smith VA, et al. Survival among high-risk patients after bariatric surgery. JAMA. 2011;305(23):2419-2426. 206. Maciejewski ML, Livingston EH, Smith VA, Kahwati LC, Henderson WG, Arterburn DE. Health expenditures among high-risk patients after gastric bypass and matched controls. Arch Surg. 2012;147(7):633-640. 207. Arterburn DE, Olsen MK, Smith VA, et al. Association between bariatric surgery and long-term survival. JAMA. 2015;313(1):62-70. 208. Maciejewski ML, Arterburn DE, Van Scoyoc L, et al. Bariatric surgery and long-term durability of weight loss. JAMA Surg. 2016;151(11):1046-1055. 209. Belle SH, Berk PD, Chapman WH, et al. Baseline characteristics of participants in the Longitudinal Assessment of Bariatric Surgery-2 (LABS-2) study. Surg Obes Relat Dis. 2013;9(6):926-935. 210. Courcoulas AP, Christian NJ, O’Rourke RW, et al. Preoperative factors and 3-year weight change in the Longitudinal Assessment of Bariatric Surgery (LABS) consortium. Surg Obes Relat Dis. 2015;11(5):1109-1118. 211. Mitchell JE, Christian NJ, Flum DR, et al. Postoperative behavioral variables and weight change 3 years after bariatric surgery. JAMA Surg. 2016;151(8):752-757. 212. Arterburn DE, Bogart A, Sherwood NE, et al. A multisite study of long-term remission and relapse of type 2 diabetes mellitus following gastric bypass. Obes Surg. 2013;23(1): 93-102. 213. Arterburn D, Bogart A, Coleman KJ, et al. Comparative effectiveness of bariatric surgery vs. nonsurgical treatment of type 2 diabetes among severely obese adults. Obes Res Clin Pract. 2013;7(4):e258-268. 214. Arterburn D, Powers JD, Toh S, et al. Comparative effectiveness of laparoscopic adjustable gastric banding vs laparoscopic gastric bypass. JAMA Surg. 2014;149(12):1279-1287. 215. Carlin AM, Zeni TM, English WJ, et al. The comparative effectiveness of sleeve gastrectomy, gastric bypass, and adjustable gastric banding procedures for the treatment of morbid obesity. Ann Surg. 2013;257(5):791-797. This is data from a statewide clinical registry, where outcomes of the 3 most common procedures; gastric bypass, sleeve gastrectomy, and laparoscopic adjustable banding are compared. It showed that rates for both short term weight loss and overall complications for the sleeve gastrectomy were positioned between gastric bypass and laparoscopic adjustable banding. 216. Finks JF, Kole KL, Yenumula PR, et al. Predicting risk for serious complications with bariatric surgery: results from the Michigan Bariatric Surgery Collaborative. Ann Surg. 2011;254(4):633-640. 217. Birkmeyer NJ, Finks JF, English WJ, et al. Risks and benefits of prophylactic inferior vena cava filters in patients undergoing bariatric surgery. J Hosp Med. 2013;8(4):173-177. 218. Varban OA, Sheetz KH, Cassidy RB, et al. Evaluating the effect of operative technique on leaks after laparoscopic Brunicardi_Ch27_p1167-p1218.indd 121523/02/19 2:21 PM 1216SPECIFIC CONSIDERATIONSPART IIsleeve gastrectomy: a case-control study. Surg Obes Relat Dis. 2017;13(4):560-567. 219. Birkmeyer JD, Finks JF, O’Reilly A, et al. Surgical skill and complication rates after bariatric surgery. N Engl J Med. 2013;369(15):1434-1442. 220. Wood GC, Benotti PN, Lee CJ, et al. Evaluation of the association between preoperative clinical factors and long-term weight loss after roux-en-y gastric bypass. JAMA Surg. 2016;151(11):1056-1062. 221. Still CD, Wood GC, Benotti P, et al. Preoperative prediction of type 2 diabetes remission after Roux-en-Y gastric bypass surgery: a retrospective cohort study. Lancet Diabet Endocrinol. 2014;2(1):38-45. 222. Tice JA, Karliner L, Walsh J, Petersen AJ, Feldman MD. Gastric banding or bypass? A systematic review comparing the two most popular bariatric procedures. Am J Med. 2008;121(10):885-893. 223. Padwal R, Klarenbach S, Wiebe N, et al. Bariatric surgery: a systematic review and network meta-analysis of randomized trials. Obes Res. 2011;12(8):602-621. 224. Trastulli S, Desiderio J, Guarino S, et al. Laparoscopic sleeve gastrectomy compared with other bariatric surgical procedures: a systematic review of randomized trials. Surg Obes Relat Dis. 2013;9(5):816-829. 225. Yang X, Yang G, Wang W, Chen G, Yang H. A meta-analysis: to compare the clinical results between gastric bypass and sleeve gastrectomy for the obese patients. Obes Surg. 2013;23(7):1001-1010. 226. Vest AR, Heneghan HM, Agarwal S, Schauer PR, Young JB. Bariatric surgery and cardiovascular outcomes: a systematic review. Heart. 2012;98(24):1763-1777. 227. Vest AR, Heneghan HM, Schauer PR, Young JB. Surgical management of obesity and the relationship to cardiovascular disease. Circulation. 2013;127(8):945-959. 228. Frezza EE, Ikramuddin S, Gourash W, et al. Symptomatic improvement in gastroesophageal reflux disease (GERD) following laparoscopic Roux-en-Y gastric bypass. Surg Endosc. 2002;16(7):1027-1031. 229. Perry Y, Courcoulas AP, Fernando HC, Buenaventura PO, McCaughan JS, Luketich JD. Laparoscopic Roux-en-Y gastric bypass for recalcitrant gastroesophageal reflux disease in morbidly obese patients. JSLS. 2004;8(1):19-23. 230. Zhang N, Maffei A, Cerabona T, Pahuja A, Omana J, Kaul A. Reduction in obesity-related comorbidities: is gastric bypass better than sleeve gastrectomy? Surg Endosc. 2013;27(4):1273-1280. 231. Sarkhosh K, Switzer NJ, El-Hadi M, Birch DW, Shi X, Karmali S. The impact of bariatric surgery on obstructive sleep apnea: a systematic review. Obes Surg. 2013;23(3):414-423. 232. Dixon JB, Schachter LM, O’Brien PE, et al. Surgical vs conventional therapy for weight loss treatment of obstructive sleep apnea: a randomized controlled trial. JAMA. 2012;308(11):1142-1149. 233. Dixon AE, Pratley RE, Forgione PM, et al. Effects of obesity and bariatric surgery on airway hyperresponsiveness, asthma control, and inflammation. J Allerg Clin Immunol. 2011;128(3):508-515 e501-502. 234. Boulet LP, Turcotte H, Martin J, Poirier P. Effect of bariatric surgery on airway response and lung function in obese subjects with asthma. Respirat Med. 2012;106(5):651-660. 235. Beymer C, Kowdley KV, Larson A, Edmonson P, Dellinger EP, Flum DR. Prevalence and predictors of asymptomatic liver disease in patients undergoing gastric bypass surgery. Arch Surg. 2003;138(11):1240-1244. 236. Rabl C, Campos GM. The impact of bariatric surgery on nonalcoholic steatohepatitis. Semin Liver Dis. 2012;32(1): 80-91. 237. Iossi MF, Konstantakos EK, Teel DD, 2nd, et al. Musculoskeletal function following bariatric surgery. Obesity. 2013;21(6):1104-1110. 238. Vincent HK, Heywood K, Connelly J, Hurley RW. Obesity and weight loss in the treatment and prevention of osteoarthritis. PM R. 2012;4(5 suppl):S59-S67. 239. King WC, Chen JY, Belle SH, et al. Change in pain and physical function following bariatric surgery for severe obesity. JAMA. 2016;315(13):1362-1371. 240. Karlsson J, Taft C, Ryden A, Sjostrom L, Sullivan M. Ten-year trends in health-related quality of life after surgical and conventional treatment for severe obesity: the SOS intervention study. Int J Obes. 2007;31(8):1248-1261. 241. Kolotkin RL, Davidson LE, Crosby RD, Hunt SC, Adams TD. Six-year changes in health-related quality of life in gastric bypass patients versus obese comparison groups. Surg Obes Relat Dis. 2012;8(5):625-633. 242. Nickel MK, Loew TH, Bachler E. Change in mental symptoms in extreme obesity patients after gastric banding, part II: six-year follow up. Int J Psychiatry Med. 2007;37(1):69-79. 243. Schauer PR, Nor Hanipah Z, Rubino F. Metabolic surgery for treating type 2 diabetes mellitus: now supported by the world’s leading diabetes organizations. Cleve Clin J Med. 2017;84 (7 suppl 1):S47-S56. 244. Buchwald H, Estok R, Fahrbach K, et al. Weight and type 2 diabetes after bariatric surgery: systematic review and meta-analysis. Am J Med. 2009;122(3):248-256 e245. 245. Sjostrom L, Peltonen M, Jacobson P, et al. Association of bariatric surgery with long-term remission of type 2 diabetes and with microvascular and macrovascular complications. JAMA. 2014;311(22):2297-2304. 246. Schauer PR, Bhatt DL, Kirwan JP, et al. Bariatric surgery versus intensive medical therapy for diabetes—3-year outcomes. N Engl J Med. 2014;370(21):2002-2013. 247. Ikramuddin S, Billington CJ, Lee WJ, et al. Roux-en-Y gastric bypass for diabetes (the Diabetes Surgery Study): 2-year outcomes of a 5-year, randomised, controlled trial. Lancet Diabet Endocrinol. 2015;3(6):413-422. 248. Liang Z, Wu Q, Chen B, Yu P, Zhao H, Ouyang X. Effect of laparoscopic Roux-en-Y gastric bypass surgery on type 2 diabetes mellitus with hypertension: a randomized controlled trial. Diabet Clin Res Pract. 2013;101(1):50-56. 249. Courcoulas AP, Yanovski SZ, Bonds D, et al. Long-term outcomes of bariatric surgery: a National Institutes of Health symposium. JAMA Surg. 2014;149(12):1323-1329. 250. Wentworth JM, Playfair J, Laurie C, et al. Multidisciplinary diabetes care with and without bariatric surgery in overweight people: a randomised controlled trial. Lancet Diabet Endocrinol. 2014;2(7):545-552. 251. Parikh M, Chung M, Sheth S, et al. Randomized pilot trial of bariatric surgery versus intensive medical weight management on diabetes remission in type 2 diabetic patients who do NOT meet NIH criteria for surgery and the role of soluble RAGE as a novel biomarker of success. Ann Surg. 2014;260(4):617-622; discussion 622-614. 252. Schauer PR, Bhatt DL, Kirwan JP, et al. Bariatric surgery versus intensive medical therapy for diabetes—5-year outcomes. N Engl J Med. 2017;376(7):641-651. This is a randomized clinical trial comparing gastric bypass, gastric sleeve, and intensive medical management for the treatment of type 2 diabetes in people with obesity. It is only one of 2 randomized studies with 5 year follow up, at this time. It shows that surgical treatments are superior to intensive medical treatment for glycemic control. 253. Shah SS Todkar J, Phadake U, et al. Gastric bypass vs. medical/lifestyle care for type 2 diabetes in South Asians with BMI 25-40 kg/m2: the COSMID randomized trial Brunicardi_Ch27_p1167-p1218.indd 121623/02/19 2:21 PM 1217THE SURGICAL MANAGEMENT OF OBESITYCHAPTER 27[261-OR]. Presented at the American Diabetes Association’s 76th Scientific Session; June 10-14, 2016; New Orleans, LA. 254. Encinosa WE, Bernard DM, Du D, Steiner CA. Recent improvements in bariatric surgery outcomes. Med Care. 2009; 47(5):531-535. 255. Birkmeyer NJ, Dimick JB, Share D, et al. Hospital complication rates with bariatric surgery in Michigan. JAMA. 2010;304(4):435-442. 256. Rubino F, Kaplan LM, Schauer PR, Cummings DE. The Diabetes Surgery Summit consensus conference: recommendations for the evaluation and use of gastrointestinal surgery to treat type 2 diabetes mellitus. Ann Surg. 2010;251(3):399-405. 257. Buchwald H, Estok R, Fahrbach K, Banel D, Sledge I. Trends in mortality in bariatric surgery: a systematic review and meta-analysis. Surgery. 2007;142(4):621-632; discussion 632-625. 258. Dimick JB, Nicholas LH, Ryan AM, Thumma JR, Birkmeyer JD. Bariatric surgery complications before vs after implementation of a national policy restricting coverage to centers of excellence. JAMA. 2013;309(8):792-799. 259. DeMaria EJ, Murr M, Byrne TK, et al. Validation of the obesity surgery mortality risk score in a multicenter study proves it stratifies mortality risk in patients undergoing gastric bypass for morbid obesity. Ann Surg. 2007;246(4):578-582; discussion 583-574. 260. DeMaria EJ, Portenier D, Wolfe L. Obesity surgery mortality risk score: proposal for a clinically useful score to predict mortality risk in patients undergoing gastric bypass. Surg Obes Relat Dis. 2007;3(2):134-140. 261. Thomas H, Agrawal S. Systematic review of obesity surgery mortality risk score—preoperative risk stratification in bariatric surgery. Obes Surg. 2012;22(7):1135-1140. 262. O’Brien PE, MacDonald L, Anderson M, Brennan L, Brown WA. Long-term outcomes after bariatric surgery: fifteen-year follow-up of adjustable gastric banding and a systematic review of the bariatric surgical literature. Ann Surg. 2013;257(1):87-94. 263. Rariy CM, Rometo D, Korytkowski M. Post-gastric bypass hypoglycemia. Curr Diabet Rep. 2016;16(2):19. 264. Goldfine AB, Patti ME. How common is hypoglycemia after gastric bypass? Obesity. 2016;24(6):1210-1211. 265. Service GJ, Thompson GB, Service FJ, Andrews JC, Collazo-Clavell ML, Lloyd RV. Hyperinsulinemic hypoglycemia with nesidioblastosis after gastric-bypass surgery. N Engl J Med. 2005;353(3):249-254. 266. Patti ME, Goldfine AB. Hypoglycemia after gastric bypass: the dark side of GLP-1. Gastroenterology. 2014;146(3):605-608. 267. Eisenberg D, Azagury DE, Ghiassi S, Grover BT, Kim JJ. ASMBS position statement on postprandial hyperinsulinemic hypoglycemia after bariatric surgery. Surg Obes Relat Dis. 2017;13(3):371-378. 268. Stephansson O, Johansson K, Naslund I, Neovius M. Bariatric Surgery and Preterm Birth. N Engl J Med. 2016;375(8):805-806. 269. Maluenda F, Csendes A, De Aretxabala X, et al. Alcohol absorption modification after a laparoscopic sleeve gastrectomy due to obesity. Obes Surg. 2010;20(6):744-748. 270. Steffen KJ, Engel SG, Pollert GA, Li C, Mitchell JE. Blood alcohol concentrations rise rapidly and dramatically after Roux-en-Y gastric bypass. Surg Obes Relat Dis. 2013;9(3): 470-473. 271. King WC, Chen JY, Mitchell JE, et al. Prevalence of alcohol use disorders before and after bariatric surgery. JAMA. 2012;307(23):2516-2525. 272. King WC, Chen JY, Courcoulas AP, et al. Alcohol and other substance use after bariatric surgery: prospective evidence from a U.S. multicenter cohort study. Surg Obes Relat Dis. 2017;13(8):1392-1402. 273. Peterhansel C, Petroff D, Klinitzke G, Kersting A, Wagner B. Risk of completed suicide after bariatric surgery: a systematic review. Obes Rev. 2013;14(5):369-382. 274. Gribsholt SB, Thomsen RW, Svensson E, Richelsen B. Overall and cause-specific mortality after Roux-en-Y gastric bypass surgery: a nationwide cohort study. Surg Obes Relat Dis. 2017;13(4):581-587. 275. Bhatti JA, Nathens AB, Thiruchelvam D, Grantcharov T, Goldstein BI, Redelmeier DA. Self-harm emergencies after bariatric surgery: a population-based cohort study. JAMA Surg. 2016;151(3):226-232. 276. Courcoulas A. Who, why, and how? Suicide and harmful behaviors after bariatric surgery. Ann Surg. 2017;265(2): 253-254. 277. Tindle HA, Omalu B, Courcoulas A, Marcus M, Hammers J, Kuller LH. Risk of suicide after long-term follow-up from bariatric surgery. Am J Med. 2010;123(11):1036-1042. 278. Parrott J, Frank L, Rabena R, Craggs-Dino L, Isom KA, Greiman L. American Society for Metabolic and Bariatric Surgery integrated health nutritional guidelines for the surgical weight loss patient 2016 update: micronutrients. Surg Obes Relat Dis. 2017;13(5):727-741. 279. Dogan K, Homan J, Aarts EO, de Boer H, van Laarhoven CJ, Berends FJ. Long-term nutritional status in patients following Roux-en-Y gastric bypass surgery. Clin Nutr. 2018;37(2):612-617. 280. Pellitero S, Martinez E, Puig R, et al. Evaluation of vitamin and trace element requirements after sleeve gastrectomy at long term. Obes Surg. 2017;27(7):1674-1682. 281. Brethauer SA, Kothari S, Sudan R, et al. Systematic review on reoperative bariatric surgery: American Society for Metabolic and Bariatric Surgery Revision Task Force. Surg Obes Relat Dis. 2014;10(5):952-972. 282. Field AE, Camargo CA Jr, Ogino S. The merits of subtyping obesity: one size does not fit all. JAMA. 2013; 310(20):2147-2148. 283. Kellogg TA. Revisional bariatric surgery. Surg Clin North Am. 2011;91(6):1353-1371, x. 284. Moshiri M, Osman S, Robinson TJ, Khandelwal S, Bhargava P, Rohrmann CA. Evolution of bariatric surgery: a historical perspective. AJR Am J Roentgenol. 2013;201(1):W40-W48. 285. Switzer NJ, Karmali S, Gill RS, Sherman V. Revisional bariatric surgery. Surg Clin North Am. 2016;96(4):827-842. 286. Ikramuddin S, Livingston EH. New insights on bariatric surgery outcomes. JAMA. 2013;310(22):2401-2402. 287. Kral JG. Selection of patients for anti-obesity surgery. Int J Obes Relat Metab Disord. 2001;25(suppl 1):S107-S112. 288. Zundel N, Hernandez JD. Revisional surgery after restrictive procedures for morbid obesity. Surg Laparosc Endosc Percutan Tech. 2010;20(5):338-343. 289. Fulton C, Sheppard C, Birch D, Karmali S, de Gara C. A comparison of revisional and primary bariatric surgery. Can J Surg. 2017;60(3):205-211. 290. Hallowell PT, Stellato TA, Yao DA, Robinson A, Schuster MM, Graf KN. Should bariatric revisional surgery be avoided secondary to increased morbidity and mortality? Am J Surg. 2009;197(3):391-396. 291. Sarr MG. Reoperative bariatric surgery. Surg Endosc. 2007;21(11):1909-1913. 292. van Gemert WG, van Wersch MM, Greve JW, Soeters PB. Revisional surgery after failed vertical banded gastroplasty: restoration of vertical banded gastroplasty or conversion to gastric bypass. Obes Surg. 1998;8(1):21-28. 293. Gagne DJ, Dovec E, Urbandt JE. Laparoscopic revision of vertical banded gastroplasty to Roux-en-Y gastric bypass: outcomes of 105 patients. Surg Obes Relat Dis. 2011;7(4):493-499.Brunicardi_Ch27_p1167-p1218.indd 121723/02/19 2:21 PM 1218SPECIFIC CONSIDERATIONSPART II 294. Schouten R, Wiryasaputra DC, van Dielen FM, van Gemert WG, Greve JW. Influence of reoperations on long-term quality of life after restrictive procedures: a prospective study. Obes Surg. 2011;21(7):871-879. 295. Foletto M, Prevedello L, Bernante P, et al. Sleeve gastrectomy as revisional procedure for failed gastric banding or gastroplasty. Surg Obes Relat Dis. 2010;6(2):146-151. 296. Dapri G, Cadiere GB, Himpens J. Laparoscopic conversion of adjustable gastric banding and vertical banded gastroplasty to duodenal switch. Surg Obes Relat Dis. 2009;5(6):678-683. 297. Coblijn UK, Verveld CJ, van Wagensveld BA, Lagarde SM. Laparoscopic Roux-en-Y gastric bypass or laparoscopic sleeve gastrectomy as revisional procedure after adjustable gastric band--a systematic review. Obes Surg. 2013;23(11):1899-1914. 298. Aarts EO, Dogan K, Koehestanie P, Janssen IM, Berends FJ. What happens after gastric band removal without additional bariatric surgery? Surg Obes Relat Dis. 2014;10(6):1092-1096. 299. Ardestani A, Lautz DB, Tavakkolizadeh A. Band revision versus Roux-en-Y gastric bypass conversion as salvage operation after laparoscopic adjustable gastric banding. Surg Obes Relat Dis. 2011;7(1):33-37. 300. Lanthaler M, Mittermair R, Erne B, Weiss H, Aigner F, Nehoda H. Laparoscopic gastric re-banding versus laparoscopic gastric bypass as a rescue operation for patients with pouch dilatation. Obes Surg. 2006;16(4):484-487. 301. Muller MK, Attigah N, Wildi S, et al. High secondary failure rate of rebanding after failed gastric banding. Surg Endosc. 2008;22(2):448-453. 302. Obeid NR, Schwack BF, Kurian MS, Ren-Fielding CJ, Fielding GA. Single-stage versus 2-stage sleeve gastrectomy as a conversion after failed adjustable gastric banding: 30-day outcomes. Surg Endosc. 2014;28(11):3186-3192. 303. Van Nieuwenhove Y, Ceelen W, Van Renterghem K, Van de Putte D, Henckens T, Pattyn P. Conversion from band to bypass in two steps reduces the risk for anastomotic strictures. Obes Surg. 2011;21(4):501-505. 304. Switzer NJ & Karmali S. The sleeve gastrectomy and how and why it can fail? Surg Curr Res 2014;4:180. 2014;4:180. SNKSTsgahawicfSCR. 305. Eid GM, Brethauer S, Mattar SG, Titchner RL, Gourash W, Schauer PR. Laparoscopic sleeve gastrectomy for super obese patients: forty-eight percent excess weight loss after 6 to 8 years with 93% follow-up. Ann Surg. 2012;256(2):262-265. 306. Carmeli I, Golomb I, Sadot E, Kashtan H, Keidar A. Laparoscopic conversion of sleeve gastrectomy to a biliopancreatic diversion with duodenal switch or a Roux-en-Y gastric bypass due to weight loss failure: our algorithm. Surg Obes Relat Dis. 2015;11(1):79-85. 307. Cheung D, Switzer NJ, Gill RS, Shi X, Karmali S. Revisional bariatric surgery following failed primary laparoscopic sleeve gastrectomy: a systematic review. Obes Surg. 2014; 24(10):1757-1763. 308. Nedelcu M, Noel P, Iannelli A, Gagner M. Revised sleeve gastrectomy (re-sleeve). Surg Obes Relat Dis. 2015;11(6): 1282-1288. 309. Dykstra M SN, et al. Roux-en-Y gastric bypass: how and why it fails? Surg Curr Res. 2014;4:165. 310. Tsai WS, Inge TH, Burd RS. Bariatric surgery in adolescents: recent national trends in use and in-hospital outcome. Arch Pediatr Adolesc Med. 2007;161(3):217-221. 311. Zwintscher NP, Azarow KS, Horton JD, Newton CR, Martin MJ. The increasing incidence of adolescent bariatric surgery. J Pediatr Surg. 2013;48(12):2401-2407. 312. Treadwell JR, Sun F, Schoelles K. Systematic review and meta-analysis of bariatric surgery for pediatric obesity. Ann Surg. 2008;248(5):763-776. 313. Michalsky M, Reichard K, Inge T, et al. ASMBS pediatric committee best practice guidelines. Surg Obes Relat Dis. 2012;8(1):1-7. 314. Inge TH, Zeller M, Harmon C, et al. Teen-Longitudinal Assessment of Bariatric Surgery: methodological features of the first prospective multicenter study of adolescent bariatric surgery. J Pediatr Surg. 2007;42(11):1969-1971. 315. Inge TH, Zeller MH, Jenkins TM, et al. Perioperative outcomes of adolescents undergoing bariatric surgery: the Teen-Longitudinal Assessment of Bariatric Surgery (Teen-LABS) study. JAMA Pediatr. 2014;168(1):47-53. 316. Bariatric Surgery for Adolescents and Young Adults: A Review of Comparative Clinical Effec-tiveness, Cost-Effectiveness, and Evidence-Based Guidelines [Internet]. Ottawa (ON): Canadian Agency for Drugs and Technologies in Health; 2016 Aug 3. 317. Klebanoff MJ, Chhatwal J, Nudel JD, Corey KE, Kaplan LM, Hur C. Cost-effectiveness of bariatric surgery in adolescents with obesity. JAMA Surg. 2017;152(2):136-141. 318. Sampalis JS, Liberman M, Auger S, Christou NV. The impact of weight reduction surgery on health-care costs in morbidly obese patients. Obes Surg. 2004;14(7):939-947. 319. Cremieux PY, Buchwald H, Shikora SA, Ghosh A, Yang HE, Buessing M. A study on the economic impact of bariatric surgery. Am J Manag Care. 2008;14(9):589-596. 320. Finkelstein EA, Allaire BT, Burgess SM, Hale BC. Financial implications of coverage for laparoscopic adjustable gastric banding. Surg Obes Relat Dis. 2011;7(3):295-303. 321. Neovius M, Narbro K, Keating C, et al. Health care use during 20 years following bariatric surgery. JAMA. 2012;308(11):1132-1141. 322. Weiner JP, Goodwin SM, Chang HY, et al. Impact of bariatric surgery on health care costs of obese persons: a 6-year follow-up of surgical and comparison cohorts using health plan data. JAMA Surg. 2013;148(6):555-562. 323. Picot J, Jones J, Colquitt JL, et al. The clinical effectiveness and cost-effectiveness of bariatric (weight loss) surgery for obesity: a systematic review and economic evaluation. Health Technol Assess. 2009;13(41):1-190, 215-357, iii-iv. 324. Padwal R, Klarenbach S, Wiebe N, et al. Bariatric surgery: a systematic review of the clinical and economic evidence. J Gen Intern Med. 2011;26(10):1183-1194. 325. Blondet JJ, Morton JM, Nguyen NT. Hospital accreditation and bariatric surgery: is it important? Adv Surg. 2015;49:123-129. 326. Surgery, A. C. o. S. a. A. S. f. M. a. B. (2016). Standards Manual V2.0: Resources for Optimal Care of the Metabolic and bariatric Surgery patient 2016 (pp. 1-62). https://www.facs.org/quality-programs/mbsaqip: American College of Surgery. 327. Azagury D, Morton JM. Bariatric surgery outcomes in us accredited vs non-accredited centers: a systematic review. J Am Coll Surg. 2016;223(3):469-477. 328. Froylich D, Corcelles R, Daigle CR, et al. Weight loss is higher among patients who undergo body contouring procedures after bariatric surgery. Surg Obes Relat Dis. 2016;12(9):1731-1736. 329. Hurwitz DJ. Body contouring surgery in the bariatric surgical patient. In: Operative Techniques in Plastic Surgery and Reconstructive Surgery. New York: Elsevier; 2002:87. 330. Hurwitz DJ. Single-staged total body lift after massive weight loss. Ann Plast Surg. 2004;52(5):435-441; discussion 441. 331. Balague N, Combescure C, Huber O, Pittet-Cuenod B, Modarressi A. Plastic surgery improves long-term weight control after bariatric surgery. Plast Reconstruct Surg. 2013;132(4):826-833.Brunicardi_Ch27_p1167-p1218.indd 121823/02/19 2:21 PM
Small IntestineAli Tavakkoli, Stanley W. Ashley, and Michael J. Zinner 28chapterINTRODUCTORY COMMENTSThe small intestine is a remarkable and complex organ that is not only the principle site of nutrient digestion and absorption but also contains the body’s largest reservoir of immunologi-cally active and hormone-producing cells. Hence, it can be con-ceptualized as the largest organ of the immune and endocrine systems.1 It achieves this diversity of action through unique anatomical features, which provide it with a massive sur-face area, a diversity of cell types, and a complex neural network to coordinate these functions.Despite the size and importance of the small intestine, diseases of this organ are relatively infrequent and can present diagnostic and therapeutic challenges. Despite introduction of novel imaging techniques such as capsule endoscopy and dou-ble balloon endoscopy, diagnostic tests lack sufficient ability to reliably assess the small bowel. Furthermore, few high-quality, controlled data on the efficacy of surgical therapies for small bowel diseases are available.1Therefore, sound clinical judgment and a thorough under-standing of anatomy, physiology, and pathophysiology remain essential to the care of patients with suspected small bowel disorders.GROSS ANATOMYThe small intestine is a tubular structure that extends from the pylorus to the cecum. The estimated length varies depending on whether radiologic, surgical, or autopsy measurements are made. In the living, it is thought to measure 4 to 6 meters.2 The small intestine consists of three segments lying in series: the duodenum, the jejunum, and the ileum. The duodenum, the most proximal segment, lies in the retroperitoneum immediately adja-cent to the head and inferior border of the body of the pancreas. The duodenum is demarcated from the stomach by the pylorus and from the jejunum by the ligament of Treitz. The jejunum and ileum lie within the peritoneal cavity and are tethered to the Introductory Comments1219Gross Anatomy1219Histology1220Development1221Physiology1222Digestion and Absorption / 1222Barrier and Immune Function / 1225Motility / 1226Endocrine Function / 1227Intestinal Adaptation / 1228Small Bowel Obstruction1228Epidemiology / 1228Pathophysiology / 1229Clinical Presentation / 1229Diagnosis / 1229Therapy / 1231Outcomes / 1232Prevention / 1233Other Causes of Small Bowel Obstruction / 1233Ileus and Other Disorders of Intestinal Motility1233Pathophysiology / 1233Clinical Presentation / 1234Diagnosis / 1234Therapy / 1234Crohn’s Disease1235Pathophysiology / 1235Clinical Presentation / 1236Diagnosis / 1237Therapy / 1238Outcomes / 1240Intestinal Fistulas1240Pathophysiology / 1240Clinical Presentation / 1240Diagnosis / 1240Therapy / 1241Outcomes / 1241Small Bowel Neoplasms1241Pathophysiology / 1242Clinical Presentation / 1243Diagnosis / 1243Therapy / 1244Outcomes / 1245Radiation Enteritis1245Pathophysiology / 1245Clinical Presentation / 1245Diagnosis / 1245Therapy / 1246Outcomes / 1246Prevention / 1246Meckel’s Diverticula1246Pathophysiology / 1246Clinical Presentation / 1247Diagnosis / 1247Therapy / 1248Acquired Diverticula1248Pathophysiology / 1249Clinical Presentation / 1250Diagnosis / 1250Therapy / 1250Mesenteric Ischemia1250Miscellaneous Conditions1250Obscure GI Bleeding / 1250Small Bowel Perforation / 1251Chylous Ascites / 1252Intussusception / 1253Pneumatosis Intestinalis / 1253Short Bowel Syndrome1254Pathophysiology / 1254Therapy / 1255Outcomes / 1255Brunicardi_Ch28_p1219-p1258.indd 121923/02/19 2:24 PM 1220JejunumIleumKey Points1 The small intestine performs a diverse set of functions.2 Small bowel obstruction is one of the most common surgical diagnoses.3 Most cases of small bowel obstruction are due to adhe-sions from previous surgery and resolve with conservative management.4 Tumors and malignancies of the small bowel are rare and difficult to diagnose. 5 If following surgical resection less than 200 cm of small bowel remains, patients are at risk of developing short bowel syndrome.retroperitoneum by a broad-based mesentery. No distinct ana-tomical landmark demarcates the jejunum from the ileum; the proximal 40% of the jejunoileal segment is arbitrarily defined as the jejunum and the distal 60% as the ileum. The ileum is demarcated from the cecum by the ileocecal valve.The small intestine contains internal mucosal folds known as plicae circulares or valvulae conniventes that are visible upon gross inspection. These folds are also visible radiographically and help in the distinction between small intestine and colon, which does not contain them, on abdominal radiographs. These folds are more prominent in the proximal intestine than in the distal small intestine. Other features evident on gross inspection that are more characteristic of the proximal than distal small intestine include larger circumference, thicker wall, less fatty mesentery, and longer vasa recta (Fig. 28-1). Gross examination of the small-intestinal mucosa also reveals aggregates of lymphoid follicles. Those follicles, located in the ileum, are the most prominent and are designated Peyer’s patches.Most of the duodenum derives its arterial blood from branches of both the celiac and the superior mesenteric arteries. The distal duodenum, the jejunum, and the ileum derive their arterial blood from the superior mesenteric artery. Their venous drainage occurs via the superior mesenteric vein. Lymph drain-age occurs through lymphatic vessels coursing parallel to corre-sponding arteries. This lymph drains through mesenteric lymph nodes to the cisterna chyli, then through the thoracic duct, and ultimately into the left subclavian vein. The parasympathetic and sympathetic innervation of the small intestine is derived from the vagus and splanchnic nerves, respectively.HISTOLOGYThe wall of the small intestine consists of four distinct layers: mucosa, submucosa, muscularis propria, and serosa (Fig. 28-2).The mucosa is the innermost layer and it consists of three layers: epithelium, lamina propria, and muscularis mucosae. The epithelium is exposed to the intestinal lumen and is the surface through which absorption from and secretion into the lumen occurs. The lamina propria is located immediately external to the epithelium and consists of connective tissue and a heterogeneous population of cells. It is demarcated from the more external submucosa by the muscularis mucosae, a thin sheet of smooth muscle cells.The mucosa is organized into villi and crypts (crypts of Lieberkuhn). Villi are finger-like projections of epithelium and underlying lamina propria that contain blood and lymphatic (lacteals) vessels that extend into the intestinal lumen. Intes-tinal, epithelial cellular proliferation is confined to the crypts, each of which carries 250 to 300 cells. All epithelial cells in each crypt are derived from an unknown number of multipotent stem cells located at or near the crypt’s base. Our understanding of these crypt cells is rapidly expanding. It appears that there are two subgroups of intestinal stem cells, with specific cell markers. Bmi1-positive cells are usually quiescent, radiation-resistant cells that are induced by injury, while LGR5-positive cells facilitate homeostatic vs. injury-induced regeneration and are radiation sensitive.3The stem cells can differentiate along one of four path-ways that ultimately yield enterocytes and goblet, enteroendo-crine, and Paneth cells. Except for Paneth cells, these lineages complete their terminal differentiation during an upward migra-tion from each crypt to adjacent villi. The journey from the crypt to the villus tip is completed in 2 to 5 days and terminates with cells being removed by apoptosis and/or exfoliation. Thus, the small-intestinal epithelium undergoes continuous renewal, mak-ing it one of the body’s most dynamic tissues. The high cellular turnover rate contributes to mucosal resiliency but also makes the intestine uniquely susceptible to certain forms of injury such as that induced by radiation and chemotherapy.Figure 28-1. Gross features of jejunum contrasted with those of ileum. Relative to the ileum, the jejunum has a larger diameter, a thicker wall, more prominent plicae circulares, a less fatty mesentery, and longer vasa recta.Brunicardi_Ch28_p1219-p1258.indd 122023/02/19 2:24 PM 1221SMALL INTESTINECHAPTER 284. MucosaCircular layerLongitudinallayer2. Muscularis propriaSubserous layer1. SerosaVascular network,longisection of villusSimple columnar epitheliumwith mucous cellsLamina propria,smooth muscle cells, blood vesselsCentral lymph capillary (lacteal)Muscularis mucosae3. Submucosa4321Opening of crypts (of Lieberkühn)Figure 28-2. Layers of wall of the small intestine. The individual layers and their prominent features are repre-sented schematically.Enterocytes are the predominant absorptive cell of the intestinal epithelium. Their apical (lumen-facing) cell mem-brane contains specialized digestive enzymes, transporter mechanisms, and microvilli that are estimated to increase the absorptive surface area of the small intestine by up to 40-fold. Goblet cells produce mucin believed to play a role in mucosal defense against pathogens. Enteroendocrine cells are charac-terized by secretory granules containing regulatory agents and are discussed in greater detail in the “Endocrine Function” section. Paneth cells are located at the base of the crypt and contain secretory granules containing growth factors, diges-tive enzymes, and antimicrobial peptides, through which they control the host-microbe interaction and influence the intestinal microbiome. In addition, the intestinal epithelium contains M cells and intraepithelial lymphocytes. These two components of the immune system are discussed in this chapter.The submucosa consists of dense connective tissue and a heterogeneous population of cells, including leukocytes and fibroblasts. The submucosa also contains an extensive network of vascular and lymphatic vessels, nerve fibers, and ganglion cells of the submucosal (Meissner’s) plexus.The muscularis propria consists of an outer, longitudinally-oriented layer and an inner, circularly-oriented layer of smooth muscle fibers. Located at the interface between these two layers are ganglion cells of the myenteric (Auerbach’s) plexus.The serosa consists of a single layer of mesothelial cells and is a component of the visceral peritoneum.DEVELOPMENTThe first recognizable precursor of the small intestine is the embryonic gut tube, formed from the endoderm during the fourth week of gestation. The gut tube is divided into forgut, midgut, and hindgut. Other than the duodenum, which is a forgut structure, the rest of the small intestine is derived from the midgut. The gut tube initially communicates with the yolk sac; however, the communication between these two struc-tures narrows by the sixth week to form the vitelline duct. The yolk sac and vitelline duct usually undergo obliteration by the end of gestation. Incomplete obliteration of the vitelline duct results in the spectrum of defects associated with Meckel’s diverticuli.Also during the fourth week of gestation, the mesoderm of the embryo splits. The portion of mesoderm that adheres to the endoderm forms the visceral peritoneum, while the portion that adheres to the ectoderm forms the parietal peritoneum. This mesodermal division results in the formation of a coelomic cav-ity that is the precursor of the peritoneal cavity.At approximately the fifth week of gestation, the bowel begins to lengthen to an extent greater than that which can be accommodated by the developing abdominal cavity, resulting in the extracoelomic herniation of the developing bowel. The bowel continues to lengthen during the subsequent weeks and is retracted back into the abdominal cavity during the tenth week of gestation. Subsequently, the duodenum becomes a retroperitoneal structure. Coincident with extrusion and retraction, the bowel undergoes a 270° counterclockwise rotation relative to the posterior abdominal wall. This rotation accounts for the usual locations of the cecum in the right lower quadrant and the duodenojejunal junction to the left of midline (Fig. 28-3).The celiac and superior mesenteric arteries and veins are derived from the vitelline vascular system, which in turn is derived from blood vessels formed within the splanchnopleuric mesoderm during the third week of gestation. Neurons found in the small intestine are derived from neural crest cells that begin to migrate away from the neural tube during the third week of gestation. These neural crest cells enter the mesenchyme of the primitive foregut and subsequently migrate to the remainder of the bowel.During the sixth week of gestation, the lumen of the developing bowel becomes obliterated as bowel epithelial proliferation accelerates. Vacuoles form within the bowel substance during the subsequent weeks and coalesce to form the intestinal lumen by the ninth week of gestation. Errors in this recanalization may account for defects such as intestinal webs and stenoses. Most intestinal atresias, however, are believed to be related to ischemic episodes occurring after organogenesis has been completed rather than to errors in recanalization.During the ninth week of gestation, the intestinal epithe-lium develops intestine-specific features such as crypt-villus architecture. Organogenesis is complete by approximately the twelfth week of gestation.Brunicardi_Ch28_p1219-p1258.indd 122123/02/19 2:24 PM 1222SPECIFIC CONSIDERATIONSPART IIStomachDuodenumProximal limb of prim.intestinal loopVitelline ductDistal limb of prim. intestinal loopSuperiormesentericarteryStomachTransverse colonCecal budVitelline ductAscending colonJejunoileal loopsACDuodenumCecal budTransverse colonSmall intestineHepatic flextureAppendixTransversecolonDescending colonSigmoidcolonCecumBDFigure 28-3. Developmental rotation of the intestine. A. During the fifth week of gestation, the developing intestine herniates out of the coelomic cavity and begins to undergo a counterclockwise rotation about the axis of the superior mesenteric artery. B and C. Intestinal rotation continues, as the developing transverse colon passes anterior to the developing duodenum. D. Final positions of the small intestine and colon resulting from a 270° counterclockwise rotation of the developing intestine and its return into the abdominal cavity.• Oral intake 2000 mL• Saliva 1500 mL• Gastric secretions 2500• Bile 500 mL• Pancreatic secretions 1500 mL• Small intestinal secretions 1000 mL• Small intestinal absorption 7500 mL•1500 mL to colonFigure 28-4. Small intestinal fluid fluxes. Typical quantities (in volume per day) of fluid entering and leaving the small intestinal lumen in a healthy adult are shown.PHYSIOLOGYDigestion and AbsorptionThe intestinal epithelium is the interface through which absorp-tion and secretion occur. It has features characteristic of absorp-tive epithelia in general, including epithelial cells with cellular membranes possessing distinct apical (luminal) and basolateral (serosal) domains demarcated by intercellular tight junctions and an asymmetric distribution of transmembrane transporter mechanisms that promotes vectorial transport of solutes across the epithelium.Solutes can traverse the epithelium by active or passive transport. Passive transport of solutes occurs through diffusion or convection and is driven by existing electrochemical gradi-ents. Active transport is the energy-dependent net transfer of solutes in the absence of or against an electrochemical gradient.Active transport occurs through transcellular pathways (through the cell), whereas passive transport can occur through either transcellular or paracellular pathways (between cells through the tight junctions). Transcellular transport requires solutes to traverse the cell membranes through specialized membrane proteins, such as channels, carriers, and pumps. The molecular characterization of transporter proteins is evolving rapidly, with different transporter families, each containing many individual genes encoding specific transporters, now identified. Similarly, understanding of the paracellular pathway is evolving. In contrast to what was once believed, it is becoming apparent that paracellular permeability is substrate-specific, dynamic, and subject to regulation by specific tight junction proteins.Water and Electrolyte Absorption and Secretion. Eight to 9 L of fluid enter the small intestine daily. Most of this volume consists of salivary, gastric, biliary, pancreatic, and intestinal secretions. Under normal conditions, the small intestine absorbs over 80 percent of this fluid, leaving approximately 1.5 L that enters the colon (Fig. 28-4). Small-intestinal absorption and secretion are tightly regulated; derangements in water and electrolyte homeostasis characteristic of many of the disorders discussed in this chapter play an important role in contributing to their associated clinical features.Gut epithelia have two pathways for water transport: (a) the paracellular route, which involves transport through the spaces between cells, (b) the transcellular route, through apical and the basolateral cell membranes, with most occurring through Brunicardi_Ch28_p1219-p1258.indd 122223/02/19 2:24 PM 1223SMALL INTESTINECHAPTER 28the transcellular pathway.4 The specific transport mechanisms mediating this transcellular transport are not completely char-acterized, and they may involve passive diffusion through the phospholipid bilayer, cotransport with other ions and nutrients, or diffusion through water channels called aquaporins. Many different types of aquaporins have been identified; however, their contribution to overall intestinal water absorption appears to be relatively minor.5The prevailing model for intestinal epithelial Na+ absorp-tion is shown in Fig. 28-5. Activity of the Na+/K+ ATPase enzyme, which is located in the basolateral membrane and exchanges three intracellular Na+ for every two extracellular K+ in an energy-dependent process, generates the electrochemi-cal gradient that drives the transport of Na+ from the intestinal lumen into the cytoplasm of enterocytes. Na+ ions traverse the apical membrane through several distinct transporter mecha-nisms, including nutrient-coupled sodium transport (e.g., sodium glucose cotransporter-1, SGLT1), sodium channels, and sodium-hydrogen exchangers (NHEs). Absorbed Na+ ions are then extruded from enterocytes through the Na+/K+ ATPase located in the basolateral membrane. Similar mechanistic mod-els that account for the transport of other common ions such as K+ and HCO3also exist.Substantial heterogeneity, with respect to both crypt-villus and craniocaudal axes, exists for intestinal epithelial transport mechanisms. This spatial distribution pattern is consistent with a model in which absorptive function resides primarily in the villus and secretory function in the crypt.Intestinal absorption and secretion are subject to modu-lation under physiologic and pathophysiologic conditions by a wide array of hormonal, neural, and immune regulatory media-tors (Table 28-1).Carbohydrate Digestion and Absorption. Approximately 45% of energy consumption in the average Western diet con-sists of carbohydrates, approximately one-half of which is in the form of starch (linear or branched polymers of glucose) derived from cereals and plants. Other major sources of dietary carbo-hydrates include sugars derived from milk (lactose), fruits and LUMEN –BLOOD +Na+GlucoseNa+K+Na+Na+H+Figure 28-5. Model of transepithelial Na+ absorption. Na+ traverses the apical membrane of enterocytes through a variety mechanisms, including nutrient-coupled Na+ transport, Na+/H+ exchange, and Na+ channels. Activity of the Na+/K+ATPase located on the basolateral membrane generates the electrochemical gradient that provides the driving force for Na+ absorption.Table 28-1Regulation of intestinal absorption and secretionAgents that stimulate absorption or inhibit secretion of water Aldosterone Glucocorticoids Angiotensin Norepineprhine Epinephrine Dopamine Somatostatin Neuropeptide Y Peptide YY EnkephalinAgents that simulate secretion or inhibit absorption of water Secretin Bradykinin Prostaglandins Acetylcholine Atrial natriuretic factor Vasopressin Vasoactive intestinal peptide Bombesin Substance P Serotonin Neurotensin Histaminevegetables (fructose, glucose, and sucrose), or purified from sugar cane or beets (sucrose). Processed foods contain a vari-ety of sugars including fructose, oligosaccharides, and polysac-charides. Glycogen derived from meat contributes only a small fraction of dietary carbohydrate.Pancreatic amylase is the major enzyme of starch diges-tion, although salivary amylase initiates the process. The ter-minal products of amylase-mediated starch digestion are oligosaccharides, maltotriose, maltose, and alpha-limit dextrins (Fig. 28-6). These products, as well as the major disaccharides in the diet (sucrose and lactose), are unable to undergo absorp-tion in this form. They must first undergo hydrolytic cleavage into their constituent monosaccharides; these hydrolytic reac-tions are catalyzed by specific brush border membrane hydro-lases that are expressed most abundantly in the villi of the duodenum and jejunum. The three major monosaccharides that represent the terminal products of carbohydrate digestion are glucose, galactose, and fructose.Under physiologic conditions, most of these sugars are absorbed through the epithelium via the transcellular route. Glucose and galactose are transported through the enterocyte brush border membrane via intestinal Na+–glucose cotrans-porter, SGLT1 (Fig. 28-7). Fructose is transported through the brush border membrane by facilitated diffusion via GLUT5 (a member of the facilitative glucose transporter family). All three monosaccharides are extruded through the basolateral membrane by facilitated diffusion using GLUT2 and five trans-porters. Extruded monosaccharides diffuse into venules and ulti-mately enter the portal venous system.There is evidence of overexpression of hexose transport-ers, specifically SGLT1, in disease states such as diabetes.6 Several approaches aimed at downregulation of small intestinal Brunicardi_Ch28_p1219-p1258.indd 122323/02/19 2:24 PM 1224SPECIFIC CONSIDERATIONSPART IIGlucose, galactose, fructoseAbsorptionDietary starchSalivary amylasePancreatic amylaseBrush-border hydrolasesOligosaccharidesMaltotrioseMaltosea-limit dextransSucrose and lactoseFigure 28-6. Carbohydrate digestion. Dietary carbohydrates, including starch and the disaccharides sucrose and lactose, must undergo hydrolysis into constituent monosaccharides glucose, galactose, and fructose before being absorbed by the intestinal epithelium. These hydrolytic reactions are catalyzed by salivary and pancreatic amylase and by enterocyte brush border hydrolases.LUMENTight junctionTight junctionBLOOD SGLT1GLUT5GLUT5GLUT2FructoseFructoseNa+GlucoseGalactoseGlucoseGalactoseNa+Figure 28-7. Hexose transporters. Glucose and galactose enter the enterocyte through secondary active transport via the sodium-glucose cotransporter (SGLT1) located on the apical (brush border) membrane. Fructose enters through facilitated diffusion via glucose transporter 5 (GLUT5). Glucose and galactose are extruded basolaterally through facilitated diffusion via glucose transporter 2 (GLUT2). Fructose is extruded basolaterally via GLUT5.Dipeptides + Tripeptides + Amino acidsAbsorptionDietary proteinsPolypeptidesAmino acidsTrypsinChymotrypsinElastaseCarboxypeptidase ACarboxypeptidase BOligopeptidesBrush-borderpeptidasesAmino acids++PepsinFigure 28-8. Protein digestion. Dietary proteins must undergo hydrolysis into constituent single amino acids and diand tri-peptides before being absorbed by the intestinal epithelium. These hydrolytic reactions are catalyzed by pancreatic peptidases (e.g., trypsin) and by enterocyte brush border peptidases.glucose transporter are being investigated as a novel therapy for disease states such as diabetes and obesity. In fact, recent con-sensus statements have recognized the small bowel as a thera-peutic target for treatment of diabetes.7Protein Digestion and Absorption. Ten percent to 15% of energy consumption in the average Western diet consists of pro-teins. In addition to dietary proteins, approximately one-half of the protein load that enters the small intestine is derived from endogenous sources, including salivary and gastrointestinal secretions and desquamated intestinal epithelial cells. Protein digestion begins in the stomach with action of pepsins. This is not, however, an essential step because surgical patients who are acholorhydric, or have lost part or all their stomach, are still able to successfully digest proteins. Digestion continues in the duodenum with the actions of a variety of pancreatic peptidases. These enzymes are secreted as inactive proenzymes. This con-trasts with pancreatic amylase and lipase, which are secreted in their active forms. In response to the presence of bile acids, enterokinase is liberated from the intestinal brush border mem-brane to catalyze the conversion of trypsinogen to active tryp-sin; trypsin in turn activates itself and other proteases. The final products of intraluminal protein digestion consist of neutral and basic amino acids and peptides two to six amino acids in length (Fig. 28-8). Additional digestion occurs through the actions of peptidases that exist in the enterocyte brush border and cyto-plasm. Epithelial absorption occurs for both single amino acids and dior tripeptides via specific membrane-bound transporters. Absorbed amino acids and peptides then enter the portal venous circulation.Of all amino acids, glutamine appears to be a unique, major source of energy for enterocytes. Active glutamine uptake into enterocytes occurs through both apical and basolateral transport mechanisms.Fat Digestion and Absorption. Approximately 40% of the average Western diet consists of fat. Over 95% of dietary fat is in the form of long-chain triglycerides; the remainder includes phospholipids such as lecithin, fatty acids, cholesterol, and Brunicardi_Ch28_p1219-p1258.indd 122423/02/19 2:24 PM 1225SMALL INTESTINECHAPTER 28Dietary long-chaintriglyceridesShort& medium-chaintriglyceridesLong-chain fatty acidsand monoglyceridesTriglyceridesresynthesizedin enterocytesGastric lipasePancreatic lipaseChyle (lymphatics)Portal venous bloodAbsorbedAbsorbedFigure 28-9. Fat digestion. Long-chain triglycerides, which constitute the majority of dietary fats, must undergo lipolysis into constituent log-chain fatty acids and monoglycerides before being absorbed by the intestinal epithelium. These reactions are catalyzed by gastric and pancreatic lipases. The products of lipolysis are transported in the form of mixed micelles to enterocytes, where they are resynthesized into triglycerides, which are then packaged in the form of chylomicrons that are secreted into the intestinal lymph (chyle). Triglycerides composed of shortand medium-chain fatty acids are absorbed by the intestinal epithelium directly, without undergoing lipolysis, and are secreted into the portal venous circulation.fat-soluble vitamins. Over 94% of the ingested fats are absorbed in the proximal jejunum.Since fats are normally water insoluble, key to success-ful digestion of ingested fats is solubalization of them into an emulsion by the mechanical actions of mastication and antral peristalsis. Although lipolysis of triglycerides to form fatty acids and monoglyciderides is initiated in the stomach by gastric lipase, its principal site is the proximal intestine, where pancre-atic lipase is the catalyst (Fig. 28-9).Bile acids act as detergents that help in solubalization of the lipolysis by forming mixed micelles. These micelles are polymolecular aggregates with a hydrophobic core of fat and a hydrophillic surface that act as shuttles, delivering the products of lipolysis to the enterocyte brush border membrane, where they are absorbed. The bile salts, however, remain in the bowel lumen and travel to the terminal ileum, where they are actively resorbed. They enter the portal circulation and are resecreted into bile, thus completing the enterohepatic circulation.Dissociation of lipids from the micelles occurs in a thin layer of water (50 to 500 μm thick) with an acidic microenvi-ronment immediately adjacent to the brush border called the unstirred water layer. Most lipids are absorbed in the proxi-mal jejunum, whereas bile salts are absorbed in the distal ileum through an active process. Fatty acid binding proteins (FABP) are a family of proteins located on the brush border membrane, facilitating diffusion of long-chain fatty acids across the brush border membrane. Cholesterol crosses the brush border mem-brane through an active process that is yet to be completely characterized. Within the enterocytes, triglycerides are resyn-thesized and incorporated into chylomicrons that are secreted into the intestinal lymphatics and ultimately enter the thoracic duct. In these chylomicrons, lipoproteins serve a detergent-like role similar to that served by bile salts in the mixed micelles.The aforementioned steps are required for the digestion and absorption of triglycerides containing long-chain fatty acids. However, triglycerides containing shortand medium-chain fatty acids are more hydrophilic and are absorbed without undergoing intralumenal hydrolysis, micellular solubilization, mucosal reesterification, and chylomicron formation. Instead, they are directly absorbed and enter the portal venous circula-tion rather than the lymphatics. This information provides the rationale for administering nutritional supplements containing medium-chain triglycerides to patients with gastrointestinal dis-eases associated with impaired digestion and/or malabsorption of long-chain triglycerides.Vitamin and Mineral Absorption. Vitamin B12 (cobalamin) malabsorption can result from a variety of surgical manipula-tions. The vitamin is initially bound by saliva-derived R protein. In the duodenum, R protein is hydrolyzed by pancreatic enzymes, allowing free cobalamin to bind to gastric parietal cell-derived intrinsic factor. The cobalamin-intrinsic factor complex can escape hydrolysis by pancreatic enzymes, allowing it to reach the terminal ileum, which expresses specific receptors for intrin-sic factor. Subsequent events in cobalamin absorption are poorly characterized, but the intact complex probably enters enterocytes through translocation. Because each of these steps is necessary for cobalamin assimilation, gastric resection, gastric bypass, and ileal resection can each result in vitamin B12 insufficiency.Other water-soluble vitamins for which specific carrier-mediated transport processes have been characterized include ascorbic acid, folate, thiamine, riboflavin, pantothenic acid, and biotin. Fat-soluble vitamins A, D, and E appear to be absorbed through passive diffusion. Vitamin K appears to be absorbed through both passive diffusion and carrier-mediated uptake.Calcium is absorbed through both transcellular transport and paracellular diffusion. The duodenum is the major site for transcellular transport; paracellular transport occurs throughout the small intestine. A key step in transcellular calcium transport is mediated by calbindin, a calcium-binding protein located in the cytoplasm of enterocytes. Regulation of calbindin synthesis is the principle mechanism by which vitamin D regulates intes-tinal calcium absorption. Abnormal calcium levels are increas-ingly seen in surgical patients who have undergone a gastric bypass. Although usual calcium supplementation is often in the form of calcium carbonate, which is cheap, in such patients with low acid exposure, calcium citrate is a better formulation for supplemental therapy.Iron and magnesium are each absorbed through both tran-scellular and paracellular routes. A divalent metal transporter capable of transporting Fe2+, Zn2+, Mn2+, Co2+, Cd2+, Cu2+, Ni2+, and Pb2+ that has been localized to the intestinal brush border may account for at least a portion of the transcellular absorption of these ions.8Barrier and Immune FunctionAlthough the intestinal epithelium allows for the efficient absorption of dietary nutrients, it must discriminate between pathogens and harmless antigens such as food proteins and com-mensal bacteria, and it must resist invasion by pathogens. Fac-tors contributing to epithelial defense include immunoglobulin A (IgA), mucins, and the relative impermeability of the brush border membrane and tight junctions to macromolecules and Brunicardi_Ch28_p1219-p1258.indd 122523/02/19 2:24 PM 1226SPECIFIC CONSIDERATIONSPART IIIntestinal lumenPeyer’s patchLamina propriaFAESEDDCGCIgAPlasmacellM cellBVillusTTbacteria. Other factors likely to play important roles in intesti-nal mucosal defense include antimicrobial peptides such as the defensins.9 The intestinal component of the immune system, known as the gut-associated lymphoid tissue (GALT), contains over 70% of the body’s immune cells.The GALT is conceptually divided into inductive and effector sites.10 Inductive sites include Peyer’s patches, mesenteric lymph nodes, and smaller isolated lymphoid follicles scattered throughout the small intestine (Fig. 28-10). Peyer’s patches are macroscopic aggregates of B-cell follicles and intervening T-cell areas found in the lamina propria of the small intestine, primarily the distal ileum. Overlying Peyer’s patches is a specialized epithelium containing microfold (M) cells. These cells possess an apical membrane with microfolds rather than microvilli, which is characteristic of most intestinal epithelial cells. Using transepithelial vesicular transport, M cells transfer microbes to underlying professional antigen presenting cells (APCs), such as dendritic cells. Dendritic cells, in addition, may sample luminal antigens directly through their dendrite-like processes that extend through epithelial tight junctions. APCs interact with and prime naive lymphocytes, which then exit through the draining lymphatics to enter the mesenteric lymph nodes, where they undergo differentiation. These lymphocytes then migrate into the systemic circulation via the thoracic duct and ultimately accumulate in the intestinal mucosa at effector sites. Alternative induction mechanisms, such as antigen presentation within mesenteric lymph nodes, are also likely to exist.Effector lymphocytes are distributed into distinct compart-ments. IgA-producing plasma cells are derived from B cells and are located in the lamina propria. CD4+ T cells are also located in the lamina propria. CD8+ T cells migrate preferentially to the epithelium, but they are also found in the lamina propria. These T cells are central to immune regulation; in addition, the CD8+ T cells have potent cytotoxic (CTL) activity. IgA is transported through the intestinal epithelial cells into the lumen, where it exists in the form of a dimer complexed with a secretory component. This configuration renders IgA resistant to proteolysis by diges-tive enzymes. IgA is believed to both help prevent the entry of microbes through the epithelium and to promote excretion of anti-gens or microbes that have already penetrated the laminal propria.It has been increasingly recognized that the gastrointestinal tract is colonized with many bacteria that are essential for health. Communication between the microbiota and the host defense allows for protective immune responses against pathogens while preventing adverse inflammatory responses to harmless com-mensal microbes, which could lead to chronic inflammatory dis-orders such as celiac disease and Crohn’s disease.11MotilityMyocytes of the intestinal muscle layers are electrically and mechanically coordinated in the form of syncytia. Contractions of the muscularis propria are responsible for small-intestinal peri-stalsis. Contraction of the outer longitudinal muscle layer results in bowel shortening; contraction of the inner circular layer results in luminal narrowing. Contractions of the muscularis mucosa contribute to mucosal or villus motility, but not to peristalsis.Several distinctive patterns of muscularis propria activity have been observed to occur in the small intestine. These patterns include ascending excitation and descending inhibition in which muscular contraction occurs proximal to a stimulus, such as the presence of a bolus of ingested food, and muscular relaxation occurs distal to the stimulus (Fig. 28-11). These two reflexes are present even in the absence of any extrinsic innervation to the small intestine and contribute to peristalsis when they are propagated in a coordinated fashion along the length of the intestine. The fed or postprandial pattern begins within 10 to 20 minutes of meal ingestion and abates 4 to 6 hours afterwards. Rhythmic segmentations or pressure waves traveling only short distances also are observed. This segmenting pattern is hypothesized to assist in mixing intraluminal contents and in facilitating their contact with the absorptive mucosal surface. The fasting pattern or interdigestive motor cycle (IDMC) consists of three phases. Phase 1 is characterized by motor quiescence, phase 2 by seemingly disorganized pressure waves occurring at submaximal rates, and phase 3 by sustained pressure waves occurring at maximal rates. This pattern is hypothesized to expel residual debris and bacteria from the small intestine. The median duration of the IDMC ranges from 90 to 120 minutes. At any given time, different portions of the small intestine can be in different phases of the IDMC.Figure 28-10. Gut-associated lymphoid tissue. Select components of the gut-associated lymphoid tissue (GALT) are schematically represented. Peyer’s patches consist of a specialized follicle-associated epithelium (FAE) containing M cells, a subepithelial dome (SED) rich in dendritic cells (DC), and B-cell follicle containing germinal centers (GC). Plasma cells in the lamina propria produce IgA, which is transported to the intestinal lumen where serves as the first line of defense against pathogens. Other components of the GALT include isolated lymphoid follicles, mesenteric lymph nodes, and regulatory and effector lymphocytes.Brunicardi_Ch28_p1219-p1258.indd 122623/02/19 2:24 PM 1227SMALL INTESTINECHAPTER 28EMNSNIMNProximalDistalFigure 28-11. Ascending excitation and descending inhibition. The presence of a food bolus within the intestinal lumen is sensed by a sensory neuron (SN) that relays signals to (a) excitatory motor neurons (EMN) that have projections to intestinal muscle cells located proximal to the food bolus and (b) inhibitory motor neu-rons (IMN) that have projections to intestinal muscle cells located distal to the food bolus. This stereotypical motor reflex is controlled by the enteric nervous system and occurs in the absence of extra-intestinal innervations. It contributes to peristalsis.The regulatory mechanisms driving small-intestinal motil-ity consist of both pacemakers intrinsic to the small intestine and external neurohumoral modulatory signals. The interstitial cells of Cajal are pleomorphic mesenchymal cells located within the muscularis propria of the intestine that generate the electrical slow wave (basic electrical rhythm or pacesetter potential) that plays a pacemaker role in setting the fundamental rhythmicity of small-intestinal contractions. The frequency of the slow wave varies along the longitudinal axis of the intestine: it ranges from 12 waves per minute in the duodenum to 7 waves per minute in the distal ileum. Smooth muscle contraction occurs only when an electrical action potential (spike burst) is superimposed on the slow wave. Thus, the slow wave determines the maximum frequency of contractions; however, not every slow wave is associated with a contraction.This intrinsic contractile mechanism is subject to neural and hormonal regulation. The enteric motor system (ENS) pro-vides both inhibitory and excitatory stimuli. The predominant excitatory transmitters are acetylcholine and substance P, and the inhibitory transmitters include nitric oxide, vasoactive intes-tinal peptide, and adenosine triphosphate. In general, the sympa-thetic motor supply is inhibitory to the ENS; therefore, increased sympathetic input into the intestine leads to decreased intestinal smooth muscle activity. The parasympathetic motor supply is more complex, with projections to both inhibitory and excitatory ENS motor neurons. Correspondingly, the effects of parasympa-thetic inputs into intestinal motility are more difficult to predict.Endocrine FunctionEndocrinology as a discipline was born with the discovery of secretin, an intestinal regulatory peptide that was the first hormone to be identified. Our improving understanding of the physiology of the small intestine has led to identification of many additional intestinal-derived hormones, which make this the largest hormone-producing organ in the body. Over 30 peptide hormone genes have been identified as being expressed in the gastrointestinal tract. Because of differential posttranscriptional and posttranslational processing, over 100 distinct regulatory peptides are produced. In addition, monoamines, such as histamine and dopamine, and eicosanoids with hormone-like activities are produced in the intestine.“Gut hormones” were previously conceptualized as pep-tides produced by the enteroendocrine cells of the intestinal mucosa that are released into the systemic circulation to reach receptors in target sites in the gastrointestinal tract. Now it is clear that “gut hormone” genes are widely expressed through-out the body, not only in endocrine cells but also in central and peripheral neurons. The products of these genes are general intercellular messengers that can act as endocrine, paracrine, autocrine, or neurocrine mediators. Thus, they may act as true blood-borne hormones as well as through local effects.There are notable homology patterns among individual regulatory peptides found in the gastrointestinal tract. Based on these homologies, approximately one-half of the known regulatory peptides can be classified into families.12 For example, the secretin family includes secretin, glucagon, and glucagon-like peptides, glucose-dependent insulinotropic peptide, vasoactive intestinal polypeptide, peptide histidine isoleucine, growth hormone releasing hormone, and pituitary adenylyl cyclase-activating peptide. Other peptide families include those named for insulin, epidermal growth factor, gastrin, pancreatic polypeptide, tachykinin, and somatostatin.Receptor subtype multiplicity and cell-specific expres-sion patterns for these receptor subtypes that are characteristic of these regulatory mediators makes definition of their actions complex. Detailed description of these actions is beyond the scope of this chapter; however, examples of regulatory pep-tides produced by enteroendocrine cells of the small-intestinal epithelium and their most commonly ascribed functions are summarized in Table 28-2. Some of these peptides, or their analogues, are used in routine clinical practice. For example, Table 28-2Representative regulatory peptides produced in the small intestineHORMONESOURCEaACTIONSSomatostatinD cellInhibits gastrointestinal secretion, motility, and splanchnic perfusionSecretinS cellStimulates exocrine pancreatic secretion, stimulates intestinal secretionCholecystokininI cellSimulates pancreatic exocrine secretion, simulates gallbladder emptying, inhibits sphincter of Oddi contractionMotilinM cellSimulates intestinal motilityPeptide YYL cellInhibits intestinal motility and secretionGlucagon-like Peptide 2L cellStimulates intestinal epithelial proliferationNeurotensinN cellStimulates pancreatic and biliary secretion, inhibits small bowel motility, stimulates intestinal mucosal growthaThis table indicates which enteroendocrine cell types located in the intestinal epithelium produce these peptides. These peptides are also widely expressed in nonintestinal tissues.Brunicardi_Ch28_p1219-p1258.indd 122723/02/19 2:24 PM 1228SPECIFIC CONSIDERATIONSPART IITable 28-3Small bowel obstruction: common etiologiesAdhesionsNeoplasms Primary small bowel neoplasms Secondary small bowel cancer (e.g., melanomaderived metastasis) Local invasion by intra-abdominal malignancy (e.g., Desmoid tumors) CarcinomatosisHernias External (e.g., inguinal and femoral) Internal (e.g., following Roux-en-Y gastric bypass surgery)Crohn’s diseaseVolvulusIntussusceptionRadiation-induced stricturePostischemic strictureForeign bodyGallstone ileusDiverticulitisMeckel’s diverticulumHematomaCongenital abnormalities (e.g., webs, duplications, and malrotation)therapeutic applications of octreotide, a long-acting analogue of somatostatin, include the amelioration of symptoms associ-ated with neuroendocrine tumors (e.g., carcinoid syndrome), postgastrectomy dumping syndrome, enterocutaneous fis-tulas, and the initial treatment of acute hemorrhage due to esophageal varices. The gastrin secretory response to secretin administration forms the basis for the standard test used to establish the diagnosis of Zollinger-Ellison syndrome. Chole-cystokinin is used in evaluations of gallbladder ejection frac-tion, a parameter that may have utility in patients who have symptoms of biliary colic but are not found to have gallstones. Of the peptides listed in Table 28-2, glucagon-like peptide 2 (GLP-2) has been identified as a specific and potent intestino-trophic hormone and is currently under clinical evaluation as an intestinotrophic agent in patients suffering from the short bowel syndrome, as discussed in the “Short Bowel Syndrome” section.Intestinal AdaptationThe small intestine has the capacity to adapt in response to vary-ing demands imposed by physiologic and pathologic conditions. Of relevance to many of the diseases discussed in this chapter is the adaptation that occurs in the remnant intestine following surgical resection of a large portion of the small intestine (mas-sive small bowel resection). Postresection intestinal adaptation has been studied extensively using animal models. Within a few hours after bowel resection, the remnant small intestine displays evidence of epithelial cellular hyperplasia. With additional time, villi lengthen, intestinal absorptive surface area increases, and digestive and absorptive functions improve. Postresection intes-tinal adaptation in human patients is less well studied, but it seems to follow similar steps as that seen in experimental mod-els, and it takes 1 to 2 years to complete.13The mechanisms responsible for inducing postresection intestinal adaptation are under active investigation. Several classes of effectors that stimulate intestinal growth include spe-cific nutrients, peptide hormones and growth factors, pancreatic secretions, and some cytokines. Nutritional components with intestinal growth-stimulating effects include fiber, fatty acids, triglycerides, glutamine, polyamines, and lectins.Postresection adaptation serves to compensate for the function of intestine that has been resected. Jejunal resection is generally better tolerated, as ileum shows better capacity to compensate. However, the magnitude of this response is limited. If enough small intestine is resected, a devastating condition known as the short bowel syndrome results. This condition is discussed in the “Short Bowel Syndrome” section at the end of this chapter.SMALL BOWEL OBSTRUCTIONEpidemiologyMechanical small bowel obstruction is the most frequently encountered surgical disorder of the small intestine. Although a wide range of etiologies for this condition exist, the obstructing lesion can be conceptualized according to its anatomical relationship to the intestinal wall as:1. intraluminal (e.g., foreign bodies, gallstones, or meconium)2. intramural (e.g., tumors, Crohn’s disease–associated inflam-matory strictures)3. extrinsic (e.g., adhesions, hernias, or carcinomatosis)2Intra-abdominal adhesions related to prior abdominal sur-gery account for up to 75% of cases of small bowel obstruction. Over 300,000 patients are estimated to undergo surgery to treat adhesion-induced small bowel obstruction in the United States annually. A 20-year trend analysis between 1988 and 2007 has documented no decrease in this rate during this period, highlighting the ongoing problem of this “old” disease.14 In fact, small bowel resection and lysis of adhesions account for two of the seven procedures that were responsible for 80% of the emergency surgeries in the United States between 2008 and 2011.15Less prevalent etiologies for small bowel obstruction include hernias, malignant bowel obstruction, and Crohn’s dis-ease. The frequency with which obstruction related to these con-ditions is encountered varies according to the patient population and practice setting. Cancer-related small bowel obstructions are commonly due to extrinsic compression or invasion by advanced malignancies arising in organs other than the small bowel; few are due to primary small bowel tumors. The most commonly encountered etiologies of small bowel obstruction are summarized in Table 28-3. Although congenital abnormali-ties capable of causing small bowel obstruction usually become evident during childhood, they sometimes elude detection and are diagnosed for the first time in adult patients presenting with abdominal symptoms. For example, intestinal malrotation and midgut volvulus should not be forgotten when considering the differential diagnosis of adult patients with acute or chronic symptoms of small bowel obstruction, espe-cially those without a history of prior abdominal surgery. A rare etiology of obstruction is the superior mesenteric artery syn-drome, characterized by compression of the third portion of the duodenum by the superior mesenteric artery as it crosses over this portion of the duodenum. This condition should be 34Brunicardi_Ch28_p1219-p1258.indd 122823/02/19 2:24 PM 1229SMALL INTESTINECHAPTER 28considered in young asthenic individuals who have chronic symptoms suggestive of proximal small bowel obstruction.PathophysiologyWith onset of obstruction, gas and fluid accumulate within the intestinal lumen proximal to the site of obstruction. The intestinal activity increases to overcome the obstruction, accounting for the colicky pain and the diarrhea that some experience even in the presence of complete bowel obstruction. Most of the gas that accumulates originates from swallowed air, although some is produced within the intestine. The fluid consists of swallowed liquids and gastrointestinal secretions (obstruction stimulates intestinal epithelial water secretion). With ongoing gas and fluid accumulation, the bowel distends and intraluminal and intramural pressures rise. The intestinal motility is eventually reduced with fewer contractions. With obstruction, the luminal flora of the small bowel, which is usually sterile, changes and a variety of organisms have been cultured from the contents. Translocation of these bacteria to regional lymph nodes has been demonstrated, although the significance of this process is not well understood. If the intramural pressure becomes high enough, intestinal microvascular perfusion is impaired leading to intestinal ischemia, and, ultimately, necrosis. This condition is termed strangulated bowel obstruction.With partial small bowel obstruction, only a portion of the intestinal lumen is occluded, allowing passage of some gas and fluid. The progression of pathophysiologic events described previously tends to occur more slowly than with complete small bowel obstruction, and development of strangulation is less likely.A particularly dangerous form of bowel obstruction is closed loop obstruction in which a segment of intestine is obstructed both proximally and distally (e.g., with volvulus). In such cases, the accumulating gas and fluid cannot escape either proximally or distally from the obstructed segment, lead-ing to a rapid rise in luminal pressure and a rapid progression to strangulation.Clinical PresentationThe symptoms of small bowel obstruction are colicky abdomi-nal pain, nausea, vomiting, and obstipation. Vomiting is a more prominent symptom with proximal obstructions than distal. Character of vomitus is important as with bacterial overgrowth, the vomitus is more feculent, suggesting a more established obstruction. Continued passage of flatus and/or stool beyond 6 to 12 hours after onset of symptoms is characteristic of par-tial rather than complete obstruction. The signs of small bowel obstruction include abdominal distention, which is most pro-nounced if the site of obstruction is in the distal ileum and may be absent if the site of obstruction is in the proximal small intestine. Bowel sounds may be hyperactive initially, but in late stages of bowel obstruction, minimal bowel sounds may be heard. Laboratory findings reflect intravascular volume deple-tion and consist of hemoconcentration and electrolyte abnor-malities. Mild leukocytosis is common.Features of strangulated obstruction include abdominal pain often disproportionate to the degree of abdominal findings, suggestive of intestinal ischemia. Patients often have tachycar-dia, localized abdominal tenderness, fever, marked leukocyto-sis, and acidosis. Any of these findings should alert the clinician to the possibility of strangulation and the need for early surgical intervention.DiagnosisThe diagnostic evaluation should focus on the following goals: (a) distinguish mechanical obstruction from ileus, (b) determine the etiology of the obstruction, (c) discriminate partial from complete obstruction, and (d) discriminate simple from stran-gulating obstruction.Important elements to obtain on history include prior abdominal operations (suggesting the presence of adhesions) and the presence of abdominal disorders (e.g., intra-abdominal cancer or inflammatory bowel disease) that may provide insights into the etiology of obstruction. Upon examination, a meticulous search for hernias (particularly in the inguinal and femoral regions) should be conducted.The diagnosis of small bowel obstruction is usually con-firmed with radiographic examination. The abdominal series consists of (a) a radiograph of the abdomen with the patient in a supine position, (b) a radiograph of the abdomen with the patient in an upright position, and (c) a radiograph of the chest with the patient in an upright position. The finding most specific for small bowel obstruction is the triad of dilated small bowel loops (>3 cm in diameter), air-fluid levels seen on upright films, and a paucity of air in the colon. The sensitivity of abdominal radiographs in the detection of small bowel obstruction ranges from 70% to 80%. Specificity is low because ileus and colonic obstruction can be associated with findings that mimic those observed with small bowel obstruction. False-negative findings on radiographs can result when the site of obstruction is in the proximal small bowel and when the bowel lumen is filled with fluid but no gas, thereby preventing visualization of air-fluid levels or bowel distention. The latter situation is associated with closed-loop obstruction. Despite these limitations, abdominal radiographs remain an important study in patients with sus-pected small bowel obstruction because of their widespread availability and low cost (Fig. 28-12).Computed tomographic (CT) scanning is becoming increasingly the imaging test of choice for patients with small bowel obstruction, and it is ideally done with oral contrast. CT is 80% to 90% sensitive and 70% to 90% specific in the detec-tion of small bowel obstruction. The findings of small bowel obstruction include a discrete transition zone with dilation of bowel proximally, decompression of bowel distally, intralumi-nal contrast that does not pass beyond the transition zone, and a colon containing little gas or fluid (Figs. 28-13 and 28-14). CT scanning may also provide evidence for the presence of closed-loop obstruction and strangulation. Closed-loop obstruction is suggested by the presence of a U-shaped or C-shaped dilated bowel loop associated with a radial distribution of mesenteric vessels converging toward a torsion point. Strangulation is sug-gested by thickening of the bowel wall, pneumatosis intestinalis (air in the bowel wall), portal venous gas, mesenteric haziness, and poor uptake of intravenous contrast into the wall of the affected bowel (Fig. 28-15). CT scanning also offers a global evaluation of the abdomen and may therefore reveal the etiol-ogy of obstruction. This feature is important in the acute setting when intestinal obstruction represents only one of many diag-noses in patients presenting with acute abdominal conditions.The CT scan is usually performed after administration of oral water-soluble contrast or diluted barium. The water-soluble contrast has been shown to have prognostic and therapeutic val-ues too. Several studies and several subsequent meta-analysis have shown that water-soluble contrast could in fact have ther-apeutic and prognostic value. The appearance of the contrast Brunicardi_Ch28_p1219-p1258.indd 122923/02/19 2:24 PM 1230SPECIFIC CONSIDERATIONSPART IIFigure 28-12. Small bowel obstruction. Plain radiographs (A) supine, which show dilated loops of small bowel in the right upper quadrant; (B) erect, which confirm the presence of airfluid level in the loops of small bowel as well as the stomach, consistant with small bowel obstruction.Figure 28-13. Small bowel obstruction. A CT scan of a patient presenting with signs and symptoms of bowel obstruction. Image shows grossly dilated loops of small bowel, with decompressed terminal ileum (I) and ascending colon (C), suggesting a complete distal small bowel obstruction. At laparotomy, adhesive bands from a previous surgery were identified and divided.Figure 28-14. Chronic partial small bowel obstruction. This patient presented with a several months history of chronic abdominal pain and intermittent vomiting. The coronal CT image shows grossly dilated loops of proximal small bowel on the left side (wide arrow), with decompressed loops of small bowel on the right side (narrow arrow). The dilated segment shows evidence of feculization of bowel contents, consistent with the chronic nature of the obstruction. Patient’s vomitus had characteristic feculent smell and quality. At exploratory laparotomy, adhesive bands were identified and divided.in the colon within 24 hours of administration is predictive of nonsurgical resolution of bowel obstruction with a sensitivity of 92% and a specificity of 93%.16A limitation of CT scanning is its low sensitivity (<50%) in the detection of low-grade or partial small bowel obstruction. A subtle transition zone may be difficult to identify in the axial images obtained during CT scanning. In such cases, contrast examinations of the small bowel, either small bowel series (small bowel follow-through) or enteroclysis, can be helpful. For standard small bowel series, contrast is swallowed or instilled into the stomach through a nasogastric tube. Abdominal radiographs are then taken serially as the contrast travels distally in the intestine. Although barium can be used, water-soluble contrast agents, such as gastrograffin, should be used if the possibility of intestinal perforation exists. These examinations are more labor-intensive and less rapidly performed than CT scanning but may offer greater sensitivity in the detection of luminal and mural etiologies of obstruction, such as primary intestinal tumors. For enteroclysis, 200 to 250 mL of barium followed by 1 to 2 L of a solution of methylcellulose in water is instilled into the proximal jejunum via a long nasoenteric catheter. The double-contrast technique used in enterocolysis Brunicardi_Ch28_p1219-p1258.indd 123023/02/19 2:24 PM 1231SMALL INTESTINECHAPTER 28Figure 28-15. Intestinal pneumatosis. This CT scan shows intestinal pneumatosis (arrow). The cause of this radiological finding was intestinal ischemia. Patient was taken emergently to the operating room and underwent resection of an infarcted segment of small bowel.permits a better assessment of mucosal surface and detection of relatively small lesions, even through overlapping small bowel loops. Enterocolysis is rarely performed in the acute setting but offers greater sensitivity than small bowel series in the detection of lesions that may be causing partial small bowel obstruction. Recently, CT enterocolysis has been used, and it was reported to be superior to plain X-ray small bowel contrast studies.TherapySmall bowel obstruction is usually associated with a marked depletion of intravascular volume due to decreased oral intake, vomiting, and sequestration of fluid in bowel lumen and wall. Therefore, fluid resuscitation is integral to treatment. Isotonic fluid should be given intravenously, and an indwelling bladder catheter may be placed to monitor urine output. Central-venous or pulmonary-artery catheter monitoring are not generally indi-cated unless the patient has underlying cardiac disease and severe dehydration. Broad-spectrum antibiotics are not indi-cated unless there is concern for bowel ischemia and surgery is planned.The stomach should be continuously evacuated of air and fluid using a nasogastric (NG) tube. Effective gastric decom-pression decreases nausea, distention, and the risk of vomiting and aspiration. Longer nasoenteric tubes, with tips placed into the jejunum or ileum, were favored in the past but are rarely used today, as they are associated with higher complication rates than NG tubes, with no proven greater efficacy in several studies.While a period of close observation and nonoperative management has been the mainstay of treatment for partial bowel obstruction, the standard therapy for complete small bowel obstruction has generally been expeditious surgery, with the dictum that “the sun should never rise and set on a complete bowel obstruction.” The rationale for favoring early surgical intervention is to minimize the risk for bowel strangu-lation, which is associated with an increased risk for morbidity and mortality. Clinical signs and currently available laboratory tests and imaging studies do not reliably permit the distinction between patients with simple obstruction and those with stran-gulated obstruction prior to the onset of irreversible ischemia. Therefore, the goal is to operate before the onset of irreversible ischemia. This treatment approach has, however, undergone significant reassessment in recent years, with many advocating for nonoperative approaches in management of these patients, providing closed-loop obstruction is ruled out and there is no evidence of intestinal ischemia. In a study of 145 patients with CT-diagnosed high-grade compete small bowel obstruction, 46% of the overall cohort were managed nonoperatively. More specifically, of the 104 patients who did not meet criteria for immediate surgery, 66 patients were successfully managed nonoperatively.17Thus, conservative therapy in the form of NG decompres-sion and fluid resuscitation is now commonly recommended in the initial management of nonischemic bowel obstruction. Non-operative management has been documented to be successful in 65% to 81% of patients with partial small bowel obstruction. Of those successfully treated nonoperatively, only 5% to 15% have been reported to have symptoms that were not substantially improved within 48 hours after initiation of therapy. Therefore, most patients with partial small obstruction whose symptoms do not improve within 48 hours after initiation of nonopera-tive therapy should be considered for surgery. In a study using the National Inpatient Sample, this principle was further high-lighted. The authors concluded that a 2-day limit of watchful waiting before surgery is not associated with an increase in mortality or postoperative morbidity, although inpatient costs were higher.18The observation that administration of water-soluble oral contrast has not only diagnostic but also therapeutic and prog-nostic value has led to the creation of several protocols and path-ways for management of patients presenting with small bowel obstruction. An example of such a pathway that is utilized at our institution is outlined in Fig. 28-16. Several studies and subsequent meta-analyses have shown that use of water-soluble contrast not only predicts likelihood of success of nonoperative management but also reduces the need for surgery (odds ratio 0.44), length of stay by about 2 days, and time to resolution by about 28 hours, without an increase in morbidity or mortality.16The operative procedure performed for small bowel obstruction varies according to the etiology of the obstruc-tion. For example, adhesions are lysed, tumors are resected, and hernias are reduced and repaired. Regardless of the etiol-ogy, the affected intestine should be examined, and nonviable bowel should be resected. Criteria suggesting viability are nor-mal color, peristalsis, and marginal arterial pulsations. Usu-ally, visual inspection alone is adequate in judging viability. In borderline cases, a Doppler probe may be used to check for pulsatile flow to the bowel, and arterial perfusion can be veri-fied by visualizing intravenously administered fluorescein dye in the bowel wall under ultraviolet illumination. Neither tech-nique has, however, been found to be superior to clinical judg-ment. In general, if the patient is hemodynamically stable, short lengths of bowel of questionable viability should be resected, and primary anastomosis of the remaining intestine should be performed. However, if the viability of a large proportion of the intestine is in question, a concerted effort to preserve intestinal tissue should be made. In such situations, the bowel of uncertain viability should be left intact and the patient reexplored in 24 to 48 hours in a “second-look” operation. At that time, definitive resection of nonviable bowel is completed.Brunicardi_Ch28_p1219-p1258.indd 123123/02/19 2:24 PM 1232SPECIFIC CONSIDERATIONSPART IINoNoYesYesAdhesive smallbowel obstructionSigns and symptomsof strangulation andintestinal ischemia?Operating roomfor explorationNPOIVFNG tubeSerial abdominal exam100 mL of water-solublecontrast through NGKUB after 8 hoursHas contrastreached colon?High likelihood for nonoperativeresolution of bowel obstructionRemove NGStart sipsRepeat KUBafter 24 hoursHas contrastreached colon?Strongly consider surgerywithin 72 hours of admissionYesFigure 28-16. Management of small bowel obstruction.Successful laparoscopic surgery for bowel obstruction is being reported with greater frequency. In a propensity score-matched study of patients who underwent adhesiolysis for small bowel obstruction, the laparoscopic approach was associated with significantly lower rates of overall complications, surgical site infections, and a shorter length of hospital stay (4 vs. 10 days).19 Since distended loops of bowel can interfere with adequate visualization, early cases of proximal small bowel obstruction that are likely due to a single adhesive band are best suited for this approach. Presence of bowel distention and multiple adhesions can cause these procedures to be difficult, with a reported conversion rate of 17% to 33%. One of the major concerns with the laparoscopic approach has been the risk of iatrogenic bowel injury. A pooled analysis of 11 nonrandomized comparative studies has, however, shown that the risk of bowel injury and reoperation were not different between the two procedures, although the laparoscopic approach was associated with greater surgical time.20OutcomesThe perioperative mortality rate associated with surgery for nonstrangulating small bowel obstruction is less than 5%, with most deaths occurring in elderly patients with significant comorbidities. Mortality rates associated with surgery for stran-gulated obstruction is higher, highlighting the need for prompt intervention in this group. Long-term prognosis is related to the etiology of obstruction. Many patients who are treated conser-vatively for adhesive small bowel obstruction do not require future readmissions; less than 20% of such patients will have a readmission over the subsequent 5 years with another episode of bowel obstruction.In a study of 286 patients who had undergone surgical intervention for adhesive small bowel obstruction, the risk of recurrent obstruction was 5.5% at 1 year, 11.3% at 3 years, and 13.5% at 5 years. The risk of reoperation for recurrent obstruction was 3.7% at 1 year, 4.8% at 3 years, and 5.8% at 5 years.21 Considering the frequency of small bowel obstruction and the varied degree of clinical severity and presentation, there is often variation in the care of patients admitted with bowel obstruction. Studies have shown that a standard hospital-wide policy can help improve care of patients with bowel obstruction, reducing their time to surgery and shortening their length of hospital stay.22Brunicardi_Ch28_p1219-p1258.indd 123223/02/19 2:24 PM 1233SMALL INTESTINECHAPTER 28PreventionWith adhesive small bowel obstruction representing a large therapeutic burden, prevention of postoperative adhesions has become an area of great interest. Good surgical technique, careful handling of tissue, and minimal use and exposure of peritoneum to foreign bodies, forms the cornerstone of adhe-sion prevention. These measures alone are often inadequate. In patients undergoing colorectal or pelvic surgery, hospital read-mission rates of greater than 30% over the subsequent 10 years have been reported for adhesive small bowel obstruction.23Use of laparoscopic surgery, when possible, has been strongly promoted. A recent study using the Swedish National Inpatient Register has shown that, compared to laparoscopy, open surgery is associated with a fourfold increase in risk of small bowel obstruction within 5 years of the index procedure, even after accounting for other risk factors such as age, comor-bidity, and previous abdominal surgery.24In those undergoing open surgery, several strategies for adhesion prevention have been tried; however, the only therapy that has shown some success has been the use of hyaluronan-based agents, such as Sperafilm. The use of this barrier has been clearly shown to reduce the incidence of postoperative bowel adhesions; however, their effect in actually reducing the inci-dence of small bowel obstruction remains less well defined.25 The use of these products is often left to the discretion of the surgeon and the clinical context. Wrapping of an intestinal anas-tomosis with the material may be associated with increased leak rates and is generally discouraged.26Other Causes of Small Bowel ObstructionEarly postoperative bowel obstruction, as defined by signs, symptoms, and radiographic signs of SBO occurring within 30 days following surgery, been reported to occur in 0.7% to 9% of patients, with a higher rate in patients undergoing pelvic sur-gery, especially colorectal procedures.27 CT scanning or small bowel series is often required to make the diagnosis. Obstruc-tion that occurs in the early postoperative period is usually par-tial and only rarely is associated with strangulation. Therefore, a period of extended nonoperative therapy (2–3 weeks) consist-ing of bowel rest, hydration, and TPN administration is usually warranted. However, if complete obstruction is demonstrated or if signs suggestive of peritonitis are detected, expeditious reop-eration should be undertaken without delay. In a series of 180 patients undergoing anterior resection for rectal cancer, 12.8% developed early postoperative bowel obstruction on the median postoperative day 5, with 4 requiring surgical exploration at a median interval of 2 weeks from the index case.27Crohn’s disease as a cause of small bowel obstruction is discussed in more detail later in this chapter in the “Crohn’s Disease” section.Malignant small bowel obstruction can be a challenging problem. Although it often indicates advanced disease with poor prognosis, 25% to 33% of patients with a history of cancer who present with small bowel obstruction have adhesions as the etiol-ogy of their obstruction and therefore should not be denied appro-priate therapy. Even in cases in which the obstruction is related to recurrent malignancy, palliative resection or bypass can be performed, and in select cases these procedures lead to improved quality of life. In a series of 81 patients with small bowel obstruc-tion, palliation was achieved in over 80% of patients, with over 70% able to reestablish oral intake. In this series, the surgical mor-bidity was high, with 7% developing an enterocutaneous fistula/Table 28-4Ileus: common etiologiesAbdominal surgeryInfection Sepsis Intra-abdominal abscess Peritonitis PneumoniaElectrolyte abnormalities Hypokalemia Hypomagnesemia Hypermagnesemia HyponatremiaMedications Anticholinergics Opiates Phenothiazines Calcium channel blockers Tricyclic antidepressantsHypothyroidismUreteral colicRetroperitoneal hemorrhageSpinal cord injuryMyocardial infarctionMesenteric ischemiaanastomotic leak and a 30-day mortality rate of 6%.28 Patients with obvious carcinomatosis and multifocal obstruction pose a difficult challenge, given their limited prognosis. Thus, management must be tailored to an individual patient’s prognosis and desires. At the time of surgery, relief of the obstruction may be best achieved by a bypass procedure, avoiding a potentially difficult bowel resection, and even if that is not feasible, a palliative gastrostomy tube can be considered to help resolve nausea and vomiting.ILEUS AND OTHER DISORDERS OF INTESTINAL MOTILITYIleus and intestinal pseudo-obstruction are clinical syndromes caused by impaired intestinal motility and are characterized by symptoms and signs of intestinal obstruction in the absence of a lesion-causing mechanical obstruction. Ileus is a temporary motility disorder that is reversed with time as the inciting factor is corrected. In contrast, chronic intestinal pseudo-obstruction comprises a spectrum of specific disorders associated with irre-versible intestinal dysmotility.Ileus is a major cause of morbidity in hospitalized patients. A degree of intestinal ileus is a normal physiological response to abdominal surgery, which often resolves quickly without any long-term sequela. However, when postoperative ileus is pro-longed, it can cause significant morbidity and cost. Prolonged postoperative ileus is the most frequently implicated cause of delayed discharge following abdominal operations, and its eco-nomic impact has been estimated to be between $750 million and $1 billion annually in the United States.29PathophysiologyNumerous factors capable of impairing intestinal motility, and thus inciting ileus, have been described (Table 28-4). The most Brunicardi_Ch28_p1219-p1258.indd 123323/02/19 2:24 PM 1234SPECIFIC CONSIDERATIONSPART IIfrequently encountered factors are abdominal operations, infec-tion and inflammation, electrolyte abnormalities, and drugs.Following most abdominal operations or injuries, the motility of the gastrointestinal tract is transiently impaired. Among the proposed mechanisms responsible for this dysmotility are surgical stress-induced sympathetic reflexes, inflammatory response mediator release, and anesthetic/analgesic side effects; each of which can inhibit intestinal motility. The return of normal motility generally follows a characteristic temporal sequence, with small-intestinal motility returning to normal within the first 24 hours after laparotomy and gastric and colonic motility returning to normal by 48 hours and 2 to 5 days, respectively. Since small bowel motility is returned before colonic and gastric motility, listening for bowel sounds is not a reliable indicator that ileus has fully resolved. Functional evidence of coordinated gastrointestinal motility in the form of passing flatus or bowel movement is a more useful indicator. Resolution of ileus may be delayed in the presence of other factors capable of inciting ileus such as the presence of intra-abdominal abscesses or electrolyte abnormalities.Chronic intestinal pseudo-obstruction can be caused by a large number of specific abnormalities affecting intestinal smooth muscle, the myenteric plexus, or the extraintestinal nervous system (Table 28-5). Visceral myopathies constitute a group of diseases characterized by degeneration and fibro-sis of the intestinal muscularis propria. Visceral neuropathies encompass a variety of degenerative disorders of the myenteric and submucosal plexuses. Both sporadic and familial forms of visceral myopathies and neuropathies exist. Systemic disor-ders involving the smooth muscle such as progressive systemic sclerosis and progressive muscular dystrophy, and neurologi-cal diseases such as Parkinson’s disease, can also be compli-cated by chronic intestinal pseudo-obstruction. In addition, viral infections, such as those associated with cytomegalovirus and Epstein-Barr virus, can cause intestinal pseudo-obstruction.Table 28-5Chronic intestinal pseudo-obstruction: etiologiesPrimary CausesFamilial types Familial visceral myopathies (types I, II, and III) Familial visceral neuropathies (types I and II) Childhood visceral myopathies (types I and II)Sporadic types Visceral myopathies Visceral neuropathiesSecondary CausesSmooth muscle disorders Collagen vascular diseases (e.g., scleroderma) Muscular dystrophies (e.g., myotonic dystrophy) AmyloidosisNeurological disorders Chagas disease, Parkinson’s disease, spinal cord injuryEndocrine disorders Diabetes, hypothyroidism, hypoparathyroidismMiscellaneous disorders Radiation enteritisPharmacological causes E.g., phenothiazines and tricyclic antidepressantsViral infectionsClinical PresentationThe clinical presentation of ileus resembles that of small bowel obstruction. Inability to tolerate liquids and solids by mouth, nausea, and lack of flatus or bowel movements are the most common symptoms. Vomiting and abdominal distension may occur. Although bowel sound characteristics are not diagnostic, they are usually diminished or absent, in contrast to the hyper-active bowel sounds that usually accompany mechanical small bowel obstruction. The clinical manifestations of chronic intes-tinal pseudo-obstruction include variable degrees of nausea and vomiting and abdominal pain and distention.DiagnosisRoutine postoperative ileus should be expected and requires no diagnostic evaluation. Definition of prolonged postoperative ileus has been varied but generally diagnosed if ileus persists beyond 5 days postoperatively. A recent global survey synthesized the results of the data to define postoperative ileus as “interval from surgery until passage of flatus/stool AND tolerance of an oral diet,” with prolonged postoperative ileus being defined as “two or more of nausea/vomiting, inability to tolerate oral diet over 24 h, absence of flatus over 24 h, distension, radiologic confirmation occurring on or after day 4 postoperatively without prior resolu-tion of postoperative ileus.”30 Prolonged ileus is reported to occur in 10% to 15% of patients undergoing intestinal surgery.31Once suspected, diagnostic evaluation to detect specific underlying factors capable of inciting ileus and to rule out the presence of mechanical obstruction is warranted.Patient medication lists should be reviewed for the pres-ence of drugs, especially opiates, known to be associated with impaired intestinal motility. Measurement of serum electrolytes may demonstrate electrolyte abnormalities commonly associ-ated with ileus. Abdominal radiographs are often obtained, but the distinction between ileus and mechanical obstruction may be difficult based on this test alone. In the postoperative setting, CT scanning is the test of choice as it can demonstrate the presence of an intra-abdominal abscess or other evidence of peritoneal sepsis that may be causing ileus and can exclude the presence of complete mechanical obstruction. Distinction of postoperative ileus from early postoperative obstruction can be difficult but is helpful in developing the appropriate management plan.The diagnosis of chronic pseudo-obstruction is suggested by clinical features and confirmed by radiographic and mano-metric studies. Diagnostic laparotomy or laparoscopy with full-thickness biopsy of the small intestine may be required to establish the specific underlying cause in cases of suspected neural disorder.TherapyThe management of ileus consists of limiting oral intake and correcting the underlying inciting factor. If vomiting or abdom-inal distention are prominent, the stomach should be decom-pressed using a nasogastric tube. Fluid and electrolytes should be administered intravenously until ileus resolves. If the dura-tion of ileus is prolonged, total parental nutrition (TPN) may be required.Given the frequency of postoperative ileus and its financial impact, many strategies have been tested to reduce its duration. The administration of nonsteroidal anti-inflammatory drugs such as ketorolac and concomitant reductions in opioid dosing have been shown to reduce the duration of ileus in most studies. Similarly, the use of perioperative thoracic epidural anesthesia/analgesia with Brunicardi_Ch28_p1219-p1258.indd 123423/02/19 2:24 PM 1235SMALL INTESTINECHAPTER 28regimens containing local anesthetics combined with limitation or elimination of systemically administered opioids has been shown to reduce duration of postoperative ileus, although they have not reduced the overall length of hospital stay.32 Many studies have also suggested that limiting intraand postoperative fluid administration can also result in reduction of postoperative ileus and shortened hospital stay.33 Furthermore, studies have shown that early postoperative feeding after GI surgery is generally well tolerated and can lead to reduced postoperative ileus and a shorter hospital stay. Table 28-6 summarizes some of the measures used to minimize postoperative ileus. Such data have generated significant interest in Early Recovery After Surgery (ERAS) pathways, which are a collection of steps taken to expedite postoperative recovery in general. ERAS protocols typically involve 15 to 20 steps that involve the pre-, intraand postoperative phases of care and form a multimodal pathway. Although the contribution of each element to the overall outcome has not been well studied, the bundle of steps leads to reduced length of stay and surgical complications. In cases of GI surgery, many of these steps are targeted towards reducing postoperative ileus, which is often the barrier to early discharge.Although prokinetic agents have been tried to pro-mote return of GI motility, they are associated with efficacytoxicity profiles that are too unfavorable to warrant routine use. Recently, administration of alvimopan, a novel, peripherally active mu-opioid receptor antagonist with limited oral absorp-tion, has been shown to reduce duration of postoperative ileus, hospital stay, and rate of readmissions in several prospective, randomized, placebo-controlled trials and the subsequent meta-analysis.34 Any cost savings associated with the use of this drug outside of a clinical trial has, however, been debated.35The therapy of patients with chronic intestinal pseudo-obstruction focuses on palliation of symptoms as well as fluid, electrolyte, and nutritional management. Surgery should be avoided if possible. No standard therapies are curative or delay the natural history of any of the specific disorders causing intes-tinal pseudo-obstruction. Prokinetic agents, such as metoclo-promide and erythromycin, are associated with poor efficacy. Cisapride has been associated with palliation of symptoms; however, because of cardiac toxicity and reported deaths, this agent is restricted to compassionate use in the United States.Patients with refractory disease may require strict limitation of oral intake and long-term TPN administration. Despite these measures, some patients will continue to have severe abdomi-nal pain or such copious intestinal secretions that vomiting and fluid and electrolyte losses remain substantial. These patients may require a decompressive gastrostomy or an extended small bowel Table 28-6Measures to reduce postoperative ileusIntraoperative measures Minimalize handling of the bowel Laparoscopic approach, if possible Restricted intraoperative fluid administrationPostoperative measures Avoid nasogastric tubes Early enteral feeding Epidural anesthesia, if indicated Restricted IV fluid administration Correct electrolyte abnormalities Consider mu-opiod antagonistsresection to remove abnormal intestine. Small-intestinal trans-plantation has been applied in these patients with increasing fre-quency; the ultimate role of this modality remains to be defined.CROHN’S DISEASECrohn’s disease is a chronic, idiopathic transmural inflamma-tory disease with skip lesions that may affect any part of the alimentary tract, although there is propensity to affect the dis-tal small bowel. Nearly 80% of patients with Crohn’s disease have small bowel involvement, with 30% having terminal ileitis exclusively. Recent studies suggest a prevalence of about 241 cases per 100,000 in the United States.36 The rates of Crohn’s and ulcerative colitis have been increasing globally over the past several decades with substantial regional variations in inci-dence. The highest incidences are reported in western nations and those in northern latitudes, with Canada having the highest reported rates.37 In countries such as China, the prevalence of Crohn’s disease is substantially below that seen in the West, but rates have been rapidly increasing recently.38 The incidence of Crohn’s disease varies among ethnic groups within the same geographic region. For example, members of Eastern European Ashkenazi Jewish population are at a twoto fourfold higher risk of developing Crohn’s disease than members of other popu-lations living in the same location.Most studies suggest that Crohn’s disease is slightly more prevalent in females than in males. The mean age at which patients are diagnosed with Crohn’s disease falls in the third decade of life years, with a second smaller peak in the sixth decade of life, giv-ing it a bimodal distribution. The age at diagnosis can, however, range from early childhood through the entire lifespan.Both genetic and environmental factors appear to influ-ence the risk for developing Crohn’s disease. The relative risk among first-degree relatives of patients with Crohn’s disease is 14 to 15 times higher than that of the general population, with about 20% of patients reporting a family history. The concor-dance rate among monozygotic twins is as high as 67%; how-ever, Crohn’s disease is not associated with simple Mendelian inheritance patterns. Although there is a tendency within fami-lies for either ulcerative colitis or Crohn’s disease to be present exclusively, mixed kindreds also occur, suggesting the presence of some shared genetic traits as a basis for both diseases.Higher socioeconomic status is associated with an increased risk of Crohn’s disease. Most studies have found breastfeeding to be protective against the development of Crohn’s disease. Crohn’s disease is more prevalent among smokers. Furthermore, smoking is associated with the increased risk for both the need for surgery and the risk of relapse after surgery for Crohn’s disease.PathophysiologyCrohn’s disease is characterized by sustained inflammation. Whether this inflammation represents an appropriate response to a yet unrecognized pathogen or an inappropriate response to a normally innocuous stimulus is unknown. Various hypotheses on the roles of environmental and genetic factors in the patho-genesis of Crohn’s disease have been proposed. Many infec-tious agents have been suggested to be the causative organism of Crohn’s disease; however, there has been no conclusive evidence to confirm any. Studies using animal models suggest that in a genetically susceptible host, a nonpathogenic gut microbiome is sufficient to induce a chronic inflammatory response resembling Brunicardi_Ch28_p1219-p1258.indd 123523/02/19 2:24 PM 1236SPECIFIC CONSIDERATIONSPART IIthat associated with Crohn’s disease. In these models, the sus-tained intestinal inflammation is the result of either abnormal epithelial barrier function or immune dysregulation. A full dis-cussion of the role of gut immune system and microbiome in the development of Crohn’s disease is beyond the scope of this work, but it is an area of great interest and under investigation. In general, poor barrier function is hypothesized to permit inap-propriate exposure of lamina propria lymphocytes to antigenic stimuli derived from the intestinal lumen. In addition, a variety of defects in immune regulatory mechanisms, e.g., overrespon-siveness of mucosal T cells to enteric flora-derived antigens, can lead to defective immune tolerance and sustained inflammation.Specific genetic defects associated with Crohn’s disease in human patients are beginning to be defined. For example, the presence of a locus on chromosome 16 (the so-called IBD1 locus) has been linked to Crohn’s disease. The IBD1 locus has been identified as the NOD2 gene. Persons with allelic variants on both chromosomes have a 40-fold relative risk of Crohn’s disease com-pared to those without variant NOD2 genes. The relevance of this gene to the pathogenesis of Crohn’s disease is biologically plau-sible, as the protein product of the NOD2 gene mediates the innate immune response to microbial pathogens. Other putative IBD loci have been identified on other chromosomes (IBD2 on chromose 12q, and IBD3 on chromose 6), and are under investigation.Although appendectomy has been shown to lower the risk of subsequent development of ulcerative colitis, it was suspected that the surgery may increase the risk of developing Crohn’s disease. A meta-analysis has, however, suggested that the observed increased risk of Crohn’s disease in the first few years after an appendectomy may in fact reflect diagnostic dif-ficulty in a group of patients with incipient Crohn’s.39Although the pathological hallmark of Crohn’s disease is focal, transmural inflammation of the intestine, a spectrum of pathological lesions can be present. The earliest lesion characteristic of Crohn’s disease is the aphthous ulcer. These superficial ulcers are up to 3 mm in diameter and are surrounded by a halo of erythema. In the small intestine, aphthous ulcers typically arise over lymphoid aggregates. Granulomas are highly characteristic of Crohn’s disease and are reported to be present in up to 70% of intestinal specimens obtained during surgical resection. These granulomas are noncaseating and can be found in both areas of active disease and apparently normal intestine, in any layer of the bowel wall, and in mesenteric lymph nodes.As disease progresses, aphthae coalesce into larger, stellateshaped ulcers. Linear or serpiginous ulcers may form when multiple ulcers fuse in a direction parallel to the longitudinal axis of the intestine. With transverse coalescence of ulcers, a cobblestoned appearance of the mucosa may arise.With advanced disease, inflammation can be transmural. Serosal involvement results in adhesion of the inflamed bowel to other loops of bowel or other adjacent organs. Transmural inflammation can also result in fibrosis with stricture formation, intra-abdominal abscesses, fistulas, and, rarely, free perforation. Inflammation in Crohn’s disease can affect discontinuous por-tions of intestine, so-called skip lesions that are separated by intervening normal-appearing intestine.A feature of Crohn’s disease that is grossly evident and helpful in identifying affected segments of intestine during sur-gery is the presence of fat wrapping, which represents encroach-ment of mesenteric fat onto the serosal surface of the bowel (Fig. 28-17). This finding is virtually pathognomonic of Crohn’s Figure 28-17. Crohn’s disease. This intraoperative photograph demonstrates encroachment of mesenteric fat onto the serosal surface of the intestine (“fat wrapping”) that is characteristic of intestinal segments affected by active Crohn’s’ disease.disease. The presence of fat wrapping correlates well with the presence of underlying acute and chronic inflammation.Features that allow for differentiation between Crohn’s dis-ease of the colon and ulcerative colitis include the layers of the bowel wall affected (inflammation in ulcerative colitis is limited to the mucosa and submucosa but may involve the full-thickness of the bowel wall in Crohn’s disease) and the longitudinal extent of inflammation (inflammation is continuous and characteristi-cally affects the rectum in ulcerative colitis but may be discon-tinuous and spare the rectum in Crohn’s disease). In the absence of full expression of features of advanced disease, Crohn’s colitis can sometimes be difficult to distinguish from ulcerative colitis. It is also important to remember that although ulcerative colitis is a disease of the colon, it can be associated with inflammatory changes in the distal ileum (backwash ileitis).Clinical PresentationThe most common symptoms of Crohn’s disease are abdominal pain, diarrhea, and weight loss. However, the clinical features are highly variable among individual patients and depend on which segment(s) of the gastrointestinal tract is (are) predomi-nantly affected, the intensity of inflammation, and the presence or absence of specific complications. In fact, some patients with Crohn’s disease may have been initially misdiagnosed as having irritable bowel syndrome or celiac disease.Patients can be classified by their predominant clinical manifestation as having primarily (a) fibrostenotic disease, (b) fistulizing disease, and (c) aggressive inflammatory disease. There is substantial overlap among these disease patterns in individual patients, however. The onset of symptoms is insidious, and once present, their severity follows a waxing and waning course. Constitutional symptoms, particularly weight loss and fever, or growth retardation in children, may also be prominent and are occasionally the sole presenting features of Crohn’s disease.The disease affects the small bowel in 80% of cases and colon alone in 20%. In those with small bowel disease, the major-ity have ileocecal disease. Isolated perineal and anorectal disease occurs in 5% to 10% of affected patients. Uncommon sites of involvement include the esophagus, stomach, and duodenum.An estimated one-fourth of all patients with Crohn’s disease will have an extraintestinal manifestation of their disease. One Brunicardi_Ch28_p1219-p1258.indd 123623/02/19 2:24 PM 1237SMALL INTESTINECHAPTER 28fourth of those affected will have more than one manifestation. Many of these complications can be seen with both Crohn’s disease and ulcerative colitis, although they are more prevalent among patients with Crohn’s disease. The most common extraintestinal manifestations are listed in Table 28-7. The clinical severity of some of these manifestations, such as erythema nodosum and peripheral arthritis, are correlated with the severity of intestinal inflammation. The severity of other manifestations, such as pyoderma gangrenosum and ankylosing spondylitis, bear no apparent relationship to the severity of intestinal inflammation.DiagnosisThe diagnosis is usually established with endoscopic findings in a patient with a compatible clinical history. The diagnosis should be considered in those presenting with acute or chronic abdominal pain, especially when localized to the right lower quadrant, chronic diarrhea, evidence of intestinal inflammation on radiography or endoscopy, the discovery of a bowel stricture or fistula arising from the bowel, and evidence of inflamma-tion or granulomas on intestinal histology. Disorders associated with clinical presentations that resemble those of Crohn’s dis-ease include ulcerative colitis, functional bowel disorders such as irritable bowel syndrome, mesenteric ischemia, collagen vascular diseases, carcinoma and lymphoma, diverticular dis-ease, and infectious enteritides. Infectious enteritides are most frequently diagnosed in immunocompromised patients, but they can also occur in patients with normal immune function. Acute ileitis caused by Campylobacter and Yersinia species can be difficult to distinguish from that caused by an acute presenta-tion of Crohn’s disease. Typhoid enteritis caused by Salmonella Table 28-7Extraintestinal manifestations of Crohn’s diseaseDermatologic Erythema nodosum Pyoderma gangrenosumRheumatologic Peripheral arthritis Ankylosing spondylitis SacroiliitisOcular Conjunctivitis Uveitis/iritis EpiscleritisHepatobiliary Hepatic steatosis Cholelithiasis Primary sclerosing cholangitis PericholangitisUrologic Nephrolithiasis Ureteral obstructionMiscellaneous Thromboembolic disease Vasculitis Osteoporosis Endocarditis, myocarditis, pleuropericarditis Interstitial lung disease Amyloidosis Pancreatitistyphosa can lead to overt intestinal bleeding and perforation, most often affecting the terminal ileum. The distal ileum and cecum are the most common sites of intestinal involvement by infection due to Mycobacterium tuberculosis. This condi-tion can result in intestinal inflammation, strictures, and fistula formation, like those seen in Crohn’s disease. Cytomegalovirus (CMV) can cause intestinal ulcers, bleeding, and perforation.No single symptom, sign, or diagnostic test establishes the diagnosis of Crohn’s disease. Instead, the diagnosis is based on a complete assessment of the clinical presentation with confirmatory findings derived from radiographic, endoscopic, and in most cases, pathologic tests. Patients presenting with a history of Crohn’s disease should have their full blood count, electrolytes and renal function, liver function, iron, B12, ESR, and CRP levels checked. The results may be abnormal, show-ing anemia, but these results are nondiagnostic. Colonoscopy with intubation of terminal ileum is the main diagnostic tool and can reveal focal ulcerations adjacent to areas of normal appear-ing mucosa along with polypoid mucosal changes that give a “cobblestone appearance.” Skip areas of involvement are typical with segments of normal-appearing bowel interrupted by large areas of obvious disease; this pattern is different from the con-tinuous involvement in ulcerative colitis. Pseudopolyps, as seen in ulcerative colitis, are also often present. Barium small bowel follow-through, CT enterography, or MR enterography may be used as contrast examinations of the small bowel to reveal strictures or networks of ulcers and fissures. CT scanning may reveal intra-abdominal abscesses and is useful in acute presenta-tions to rule out the presence of other intra-abdominal disorders. Esophagogastroduodenoscopy (EGD) is done for disease of the proximal alimentary tract. Because Crohn’s disease often affects the small bowel, which is difficult to image, capsule endoscopy has been increasing used to make this diagnosis (Fig. 28-18).40Figure 28-18. Crohn’s disease. This image was captured by a wireless capsule endoscope as it was traveling through the small intestine. It demonstrates a superficial ulceration in the small bowel consistent with Crohn’s disease. (Used with permission from Anne T. Wolf, M.D., Department of Medicine, Brigham and Women’s Hospital, Boston, MA.)Brunicardi_Ch28_p1219-p1258.indd 123723/02/19 2:24 PM 1238SPECIFIC CONSIDERATIONSPART IISeveral antibodies have also been identified in patients with inflammatory bowel disease, which may have diagnostic value. The most commonly tested antibodies are antineutrophil cytoplasmic antibody (pANCA) and antisaccharmyces cerevi-siae antibody (ASCA). ASCA+/pANCA–, is associated with a diagnosis of Crohn’s disease, while ASCA–/pANCA+, corre-lates with ulcerative colitis. Although these antibody tests have high specificity, their use has been hampered by low test sensi-tivities. There is ongoing interest in developing other antibody tests to diagnose inflammatory bowel disease and help differ-entiate Crohn’s disease from ulcerative colitis. There have been attempts to develop stool tests to diagnose inflammatory bowel disease, and although fecal calprotectin or lactoferrin can iden-tify patients with intestinal inflammation, they are not routinely done in clinical practice.Because of the insidious, and often nonspecific, presenta-tion of Crohn’s disease, a diagnosis of Crohn’s is typically made only after symptoms have been present for several years. How-ever, in acute presentations, the diagnosis is sometimes made intraoperatively or during surgical evaluation. The initial mani-festation of Crohn’s disease can consist of right lower quadrant abdominal mimicking the presentation of acute appendicitis. In patients with this presentation, Crohn’s disease can be discov-ered for the first time during laparotomy or laparoscopy per-formed for presumed appendicitis. In some patients, the initial manifestation of Crohn’s disease is an acute abdomen related to small bowel obstruction, intra-abdominal abscess, or free intestinal perforation. In other patients, perianal abscesses and fistulas requiring surgical therapy may be the first manifestation of Crohn’s disease.TherapyBecause no curative therapies are available for Crohn’s dis-ease, the goal of treatment is to palliate symptoms rather than to achieve cure. Medical therapy is used to induce and maintain disease remission. Surgery is reserved for specific indications described later in this chapter. In addition, nutritional support in the form of aggressive enteral regimens or, if necessary, paren-teral nutrition, is used to manage the malnutrition that is com-mon in patients with Crohn’s disease.Medical Therapy. Pharmacologic agents used to treat Crohn’s disease include antibiotics, aminosalicylates, corticosteroids, immunomodulators, and biologic therapies. Antibiotics have an adjunctive role in the treatment of infectious complications associated with Crohn’s disease. They are also used to treat patients with perianal disease, enterocutaneous fistulas, and active colonic disease.Crohn’s disease activity is assessed using the Crohn’s dis-ease Activity Index or Harvey-Bradshaw Index, and depending on the scores, it can be categorized as asymptomatic, mild, mod-erate, or severe disease to guide therapy. While patients with mild and moderate disease can be managed on an outpatient basis, those with severe or fulminant disease often require hospitaliza-tion for treatment, bowel rest, and possible nutritional support. There are two general approaches to treating Crohn’s disease: top-down (which starts with the most potent agents to achieve remission with a subsequent decrease in medication) or step-up (starts with less potent and often safer drugs, and if symptoms fail to improve advances to the next group of medications).The use of oral 5-aminosalicylic acid (5-ASA) drugs (e.g., mesalamine) is somewhat controversial with mixed results from several randomized studies and meta-analyses. Aminosalicylates are associated with minimal toxicity and are available in a variety of formulations that allow for their delivery to specific regions of the alimentary tract. Thus, many continue to recommend use of mesalamine as an initial step in management of mild symptoms in patients with small bowel Crohn’s disease.Orally administered glucocorticoids are used to treat patients with mild disease that does not respond to aminosalicy-lates, or as initial treatment of patients with moderate disease. Patients with severe active disease usually require intravenous administration of glucocorticoids. Although glucocorticoids are effective in inducing remission, they are ineffective in prevent-ing relapse, and their adverse side-effect profile makes long-term use hazardous. Therefore, they should be tapered once remis-sion is achieved. Some patients are unable to undergo glucocor-ticoid tapering without suffering recurrence of symptoms. Such patients are said to have steroid dependence. These patients, along with those who do not respond to steroids at all (steroid resistant), should be considered for immune modulator therapies. Controlled ileal-released budesonide is an oral steroid with high first-pass hepatic metabolism and few systemic effects that can be tried in those with ileal and colonic Crohn’s disease.For those with severe disease, the thiopurine antimetabo-lites azathioprine and its active metabolite, 6-mercaptopurine, have demonstrated efficacy in inducing remission, maintaining remission, and allowing for glucocorticoid tapering in gluco-corticoid-dependent patients. A response to these medications is usually observed in 3 to 6 months, during which patients may need to continue with steroids. There is also some evidence that they decrease the risk of relapse after intestinal resection for Crohn’s disease. These agents are relatively safe but can induce bone marrow suppression and promote infectious complications. For patients who do not respond to the thiopurines, methotrexate is an alternative that is usually initially given intramuscularly before switching to oral form after achieving symptomatic con-trol. There is little role for cyclosporine in Crohn’s disease; its efficacy/toxicity profile in this disease is poor.The successful introduction of infliximab (Remicade), an anti-TNFα antibody, heralded the era of biological therapies for inflammatory bowel disease. Infliximab is a chimeric monoclo-nal antitumor necrosis-factor alpha (TNFα) antibody that has been shown to have efficacy in inducing remission and in pro-moting closure of enterocutaneous fistulae. There are two other anti-TNFα antibodies, with no randomized studies comparing efficacy of the drugs head to head. In general, it is thought that there is no significant difference in efficacy between them. While infliximab is a mouse-human chimeric antibody, adalimumab (Humira) is a fully human antibody. Certolizumab pegol (Cimzia) is a PEGylated Fab fragment of a humanized TNF inhibitor mono-clonal antibody. These agents are generally used for patients who are resistant to standard therapy, to help taper steroid dosage. They are generally well tolerated, but they should not be used in patients with ongoing septic processes, such as undrained intra-abdomi-nal abscesses. Antibodies against other targets in this inflamma-tory pathway have also been developed, including vedolizumab (Entyvio), a humanized anti–α4β7 integrin monoclonal antibody, with more specific anti-inflammatory effect in the intestine.For patients with perianal disease, antibiotic therapy with metronidazole or ciprofloxacin is the primary step. Two to 4 weeks of therapy is needed before improvements are seen, and often long-term therapy is required to prevent relapse. In cases of relapse, azathioprine can be considered. In patients with fis-tulas, infliximab and azathiprine are drugs of choice.Brunicardi_Ch28_p1219-p1258.indd 123823/02/19 2:24 PM 1239SMALL INTESTINECHAPTER 28Surgical Therapy. With introduction of new treatments, the need for surgery for Crohn’s disease has decreased steadily over the past few decades. Recent meta-analysis estimated the risk of surgery to be 16.3%, 33.3%, and 46.6% at 1, 5, and 10 years respectively.41 Surgery is generally reserved for patients whose disease is unresponsive to aggressive medical therapy or who develop complications of their disease (Table 28-8). Failure of medical management may be the indication for surgery if symp-toms persist despite aggressive therapy for several months or if symptoms recur whenever aggressive therapy is tapered. Sur-gery should be considered if medication-induced complications arise, specifically corticosteroid-related complications, such as cushingoid features, cataracts, glaucoma, systemic hyperten-sion, compression fractures, or aseptic necrosis of the femoral head. Growth retardation constitutes an indication for surgery in 30% of children with Crohn’s disease.One of the most common indications for surgical interven-tion is intestinal obstruction. Abscesses and fistulas are frequently encountered during operations performed for intestinal obstruc-tion in these patients, but they are rarely the only indication for surgery. Most abscesses are amenable to percutaneous drain-age, and fistulas, unless associated with symptoms or metabolic derangements, do not require surgical intervention. Less common complications that require surgical intervention are acute gastro-intestinal hemorrhage, perforations, and development of cancer.Although surgery for Crohn’s disease is usually planned, an uncommon, but not rare, scenario is the intraoperative dis-covery of inflammation limited to the terminal ileum during operations performed for presumed appendicitis. This scenario can result from an acute presentation of Crohn’s disease or from acute ileitis caused by bacteria such as Yersinia or Campylo-bacter. Both conditions should be treated medically; ileal resec-tion is not generally indicated. However, the appendix, even if normal appearing, should be removed (unless the cecum is inflamed, increasing the potential morbidity of this procedure) to eliminate appendicitis from the differential diagnosis of abdominal pain in these patients, particularly those with Crohn’s disease who may be destined to have recurring symptoms.When the diagnosis of Crohn’s disease is known and sur-gery is planned, a thorough examination of the entire intestine should be performed. The presence of active disease is suggested by thickening of the bowel wall, narrowing of the lumen, serosal inflammation and coverage by creeping fat, and thickening of Table 28-8Indications for surgical intervention in Crohn’s diseaseAcute onset of severe disease: Crohn’s colitis +/− toxic megacolon (rare)Failure of medical therapy: Persistent symptoms despite long-term steroid use Recurrence of symptoms when high-dose steroids are tapered Drug-induced complications (Cushing’s disease, hypertension)Development of disease complications: Obstruction Perforation Complicated fistulas Hemorrhage Malignancy riskthe mesentery. Skip lesions are present in approximately 20% of cases and should be sought. The length of uninvolved small intestine should be noted.Segmental intestinal resection of grossly evident disease followed by primary anastomosis is the usual procedure of choice. Microscopic evidence of Crohn’s disease at the resection margins does not compromise a safe anastomosis, and frozen section analysis of resection margins is unnecessary. In a ran-domized prospective trial, the effects of achieving 2-cm resec-tion margins beyond grossly evident disease were compared with achieving 12-cm resection margins.42 There were no evident dif-ferences with respect to clinical recurrence rates or anastomotic recurrences. Recurrence rates were similar whether margins were histologically free of or involved with Crohn’s disease. An area of controversy in surgical management of Crohn’s disease has been the ideal anastomotic technique for the bowel after intestinal resection. This issue was addressed in a randomized study of 139 patients undergoing an ileocolic resection for Crohn’s disease, with a mean follow-up of 11.9 months. There were no differ-ences in endoscopic or symptomatic disease recurrence between the groups reconstructed using end-to-end sutured (2-0 PDS) anastomosis versus those with side-to-side staples anastomosis.43An alternative to segmental resection for obstructing lesions is stricturoplasty (Fig. 28-19). This technique allows for preservation of intestinal surface area and is especially well suited to patients with extensive disease and fibrotic stric-tures who may have undergone previous resection and are at risk for developing short bowel syndrome. In this technique, the bowel is opened longitudinally to expose the lumen. Any ABFigure 28-19. Stricturoplasty. The wall of the strictured bowel is incised longitudinally. Reconstruction is performed by closing the defect transversely in a manner similar to the Heinecke-Mickulicz pyloroplasty for short strictures (A), or the Finney pyloroplasty for longer strictures (B).Brunicardi_Ch28_p1219-p1258.indd 123923/02/19 2:24 PM 1240SPECIFIC CONSIDERATIONSPART IIintraluminal ulcerations should be biopsied to rule out the pres-ence of neoplasia. Depending on the length of the stricture, the reconstruction can be fashioned in a manner similar to the Heinecke-Mickulicz pyloroplasty (for strictures less than 12 cm in length) or the Finney pyloroplasty (for longer strictures as much as 25 cm in length). For longer strictures, variations on the standard stricturoplasty, namely the side-to-side isoperistaltic enteroenterostomy, have been advocated and used for strictures with mean lengths of 50 cm.44 Stricturoplasty sites should be marked with metallic clips to facilitate their identification on radiographs and during subsequent operations. Stricturoplasty is associated with recurrence rates that are no different from those associated with segmental resection. Because the affected bowel is left in situ rather than resected, there is the potential for cancer developing at the stricturoplasty site. However, as data on this complication are limited to anecdotes, this risk remains a theo-retical one. Stricturoplasty is contraindicated in patients with intra-abdominal abscesses or intestinal fistulas. The presence of a solitary stricture relatively close to a segment for which resection is planned is a relative contraindication. In general, stricturoplasty is performed in cases where single or multiple strictures are identified in diffusely involved segments of bowel, or where previous resections have been performed and mainte-nance of intestinal length is of great importance.Intestinal bypass procedures are sometimes required in the presence of intramesenteric abscesses or if the diseased bowel is coalesced in the form of a dense inflammatory mass, making its mobilization unsafe. Bypass procedures (gastrojejunostomy) are also used in the presence of duodenal strictures, for which stric-turoplasty and segmental resection can be technically difficult.Since the 1990s, laparoscopic surgical techniques have been applied to patients with Crohn’s disease. The inflamma-tory changes associated with Crohn’s disease such as thickened and for eshortened mesentery, obliterated tissue planes, and fri-able tissues with engorged vasculature can make laparoscopic approach challenging. Randomized studies and a meta-analysis have confirmed that laparoscopic surgery for Crohn’s disease is associated with less postoperative pain, shorter duration of ileus, and a shorter hospital stay. The rates of disease recurrence were similar between the two groups.45OutcomesOverall complication rates following surgery for Crohn’s dis-ease range from 15% to 30%. Wound infections, postoperative intra-abdominal abscesses, and anastomotic leaks account for most of these complications.Surgery is not a curative intervention in Crohn’s disease, and many patients develop recurrence. If recurrence is defined endoscopically, 70% recur within 1 year of a bowel resection and 85% by 3 years.46 Clinical recurrence, defined as the return of symptoms confirmed as being due to Crohn’s disease, affects 60% of patients by 5 years and 94% by 15 years after intestinal resection. Reoperation becomes necessary in approximately one-third of patients by 5 years after the initial operation, with a median time to reoperation of 7 to 10 years.47 Of patient-modifying factors, smoking is a strong risk factor for disease recurrence.INTESTINAL FISTULASA fistula is defined as an abnormal communication between two epithelialized surfaces. The communication occurs between two parts of the gastrointestinal tract or adjacent organs in an internal fistula (e.g., enterocolonic fistula or colovesicular fistula). An external fistula (e.g., enterocutaneous fistula or rectovaginal fistula) involves the skin or another external surface epithelium. Enterocutaneous fistulas that drain less than 200 mL of fluid per day are known as low-output fistulas, whereas those that drain more than 500 mL of fluid per day are known as high-output fistulas.Over 80% of enterocutaneous fistulas represent iatrogenic complications that occur as the result of enterotomies or intes-tinal anastomotic dehiscences. Fistulas that arise spontaneously without antecedent iatrogenic injury are usually manifestations of progression of underlying Crohn’s disease or cancer.PathophysiologyThe manifestations of fistulas depend on which structures are involved. Low-resistance enteroenteric fistulas, which allow luminal contents to bypass a significant proportion of the small intestine, may result in clinically-significant malabsorption. Enterovesicular fistulas often cause recurrent urinary tract infec-tions. The drainage emanating from enterocutaneous fistulas are irritating to the skin and cause excoriation. The loss of enteric luminal contents, particularly from high-output fistulas originat-ing from the proximal small intestine, results in dehydration, electrolyte abnormalities, and malnutrition.Fistulas have the potential to close spontaneously. Factors inhibiting spontaneous closure, however, include malnutrition, sepsis, inflammatory bowel disease, cancer, radiation, obstruc-tion of the intestine distal to the origin of the fistula, foreign bodies, high output, short fistulous tract (<2 cm) and epitheli-alization of the fistula tract (Table 28-9).Clinical PresentationIatrogenic enterocutaneous fistulas usually become clinically evident between the fifth and tenth postoperative days. Fever, leukocytosis, prolonged ileus, abdominal tenderness, and wound infection are the initial signs. The diagnosis becomes obvious when drainage of enteric material through the abdominal wound or through existing drains occurs. These fistulas are often asso-ciated with intra-abdominal abscesses.DiagnosisCT scanning following the administration of enteral contrast is the most useful initial test. Leakage of contrast material from the intestinal lumen can be observed. Intra-abdominal abscesses Table 28-9Factors negatively impacting enteric fistula closurePatient factors Poor nutrition Medications such as steroidsEtiological factors Malignant fistula Fistula related to Crohn’s disease Fistula in radiated fieldsFistula site Gastric DuodenalLocal Factors Persistence of local inflammation and sepsis Presence of a foreign body (e.g., meshes or sutures) Epithelialization of fistula tract Fistula tract <2 cm Distal obstruction to the fistula siteBrunicardi_Ch28_p1219-p1258.indd 124023/02/19 2:24 PM 1241SMALL INTESTINECHAPTER 28should be sought and drained percutaneously. If the anatomy of the fistula is not clear on CT scanning, a small bowel series or enteroclysis examination can be obtained to demonstrate the fistula’s site of origin in the bowel. This study is also useful to rule out the presence of intestinal obstruction distal to the site of origin. Occasionally, contrast administered into the intestine does not demonstrate the fistula tract. A fistulogram, in which contrast is injected under pressure through a catheter placed per-cutaneously into the fistula tract, may offer greater sensitivity in localizing the fistula origin.TherapyThe treatment of enterocutaneous fistulas should proceed through an orderly sequence of steps48:1. Stabilization. Fluid and electrolyte resuscitation is begun. Nutrition is provided, usually through the parenteral route initially. Sepsis is controlled with antibiotics and drainage of abscesses. The skin is protected from the fistula effluent with ostomy appliances or fistula drains.2. Investigation. The anatomy of the fistula is defined using the aforementioned studies.3. Decision. The available treatment options are considered, and a time line for conservative measures is determined.4. Definitive Management. This entails the surgical procedure and requires appropriate preoperative planning and surgical experience.5. Rehabilitation.The overall objectives are to increase the probability of spontaneous closure. Nutrition and time are the key components of this approach. Most patients will require TPN; however, a trial of oral or enteral nutrition should be attempted in patients with low-output fistulas originating from the distal intestine. The somatostatin analogue octreotide is a useful adjunct, par-ticularly in patients with high-output fistulas. A meta-analysis of several randomized studies confirmed that somatostatin treatment reduced length of hospital stay and time to closure of fistulas; however, its administration did not lead to a significant differ-ence in fistula closure rates.49 Use of negative pressure wound therapy has increased in management of enterocutaneous fistulas. The system can allow better management of the fistula output. In a study of 91 patients with enterocutaneous fistulas, 40% of fis-tulae reached minimal output within a week, and with an average follow-up of 90 days, spontaneous closure rate was 46%.50Timing of Surgical Intervention. Most surgeons would pur-sue 2 to 3 months of conservative therapy before considering surgical intervention. This approach is based on evidence that 90% of fistulas that are going to close do so within 5 weeks and that surgical intervention after this period is associated with bet-ter outcomes and lower morbidity.51If the fistula fails to resolve during this period, surgery may be required, during which the fistula tract, together with the segment of intestine from which it originates, should be resected. Simple closure of the opening in the intestine from which the fistula originates is associated with high recurrence rates. Patients with intestinal fistulas typically have extensive and dense intra-abdominal adhesions. Thus, operations per-formed for nonhealing fistulas can present formidable chal-lenges. Successful applications of alternative therapies to close intestinal fistulas such as the use of biologic sealants have been reported. The indications for their use remain to be defined.OutcomesOver 50% of intestinal fistulas close spontaneously. A useful mnemonic designates factors that inhibit spontaneous closure of intestinal fistulas: “FRIEND” (Foreign body within the fistula tract, Radiation enteritis, Infection/Inflammation at the fistula origin, Epithelialization of the fistula tract, Neoplasm at the fis-tula origin, Distal obstruction of the intestine).In a 23-year old retrospective review of 153 cases of enterocutaneous fistulas that were treated surgically, most fis-tulas were found to originate from the small bowel and be iat-rogenic in nature, with patients having undergone five or more previous abdominal surgeries. Operative repair was associated with a 30-day mortality of approximately 4% and a 1-year mor-tality of 15%. Morbidity was over 80%. First attempt at surgical repair was successful in 70% of cases, with an overall closure rate of 84% and some patients requiring up to 3 attempts at surgical repair. The authors identified closure of the abdominal fascia as an important factor in reducing rates of refistulization and postoperative mortality.52 In another similar study, fistula recurrence rates of 30% were documented and were indepen-dently associated with high output fistulas and the type of surgi-cal treatment: operations not involving resection of the fistula had a much higher rate of recurrence.53SMALL BOWEL NEOPLASMSAdenomas are the most common benign neoplasm of the small intestine. Other benign tumors include fibromas, lipomas, hemangiomas, lymphangiomas, and neurofibromas. The prevalence of small bowel tumors identified at autopsy is 0.2% to 0.3%, which is significantly higher than the rate of operation for small bowel tumors. This suggests that majority of small bowel tumors are asymptomatic. These lesions are most frequently encountered in the duodenum as incidental findings during esophagogastroduodenoscopic (EGD) examinations (Fig. 28-20). The reported prevalence of Figure 28-20. Duodenal polyp. This polyp was incidentally encountered during EGD. It was biopsied and found to be an adenoma.Brunicardi_Ch28_p1219-p1258.indd 124123/02/19 2:24 PM 1242SPECIFIC CONSIDERATIONSPART IIduodenal polyps, as detected during EGD performed for other reasons, range from 0.3% to 4.6%.Benign neoplasms account for 30% to 50% of small bowel tumors and include adenomas, lipomas, hematomas, and hemangiomas. Primary small bowel cancers are rare but have been increasing in incidence, with an estimated incidence of 10,190 cases in 2017 in the United States. Among small bowel cancers, adenocarcinomas comprise 35% to 50% of all cases, carcinoid tumors comprise 20% to 40%, and lymphomas comprise approximately 10% to 15%. In a retrospective review of a large U.S. database (SEER) between 1992 and 2006, of a total number of 10,945 small intestine cancers, 4315 were neuroendocrine in origin, 3412 were carcinomas, 2023 were lymphomas, and 1084 were sarcomas.54 Gastrointestinal stromal tumors (GISTs) are the most common mesenchymal tumors arising in the small intestine and comprise the vast majority of tumors that were formerly classified as leiomyomas, leiomyosarcomas, and smooth muscle tumors of the intestine. The small intestine is frequently affected by metastases from or local invasion by cancers originating at other sites. Melanoma, in particular, is associated with a propensity for metastasis to the small intestine.Most patients with small-intestinal cancers are in their fifth or sixth decade of life. Reported risk factors for developing small-intestinal cancers include consumption of red meat, inges-tion of smoked or cured foods, Crohn’s disease, celiac sprue, hereditary nonpolyposis colorectal cancer (HNPCC), familial adenomatous polyposis (FAP), and Peutz-Jeghers syndrome.PathophysiologyThe small intestine contains over 90% of the mucosal surface area of the gastrointestinal tract but only 1.1% to 2.4% of all gastrointestinal malignancies. Proposed explanations for the low frequency of small-intestinal neoplasms include (a) dilu-tion of environmental carcinogens in the liquid chyme present in the small-intestinal lumen; (b) rapid transit of chyme, limiting the contact time between carcinogens and the intestinal mucosa; (c) a relatively low concentration of bacteria in small-intestinal chyme and, therefore, a relatively low concentration of carcino-genic products of bacterial metabolism; (d) mucosal protection by secretory IgA and hydrolases such as benzpyrene hydroxy-lase that may render carcinogens less active; and (e) efficient epithelial cellular apoptotic mechanisms that serve to eliminate clones harboring genetic mutations.Recent advances have begun to clarify the molecular pathogenesis of small-intestinal adenocarcinomas and GISTs; there has been less progress with respect to the pathogen-esis of the other small-intestinal malignancies (Table 28-10). Small-intestinal adenocarcinomas are believed to arise from Table 28-10Features of small intestinal malignanciesTUMOR TYPECELL OF ORIGINFREQUENCYaPREDOMINANT SITEAdenocarcinomaEpithelial cell35–50%DuodenumCarcinoidEnterochromaffin cell20–40%IleumLymphomaLymphocyte10–15%IleumGISTInterstitial cell of Cajal10–15%–aFrequencies given as percentages of small intestinal malignancies comprised by each of the tumor types. Gastrointestinal stromal tumors (GISTs) display no regional variation in prevalence within the small intestine.preexisting adenomas through a sequential accumulation of genetic abnormalities in a model like that described for the pathogenesis of colorectal cancer. Adenomas are histologi-cally classified as tubular, villous, and tubulovillous. Tubular adenomas have the least aggressive features. Villous adenomas have the most aggressive features and tend to be large, sessile, and located in the second portion of the duodenum. Malignant degeneration has been reported to be present in up to 45% of vil-lous adenomas by the time of diagnosis. Patients with FAP have a nearly 100% cumulative lifetime risk of developing duodenal adenomas that have the potential to undergo malignant trans-formation. The risk of duodenal cancer in these patients is over 100-fold greater than in the general population. Indeed, duode-nal cancer is the leading cause of cancer-related death among patients with FAP who have undergone colectomy. Patients with Peutz-Jeghers syndrome develop hamartomatous polyps; however, these polyps can contain adenomatous foci that can undergo malignant transformation (Fig. 28-21).A defining feature of GISTs is their gain of function mutation of proto-oncogene KIT, a receptor tyrosine kinase. Figure 28-21. Small bowel polyp in Peutz-Jeghers syndrome. This image was captured by a wireless capsule endoscope as it was traveling through the small intestine. (Used with permission from Anne T. Wolf, M.D., Department of Medicine, Brigham and Women’s Hospital, Boston, MA.)Brunicardi_Ch28_p1219-p1258.indd 124223/02/19 2:24 PM 1243SMALL INTESTINECHAPTER 28Pathological KIT signal transduction is believed to be a cen-tral event in GIST pathogenesis. The majority of GISTs have activating mutations in the c-kit proto-oncogene, which cause KIT to become constitutively activated, presumably leading to persistence of cellular growth or survival signals. Because the interstitial cells of Cajal normally express KIT, these cells have been implicated as the cell of origin for GISTs. KIT expression is assessed by staining the tissues for CD117 antigen, which is part of the KIT receptor and is present in 95% of GISTs.Clinical PresentationMost small-intestinal neoplasms are asymptomatic until they become large. Partial small bowel obstruction, with associ-ated symptoms of crampy abdominal pain and distention, nau-sea, and vomiting, is the most common mode of presentation. Obstruction can be the result of either luminal narrowing by the tumor itself or intussusception, with the tumor serving as the lead point. Hemorrhage, usually indolent, is the second most common mode of presentation.Physical examination may be unrevealing, but it also may reveal a palpable abdominal mass in those with large tumors. Findings of intestinal obstruction may be present in some patients. A fecal occult blood test may be positive. Jaundice secondary to biliary obstruction or hepatic metastasis may be present. Cachexia, hepatomegaly, and ascites may be present with advanced disease.Although the clinical presentation is usually not specific for tumor type, some general comments are appropriate. Adeno-carcinomas, as well as adenomas (from which most are believed to arise), are most commonly found in the duodenum, except in patients with Crohn’s disease, in whom most are found in the ileum. Lesions in the periampullary location can cause obstruc-tive jaundice or pancreatitis. Adenocarcinomas located in the duodenum tend to be diagnosed earlier in their progression than those located in the jejunum or ileum, which are rarely diagnosed prior to the onset of locally advanced or metastatic disease.Carcinoid tumors of the small intestine are also usually diagnosed after the development of metastatic disease. These tumors are associated with a more aggressive behavior than the more common appendiceal carcinoid tumors. Approximately 25% to 50% of patients with carcinoid tumor-derived liver metastases will develop manifestations of the carcinoid syn-drome. These manifestations include diarrhea, flushing, hypo-tension, tachycardia, and fibrosis of the endocardium and valves the right heart. Candidate tumor-derived mediators of the car-cinoid syndrome such as serotonin, bradykinin, and substance P undergo nearly complete metabolism during the first passage through the liver. As a result, symptoms of carcinoid syndrome are rare in the absence of liver metastases.Lymphoma may involve the small intestine primarily or as a manifestation of disseminated systemic disease. Primary small-intestinal lymphomas are most commonly located in the ileum, which contains the highest concentration of lymphoid tissue in the intestine. Although partial small bowel obstruction is the most common mode of presentation, 10% of patients with small-intestinal lymphoma present with bowel perforation.The small intestine is the second most common site of GIST tumors after the stomach, containing 25% to 35% of GISTs. There appears to be no regional variation in the preva-lence of GISTs within the small intestine. GISTs have a greater propensity to be associated with overt hemorrhage than the other small-intestinal malignancies (Fig. 28-22).Metastatic tumors involving the small intestine can induce intestinal obstruction and bleeding.DiagnosisBecause of the absent or nonspecific symptoms associated with most small-intestinal neoplasms, these lesions are rarely diagnosed preoperatively. Laboratory tests are nonspecific, except for elevated urinary 5-hydroxyindole acetic acid (5-HIAA) and serum chromogranin A (CgA) levels in patients with carcinoid syndrome, both of which have low sensitivity. Elevated carcinoembryonic antigen (CEA) levels are associated with small-intestinal adenocarcinomas, but only in the presence of liver metastases.Contrast radiography of the small intestine may demon-strate benign and malignant lesions. Enterocolysis is reported to have a sensitivity of over 90% in the detection of small bowel tumors and is the test of choice, particularly for tumors located in the distal small bowel. Upper GI with small bowel follow-through examinations have reported sensitivities ranging from only 30% to 44% (Fig. 28-23). CT scanning can detect abnor-malities in 70% to 80% of cases with small bowel tumor and assess for metastatic spread. Tumors associated with significant bleeding can be localized with angiography or radioisotope-tagged red blood cell (RBC) scans.Tumors located in the duodenum can be visualized and biopsied on EGD. In addition, endoscopic ultrasonography (EUS) can offer additional information such as the layers of the intestinal wall involved by the lesion. Occasionally, the distal ileum can suc-cessfully be visualized during colonoscopy. Intraoperative enter-oscopy can be used to directly visualize small-intestinal tumors beyond the reach of standard endoscopic techniques. For more distal small bowel lesions, capsule endoscopy and double-balloon Figure 28-22. Jejunal gastrointestinal stromal tumor (GIST). This patient presented with overt obscure GI bleeding and was found to have a 7-cm jejunal GIST. The picture represents the laparo-scopic view of the mass (black arrow), arising from the antimesenteric side of the small bowel (*). He underwent a successful laparoscopic resection.Brunicardi_Ch28_p1219-p1258.indd 124323/02/19 2:24 PM 1244SPECIFIC CONSIDERATIONSPART IIFigure 28-23. Small bowel lesion identified during a small bowel follow-through (arrow). This patient had previously had a metastatic renal lesion to his duodenum requiring a Whipple procedure. During follow-up imaging 3 years later, he was found to have this new lesion in his jejunum. He underwent a laparoscopic small bowel resection. Pathology revealed a benign jejunal sessile polyp.endoscopy have been used to evaluate small bowel. CT and MR enterography are also increasing utilized as noninvasive tests to look for small bowel masses. PET scans can also help assess metabolic activity of lesions and risk of malignancy.TherapyBenign neoplasms of the small intestine that are symptomatic should be surgically resected or removed endoscopically, if fea-sible. Tumors located in the duodenum, including asymptomatic lesions incidentally found during EGD, can pose the great-est therapeutic challenges. These lesions should be biopsied; symptomatic tumors and adenomas, because of their malignant potential, should be removed. In general, duodenal tumors less than 1 cm in diameter are amenable to endoscopic polypectomy. Lesions greater than 2 cm in diameter are technically difficult to remove endoscopically and may need to be removed surgi-cally. Surgical options include transduodenal polypectomy and segmental duodenal resection. Tumors located in the second portion of the duodenum near the ampulla of Vater may require pancreaticoduodenectomy. EUS may offer utility for duodenal tumors ranging in size between 1 and 2 cm in diameter, with those limited to the mucosa being amenable to endoscopic pol-ypectomy. Endoscopic resection of biopsy-proven benign duo-denal periampullary adenomas leads to equivalent efficacy to surgery but with lower morbidity. Adenomas can recur; there-fore, surveillance endoscopy is required after these procedures.55Duodenal adenomas occurring in the setting of FAP require an especially aggressive approach to management. Patients with FAP should undergo screening EGD starting sometime during their second or third decade of life. Adenomas detected should be removed endoscopically, if possible, followed by surveillance endoscopy in 6 months and yearly thereafter, in the absence of recurrence. If surgery is required, pancreaticoduodenectomy is generally necessary because adenomas in patients with FAP tend to be multiple and sessile, with a predilection for the peri-ampullary region. Further, localized resections are complicated by high recurrence rates. Given the potential for recurrences in the duodenal remnant following pylorus-preserving pancreati-coduodenectomy, there is rationale for recommending the appli-cation of standard pancreaticoduodenectomy in these patients. However, recurrences have been reported even following this procedure; therefore, continuing surveillance is necessary. For most adenocarcinomas of the duodenum, except those in the third or fourth portion of the duodenum where a local resection could be considered, pancreaticoduodenectomy is required.The surgical therapy of jejunal and ileal malignancies usually consists of wide-local resection of the intestine harboring the lesion. For adenocarcinomas, a wide excision of corresponding mesentery is done to achieve regional lymphadenectomy, as is done for adenocarcinomas of the colon. In the presence of locally-advanced or metastatic disease, palliative intestinal resection or bypass is performed. Chemotherapy has no proven efficacy in the adjuvant or palliative treatment of small-intestinal adenocarcinomas.The goal of surgical therapy for carcinoids is resection of all visible disease. Localized small-intestinal carcinoid tumors should be treated with segmental intestinal resection and regional lymphadenectomy. Nodal metastases are unusual with tumors less than 1 cm in diameter, but they are present with 75% to 90% of tumors larger than 3 cm in diameter. In approximately 30% of cases, multiple small-intestinal carcinoid tumors are present (Fig. 28-24). Therefore, the entire small intestine should Figure 28-24. Small bowel carcinoid tumor. This patient pre-sented with history of abdominal pain and on CT was found to have a circumferentially thickened loop of distal small bowel with associated mesenteric stranding and lymphadenopathy. An octreotide scan demonstrated abnormal activity in the area, concerning for a carcinoid tumor. He underwent an open small bowel resection. Pathology revealed a multifocal carcinoid tumor with 50 distinct nodules and metastasis to mesenteric lymph nodes.Brunicardi_Ch28_p1219-p1258.indd 124423/02/19 2:24 PM 1245SMALL INTESTINECHAPTER 28be examined before planning extent of resection. In the presence of metastatic disease, tumor debulking should be conducted as it can be associated with long-term survival and amelioration of symptoms of the carcinoid syndrome. Response rates of 30% to 50% have been reported to chemotherapy regimens based on agents such as doxorubicin, 5-fluorouracil, and streptozocin. However, none of these regimens is associated with a clearly demonstrable impact on the natural history of disease. Octreo-tide is the most effective pharmacologic agent for management of symptoms of carcinoid syndrome.Localized small-intestinal lymphoma should be treated with segmental resection of the involved intestine and adjacent mesentery. If the small intestine is diffusely affected by lym-phoma, chemotherapy rather than surgical resection should be the primary therapy. The value to adjuvant chemotherapy after resection of localized lymphoma is controversial.Small-intestinal GISTs should be treated with segmental intestinal resection. If the diagnosis is known prior to resec-tion, wide lymphadenectomy can be avoided as GISTs are rarely associated with lymph node metastases. GISTs are resistant to conventional chemotherapy agents. Imatinib (Gleevec) is a tyrosine kinase inhibitor with potent activity against tyrosine kinase KIT, and it is used in those with metastatic disease. Clini-cal trials have shown that 80% of patients with unresectable or metastatic GISTs derive clinical benefit from the administra-tion of Imatinib, with 50% to 60% having objective evidence of reduction in tumor volume.56 Imatinib has shown great promise as a neoadjuvant and adjuvant therapy for GISTs. Studies have emphasized the potential for development of tumor resistance to this agent. In this setting, an alternative tyrosine kinas inhibitor, sunitinib, has been used with good results.Metastatic cancers affecting the small intestine that are symptomatic should be treated with palliative resection or bypass except in the most advanced cases. Systemic therapy may be offered if effective chemotherapy exists for the primary cancer.OutcomesComplete resection of duodenal adenocarcinomas is associ-ated with postoperative 5-year survival rates ranging from 50% to 60%. Complete resection of adenocarcinomas located in the jejunum or ileum is associated with 5-year survival rates of 20% to 30%.57 Five-year survival rates of 75% to 95% fol-lowing resection of localized small-intestinal carcinoid tumors have been reported. In the presence of carcinoid tumor-derived liver metastases, 5-year survival rates of 19% to 54% have been reported. The overall 5-year survival rate for patients diagnosed with intestinal lymphoma ranges from 20% to 40%. For patients with localized lymphoma amenable to surgical resection, the 5-year survival rate is 60%.The recurrence rate following resection of GISTs aver-ages 35%. The 5-year survival rate following surgical resection has been reported to range from 35% to 60%. Both tumor size and mitotic index are independently correlated with prognosis. Low-grade tumors (mitotic index <10 per high-power field) measuring less than 5 cm in diameter are associated with excel-lent prognosis.RADIATION ENTERITISRadiation therapy is a component of multi-modality therapy for many intra-abdominal and pelvic cancers such as those of the cervix, endometrium, ovary, bladder, prostate, and rectum. An undesired side effect of radiation therapy is radiation-induced injury to the small intestine, which can present clinically as two distinct syndromes: acute and chronic radiation enteritis. Acute radiation enteritis is a transient condition that occurs in approximately 75% of patients undergoing radiation therapy for abdominal and pelvic cancers. Chronic radiation is enteritis is inexorable and develops in approximately 5% to 15% of these patients.PathophysiologyRadiation induces cellular injury directly and through the gen-eration of free radicals. The principal mechanism of radiation-induced cell death is believed to be apoptosis resulting from free-radical–induced breaks in double-stranded DNA. Because radiation has its greatest impact on rapidly proliferating cells, the small-intestinal epithelium is acutely susceptible to radiationinduced injury. Pathological correlates of this acute injury include villus blunting and a dense infiltrate of leukocytes and plasma cells within the crypts. With severe cases, mucosal sloughing, ulceration, and hemorrhage are observed. The inten-sity of injury is related to the dose of radiation administered, with most cases occurring in patients who have received at least 4500 cGy. Risk factors for acute radiation enteritis include con-ditions that may limit splanchnic perfusion such as hyperten-sion, diabetes mellitus, coronary artery disease, and restricted mobility of the small intestine due to adhesions. Injury is potentiated by concomitant administration of chemotherapeutic agents, such as doxorubicin, 5-fluorouracil, actinomycin D, and methotrexate, that act as radiation-sensitizers. Because of the intestinal epithelium’s capacity for regeneration, the mucosal injury that is characteristic of acute radiation enteritis resolves after the cessation of radiation therapy.In contrast, chronic radiation enteritis is characterized by a progressive occlusive vasculitis that leads to chronic ischemia and fibrosis that affects all layers of the intestinal wall, rather than the mucosa alone. These changes can lead to strictures, abscesses, and fistulas, which are responsible for the clinical manifestations of chronic radiation enteritis.Clinical PresentationThe most common manifestations of acute radiation enteritis are nausea, vomiting, diarrhea, and crampy abdominal pain. Symptoms are generally transient and subside after the discon-tinuation of radiation therapy. Because the diagnosis is usually obvious, given the clinical context, no specific diagnostic tests are required. However, if patients develop signs suggestive of peritonitis, CT scanning should be performed to rule out the presence of other conditions capable of causing acute abdominal syndromes.The clinical manifestations of chronic radiation enteritis usually become evident within 2 years of radiation administra-tion, although they can begin as early as several months or as late as decades afterwards. The most common clinical presenta-tions are diarrhea or one of partial small bowel obstruction with nausea, vomiting, intermittent abdominal distention, crampy abdominal pain, and weight loss. The terminal ileum is the most frequently affected segment. Other manifestations of chronic radiation enteritis include complete bowel obstruction, acute or chronic intestinal hemorrhage, and abscess or fistula formation.DiagnosisEvaluation of patients suspected of having chronic radia-tion enteritis should include review of the records of their Brunicardi_Ch28_p1219-p1258.indd 124523/02/19 2:24 PM 1246SPECIFIC CONSIDERATIONSPART IIradiation treatments for information on total radiation dose administered, fractionation, and volume of treatment. Areas that received high doses should be noted, as lesions subse-quently found in imaging studies usually localize to areas that had received high radiation doses. Enterocolysis is the most accurate imaging test for diagnosing chronic radiation enteri-tis, with reported sensitivities and specificities of over 90% (Fig. 28-25). CT scan findings are neither very sensitive nor specific for chronic radiation enteritis. However, CT scanning should be obtained to rule out the presence of recurrent can-cer since its clinical manifestations may overlap with those of chronic radiation enteritis.TherapyMost cases of acute radiation enteritis are self-limited. Support-ive therapy, including the administration of antiemetics, is usu-ally sufficient. Patients with diarrhea-induced dehydration may require hospital admission and parenteral fluid administration. Rarely are symptoms severe enough to necessitate reduction in or cessation of radiation therapy.In contrast, the treatment of chronic radiation enteritis represents a formidable challenge. Antidiarrheal agents may have a role in the management of diarrhea while, in those with obstructive symptoms, a low residue diet may be tried. Surgery for this condition is difficult, is associated with high morbidity rates, and should be avoided in the absence of specific indica-tions such as high-grade obstruction, perforation, hemorrhage, intra-abdominal abscesses, and fistulas. The goal of surgery is limited resection of diseased intestine with primary anastomosis Figure 28-25. Radiation enteritis. This contrast radiograph reveals widely separated loops of small bowel with luminal narrowing, loss of mucosal folds, and ulceration. This patient had received radiation therapy for a pelvic malignancy 8 years before this examination.between healthy bowel segments. However, the characteristi-cally diffuse nature of fibrosis and dense adhesions among bowel segments can make limited resection difficult to achieve. Further, it is difficult to distinguish between normal and irra-diated intestine intraoperatively by either gross inspection or even frozen section analysis. This distinction is important as anastomoses between irradiated segments of intestine have been associated with leak rates as high as 50%.58 If limited resec-tion is not achievable, an intestinal bypass procedure may be an option, except in cases for which hemorrhage is the surgical indication. There remain cases in which resections extensive enough to cause short bowel syndrome are unavoidable. This condition is discussed in detail below in the “Short Bowel Syn-drome” section.OutcomesAcute radiation injury to the intestine is self-limited; its sever-ity is not correlated with the probability of chronic radiation enteritis developing. Surgery for chronic radiation enteritis is associated with high morbidity rates and reported mortality rates averaging 10%.PreventionIn view of significant morbidity associated with radiation enteri-tis, groups have studies possible measures to reduce or prevent such side effects. Keeping radiation exposure to below 5000 cGy is associated with minimal long-term side effects and is recom-mended where clinically possible.Uses of multibeam radiation techniques to minimize the area of maximal radiation exposure, as well as tilt tables to move the bowel out of the pelvic during radiation, are increasingly utilized. Few small studies have suggested that oral sulphasala-zine may help reduce the incidence of acute radiation-induced enteritis.59In patients undergoing pelvic surgery that are likely to require postoperative radiation therapy, surgical techniques that keep the small bowel out of the pelvic have been recommended. These measures include use of absorbable mesh sling to sepa-rate the pelvic from the true abdominal cavity and prevent the small bowel from being exposed to pelvic radiation.60MECKEL’S DIVERTICULAMeckel’s diverticulum is the most prevalent congenital anom-aly of the gastrointestinal tract, affecting approximately 2% of the general population. Meckel’s diverticuli are designated true diverticuli because their walls contain all the layers found in normal small intestine. Their location varies among individual patients, but they are usually found in the ileum within 100 cm of the ileocecal valve (Fig. 28-26). Approximately 60% of Meckel’s diverticuli contain heterotopic mucosa, of which over 60% consist of gastric mucosa. Pancreatic acini are the next most common; others include Brunner’s glands, pancre-atic islets, colonic mucosa, endometriosis, and hepatobiliary tissues. A useful, although crude, mnemonic describing Meck-el’s diverticuli is the “rule of twos”: 2% prevalence, 2:1 male predominance, location 2 feet proximal to the ileocecal valve in adults, and half of those who are symptomatic are under 2 years of age.PathophysiologyDuring the eighth week of gestation, the omphalomesenteric (vitelline) duct normally undergoes obliteration. Failure or Brunicardi_Ch28_p1219-p1258.indd 124623/02/19 2:24 PM 1247SMALL INTESTINECHAPTER 28Figure 28-26. Meckel’s diverticulum. This intraoperative photograph shows Meckel’s diverticulum in ileum that has been eviscerated.incomplete vitelline duct obliteration results in a spectrum of abnormalities, the most common of which is Meckel’s divertic-ulum. Other abnormalities include omphalomesenteric fistula, enterocyst, and a fibrous band connecting the intestine to the umbilicus. A remnant of the left vitelline artery can persist to form a mesodiverticular band tethering a Meckel’s diverticulum to the ileal mesentery.Bleeding associated with Meckel’s diverticulum is usu-ally the result of ileal mucosal ulceration that occurs adjacent to acid-producing, heterotopic gastric mucosa located within the diverticulum. Intestinal obstruction associated with Meckel’s diverticulum can result from several mechanisms:1. Volvulus of the intestine around the fibrous band attaching the diverticulum to the umbilicus2. Entrapment of intestine by a mesodiverticular band (Fig. 28-27)3. Intussusception with the diverticulum acting as a lead point4. Stricture secondary to chronic diverticulitisMeckel’s diverticuli can be found in inguinal or femoral hernia sacs (known as Littre’s hernia). These hernias, when incarcerated, can cause intestinal obstruction.Figure 28-27. Meckel’s diverticulum with mesodiverticular band (A). One mechanism by which Meckel’s diverticuli can cause small bowel obstruction is entrapment of the intestine by a mesodiverticular band (B).Clinical PresentationMeckel’s diverticuli are asymptomatic unless associated com-plications arise. The lifetime incidence rate of complications arising in patients with Meckel’s diverticuli has been estimated to be approximately 4% to 6%.61,62 Although initial data had suggested that the risk of developing a complication related to Meckel’s diverticulum decreases with age, this has been ques-tioned. In a population-based reviews at Olmsted County, Cullen and colleagues suggested that the risk of developing Meckel’s diverticulum–related complications does not change with age.62The most common presentations associated with symp-tomatic Meckel’s diverticuli are bleeding, intestinal obstruction, and diverticulitis. Bleeding is the most common presentation in children with Meckel’s diverticuli, representing over 50% of Meckel’s diverticulum-related complications among patients less than 18 years of age. Bleeding associated with Meckel’s diverticuli is rare among patients older than 30 years of age.Intestinal obstruction is the most common presentation in adults with Meckel’s diverticuli. Diverticulitis, present in 20% of patients with symptomatic Meckel’s diverticuli, is associated with a clinical syndrome that is indistinguishable from acute appendicitis. Neoplasms, most commonly carcinoid tumors, are present in 0.5% to 3.2% of symptomatic Meckel’s diverticuli that are resected.DiagnosisMost Meckel’s diverticuli are discovered incidentally on radio-graphic imaging, during endoscopy, or at the time of surgery. In the absence of bleeding, Meckel’s diverticuli rarely are diag-nosed prior to the time of surgical intervention. For those pre-senting with symptoms suggestive of a Meckel’s diverticulum, confirmatory imaging can be challenging. The sensitivity of CT scanning for the detection of Meckel’s diverticuli is too low to be clinically useful. Enterocolysis is associated with an accuracy of 75% but is usually not applicable during acute presentations of complications related to Meckel’s diverticuli. Radionuclide scans (99MTc–pertechnetate) can be helpful in the diagnosis of Meckel’s diverticulum; this test is, however, positive only when the diverticulum contains associated ectopic gastric mucosa that is capable of uptake of the tracer (Fig. 28-28). The accuracy of radionuclide scanning is reported to be 90% in pediatric patients but less than 50% in adults. Angiography can localize the site of bleeding during acute hemorrhage related to Meckel’s diverticuli.Brunicardi_Ch28_p1219-p1258.indd 124723/02/19 2:24 PM 1248SPECIFIC CONSIDERATIONSPART IIFigure 28-28. Meckel’s diverticulum with ectopic gastric tissue. The diagnosis was made in this patient using 99MTc–pertechnetate scintig-raphy. The study revealed an abnormal focus of radiotracer accumulation in the right lower quadrant (arrow).TherapyThe surgical treatment of symptomatic Meckel’s diverticuli should consist of diverticulectomy with removal of associated bands connecting the diverticulum to the abdominal wall or intestinal mesentery. If the indication for diverticulectomy is bleeding, segmental resection of ileum that includes both the diverticulum and the adjacent ileal peptic ulcer should be per-formed. Segmental ileal resection may also be necessary if the diverticulum contains a tumor or if the base of the diverticulum is inflamed or perforated.The management of incidentally found (asymptomatic) Meckel’s diverticuli is controversial. Until recently, most authors recommended against prophylactic removal of asymptomatic Meckel’s diverticuli, given the low lifetime incidence of com-plications. Supporting this approach, a meta-analysis has shown that 758 prophylactic diverticulectomies needed to be performed to prevent one Meckel’s-related death.63 Others have had greater enthusiasm for prophylactic diverticulectomy has appeared in the literature.64 Proponents of this approach cite the minimal mor-bidity associated with removing Meckel’s diverticuli and the possibility that previous estimates of the lifetime incidence of complications related to Meckel’s diverticuli may be erroneously low. Many have advocated a selective approach, with a recom-mendation to remove diverticuli in patients younger than 50 years of age, or those with band attachments, those with ectopic tissue, or those >2 cm in length on the assumption that these diverticuli are more likely to develop complications. No controlled data sup-porting or refuting these recommendations exist.ACQUIRED DIVERTICULAAcquired diverticuli are designated false diverticuli because their walls consist of mucosa and submucosa but lack a com-plete muscularis. Acquired diverticuli are more common in the duodenum, and tend to be located near the ampulla; such diverticuli are known as periampullary, juxtapapillary, and perivaterian diverticuli. Approximately 75% of juxtapapillary diverticuli arise on the medial wall of the duodenum. Acquired diverticuli in the jejunum or ileum are known as jejunoileal diverticuli. Eighty percent of jejunoileal diverticuli are localized to the jejunum, 15% to the ileum, and 5% to both jejunum and ileum. Diverticuli in the jejunum tend to be large and accom-panied by multiple other diverticuli, whereas those in the ileum tend to be small and solitary.The prevalence of duodenal diverticuli, as detected on upper GI examinations (Fig. 28-29), has been reported to range from 0.16% to 6%.65 Their prevalence, as detected during ERCP examinations, has been reported to range from 5% to 27%. A 23% prevalence rate has been reported in an autopsy series. The prevalence of duodenal diverticuli increases with age; they are Brunicardi_Ch28_p1219-p1258.indd 124823/02/19 2:24 PM 1249SMALL INTESTINECHAPTER 28Figure 28-29. Duodenal diverticulum. This contrast radiograph demonstrates a duodenal diverticulum (arrows) that extends medially into the substance of the head of the pancreas.Figure 28-30. Jejunoileal diverticuli. This picture demonstrates incidental jejunal diverticuli identified during a laparoscopic cholecystectomy. The diverticuli are typically located on the mesenteric aspect of the jejunum. Resection was not indicated as the diverticuli were asymptomatic.rare in patients under the age of 40 years. The mean age of diagnosis ranges from 56 to 76 years.The prevalence of jejunoileal diverticuli (Fig. 28-30) has been estimated to range from 1% to 5%.66 Their prevalence increases with age; most patients diagnosed with these diver-ticuli are in the sixth and seventh decades of life.PathophysiologyThe pathogenesis of acquired diverticuli is hypothesized to be related to acquired abnormalities of intestinal smooth muscle or dysregulated motility, leading to herniation of mucosa and submucosa through weakened areas of muscularis.Acquired diverticuli can be associated with bacterial over-growth, leading to vitamin B12 deficiency, megaloblastic anemia, malabsorption, and steatorrhea. Periampullary duodenal diver-ticuli have been described to become distended with intralumi-nal debris and to compress the common bile duct or pancreatic duct, thus causing obstructive jaundice or pancreatitis, respec-tively. Jejunoileal diverticuli can also cause intestinal obstruction through intussusception or compression of adjacent bowel.Brunicardi_Ch28_p1219-p1258.indd 124923/02/19 2:25 PM 1250SPECIFIC CONSIDERATIONSPART IIClinical PresentationAcquired diverticuli are asymptomatic unless associated com-plications arise. Such complications are estimated to occur in 6% to 10% of patients with acquired diverticuli and include intestinal obstruction, diverticulitis, hemorrhage, perforation, and malabsorption. Periampullary duodenal diverticuli may be associated with choledocholithiasis, cholangitis, recurrent pan-creatitis, and sphincter of Oddi dysfunction. However, a clear link between the presence of the diverticuli and the development of these conditions has not been demonstrated. Symptoms such as intermittent abdominal pain, flatulence, diarrhea, and consti-pation are reported to be present in 10% to 30% of patients with jejunoileal diverticuli. The relationship between these symp-toms and the presence of the diverticuli is similarly unclear.DiagnosisMost acquired diverticuli are discovered incidentally on radiographic imaging, during endoscopy, or at the time of surgery. On ultrasound and CT scanning, duodenal diverticuli may be mistaken for pancreatic pseudocysts and fluid collections, biliary cysts, and periampullary neoplasms. These lesions can be missed on endoscopy, particularly with forward-viewing endoscopes, and are best diagnosed on upper gastrointestinal radiographs. Enterocolysis is the most sensitive test for detecting jejunoileal diverticuli.TherapyAsymptomatic-acquired diverticuli should be left alone. Bacte-rial overgrowth associated with acquired diverticuli is treated with antibiotics. Other complications, such as bleeding and diverticulitis, are treated with segmental intestinal resection for diverticuli located in the jejunum or ileum.Bleeding and obstruction related to lateral duodenal diverticuli are generally treated with diverticulectomy alone. Treatment of such complications in medial duodenal diverticuli that penetrate the substance of the pancreas can be very challenging. Complications related to these medial duodenal diverticuli should be managed nonoperatively if possible, using endoscopy. In emergent situations, bleeding related to medial duodenal diverticuli can be controlled using a lateral duodenotomy and oversewing of the bleeding vessel. Similarly, perforation can be managed with wide drainage rather than complex surgery. Whether diverticulectomy should be done in patients with biliary or pancreatic symptoms is controversial and is not routinely recommended.MESENTERIC ISCHEMIAMesenteric ischemia can present as one of two distinct clinical syndromes: acute mesenteric ischemia and chronic mesenteric ischemia.Four distinct pathophysiologic mechanisms can lead to acute mesenteric ischemia:1. Arterial embolus2. Arterial thrombosis3. Vasospasm (also known as nonocclusive mesenteric isch-emia or NOMI)4. Venous thrombosisEmbolus is the most common cause of acute mesen-teric ischemia and is responsible for over 50% of cases. The embolic source is usually in the heart, most often the left atrial or ventricular thrombi or valvular lesions. Indeed, up to 95% of patients with acute mesenteric ischemia due to emboli will have a documented history of cardiac disease. Embolism to the superior mesenteric artery accounts for 50% of cases; most of these emboli become wedged and cause occlusion at branch points in the midto distal superior mesenteric artery, usually distal to the origin of the middle colic artery. In contrast, acute occlusions due to thrombosis tend to occur in the proximal mes-enteric arteries, near their origins. Acute thrombosis is usually superimposed on preexisting atherosclerotic lesions at these sites. NOMI is the result of vasospasm and is usually diagnosed in critically ill patients receiving vasopressor agents.Mesenteric venous thrombosis accounts for 5% to 15% of cases of acute mesenteric ischemia and involves the supe-rior mesenteric vein in 95% of cases.67 The inferior mesenteric vein is only rarely involved. Mesenteric venous thrombosis is classified as primary if no etiologic factor is identifiable, or as secondary if an etiologic factor, such as heritable or acquired coagulation disorders, is identified.Regardless of the pathophysiologic mechanism, acute mes-enteric ischemia can lead to intestinal mucosal sloughing within 3 hours of onset and full-thickness intestinal infarction by 6 hours.In contrast, chronic mesenteric ischemia develops insidi-ously, allowing for development of collateral circulation, and, therefore, rarely leads to intestinal infarction. Chronic mesen-teric arterial ischemia results from atherosclerotic lesions in the main splanchnic arteries (celiac, superior mesenteric, and inferior mesenteric arteries). In most patients with symptoms attributable to chronic mesenteric ischemia, at least two of these arteries are either occluded or severely stenosed. A chronic form of mesenteric venous thrombosis can involve the portal or splenic veins and may lead to portal hypertension, with result-ing esophagogastric varices, splenomegaly, and hypersplenism.Severe abdominal pain, out of proportion to the degree of tenderness on examination is the hallmark of acute mesenteric ischemia, regardless of the pathophysiologic mechanism. The pain is typically perceived to be colicky and most severe in the mid-abdomen. Associated symptoms can include nausea, vomiting, and diarrhea. Physical findings are characteristically absent early in the course of ischemia. With the onset of bowel infarction, abdominal distension, peritonitis, and passage of bloody stools occur.Chronic mesenteric ischemia presents insidiously. Post-prandial abdominal pain is the most prevalent symptom, produc-ing a characteristic aversion to food (“food fear”) and weight loss. These patients are often thought to have a malignancy and suffer a prolonged period of symptoms before the correct diag-nosis is made.Most patients with chronic mesenteric venous thrombosis are asymptomatic because of the presence of extensive collat-eral venous drainage routes; this condition is usually discovered as an incidental finding on imaging studies. However, some patients with chronic mesenteric venous thrombosis present with bleeding from esophagogastric varices.The diagnosis and management of these disorders, which are of primary vascular origin, are discussed in the section on “Mesen-teric Artery Occlusive Disease” in Chapter 23 “Arterial Disease.”MISCELLANEOUS CONDITIONSObscure GI BleedingUp to 90% of lesions responsible for GI bleeding are within the reach of EGD and colonoscopy. Obscure GI bleeding refers to gastrointestinal bleeding for which no source has been identified by routine endoscopic studies (EGD and colonoscopy). Overt Brunicardi_Ch28_p1219-p1258.indd 125023/02/19 2:25 PM 1251SMALL INTESTINECHAPTER 28GI bleeding refers to the presence of hematemesis, melena, or hematochezia. In contrast, occult GI bleeding occurs in the absence of overt bleeding and is identified on laboratory tests (e.g., iron-deficiency anemia) or examination of the stool (e.g., positive guaiac test). Obscure GI bleeding is occult in 20% of cases.68Obscure bleeding can be frustrating for both the patient and the clinician, and this is particularly true for obscure-overt bleeding, which cannot be localized despite aggressive diag-nostic measures. Most of the small bowel is beyond the reach of these examinations and, hence, contains most lesions respon-sible for obscure GI bleeding. Small intestinal angiodysplasias account for approximately 75% of cases in adults, and neo-plasms account for approximately 10%. Meckel’s diverticulum is the most common etiology of obscure GI bleeding in children. Other etiologies of obscure GI bleeding include Crohn’s dis-ease, infectious enteritides, nonsteroidal anti-inflammatory drug (NSAID)-induced ulcers and erosions, vasculitis, ischemia, var-ices, diverticuli, and intussusception.The diagnostic evaluation of patients with obscure GI bleeding should be tailored to the severity to bleeding and to the availability of technology and expertise. Enteroscopy is playing an increasingly important role. Several endoscopic techniques for visualizing the small intestine are available: push enteros-copy, sonde enteroscopy, intraoperative enteroscopy, double balloon endoscopy, and wireless capsule enteroscopy.Push enteroscopy entails advancing a long endoscope (such as a pediatric or adult colonoscope or a specialized instru-ment) beyond the ligament of Treitz into the proximal jejunum. This procedure can allow for visualization of approximately 60 cm of the proximal jejunum. Diagnostic yield in patients with obscure GI bleeding ranges from 3% to 65%. In addition to diagnosis, push enteroscopy allows for cauterization of bleed-ing sites.In Sonde enteroscopy, a long, thin fiberoptic instrument is propelled through the intestine by peristalsis following infla-tion of a balloon at the instrument’s tip. Visualization is done during instrument withdrawal; approximately 50% to 75% of the small intestinal mucosa can be examined. However, this instrument lacks biopsy or therapeutic capability. Further, it lacks tip deflection capability, limiting complete mucosal visu-alization, and has therefore been abandoned in favor of capsule endoscopy.Wireless capsule enteroscopy is an excellent tool in the patient who is hemodynamically stable but continues to bleed. This technique has reported success rates as high as 90% in identifying a small bowel pathology. In a randomized study of patients with obscure GI bleeding, evaluation with capsule endoscopy vs. small bowel contrast study had a much higher diagnostic yield (30% vs. 7%, respectively); however, this did not translate into an improvement in outcomes. The rates of rebleeding, hospitalization, need for blood transfusion, and therapeutic interventions were similar between the two arms.The inability to perform biopsies or carry out any thera-peutic interventions of capsule endoscope likely prevents the improved diagnostic yield of the test from translating into improved patient outcomes and highlights the continuing chal-lenge with evaluation of the small bowel.69For patients in whom bleeding from an obscure GI source has apparently stopped, push enteroscopy or capsule enteroscopy is a reasonable initial study. If these examinations do not reveal a potential source of bleeding, then enterocolysis should be performed. Standard small bowel follow-through examinations are associated with a low diagnostic yield in this setting and should be avoided. 99MTc–pertechnetate scintigraphy to diagnose Meckel’s diverticulum should be considered, although its yield in patients older than 40 years of age is extremely low. If still no diagnosis has been made, a “watch-and-wait” approach is reasonable, although angiography should be considered if the episode of bleeding was overt. Angiography can reveal angiodysplasia and vascular tumors in the small intestine even in the absence of ongoing bleeding. In many instances, however, angiography is done in patients with persistent bleeding from an obscure GI source, and it is also often performed after a 99MTc-labeled RBC scan, which, if positive, is followed by angiography to localize the source of bleeding. Patients who remain undiagnosed but continue to bleed and those with recurrent episodic bleeding significant enough to require blood transfusions should then undergo exploratory laparoscopy or laparotomy with intraoperative enteroscopy. An endoscope (usually a colonoscope) is inserted into the small bowel through peroral intubation or through an enterotomy made in the small bowel or cecum. The endoscope is advanced by successively telescoping short segments of intestine onto the end to the instrument. In addition to the endoscopic image, the transilluminated bowel should be examined externally with the operating room lights dimmed, as this maneuver may facilitate the identification of angiodysplasias. Identified lesions should be marked with a suture placed on the serosal surface of the bowel; these lesions can be resected after completion of endoscopy. Examination should be performed during instrument insertion rather than withdrawal because instrument-induced mucosal trauma can be confused with angiodysplasias.Figure 28-31 provides a diagnostic and management algo-rithm for patients with obscure GI bleeding.Small Bowel PerforationPrior to the 1980s, duodenal perforation due to peptic ulcer dis-ease was the most common form of small bowel perforation. Today, iatrogenic injury incurred during gastrointestinal endos-copy is the most common cause of small bowel perforation. Other etiologies of small bowel perforation include infections (especially tuberculosis, typhoid, and CMV), Crohn’s disease, ischemia, drugs (e.g., potassiumand NSAID-induced ulcers), radiation-induced injury, Meckel’s and acquired diverticuli, neoplasms (especially lymphoma, adenocarcinoma, and mela-noma), and foreign bodies.Among iatrogenic injuries, duodenal perforation dur-ing endoscopic retrograde cholangiography (ERCP) with endoscopic sphincterotomy (ES) is the most common. With improved technique and technology, the incidence of this is decreasing but remains at around 0.5%.70 The Stapfer classifi-cation is commonly used to categorize different types of ERCP-related perforations. These are:• Type I: Free bowel wall perforation• Type II: Retroperitoneal duodenal perforation secondary to periampullary injury• Type III: Perforation of the pancreatic or bile duct• Type IV: Retroperitoneal air aloneType II (retroperitoneal duodenal injuries) are the most common and can often be managed nonsurgically. Manifesta-tions of such contained duodenal perforation following ERCP can resemble those of ERCP-induced pancreatitis, including hyperamylasemia.Brunicardi_Ch28_p1219-p1258.indd 125123/02/19 2:25 PM 1252SPECIFIC CONSIDERATIONSPART IICT scanning is the most sensitive test for diagnosing duo-denal perforations; positive findings include pneumoperitoneum for free perforations, but more commonly retroperitoneal air, contrast extravasation, and paraduodenal fluid collections. If all patients undergoing a therapeutic ERCP are imaged with a CT scan following the procedure, up to 30% will have evidence of air in the retroperitoneum, but the majority are asymptomatic. These patients do not require any specific therapy.71True cases of retroperitoneal perforations of the duodenum can be managed nonoperatively in the absence of progression and sepsis. However, intraoperitoneal duodenal perforations require surgical repair with pyloric exclusion and gastrojeju-nostomy or tube duodenostomy. Iatrogenic small bowel perfora-tion incurred during endoscopy, if immediately recognized, can sometimes be repaired using endoscopic techniques.Perforation of the jejunum and ileum occurs into the peri-toneal cavity and usually causes overt symptoms and signs, such as abdominal pain, tenderness, and distention accompa-nied by fever and tachycardia. Plain abdominal radiographs may reveal free intraperitoneal air if intraperitoneal perforation has occurred. If perforation is suspected but not clinically obvious, CT scanning should be performed. Jejunal and ileal perforations require surgical repair or segmental resection.Chylous AscitesChylous ascites refers to the accumulation of triglyceride-rich peritoneal fluid with a milky or creamy appearing, caused by the presence of intestinal lymph in the peritoneal cavity. Chy-lomicrons, produced by the intestine and secreted into lymph during the absorption of long-chain fatty acids, account for the characteristic appearance and triglyceride content of chyle.The most common etiologies of chylous ascites in Western countries are abdominal malignancies and cirrhosis. In Eastern and developing countries, infectious etiologies, such as tuber-culosis and filariasis, account for most cases. Chylous ascites can also develop as a complication of abdominal and thoracic operations and trauma. Operations particularly associated with this complication include abdominal aortic aneurysm repair, retroperitoneal lymph node dissection, inferior vena cava resec-tion, and liver transplantation. Other etiologies of chylous asci-tes include congenital lymphatic abnormalities (e.g., primary lymphatic hypoplasia), radiation, pancreatitis, and right-sided heart failure.Three mechanisms have been postulated to cause chylous ascites: (a) exudation of chyle from dilated lymphatics on the wall of the bowel and in the mesentery caused by obstruction of lymphatic vessels at the base of the mesentery or the cisterna chili (e.g., by malignancies), (b) direct leakage of chyle through a lymphoperitoneal fistula (e.g., those that develop as a result of trauma or surgery), and (c) exudation of chyle through the wall of dilated retroperitoneal lymphatic vessels (e.g., in congenital lymphangiectasia or thoracic duct obstruction).Patients with chylous ascites develop abdominal distention over a period of weeks to months. Postoperative chylous ascites can present acutely during the first postoperative week. Delayed presentations following surgery can occur if the mechanism of ascites formation is adhesion-induced lymphatic obstruction rather than lymphatic vessel disruption.Obscure gastrointestinal bleedingRule out upper and lower GIbleeding;EGD and colonoscopyMinor bleeding(intermittent)Major bleeding(persistent)Initiate appropriatetherapyRepeat EGD/Colonoscopy ifrebleedsTreat source, e.g.,small bowelresectionLocalize bleeding:Serial clamping or intraoperativeenteroscopy followed by resectionPositivePositiveNegativeUnstableStableTaggedRBC scanNegativeandpatient stableSource ofbleeding identifiedSourceuncertainAngiographyand treatmentOperatingroomEnteroclysisEnteroscopyCapsuleendoscopyFigure 28-31. Diagnostic and management algorithm for obscure gastrointestinal bleeding.Brunicardi_Ch28_p1219-p1258.indd 125223/02/19 2:25 PM 1253SMALL INTESTINECHAPTER 28Paracentesis is the most important diagnostic test. Chyle typically has a cloudy and turbid appearance; however, it may be clear in fasting patients (such as those in the immediate postoperative period). Fluid triglyceride concentrations above 110 mg/dL are diagnostic. CT scanning may be useful in identifying pathological intraabdominal lymph nodes and masses and in identifying extent and localization of fluid. Lymphangiography and lymphoscintigraphy may help localize lymph leaks and obstruction; this information is particularly useful for surgical planning.There is little data on optimal management of patients with chylous ascites. The general approach is to focus on evaluating and treating the underlying causes, especially for patients with infec-tious, inflammatory, or hemodynamic etiologies for this condition.Most patients respond to administration of a high-protein and low-fat diet supplemented with medium-chain triglycerides. This regimen is designed to minimize chyle production and flow. Medium-chain triglycerides are absorbed by the intestinal epithelium and are transported to liver through the portal vein; they do not contribute to chylomicron formation.Patients who do not respond to this approach should be fasted and placed on TPN. Octreotide can further decrease lymph flow. Paracentesis is indicated for respiratory difficul-ties related to abdominal distention. Overall, two-thirds of patients will respond to conservative therapy. However, one-third of patients will require surgical therapy for chylous ascites. In general, postoperative and trauma-related cases that fail to respond to initial nonoperative therapy are best managed by surgical repair. Lymphatic leaks are localized and repaired with fine nonabsorbable sutures. If extravasation of chyle is localized to the periphery of the small bowel mesentery, then a limited small bowel resection can be performed instead. For patients who are poor surgical candidates and who do not respond to prolonged conservative therapy, peritoneovenous shunting may be an option. However, these shunts are associated with high rates of complications, including sepsis and disseminated intra-vascular coagulation. Because of the viscosity of chyle, these shunts are associated with a high occlusion rate.IntussusceptionIntussusception refers to a condition where one segment of the intestine becomes drawn in to the lumen of the distal segment of the bowel. It is usually seen in the pediatric population, where the ileum intussuscepts into the cecum (ileocolic intussuscep-tion). In children, it is often an idiopathic condition and treated nonsurgically by radiological reduction.Intussusceptions are far less common and usually have a distinct pathologic lead point, which can be malignant in up to one-half of cases.72 They commonly present with a history of intermittent abdominal pain and signs and symptoms of bowel obstruction. CT scan is the investigation of choice, where a “tar-get sign” may be seen (Fig. 28-32). Treatment is surgical resec-tion of the involved segment and the lead point, which needs to undergo pathological evaluation to rule out an underlying malignancy.With increasing use of CT imaging, target signs are some-times seen on CT scans of patients who do not have a clinical presentation indicative of bowel obstruction. In such cases, the finding is of little clinical significance and is probably related to normal peristalsis.In patients who have undergone a Roux-en-Y gastric bypass surgery, an atypical form of intussusception has been increasingly described. In these cases, the distal bowel is drawn in to the lumen of the proximal bowel (retrograde intussuscep-tion). These intussusceptions are usually not associated with a lead point and may represent a motility disorder of the bowel following the Roux-en-Y reconstruction. Surgical reductions without resection have been successfully reported in these patients.73Pneumatosis IntestinalisPneumatosis intestinalis indicates the presence of gas within the bowel wall. It may affect any region of the GI tract, but it is most commonly seen in the jejunum. Pneumatosis intestinalis is not a disease but merely a sign that can be idiopathic or associated with many intestinal or nonintestinal disorders, such as obstruc-tive pulmonary disease and asthma. Most cases of pneumatosis intestinalis are secondary to an identifiable cause, and 15% are idiopathic. The pathogenesis of pneumatosis intestinalis is not fully understood.The surgical interest in this finding is the association of it with bowel ischemia and infarction, both of which necessitate emergent surgical intervention (Fig. 28-33). Thus, patients with this radiological finding need to be fully evaluated and moni-tored closely to rule out such intraabdominal catastrophes.ABFigure 28-32. Small bowel intussusception. A. Target sign seen on CT scans in patients with small bowel intussusception (arrow). B. The distal bowel is clearly within the lumen of the proximal bowel (arrow).Brunicardi_Ch28_p1219-p1258.indd 125323/02/19 2:25 PM 1254SPECIFIC CONSIDERATIONSPART IISHORT BOWEL SYNDROMEIntestinal resection is performed for many of the diseases dis-cussed in this chapter and generally is associated with minimal morbidity. However, when extent of resection is great enough, a devastating condition known as short bowel syndrome may result. Although the best definition of short bowel syndrome is likely a functional one, reflecting a state of significant malabsorption of both macronutrients and micronutrients, some have used a more anatomical definition with it being arbi-trarily defined as the presence of less than 200 cm of residual small bowel in adult patients.74In adults, the most common etiologies of short bowel syn-drome are acute mesenteric ischemia, malignancy, and Crohn’s disease. Seventy-five percent of cases result from resection of a large amount of small bowel at a single operation. Twenty-five percent of cases result from the cumulative effects of multiple operations during which small intestine is resected. This latter pattern is typical of patients with Crohn’s disease who develop short bowel syndrome; the former is typical of patients with acute mesenteric ischemia who develop intestinal infarction. In pediat-ric patients, intestinal atresias, volvulus, and necrotizing entero-colitis are the most common etiologies of short bowel syndrome.The prevalence of short bowel syndrome is hard to esti-mate due to its multifactorial nature and wide spectrum of presentation and treatment, which may include home total par-enteral nutrition (TPN).PathophysiologyResection of less than 50% of the small intestine is generally well tolerated. However, clinically significant malabsorption occurs when greater than 50% to 80% of the small intestine has been resected. Among adult patients who lack a functional colon, lifelong TPN dependence is likely to persist if there is less than 100 cm of residual small intestine. Among adult patients who have an intact and functional colon, lifelong TPN dependence is likely to persist if there is less than 60 cm of residual small intestine. Among infants with short bowel syn-drome, weaning from TPN-dependence has been achieved with as little as 10 cm of residual small intestine.Residual bowel length is not the only factor predictive of achieving independence from TPN (enteral autonomy), 5Figure 28-33. STEP procedure. This illustration depicts the serial transverse enteroplasty (STEP) procedure. Lengthening of dilated small intestine is accomplished by serial applications of an intestinal stapling device, with firings oriented perpendicular to the long axis of the intestine. (Used with permission from Patrick Javid, M.D. and Tom Jaksic, M.D., Department of Surgery, Children’s Hospital, Boston, MA.)Table 28-11Risk factors for development of short bowel syndrome after massive small bowel resectionSmall bowel length <200 cmAbsence of ileocecal valveAbsence of colonDiseased remaining bowel (e.g., Crohn’s disease)Ileal resectionhowever. Other determinants of the severity of malabsorption include the presence or absence of an intact colon, as indicated previously. The colon has the capacity to absorb large fluid and electrolyte loads. In addition, the colon can play an important, albeit small, role in nutrient assimilation by absorbing short chain fatty acids. Second, an intact ileocecal valve is believed to be associated with decreased malabsorption. The ileocecal valve delays transit of chyme from the small intestine into the colon, thereby prolonging the contact time between nutrients and the small-intestinal absorptive mucosa. Third, healthy, rather than diseased, residual small intestine is associated with decreased severity of malabsorption. Fourth, resection of jejunum is better tolerated than resection of ileum, as the capacity for bile salt and vitamin B12 absorption is specific to the ileum (Table 28-11).During the first 1 to 2 years following massive small bowel resection, the remaining intestine undergoes compensa-tory adaptation, as discussed previously. Clinically, the period of adaptation is associated with reductions in volume and fre-quency of bowel movements, increases in the capacity for enteral nutrient assimilation, and reductions in TPN requirements. As this process completes, some patients are successfully weaned off TPN. Understanding the mechanisms mediating intestinal adaptation may suggest strategies for enhancing adaptation in patients with short bowel syndrome who are unable to achieve independence from TPN. To date, the phenomenon of intestinal adaptation in patients remains poorly understood.13Malabsorption in patients who have undergone mas-sive small bowel resection is exacerbated by a characteristic hypergastrinemia-associated gastric acid hypersecretion that persists for 1 to 2 years postoperatively. The increased acid Brunicardi_Ch28_p1219-p1258.indd 125423/02/19 2:25 PM 1255SMALL INTESTINECHAPTER 28load delivered to the duodenum inhibits absorption by a variety of mechanisms, including the inhibition of digestive enzymes, most of which function optimally under alkaline conditions.TherapyMedical Therapy. For patients after massive small bowel resection, the initial treatment priorities include management of the primary condition precipitating the intestinal resection and the repletion of fluid and electrolytes lost in the severe diarrhea that characteristically occurs. Most patients will require TPN, at least initially. Enteral nutrition should be gradually introduced, once ileus has resolved. High-dose histamine-2 receptor antago-nists or proton pump inhibitors should be administered to reduce gastric acid secretion. Antimotility agents, such as loperamide hydrochloride or diphenoxylate, may be administered to delay small-intestinal transit. Octreotide can be administered to reduce the volume of gastrointestinal secretions, although, in animal models, its use is associated with an inhibition of intestinal adaptation.During the period of adaptation, generally lasting 1 to 2 years postoperatively, TPN and enteral nutrition are titrated to allow for independence from TPN. Patients who remain dependent on TPN face substantial TPN-associated morbidities including catheter sepsis, venous thrombosis, liver and kidney failure, and osteoporosis. Liver failure is a significant source of morbidity and often leads to liver transplantation (always in combination with small bowel transplantation). Due to these complications, patients with short bowel syndrome on TPN have a reduced life expectancy, with 5-year survival rates of 50% to 75%.Nontransplant Surgical Therapy. Among patients with sto-mas, restoration of intestinal continuity should be performed whenever possible, to capitalize on the absorptive capacity of all residual intestine. Other forms of nontransplant surgery designed to improve intestinal absorption are associated with unclear efficacy and/or substantial morbidities and therefore should not be applied routinely.The goal of these operations is to increase nutrient and fluid absorption by either slowing intestinal transit or increasing intestinal length. Operations designed to slow intestinal transit include segmental reversal of the small bowel, interposition of a segment of colon between segments of small bowel, construc-tion of small-intestinal valves, and electrical pacing of the small intestine. Reported experience with these procedures is limited to case reports or series of a few cases. Objective evidence of increased absorption is lacking; further, these procedures are frequently associated with intestinal obstruction.The intestinal lengthening operation for which has the lon-gest history is the longitudinal intestinal lengthening and tailor-ing (LILT) procedure, first described by Bianchi in 1980.75 The procedure entails separation of the dual vasculature of the small intestine, followed by longitudinal division of the bowel with subsequent isoperistaltic end-to-end anastomosis. This proce-dure has the potential to double the length of small intestine to which it is applied. This procedure has generally been used for pediatric patients with dilated residual small bowel.An alternative surgical approach to lengthening the small bowel is the serial transverse enteroplasty procedure (STEP) has been described. This procedure is designed to accom-plish lengthening of dilated small intestine without the need for separating its dual vasculature (Fig. 28-33). A report from an international registry of 111 patients showed that 47% of patients achieved enteral autonomy at a median follow-up of 21 months.76Intestinal Transplantation. This complex procedure is being increasingly performed to treat patients with short bowel syn-drome. The currently accepted indication for intestinal trans-plantation is the presence of life-threatening complications attributable to intestinal failure and/or long-term TPN therapy. Specific complications for which intestinal transplantation is indicated include (a) impending or overt liver failure, (b) throm-bosis of major central veins, (c) frequent episodes of catheter-related sepsis, and (d) frequent episodes of severe dehydration.Of the transplants involving the intestine, 37% were intestine-alone transplants, 30% included intestine, liver, and pancreas, and 24% were intestine and liver.77Isolated intestinal transplantation is used for patients with intestinal failure who have no significant liver disease or failure of other organs. Combined intestine/liver transplantation is used for patients with both intestinal and liver failure. Multivisceral transplantation has been used for patients with giant desmoid tumors involving the vascular supply of the liver and pancreas as well as that of the intestine, for diffuse gastrointestinal motil-ity disturbances, and for diffuse splanchnic thrombosis.Nearly 80% of survivors have full intestinal graft function with no need for TPN. However, morbidities associated with intestinal transplantation are substantial and include acute and chronic rejection, CMV infection, and posttransplant lymphop-roliferative disease.Alternative Therapies. Pharmacologic and biologic thera-pies designed to expand intestinal mucosal surface area or to enhance the efficiency of intestinal absorption are beginning to undergo clinical evaluation. Promising regimens include GLP-2 and the combination of glutamine and growth hormone with a modified, high-carbohydrate diet.OutcomesApproximately 50% to 70% of patients with short bowel syn-drome who initially require TPN are ultimately able to achieve independence from TPN.73 Prognosis for achieving enteral autonomy is better among pediatric patients than among adults.Information on survival among patients with short bowel syndrome is limited. In a recently reported study of 124 adults with short bowel syndrome due to nonmalignant etiologies, the survival rates at 2 and 5 years of follow up were 86% and 45%, respectively.77 Patients with end-enterostomies and those hav-ing less than 50 cm of residual small intestine had significantly worse survivals than those without these features.No randomized trials comparing intestinal transplanta-tion to chronic TPN administration among patients with short bowel syndrome have been reported. One-, 5-, and 10-year graft survival rates of intestine-alone recipients were 80%, 44%, and 26%; while those for intestine and liver and intestine, liver, and pancreas were 62%, 45%, 36% and 69%, 48%, 33%, respectively.78REFERENCESEntries highlighted in bright blue are key references. 1. Tavakkolizadeh A, Whang EE, Ashley SW, Zinner MJ. Small intestine. In: Brunicardi F, Andersen D, Billiar T, et al, eds. Principles of Surgery. 9th ed. New York: McGraw-Hill; 2004:28-1 to 28-32. 2. McMinn RMH. Last’s Anatomy: Regional and Applied. 9th ed. Singapore: Churchill Livingstone; 1994:337.Brunicardi_Ch28_p1219-p1258.indd 125523/02/19 2:25 PM 1256SPECIFIC CONSIDERATIONSPART II 3. Yan KS, Chia LA, Li X, et al. The intestinal stem cell markers Bmi1 and Lgr5 identify two functionally distinct populations. Proc Natl Acad Sci U S A. 2012;109:466-471. 4. Thomson ABR, Keelan M, Thiesen A, et al. Small bowel review: normal physiology part 2. Dig Dis Sci. 2001;46: 2567-2587. 5. Laforenza U. Water channel proteins in the gastrointestinal tract. Mol Aspects Med. 2012;33:642-650. 6. Dyer J, Wood IS, Palejwala A, Ellis A, Shirazi-Beechy SP. Expression of monosaccharide transporters in intestine of diabetic humans. Am J Physiol. 2002;282:G241-G248. 7. Rubino F, Nathan DM, Eckel RH, et al; Delegates of the 2nd Diabetes Surgery Summit. Metabolic surgery in the treatment algorithm for type 2 diabetes: a joint statement by international diabetes organizations. Diabetes Care. 2016; 39(6):861-877. 8. Rolfs A, Hediger MA. Intestinal metal ion absorption: an update. Curr Opin Gastroenterol. 2001;17:177-183. 9. Nagler-Anderson C. Man the barrier! Strategic defenses in the intestinal mucosa. Nat Rev Immunol. 2001;1:59-67. 10. Mowat AM. Anatomical basis of tolerance and immunity to intestinal antigens. Nat Rev Immunol. 2003;3:331-341. 11. Jarchum I, Pamer EG. Regulation of innate and adaptive immunity by the commensal microbiota. Curr Opin Immunol. 2011;23:353-360. 12. Rehfeld JF. The new biology of gastrointestinal hormones. Physiol Rev. 1998;78(4):1087-1108. 13. Tavakkolizadeh A, Whang EE. Understanding and augmenting human intestinal adaptation: a call for more clinical research. JPEN J Parenter Enteral Nutr. 2002;26:251-255. 14. Scott FI, Osterman MT, Mahmoud NN, Lewis JD. Secular trends in small-bowel obstruction and adhesiolysis in the United States: 1988-2007. Am J Surg. 2012;204(3):315-320. 15. Scott JW, Olufajo OA, Brat GA, et al. Use of national burden to define operative emergency general surgery. JAMA Surg. 2016;151(6):e160480. 16. Ceresoli M, Coccolini F, Catena F, et al. Water-soluble contrast agent in adhesive small bowel obstruction: a systematic review and meta-analysis of diagnostic and therapeutic value. Am J Surg. 2016;211(6):1114-1125. 17. Rocha FG, Theman TA, Matros E, Ledbetter SM, Zinner MJ, Ferzoco SJ. Nonoperative management of patients with a diagnosis of high-grade small bowel obstruction by computed tomography. Arch Surg. 2009;144(11):1000-1004. 18. Chu DI, Gainsbury ML, Howard LA, Stucchi AF, Becker JM. Early versus late adhesiolysis for adhesive-related intestinal obstruction: a nationwide analysis of inpatient outcomes. J Gastrointest Surg. 2013;17:288-297. 19. Lombardo S, Baum K, Filho JD, Nirula R. Should adhesive small bowel obstruction be managed laparoscopically? A National Surgical Quality Improvement Program propensity score analysis. J Trauma Acute Care Surg. 2014;76(3):696-703. 20. Wiggins T, Markar SR, Harris A. Laparoscopic adhesiolysis for acute small bowel obstruction: systematic review and pooled analysis. Surg Endosc. 2015;29(12):3432-3442. 21. Duron J, Jourdan-Da Silva N, Tezenas du Montcel S, et al. Adhesive postoperative small bowel obstruction: incidence and risk factors of recurrence after surgical treatment: a multicenter prospective study. Ann Surg. 2006;244(5):750-757. 22. Wahl WL, Wong SL, Sonnenday CJ, et al. Implementation of a small bowel obstruction guideline improves hospital efficiency. Surgery. 2012;152:626-632. 23. Ellis H, Moran BJ, Thompson JN, et al. Adhesion-related hospital readmissions after abdominal and pelvic surgery: a retrospective cohort study. Lancet. 1999;353:1476-1480. 24. Angenete E, Jacobsson A, Gellerstedt M, Haglind E. Effect of laparoscopy on the risk of small-bowel obstruction: a population-based register study. Arch Surg. 2012;147(4):359-365. 25. Fazio VW, Cohen Z, Fleshman JW, et al. Reduction in adhesive small-bowel obstruction by Seprafilm adhesion barrier after intestinal resection. Dis Colon Rectum. 2006; 49(1):1-11. 26. Kumar S, Wong PF, Leaper DJ. Intra-peritoneal prophylactic agents for preventing adhesions and adhesive intestinal obstruction after non-gynaecological abdominal surgery. Cochrane Database Syst Rev. 2009;(1):CD005080. 27. Suwa K, Ushigome T, Ohtsu M, et al. Risk factors for early postoperative small bowel obstruction after anterior resection for rectal cancer. World J Surg. 2018;42(1):233-238. 28. Dalal KM, Gollub MJ, Miner TJ, et al. Management of patients with malignant bowel obstruction and stage IV colorectal cancer. J Palliat Med. 2011;14(7):822-828. 29. Doorly MG, Senagore AJ. Pathogenesis and clinical and economic consequences of postoperative ileus. Surg Clin North Am. 2012;92(2):259-272. 30. Vather R, Trivedi S, Bissett I. Defining postoperative ileus: results of a systematic review and global survey. J Gastrointest Surg. 2013;17(5):962-972. 31. Wolff BG, Viscusi ER, Delaney CP, Du W, Techner L. Patterns of gastrointestinal recovery after bowel resection and total abdominal hysterectomy: pooled results from the placebo arms of alvimopan phase III North American clinical trials. Am Coll Surg. 2007;205(1):43-51. 32. Gendall KA, Kennedy RR, Watson AJ, Frizelle FA. The effect of epidural analgesia on postoperative outcome after colorectal surgery. Colorectal Dis. 2007;9(7):584-598. 33. Noblett SE, Snowden CP, Shenton BK, Horgan AF. Randomized clinical trial assessing the effect of Doppler-optimized fluid management on outcome after elective colorectal resection. Br J Surg. 2006;93:1069-1076. 34. Tan EK, Cornish J, Darzi AW, Tekkis PP. Meta-analysis: alvimopan vs. placebo in the treatment of post-operative ileus. Aliment Pharmacol Ther. 2007;25(1):47-57. 35. Gaines SL, Giroux K, Thomas S, Gregory JS. Real world efficacy of alvimopan on elective bowel resection patients: an analysis of statistical versus clinical significance. Am J Surg. 2012;203(3):308-311. 36. Kappelman MD, Moore KR, Allen JK, Cook SF. Recent trends in the prevalence of Crohn’s disease and ulcerative colitis in a commercially insured US population. Dig Dis Sci. 2013;58(2):519-525. 37. Molodecky NA, Soon IS, Rabi DM, et al. Increasing incidence and prevalence of the inflammatory bowel diseases with time, based on systematic review. Gastroenterology. 2012;142(1):46-54. 38. Zheng JJ, Zhu XS, Huangfu Z, Gao ZX, Guo ZR, Wang Z. Crohn’s disease in mainland China: a systematic analysis of 50 years of research. Chin J Dig Dis. 2005;6(4):175-181. 39. Kaplan GG, Jackson T, Sands BE, Frisch M, Andersson RE, Korzenik J. The risk of developing Crohn’s disease after an appendectomy: a meta-analysis. Am J Gastroenterol. 2008;103(11):2925-2931. 40. Nikolaaus S, Schreiber S. Diagnosis of inflammatory bowel disease. Gastroenterology. 2007;133(5):1670-1689. 41. Frolkis AD, Dykeman J, Negrón ME, et al. Risk of surgery for inflammatory bowel diseases has decreased over time: a systematic review and meta-analysis of population-based studies. Gastroenterology. 2013;145(5):996-1006. 42. Fazio VW, Marchetti F, Church JM, et al. Effect of resection margins on the recurrence of Crohn’s disease of the small bowel. Ann Surg. 1996;224(4):563-571. 43. McLeod RS, Wolff BG, Ross S, Parkes R, McKenzie M. Recurrence of Crohn’s disease after ileocolic resection is not affected by anastomotic type: results of a multicenter, randomized, controlled trial. Dis Colon Rectum. 2009;52(5): 919-927.Brunicardi_Ch28_p1219-p1258.indd 125623/02/19 2:25 PM 1257SMALL INTESTINECHAPTER 28 44. Michelassi F, Upadhyay GA. Side-to-side isoperistaltic strictureplasty in the treatment of extensive Crohn’s disease. J Surg Res. 2004;117(1):71-78. 45. Tan JJ, Tjandra JJ. Laparoscopic surgery for Crohn’s disease: a meta-analysis. Dis Colon Rectum. 2007;50(5):576-585. 46. Delaney CP, Fazio VW. Crohn’s disease of the small bowel. Surg Clin North Am. 2001;81:137-158. 47. Penner RM, Madsen KL, Fedorak RN. Postoperative Crohn’s disease. Inflamm Bowel Dis. 2005;11:765-777. 48. Evenson AR, Shrikhande G, Fischer JE. Abdominal abscess and enteric fistula. In: Zinner MJ, Ashley SW, eds. Maingot’s Abdominal Operations. 11th ed. New York: McGraw Hill; 2007:184. 49. Coughlin S, Roth L, Lurati G, Faulhaber M. Somatostatin analogues for the treatment of enterocutaneous fistulas: a systematic review and meta-analysis. World J Surg. 2012;36(5):1016-1029. 50. Wainstein DE, Fernandez E, Gonzalez D, Chara O, Berkowski D. Treatment of high-output enterocutaneous fistulas with a vacuum-compaction device. A ten-year experience. World J Surg. 2008;32(3):430-435. 51. Fazio VW, Coutsoftides T, Steiger E. Factors influencing the outcome of treatment of small bowel cutaneous fistula. World J Surg. 1983;7:481-488. 52. Owen RM, Love TP, Perez SD, et al. Definitive surgical treatment of enterocutaneous fistula: outcomes of a 23-year experience. JAMA Surg. 2013;148(2):118-126. 53. Martinez JL, Luque-de-Leon E, Ballinas-Oseguera G, Mendez JD, Juarez-Oropeza MA, Roman-Ramos R. Factors predictive of recurrence and mortality after surgical repair of enterocutaneous fistula. J Gastrointest Surg. 2012;16(1):156-163. 54. Qubaiah O, Devesa SS, Platz CE, Huycke MM, Dores GM. Small intestinal cancer: a population-based study of incidence and survival patterns in the United States, 1992 to 2006. Cancer Epidemiol Biomarkers Prev. 2010;19:1908-1918. 55. Ceppa EP, Burbridge RA, Rialon KL, et al. Endoscopic versus surgical ampullectomy: an algorithm to treat disease of the ampulla of Vater. Ann Surg. 2013;257(2):315-322. 56. Judson I, Demetri G. Advances in the treatment of gastrointestinal stromal tumors. Ann Oncol. 2007;18:S20-S24. 57. Agrawal S, McCarron EC, Gibbs JF, Nava HR, Wilding GE, Rajput A. Surgical management and outcome in primary adenocarcinoma of the small bowel. Ann Surg Onc. 2007;14:2263-2269. 58. Girvent M, Carlson GL, Anderson I, et al. Intestinal failure after surgery for complicated radiation enteritis. Ann R Coll Surg Engl. 2000;82:198-201. 59. Kiliç D, Egehan I, Ozenirler S, Dursun A. Double-blinded, randomized, placebo-controlled study to evaluate the effectiveness of sulphasalazine in preventing acute gastrointestinal complications due to radiotherapy. Radiother Oncol. 2000;57:125-129. 60. Waddell BE, Lee RJ, Rodriguez-Bigas MA, Weber TK, Petrelli NJ. Absorbable mesh sling prevents radiation-induced bowel injury during “sandwich” chemoradiation for rectal cancer. Arch Surg. 2000;135:1212-1217. 61. Yahchouchy EK, Marano AF, Etienne JC, et al. Meckel’s diverticulum. J Am Coll Surg. 2001;192(5):654-662. 62. Cullen JJ, Kelly KA, Moir CR, et al. Surgical management of Meckel’s diverticulum. An epidemiologic, population-based study. Ann Surg. 1994;220(4):564-568. 63. Zani A, Eaton S, Rees CM, et al. Incidentally detected Meckel diverticulum: to resect or not to resect? Ann Surg. 2008;247:276-281. 64. Park JJ, Wolff BG, Tollefson MK, Walsh EE, Larson DR. Meckel diverticulum: the Mayo Clinic experience with 1476 patients (1950-2002). Ann Surg. 2005;241(3):529-533. 65. Lobo DN, Balfour TW, Iftikhar SY, et al. Periampullary diverticula and pancreaticobiliary disease. Br J Surg. 1999; 86:588-597. 66. Chow DC, Babaian M, Taubin HL. Jejunoileal diverticula. Gastroenterologist. 1997;5:78-84. 67. Kumar S, Sarr MG, Kamath PS: Mesenteric venous thrombosis. N Engl J Med. 2001;345:1683-1688. 68. Gralnek IM. Obscure-overt gastrointestinal bleeding. Gastroenterology. 2005;128:1424-1430. 69. Laine L, Sahota A, Shah A. Does capsule endoscopy improve outcomes in obscure gastrointestinal bleeding? Randomized trial versus dedicated small bowel radiography. Gastroenterology. 2010;138(5):1673-1680. 70. Andriulli A, Loperfido S, Napolitano G, et al. Incidence rates of post-ERCP complications: a systematic survey of prospective studies. Am J Gastroenterol. 2007;102(8):1781-1788. 71. Genzlinger JL, McPhee MS, Fisher JK, et al. Significance of retroperitoneal air after endoscopic retrograde cholangiopancreatography with sphincterotomy. Am J Gastroenterol. 1999;94(5):1267-1270. 72. Varban O, Ardestani A, Azagury D, Kis B, Brooks DC, Tavakkoli A. Contemporary management of adult intussusception: who needs a resection? World J Surg. 2013;37(8):1872-1877. 73. Varban O, Ardestani A, Azagury D, et al. Resection or reduction? The dilemma of managing retrograde intussusception after Roux-en-Y gastric bypass. Surg Obes Relat Dis. 2013;9(5): 725-730. 74. Buchman AL, Solapio J, Fryer J. AGA technical review on short bowel syndrome and intestinal transplantation. Gastroenterology. 2003;124(4):1111-1134. 75. Bianchi A. Intestinal loop lengthening—a technique for increasing small-intestinal length. J Pediatr Surg. 1980;15(2): 145-151. 76. Jones BA, Hull MA, Potanos KM, et al. Report of 111 consecutive patients enrolled in the International Serial Transverse Enteroplasty (STEP) data registry: a retrospective observational study. J Am Coll Surg. 2013;216(3):438-446. 77. Messing B, Crenn P, Beau P, Boutron-Ruault MC, Rambaud JC, Matuchansky C. Long-term survival and parenteral nutrition dependence in adult patients with short bowel syndrome. Gastroenterology. 1999;117(5):1043-1050. 78. Cai J. Intestine and multivisceral transplantation in the United States: a report of 20-year national registry data (1990-2009). Clin Transpl. 2009;83-101.Brunicardi_Ch28_p1219-p1258.indd 125723/02/19 2:25 PM
Brunicardi_Ch28_p1219-p1258.indd 125823/02/19 2:25 PMThis page intentionally left blankColon, Rectum, and AnusMary R. Kwaan, David B. Stewart Sr, and Kelli Bullard Dunn 29chapterEMBRYOLOGY AND ANATOMYEmbryologyThe embryonic gastrointestinal tract begins developing during the fourth week of gestation. The primitive gut is derived from the endoderm and divided into three segments: foregut, midgut, and hindgut. Both midgut and hindgut contribute to the colon, rec-tum, and anus.The midgut develops into the small intestine, ascending colon, and proximal transverse colon, and receives blood supply from the superior mesenteric artery. During the sixth week of gestation, the midgut herniates out of the abdominal cavity and then rotates 270° counterclockwise around the superior mesen-teric artery to return to its final position inside the abdominal cavity during the tenth week of gestation. The hindgut develops into the distal transverse colon, descending colon, rectum, and Embryology and Anatomy 1259Embryology / 1259Anatomy / 1260Congenital Anomalies / 1263Normal Physiology 1263Fluid and Electrolyte Exchanges / 1263Short-Chain Fatty Acids / 1263Colonic Microflora and Intestinal Gas / 1263Motility, Defecation, and Continence / 1263Clinical Evaluation 1264Clinical Assessment / 1264Endoscopy / 1264Imaging / 1265Physiologic and Pelvic Floor Investigations / 1266Laboratory Studies / 1266Evaluation of Common Symptoms / 1267General Surgical Considerations 1270Resections / 1270Anastomoses / 1274Ostomies and Preoperative Stoma Planning / 1275Functional Results / 1278Anesthesia Considerations / 1278Operative Preliminaries / 1279Inflammatory Bowel Disease 1279General Considerations / 1279Ulcerative Colitis / 1282Operative Management / 1283Crohn’s Disease / 1283Indeterminate Colitis / 1286Diverticular Disease 1286Inflammatory Complications (Diverticulitis) / 1286Hemorrhage / 1288Giant Colonic Diverticulum / 1288Right-Sided Diverticula / 1288Adenocarcinoma and Polyps 1288Incidence / 1288Epidemiology (Risk Factors) / 1288Pathogenesis of Colorectal Cancer / 1289Polyps / 1290Inherited Colorectal Carcinoma / 1291Prevention: Screening and Surveillance / 1293Routes of Spread and Natural History / 1295Staging and Preoperative Evaluation / 1295Therapy for Colonic Carcinoma / 1296Therapy for Rectal Carcinoma / 1299Follow-Up and Surveillance / 1302Treatment of Recurrent Colorectal Carcinoma / 1302Minimally Invasive Techniques for Resection / 1302Other Neoplasms 1303Rare Colorectal Tumors / 1303Retrorectal/Presacral Tumors / 1304Anal Canal and Perianal Tumors / 1304Other Benign Colorectal  Conditions 1305Rectal Prolapse and Solitary Rectal Ulcer Syndrome / 1305Volvulus / 1306Megacolon / 1308Colonic Pseudo-Obstruction (Ogilvie’s Syndrome) / 1308Ischemic Colitis / 1309Infectious Colitis / 1309Anorectal Diseases 1310Hemorrhoids / 1310Anal Fissure / 1313Anorectal Sepsis and Cryptoglandular Abscess / 1313Perianal Abscess / 1314Ischiorectal Abscess / 1314Intersphincteric Abscess / 1314Supralevator Abscess / 1316Perianal Sepsis in the Immunocompromised Patient / 1316Necrotizing Soft Tissue Infection of the Perineum / 1316Fistula In Ano / 1317Rectovaginal Fistula / 1317Perianal Dermatitis / 1319Sexually Transmitted Diseases / 1320Pilonidal Disease / 1320Hidradenitis Suppurativa / 1320Trauma 1321Penetrating Colorectal Injury / 1321Blunt Colorectal Injury / 1321Iatrogenic Injury / 1321Anal Sphincter Injury and Incontinence / 1322Foreign Body / 1323The Immunocompromised  Patient 1323Human Immunodeficiency Virus / 1323Immunosuppression for  Transplantation 1323The Neutropenic Patient 1323Brunicardi_Ch29_p1259-p1330.indd 125923/02/19 2:28 PM 1260proximal anus, all of which receive their blood supply from the inferior mesenteric artery. During the sixth week of gestation, the distal-most end of the hindgut, the cloaca, is divided by the urorectal septum into the urogenital sinus and the rectum.The distal anal canal is derived from ectoderm and receives its blood supply from the internal pudendal artery. The dentate line divides the endodermal hindgut from the ectodermal distal anal canal.AnatomyThe large intestine extends from the ileocecal valve to the anus. It is divided anatomically and functionally into the colon, rectum, and anal canal. The wall of the colon and rectum comprise four distinct layers: mucosa, submucosa, muscularis propria (inner circular muscle, outer longitudinal muscle), and serosa. In the colon, the outer longitudinal muscle is separated into three teniae coli, which converge proximally at the appendix and dis-tally at the rectum, where the outer longitudinal muscle layer is circumferential. In the distal rectum, the inner smooth muscle layer coalesces to form the internal anal sphincter. The intraperi-toneal colon and proximal one-third of the rectum are covered by serosa; the mid and lower rectum lack serosa.Colon Landmarks. The colon begins at the junction of the terminal ileum and cecum and extends approximately 150 cm (3 to 5 feet) to the rectum. The rectosigmoid junction is found at approximately the level of the sacral promontory and is arbitrarily described as the point at which the three teniae coli coalesce to form the outer longitudinal smooth muscle layer of the rectum. The cecum is the widest diameter portion of the colon (normally 7.5–8.5 cm) and has the thinnest muscular wall. As a result, the cecum is most vulnerable to perforation and least vulnerable to obstruction. The ascending colon is usu-ally fixed to the retroperitoneum. The hepatic flexure marks the transition to the transverse colon. The transverse colon is relatively mobile, but it is tethered by the gastrocolic ligament and colonic mesentery. The greater omentum is attached to the anterior/superior edge of the transverse colon. These attach-ments explain the characteristic triangular appearance of the transverse colon observed during colonoscopy. The splenic flexure marks the transition from the transverse colon to the descending colon. The attachments between the splenic flexure and the spleen (the lienocolic ligament) can be short and dense, making mobilization of this flexure during colectomy challeng-ing. The descending colon is relatively fixed to the retroperi-toneum. The sigmoid colon is the narrowest part of the large intestine and is extremely mobile. Although the sigmoid colon is usually located in the left lower quadrant, redundancy and mobility can result in a portion of the sigmoid colon residing in the right lower quadrant. This mobility explains why volvulus is most common in the sigmoid colon and why diseases affect-ing the sigmoid colon, such as diverticulitis, may occasionally present as right-sided abdominal pain. The narrow caliber of the sigmoid colon makes this segment of the large intestine the most vulnerable to obstruction.Colon Vascular Supply. The arterial supply to the colon is highly variable (Fig. 29-1). In general, the superior mesenteric artery branches into the ileocolic artery (absent in up to 20% of people), which supplies blood flow to the terminal ileum and proximal ascending colon; the right colic artery, which supplies the ascending colon; and the middle colic artery, which supplies the transverse colon. The inferior mesenteric artery branches into the left colic artery, which supplies the descending colon; several sigmoidal branches, which supply the sigmoid colon; and the superior rectal artery, which supplies the proximal rec-tum. The terminal branches of each artery form anastomoses with the terminal branches of the adjacent artery and communi-cate via the marginal artery of Drummond. This arcade is com-plete in only 15% to 20% of people.Key Points1 Resection principles: The mesenteric clearance technique dictates the extent of resection and is determined by the nature of the primary pathology, the intent of resection, the location of the lesion, and the condition of the mesentery.2 Function after resection: Bowel function is often com-promised after colorectal resection, especially after low anterior resection. For this reason, it is important to obtain a history of prior anorectal trauma and/or incontinence before considering a low anastomosis.3 Ostomies/Stomas: Preoperative marking for a planned stoma is critical for a patient’s quality of life. Ideally, a stoma should be located within the rectus muscle, in a location where the patient can easily see and manipulate the appliance, and away from previous scars, bony promi-nences, or abdominal creases.4 Inflammatory bowel disease: Both Crohn’s disease and ulcerative colitis are associated with an increased risk of colorectal carcinoma. Risk depends on the amount of colon involved and the duration of disease.5 Pathogenesis of colorectal cancer: A variety of mutations have been identified in colorectal cancer. Mutations may cause activation of oncogenes (K-ras) and/or inactivation of tumor suppressor genes (adenomatous polyposis coli [APC], deleted in colorectal carcinoma [DCC], p53).6 Minimally invasive resection: Laparoscopy and HAL have been shown to be both safe and efficacious for colorec-tal resection. Robotic surgery increasingly has been used, especially for rectal/pelvic dissection.7 Anal epidermoid carcinoma: Unlike rectal adenocarci-noma, anal epidermoid carcinoma is treated primarily with chemoradiation. Surgery is reserved for patients with persistent or recurrent disease.8 Rectal prolapse: Rectal prolapse occurs most commonly in elderly women. Transabdominal repair (rectopexy with or without resection) offers more durability than perineal proctosigmoidectomy, but it carries greater operative risk.9 Hemorrhoids: Hemorrhoids are cushions of submucosal tissue containing venules, arterioles, and smooth muscle fibers. They are thought to play a role in maintaining continence. Resection is only indicated for refractory symptoms.10 Fistula in ano: Treatment of fistula in ano depends on the location of the fistula, amount of anal sphincter involved in the fistula, and the underlying disease process.Brunicardi_Ch29_p1259-p1330.indd 126023/02/19 2:28 PM 1261COLON, RECTUM, AND ANUSCHAPTER 29Except for the inferior mesenteric vein, the veins of the colon parallel their corresponding arteries and bear the same terminology (Fig. 29-2). The inferior mesenteric vein ascends in the retroperitoneal plane over the psoas muscle and continues posterior to the pancreas to join the splenic vein. During a col-ectomy, this vein is often mobilized independently and ligated at the inferior edge of the pancreas.Colon Lymphatic Drainage. The lymphatic drainage of the colon originates in a network of lymphatics in the muscula-ris mucosa. Lymphatic vessels and lymph nodes follow the regional arteries. Lymph nodes are found on the bowel wall (epicolic), along the inner margin of the bowel adjacent to the arterial arcades (paracolic), around the named mesenteric ves-sels (intermediate), and at the origin of the superior and inferior mesenteric arteries (main).Colon Nerve Supply. The colon is innervated by both sympathetic (inhibitory) and parasympathetic (stimulatory) nerves, which parallel the course of the arteries. Sympathetic nerves arise from T6–T12 and L1–L3. The parasympathetic innervation to the right and transverse colon is from the vagus nerve; the parasympathetic nerves to the left colon arise from sacral nerves S2–S4 to form the nervi erigentes.Anorectal Landmarks. The rectum is approximately 12 to 15 cm in length. Three distinct submucosal folds, the valves of Houston, extend into the rectal lumen. Posteriorly, the presecral fascia separates the rectum from the presacral venous plexus and the pelvic nerves. At S4, the rectosacral fascia (Waldeyer’s fascia) extends anteriorly and caudally and attaches to the fas-cia propria at the anorectal junction. Anteriorly, Denonvilliers’ fascia separates the rectum from the prostate and seminal ves-icles in men and from the vagina in women. The lateral liga-ments support the lower rectum.The anatomic anal canal extends from the dentate or pectinate line to the anal verge. The dentate or pectinate line marks the transition point between columnar rectal mucosa and squamous anoderm. The anal transition zone includes mucosa proximal to the dentate line that shares histologic characteris-tics of columnar, cuboidal, and squamous epithelium. Although the anal transition zone was long thought to extend only 1 to 2 cm proximal to the dentate line, it is known that the proxi-mal extent of this zone is highly variable and can be as far as 15 cm proximal to the dentate line. The dentate line is sur-rounded by longitudinal mucosal folds, known as the columns of Morgagni, into which the anal crypts empty. These crypts are the source of cryptoglandular abscesses (Fig. 29-3). In contrast to the anatomic anal canal, the surgical anal canal begins at the Middlecolic a.Rightcolic a.Leftcolic a.Ileocolic a.Superiormesenteric a.Superiorrectal a.Sigmoidal a.Inferiormesenteric a.Figure 29-1. Arterial blood supply to the colon. a. = artery.Inferiormesenteric v.Middlecolic v.Rightcolic v.Superiormesenteric v.Portal v.Leftcolic v.Sigmoidal v.Superiorrectal v.Ileocolic v.Figure 29-2. Venous drainage of the colon. v. = vein. (Reproduced with permission from Bell RH, Rikkers LF, Mulholland M: Diges-tive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)Brunicardi_Ch29_p1259-p1330.indd 126123/02/19 2:28 PM 1262SPECIFIC CONSIDERATIONSPART IIanorectal junction and terminates at the anal verge. The surgical anal canal measures 2 to 4 cm in length and is generally longer in men than in women. It begins at the anorectal junction and terminates at the anal verge.In the distal rectum, the inner smooth muscle is thickened and comprises the internal anal sphincter that is surrounded by the subcutaneous, superficial, and deep external sphincter. The deep external anal sphincter is an extension of the puborectalis muscle. The puborectalis, iliococcygeus, and pubococcygeus muscles form the levator ani muscle of the pelvic floor (Fig. 29-4).Anorectal Vascular Supply. The superior rectal artery arises from the terminal branch of the inferior mesenteric artery and supplies the upper rectum. The middle rectal artery arises from the internal iliac; the presence and size of these arteries are highly variable. The inferior rectal artery arises from the inter-nal pudendal artery, which is a branch of the internal iliac artery. A rich network of collaterals connects the terminal arterioles of each of these arteries, thus making the rectum relatively resis-tant to ischemia (Fig. 29-5).The venous drainage of the rectum parallels the arterial supply. The superior rectal vein drains into the portal system via the inferior mesenteric vein. The middle rectal vein drains into the internal iliac vein. The inferior rectal vein drains into the internal pudendal vein, and subsequently into the internal iliac vein. A submucosal plexus deep to the columns of Morgagni forms the hemorrhoidal plexus and drains into all three veins.Anorectal Lymphatic Drainage. Lymphatic drainage of the rectum parallels the vascular supply. Lymphatic channels in the upper and middle rectum drain superiorly into the inferior mes-enteric lymph nodes. Lymphatic channels in the lower rectum drain both superiorly into the inferior mesenteric lymph nodes and laterally into the internal iliac lymph nodes. The anal canal has a more complex pattern of lymphatic drainage. Proximal to the dentate line, lymph drains into both the inferior mesen-teric lymph nodes and the internal iliac lymph nodes. Distal to the dentate line, lymph primarily drains into the inguinal lymph nodes, but can also drain into the inferior mesenteric lymph nodes and internal iliac lymph nodes.AnalcanalColumn of MorgagniDentate lineAnal cryptAnal glandAnodermTransitionzoneFigure 29-3. The lining of the anal canal. (Reproduced with permission from Goldberg SM, Gordon PH, Nivatvongs S: Essentials of Anorectal Surgery. Philadelphia, PA: JB Lippincott Company; 1980.)Deep external sphincterand puborectalis mm.Conjoinedlongitudinal m.Superficial externalsphincter m.Subcutaneous externalsphincter m.Valve of HoustonInternal rectalplexusMuscularis submucosa ani m.Transverse septumof ischiorectal fossaExternal rectalplexusInternalsphincter m.Figure 29-4. The distal rectum and anal canal. m. = muscle.Brunicardi_Ch29_p1259-p1330.indd 126223/02/19 2:28 PM 1263COLON, RECTUM, AND ANUSCHAPTER 29Anorectal Nerve Supply. Both sympathetic and parasym-pathetic nerves innervate the anorectum. Sympathetic nerve fibers are derived from L1–L3 and join the preaortic plexus. The preaortic nerve fibers then extend below the aorta to form the hypogastric plexus, which subsequently joins the para-sympathetic fibers to form the pelvic plexus. Parasympathetic nerve fibers are known as the nervi erigentes and originate from S2–S4. These fibers join the sympathetic fibers to form the pel-vic plexus. Sympathetic and parasympathetic fibers then supply the anorectum and adjacent urogenital organs.The internal anal sphincter is innervated by sympathetic and parasympathetic nerve fibers; both types of fibers inhibit sphincter contraction. The external anal sphincter and puborec-talis muscles are innervated by the inferior rectal branch of the internal pudendal nerve. The levator ani receives innervation from both the internal pudendal nerve and direct branches of S3 to S5. Sensory innervation to the anal canal is provided by the inferior rectal branch of the pudendal nerve. While the rec-tum is relatively insensate, the anal canal below the dentate line receives somatic innervation.Congenital AnomaliesPerturbation of the embryologic development of the midgut and hindgut may result in anatomic abnormalities of the colon, rec-tum, and anus. Failure of the midgut to rotate and return to the abdominal cavity during the tenth week of gestation results in varying degrees of intestinal malrotation and colonic nonfix-ation. Failure of canalization of the primitive gut can result in colonic duplication. Incomplete descent of the urogenital sep-tum may result in imperforate anus and associated fistulas to the genitourinary tract. Many infants with congenital anomalies of the hindgut have associated abnormalities in the genitourinary tract.NORMAL PHYSIOLOGYFluid and Electrolyte ExchangesWater, Sodium, Potassium, Chloride, Bicarbonate, and Ammonia. The colon is a major site for water absorption and electrolyte exchange. Under normal circumstances, approxi-mately 90% of the water contained in ileal fluid is absorbed in the colon (1000–2000 mL/d), but up to 5000 mL of fluid can be absorbed daily. Sodium is absorbed actively via sodiumpotassium (Na+/K+) ATPase. The colon can absorb up to 400 mEq of sodium per day. Water accompanies the transported sodium and is absorbed passively along an osmotic gradient. Potassium is actively secreted into the colonic lumen and absorbed by passive diffusion. Chloride is absorbed actively via a chloride-bicarbonate exchange.Bacterial degradation of protein and urea produces ammo-nia. Ammonia is subsequently absorbed and transported to the liver. Absorption of ammonia depends in part on intraluminal pH. A decrease in colonic bacteria (e.g., due to broad-spectrum antibiotic use) and/or a decrease in intraluminal pH (e.g., due to lactulose administration) will decrease ammonia absorption.Short-Chain Fatty AcidsShort-chain fatty acids (acetate, butyrate, and propionate) are produced by bacterial fermentation of dietary carbohydrates. Short-chain fatty acids are an important source of energy for the colonic mucosa, and metabolism by colonocytes provides energy for processes such as active transport of sodium. Lack of a dietary source for production of short-chain fatty acids, or diversion of the fecal stream by an ileostomy or colostomy, may result in mucosal atrophy and inflammation, the latter termed “diversion colitis.”Colonic Microflora and Intestinal GasApproximately 30% of fecal dry weight is composed of bacteria (1011–1012 bacteria/g of feces). Anaerobes are the predominant class of microorganism, and Bacteroides species are the most common (1011–1012 organisms/mL). Escherichia coli are the most numerous aerobes (108–1010 organisms/mL). Endogenous microflora are crucial for the breakdown of carbohydrates and proteins in the colon and participate in the metabolism of biliru-bin, bile acids, estrogen, and cholesterol. Colonic bacteria also are necessary for production of vitamin K. Endogenous bacteria also are thought to suppress the emergence of pathogenic micro-organisms, such as Clostridium difficile, a phenomenon termed “colonization resistance.” However, the high bacterial load of the large intestine may contribute to sepsis in critically ill patients and may contribute to intra-abdominal sepsis, abscess, and wound infection following colectomy. Burgeoning research on the human gut microbiome offers new concepts of bacterial community structure and its impact on gastrointestinal disease. Use of 16S ribosomal RNA, universally present in bacteria, allows for a more complete understanding of colonic samples, without the use of stool cultures.Intestinal gas arises from swallowed air, diffusion from the blood, and intraluminal production. Nitrogen, oxygen, car-bon dioxide, hydrogen, and methane are the major components of intestinal gas. Nitrogen and oxygen are largely derived from swallowed air. Carbon dioxide is produced by the reaction of bicarbonate and hydrogen ions and by the digestion of triglyc-erides to fatty acids. Hydrogen and methane are produced by colonic bacteria. The production of methane is highly variable. The gastrointestinal tract usually contains between 100 and 200 mL of gas, and 400 to 1200 mL/d are released as flatus, depending on the type of food ingested.Motility, Defecation, and ContinenceMotility. Unlike the small intestine, the large intestine does not demonstrate cyclic motor activity characteristic of the migra-tory motor complex. Instead, the colon displays intermittent Internaliliac arterySuperiorrectal arteryMiddlerectal arteryInferiorrectal arteryInferiormesenteric arteryMiddlesacral arteryLevatorani muscleFigure 29-5. Arterial supply to the rectum and anal canal.Brunicardi_Ch29_p1259-p1330.indd 126323/02/19 2:28 PM 1264SPECIFIC CONSIDERATIONSPART IIcontractions of either low or high amplitude. Low-amplitude, short-duration contractions occur in bursts and appear to move the colonic contents both antegrade and retrograde. It is thought that these bursts of motor activity delay colonic transit and thus increase the time available for absorption of water and exchange of electrolytes. High-amplitude, prolonged duration, propagated contractions (HAPCs) occur in a more coordinated fashion and create “mass movements,” four to ten times per day, mostly after meals and awakening. Bursts of “rectal motor complexes” also have been described. In general, cholinergic activation increases colonic motility.Defecation. Defecation is a complex, coordinated mechanism involving colonic mass movement, increased intra-abdominal and rectal pressure, and relaxation of the pelvic floor. Disten-tion of the rectum causes a reflex relaxation of the internal anal sphincter (the rectoanal inhibitory reflex) that allows the contents to make contact with the anal canal. This “sampling reflex” allows the sensory epithelium to distinguish solid stool from liquid stool and gas. If defecation does not occur, the rec-tum relaxes and the urge to defecate passes (accommodation response). Defecation proceeds by coordinating increasing intra-abdominal pressure via a Valsalva maneuver with rectal contraction, relaxation of the puborectalis muscle, and opening of the anal canal.Continence. The maintenance of fecal continence is at least as complex as the mechanism of defecation. Continence requires adequate rectal wall compliance to accommodate the fecal bolus, appropriate neurogenic control of the pelvic floor and sphincter mechanism, and functional internal and exter-nal sphincter muscles. At rest, the puborectalis muscle creates a “sling” around the distal rectum, forming a relatively acute angle that distributes intra-abdominal forces onto the pelvic floor. With defecation, this angle straightens, allowing down-ward force to be applied along the axis of the rectum and anal canal. The internal and external sphincters are tonically active at rest. The internal sphincter is responsible for most of the rest-ing, involuntary sphincter tone (resting pressure). The external sphincter is responsible for most of the voluntary sphincter tone (squeeze pressure). Branches of the pudendal nerve innervate both the internal and external sphincter. The hemorrhoidal cush-ions may contribute to continence by mechanically blocking the anal canal. Finally, liquid stools exacerbate abnormalities with these anatomic and physiologic mechanisms, so a formed stool contributes to maintaining continence. Thus, impaired con-tinence may result from poor rectal compliance, injury to the internal and/or external sphincter or puborectalis, or neuropathy.CLINICAL EVALUATIONClinical AssessmentObtaining a complete history and performing a physical exami-nation are the starting points for evaluating any patient with suspected disease of the colon, rectum, or anus. Special atten-tion should be paid to the patient’s past medical and surgical history to detect underlying conditions that might contribute to a gastrointestinal problem. If patients have had prior intes-tinal surgery, it is essential that one understand the resultant gastrointestinal anatomy. A history of anorectal surgery may be critical for patients with either abdominal or anorectal com-plaints. The obstetrical history in women is essential to detect occult pelvic floor and/or anal sphincter damage. Identifying a family history of colorectal disease, especially inflammatory bowel disease, polyps, and colorectal cancer, is crucial. In addi-tion to a family history of colorectal disease, a history of other malignancies may suggest the presence of a genetic syndrome. Medication use must be detailed as many drugs cause gastroin-testinal symptoms. Before recommending operative interven-tion, the adequacy of medical treatment must be ascertained. In addition to examining the abdomen, visual inspection of the anus and perineum and careful digital rectal exam are essential.EndoscopyAnoscopy. The anoscope is a useful instrument for examina-tion of the anal canal. Anoscopes are made in a variety of sizes and measure approximately 8 cm in length. A larger anoscope provides better exposure for anal procedures such as rubber band ligation or sclerotherapy of hemorrhoids. The anoscope, with obturator in place, should be adequately lubricated and gently inserted into the anal canal. The obturator is withdrawn, inspec-tion of the visualized anal canal is done, and the anoscope should then be withdrawn. It is rotated 90° and reinserted to allow visual-ization of all four quadrants of the canal. If the patient complains of severe perianal pain and cannot tolerate a digital rectal exami-nation, anoscopy should not be attempted without anesthesia.Proctoscopy. The rigid proctoscope is useful for examination of the rectum and distal sigmoid colon and is occasionally used therapeutically. The standard proctoscope is 25 cm in length and available in various diameters. Most often, a 15or 19-mm diameter proctoscope is used for diagnostic examinations. A smaller “pediatric” proctoscope (11-mm diameter) is better tol-erated by patients with anal stricture. Suction is necessary for an adequate proctoscopic examination. An operating platform for transanal surgery known as transanal endoscopic microsurgery (TEM) has a much wider diameter and can be used for exci-sions of large polyps and tumors. Transanal minimally invasive surgery (TAMIS) can achieve similar resections to TEM, but it does not utilize a proctoscope and instead depends on insuf-flation to create a working space in the rectum while utilizing a circular wound protector to open the anus.Flexible Sigmoidoscopy and Colonoscopy. Video or fiber-optic flexible sigmoidoscopy and colonoscopy provide excellent visualization of the colon and rectum. Sigmoidoscopes measure 60 cm in length. Full depth of insertion may allow visualiza-tion as high as the splenic flexure, although the mobility and redundancy of the sigmoid colon often limit the extent of the examination. Partial preparation with enemas is usually adequate for sigmoidoscopy, and most patients can tolerate this proce-dure without sedation. Colonoscopes measure 100 to 160 cm in length and are capable of examining the entire colon and terminal ileum. A complete oral bowel preparation is usually necessary for colonoscopy, and the duration and discomfort of the procedure usually require conscious sedation. Both sigmoid-oscopy and colonoscopy can be used diagnostically and thera-peutically. Electrocautery should generally not be used in the absence of a complete bowel preparation because of the risk of explosion of intestinal methane or hydrogen gases. Diagnostic colonoscopes possess a single channel through which instru-ments such as snares, biopsy forceps, or electrocautery can be passed; this channel also provides suction and irrigation capa-bility. Therapeutic colonoscopes possess two channels to allow simultaneous suction/irrigation and the use of snares, biopsy forceps, or electrocautery.Brunicardi_Ch29_p1259-p1330.indd 126423/02/19 2:28 PM 1265COLON, RECTUM, AND ANUSCHAPTER 29Capsule Endoscopy. Capsule endoscopy uses a small ingest-ible camera. After swallowing the camera, images of the mucosa of the gastrointestinal tract are captured, transmitted by radiofre-quency to a belt-held receiver, and then downloaded to a com-puter for viewing and analysis. Capsule endoscopy largely has been used to detect small bowel lesions. Recent advances in the development of maneuverable capsules may improve the sensi-tivity of this procedure.1 Finally, concern over the possibility of an acute obstruction has led to the development of a dissolvable capsule that can detect obstruction lesions. Although this tech-nology is promising, the ultimate utility of capsule endoscopy remains unknown.ImagingPlain X-Rays and Contrast Studies. Despite advanced radio-logic techniques, plain X-rays and contrast studies continue to play an important role in the evaluation of patients with sus-pected colon and rectal diseases. Plain X-rays of the abdomen (supine, upright, and diaphragmatic views) are useful for detect-ing free intra-abdominal air, bowel gas patterns suggestive of small or large bowel obstruction, and volvulus. Contrast studies are useful for evaluating obstructive symptoms, delineating fis-tulous tracts, and diagnosing small perforations or anastomotic leaks. Although Gastrografin cannot provide the mucosal detail provided by barium, this water-soluble contrast agent is rec-ommended if perforation or leak is suspected. Double-contrast barium enema (use of barium followed by the insufflation of air into the colon) has been reported to be 70% to 90% sensitive for the detection of mass lesions greater than 1 cm in diameter. Detection of small lesions can be extremely difficult, especially in a patient with extensive diverticulosis. For this reason, a colo-noscopy is preferred for evaluating nonobstructing mass lesions in the colon. Double-contrast barium enema has been used as a back-up examination if colonoscopy is incomplete.Computed Tomography. Computed tomography (CT) com-monly is employed in the evaluation of patients with abdominal complaints. Its utility is primarily in the detection of extralu-minal disease, such as intra-abdominal abscesses and pericolic inflammation, and in staging colorectal carcinoma because of its sensitivity in detection of hepatic metastases.Extravasation of oral or rectal contrast may also confirm the diagnosis of perforation or anastomotic leak. Nonspecific findings such as bowel wall thickening or mesenteric strand-ing may suggest inflammatory bowel disease, enteritis/colitis, or ischemia. A standard CT scan is relatively insensitive for the detection of intraluminal lesions.Computed Tomography Colonography. CT colonography (virtual colonoscopy) is a radiologic technique that is designed to overcome some of the limitations of traditional CT scan-ning. This technology uses helical CT and three-dimensional reconstruction to detect intraluminal colonic lesions. Oral bowel preparation, oral and rectal contrast, and colon insufflation have been used to maximize sensitivity. Experience with this technol-ogy has shown a sensitivity and specificity for detecting 1 cm or larger polyps of 85% to 90% in most studies, making it compa-rable to traditional colonoscopy. Although this technology has yet to be widely adopted, it remains an alternative to traditional colonoscopy for select patients.2Magnetic Resonance Imaging. The main use of magnetic resonance imaging (MRI) in colorectal disorders is in evaluation of pelvic lesions. MRI is more sensitive than CT for detecting bony involvement or pelvic sidewall extension of rectal tumors. MRI accurately determines the extent of spread of rectal cancer into the adjacent mesorectum and can reliably predict diffi-culty achieving radial margin clearance of a rectal cancer by surgery alone. When the radial margin is threatened, neoadju-vant chemoradiation is indicated. MRI also can be helpful in the detection and delineation of complex fistulas in ano. The use of an endorectal coil may increase sensitivity.Positron Emission Tomography. Positron emission tomog-raphy (PET) is used for imaging tissues with high levels of anaerobic glycolysis, such as malignant tumors. 13F-fluorode-oxyglucose (FDG) is injected as a tracer; metabolism of this molecule then results in positron emission. PET has been used as an adjunct to CT in the staging of colorectal cancer and may prove useful in discriminating recurrent cancer from fibrosis. By combining PET and CT technology (PET/CT), anatomic correlation between regions of high isotope accumulation (“hot spots”) on PET and abnormalities on CT can be determined. PET/CT increasingly is used to diagnose recurrent and/or meta-static colorectal cancer. However, the efficacy and utility of this technology remains unproven.Scintigraphy to Assess Gastrointestinal Bleeding. Scin-tigraphy to assess for gastrointestinal bleeding (technetium-99-tagged red blood cell [RBC] scan; “tagged RBC scan”) is a nuclear medicine test that uses 99mTc-erythrocytes and dynamic images to localize a bleeding source. Patients must be actively bleeding at the time of imaging, and a normal distribution of 99mTc-erythrocytes in vasculature, liver, spleen, penile circula-tion with mild uptake in kidneys and bladder can interfere with localization in bowel segments near those structures. Patients must be stable enough to tolerate imaging intervals of up to 4 hours, but slow bleeding at a rate of 0.05 to 0.2 mL/minute can be detected.3Single Photon Emission Computed Tomography (SPECT/CT). Radiolabeled erythrocytes are also used for SPECT/CT, but cross-sectional images provide a more specific localization of the bleeding source, which can be very helpful for surgical planning, especially if direct visualization via endoscopy has not been successful.4Angiography. Angiography is occasionally used for the detec-tion of bleeding within the colon or small bowel. To visual-ize hemorrhage angiographically, bleeding must be relatively brisk (approximately 0.5 to 1.0 mL per minute). If extravasa-tion of contrast is identified, infusion of vasopressin or angio-graphic embolization can be therapeutic. If surgical resection is required, the angiographic catheter can be left in place to assist with identification of the bleeding site intraoperatively.CT and magnetic resonance angiography are also useful for assessing patency of visceral vessels. This technique uses three-dimensional reconstruction to detect vascular lesions. If an abnormality is found, more traditional techniques (angiography, surgery) may then be used to further define and/or correct the problem.Endorectal and Endoanal Ultrasound. Endorectal ultra-sound is primarily used to evaluate the depth of invasion of neoplastic lesions in the rectum. The normal rectal wall appears as a five-layer structure (Fig. 29-6). Ultrasound can reliably dif-ferentiate most benign polyps from invasive tumors based on the integrity of the submucosal layer. Ultrasound can also dif-ferentiate superficial T1-T2 from deeper T3-T4 tumors. Overall, Brunicardi_Ch29_p1259-p1330.indd 126523/02/19 2:28 PM 1266SPECIFIC CONSIDERATIONSPART IIthe accuracy of ultrasound in detecting depth of mural invasion ranges between 81% and 94%. This modality also can detect enlarged perirectal lymph nodes, which may suggest nodal metastases; accuracy of detection of pathologically positive lymph nodes is 58% to 83%. Ultrasound may also prove useful for early detection of local recurrence after surgery.5Endoanal ultrasound is used to evaluate the layers of the anal canal. Internal anal sphincter, external anal sphincter, and puborectalis muscle can be differentiated. Endoanal ultrasound is particularly useful for detecting sphincter defects and for out-lining complex anal fistulas. MRI has also proven to be helpful in delineating the anatomy of fistulae, especially in complex cases. This modality increasingly is utilized for the evaluation of anal fistulae.Physiologic and Pelvic Floor InvestigationsAnorectal physiologic testing uses a variety of techniques to investigate the function of the pelvic floor. These techniques are useful in the evaluation of patients with incontinence, constipa-tion, rectal prolapse, obstructed defecation, and other functional disorders of the pelvic floor.Manometry. Anorectal manometry is performed by placing a pressure-sensitive catheter in the lower rectum. The catheter is then withdrawn through the anal canal and pressures recorded. A balloon attached to the tip of the catheter also can be used to test anorectal sensation. The resting pressure in the anal canal reflects the function of the internal anal sphincter (nor-mal 40–80 mmHg), whereas the squeeze pressure, defined as the maximum voluntary contraction pressure minus the resting pressure, reflects function of the external anal sphincter (normal 40–80 mmHg above resting pressure). The high-pressure zone estimates the length of the anal canal (normal 2.0–4.0 cm). The rectoanal inhibitory reflex can be detected by inflating a balloon in the distal rectum; absence of this reflex is characteristic of Hirschsprung’s disease.Neurophysiology. Neurophysiologic testing assesses func-tion of the pudendal nerves and recruitment of puborectalis muscle fibers. Pudendal nerve terminal motor latency mea-sures the speed of transmission of a nerve impulse through the distal pudendal nerve fibers (normal 1.8–2.2 ms); prolonged latency suggests the presence of neuropathy. Electromyographic (EMG) recruitment assesses the contraction and relaxation of the puborectalis muscle during attempted defecation. Normally, recruitment increases when a patient is instructed to “squeeze” and decreases when a patient is instructed to “push.” Inappro-priate recruitment is an indication of paradoxical contraction (nonrelaxation of the puborectalis). Needle EMG has been used to map both the pudendal nerves and the anatomy of the internal and external sphincters. However, this examination is painful and poorly tolerated by most patients. Needle EMG has largely been replaced by pudendal nerve motor latency testing to assess pudendal nerve function and endoanal ultrasound to map the sphincters.Rectal Evacuation Studies. Rectal evacuation studies include the balloon expulsion test and video defecography. Balloon expulsion assesses a patient’s ability to expel an intrarectal bal-loon. Video defecography provides a more detailed assessment of defecation. In this test, barium paste is placed in the rectum, and defecation is then recorded fluoroscopically. Defecography is used to help diagnose obstructed defecation from nonrelax-ation of the puborectalis muscle or anal sphincter dyssynergy, increased perineal descent, rectal prolapse and intussusception, rectocele, and enterocele. The addition of vaginal contrast and intraperitoneal contrast is useful in delineating complex disor-ders of the pelvic floor.Laboratory StudiesFecal Occult Blood Testing and Fecal Immunohistochemical Testing. Fecal occult blood testing (FOBT) has been used as a screening test for colonic neoplasms in asymptomatic, average-risk individuals. The efficacy of this test is based on serial test-ing because the majority of colorectal malignancies will bleed intermittently. FOBT has been a nonspecific test for peroxidase contained in hemoglobin; consequently, occult bleeding from any gastrointestinal source will produce a positive result. Simi-larly, many foods (red meat, some fruits and vegetables, and vitamin C) will produce a false-positive result. Increased speci-ficity for cancer detection is possible by using fecal immuno-chemical test (FIT). Reported sensitivity of 79% and specificity Mucosal surfaceMucosa/Muscularis mucosaSubmucosaMuscularis propriaSerosa/Perirectal fatBAFigure 29-6. A. Schematic of the layers of the rectal wall observed on endorectal ultrasonography. B. Normal endorectal ultrasonog-raphy. (A. Used with permission from Charles O. Finne III, MD, Minneapolis, MN.)Brunicardi_Ch29_p1259-p1330.indd 126623/02/19 2:28 PM 1267COLON, RECTUM, AND ANUSCHAPTER 29of 94% has led to widespread use of FIT in current population-based screening approaches. These tests rely on monoclonal or polyclonal antibodies to react with the intact globin portion of human hemoglobin and are more specific for identifying occult bleeding from the colon or rectum. Any positive FOBT or FIT mandates further investigation, usually by colonoscopy.6 More recently, stool DNA testing has been proposed for early detec-tion of colorectal cancer.7Stool Studies. Stool studies are often helpful in evaluating the etiology of diarrhea. Wet-mount examination reveals the pres-ence of fecal leukocytes, which may suggest colonic inflamma-tion or the presence of an invasive organism such as invasive E coli or Shigella species. Stool cultures can detect pathogenic bacteria, ova, and/or parasites. C difficile colitis is diagnosed by detecting bacterial toxin in the stool. Steatorrhea may be diag-nosed by adding Sudan red stain to a stool sample.Tumor Markers. Carcinoembryonic antigen (CEA) may be elevated in 60% to 90% of patients with colorectal cancer. Preoperative CEA level has recently been suggested to be a prognostic indicator.8 Despite this, CEA is not an effective screening tool for this malignancy. Many practitioners follow serial CEA levels after curative-intent surgery in order to detect early recurrence of colorectal cancer. However, this tumor marker is nonspecific, and no survival benefit associated with its serial measurements has yet been proven. It is also important to note that CEA may be mildly elevated in patients who smoke tobacco. Other biochemical markers (ornithine decarboxylase, urokinase) have been proposed, but none has yet proven sensi-tive or specific for detection, staging, or predicting prognosis of colorectal carcinoma.Genetic Testing. Although familial colorectal cancer syn-dromes, such as familial adenomatous polyposis (FAP) and hereditary nonpolyposis colon cancer (HNPCC) are rare, infor-mation about the specific genetic abnormalities underlying these disorders has led to significant interest in the role of genetic testing for colorectal cancer.9Tests for mutations in the adenomatous polyposis coli (APC) gene responsible for FAP and in mismatch repair genes responsible for HNPCC are commercially available and extremely accurate in families with known mutations. However, in the absence of an identified mutation, a negative result is uninformative. For individuals from high-risk families without an identified mutation, increased surveillance is recommended.10 Although many of these mutations are also present in sporadic colorectal cancer, the accuracy of genetic testing in average-risk individuals is considerably lower, and these tests are not recommended for screening. Due to the potential psychosocial implications of genetic testing, it is strongly recommended that professional genetic counselors be involved in the care of any patient considering these tests.Evaluation of Common SymptomsPain Abdominal Pain Abdominal pain is a nonspecific symptom with myriad causes. Abdominal pain related to the colon and rectum can result from obstruction (either inflammatory or neo-plastic), inflammation, perforation, or ischemia. Plain X-rays and judicious use of contrast studies and/or a CT scan can often confirm the diagnosis. Gentle retrograde contrast studies (Gastrografin enema) may be useful in delineating the degree of colonic obstruction. Sigmoidoscopy and/or colonoscopy performed by an experienced endoscopist can assist in the diagnosis of ischemic colitis, infectious colitis, and inflamma-tory bowel disease. However, if perforation or near complete obstruction is suspected, colonoscopy and/or sigmoidoscopy are generally contraindicated. Evaluation and treatment of abdomi-nal pain from a colorectal source should follow the usual surgi-cal principles of a thorough history and physical examination, appropriate diagnostic tests, resuscitation, and appropriately timed surgical intervention.Pelvic Pain Pelvic pain can originate from the distal colon and rectum or from adjacent urogenital structures. Tenesmus may result from proctitis or from a rectal or retrorectal mass, or fecal impaction in a constipated patient. Cyclical pain associated with menses, especially when accompanied by rectal bleeding, suggests a diagnosis of endometriosis. Pelvic inflammatory dis-ease also can produce significant abdominal and pelvic pain. The extension of a peridiverticular abscess or periappendiceal abscess into the pelvis may also cause pain. CT scan and/or MRI may be useful in differentiating these diseases. Proctoscopy (if tolerated) also can be helpful. Occasionally, laparoscopy will yield a diagnosis, although with access to high-quality imaging, indications for diagnostic surgery should be rare.Anorectal Pain. Anorectal pain is most often secondary to an anal fissure, perirectal abscess and/or fistula, or a throm-bosed hemorrhoid. Physical examination can usually differenti-ate these conditions. Other, less common causes of anorectal pain include anal canal neoplasms, perianal skin infection, and dermatologic conditions. Proctalgia fugax results from levator spasm and may present without any other anorectal findings. Physical exam is critical in evaluating patients with anorec-tal pain. If a patient is too tender to examine in the office, an examination under anesthesia is necessary. MRI or other imag-ing studies may be helpful in select cases where the etiology of pain is elusive.Lower Gastrointestinal Bleeding. The first goal in evaluat-ing and treating a patient with gastrointestinal hemorrhage is adequate resuscitation. The second goal is to identify the source of hemorrhage. Because the most common source of gastroin-testinal hemorrhage is esophageal, gastric, or duodenal, naso-gastric aspiration should always be performed; return of bile suggests that the source of bleeding is distal to the ligament of Treitz. If aspiration reveals blood or nonbile secretions, or if symptoms suggest an upper intestinal source, esophagogastro-duodenoscopy should be performed. Anoscopy and/or limited proctoscopy can identify hemorrhoidal bleeding. A techne-tium-99 (99mTc)-tagged red blood cell (tagged RBC scan) scan is extremely sensitive and is able to detect as little as 0.1 mL/h of bleeding; however, localization is imprecise. If the 99mTc-tagged RBC scan is positive, angiography can then be both diagnostic and potentially therapeutic. If the patient is hemodynamically stable, a rapid bowel preparation (over 4–6 hours) can be per-formed to allow colonoscopy. Colonoscopy may identify the cause of the bleeding, and cautery or injection/application of epinephrine into the bleeding site may be used to control hem-orrhage. A SPECT/CT may be helpful if other modalities have not achieved localization, particularly in distinguishing between small intestinal and colon sources. Colectomy may be required if bleeding persists despite interventions. Intraoperative colo-noscopy and/or enteroscopy may assist in localizing bleeding. If colectomy is required, a segmental resection is preferred if the bleeding source can be localized. “Blind” subtotal colectomy Brunicardi_Ch29_p1259-p1330.indd 126723/02/19 2:28 PM 1268SPECIFIC CONSIDERATIONSPART IIvery rarely may be required in a patient who is hemodynami-cally unstable with ongoing colonic hemorrhage of an unknown source. In this setting, just prior to proceeding with a “blind” subtotal colectomy, it is crucial to irrigate the rectosigmoid and reexamine the mucosa of the anal canal and rectum by anoscopy and proctoscopy to ensure the source of ongoing bleeding is not distal to the planned resection margin (Fig. 29-7).Occult blood loss from the gastrointestinal tract may mani-fest as iron-deficiency anemia or may be detected with FOBT or FIT. Because colon neoplasms bleed intermittently and rarely present with rapid hemorrhage, the presence of occult fecal blood should always prompt a colonoscopy. Unexplained iron-deficiency anemia is also an indication for colonoscopy.Hematochezia is commonly caused by hemorrhoids or a fissure. Sharp, knife-like pain and bright red rectal bleeding with bowel movements suggest the diagnosis of fissure. Pain-less, bright red rectal bleeding with bowel movements is often secondary to a friable internal hemorrhoid that is easily detected by anoscopy. In the absence of a painful, obvious fissure, any patient with rectal bleeding should undergo a careful digital rectal examination, anoscopy, and proctosigmoidoscopy. Fail-ure to diagnose a source in the distal anorectum should prompt colonoscopy.Constipation and Obstructed Defecation. Constipation is an extremely common complaint, affecting more than 4 million people in the United States. Despite the prevalence of this prob-lem, there is lack of agreement about an appropriate definition of constipation. Patients may describe infrequent bowel move-ments, hard stools, or excessive straining. A careful history of these symptoms often clarifies the nature of the problem.Constipation has many causes. Underlying metabolic, pharmacologic, endocrine, psychological, and neurologic causes often contribute to the problem. A stricture or mass lesion should be excluded by colonoscopy, barium enema, or CT colonography. After these causes have been excluded, eval-uation focuses on differentiating slow-transit constipation from outlet obstruction. Transit studies, in which radiopaque markers are swallowed and then followed radiographically, are useful for diagnosing slow-transit constipation. In this study, patients ingest radiopaque studies and are followed radiographically for 5 days. Retention of 20% or greater of these markers in the colon demonstrated slow transit. If these markers are congregated in the rectosigmoid colon and rectum, obstructed defecation/outlet obstruction is suggested. Anorectal manometry and EMG can detect nonrelaxation of the puborectalis, which contributes to outlet obstruction. The absence of an anorectal inhibitory reflex Massive life-threatening bleedingPositiveRebleedingRebleedingModerate bleedingcontinuedBleeding stopped or slowed downPositivePositivePositivePositivePositivePositivePositivePositiveNegativeNegativeNegativeNegativeNegativeNegativeNegativeNegativeNegativeFailFailorAcute colonic bleedingVolume resuscitationplus blood transfusionNG aspiratenegativeNG aspiratepositiveProctoscopyRule out anorectal bleedingGastroduodenoscopy+ endoscopic treatmentElective colonoscopyMesenteric arteriographyMesenteric arteriographyUrgent colonoscopy99MTc RBC scintigraphyColonoscopic treatmentor explore, segmentalresectionEndoscopictreatmentVasopressinor emboliVasopressinor emboliExplore, intraoperativeendoscopyExplore, intraoperativeendoscopyExplore, intraoperativeendoscopyExplore, intraoperativeendoscopyObserveSegmentalresectionTotalcolectomyTotalcolectomyTotalcolectomyTotalcolectomySegmentalresectionSegmentalresectionSegmentalresectionSegmentalresectionSegmentalresectionSegmentalresectionSee moderate bleedingor massive bleedingFigure 29-7. Algorithm for treatment of colorectal hemorrhage. NG = nasogastric; 99mTc = technetium-99; RBC = red blood cell. (Repro-duced with permission of Gordon PH, Nivatvongs S: Principles and Practice of Surgery for the Colon, Rectum, and Anus, 2nd ed. New York, NY: Marcel Dekker, Inc; 1999.)Brunicardi_Ch29_p1259-p1330.indd 126823/02/19 2:28 PM 1269COLON, RECTUM, AND ANUSCHAPTER 29suggests Hirschsprung’s disease and may prompt a rectal muco-sal biopsy. Defecography can identify rectal prolapse, intussus-ception, rectocele, or enterocele.Medical management is the mainstay of therapy for consti-pation and includes fiber, increased fluid intake, and laxatives. Outlet obstruction from nonrelaxation of the puborectalis or anal sphincter dyssynergy often responds to biofeedback. Surgery to correct rectocele and rectal prolapse (with or without sigmoid resection) has a variable effect on symptoms of constipation but can be successful in selected patients. Subtotal colectomy is considered only for patients with severe slow-transit consti-pation (colonic inertia) refractory to maximal medical inter-ventions. While this operation almost always increases bowel movement frequency, complaints of diarrhea, incontinence, and abdominal pain are not infrequent, and patients should be care-fully selected and counseled.11Diarrhea and Irritable Bowel Syndrome. Diarrhea is also a common complaint and is usually a self-limited symptom of infectious gastroenteritis. If diarrhea is chronic or is accom-panied by bleeding or abdominal pain, further investigation is warranted. Bloody diarrhea and pain are characteristic of colitis; etiology can be an infection (invasive E coli, Shigella, Salmonella, Campylobacter, Entamoeba histolytica, or C difficile), inflammatory bowel disease (ulcerative colitis or Crohn’s coli-tis), or ischemia. Stool wet-mount and culture can often diag-nose infection. Sigmoidoscopy or colonoscopy can be helpful in diagnosing inflammatory bowel disease or ischemia. However, if the patient has abdominal tenderness, particularly with peri-toneal signs, or any other evidence of perforation, endoscopy is contraindicated.Chronic diarrhea may present a more difficult diagnos-tic dilemma. Chronic ulcerative colitis, Crohn’s colitis, infec-tion, malabsorption, and short gut syndrome can cause chronic diarrhea. Rarely, carcinoid syndrome and islet cell tumors (vasoactive intestinal peptide–secreting tumor [VIPoma], somatostatinoma, gastrinoma) present with this symptom. Large villous lesions may cause secretory diarrhea. Collagenous colitis can cause diarrhea without any obvious mucosal abnor-mality. Along with stool cultures, tests for malabsorption, and metabolic investigations, colonoscopy can be invaluable in dif-ferentiating these causes. Biopsies should be taken even if the colonic mucosa appears grossly normal.Irritable bowel syndrome is a particularly troubling con-stellation of symptoms consisting of crampy abdominal pain, bloating, constipation, and urgent diarrhea. Workup reveals no underlying anatomic or physiologic abnormality. Once other disorders have been excluded, dietary restrictions and avoid-ance of caffeine, alcohol, and tobacco may help to alleviate symptoms. Antispasmodics and bulking agents may be helpful.Incontinence. The true incidence of fecal incontinence is unknown, but has been estimated to occur in 10 to 13 individu-als per 1000 people older than age 65 years. Incontinence ranges in severity from occasional leakage of gas and/or liquid stool to daily loss of solid stool. The underlying cause of incontinence is often multifactorial, and diarrhea is often contributory. In gen-eral, causes of incontinence can be classified as neurogenic or anatomic. Neurogenic causes include diseases of the central ner-vous system and spinal cord along with pudendal nerve injury. Anatomic causes include congenital abnormalities, procidentia (rectal prolapse), overflow incontinence secondary to impac-tion or an obstructing neoplasm, and trauma. The most common Figure 29-8. A. Endoanal ultrasonography showing the normal layers of the anal canal. B. Endoanal ultrasonography with anterior sphincter defect from birthing injury. EAS = external anal sphincter; IAS = internal anal sphincter. (Used with permission from Charles O. Finne III, MD, Minneapolis, MN.)ABtraumatic cause of incontinence is injury to the anal sphincter during vaginal delivery. Other causes include anorectal surgery, impalement, and pelvic fracture.After a thorough medical evaluation to detect underly-ing conditions that might contribute to incontinence, evalua-tion focuses on assessment of the anal sphincter and pudendal nerves. Pudendal nerve terminal motor latency testing may detect neuropathy. Anal manometry can detect low resting and squeeze pressures. Physical examination and defecography can detect rectal prolapse. Endoanal ultrasound is invaluable in diagnosing sphincter defects (Fig. 29-8).Therapy depends on the underlying abnormality. Diarrhea should be treated medically (fiber, antidiarrheal agents). Even in the absence of frank diarrhea, the addition of dietary fiber may improve continence. Some patients may respond to bio-feedback and this approach may be considered in patients who fail dietary modification. Many patients with a sphincter defect are candidates for an overlapping sphincteroplasty. Sacral nerve Brunicardi_Ch29_p1259-p1330.indd 126923/02/19 2:28 PM 1270SPECIFIC CONSIDERATIONSPART IIstimulation been shown to decrease episodes of fecal incon-tinence and has proven durability in the long term (5 years). The artificial bowel sphincter may be useful in patients who fail other interventions. Other options include radiofrequency energy to the anal canal (SECCA procedure), magnetic anal sphincter, and injectable submucosal bulking agents, but long-term efficacy has not yet been proven.12-14 Finally, a stoma can provide relief for severely incontinent patients who have failed or are not candidates for other interventions.GENERAL SURGICAL CONSIDERATIONSColorectal resections are performed for a wide variety of condi-tions, including neoplasms (benign and malignant), inflamma-tory bowel diseases, and other benign conditions. Although the indication and urgency for surgery will alter some of the tech-nical details, the operative principles of colorectal resections, anastomoses, and use of ostomies are well established.ResectionsThe mesenteric clearance technique dictates the extent of colonic resection and is determined by the nature of the primary pathology (malignant or benign), the intent of the resection (curative or palliative), the precise location(s) of the primary pathology, and the condition of the mesentery (thin and soft or thick and indurated). In general, a proximal mesenteric ligation will eliminate the blood supply to a greater length of colon and require a more extensive “colectomy.” Curative resection of a colorectal cancer is usually best accomplished by performing a proximal mesenteric vessel ligation and radical mesenteric clearance of the lymphatic drainage basin of the tumor site (Fig. 29-9). Resection of a benign process does not require wide mesenteric clearance.Emergency Resection. Emergency resection may be required because of obstruction, perforation, or hemorrhage. In this set-ting, the bowel is almost always unprepared and the patient may be unstable. The surgical principles described earlier apply, and an attempt should be made to resect the involved segment along with its lymphovascular supply. If the resection involves the right colon or proximal transverse colon (right or extended right colectomy), a primary ileocolonic anastomosis can usually be performed safely as long as the remaining bowel appears healthy and the patient is stable. For left-sided tumors, the traditional approach has involved resection of the involved bowel and end colostomy, with or without a mucus fistula. However, there is an increasing body of data to suggest that a primary anasto-mosis without a bowel preparation or with an on-table lavage, with or without a diverting ileostomy, may be equally safe in this setting. If the proximal colon appears unhealthy (vascular compromise, serosal tears, perforation), a subtotal colectomy can be performed with a small bowel to rectosigmoid anastomo-sis. Resection and diversion (ileostomy or colostomy) remain safe and appropriate if the bowel appears compromised or if the patient is unstable, malnourished, or immunosuppressed.Minimally Invasive Techniques of Resection. With advances in minimally invasive technology, many proce-dures that previously have required laparotomy can now be performed laparoscopically, with hand-assisted laparoscopy (HAL), or robotically.15,16 Potential advantages of minimally invasive surgery include improved cosmetic result, decreased postoperative pain, and earlier return of bowel function. More-over, some experimental data suggest that minimally invasive 1operations have less immunosuppressive impact on the patient and thus might improve postoperative outcome and even long-term survival. To date, most studies have demonstrated equiva-lence between laparoscopic, HAL, and open resection in terms of extent of resection. Return of bowel function and length of hospital stay are highly variable. Long-term outcome has yet to be determined; however, short-term quality of life appears to be improved by laparoscopy.17,18 Laparoscopic total mesorec-tal excision for rectal cancer, however, may not be appropriate. The most recent advances in minimally invasive surgery involve use of robotics and telemanipulation in which the surgeon oper-ates from a console remote from the patient. These procedures have been rapidly gaining in popularity, especially for pelvic and rectal resections. Early studies suggest equivalence between robotic resections and laparoscopic/HAL resections.19In addition, some proponents have suggested that robotic procedures may be easier to learn (a shorter “learning curve”) and that robotic surgery may be ergonomically better for the operating surgeon. Nevertheless, long-term superiority, or even equivalence, has yet to be demonstrated, and these advanced technologies are likely to be associated with significant cost.Colectomy. A variety of terms are used to describe different types of colectomy (Fig. 29-10).Ileocolic Resection An ileocolic resection describes a limited resection of the terminal ileum, cecum, and appendix. It is used to remove disease involving these segments of the intestine (e.g., ileocecal Crohn’s disease) and benign lesions or incur-able cancers arising in the terminal ileum, cecum, and, occa-sionally, the appendix. If curable malignancy is suspected, more radical resections, such as a right hemicolectomy, are gener-ally indicated. The ileocolic vessels are ligated and divided. A variable length of small intestine may be resected depending on the disease process. A primary anastomosis is created between the distal small bowel and the ascending colon. It is technically difficult to perform an anastomosis at or just proximal to the ileocecal valve; therefore, if the most distal ileum needs to be resected, the cecum is generally also removed.Right Colectomy A right colectomy is used to remove lesions or disease in the right colon and is oncologically the most appro-priate operation for curative intent resection of proximal colon carcinoma. The ileocolic vessels, right colic vessels, and right branches of the middle colic vessels are ligated and divided. Approximately 10 cm of terminal ileum are usually included in the resection. A primary ileal-transverse colon anastomosis is almost always possible.Extended Right Colectomy An extended right colectomy may be used for curative intent resection of lesions located at the hepatic flexure or proximal transverse colon. A standard right colectomy is extended to include ligation of the middle colic vessels at their base. The right colon and proximal trans-verse colon are resected, and a primary anastomosis is created between the distal ileum and distal transverse colon. Such an anastomosis relies on the marginal artery of Drummond. If the blood supply to the distal transverse colon is questionable, the resection is extended distally beyond the splenic flexure to well-perfused descending colon where the ileocolic anastomosis can be performed safely.Transverse Colectomy Lesions in the mid and distal trans-verse colon may be resected by ligating the middle colic vessels and resecting the transverse colon, followed by a colocolonic anastomosis. However, an extended right colectomy with an Brunicardi_Ch29_p1259-p1330.indd 127023/02/19 2:28 PM 1271COLON, RECTUM, AND ANUSCHAPTER 29anastomosis between the terminal ileum and descending colon may be a safer anastomosis with an equivalent functional result.Left Colectomy For lesions or disease states confined to the distal transverse colon, splenic flexure, or descending colon, a left colectomy is performed. The left branches of the middle colic vessels, the left colic vessels, and the first branches of the sigmoid vessels are ligated. A colocolonic anastomosis can usually be performed.Extended Left Colectomy An extended left colectomy is an option for removing lesions in the distal transverse colon. In this operation, the left colectomy is extended proximally to include the right branches of the middle colic vessels.Sigmoid Colectomy Lesions in the sigmoid colon require ligation and division of the sigmoid branches of the inferior mesenteric artery. In general, the entire sigmoid colon should be resected to the level of the peritoneal reflection and an BADCFEFigure 29-9. Extent of resection for carcinoma of the colon. A. Cecal cancer. B. Hepatic flexure cancer. C. Transverse colon cancer. D. Splenic flexure cancer. E. Descending colon cancer. F. Sigmoid colon cancer.Brunicardi_Ch29_p1259-p1330.indd 127123/02/19 2:28 PM 1272SPECIFIC CONSIDERATIONSPART IIanastomosis created between the descending colon and upper rectum. Full mobilization of the splenic flexure is often required to create a tension-free anastomosis.Total and Subtotal Colectomy Total or subtotal colectomy is occasionally required for patients with fulminant colitis, attenu-ated FAP, or synchronous colon carcinomas. In this procedure, the ileocolic vessels, right colic vessels, middle colic vessels, and left colic vessels are ligated and divided. The superior rectal vessels are preserved. If it is desired to preserve the sigmoid, the distal sigmoid vessels are left intact, and an anastomosis is created between the ileum and distal sigmoid colon (subtotal colectomy with ileosigmoid anastomosis). If the sigmoid is to be resected, the sigmoidal vessels are ligated and divided, and the ileum is anastomosed to the upper rectum (total abdominal colectomy with ileorectal anastomosis). If an anastomosis is contraindicated, an end ileostomy is created, and the remain-ing sigmoid or rectum is managed either as a mucus fistula or a Hartmann’s pouch.Proctocolectomy Total Proctocolectomy In this procedure, the entire colon, rectum, and anus are removed, and the ileum is brought to the skin as a Brooke ileostomy.Restorative Proctocolectomy (Ileal Pouch–Anal Anasto-mosis) The entire colon and rectum are resected, but the anal sphincter muscles and a variable portion of the distal anal canal are preserved. Bowel continuity is restored by anastomosis of an ileal reservoir to the anal canal. The original technique included a transanal mucosectomy and hand-sewn ileoanal anastomosis. Proponents of this technique argue that mucosectomy guarantees removal of all of the diseased mucosa, including the anal transi-tion zone, and therefore decreases the risk of ongoing disease, dysplasia, and carcinoma. Opponents cite the increased risk of incontinence after mucosectomy and argue that even meticulous technique invariably leaves behind mucosal “islands” that are subsequently hidden under the anastomosis. However, persistent or recurrent dysplasia in the anal transition zone is uncommon (4.5%), and cancers occur even more rarely.19 Moreover, the “double-staple” technique using the circular stapling devices is considerably simpler than mucosectomy and a hand-sewn anas-tomosis and may be associated with a better functional outcome (Fig. 29-11).20-22 Regardless of the anastomotic technique, many surgeons recommend that patients undergo annual surveillance of the anastomosis and/or anal transition zone by digital rectal exam and anoscopy or proctoscopy.The neorectum is made by anastomosis of the terminal ileum aligned in a “J,” “S,” or “W” configuration. Because func-tional outcomes are similar and because the J-pouch is the sim-plest to construct, it has become the most used configuration. ABCDEFGHIJKLFigure 29-10. Terminology of types of colorectal resections: A→C Ileocecectomy; + A + B→D Ascending colectomy; + A + B→F Right hemicolectomy; + A + B→G Extended right hemi-colectomy; + E + F→G + H Transverse colectomy; G→I Left hemicolectomy; F→I Extended left hemicolectomy; J + K Sigmoid colectomy; + A + B→J Subtotal colectomy; + A + B→K Total col-ectomy; + A + B→L Total proctocolectomy. (Reproduced with per-mission from Fielding LP, Goldberg SM: Rob & Smith’s Operative: Surgery of the Colon, Rectum, and Anus. London: Elsevier; 1993.)BCAFigure 29-11. After a total colectomy and resection of the rec-tum (A), the anal canal with a short cuff of transitional mucosa and sphincter muscles is preserved (B). An ileal J-pouch has been constructed and is anastomosed to the anal canal using a double-staple technique (C). (Reproduced with permission from Bell RH, Rikkers LF, Mulholland M: Digestive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)Brunicardi_Ch29_p1259-p1330.indd 127223/02/19 2:29 PM 1273COLON, RECTUM, AND ANUSCHAPTER 29With increasing experience in laparoscopic and robotic colec-tomy, some centers have begun performing total proctocolec-tomy with ileal pouch–anal reconstruction using minimally invasive surgical techniques.15 Most surgeons perform a proxi-mal ileostomy to divert succus from the newly created pouch in an attempt to minimize the consequences of leak and sepsis, especially in patients who are malnourished or immunosup-pressed (Fig. 29-12). The ileostomy is then closed 6 to 12 weeks later, after a contrast study confirms the integrity of the pouch. In low-risk patients, however, there are reports of successful creation of an ileoanal pouch without a diverting stoma.Anterior Resection. Anterior resection is the general term used to describe resection of the rectum from an abdominal approach to the pelvis with no need for a perineal, sacral, or other incision. Three types of anterior resection have been described.High Anterior Resection A high anterior resection is the term used to describe resection of the distal sigmoid colon and upper rectum and is the appropriate operation for benign lesions and disease at the rectosigmoid junction such as diverticulitis. The upper rectum is mobilized, but the pelvic peritoneum is not divided and the rectum is not mobilized fully from the concavity of the sacrum. The inferior mesenteric artery is ligated at its base, and the inferior mesenteric vein, which follows a different course than the artery, is ligated separately. A primary anasto-mosis (usually end-to-end) between the colon and rectal stump with a short cuff of peritoneum surrounding its anterior two thirds generally can be performed.Low Anterior Resection. A low anterior resection is used to remove lesions in the upper and mid rectum. The rectosigmoid is mobilized, the pelvic peritoneum is opened, and the inferior mesenteric artery is ligated and divided either at its origin from the aorta or just distal to the takeoff of the left colic artery. The rectum is mobilized from the sacrum by sharp dissection under direct view within the endopelvic fascial plane. The dissec-tion may be performed distally to the anorectal ring, extend-ing posteriorly through the rectosacral fascia to the coccyx and anteriorly through Denonvilliers’ fascia to the vagina in women or the seminal vesicles and prostate in men. The rectum and accompanying mesorectum are divided at the appropriate level, depending on the nature of the lesion. A low rectal anastomosis usually requires mobilization of the splenic flexure and ligation and division of the inferior mesenteric vein just inferior to the pancreas. Circular stapling devices have greatly facilitated the conduct and improved the safety of the colon to extraperitoneal rectal anastomosis.Extended Low Anterior Resection An extended low anterior resection is necessary to remove lesions located in the distal rectum, but several centimeters above the sphincter. The rectum is fully mobilized to the level of the levator ani muscle just as for a low anterior resection, but the anterior dissection is extended along the rectovaginal septum in women and distal to the semi-nal vesicles and prostate in men. After resection at this level, a coloanal anastomosis can be created using one of a variety of techniques. An end-to-end stapled or hand-sewn anastomo-sis has traditionally been the procedure of choice. However, the functional consequences of a “straight” anastomosis have led to consideration for creation of a colon J-pouch to increase the capacity of the neorectal reservoir. A side-to-end anastomosis can be constructed by placing the anvil of an EEA stapler 3 to 4 cm away from the stapled end of the proximal colon, with simi-lar functional outcomes to the colon J-pouch reconstruction.20-22 Because the risk of an anastomotic leak and subsequent sepsis is higher when an anastomosis is created in the distal rectum or anal canal, creation of a temporary ileostomy should be consid-ered in this setting, especially if the patient has received neoad-juvant radiation.23Although an anastomosis may be technically feasible very low in the rectum or anal canal, it is important to note that post-operative function may be poor. Because the descending colon lacks the distensibility of the rectum, the reservoir function may be compromised. Pelvic radiation, prior anorectal surgery, and obstetrical trauma may cause unsuspected sphincter damage. Finally, a very low anastomosis may involve and compromise the upper sphincter. Creation of a colon J-pouch or transverse coloplasty may improve function, but few long-term studies have addressed this issue.20-22A history of sphincter damage or any degree of inconti-nence is a relative contraindication for a coloanal anastomosis. In such patients, an end colostomy may be a more satisfac-tory option.Hartmann’s Procedure and Mucus Fistula. Hartmann’s procedure refers to a colon or rectal resection without an 2Figure 29-12. Ileal S-pouch anal anastomosis with temporary loop ileostomy. (Reproduced with permission from Bell RH, Rikkers LF, Mulholland M: Digestive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)Brunicardi_Ch29_p1259-p1330.indd 127323/02/19 2:29 PM 1274SPECIFIC CONSIDERATIONSPART IIanastomosis in which a colostomy or ileostomy is created and the distal colon or rectum is left as a blind pouch. The term is typically used when the left or sigmoid colon is resected and the closed off rectum is left in the pelvis. If the distal colon is long enough to reach the abdominal wall, a mucus fistula can be created by opening the defunctioned bowel and suturing the open lumen to the skin.Abdominoperineal Resection. An abdominoperineal resec-tion (APR) involves removal of the entire rectum, anal canal, and anus with construction of a permanent colostomy from the descending or sigmoid colon. The abdominal-pelvic portion of this operation proceeds in the same fashion as described for an extended low anterior resection. The perineal dissection can be performed with the patient in lithotomy position (often by a second surgeon) or in the prone position after closure of the abdomen and creation of the colostomy. For cancer, the perineal dissection is designed to excise the anal canal with a wide cir-cumferential margin including a cylindrical cuff of the levator muscle. A deliberate resection of the levator muscles near their bony attachments, in order to avoid opening the space between the tumor and the levator ani, is known as the extralevator abdomi-noperineal resection (ELAPE). ELAPE is useful for low, locally advanced rectal cancers, but routine use for all rectal cancer has not been shown to improve cancer outcomes.24 Primary wound closure is usually successful, but a large perineal defect, espe-cially if preoperative radiation has been used, may require a vascularized flap closure in some patients.25 For benign disease, proctectomy may be performed using an intersphincteric dissec-tion between the internal and external sphincters. This approach minimizes the perineal wound, making it easier to close because the levator muscle remains intact.AnastomosesAnastomoses may be created between two segments of bowel in a multitude of ways. The geometry of the anastomosis may be end-to-end, end-to-side, side-to-end, or side-to-side. The anas-tomotic technique may be hand-sewn or stapled (Fig. 29-13). The submucosal layer of the intestine provides the strength of the bowel wall and must be incorporated in the anastomosis to assure healing. The choice of anastomosis depends on the opera-tive anatomy and surgeon preference. Although many surgeons advocate one method over another, none has been proven to be superior. Accurate approximation of two well-vascularized, healthy limbs of bowel without tension in a normotensive, well-nourished patient almost always results in a good outcome. Anastomoses at highest risk of leak or stricture are those that are in the distal rectal or anal canal, involve irradiated or dis-eased intestine including perforation with peritoneal soilage, are inadvertently fashioned above a partial distal obstruction, or are performed in malnourished, immunosuppressed, or ill patient.Anastomotic Configuration End-to-End An end-to-end anastomosis can be performed when two segments of bowel are roughly the same caliber. This technique is most often employed in rectal resections, but may be used for colocolostomy or small bowel anastomoses.End-to-Side An end-to-side configuration is useful when one limb of bowel is larger than the other. This most commonly occurs in the setting of chronic obstruction.Side-to-End A side-to-end anastomosis is used when the proxi-mal bowel is of smaller caliber than the distal bowel. Ileorectal anastomoses commonly make use of this configuration. A side-to-end anastomosis may have a less tenuous blood supply than an end-to-end anastomosis.Side-to-Side A side-to-side anastomosis allows a large, well-vascularized connection to be created on the antimesenteric side of two segments of intestine. This technique is commonly used in ileocolic and small bowel anastomoses.Anastomotic Technique Hand-Sutured Technique Any of the configurations described earlier may be created using a hand-sutured or stapled technique. Hand-sutured anastomoses may be single layer, using either running or interrupted stitches, or double layer. A double-layer anastomosis usually consists of a continuous inner layer and an interrupted outer layer. Suture material may be either perma-nent or absorbable. After distal rectal or anal canal resection, a transanal, hand-sewn coloanal anastomosis may be necessary to restore bowel continuity. This can be done in conjunction with an anal canal mucosectomy to allow the anastomosis to be cre-ated at the dentate line.Stapled Techniques Linear cutting/stapling devices are used to divide the bowel and to create side-to-side anastomoses. The anastomosis may be reinforced with interrupted sutures if desired. Circular cutting/stapling devices can create end-to-end, end-to-side, or side-to-end anastomoses. These instruments are particularly useful for creating low rectal or anal canal anas-tomoses where the anatomy of the pelvis makes a hand-sewn anastomosis technically difficult or impossible.Following resection of the colorectum, a stapled end-to-end colorectal, coloanal canal, or ileal pouch–anal canal anasto-mosis may be created by one of two techniques. With the open purse-string technique, the distal rectal stump purse-string is placed by hand, and the assembled circular stapler is inserted into the anus and guided up to the rectal purse-string. The sta-pler is opened, and the distal purse-string is tied. A purse-string is placed in the distal end of the proximal colon; the proximal colon is placed over the anvil and the purse-string tightened. The stapler is closed and fired (Fig. 29-14). With the alterna-tive double-staple technique, the distal rectum or anal canal is closed with a transverse staple line. The circular stapler is inserted through the anus without its anvil until the cartridge effaces the transverse staple line. The stapler is opened, causing the trocar to perforate through the rectal stump adjacent to the transverse staple line. The anastomosis in then completed as described earlier (see Fig. 29-11). If the stapler cannot advance to the end of the rectal stump, further dissection of the stump may be necessary to optimize tissue apposition. After firing and removing the stapler, the resulting anastomotic rings should be inspected to ensure that they are full-thickness and concentric, and in cases of rectal cancer, the distal anastomotic ring should be sent to pathology as a specimen (true distal margin). A gap in an anastomotic ring suggests that the circular staple line is incomplete and the anastomosis should be reinforced with suture circumferentially, if technically feasible. A temporary proximal ileostomy may be indicated as well. Most surgeons will also leak test an anastomosis by instilling water or saline into the pelvis and insufflating the rectum with air via a proc-toscope to looking or alternatively instilling methylene blue or betadine into the rectum to look for extravasation. A leak test strongly suggests a defect and/or disruption of the anastomosis. As such, the suture should line reinforced and sometimes may require reanastomosis.23Brunicardi_Ch29_p1259-p1330.indd 127423/02/19 2:29 PM 1275COLON, RECTUM, AND ANUSCHAPTER 29Ostomies and Preoperative Stoma PlanningDepending on the clinical situation, a stoma may be temporary or permanent. It may be end-on or a loop. However, regardless of the indication for a stoma, placement and construction are crucial for function.The preoperative preparation of a patient who is expected to require a stoma should include a consultation with an enter-ostomal therapy (ET) nurse. ET nurses are specially trained and credentialed by the Wound, Ostomy, and Continence Nurses Society. Preoperative planning includes counseling, education, and stoma siting. Postoperatively, the ET nurse assists with local skin care and pouching. Other considerations in stoma planning include evaluation of other medical conditions that may impact on a patient’s ability to manage a stoma (e.g., eyesight, manual dexterity). Family or other caregivers can prove invaluable in caring for these patients.Preoperative stoma siting is crucial for a patient’s postop-erative function and quality of life. A poorly placed stoma can result in leakage and skin breakdown. Ideally, a stoma should be placed in a location that the patient can easily see and manipulate, within the rectus muscle, and below the belt line (Fig. 29-15). Because the abdominal landmarks in a supine, anesthetized patient may be dramatically different from those in an awake, standing, or sitting patient, the stoma site should always be marked with a tattoo, skin scratch, or permanent marker preoperatively, if possible. In an emergency operation where the stoma site has not been marked, an attempt should be made to place a stoma within the rectus muscle and away from 3BCAFigure 29-13. A. Sutured end-to-end colocolic anastomosis. B. Sutured end-to-side ileocolic anastomosis. C. Stapled side-to-side, functional end-to-end ileocolic anastomosis. (Reproduced with permission from Bell RH, Rikkers LF, Mulholland M: Digestive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)Brunicardi_Ch29_p1259-p1330.indd 127523/02/19 2:29 PM 1276SPECIFIC CONSIDERATIONSPART IIboth the costal margin and iliac crest. In emergencies, placement high on the abdominal wall is preferred to a more caudal site.For all stomas, a circular skin incision is created, and the subcutaneous tissue is dissected to the level of the anterior rec-tus sheath. The anterior rectus sheath is incised in a cruciate fashion, the muscle fibers separated bluntly, and the posterior sheath identified and incised. Care should be taken to avoid injuring and causing bleeding from the inferior epigastric artery and vein. The size of the defect depends on the size of the bowel used to create the stoma, but it should be as small as possible without compromising the intestinal blood supply (usually the width of two to three fingers). The bowel is then brought through the defect and secured with sutures. The abdominal incision is usually closed and dressed prior to maturing the stoma to avoid contaminating the wound. In order to make appliance use easier, a protruding nipple is fashioned by everting the bowel. Three or four interrupted absorbable sutures are placed through the edge of the bowel, then through the serosa, approximately 2 cm proximal to the edge, and then through the dermis (Brooke tech-nique). After the stoma is everted, the mucocutaneous junction is sutured circumferentially with interrupted absorbable suture (Fig. 29-16).Ileostomy Temporary Ileostomy A temporary ileostomy is often used to “protect” an anastomosis that is at risk for leakage (low in the rectum, in an irradiated field, in an immunocompromised or malnourished patient, and during some emergency operations). In this setting, the stoma is often constructed as a loop ileostomy (see Fig. 29-12). A segment of distal ileum is brought through the defect in the abdominal wall as a loop. An enterotomy is created and the stoma matured as described earlier. The loop may be secured with or without an underlying rod. A divided loop may also be created by firing a linear cutting/stapler across the distal limb of the loop flush with the skin followed by mat-uration of the proximal limb of the loop. This technique pre-vents incomplete diversion that occasionally occurs with a loop ileostomy.The advantage of a loop or divided loop ileostomy is that subsequent closure can often be accomplished without a formal laparotomy. An elliptical incision is created around the stoma and the bowel gently dissected free of the subcutaneous tissues and fascia. A hand-sewn or stapled anastomosis can then be created and the intestine returned to the peritoneal cavity. This ABDCEFigure 29-14. Technique of end-to-end colorectal anastomosis using a circular stapler. A. The patient is in modified lithotomy position. B. After resection of the rectosigmoid and placement of purse-string sutures proximally and distally, the stapler is inserted into the anal canal and opened. C. Rectal purse-string suture is tied to secure the rectal stump to the rod of the stapler, and the colonic purse-string is tied to secure the colon to the anvil of the stapler. D. The stapler is closed and fired. E. The stapler is removed, leaving a circular stapled end-to-end anastomosis.Brunicardi_Ch29_p1259-p1330.indd 127623/02/19 2:29 PM 1277COLON, RECTUM, AND ANUSCHAPTER 29avoids a long laparotomy incision and generally is well toler-ated. The timing of ileostomy closure should take into account anastomotic healing as well as the patient’s overall condition. A flexible endoscopy exam and a contrast enema (Gastrografin) are recommended prior to closure to ensure that the anastomosis has not leaked and is patent. A patient’s nutritional status should be optimized. Because the timing of adjuvant chemotherapy effects survival, cancer patients receiving adjuvant chemother-apy usually should defer ileostomy closure until completion of treatment.Permanent Ileostomy A permanent ileostomy is sometimes required after total proctocolectomy or in patients with obstruc-tion. An end ileostomy is the preferred configuration for a per-manent ileostomy because a symmetric protruding nipple can be fashioned more easily than with a loop ileostomy (see Fig. 29-16). The end of the small intestine is brought through the abdominal wall defect and matured. Stitches are often used to secure the bowel to the posterior fascia.Complications of Ileostomy Stoma necrosis may occur in the early postoperative period and is usually caused by skel-etonizing the distal small bowel and/or creating an overly tight fascial defect. Limited mucosal necrosis above the fascia may be treated expectantly, but necrosis below the level of the fascia requires surgical revision. Stoma retraction may occur early or late and may be exacerbated by obesity. Local revision may be necessary. The creation of an ileostomy bypasses the fluid-absorbing capability of the colon, and dehydration with fluid and electrolyte abnormalities is not uncommon. Ideally, ileos-tomy output should be maintained at less than 1500 mL/d to avoid this problem. Bulk agents and opioids (Lomotil, Imodium, tincture of opium) are useful. The somatostatin analogue, octreotide, has been used with varying success in this setting. Skin irritation can also occur, especially if the stoma appliance fits poorly. Skin-protecting agents and custom pouches can help to solve this problem. Obstruction may occur intra-abdominally or at the site where the stoma exits the fascia. Parastomal hernia is less common after an ileostomy than after a colostomy but can cause poor appliance fitting, pain, obstruction, or strangulation. In general, symptomatic parastomal hernias should be repaired. A variety of techniques to repair these hernias have been described, including local repair (either with or without mesh), laparoscopic repair, and stoma resiting. Prolapse is a rare, late complication and is often associated with a parastomal hernia.Colostomy. Most colostomies are created as end colostomies rather than loop colostomies (Fig. 29-17). The bulkiness of the colon makes a loop colostomy awkward for use of an appliance, and prolapse is more likely with this configuration. Most colos-tomies are created on the left side of the colon. An abdominal wall defect is created and the end of the colon mobilized through it. Because a protruding stoma is considerably easier to pouch, colostomies should also be matured in a Brooke fashion. The distal bowel may be brought through the abdominal wall as a mucus fistula or left intra-abdominally as a Hartmann’s pouch. Tacking the distal end of the colon to the abdominal wall or tagging it with permanent suture can make identification of the stump easier if the colostomy is closed at a later date. Closure of an end colostomy has traditionally required a laparotomy, but increasingly minimally invasive techniques have been adopted. The stoma is dissected free of the abdominal wall and the distal bowel identified. An end-to-end anastomosis is then created.MidlineincisionStoma siteLateral edgeof rectus sheathWaistlineHiplineFigure 29-15. Marking of an ideal site for ileostomy. (Reproduced with permission from Bell RH, Rikkers LF, Mulholland M: Diges-tive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)BACFigure 29-16. Brooke ileostomy. A. Four sutures incorporating the cut end of the ileum, the seromuscular layer at the level of the anterior rectus fascia, and the subcuticular edge of the skin are placed at 90° to each other. B. The sutures are tied to produce sto-mal eversion, and (C) simple sutures from the cut edge of the bowel to the subcuticular tissue complete the maturation of the ileostomy. (Reproduced with permission from Bell RH, Rikkers LF, Mulhol-land M: Digestive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)Brunicardi_Ch29_p1259-p1330.indd 127723/02/19 2:29 PM 1278SPECIFIC CONSIDERATIONSPART IIComplications of Colostomy Colostomy necrosis may occur in the early postoperative period and results from an impaired vascular supply (skeletonization of the distal colon or a tight fas-cial defect). Like ileostomy necrosis, limited suprafascial necro-sis may be followed expectantly, but necrosis below the fascia requires surgery. Retraction may also occur but is less problem-atic with a colostomy than with an ileostomy because the stool is less irritating to the skin than succus entericus. Obstruction is unusual, but may also occur. Parastomal hernia is the most common late complication of a colostomy and requires repair if it is symptomatic. Prolapse occurs rarely, but is more com-mon with a loop colostomy. Interestingly, it is almost always the efferent limb of the loop that prolapses. Dehydration is rare after colostomy, and skin irritation is less common than with ileostomy.Functional ResultsFunction following segmental colonic resection and primary anastomosis is generally excellent. A small percentage of patients following subtotal or total colectomy and ileosigmoid or ileorectal anastomosis may experience diarrhea and bowel frequency. This is especially true if the patient is elderly, if sig-nificant length of small bowel has been resected, and if residual proctocolitis is poorly controlled. In general, the more distal the anastomosis, the greater is the risk of troublesome diarrhea and frequency. However, some patients develop significant diarrhea after right colectomy due to malabsorption of bile acids; in these cases, bile acid binding resins (e.g., cholestyramine) sometimes can be helpful.Function following anterior resection is highly dependent on the level of anastomosis, the use of preor postoperative pelvic radiation, and underlying sphincter function. Following low anterior or extended low anterior resection, some surgeons prefer to construct a short (5-cm) colon J-pouch to anastomose to the distal rectum or anal canal in order to increase the capacity of the neorectum. The reservoirs are thought to lessen urgency, frequency, and incontinence, but some patients have difficulty initiating defecation, and long-term superiority over a “straight” anastomosis has yet to be proven. In addition, these reservoirs can be technically difficult, especially in an obese male with a narrow pelvis.20-22The physical and psychological problems associated with a permanent Brooke ileostomy led to development of the con-tinent Kock pouch ileostomy. Unfortunately, complications, especially complications related to valve slippage, are common. Despite variations of technique designed to improve the func-tion of the continent ileostomy, most surgeons have abandoned this operation and instead perform restorative proctocolectomy with ileal pouch–anal anastomosis.Although ileal pouch–anal reconstruction is anatomically appealing, functional outcome is far from perfect.26,27 Patients should be counseled to expect 8 to 10 bowel movements per day. Up to 50% have some degree of nocturnal incontinence. Pouchitis (see the following paragraph) occurs in nearly 50% of patients who undergo the operation for chronic ulcerative colitis, and small bowel obstruction is not uncommon. Other less com-mon complications include difficulties with pouch evacuation, pouch-perineal and/or pouch-vaginal fistula, and anal stricture. Pouch failure rate averages 5% to 10%. Patients who are sub-sequently diagnosed with Crohn’s disease have a considerably higher pouch failure rate (approximately 50%), whereas patients with indeterminate colitis have an intermediate pouch failure rate (15–20%). Despite these drawbacks, the vast majority of patients are satisfied and prefer ileal pouch–anal reconstruction to permanent ileostomy.26,27Pouchitis is an inflammatory condition that affects both ileoanal pouches and continent ileostomy reservoirs. The inci-dence of pouchitis ranges from 30% to 55%. Symptoms include increased diarrhea, hematochezia, abdominal pain, fever, and malaise. Diagnosis is made endoscopically with biopsies. Dif-ferential diagnosis includes infection and undiagnosed Crohn’s disease. The etiology of pouchitis is unknown. Some believe pouchitis results from fecal stasis within the pouch, but empty-ing studies are not confirmatory. Antibiotics (metronidazole ± ciprofloxacin) are the mainstays of therapy, and most patients will respond rapidly to either oral preparations or enemas. Some patients develop chronic pouchitis that necessitates ongoing suppressive antibiotic therapy. Salicylate and corticosteroid enemas have also been used with some success.28-31 Biologic agents targeting TNFa (infliximab, vedulizumab, ustekinumab) are also being studied.32-34 Reintroduction of normal flora by ingestion of probiotics and/or an elemental diet have been sug-gested as a possible treatment in refractory cases. Occasionally, pouch excision is necessary to control the symptoms of chronic pouchitis.30Anesthesia ConsiderationsLocal Anesthesia. Many anorectal procedures can be per-formed with local anesthetic alone. Intravenous sedation is often provided to calm the patient. Injection of 0.5% lidocaine (short acting) and 0.25% bupivacaine (long acting) into the perianal skin, sphincter, and area around the pudendal nerves usually provides an adequate block. The addition of dilute epinephrine decreases bleeding and prolongs the anesthetic effect.Regional Anesthesia. Epidural, spinal, and caudal anesthetics can be used for anorectal procedures and transanal resections. In patients with severe medical comorbidity, regional anesthesia may occasionally be used for laparotomy and colectomy. Post-operative epidural anesthesia provides excellent pain relief and improves pulmonary function especially after an open operation.General Anesthesia. General anesthesia is required for the vast majority of intra-abdominal procedures. Patients should Figure 29-17. Intraperitoneal end colostomy.Brunicardi_Ch29_p1259-p1330.indd 127823/02/19 2:29 PM 1279COLON, RECTUM, AND ANUSCHAPTER 29undergo a thorough preoperative cardiovascular evaluation. In patients with significant comorbid disease, an anesthesia con-sultation may be appropriate.Positioning. Most abdominal colectomies can be performed in the supine position. Anterior resection and APR require lithotomy positioning to facilitate the pelvic dissection and mobilization of the splenic flexure. Adequate padding should be provided for the patient’s sacrum, and care should be taken to avoid stirrup pressure on the peroneal nerves.Anorectal procedures may be performed in lithotomy or in the prone jackknife position. Some surgeons prefer the prone jackknife position because exposure may be better, espe-cially for anterior lesions. Distal posterior lesions can usually be accessed from either position, but more proximal posterior lesions are better accessed in the prone position.Operative PreliminariesBowel Preparation. The rationale for bowel preparation is that decreasing the bacterial load in the colon and rectum will decrease the incidence of postoperative infection. Mechanical bowel preparation uses cathartics to rid the colon of solid stool the night before surgery. The most commonly used regimens include polyethylene glycol (PEG) solutions or magnesium citrate. PEG solutions require patients to drink a large volume of fluid and may cause bloating and nausea. Magnesium citrate solutions are generally better tolerated but are more likely to cause fluid and electrolyte abnormalities. Both are equally efficacious in bowel cleansing. Preparatory formulations have been recently introduced in tablet form in an attempt to improve tolerance. However, these methods of bowel cleansing require ingestion of 40 or more tablets with water over several hours. To date, these formulations have not been proven to be superior to the more traditional products. Antibiotic prophylaxis also is recommended. The addition of oral antibiotics to the preopera-tive mechanical bowel preparation has been thought to decrease postoperative infection by further decreasing the bacterial load of the colon. A recent analysis of the Surgical Care Improve-ment Project-1 (SCIP-1) suggests that oral antibiotics reduce postoperative wound infection, especially if a mechanical bowel preparation is not used.35-37Longstanding, convincing data support the efficacy of parenteral antibiotic prophylaxis at the time of surgery. Broad-spectrum parenteral antibiotic(s) with activity against aerobic and anaerobic enteric pathogens should be administered just prior to the skin incision and redosed as needed depending on the length of the operation. There is no proven benefit to using antibiotics postoperatively after an uncomplicated colectomy.Despite widespread use of mechanical bowel prepara-tion, the necessity of bowel cleansing prior to colectomy has been questioned. European surgeons in particular have advo-cated abandoning this practice. Arguments against mechani-cal bowel preparation include dehydration and electrolyte abnormalities that often result from bowel cleansing, as well as the risk of spillage of liquid stool left over from the “prep.” Arguments in favor of mechanical bowel preparation included easier manipulation of an “empty” colon (especially in mini-mally invasive procedures) and avoidance of a “stool column” above an anastomosis, especially in the pelvis. Interestingly, a recent meta-analysis of 14 randomized controlled trials sug-gested that mechanical bowel preparation does not prevent sur-gical site infection and should be abandoned in clinical practice. However, these studies did not include the use of oral antibiotics in the mechanical preparation groups, and further studies will be needed to determine the optimal preparation regimen.35-37Ureteral Stents. Ureteral stents may be useful for identify-ing the ureters intraoperatively and are placed via cystoscopy after the induction of general anesthesia and removed at the end of the operation. Stents can be invaluable during reopera-tive pelvic surgery or when there is significant retroperitoneal inflammation (such as complicated diverticulitis), as well as in obese patients. Lighted stents may be helpful in laparoscopic and robotic resections. Patients often have transient hematuria postoperatively, but major complications are rare.Multidisciplinary Teams. Patients with complex colorectal disease often benefit from a multidisciplinary approach to their care. Patients with pelvic floor disorders (especially inconti-nence) often require evaluation by both a colorectal surgeon and a urologist or urogynecologist. Preoperative evaluation of cancer patients by a medical oncologist and/or radiation oncolo-gist is crucial for planning either neoadjuvant or adjuvant ther-apy. Intraoperatively, complex pelvic resections often require the involvement of not only a colorectal surgeon but also a urologist, gynecologic oncologist, neurosurgeon, and/or plastic surgeon. Radiation oncologists should be involved in the opera-tion if brachytherapy catheters are to be placed for intracavi-tary radiation or if intraoperative radiation therapy is planned. Rarely, psychiatric disorders may manifest as colorectal prob-lems (especially functional disorders and chronic pain), and involvement of a psychiatrist or psychologist may be beneficial.INFLAMMATORY BOWEL DISEASEGeneral ConsiderationsEpidemiology. Inflammatory bowel disease includes ulcer-ative colitis, Crohn’s disease, and indeterminate colitis. Ulcerative colitis occurs in 8 to 15 people per 100,000 in the United States and Northern Europe. The incidence is consid-erably lower in Asia, Africa, and South America, and among the nonwhite population in the United States. Ulcerative coli-tis incidence peaks during the third decade of life and again in the seventh decade of life. The incidence of Crohn’s disease is slightly lower, 1 to 5 people per 100,000. Crohn’s disease also affects Northern European and Caucasian populations dispro-portionately. Crohn’s disease has a similar bimodal incidence, with most cases occurring between ages 15 to 30 years and ages 60 to 70 years.38 In 15% of patients with inflammatory bowel disease, differentiation between ulcerative colitis and Crohn’s colitis is impossible; these patients are classified as having indeterminate colitis.Etiology. Inflammatory bowel disease is a multifactorial con-dition that includes environmental, genetic, and immune causal elements; the variation in disease distributions and severity, as well as the differential responses to medical therapy, reflect a complex pathophysiology that is not reducible to a single cause. Nonetheless, there are several consistent observations among IBD populations that allow some degree of generalization. The consistent differences in IBD incidence between different geographic regions strongly suggest that environmental factors such as diet and exposure to microorganisms have a causal role. Alcohol and oral contraceptive use have also been implicated, as has tobacco use, in the etiology and exacerbation of Crohn’s disease.Brunicardi_Ch29_p1259-p1330.indd 127923/02/19 2:29 PM 1280SPECIFIC CONSIDERATIONSPART IIIBD is a genetic disease, though one that is polygenic, explaining why IBD frequently affects multiple family mem-bers across more than one generation, while also explaining the large number of genes implicated in the development of IBD. Most of the data on the genetics of IBD focus on Crohn’s disease. Although ulcerative colitis has an association with at least 20 genetic loci based on genome-wide association studies (GWAS), this form of IBD has a weaker genetic link than does Crohn’s disease. Approximately 10% to 30% of IBD patients will have at least one other family member also affected by IBD.39,40 Additionally, there is 50% disease concordance among monozygotic twins and a 10% disease concordance among dizy-gotic twins.41Many of the genetic variants most consistently associated with IBD involve loci involved in innate immune function. These include NOD2 (nucleotide-binding oligomerization domain-containing protein 2), which is located on chromosome 16 and which is responsible for coordinating the function of several genes leading to the production of proinflammatory cytokines in response to gut microbes. This genetic variant is arguably the most strongly associated with IBD, being strongly connected with Crohn’s disease, although it is also associated with severe pouchitis in patients with a history of ulcerative colitis.42,43The ATG16L1 gene is located on chromosome 2, and its product is involved in the immune response to muramyl dipep-tide, a component of both gram-positive and gram-negative bac-teria that is recognized by the immune system. A related gene, IRGM, is located on chromosome 5, and its product is pivotal in the interferon-gamma–mediated clearance of intracellular pathogens. Variants in this gene are associated with a higher incidence of ileocolic resections in Crohn’s disease patients.42-44Patients with IBD appear to have a chronic immune dys-regulation, which may lead to an interplay with gut microbes which are also present in non-IBD patients, but which elicit pathologic immune responses in the IBD population leading to chronic, idiopathic inflammation of the alimentary tract. Bacteria such as Mycobacterium paratuberculosis and Liste-ria monocytogenes, as well as viruses such as paramyxovirus and measles virus, have been suggested as having a role in the development of Crohn’s disease. With the decreased cost of sequencing and with the expansion of reference databases for identification of organisms, microbiome studies have been applied to the study of IBD patients, both to learn about the pathogenesis of IBD as well as for disease prognostication. Recent studies have identified an abundance of Serratia marc-escens, E coli, and Candida tropicalis in the guts of patients with Crohn’s disease. In a study of 543 stool samples, patients with ulcerative colitis and primary sclerosing cholangitis (PSC) demonstrated a distinct bacterial community structure, with an enrichment of bacteria belonging to the Veillonella genus, which is associated with several diseases characterized by inflammation and fibrosis.45-49A defect in the gut mucosal barrier, which increases exposure to intestinal microbes as well as proinflammatory substances, is a potential etiologic factor related to immune dys-regulation. An autoimmune mechanism has also been postulated. Although there is no clear evidence linking an immunologic disorder to inflammatory bowel disease, the similarity of many of the extraintestinal manifestations to rheumatologic disorders has made this theory attractive. In summary, IBD is primarily characterized by intestinal inflammation, and medical therapy is focused on reducing or preventing that inflammation.45-49Pathology and Differential Diagnosis. Although ulcer-ative colitis and Crohn’s colitis share many pathologic and clinical similarities, these conditions can be differentiated in 85% of patients. Ulcerative colitis is a mucosal process in which the colonic mucosa and submucosa are infiltrated with inflammatory cells. The mucosa may be atrophic, and crypt abscesses are common. Endoscopically, the mucosa is fre-quently friable and may possess multiple inflammatory pseu-dopolyps. In long-standing ulcerative colitis, the colon may be foreshortened and the mucosa replaced by scar. In quies-cent ulcerative colitis, the colonic mucosa may appear normal both endoscopically and microscopically. Ulcerative colitis may affect the rectum (proctitis), rectum and sigmoid colon (proctosigmoiditis), rectum and left colon (left-sided colitis), or the rectum and varying lengths of colon extending proxi-mal to the splenic flexure (pancolitis). Ulcerative colitis does not primarily affect the small intestine, but the terminal ileum may demonstrate inflammatory changes (“backwash ileitis”). A key feature of ulcerative colitis is the continuous involve-ment of the rectum and colon; rectal sparing or skip lesions suggest a diagnosis of Crohn’s disease. Symptoms are related to the degree of mucosal inflammation and the extent of coli-tis. Patients typically complain of bloody diarrhea and crampy abdominal pain. Proctitis may produce tenesmus. Severe abdominal pain and fever raise the concern of fulminant coli-tis or toxic megacolon. Physical findings are nonspecific and range from minimal abdominal tenderness and distention to frank peritonitis. In the nonemergent setting, the diagnosis is typically made by colonoscopy and mucosal biopsy.In contrast to ulcerative colitis, Crohn’s disease is a trans-mural inflammatory process that can affect any part of the gas-trointestinal tract from mouth to anus. Mucosal ulcerations, an inflammatory cell infiltrate, and noncaseating granulomas are characteristic pathologic findings. Chronic inflammation may ultimately result in fibrosis, strictures, and fistulas in either the colon or small intestine. The endoscopic appearance of Crohn’s colitis is characterized by deep serpiginous ulcers and a “cob-blestone” appearance. Skip lesions and rectal sparing are com-mon. Symptoms of Crohn’s disease depend on the severity of inflammation and/or fibrosis and the location of inflammation in the gastrointestinal tract. Acute inflammation may produce diarrhea, crampy abdominal pain, and fever. Strictures may pro-duce symptoms of obstruction. Weight loss is common, both because of obstruction and from protein loss. Perianal Crohn’s disease may present with pain, swelling, and drainage from fis-tulas or abscesses. Physical findings are also related to the site and severity of disease.In 15% of patients with colitis from inflammatory bowel disease, differentiation of ulcerative colitis from Crohn’s colitis is impossible either grossly or microscopically (indeterminate colitis).50 These patients typically present with symptoms similar to ulcerative colitis. Endoscopic and pathologic findings usually include features common to both diseases. Increasingly, sero-logic markers have been employed to differentiate ulcerative colitis from Crohn’s disease. The anti-Saccharomyces cerevi-siae antibody (ASCA) and perinuclear anticytoplasmic antibody (pANCA) may be useful in differentiating these two processes but require prospective study.50 Further differential diagnoses include infectious colitides, especially cytomegalovirus (CMV), Campylobacter jejuni, Entamoeba histolytica, toxigenic E Coli, C difficile, Neisseria gonorrhoeae, Salmonella, and Shigella species.Brunicardi_Ch29_p1259-p1330.indd 128023/02/19 2:29 PM 1281COLON, RECTUM, AND ANUSCHAPTER 29Extraintestinal Manifestations. The liver is a common site of extracolonic disease in inflammatory bowel disease. Fatty infiltration of the liver is present in 40% to 50% of patients, and cirrhosis is found in 2% to 5%. Fatty infiltration may be reversed by medical or surgical treatment of colonic disease, but cirrhosis is irreversible. Primary sclerosing cholangitis is a progressive disease characterized by intraand extrahepatic bile duct stric-tures. Forty percent to 60% of patients with primary sclerosing cholangitis have ulcerative colitis. Colectomy will not reverse this disease, and the only effective therapy is liver transplanta-tion. Pericholangitis is also associated with inflammatory bowel disease and may be diagnosed with a liver biopsy. Bile duct carcinoma is a rare complication of long-standing inflamma-tory bowel disease. Patients who develop bile duct carcinoma in the presence of inflammatory bowel disease are, on average, 20 years younger than other patients with bile duct carcinoma.51Arthritis also is a common extracolonic manifesta-tion of inflammatory bowel disease, and the incidence is 20 times greater than in the general population. Arthritis usually improves with treatment of the colonic disease. Sacroiliitis and ankylosing spondylitis are associated with inflammatory bowel disease, although the relationship is poorly understood. Medical and surgical treatment of the colonic disease does not impact symptoms.51Erythema nodosum is seen in 5% to 15% of patients with inflammatory bowel disease and usually coincides with clini-cal disease activity. Women are affected three to four times more frequently than men. The characteristic lesions are raised, red, and predominantly on the lower legs. Pyoderma gangreno-sum is an uncommon but serious condition that occurs almost exclusively in patients with inflammatory bowel disease. The lesion begins as an erythematous plaque, papule, or bleb, usu-ally located on the pretibial region of the leg and occasionally near a stoma. The lesions progress and ulcerate, leading to a painful, necrotic wound. Pyoderma gangrenosum may respond to resection of the affected bowel in some patients. In others, this disorder is unaffected by treatment of the underlying bowel disease. One of the challenges in managing pyoderma is that this manifestation of IBD exhibits pathergy, where the disease will manifest and have its severity exacerbated by the creation of surgical-sites. Depending on the circumstances, a history or the presence of pyoderma should prompt consideration for avoid-ance of a stoma.51Up to 10% of patients with inflammatory bowel dis-ease will develop ocular lesions. These include uveitis, iritis, episcleritis, and conjunctivitis, as well as macular degenerative, hyperpigmented pigmented epithelium (CHRPE). They usu-ally develop during an acute exacerbation of the inflammatory bowel disease. The etiology is unknown.51Principles of Nonoperative Management. Medical therapy for inflammatory bowel disease focuses on decreasing inflam-mation and alleviating symptoms, and many of the agents used are the same for both ulcerative colitis and Crohn’s disease. In general, mild to moderate flares may be treated in the outpatient setting. More severe signs and symptoms mandate hospitaliza-tion. Pancolitis generally requires more aggressive therapy than limited disease. Because ulcerative proctitis and proctosigmoid-itis are limited to the distal large intestine, topical therapy with salicylate and/or corticosteroid suppositories and enemas can be extremely effective. Systemic therapy is rarely required in these patients.Salicylates Sulfasalazine (Azulfidine), 5-acetyl salicylic acid (5-ASA), and related compounds are first-line agents in the medical treatment of mild to moderate inflammatory bowel dis-ease. These compounds decrease inflammation by inhibition of cyclooxygenase and 5-lipoxygenase in the gut mucosa. They require direct contact with affected mucosa for efficacy. Mul-tiple preparations are available for administration to different sites in the small intestine and colon (sulfasalazine, mesalamine [Pentasa, Asacol, Rowasa]).Antibiotics Antibiotics are often used to decrease the intra-luminal bacterial load in Crohn’s disease. Metronidazole has been reported to improve Crohn’s colitis and perianal disease, but the evidence is weak. Fluoroquinolones may also be effec-tive in some cases. In the absence of fulminant colitis or toxic megacolon, antibiotics are not used to treat ulcerative colitis.Corticosteroids Corticosteroids (either oral or parenteral) are a key component of treatment for an acute exacerbation of either ulcerative colitis or Crohn’s disease. Corticosteroids are nonspecific inhibitors of the immune system, and 75% to 90% of patients will improve with the administration of these drugs. However, corticosteroids have a number of serious side effects, and use of these agents should be limited to the short-est course possible. In addition, corticosteroids should be used judiciously in children because of the potential adverse effect on growth. Failure to wean corticosteroids is a relative indication for surgery.Because of the systemic effects of corticosteroids, an effort has been made to develop drugs that act locally and have limited systemic absorption. Agents such as budesonide, beclomethasone dipropionate, and tixocortol pivalate undergo rapid hepatic degradation that significantly decreases systemic toxicity. Budesonide is available as an oral preparation. Corti-costeroid enemas provide effective local therapy for proctitis and proctosigmoiditis and have fewer side effects than systemic corticosteroids.Immunomodulating Agents Azathioprine and 6-mercatopu-rine (6-MP) are antimetabolite drugs that interfere with nucleic acid synthesis and thus decrease proliferation of inflammatory cells. These agents are useful for treating ulcerative colitis and Crohn’s disease in patients who have failed salicylate therapy or who are dependent on, or refractory to, corticosteroids. It is important to note, however, that the onset of action of these drugs takes 6 to 12 weeks, and concomitant use of corticoste-roids almost always is required.Cyclosporine is an immunosuppressive agent that inter-feres with T-lymphocyte function. While cyclosporine is not routinely used to treat inflammatory bowel disease, up to 80% of patients with an acute flare of ulcerative colitis will improve with its use. However, the majority of these patients will ulti-mately require colectomy. Cyclosporine is also occasionally used to treat exacerbations of Crohn’s disease, and approxi-mately two-thirds of patients will note some improvement. Improvement is generally apparent within 2 weeks of beginning cyclosporine therapy. Long-term use of cyclosporine is limited by its significant toxicities (e.g., nephrotoxicity, hirsutism, gum hypertrophy).Methotrexate is a folate antagonist that also has been used to treat inflammatory bowel disease. Although the efficacy of this agent is unproven, there are reports that more than 50% of patients will improve with administration of this drug.52Brunicardi_Ch29_p1259-p1330.indd 128123/02/19 2:29 PM 1282SPECIFIC CONSIDERATIONSPART IIBiologic Agents In an effort to improve treatment for steroid-refractory inflammatory bowel disease, a class of agents has been developed based on inhibition of tumor necrosis factor alpha (TNF-α). Intravenous infusion of these agents decreases inflammation systemically. Infliximab is a monoclonal antibody directed against TNF-α and was the first biologic agent used to treat Crohn’s disease. More than 50% of patients with moderate to severe Crohn’s disease will improve with infliximab therapy. Infliximab is a chimeric monoclonal antibody directed against TNF-α and it was the first biologic agent used to treat Crohn’s disease. Based on the ACCENT I and II trials, infliximab was associated with a greater incidence of clinical remission, the ability to discontinue corticosteroids, and a longer length of remission compared to placebo.53,54 There are also multiple studies demonstrating an improvement in fistulizing perianal Crohn’s disease, although studies define “improvement” in a variety of ways, some of which do not require fistula to com-pletely involute.53-56Because infliximab is a chimera partially consisting of mouse antibody, human antibodies directed against infliximab can mitigate the efficacy of this drug. For this reason, adali-mumab and certolizumab, that have no nonhuman component, were developed. These two drugs can be administered by sub-cutaneous injection, allowing patients to self-administer these therapies and to avoid the cost and inconvenience of presenting to an infusion center. The ultimate goal of biologic agents, just as with other medical therapies for IBD, is mucosal healing.The use of biologic agents for the treatment of ulcerative colitis is an area where opinions between gastroenterologists and surgeons are more divergent. Unlike in the case of Crohn’s dis-ease, there is a putative surgical cure for ulcerative colitis, which casts the risks of long-term immunosuppression in a different light than in the setting of Crohn’s where there is no curative therapy available. For patients with moderate to severe ulcer-ative colitis not responding to other medical therapies, there is evidence supporting the use of infliximab (UC SUCCESS) and adalimumab (ULTRA I AND II). The use of infliximab as rescue therapy for inpatients with severe, steroid-dependent ulcerative colitis has more recently been investigated. Though gastroen-terologists may view this intervention as maintenance therapy that begins in an inpatient setting only to be continued following hospital discharge, it is still unclear whether inpatient infliximab is even a reliable bridge to elective surgery. Many of the stud-ies supporting inpatient rescue therapy with infliximab did not focus their analyses on patients with extensive (pan) colitis, the group at highest risk for requiring an unplanned admission due to a disease flare, and the subgroup of ulcerative colitis patients most likely to fail rescue therapy and to require colectomy.57-62Whether the preoperative use of biologics is associated with a higher incidence of postoperative complications is a matter of contention. There are individual studies demonstrat-ing a higher incidence of postoperative sepsis, intra-abdominal abscess and readmissions for patients undergoing ileocolectomy for Crohn’s disease who also received preoperative infliximab within three months of surgery. Systematic reviews on this topic, primarily focusing on Crohn’s disease, have concluded that perioperative infliximab may or may not be associated with a higher incidence of postoperative complications, with most of these complications being infectious in nature.63Nutrition Patients with inflammatory bowel disease are often malnourished. Abdominal pain and obstructive symptoms may decrease oral intake. Diarrhea can cause significant protein loss. Ongoing inflammation produces a catabolic physiologic state. Parenteral nutrition should be strongly considered early in the course of therapy for either Crohn’s disease or ulcerative colitis. The nutritional status of the patient also should be considered when planning operative intervention, and nutritional param-eters such as serum albumin, prealbumin, and transferrin should be assessed. In extremely malnourished patients, especially those who are also being treated with corticosteroids, creation of a stoma is often safer than a primary anastomosis.Ulcerative ColitisUlcerative colitis is a dynamic disease characterized by remis-sions and exacerbations. The clinical spectrum ranges from an inactive or quiescent phase to low-grade active disease to ful-minant disease. The onset of ulcerative colitis may be insidi-ous, with minimal bloody stools, or the onset can be abrupt, with severe diarrhea and bleeding, tenesmus, abdominal pain, and fever. The severity of symptoms depends on the degree and extent of inflammation. Although anemia is common, massive hemorrhage is rare. Physical findings are often nonspecific.The diagnosis of ulcerative colitis is almost always made endoscopically. Because the rectum is invariably involved, proctoscopy may be adequate to establish the diagnosis. The earliest manifestation is mucosal edema, which results in a loss of the normal vascular pattern. In more advanced disease, char-acteristic findings include mucosal friability and ulceration. Pus and mucus may also be present. While mucosal biopsy is often diagnostic in the chronic phase of ulcerative colitis, biopsy in the acute phase will often reveal only nonspecific inflammation. Evaluation with colonoscopy or barium enema during an acute flare is contraindicated because of the risk of perforation.Barium enema has been used to diagnose chronic ulcer-ative colitis and to determine the extent of disease. However, this modality is less sensitive than colonoscopy and may not detect early disease. In long-standing ulcerative colitis, the colon is foreshortened and lacks haustral markings (“lead pipe” colon). Because the inflammation in ulcerative colitis is purely mucosal, strictures are highly uncommon. Any stricture diag-nosed in a patient with ulcerative colitis must be presumed to be malignant until proven otherwise.Indications for Surgery. Indications for surgery in ulcer-ative colitis may be emergent or elective. Emergency surgery is required for patients with massive life-threatening hemorrhage, toxic megacolon, or fulminant colitis who fail to respond rap-idly to medical therapy. Patients with signs and symptoms of fulminant colitis should be treated aggressively with bowel rest, hydration, broad-spectrum antibiotics, and parenteral corticoste-roids. Colonoscopy and barium enema are contraindicated, and antidiarrheal agents should be avoided. Deterioration in clinical condition or failure to improve within 24 to 48 hours mandates surgery.Indications for elective surgery include intractability despite maximal medical therapy and high-risk development of major complications of medical therapy such as aseptic necrosis of joints secondary to chronic steroid use. Elective surgery also is indicated in patients at significant risk of developing colorec-tal carcinoma. The risk of malignancy increases with pancolonic disease and the duration of symptoms and is approximately 2% after 10 years, 8% after 20 years, and 18% after 30 years. Unlike sporadic colorectal cancers, carcinoma developing in the con-text of ulcerative colitis is more likely to arise from areas of Brunicardi_Ch29_p1259-p1330.indd 128223/02/19 2:29 PM 1283COLON, RECTUM, AND ANUSCHAPTER 29flat dysplasia and may be difficult to diagnose at an early stage. For this reason, it is recommended that patients with longstanding ulcerative colitis undergo colonoscopic surveillance with multiple (40–50), random biopsies to identify dysplasia before invasive malignancy develops. However, the adequacy of this type of screening is controversial. Recently, magnifying chro-moendoscopy has been used to improve sensitivity. This tech-nique uses topical dyes that are applied to the colonic mucosa at the time of endoscopy (Lugol’s solution, methylene blue, indigo carmine, and others). These dyes highlight contrast between normal and dysplastic epithelium, allowing more precise biopsy of suspicious areas.64,65 Surveillance is recommended annu-ally after 8 years in patients with pancolitis, and annually after 15 years in patients with left-sided colitis. Although low-grade dysplasia was long thought to represent minimal risk, more recent studies show that invasive cancer may be present in up to 20% of patients with low-grade dysplasia. For this rea-son, any patient with dysplasia should be advised to undergo proctocolectomy. Controversy exists over whether prophylac-tic proctocolectomy should be recommended for patients who have had chronic ulcerative colitis for greater than 10 years in the absence of dysplasia. Proponents of this approach note that surveillance colonoscopy with multiple biopsies samples only a small fraction of the colonic mucosa, and dysplasia and carci-noma are often missed. Opponents cite the relatively low risk of progression to carcinoma (approximately 2.4%) if all biopsies lack dysplasia. Neither approach has been shown definitively to decrease mortality from colorectal cancer.Operative ManagementEmergent Operation In a patient with fulminant colitis or toxic megacolon, total abdominal colectomy with end ileostomy (with or without a mucus fistula), rather than total proctocolectomy, is recommended. Although the rectum is invariably diseased, most patients improve dramatically after an abdominal colectomy, and this operation avoids a difficult and time-consuming pelvic dissection in a critically ill patient. Rarely, a loop ileostomy and decompressing colostomy may be necessary if the patient is too unstable to withstand colectomy. Definitive surgery may then be undertaken at a later date once the patient has recovered. Complex techniques, such as an ileal pouch–anal reconstruction, generally are contraindicated in the emergent setting. However, massive hemorrhage that includes bleeding from the rectum may necessitate proctectomy and creation of either a permanent ileostomy or an ileal pouch–anal anastomosis.Elective Operation Elective resection for ulcerative colitis usually is performed for refractory inflammation and/or the risk of malignancy (dysplasia). Because of the risk of ongo-ing inflammation, the risk of malignancy, and the availability of restorative proctocolectomy, most surgeons recommend operations that include resection of the rectum. Total procto-colectomy with end ileostomy has been the “gold standard” for treating patients with chronic ulcerative colitis. This operation removes the entire affected intestine and avoids the functional disturbances associated with ileal pouch–anal reconstruction. Most patients function well physically and psychologically after this operation. Total proctocolectomy with continent ileostomy (Kock’s pouch) was developed to improve function and quality of life after total proctocolectomy, but morbidity is significant, and restorative proctocolectomy is generally preferred today. Since its introduction in 1980, restorative proctocolectomy with ileal pouch–anal anastomosis has become the procedure of choice for most patients who require total proctocolectomy but wish to avoid a permanent ileostomy (see Figs. 29-11 and 29-12).66 Abdominal colectomy with ileorectal anastomosis may be appropriate for a patient with indeterminate colitis and rectal sparing.Crohn’s DiseaseSimilar to ulcerative colitis, Crohn’s disease is characterized by exacerbations and remissions. Crohn’s disease, however, may affect any portion of the intestinal tract, from mouth to anus. Diagnosis may be made by colonoscopy or esophagogastroduo-denoscopy or by barium small bowel study or enema, depending on which part of the intestine is most affected. The presence of skip lesions is key in differentiating Crohn’s colitis from ulcer-ative colitis, and rectal sparing occurs in approximately 40% of patients. The most common site of involvement of Crohn’s dis-ease is the terminal ileum and cecum (ileocolic Crohn’s disease), followed by the small bowel, and then by the colon and rectum. Perianal and anal canal Crohn’s disease manifest by complex anal fistulae and/or abscesses, anal ulcers, and large skin tags may be the initial site of presentation in up to 4% of cases.Indications for Surgery. Because Crohn’s disease is cur-rently incurable and because it can affect any part of the gas-trointestinal tract, the therapeutic rationale is fundamentally different from that of ulcerative colitis. Ulcerative colitis may be cured by removal of the affected intestinal segment (the colon and rectum). In Crohn’s disease, it is impossible to remove all the at-risk intestine; therefore, surgical therapy is reserved for complications of the disease.Crohn’s disease may present as an acute inflammatory process or as a chronic fibrotic process. During the acute inflam-matory phase, patients may present with intestinal inflamma-tion complicated by fistulae and/or intra-abdominal abscesses. Maximal medical therapy should be instituted, including antiinflammatory medications, bowel rest, and antibiotics. Parenteral nutrition should be considered if the patient is malnourished. Most intra-abdominal abscesses can be drained percutaneously with the use of CT scan guidance. Although the majority of these patients will ultimately require surgery to remove the dis-eased segment of bowel, these interventions allow the patient’s condition to stabilize, nutrition to be optimized, and inflamma-tion to decrease prior to embarking on a surgical resection. Once an operation is undertaken, fistulae generally require resection of the segment of bowel with active Crohn’s disease; the sec-ondary sites of the fistula are often otherwise normal and do not generally require resection after division of the fistula. Simple closure of the secondary fistula site usually suffices.Chronic fibrosis may result in strictures in any part of the gastrointestinal tract. Because the fibrotic process is gradual, free perforation proximal to the obstructing stricture is rare. Chronic strictures almost never improve with medical therapy. Strictures may be treated with resection or stricturoplasty. Distal ileal strictures are sometimes amenable to colonoscopic balloon dilatation. Optimal timing for surgery should take into account the patient’s underlying medical and nutritional status.Once an operation is undertaken for Crohn’s disease, sev-eral principles should guide intraoperative decision making. In general, a laparotomy for Crohn’s disease should be performed through a midline incision because of the possible need for a stoma. Laparoscopy is also increasingly used in this setting. Because many patients with Crohn’s disease often will require multiple operations, the length of bowel removed should be Brunicardi_Ch29_p1259-p1330.indd 128323/02/19 2:29 PM 1284SPECIFIC CONSIDERATIONSPART IIminimized. Bowel should be resected to an area with grossly nor-mal margins; frozen sections are not necessary. Finally, a primary anastomosis may be created safely if the patient is medically stable, nutritionally replete, and taking few immunosuppressive medications. Creation of a stoma should be strongly considered in any patient who is hemodynamically unstable, septic, malnour-ished, or receiving high-dose immunosuppressive therapy and among patients with extensive intra-abdominal contamination.Ileocolic and Small Bowel Crohn’s Disease. The terminal ileum and cecum are involved in Crohn’s disease in up to 41% of patients; the small intestine is involved in up to 35% of patients. The most common indications for surgery are internal fistula or abscess (30–38% of patients) and obstruction (35–37% of patients). Psoas abscess may result from ileocolic Crohn’s dis-ease. Sepsis should be controlled with percutaneous drainage of abscess(es) and antibiotics, if possible. Parenteral nutrition may be necessary in patients with chronic obstruction. The extent of resection depends on the amount of involved intestine. Short segments of inflamed small intestine and right colon should be resected and a primary anastomosis created if the patient is sta-ble, nutrition is adequate, and immunosuppression is minimal. Isolated chronic strictures should also be resected. In patients with multiple fibrotic strictures that would require extensive small bowel resection, stricturoplasty is a safe and effective alternative to resection. Short strictures are amenable to a trans-verse stricturoplasty, while longer strictures may be treated with a side-to-side small bowel anastomosis (Fig. 29-18).ABCDEFigure 29-18. Alternative stricturoplasty techniques. A. A short stricture is opened along the antimesenteric surface of the bowel wall. B. The enterotomy is closed transversely. C. A long stricture is opened along the antimesenteric surface of the bowel wall. D. The bowel is folded into an inverted “U.” E. A side-to-side anastomosis is made. (Reproduced with permission from Corman ML. Colon & Rectal Surgery, 2nd ed. Philadelphia, PA: Lippincott Williams & Wilkins; 1989.)Brunicardi_Ch29_p1259-p1330.indd 128423/02/19 2:29 PM 1285COLON, RECTUM, AND ANUSCHAPTER 29Risk of recurrence after resection for ileocolic and small bowel Crohn’s disease is high. More than 50% of patients will experience a recurrence within 10 years, and the majority of these will require a second operation.Crohn’s Colitis. Crohn’s disease of the large intestine may present as fulminant colitis or toxic megacolon. In this set-ting, treatment is identical to treatment of fulminant colitis and toxic megacolon secondary to ulcerative colitis. Resuscitation and medical therapy with bowel rest, broad-spectrum antibiot-ics, and parenteral corticosteroids should be instituted. If the patient’s condition worsens or fails to rapidly improve, total abdominal colectomy with end ileostomy is recommended. An elective proctectomy may be required if the patient has refrac-tory Crohn’s proctitis. Alternatively, if the rectum is spared, an ileorectal anastomosis may be appropriate once the patient has recovered.Other indications for surgery in chronic Crohn’s colitis are intractability, complications of medical therapy, and risk of or development of malignancy. Unlike ulcerative colitis, Crohn’s colitis may be segmental, and rectal sparing is often observed. A segmental colectomy may be appropriate if the remaining colon and/or rectum appear normal. An isolated colonic stricture may also be treated by segmental colectomy. Although it was long thought that Crohn’s disease did not increase the risk of colorectal carcinoma, it is now recognized that Crohn’s colitis (especially pancolitis) carries nearly the same risk for cancer as ulcerative colitis. Annual surveillance colonoscopy with multiple biopsies is recommended for patients with long-standing Crohn’s colitis (>7 years in duration). As in ulcerative colitis, dysplasia is an indication for total proctocolectomy. Ileal pouch–anal reconstruction is not recommended in these patients because of the risk for development of Crohn’s disease within the pouch and the high risk of complications, such as fistula, abscess, stricture, pouch dysfunction, and pouch failure.Anal and Perianal Crohn’s Disease. Anal and perianal mani-festations of Crohn’s disease are very common and occur in 35% of all patients with Crohn’s disease. Isolated anal Crohn’s disease is uncommon, affecting only 3% to 4% of patients. Detection of anal Crohn’s disease, therefore, should prompt evaluation of the remainder of the gastrointestinal tract.The most common perianal lesions in Crohn’s disease are skin tags that are minimally symptomatic. Fissures are also common. Typically, a fissure from Crohn’s disease is partic-ularly deep or broad and perhaps better described as an anal ulcer. These fissures are often multiple and located in a lateral position rather than anterior or posterior midline as seen in an idiopathic fissure in ano. A classic-appearing fissure in ano located laterally should raise the suspicion of Crohn’s disease. Perianal abscess and fistulas are common and can be particu-larly challenging. Fistulas tend to be complex and often have multiple tracts (Fig. 29-19). Hemorrhoids are not more common in patients with Crohn’s disease than in the general population, although many patients tend to attribute any anal or perianal symptom to “hemorrhoids.”Treatment of anal and perianal Crohn’s disease focuses on alleviation of symptoms. Perianal skin irritation from diarrhea often responds to medical therapy directed at small bowel or colonic disease. In general, skin tags and hemorrhoids should not be excised unless they are extremely symptomatic because of the risk of creating chronic, nonhealing wounds. Fissures may respond to local or systemic therapy; sphincterotomy is relatively contraindicated because of the risk of creating a chronic, nonhealing wound and because of the increased risk of incontinence in a patient with diarrhea from underlying colitis or small bowel disease. Anal ulcers associated with Crohn’s dis-ease are usually not very painful unless there is an underlying abscess. Thus, in patients with significant anal pain, an exami-nation under anesthesia is indicated to exclude an underlying abscess or fistula and to assess the rectal mucosa. In the absence of active Crohn’s proctitis, one can proceed cautiously with a partial internal sphincterotomy if the examination under anes-thesia reveals a classic-appearing posterior or anterior fissure and anal stenosis.Recurrent abscess(es) or complex anal fistulae should raise the possibility of Crohn’s disease. Treatment focuses on control of infection, delineation of complex anatomy, treat-ment of underlying mucosal disease, and sphincter preserva-tion. Abscesses often can be drained locally, and mushroom catheters are useful for maintaining drainage. Endoanal ultra-sound and pelvic MRI are useful for mapping complex fistulous tracts. Liberal use of setons can control many fistulas and avoid division of the sphincter. Many patients with anal Crohn’s dis-ease function well with multiple setons left in place for years. Endoanal advancement flaps may be considered for definitive therapy if the rectal mucosa is uninvolved but will not heal due to rectal inflammation. In 10% to 15% of cases, intractable peri-anal sepsis requires proctectomy.Rectovaginal fistula can be a particularly difficult problem in these patients. A rectal or vaginal mucosal advancement flap may be used if the rectal mucosa appears healthy and scarring of the rectovaginal septum is minimal. Occasionally, proctec-tomy is the best option for women with highly symptomatic rectovaginal fistulae. Although proximal diversion is often employed to protect complex perianal reconstruction, there is no evidence that diversion alone increases healing of anal and perianal Crohn’s disease.Medical treatment of underlying proctitis with salicylate and/or corticosteroid enemas may be helpful; however, control of infection is the primary goal of therapy. Metronidazole has been used with some success in this setting. Anti-TNF-α agents (infliximab and adalimumab) have shown some efficacy in heal-ing chronic fistulas secondary to Crohn’s disease. The success of these agents has led to a concerted effort to identify other 4Figure 29-19. Photograph of a patient with multiple perianal fistulas secondary to Crohn’s disease.Brunicardi_Ch29_p1259-p1330.indd 128523/02/19 2:29 PM 1286SPECIFIC CONSIDERATIONSPART IIimmunomodulators that might prove useful. Proinflammatory cytokines such as interleukin-12 and interferon-γ are potential targets. Inhibition of immune cell migration has also been sug-gested as an approach. However, it is of paramount importance to drain any and all abscesses before initiating immunosuppres-sive therapy such as corticosteroids or anti-TNF-α monoclonal antibodies.54-55Indeterminate ColitisApproximately 15% of patients with inflammatory bowel dis-ease manifest clinical and pathologic characteristics of both ulcerative colitis and Crohn’s disease. Endoscopy, barium enema, and biopsy may be unable to differentiate ulcerative colitis from Crohn’s colitis in this setting. The indications for surgery are the same as those for ulcerative colitis: intracta-bility, complications of medical therapy, and risk of or devel-opment of malignancy. In the setting of indeterminate colitis in a patient who prefers a sphincter-sparing operation, a total abdominal colectomy with end ileostomy may be the best initial procedure. Pathologic examination of the entire colon may then allow a more accurate diagnosis. If the diagnosis suggests ulcer-ative colitis, an ileal pouch–anal anastomosis procedure can be performed. If the diagnosis remains in question, the safest surgi-cal option is completion proctectomy with end ileostomy (simi-lar to Crohn’s colitis). Ileal pouch–anal reconstruction may also be considered with the understanding that the pouch failure rate is between 15% and 20%.50DIVERTICULAR DISEASEDiverticular disease is a clinical term used to describe the pres-ence of symptomatic diverticula. Diverticulosis refers to the presence of diverticula without inflammation. Diverticulitis refers to inflammation and infection associated with diverticula. The majority of colonic diverticula are false diverticula in which the mucosa and muscularis mucosa have herniated through the colonic wall. These diverticula occur between the teniae coli, at points where nutrient arterial blood vessels penetrate the colonic wall (presumably creating an area of relative weakness in the colonic muscle). They are thought to be pulsion diverticula resulting from high intraluminal pressure. Diverticular bleeding can be massive but usually is self-limited. True diverticula, which comprise all layers of the bowel wall, are rare and are usually congenital in origin.Diverticulosis is extremely common in the United States and Europe. It is estimated that half of the population older than age 50 years has colonic diverticula. The sigmoid colon is the most common site of diverticulosis (Fig. 29-20). Diverticulosis is thought to be an acquired disorder, but the etiology is poorly understood. The most accepted theory is that a lack of dietary fiber results in smaller stool volume, requiring high intraluminal pressure and high colonic wall tension for propulsion. Chronic contraction then results in muscular hypertrophy and develop-ment of the process of segmentation in which the colon acts like separate segments instead of functioning as a continuous tube. As segmentation progresses, the high pressures are directed radi-ally toward the colon wall rather than to development of propul-sive waves that move stool distally. The high radial pressures directed against the bowel wall create pulsion diverticula. A loss of tensile strength and a decrease in elasticity of the bowel wall with age have also been proposed etiologies. Although none of these theories has been proven, a high-fiber diet does appear to decrease the incidence of diverticulosis. Although diverticulosis is common, most cases are asymptomatic, and complications occur in the minority of people with this condition.Inflammatory Complications (Diverticulitis)Diverticulitis refers to inflammation and infection associated with a diverticulum and is estimated to occur in 10% to 25% of people with diverticulosis. Peridiverticular and pericolic infection results from a perforation (either macroscopic or microscopic) of a diverticulum, which leads to contamination, inflammation, and infection. The spectrum of disease ranges from mild, uncomplicated diverticulitis that can be treated in the outpatient setting, to free perforation and diffuse peritonitis that requires emergency laparotomy. Most patients present with left-sided abdominal pain, with or without fever, and leukocytosis. A mass may be present. Plain radiographs are useful for detect-ing free intra-abdominal air. CT scan is extremely useful for defining pericolic inflammation, phlegmon, or abscess. Contrast enemas and/or endoscopy are relatively contraindicated because of the risk of perforation. The differential diagnosis includes malignancy, ischemic colitis, infectious colitis, and inflamma-tory bowel disease.Uncomplicated Diverticulitis. Uncomplicated diverticulitis is characterized by left lower quadrant pain and tenderness. CT findings include pericolic soft tissue stranding, colonic wall thickening, and/or phlegmon. Most patients with uncomplicated diverticulitis will respond to outpatient therapy with broadspectrum oral antibiotics and a low-residue diet. Antibiotics should be continued for 7 to 10 days. About 10% to 20% of patients with more severe pain, tenderness, fever, and leuko-cytosis are treated in the hospital with parenteral antibiotics Figure 29-20. Diverticulosis of sigmoid colon on barium enema. (Reproduced with permission from James EC, Corry RJ, Perry JCF: Basic Surgical Practice. Philadelphia, PA: Hanley & Belfus; 1987.)Brunicardi_Ch29_p1259-p1330.indd 128623/02/19 2:29 PM 1287COLON, RECTUM, AND ANUSCHAPTER 29and bowel rest. Most patients improve within 48 to 72 hours. Failure to improve may suggest abscess formation. CT can be extremely useful in this setting, and many pericolic abscesses can be drained percutaneously. Deterioration in a patient’s clini-cal condition and the development of peritonitis are indications for laparotomy.Most patients with uncomplicated diverticulitis will recover without surgery, and 50% to 70% will have no further episodes. It has long been believed that the risk of complications increases with recurrent disease. For this reason, elective sig-moid colectomy has often been recommended after the second episode of diverticulitis, especially if the patient has required hospitalization. Resection has often been recommended after the first episode in very young patients and is often recommended after the first episode of complicated diverticulitis. These gen-eral guidelines have been questioned in recent years, and more recent studies suggest that the risk of complications and/or need for emergent resection does not increase with recurrent disease. Moreover, the rate of complications is rare after elective sur-gery and recurrences do not increase the rate of complications. As such, the rate of resection in all patients, including young patients and those with complicated disease, has decreased.67-71Many surgeons now will not advise colectomy even after two documented episodes of diverticulitis assuming the patient is completely asymptomatic and that carcinoma has been excluded by colonoscopy. Immunosuppressed patients are gen-erally still advised to undergo colectomy after a single episode of documented diverticulitis. Medical comorbidities should be considered when evaluating a patient for elective resection, and the risks of recurrent disease should be weighed against the risks of the operation.69,70 Because colon carcinoma may present in an identical fashion to diverticulitis (either complicated or uncom-plicated), all patients must be evaluated for malignancy after resolution of the acute episode. Colonoscopy is recommended 4 to 6 weeks after recovery. Inability to exclude malignancy is another indication for resection.In the elective setting, a sigmoid colectomy with a primary anastomosis is the procedure of choice. The resection should always be extended to the rectum distally because the risk of recurrence is high if a segment of sigmoid colon is retained. The proximal extent of the resection should include all thick-ened or inflamed bowel; however, resection of all diverticula is unnecessary. Increasingly, laparoscopy is being used for elec-tive sigmoid colectomy for diverticular disease.Complicated Diverticulitis. Complicated diverticulitis includes diverticulitis with abscess, obstruction, diffuse peri-tonitis (free perforation), or fistulas between the colon and adjacent structures. Colovesical, colovaginal, and coloenteric fistulas are long-term sequelae of complicated diverticulitis. The Hinchey staging system is often used to describe the severity of complicated diverticulitis: Stage I includes colonic inflam-mation with an associated pericolic abscess; stage II includes colonic inflammation with a retroperitoneal or pelvic abscess; stage III is associated with purulent peritonitis; and stage IV is associated with fecal peritonitis. Treatment depends on the patient’s overall clinical condition and the degree of peritoneal contamination and infection. Small abscesses (<2 cm in diame-ter) may be treated with parenteral antibiotics. Larger abscesses are best treated with CT-guided percutaneous drainage (Fig. 29-21) and antibiotics.72 Many of these patients will ultimately require resection, but percutaneous drainage may allow a one-stage, elective procedure and may obviate the need for colec-tomy if full recovery follows the drainage.Urgent or emergent laparotomy may be required if an abscess is inaccessible to percutaneous drainage, if the patient’s condition deteriorates or fails to improve, or if the patient pres-ents with free intra-abdominal air or peritonitis. In almost all cases, an attempt should be made to resect the affected seg-ment of bowel. Patients with small, localized pericolic or pel-vic abscesses (Hinchey stages I and II) may be candidates for a sigmoid colectomy with a primary anastomosis (a one-stage operation). Among patients with larger abscesses, peritoneal soiling, or peritonitis, sigmoid colectomy with end colostomy and Hartmann’s pouch is the most commonly used procedure.71 Success also has been reported after sigmoid colectomy, pri-mary anastomosis, with or without on-table lavage, and proxi-mal diversion (loop ileostomy). This option may be appropriate in stable patients and offers the great advantage that the subse-quent operation to restore bowel continuity is simpler than is BAFigure 29-21. A. Computed tomography scan demonstrating pelvic abscess from perforated diverticular disease. B. Posterolateral computed tomography–guided drainage of abdominal abscess from perforated diverticular disease. (Used with permission from Charles O. Finne III, MD, Minneapolis, MN.)Brunicardi_Ch29_p1259-p1330.indd 128723/02/19 2:29 PM 1288SPECIFIC CONSIDERATIONSPART IItakedown of a Hartmann’s pouch. The presence of inflammation and phlegmon may increase the risk of ureteral damage during mobilization of the sigmoid colon, and preoperative placement of ureteral catheters can be invaluable. In extremely unstable patients, or in the presence of such severe inflammation that resection would harm adjacent organs, proximal diversion and local drainage have been employed. However, this approach is generally avoided because of high morbidity and mortality rates, along with the requirement for multiple operations. More recently, several studies have suggested that laparoscopic lavage and drainage without bowel resection may be safe and effective even in the presence of free perforation. However, a 20% risk of surgical reoperation can be expected.73,74Obstructive symptoms occur in approximately 67% of patients who develop acute diverticulitis, and complete obstruc-tion occurs in 10%. Patients with incomplete obstruction often respond to fluid resuscitation, nasogastric suction, and gentle, low-volume water or Gastrografin enemas. Relief of obstruction allows full bowel preparation and elective resection. A high-volume oral bowel preparation is contraindicated in the pres-ence of obstructive symptoms. Obstruction that does not rapidly respond to medical management mandates laparotomy. Sigmoid colectomy with end colostomy is the safest procedure to per-form in this setting. However, colectomy and primary anasto-mosis, with or without on-table lavage (depending on extent of fecal load in the proximal colon), and proximal diversion may be appropriate if the patient is stable and the proximal and distal bowel appear healthy.Approximately 5% of patients with complicated diverticu-litis develop fistulas between the colon and an adjacent organ. Colovesical fistulas are most common, followed by colovaginal and coloenteric fistulas. Colocutaneous fistulas are a rare com-plication of diverticulitis. Two key points in the evaluation of fistulas are to define the anatomy of the fistula and exclude other diagnoses. Contrast enema and/or small bowel stud-ies are extremely useful in defining the course of the fistula. CT scan can identify associated abscesses or masses. The dif-ferential diagnosis includes malignancy, Crohn’s disease, and radiation-induced fistulas. While Crohn’s disease and radiation injury may be suspected based on the patient’s medical history, colonoscopy or sigmoidoscopy usually is required to rule out malignancy. In addition, in a patient who has received radia-tion therapy, a fistula must be considered to be recurrent cancer until proven otherwise. Once the anatomy of the fistula has been defined and other diagnoses excluded, operative management should include resection of the affected segment of the colon involved with diverticulitis (usually with a primary anastomo-sis) and simple repair of the secondarily involved organ. Sus-picion of carcinoma may mandate a wider, en bloc resection.HemorrhageBleeding from a diverticulum results from erosion of the peri-diverticular arteriole and may result in massive hemorrhage. Most significant lower gastrointestinal hemorrhage occurs in elderly patients in whom both diverticulosis and angiodyspla-sia are common. Consequently, the exact bleeding source may be difficult to identify. Fortunately, in 80% of patients, bleed-ing stops spontaneously. Clinical management should focus on resuscitation and localization of the bleeding site as described for lower gastrointestinal hemorrhage. Colonoscopy may occa-sionally identify a bleeding diverticulum that may then be treated with epinephrine injection or cautery. Angiography may be diagnostic and therapeutic in this setting. In the rare instance in which diverticular hemorrhage persists or recurs, laparotomy and segmental colectomy may be required.Giant Colonic DiverticulumGiant colonic diverticula are extremely rare. Most occur on the antimesenteric side of the sigmoid colon. Patients may be asymptomatic or may present with vague abdominal com-plaints such as pain, nausea, or constipation. Plain radiographs may suggest the diagnosis. Barium enema is usually diagnos-tic. Complications of a giant diverticulum include perforation, obstruction, and volvulus. Resection of the involved colon and diverticulum is recommended.Right-Sided DiverticulaThe cecum and ascending colon infrequently are involved in diverticulosis coli. Even more uncommon is a true solitary diverticulum, which contains all layers of the bowel wall and is thought to be congenital in origin. Right-sided diverticula occur more often in younger patients than do left-sided diver-ticula and are more common in people of Asian descent than in other populations. Most patients with right-sided diverticula are asymptomatic. However, diverticulitis does occur occasionally. Because patients are young and present with right lower quad-rant pain, they are often thought to suffer from acute appendici-tis, and the diagnosis of right-sided diverticulitis is subsequently made in the operating room. If there is a single large diverticu-lum and minimal inflammation, a diverticulectomy may be performed, but an ileocecal resection is usually the preferred operation in this setting. Hemorrhage rarely occurs and should be treated in the same fashion as hemorrhage from a left-sided diverticulum.ADENOCARCINOMA AND POLYPSIncidenceColorectal carcinoma is the most common malignancy of the gastrointestinal tract. Over 130,000 new cases are diagnosed annually in the United States, and more than 50,000 patients die of this disease each year, making colorectal cancer the third most lethal cancer in the United States.75The incidence is similar in men and women and has remained fairly constant over the past 20 years; however, the widespread adoption of current national screening programs is gradually decreasing the incidence of this common and lethal disease in people over 50 years of age. However, people younger than 50 have been experiencing and increase incidence and worse mortality.75 Early detection and improvements in medical and surgical care are thought to be responsible for the decreasing mortality of colorectal cancer observed in recent years.Epidemiology (Risk Factors)Identification of risk factors for development of colorectal can-cer is essential to establish screening and surveillance programs in appropriately targeted populations.Aging. Aging is the dominant risk factor for colorectal cancer, with incidence rising steadily after age 50 years. More than 90% of cases diagnosed are in people older than age 50 years. This is the rationale for initiating screening tests of asymptomatic patients at average risk of developing colorectal cancer at age 50 years. However, individuals of any age can develop colorec-tal cancer, so symptoms such as a significant change in bowel Brunicardi_Ch29_p1259-p1330.indd 128823/02/19 2:29 PM 1289COLON, RECTUM, AND ANUSCHAPTER 29habits, rectal bleeding, melena, unexplained anemia, or weight loss require a thorough evaluation.Hereditary Risk Factors. Approximately 80% of colorectal cancers occur sporadically, while 20% arise in patients with a known family history of colorectal cancer. Advances in the understanding of these familial disorders have led to interest in early diagnosis using genetic testing. Because of the medical, legal, and ethical considerations that are involved in this type of testing, all patients should be offered genetic counseling if a familial syndrome is suspected.Environmental and Dietary Factors. The observation that colorectal carcinoma occurs more commonly in populations that consume diets high in animal fat and low in fiber has led to the hypothesis that dietary factors contribute to carcinogenesis. A diet high in saturated or polyunsaturated fats increases risk of colorectal cancer, while a diet high in oleic acid (olive oil, coco-nut oil, fish oil) does not increase risk. Animal studies suggest that fats may be directly toxic to the colonic mucosa and thus may induce early malignant changes. In contrast, a diet high in vegetable fiber appears to be protective. A correlation between alcohol intake and incidence of colorectal carcinoma has also been suggested. Ingestion of calcium; selenium; vitamins A, C, and E; carotenoids; and plant phenols may decrease the risk of developing colorectal cancer. Obesity and sedentary lifestyle dramatically increase cancer-related mortality in a number of malignancies, including colorectal carcinoma. This knowl-edge is the basis for primary prevention strategies to eliminate colorectal cancer by altering diet and lifestyle.76Inflammatory Bowel Disease. Patients with long-standing colitis from inflammatory bowel disease are at increased risk for the development of colorectal cancer. It is hypothesized that chronic inflammation predisposes the mucosa to malignant changes, and there is some evidence that degree of inflamma-tion influences risk. In general, the duration and extent of colitis correlate with risk. Other factors thought to increase risk include the presence of primary sclerosing cholangitis and family his-tory of colorectal cancer.Other Risk Factors. Cigarette smoking is associated with an increased risk of colonic adenomas, especially after more than 35 years of use. Patients with ureterosigmoidostomy may also be at increased risk for both adenoma and carcinoma formation.77Acromegaly, which is associated with increased levels of circulating human growth hormone and insulin-like growth factor-1, increases risk as well. Pelvic irradiation may increase the risk of developing rectal carcinoma. However, it is unclear whether this represents a direct effect of radiation damage or is instead a correlation between the development of rectal cancer and a history of another pelvic malignancy; for example, among patients who develop prostate cancer and are treated with radia-tion, the risk of rectal cancer increases significantly.78Pathogenesis of Colorectal CancerGenetic Defects. An intense research effort has focused on elucidating the genetic defects and molecular abnormalities asso-ciated with the development and progression of colorectal adeno-mas and carcinoma. Mutations may cause activation of oncogenes (K-ras) and/or inactivation of tumor suppressor genes (APC, deleted in colorectal carcinoma [DCC], p53). Colorectal carcinoma is thought to develop from adenomatous polyps by accumulation of these mutations in what has come to be known as the adenoma-carcinoma sequence (Fig. 29-22).9,79Defects in the APC gene were first described in patients with Familial Adenomatous Polyposis (FAP). By investigating these families, characteristic mutations in the APC gene were identified. They are now known to be present in 80% of spo-radic colorectal cancers as well.The APC gene is a tumor suppressor gene. Mutations in both alleles are necessary to initiate polyp formation. The majority of mutations are premature stop codons, which result in a truncated APC protein. In FAP, the site of mutation correlates with the clinical severity of the disease. For example, mutations in either the 3′ or 5′ end of the gene result in attenuated forms of FAP (AFAP), whereas mutations in the center of the gene result in more virulent disease. Thus, knowledge of the specific mutation in a family may help guide clinical decision-making.10APC inactivation alone does not result in a carcinoma. Instead, this mutation sets the stage for the accumulation of genetic damage that results in malignancy. Additional mutations may include activation or inactivation of a variety of genes.One of the most commonly involved genes in colorectal cancer is K-ras. K-ras, a signaling molecule in the epidermal growth factor receptor (EGFR) pathway, is classified as a proto-oncogene because mutation of only one allele will perturb the cell cycle. The K-ras gene product is a G-protein involved in intracellular signal transduction. When active, K-ras binds gua-nosine triphosphate (GTP); hydrolysis of GTP to guanosine diphosphate (GDP) then inactivates the G-protein. Mutation of KRAS results in an inability to hydrolyze GTP, thus leaving the G-protein permanently in the active form. It is thought that this then leads to uncontrolled cell division. Because K-ras muta-tion results in uncontrolled downstream signaling, anti-EGFR agents are ineffective in treating K-ras mutant tumors. As such, K-ras mutation status is important in deciding when to utilize anti-EGFR therapies. Other EGFR signaling molecules such as BRAF have also been implicated in colorectal cancer patho-genesis and progression, and ongoing research is focusing on elucidating their roles in this disease.5NormalepitheliumDysplasticepitheliumEarlyadenomaIntermediateadenomaLateadenomaCarcinomaMetastasisAPCK-RASDCC/DPC4/JV18?p53Other changesFigure 29-22. Schematic showing progression from normal colonic epithelium to carcinoma of the colon.Brunicardi_Ch29_p1259-p1330.indd 128923/02/19 2:29 PM 1290SPECIFIC CONSIDERATIONSPART IIAnother common mutation occurs in the MYH gene on chromosome 1p. MYH is a base excision repair gene, and bial-lelic deletion results in changes in other downstream molecules. Since its discovery, MYH mutations have been associated with an AFAP phenotype in addition to sporadic cancers. Unlike APC gene mutations that are expressed in an autosomal domi-nant pattern, the requirement for biallelic mutation in MYH results in an autosomal recessive pattern of inheritance.80,81The tumor suppressor gene p53 has been well character-ized in a number of malignancies. The p53 protein appears to be crucial for initiating apoptosis in cells with irreparable genetic damage. Mutations in p53 are present in 75% of colorectal cancers.Deletion of the tumor suppressor phosphatase and ten-sin homolog (PTEN) appears to be involved in a number of hamartomatous polyposis syndromes. Deletions in PTEN have been identified in juvenile polyposis, Peutz-Jeghers syndrome, Cowden’s syndrome, and PTEN hamartoma syndrome, in addi-tion to multiple endocrine neoplasia type IIB. Peutz-Jeghers syndrome is also associated with mutation in STK11, a serine-threonin kinase gene. The genetic changes that underlie serratis polyposis syndrome(s) are currently poorly understood.9Genetic Pathways. The mutations involved in colorectal cancer pathogenesis and progression are now recognized to accumulate via one of three major genetic pathways: the loss of heterozygosity (LOH; chromosomal instability) pathway, the microsatellite instability (MSI) pathway, and the CpG island methylation (CIMP; serrated methylated) pathway.The Loss of Heterozygosity Pathway The LOH pathway is characterized by chromosomal deletions and tumor aneu-ploidy. Eighty percent of colorectal carcinomas appear to arise from mutations in the LOH pathway. This pathway was first described in patients with FAP in whom mutations of the APC gene were found to be inherited.Another example of LOH occurs in the region of chromo-some 18q. This region has been found to be deleted in up to 70% of colorectal cancers. Two tumor suppressor genes, DCC and SMAD4, are located in this region, and as such, deletion of 18q may result in the loss of one or both of these genes. DCC is a tumor suppressor gene, and loss of both alleles is required for malignant degeneration. The main role of this molecule appears to be in the central nervous system, where it is involved in neural differentiation and axonal migration. This observa-tion has led to the hypothesis that DCC may be involved in differentiation and cellular adhesion in colorectal cancer, but this theory remains unproven. DCC mutations are present in more than 70% of colorectal carcinomas and may negatively impact prognosis. SMAD4 functions in the signaling cascade of transforming growth factor beta and beta-catenin (also a down-stream effector of the APC gene). Loss of either of these genes is thought to promote cancer progression.82The Microsatellite Instability Pathway. Many of the remain-ing colorectal carcinomas are thought to arise from mutations in the MSI pathway, which is characterized by errors in mismatch repair during DNA replication. These errors in mismatch repair were first described in Hereditary Nonpolyposis Colon Cancer (HNPCC; Lynch syndrome) Lynch 9, but are now recognized to be present in many sporadic tumors as well. A number of genes have been identified that appear to be crucial for recognizing and repairing DNA replication errors. These mismatch repair genes include MSH2, MLH1, PMS1, PMS2, and MSH6/GTBP. A mutation in one of these genes predisposes a cell to mutations, which may occur in proto-oncogenes or tumor suppressor genes. Accumulation of these errors then leads to genomic instability and ultimately to carcinogenesis.Microsatellites are regions of the genome in which short base-pair segments are repeated several times, regions that are particularly prone to replication error. Consequently, a mutation in a mismatch repair gene produces variable lengths of these repetitive sequences, a finding that has been described as MSI.Tumors associated with MSI appear to have different bio-logic characteristics than do tumors that result from the LOH pathway. Tumors with MSI are more likely to be in the right colon and possess diploid DNA and are associated with a better prognosis than tumors that arise from the LOH pathway that are microsatellite stable. Tumors arising from the LOH pathway tend to occur in the more distal colon, often have chromosomal aneuploidy, and are associated with a poorer prognosis.CpG Island Methylation Pathway In the CIMP pathway, genes do not accumulate mutations (deletions or insertions of bases), but instead are activated or inactivated by methylation. This process has been called epigenetic alteration to differenti-ate it from the more traditional genetic alterations or true muta-tions. In normal cells, methylation is critical for regulation of gene expression. In cancer, aberrant methylation (either hyperor hypomethylation), usually of a promoter region, results in abnormal activation or inactivation of genes. This gene silenc-ing or, alternatively, activation results in a phenotype similar to that present with a true gene mutation. This pathway has also been called the serrated methylated pathway because of the observation that serrated polyps often harbor aberrant meth-ylation in contrast to adenomatous polyps that are more often associated with mutations in the APC gene (LOH pathway).83Although these classifications are useful for understanding the mechanisms underlying carcinogenesis, they are not mutu-ally exclusive. For example, a mismatch repair gene may be inactivated by methylation. Errors in mismatch repair may then allow mutations to inactivate a tumor suppressor gene. In addi-tion, there is considerable interest in targeting molecules in each of these pathways in order to design better anticancer agents. Finally, ongoing research is focusing on the utility of molecular profiling in predicting prognosis and/or response to treatment.10PolypsIt is now well accepted that the majority of colorectal carcino-mas evolve from adenomatous polyps; this sequence of events is the adenoma-carcinoma sequence. Polyp is a nonspecific clini-cal term that describes any projection from the surface of the intestinal mucosa regardless of its histologic nature. Colorec-tal polyps may be classified as neoplastic (tubular adenoma, villous adenoma, tubulovillous adenomas, serrated adenomas/polyps), hyperplastic, hamartomatous (juvenile, Peutz-Jeghers, Cronkite-Canada), or inflammatory (pseudopolyp, benign lymphoid polyp).Neoplastic Polyps. Adenomatous polyps are common, occur-ring in up to 25% of the population older than 50 years of age in the United States. By definition, these lesions are dysplas-tic. The risk of malignant degeneration is related to both the size and type of polyp. Tubular adenomas are associated with malignancy in only 5% of cases, whereas villous adenomas may harbor cancer in up to 40%. Tubulovillous adenomas are at intermediate risk (22%). Invasive carcinomas are rare in Brunicardi_Ch29_p1259-p1330.indd 129023/02/19 2:29 PM 1291COLON, RECTUM, AND ANUSCHAPTER 29polyps smaller than 1 cm; the incidence of invasive carcinoma increases with size. The risk of carcinoma in a polyp larger than 2 cm is 35% to 50%. Although most neoplastic polyps do not evolve to cancer, most colorectal cancers originate as a polyp. It is this fact that forms the basis for secondary prevention strate-gies to eliminate colorectal cancer by targeting the neoplastic polyp for removal before malignancy develops.Polyps may be pedunculated or sessile. Most pedunculated polyps are amenable to colonoscopic snare excision. Removal of sessile polyps is often more challenging. Special colonoscopic techniques, including saline lift, piecemeal snare excision, and endoscopic mucosal resection facilitate successful removal of many sessile polyps. For rectal sessile polyps, transanal opera-tive excision is preferred because it produces an intact, single pathology specimen that can be used to determine the need for further therapy. Interpretation of the precise depth of invasion of a cancer arising in a sessile polyp after piecemeal excision is often impossible. The site of sessile polypectomies should be marked by tattoo marking to guide subsequent endoscopic sur-veillance and to facilitate identification of the involved bowel segment should operative resection be necessary.84 Colectomy is reserved for cases in which colonoscopic removal is impos-sible, such as large, flat lesions, or if a focus of invasive cancer is confirmed in the specimen.Complications of polypectomy include perforation and bleeding. A small perforation (microperforation) in a fully pre-pared, stable patient may be managed with bowel rest, broad-spectrum antibiotics, and close observation. Signs of sepsis, peritonitis, or deterioration in clinical condition are indications for laparotomy. Bleeding may occur immediately after polypec-tomy or may be delayed. The bleeding will usually stop sponta-neously, but colonoscopy may be required to apply endoscopic clips, resnare a bleeding stalk, cauterize the lesion, or inject/apply epinephrine. Occasionally angiography and infusion of vasopressin may be necessary. Rarely, colectomy is required.Hyperplastic Polyps. Hyperplastic polyps are extremely com-mon in the colon. These polyps are usually small (<5 mm) and show histologic characteristics of hyperplasia without any dys-plasia. They are not considered premalignant, but they cannot be distinguished from adenomatous polyps colonoscopically and are therefore often removed. In contrast, large hyperplas-tic polyps (>2 cm) may have a risk of malignant degeneration. Hyperplastic polyposis is a rare disorder in which multiple large hyperplastic polyps occur in young adults. These patients are at increased risk for the development of colorectal cancer.Serrated Polyps. Serrated polyps, including sessile serrated adenomas and traditional serrated adenomas, are a recently recognized, histologically distinct group of neoplastic polyps. Endoscopically they are flat lesions and frequently difficult to visualize. These lesions were long thought to be similar to hyperplastic polyps with minimal malignant potential. How-ever, it has become clear that some of these polyps will develop into invasive cancers. In addition, a familial serrated polyposis syndrome has been described. Serrated polyps should be treated like adenomatous polyps.85Hamartomatous Polyps (Juvenile Polyps). In contrast to adenomatous and serrated polyps, hamartomatous polyps (juve-nile polyps) usually are not premalignant. These lesions are the characteristic polyps of childhood but may occur at any age. Bleeding is a common symptom, and intussusception and/or obstruction may occur. Because the gross appearance of these polyps is identical to adenomatous polyps, these lesions should also be treated by polypectomy. In contrast to adenomatous pol-yposis syndromes, these conditions are often associated with mutation in BMPR1A and SMAD4.Familial juvenile polyposis is an autosomal dominant dis-order in which patients develop hundreds of polyps in the colon and rectum. Unlike solitary juvenile polyps, these lesions may degenerate into adenomas and eventually carcinoma. Annual screening should begin between the ages of 10 and 12 years. Treatment is surgical and depends in part on the degree of rectal involvement. If the rectum is relatively spared, a total abdomi-nal colectomy with ileorectal anastomosis may be performed with subsequent close surveillance of the retained rectum. If the rectum is carpeted with polyps, total proctocolectomy is the more appropriate operation. These patients are candidates for ileal pouch–anal reconstruction to avoid a permanent stoma.Peutz-Jeghers syndrome is characterized by polyposis of the small intestine and, to a lesser extent, polyposis of the colon and rectum. Characteristic melanin spots are often noted on the buccal mucosa and lips of these patients. The polyps of Peutz-Jeghers syndrome are generally considered to be hamar-tomas and are not thought to be at significant risk for malignant degeneration. However, carcinoma may occasionally develop. Because the entire length of the gastrointestinal tract may be affected, surgery is reserved for symptoms such as obstruction or bleeding or for patients in whom polyps develop adenoma-tous features. Screening consists of a baseline colonoscopy and upper endoscopy at age 20 years, followed by annual flexible sigmoidoscopy thereafter. Clinicians should ensure patients are screened for associated extraintestinal malignancies (breast, upper gastrointestinal tract, pancreas, cervix, ovaries, and testicles).Cronkite-Canada syndrome is a disorder in which patients develop gastrointestinal polyposis in association with alopecia, cutaneous pigmentation, and atrophy of the fingernails and toenails. Diarrhea is a prominent symptom, and vomiting, mal-absorption, and protein-losing enteropathy may occur. Most patients die of this disease despite maximal medical therapy, and surgery is reserved for complications of polyposis such as obstruction.Cowden’s syndrome is an autosomal dominant disorder with hamartomas of all three embryonal cell layers. Facial trich-ilemmomas, breast cancer, thyroid disease, and gastrointestinal polyps are typical of the syndrome. Patients should be screened for cancers. Treatment is otherwise based on symptoms.Inflammatory Polyps (Pseudopolyps). Inflammatory pol-yps occur most commonly in the context of inflammatory bowel disease, but they may also occur after amebic colitis, ischemic colitis, and schistosomal colitis. These lesions are not premalig-nant, but they cannot be distinguished from adenomatous polyps based on gross appearance and therefore should be removed. Microscopic examination shows islands of normal, regenerat-ing mucosa (the polyp) surrounded by areas of mucosal loss. Polyposis may be extensive, especially in patients with severe colitis, and may mimic FAP.Inherited Colorectal CarcinomaMany of the genetic defects originally described in hereditary cancers have subsequently been found in sporadic tumors. Although the majority of colorectal cancer is sporadic, several hereditary syndromes provide paradigms for the study of this disease. Insight gained from studying inherited colorectal cancer Brunicardi_Ch29_p1259-p1330.indd 129123/02/19 2:29 PM 1292SPECIFIC CONSIDERATIONSPART IIsyndromes has led to better understanding of the genetics of colorectal carcinoma.Familial Adenomatous Polyposis. This rare autosomal dominant condition accounts for only about 1% of all colorec-tal adenocarcinomas. Nevertheless, this syndrome has provided tremendous insight into the molecular mechanisms underlying colorectal carcinogenesis. The genetic abnormality in FAP is a mutation in the APC gene, located on chromosome 5q. Of patients with FAP, APC mutation testing is positive in 75% of cases. While most patients with FAP will have a known family history of the disease, up to 25% present without other affected family members. Clinically, patients develop hundreds to thou-sands of adenomatous polyps shortly after puberty. The lifetime risk of colorectal cancer in FAP patients approaches 100% by age 50 years.Flexible sigmoidoscopy of first-degree relatives of FAP patients beginning at age 10 to 15 years has been the traditional mainstay of screening. Today, following genetic counseling, APC gene testing may be used to screen family members, pro-viding an APC mutation has been identified. If APC testing is positive in a relative of a patient with a known APC mutation, annual flexible sigmoidoscopy beginning at age 10 to 15 years is done until polyps are identified. If APC testing is negative, the relative can be screened starting at age 50 years per average-risk guidelines. If APC testing is refused or unavailable, or if a mutation cannot be identified, annual flexible sigmoidoscopy beginning at age 10 to 15 years is performed until age 24 years. Screening flexible sigmoidoscopy is then done every 2 years until age 34 years, every 3 years until age 44 years, and then every 3 to 5 years.FAP patients are also at risk for the development of adeno-mas anywhere in the gastrointestinal tract, particularly in the duodenum. Periampullary carcinoma is a particular concern. Upper endoscopy is therefore recommended for surveillance every 1 to 3 years beginning at age 25 to 30 years.Once the diagnosis of FAP has been made and polyps are developing, treatment is surgical. Four factors affect the choice of operation: age of the patient; presence and severity of symp-toms; extent of rectal polyposis; and presence and location of cancer or desmoid tumors. Three operative procedures can be considered: total proctocolectomy with an end (Brooke) ileos-tomy; total abdominal colectomy with ileorectal anastomosis; and restorative proctocolectomy with ileal pouch–anal anas-tomosis (IPAA) with or without a temporary ileostomy. Most patients elect to have an ileal pouch–anal anastomosis in the absence of a distal rectal cancer, a mesenteric desmoid tumor that prevents the ileum from reaching the anus, or poor sphinc-ter function. Mucosectomy has been advocated in patients with FAP undergoing ileal pouch–anal anastomosis because of the risk of neoplasia in the anal transition zone, but the requirement for this procedure remains controversial.86,87 Although patient satisfaction with IPAA remains high, function may not be ideal, and up to 50% of patients experience some degree of incon-tinence. Total abdominal colectomy with an ileorectal anasto-mosis is also an option in these patients, but requires vigilant surveillance of the retained rectum for development of rectal cancer. There is increasing data suggesting that the administra-tion of cyclooxygenase-2 (COX-2) inhibitors (celecoxib, sulin-dac) may slow or prevent the development of polyps.88,89FAP may be associated with extraintestinal manifesta-tions such as congenital hypertrophy of the retinal pigmented epithelium, desmoid tumors, epidermoid cysts, mandibular osteomas (Gardner’s syndrome), and central nervous system tumors (Turcot’s syndrome). Although they arise in a minority of FAP patients, desmoid tumors in particular can make surgi-cal management difficult and are a source of major morbidity and mortality in these patients. These lesions arise from fibro-blasts, and although technically benign, can be highly locally invasive. These tumors often involve the bowel mesentery, pel-vis, and abdominal wall. In some cases, surgery is thought to be the “trigger.” Local recurrence after attempted resection is common; therefore, surgery is to be avoided if at all possible. Desmoid tumors are often hormone responsive, and growth may be inhibited in some patients with tamoxifen. COX-2 inhibitors and nonsteroidal, anti-inflammatory drugs may also be benefi-cial in this setting. A recent report suggests that imatinib may also be effective.90,91Attenuated Familial Adenomatous Polyposis. AFAP is a recognized variant of FAP. Patients present later in life with fewer polyps (usually 10–100) predominantly located in the right colon, when compared to classic FAP. Colorectal carci-noma develops in more than 50% of these patients, but occurs later (average age, 55 years). Patients are also at risk for duo-denal polyposis. However, in contrast to FAP, APC gene muta-tions are present in only about 30% of patients with AFAP. When present, these mutations are expressed in an autosomal dominant pattern.Mutations in MYH also result in the AFAP phenotype but are expressed in an autosomal recessive pattern. It has been sug-gested that MYH mutations may be responsible for AFAP in patients who do not have a detectable APC gene mutation.80,81Genetic testing is often offered to patients with suspected AFAP. When positive, genetic counseling and testing may be used to screen at-risk family members. If the family mutation is unknown, screening colonoscopy is recommended beginning at age 13 to 15 years, then every 4 years to age 28 years, and then every 3 years. These patients are often candidates for a total abdominal colectomy with ileorectal anastomosis because the limited polyposis in the rectum can usually be treated by colo-noscopic snare excision.92 Prophylaxis with COX-2 inhibitors also may be appropriate. Because of the more subtle phenotype in these patients, it is important to rule out other familial syn-dromes such as HNPCC (Lynch syndrome) and the more com-mon familial colorectal cancer.Lynch Syndrome (Hereditary Nonpolyposis Colon Cancer; HNPCC). Lynch syndrome is more common than FAP, but it is still extremely rare (1–3% of all colon cancers). The genetic defects associated with Lynch syndrome arise from errors in mismatch repair, the phenotypic result being MSI. Lynch syn-drome is inherited in an autosomal dominant pattern and is char-acterized by the development of colorectal carcinoma at an early age (average age, 40–45 years). Approximately 70% of affected individuals will develop colorectal cancer. Cancers appear in the proximal colon more often than in sporadic colorectal cancer and have a better prognosis regardless of stage. The risk of syn-chronous or metachronous colorectal carcinoma is 40%. Lynch syndrome may also be associated with extracolonic malignan-cies, including endometrial carcinoma, which is most com-mon in women, and ovarian, pancreas, stomach, small bowel, biliary, and urinary tract carcinomas. The diagnosis is made based on family history. The Amsterdam I criteria for clini-cal diagnosis of Lynch syndrome are three affected relatives Brunicardi_Ch29_p1259-p1330.indd 129223/02/19 2:29 PM 1293COLON, RECTUM, AND ANUSCHAPTER 29with histologically verified adenocarcinoma of the large bowel (one must be a first-degree relative of one of the others) in two successive generations of a family with one patient diagnosed before age 50 years. The presence of other related carcinomas should raise the suspicion of this syndrome. Revised criteria Amsterdam II requires three or more relatives with an HNPCC related malignancy in which at least one is a first degree relative of the others, two generations are affected, at least one cancer occurred before age 50, FAP has been excluded, and pathology of the tumors has been reviewed and confirmed. In a patient with an established diagnosis of colorectal cancer, tumor testing for presence of mismatch repair gene products (immunohisto-chemistry) and/or MSI can sometimes serve as screening for this syndrome.10,93,94Lynch syndrome results from mutations in mismatch repair genes, and like FAP, specific mutations are associated with different phenotypes. For example, mutations in PMS2 or MSH6 result in a more attenuated form of Lynch syndrome when compared to mutations in other genes. MSH6 inactivation also appears to be associated with a higher risk for endometrial cancer. Further significance of these specific mutations remains to be determined.Screening colonoscopy is recommended annually for at-risk patients beginning at either age 20 to 25 years or 10 years younger than the youngest age at diagnosis in the family, which-ever comes first. Because of the high risk of endometrial carci-noma, transvaginal ultrasound or endometrial aspiration biopsy is also recommended annually after age 25 to 35 years. Because there is a 40% risk of developing a second colon cancer, total colectomy with ileorectal anastomosis is recommended once adenomas or a colon carcinoma is diagnosed. Annual proctos-copy is necessary because the risk of developing rectal cancer remains high. Similarly, prophylactic hysterectomy and bilateral salpingo-oophorectomy should be considered in women who have completed childbearing.93-95Familial Colorectal Cancer. Nonsyndromic familial colorec-tal cancer accounts for 10% to 15% of patients with colorec-tal cancer. The lifetime risk of developing colorectal cancer increases with a family history of the disease. The lifetime risk of colorectal cancer in a patient with no family history of this disease (average-risk population) is approximately 6%, but rises to 12% if one first-degree relative is affected and to 35% if two first-degree relatives are affected. Age of onset also impacts risk, and a diagnosis before the age of 50 years is associated with a higher incidence in family members. Screening colonoscopy is recommended every 5 years beginning at age 40 years or begin-ning 10 years before the age of the earliest diagnosed patient in the pedigree. While there are no specific genetic abnormalities that are associated with familial colorectal cancer, any of the defects found in either the LOH pathway or MSI pathway may be present in these patients.Prevention: Screening and SurveillanceBecause the majority of colorectal cancers are thought to arise from adenomatous polyps, preventive measures focus on identi-fication and removal of these premalignant lesions. In addition, many cancers are asymptomatic, and screening may detect these tumors at an early and curable stage (Table 29-1). Although screening for colorectal cancer decreases the incidence of can-cer and cancer-related mortality, the optimal method of screen-ing remains controversial. Screening guidelines are meant for asymptomatic patients.95-98 Any patient with a gastrointestinal complaint (bleeding, change in bowel habits, pain, etc) requires a complete evaluation, usually by colonoscopy.Fecal Occult Blood Testing and Fecal Immunohistochemical Testing. FOBT is known to reduce colorectal cancer mortality by 33% and metastatic disease by 50%. However, FOBT is rela-tively insensitive, missing up to 50% of cancers and the majority of adenomas. Its specificity is low because 90% of patients with positive tests do not have colorectal cancer. FIT is more sensitive and specific for cancer. Mortality benefits for its use are inferred from FOBT literature. Compliance with annual testing is low and costs are significant if one includes the colonoscopy examina-tions done to evaluate patients with positive FOBT/FIT. Nonethe-less, the direct evidence that FOBT screening is efficacious and decreases both the incidence and mortality of colorectal cancer is so strong that national guidelines recommend annual FOBT/FIT screening for asymptomatic, average-risk Americans older than 50 years of age as one of several accepted strategies. A positive FOBT/FIT should be followed by colonoscopy.97-100Stool DNA. Neoplastic lesions of the colon shed cells into the lumen posing an opportunity for detection via DNA testing. A commercially available multitarget stool DNA test evaluates stool samples for mutant KRAS, methylated BMP3 and the pro-moter region of NDRG4. In a large North American prospective study, this test has recently been found to be 92% sensitive for detection of colorectal cancer. Compared to FIT, stool DNA testing has a lower specificity (74%) raising concerns about how to manage stool DNA-positive patients who have a negative colonoscopic evaluation. Sensitivity for advanced precancerous lesions was 42%.100,101 This test, in combination with FIT, is supported as a screening modality every 1 to 3 years by the U.S. Preventative Task Force, and every 3-year utilization is sup-ported by NCCN guidelines.100 Nevertheless, additional studies will be necessary to determine if these tests are comparable or superior to more traditional methods has been techniques.Flexible Sigmoidoscopy. Screening by flexible sigmoidos-copy every 5 years may lead to a 60% to 70% reduction in mor-tality from colorectal cancer, chiefly by identifying high-risk individuals with adenomas. However, it is important to recog-nize that lesions in the proximal colon cannot be identified, and for this reason, flexible sigmoidoscopy has often been paired with air-contrast barium enema to detect transverse and right colon lesions. Patients found to have a polyp, cancer, or other lesion on flexible sigmoidoscopy will require colonoscopy.101-102Fecal Occult Blood Testing and Flexible Sigmoidoscopy.  Several trials have shown that FOBT screening is least effec-tive at detecting rectosigmoid cancers.97-99 This is precisely the area screened by flexible sigmoidoscopy; thus, the combination of the two tests has been suggested as a reasonable screening strategy. Winawer and colleagues, in a study of 12,479 subjects, showed that the combination of FOBT annually with flexible sigmoidoscopy every 5 years resulted in lower mortality from colorectal cancer and better survival in patients with colorectal cancer.99 A similar benefit was confirmed in long-term (11-year) follow-up from the Norwegian Colorectal Cancer Prevention Trial. Such data led to the American Cancer Society recommen-dations that one of the acceptable screening regimens for aver-age-risk Americans is the combination of FOBT/FIT annually and flexible sigmoidoscopy every 5 years; this combination was preferred over either test alone. Recent NCCN guidelines offer the option of flexible sigmoidoscopy with stool-based testing Brunicardi_Ch29_p1259-p1330.indd 129323/02/19 2:29 PM 1294SPECIFIC CONSIDERATIONSPART IIevery 10 years. The addition of air-contrast barium enema to assess the proximal colon may improve sensitivity as well.96Colonoscopy. Colonoscopy is currently the most accurate and most complete method for examining the large bowel. This procedure is highly sensitive for detecting even small polyps (<1 cm) and allows biopsy, polypectomy, control of hemor-rhage, and dilation of strictures. However, colonoscopy does require mechanical bowel preparation, and the discomfort asso-ciated with the procedure requires conscious sedation in most patients. Colonoscopy is also considerably more expensive than other screening modalities and requires a well-trained endos-copist. The risk of a major complication after colonoscopy (perforation and hemorrhage) is extremely low (0.2–0.3%). Nevertheless, deaths have been reported.Air-Contrast Barium Enema. Air-contrast barium enema is also highly sensitive for detecting polyps greater than 1 cm in diameter (90% sensitivity). Unfortunately, there are no studies proving its efficacy for screening large populations. Accuracy is greatest in the proximal colon but may be compromised in the sigmoid colon if there is significant diverticulosis. The major disadvantages of barium enema are the need for mechanical bowel preparation and the requirement for colonoscopy if a lesion is discovered.Computed Tomography Colonography (Virtual Colonos-copy). Advances in imaging technology have created a num-ber of less invasive, but highly accurate tools for screening. CT colonography makes use of helical CT technology and three-dimensional reconstruction to image the intraluminal colon. At present, patients require a mechanical bowel preparation. The colon is then insufflated with air, a spiral CT is performed, and both two-dimensional and three-dimensional images are gener-ated. In the hands of a qualified radiologist, sensitivity appears to be as good as colonoscopy for colorectal cancers and polyps greater than 1 cm in size.103 Colonoscopy is required if a lesion is identified. CT colonography has also been used for imag-ing the proximal colon in cases of obstruction or if a colonos-copy cannot be completed in selected patients. Limitations of this technique include false-positive results from retained stool, diverticular disease, haustral folds, motion artifacts, and an inability to detect flat adenomas.Guidelines for Screening. Current American Cancer Society guidelines advocate screening for the average-risk population (asymptomatic, no family history of colorectal carcinoma, no personal history of polyps or colorectal carcinoma, no familial syndrome) beginning at age 50 years. Recommended proce-dures include yearly FOBT/FIT, flexible sigmoidoscopy every Table 29-1Advantages and disadvantages of screening modalities for asymptomatic individuals ADVANTAGESDISADVANTAGESFecal occult blood testing (FOBT)Ease of use and noninvasiveLow costGood sensitivity with repeat testingMay not detect most polypsLow specificityColonoscopy required for positive resultPoor compliance with serial testingThree successive stools requiredFecal immunohistochemical test (FIT)Ease of use and noninvasiveLow costMore sensitive and specific than FOBTOnly one stool sample requiredMay not detect most polypsColonoscopy required for positive resultMultitarget stool DNAEase of use and noninvasiveMore sensitive than FITMay not detect most polypsColonoscopy required for positive resultLess specific than FITSigmoidoscopyExamines colon most at riskVery sensitive for polyp detection in left colonDoes not require full bowel preparation (enemas only)InvasiveUncomfortableSlight risk of perforation or bleedingMay miss proximal lesionsColonoscopy required if polyp identifiedColonoscopyExamines entire colonHighly sensitive and specificTherapeuticMost invasiveUncomfortable and requires sedativeRequires bowel preparationRisk of perforation or bleedingCostlyDouble-contrast barium enemaExamines entire colonGood sensitivity for polyps >1 cmExamines entire colonRequires bowel preparationLess sensitivity for polyps <1 cmMay miss lesions in the sigmoid colonColonoscopy required for positive resultComputed tomography colonography (virtual colonoscopy)NoninvasiveSensitivity may be as good as colonoscopyRequires bowel preparationInsensitive for small polypsMinimal experience and dataColonoscopy required for positive resultBrunicardi_Ch29_p1259-p1330.indd 129423/02/19 2:29 PM 1295COLON, RECTUM, AND ANUSCHAPTER 295 years, FOBT/FIT and flexible sigmoidoscopy in combination, air-contrast barium enema every 5 years, or colonoscopy every 10 years. Patients with other risk factors should be screened earlier and more frequently (Table 29-2).93-96,104,105Routes of Spread and Natural HistoryCarcinoma of the colon and rectum arises in the mucosa. The tumor subsequently invades the bowel wall and eventually adja-cent tissues and other viscera. Tumors may become bulky and circumferential, leading to colon obstruction. Local invasion (especially in the rectum or sigmoid colon) may occasionally cause obstruction of other organs such as the ureter.Regional lymph node involvement is the most common form of spread of colorectal carcinoma and usually precedes distant metastasis or the development of carcinomatosis. The likelihood of nodal metastasis increases with tumor size, poorly differentiated histology, lymphovascular invasion, and depth of invasion. The T stage (depth of invasion) is the single most significant predictor of lymph node spread. Carcinoma in situ (Tis) in which there is no penetration of the muscularis mucosa (basement membrane) has also been called high-grade dysplasia and should carry no risk of lymph node metastasis. Small lesions confined to the bowel wall (T1 and T2) are associated with lymph node metastasis in 5% to 20% of cases, whereas larger tumors that invade through the bowel wall or into adja-cent organs (T3 and T4) are likely to have lymph node metas-tasis in more than 50% of cases. The number of lymph nodes with metastases correlates with the presence of distant disease and inversely with survival. Four or more involved lymph nodes (N2 disease) predict a poor prognosis. In colon cancer, lym-phatic spread usually follows the major venous outflow from the involved segment of the colon. Lymphatic spread from the rectum follows two routes. In the upper rectum, drainage ascends along the superior rectal vessels to the inferior mesen-teric nodes. In the lower rectum, lymphatic drainage may course along the middle rectal vessels. Nodal spread along the inferior rectal vessels to the internal iliac nodes or groin is rare unless the tumor involves the anal canal or the proximal lymphatics are blocked with tumor (Fig. 29-23).The most common site of distant metastasis from colorec-tal cancer is the liver. These metastases arise from hematog-enous spread via the portal venous system. Like lymph node metastasis, the risk of hepatic metastasis increases with tumor size and tumor grade. However, even small tumors may pro-duce distant metastasis. The lung is also a site of hematogenous spread, but this rarely occurs in isolation. Carcinomatosis (dif-fuse peritoneal metastases) occurs by peritoneal seeding and has a dismal prognosis.Staging and Preoperative EvaluationClinical Presentation. Symptoms of colon and rectal can-cers are nonspecific and generally develop when the cancer is locally advanced. The classic first symptoms are a change in bowel habits and rectal bleeding. Abdominal pain, bloating, and other signs of obstruction typically occur with larger tumors and Table 29-2Screening guidelines for colorectal cancerPOPULATIONINITIAL AGERECOMMENDED SCREENING TESTAverage risk50 yAnnual FOBT orFlexible sigmoidoscopy every 5 y orAnnual FOBT and flexible sigmoidoscopy every 5 y orAir-contrast barium enema every 5 y orColonoscopy every 10 yAdenomatous polyps50 yColonoscopy at first detection; then colonoscopy in 3 yIf no further polyps, colonoscopy every 5 yIf polyps, colonoscopy every 3 yAnnual colonoscopy for >5 adenomasColorectal cancerAt diagnosisPretreatment colonoscopy; then at 12 mo after curative resection; then colonoscopy after 3 y; then colonoscopy every 5 y, if no new lesionsUlcerative colitis, Crohn’s colitisAt diagnosis; then after 8 y for pancolitis, after 15 y for left-sided colitisColonoscopy with multiple biopsies every 1–2 yFAP10–12 yAnnual flexible sigmoidoscopyUpper endoscopy every 1–3 y after polyps appearAttenuated FAP20 yAnnual flexible sigmoidoscopyUpper endoscopy every 1–3 y after polyps appearHNPCC20–25 yColonoscopy every 1–2 yEndometrial aspiration biopsy every 1–2 yFamilial colorectal cancer first-degree relative40 y or 10 y before the age of the youngest affected relativeColonoscopy every 5 yIncrease frequency if multiple family members are affected, especially before 50 yFAP = familial adenomatous polyposis; FOBT = fecal occult blood testing; HNPCC = hereditary nonpolyposis colon cancer.Data from Smith et al,79 Pignone et al,97 and Levin et al.67Brunicardi_Ch29_p1259-p1330.indd 129523/02/19 2:29 PM 1296SPECIFIC CONSIDERATIONSPART IIsuggest more advanced disease. Because of the caliber of the bowel and the consistency of the stool, left-sided tumors are more likely to cause obstruction than are right-sided tumors. Rectal tumors may cause bleeding, tenesmus, and pain. How-ever, it is important to note that many patients may be asymp-tomatic and/or present with unexplained anemia, weight loss, or poor appetite.Staging. Colorectal cancer staging is based on tumor depth and the presence or absence of nodal or distant metastases. Older staging systems, such as the Dukes’ Classification and its Astler-Coller modification, have been replaced by the tumor-node-metastasis (TNM) staging system described by the American Joint Committee on Cancer (AJCC). The AJCC TNM classification has recently been updated to reflect sur-vival outcomes based upon the Surveillance Epidemiology and End Results (SEER) registry (Table 29-3).106-109 Stage I disease includes adenocarcinomas that are invasive through the muscu-laris mucosa but are confined to the submucosa (T1) or the mus-cularis propria (T2) in the absence of nodal metastases. Stage II disease consists of tumors that invade through the bowel wall into the subserosa or nonperitonealized pericolic or perirectal tissues (T3) or into other organs or tissues or through the vis-ceral peritoneum (T4) without nodal metastases. Stage III dis-ease includes any T stage with nodal metastases, and stage IV disease denotes distant metastases.The preoperative imaging evaluation usually identifies stage IV disease. In colon cancer, differentiating stages I, II, and III depends on histologic examination of the resected specimen. In rectal cancer, endorectal ultrasound or MRI may predict the stage (ultrasound stage, uTxNx) preoperatively, but the final determination depends on pathologic examination of the resected tumor and adjacent lymph nodes (pathologic stage, pTxNx). Dis-ease stage correlates with 5-year survival. Patients with stages I and II disease can expect excellent survival rates. The pres-ence of nodal metastases (stage III) decreases survival. In rectal cancer, staging has been further refined, and outcomes suggest that subgroups of patients within each stage may have very dif-ferent prognoses. If the mesorectum around a rectal cancer is involved or threatened (only 1–2 mm of clearance), there is a very high likelihood of local recurrence and a poor prognosis. This circumferential or radial margin is probably best assessed preoperatively by MRI. Although nodal involvement is the sin-gle most important prognostic factor in colorectal carcinoma, tumor characteristics, such as degree of differentiation, muci-nous or signet-ring cell histology, vascular invasion, and DNA aneuploidy, also adversely affect prognosis. Preoperative CEA also has been suggested to be a prognostic indicator.8 Molecular profiling is currently being studied in an effort to further improve prognostic indicators.110 The 5-year survival rate with stage IV disease is low. However, in well-selected patients, metastasec-tomy, especially of isolated liver or lung lesions, can result in cure. In these patients, the involvement of a multidisciplinary team and/or tumor board is highly recommended (Fig. 29-24).Preoperative Evaluation. Once a colon or rectal carcinoma has been diagnosed, a staging evaluation should be undertaken. The colon must be evaluated for synchronous tumors, usually by colonoscopy. Synchronous disease will be present in up to 5% of patients. For rectal cancers, digital rectal examination and rigid or flexible proctoscopy with biopsy should be performed to assess tumor size, location, morphology, histology, and fixa-tion. Endorectal ultrasound or MRI can be invaluable in staging rectal cancer and is used to classify the ultrasound T and N stage of rectal cancers (see Fig. 29-24). A chest/abdominal/pelvic CT scan should be obtained to evaluate for distant metastases. Pelvic CT scan, and sometimes MRI, can be useful in large rec-tal tumors and in recurrent disease to determine the extent of local invasion. Among patients with obstructive symptoms, a water-soluble contrast study (Gastrografin enema) may be use-ful for delineating the degree of obstruction. It is important to avoid mechanical bowel preparation (for either colonoscopy or surgery) in a patient who appears to be obstructed. PET scan may be useful in evaluating lesions seen on CT scan and in patients in whom a risky or highly morbid operation is planned (pelvic exenteration, sacrectomy). Preoperative CEA is often obtained and may be useful for postoperative follow-up.Therapy for Colonic CarcinomaPrinciples of Resection. The objective in treatment of car-cinoma of the colon is to remove the primary tumor along with its lymphovascular supply. Because the lymphatics of the colon accompany the main arterial supply, the length of bowel resected depends on which vessels are supplying the segment involved with the cancer. Any adjacent organ or tissue, such as the omentum, that has been invaded should be resected en bloc with the tumor. If all of the tumor cannot be removed, a palliative procedure should be considered, although it impor-tant to note that “debulking” is rarely effective in colorectal adenocarcinoma.The presence of synchronous cancers or adenomas or a strong family history of colorectal neoplasms suggests that the entire colon is at risk for carcinoma (often called a field defect), and a subtotal or total colectomy should be considered. Meta-chronous tumors (a second primary colon cancer) identified during follow-up studies should be treated similarly. However, the surgeon must be aware of which mesenteric vessels have been ligated at the initial colectomy because that may influence the viability of the remaining colon and the choice of procedure.The number of lymph nodes recovered in the surgical specimen has long served as a proxy for the oncologic adequacy of resection. A number of studies previously have suggested that Inferiormesenteric a.Superiorrectal a.Middlerectal a.Inferiorrectal a.Common iliac a.Figure 29-23. Lymphatic drainage of the rectum. a. = artery.Brunicardi_Ch29_p1259-p1330.indd 129623/02/19 2:29 PM 1297COLON, RECTUM, AND ANUSCHAPTER 29STAGETNM0TisN0M0IT1, T2N0M0IIAT3N0M0IIBT4aN0M0IICT4bN0M0IIIAT1–T2N1/N1cM0IIIAT1N2aM0IIIBT3–T4aN1/N1cM0IIIBT2–T3N2aM0IIIBT1–T2N2bM0IIICT4aN2aM0IIICT3–T4aN2bM0IIICT4bN1–N2M0IVAAny TAny NM1aIVBAny TAny NM1bIVCAny TAny NM1cUsed with the permission of the American College of Surgeons. Amin MB, Edge SB, Greene FL, et al. (Eds.) AJCC Cancer Staging Manual, 8th Ed. Springer New York, 2017.Table 29-3TNM Staging of colorectal carcinoma DEFINITIONTumor Stage (T)TXPrimary tumor cannot be assessedT0No evidence of primary tumorTisCarcinoma in situ, intramucosal carcinoma (involvement of lamina propria with no extension through muscularis mucosae)T1Tumor invades the submucosa (through the muscularis mucosa but not into the muscularis propria)T2Tumor invades the muscularis propriaT3Tumor invades through the muscularis propria into pericolorectal tissuesT4Tumor invades the visceral peritoneum or invades or adheres to adjacent organ or structure T4aTumor invades through the visceral peritoneum (including gross perforation of the bowel through tumor and continuous invasion of tumor through areas of inflammation to the surface of the visceral peritoneum) T4bTumor directly invades or adheres to adjacent organs or structuresNodal Stage (N)NXRegional lymph nodes cannot be assessedN0No regional lymph node metastasisN1One to three regional lymph nodes are positive (tumor in lymph nodes measuring ≥0.2 mm), or any number of tumor deposits are present and all identifiable lymph nodes are negative N1aOne regional lymph node is positive N1bTwo or three regional lymph nodes are positive N1cNo regional lymph nodes are positive, but there are tumor deposits in the• subserosa• mesentery• or nonperitonealized pericolic, or perirectal/mesorectal tissues.N2Four or more regional nodes are positive N2aFour to six regional lymph nodes are positive N2bSeven or more regional lymph nodes are positiveDistant Metastasis (M)M0No distant metastasis by imaging, etc.; no evidence of tumor in distant sites or organs (This category is not assigned by pathologists.)M1Metastasis to one or more distant sites or organs or peritoneal metastasis is identified M1aMetastasis to one site or organ is identified without peritoneal metastasis M1bMetastasis to two or more sites or organs is identified without peritoneal metastasis M1cMetastasis to the peritoneal surface is identified alone or with other site or organ metastasesBrunicardi_Ch29_p1259-p1330.indd 129723/02/19 2:29 PM 1298SPECIFIC CONSIDERATIONSPART IIFigure 29-24. A. Endorectal ultrasonography showing a T3 rectal carcinoma. The dotted line is being used to measure the diameter of the lesion. B. Rectal cancer MRI. (A, Used with permission from Charles O. Finne III, MD, Minneapolis, MN.) a minimum of 12 lymph nodes in the resected specimen are nec-essary for adequate staging. In addition, patients in whom more nodes are harvested have better long-term outcome. As such, a 12-node minimum has been suggested as an appropriate bench-mark for assessing quality of care. However, several investi-gators recently have called this into question, noting that the number of lymph nodes examined does not correlate with stag-ing, use of adjuvant chemotherapy, or patient survival. Others have suggested that the number of negative lymph nodes and/or the lymph node ratio (positive lymph nodes to total lymph nodes) may further improve staging.106,111-114If unexpected metastatic disease is encountered at the time of a laparotomy, the decision about whether to proceed with resection of the primary tumor depends on the volume of dis-tant disease, location and size of the primary tumor, the opera-tion required to remove the primary tumor, and the operative approach. If the metastatic disease is low volume (isolated or potentially resectable liver lesions) and the resection of the primary tumor is straightforward (segmental abdominal colec-tomy), it is probably reasonable to proceed with resection. On the other hand, if the metastatic disease is high volume (carci-nomatosis), especially if the primary tumor is minimally symp-tomatic, the operation should be aborted in order to facilitate early systemic chemotherapy. Some centers favor starting the operation with a diagnostic laparoscopy in cases where risk of discovering metastasis is high in order to minimize the magni-tude of the operation should surgery be aborted. With recent advances in chemotherapy, many of these patients will never develop a complication from the primary tumor requiring surgi-cal intervention. Other palliative approaches include a bypass or proximal stoma for obstructing lesions.115,116Stage-Specific Therapy Stage 0 (Tis, N0, M0) Polyps containing carcinoma in situ (high-grade dysplasia) carry no risk of lymph node metastasis. However, the presence of high-grade dysplasia increases the risk of finding an invasive carcinoma within the polyp. For this reason, these polyps should be excised completely, and patho-logic margins should be free of dysplasia. Most pedunculated polyps and many sessile polyps may be completely removed endoscopically. These patients should be followed with fre-quent colonoscopy to ensure that the polyp has not recurred and that an invasive carcinoma has not developed. In cases where the polyp cannot be removed entirely, a segmental resection is recommended.Stage I: The Malignant Polyp (T1, N0, M0) Occasionally a polyp that was thought to be benign will be found to harbor invasive carcinoma after polypectomy. Treatment of a malig-nant polyp is based on the risk of local recurrence and the risk of lymph node metastasis.59 The risk of lymph node metastases depends primarily on the depth of invasion. Invasive carcinoma in the head of a pedunculated polyp with no stalk involvement carries a low risk of metastasis (<1%) and may be completely resected endoscopically. For sessile polyps, the depth of inva-sion predicts risk of lymphovascular spread. A recent classifica-tion stratifies risk by depth of submucosal spread. Superficial lesions (submucosa 1; Sm1) are low risk, whereas Sm2 and Sm3 are intermediate and high risk.117 Lymphovascular inva-sion, poorly differentiated histology, tumor budding, or tumor within 1 mm of the resection margin greatly increases the risk of local recurrence and metastatic spread. Segmental colectomy is then indicated. Invasive carcinoma arising in a sessile polyp extending into the submucosa and is usually best treated with segmental colectomy (Fig. 29-25).Stages I and II: Localized Colon Carcinoma (T1-3, N0, M0)  The majority of patients with stages I and II colon cancer will be cured with surgical resection. Few patients with completely resected stage I disease will develop either local or distant recur-rence, and adjuvant chemotherapy does not improve survival in these patients.117 However, up to 46% of patients with com-pletely resected stage II disease will ultimately die from colon cancer. For this reason, adjuvant chemotherapy has been sug-gested for selected patients with stage II disease (young patients, tumors with “high-risk” histologic findings). It remains contro-versial as to whether chemotherapy improves survival rates in these patients. In some cases, molecular profiling may predict prognosis, although it is important to note that these tools have not been shown to predict response to therapy. At present, Brunicardi_Ch29_p1259-p1330.indd 129823/02/19 2:29 PM 1299COLON, RECTUM, AND ANUSCHAPTER 29molecular profiling for selecting patients to receive chemother-apy remains unproven.Stage III: Lymph Node Metastasis (Tany, N1, M0) Patients with lymph node involvement are at significant risk for both local and distant recurrence, and adjuvant chemotherapy has been recommended routinely in these patients. 5-Fluorouracil–based regimens (with leucovorin) and oxaliplatin (FOLFOX) reduce recurrences and improve survival in this patient popula-tion. It is important to note, however, that a subgroup of patients with stage III disease will do well without chemotherapy. MSI status in particular predicts good prognosis. Subset analysis from the CRYSTAL trial has shown that patients with MSI-high stage III disease do not benefit from 5-fluorouracil–based chemotherapy. Molecular profiling, therefore, may be helpful in determining which stage III patients can safely avoid systemic chemotherapy.118Stage IV: Distant Metastasis (Tany, Nany, M1) Survival is extremely limited in stage IV colon carcinoma. Systemic che-motherapy is recommended in almost all cases of distant spread. However, unlike many other malignancies, highly selected patients with isolated, resectable metastases may benefit from resection (metastasectomy). The most common site of metasta-sis is the liver. Of patients with systemic disease, approximately 15% will have metastases limited to the liver. Of these, 20% are potentially resectable for cure. Survival is improved in these patients (20–40% 5-year survival) when compared to patients who do not undergo resection. Hepatic resection of synchronous metastases from colorectal carcinoma may be performed as a combined procedure or in two stages. The second most com-mon site of metastasis is the lung, occurring in approximately 20% of patients with colorectal carcinoma. Although very few of these patients will be potentially resectable, among those who are (about 1–2% of all colorectal cancer patients), long-term survival benefit is approximately 30% to 40%. There are limited reports of successful resection of metastases in other sites (ovary and retroperitoneum are most common). Cytore-ductive surgery and intraperitoneal chemotherapy (HIPEC) has been suggested for patients with carcinomatosis, but remains unproven for colorectal cancer and carries high morbidity.119,120The remainder of patients with stage IV disease cannot be cured surgically, and therefore, the focus of treatment should be palliation. Methods such as colonic stenting for obstruct-ing lesions of the left colon also provide good palliation. More limited surgical intervention such as a diverting stoma or bypass procedure may be appropriate in patients with stage IV disease who develop obstruction. Hemorrhage in an unresectable tumor can sometimes be controlled with angiographic embolization. External beam radiation also has been used for palliation. The involvement of a palliative care team in the management of these patients is critical.116Therapy for Rectal CarcinomaPrinciples of Resection. The biology of rectal adenocarci-noma is thought to be similar to the biology of colonic adeno-carcinoma, and the operative principles of complete resection of the primary tumor, its lymphatic bed, and any other involved organ apply to surgical resection of rectal carcinoma. However, the anatomy of the pelvis and proximity of other structures (ureters, bladder, prostate, vagina, iliac vessels, and sacrum) make resection more challenging and often require a different approach than for colonic adenocarcinoma. Moreover, it is more difficult to achieve negative radial margins in rectal cancers that extend through the bowel wall because of the anatomic limita-tions of the pelvis. Therefore, local recurrence is higher than with similar stage colon cancers. However, unlike the intraperi-toneal colon, the relative paucity of small bowel and other radi-ation-sensitive structures in the pelvis makes it easier to treat rectal tumors with radiation. Therapeutic decisions, therefore, are based on the location and depth of the tumor and its relation-ship to other structures in the pelvis.Local Therapy. The distal 10 cm of the rectum are accessible transanally. For this reason, several local approaches have been proposed for treating rectal neoplasms. Transanal excision (full thickness or mucosal) is an excellent approach for noncircum-ferential, benign, villous adenomas of the rectum. Transanal endoscopic microsurgery (TEM) and transanal minimally invasive surgery (TAMIS) make use of a specially designed proctoscope, magnifying system, and instruments similar to those used in laparoscopy to allow local excision of lesions higher in the rectum (up to 15 cm). Although this technique has been used for selected T1, and some T2, carcinomas, local excision does not allow pathologic examination of the lymph nodes and might therefore understage patients. Moreover, local recurrence rates are high after transanal excision, and salvage surgery, while often curative, has been reported to be associ-ated with poorer survival than with initial radical surgery. Cur-rent recommendation is to limit local excision of T1 lesions to patients with well to moderately differentiated small lesions (<3 cm) and/or in patients medically unfit for radical resection. In general, local excision of any rectal neoplasm should be con-sidered an excisional biopsy because final pathologic examina-tion of the specimen may reveal an invasive carcinoma that then mandates more radical therapy.120,121Ablative techniques, such as electrocautery or endocavi-tary radiation, also have been used. The disadvantage of these techniques is that no pathologic specimen is retrieved to confirm the tumor stage. Fulguration is generally reserved for extremely high-risk, symptomatic patients with a limited life span who cannot tolerate more radical surgery.120Radical Resection. Radical resection is preferred to local therapy for most rectal carcinomas. Radical resection involves removal of the involved segment of the rectum along with its lymphovascular supply. Although any microscopically nega-tive margin has been suggested to be adequate, most surgeons Pedunculated polypInvasive caSessile polypStalkNeckMuscularismucosaFigure 29-25. Levels of invasive carcinoma in pedunculated and sessile polyps. ca = carcinoma.Brunicardi_Ch29_p1259-p1330.indd 129923/02/19 2:29 PM 1300SPECIFIC CONSIDERATIONSPART IIstill attempt to obtain a 2-cm distal mural margin for curative resections.Total mesorectal excision (TME) is a technique that uses sharp dissection along anatomic planes to ensure complete resection of the rectal mesentery during low and extended low anterior resections. For upper rectal or rectosigmoid resections, a partial mesorectal excision of at least 5 cm distal to the tumor appears adequate. TME both decreases local recurrence rates and improves long-term survival rates. Moreover, this tech-nique is associated with less blood loss and less risk to the pel-vic nerves and presacral plexus than is blunt dissection. The principles of TME should be applied to all radical resections for rectal cancer.Recurrence of rectal cancer generally has a poor prog-nosis. Extensive involvement of other pelvic organs (usually occurring in the setting of tumor recurrence) may require a pelvic exenteration. The rectal and perineal portions of this operation are similar to an APR, but en bloc resection of the ureters, bladder, and prostate or uterus and vagina are also per-formed. A permanent colostomy and an ileal conduit to drain the urinary tract may be necessary. The sacrum may also be resected if necessary (sacrectomy) up to the level of the S2-S3 junction. These operations are best performed in tertiary centers with multidisciplinary teams consisting of a colon and rectal surgeon, urologist, neurosurgeon, and plastic surgeon.Stage-Specific Therapy (Fig. 29-26). Pretreatment staging of rectal carcinoma often relies on endorectal ultrasound or MRI to determine the T and N status of a rectal cancer. Ultrasound is highly accurate at assessing tumor depth, but it is less accurate in diagnosing nodal involvement. Ultrasound evaluation can guide choice of therapy in most patients. MRI is useful to assess mesorectal involvement. When the radial margin is threatened or involved, neoadjuvant chemoradiation is recommended.122Stage 0 (Tis, N0, M0) Villous adenomas harboring carci-noma in situ (high-grade dysplasia) are ideally treated with local excision. A 1-cm margin should be obtained. Rarely, radical resection will be necessary if transanal excision is not techni-cally possible (large circumferential lesions).Stage I: Localized Rectal Carcinoma (T1-2, N0, M0)  Although local excision has been used for small, favorable ses-sile uT1N0 and uT2N0 rectal cancers, local recurrence rates may be as high as 20% and 40%, respectively. Local excision increasingly is offered to patients with small, low-risk lesions, but it does not allow physicians to assess regional lymph nodes. For this reason, radical resection is recommended in all good-risk patients. Lesions with unfavorable histologic characteristics and those located in the distal third of the rectum, in particular, are prone to recurrence. In high-risk patients and in patients who refuse radical surgery because of the risk of need for a permanent colostomy, local excision may be adequate, but strong consideration should be given to adjuvant or neoadju-vant chemoradiation to improve local control. The efficacy of adjuvant or neoadjuvant chemoradiation followed by transanal excision in patients who can tolerate radical surgery has been High risk orrefuses radicalresectionTransanalexcision +/–neoadjuvant oradjuvantchemoradiationRadicalresectionRadicalresectionRadicalresectionContinuechemotherapyConsiderresectionChemoradiationvs. palliativeprocedurestent, laserablation, stoma,resectionLow risk andaccepts radicalresectionNeoadjuvantchemoradiationNeoadjuvantchemoradiationAsymptomaticSymptomaticRestageRestageUnresectable/multiplemetastaticsitesResectable/singlemetastatic siteChemotherapyNo metastasesNo metastasesRectal adenocarcinomaStage II(T3-4, N0, M0)Stage III(Tany, N1-3, M0)Staging evaluationCT chest/abdomen/pelvisEndorectal U/S+/– MRIColonoscopy/CT colonography (if possible)Stage IV(Tany, Nany, M1)Stage I(T1-2, N0, M0)RestageFigure 29-26. Diagnostic algorithm for rectal cancer. CT = computed tomography; MRI = magnetic resonance imaging; U/S = ultrasound.Brunicardi_Ch29_p1259-p1330.indd 130023/02/19 2:29 PM 1301COLON, RECTUM, AND ANUSCHAPTER 29controversial. Early results from ACOSOG Z6041, in which patients with T2 rectal cancers received neoadjuvant chemo-radiation followed by transanal excision, showed a pathologic complete response rate of 44%.123 At 3 years, disease-free sur-vival was 88%, which is comparable to cancer outcomes after a formal resection. However, population-based data suggests that survival after local excision for rectal cancer is suboptimal and should not be offered as a matter of routine.124Locally Advanced Rectal Cancer (Stages II and III) Stage II: Localized Rectal Carcinoma (T3-4, N0, M0). Larger rectal tumors, especially if located in the distal rectum, are more likely to recur locally. There are two schools of thought, each differing in their approach, concerning how to control local recurrences. Advocates of total mesorectal resection sug-gest that optimization of operative technique will obviate the need for any adjuvant chemoradiation to control local recur-rence after resection of stages I, II, and III rectal cancers. The opposing school suggests that stages II and III rectal cancers will benefit from chemoradiation. They argue that such therapy reduces local recurrences and prolongs survival whether given preoperatively or postoperatively. The advantages of preopera-tive chemoradiation include tumor shrinkage, increased likeli-hood of resection and of a sphincter-sparing procedure, tumor downstaging by treating locally involved lymph nodes, and decreased risk to the small intestine. Disadvantages include possible overtreatment of early-stage tumors, impaired wound healing, and pelvic fibrosis increasing the risk of operative com-plications. Postoperative radiation allows accurate pathologic staging of the resected tumor and lymph nodes and avoids the wound healing problems associated with preoperative radiation. However, bulky tumors, tumors involving adjacent organs, and very low rectal tumors may be much more difficult to resect without preoperative radiation and may require a more exten-sive operation.124-127Stage III: Lymph Node Metastasis (Tany, N1, M0). Many surgeons now recommend chemotherapy and radiation either preor postoperatively for node-positive rectal cancers. The advantages and disadvantages are similar to those listed for stage II disease, except that the likelihood of overtreating an early-stage lesion is considerably less.Over the past two decades, a wide variety of studies have addressed the issue of adjuvant and neoadjuvant therapy for locally advanced rectal cancer. Many of these studies demon-strated both improved local control and prolonged survival and resulted in the 1990 National Institutes of Health (NIH) con-sensus conference recommendation for postoperative chemo-radiation therapy in these patients. There is little controversy regarding chemoradiation therapy for stage III (node-positive) disease. However, advances in surgical technique, such as TME, for locally advanced node-negative cancers (T3-4, N0; stage II) have improved local control with surgery alone, prompting some to abandon adjuvant chemoradiation in these patients, especially for those with cancers in the proximal rectum. Although the data from these studies are intriguing, other reports have shown that chemoradiation improves local control and survival even in patients who undergo TME. Thus, most colorectal surgeons in the United States continue to recommend adjuvant or neo-adjuvant therapy for patients with locally advanced disease. Many European surgeons now rely heavily on MRI staging to determine the need for neoadjuvant chemoradiation. They use neoadjuvant chemoradiation if the radial margin is threatened or involved by the cancer or if anal sphincter or other local organ invasion is present. In the United States, chemoradia-tion therapy is still recommended for all patients with stage III disease and the majority of patients with stage II disease. In select patients with T3 tumors, favorable histology, and nega-tive radial margins, chemoradiation may not be necessary, but larger prospective studies are required before this approach can be recommended.125-127Appropriate timing of chemoradiation for locally advanced rectal cancer has been debated. Historically, preopera-tive chemoradiation has been advocated based on tumor shrink-age/downstaging, improved resectability, and the possibility of performing a sphincter-sparing operation in some patients. In addition, the absence of small bowel adhesions in the pelvis may decrease toxicity. However, preoperative radiation therapy may increase operative complications and impairs wound heal-ing. Although preoperative endorectal ultrasound and MRI have improved our ability to stage rectal cancer, clinical “overstag-ing” can be problematic, and neoadjuvant therapy may there-fore overtreat patients with pT1-2, N0 tumors. Advocates of postoperative radiation therapy cite more accurate pathologic staging and fewer operative/postoperative complications. How-ever, large, bulky tumors may be unresectable or require a more extensive operation (APR, pelvic exenteration) without preop-erative therapy. In addition, postoperative pelvic radiation may compromise function of the neorectum.Comparisons of perioperative toxicity and oncologic out-come have been addressed by the German CAO/ARO/AIO-94 trial. In this study, preand postoperative chemoradiation were associated with equivalent acute toxicity and equivalent post-operative complication rates. Postoperative chemoradiation, however, doubled the risk of postoperative stricture forma-tion. In addition, preoperative chemoradiation halved the risk of local recurrence (6% vs. 12%). Based on these data, most surgeons consider preoperative chemoradiation to be the most appropriate therapy for locally advanced rectal cancer.126 In the United States, this generally consists of 5-FU based chemother-apy and 5 to 6 weeks of external beam radiation (“long course”) followed by surgery 6 to 8 weeks later. It is important to note, however, that many European centers utilize a “short course” preoperative radiation regimen consisting of 5 days of radia-tion followed by surgery within 1 to 2 weeks. At present, these modalities have not been compared in any randomized, prospec-tive trial.125,127With advances in chemoradiation, an increasing number pf patients with locally advanced rectal cancer will have com-plete shrinkage of their tumor (a clinical complete response; cCR). In light of the potential morbidity of proctectomy, it has been suggested that select patients can be managed nonopera-tively (“watch and wait”). However, data from current stud-ies are contradictory and concern remains about the ability to predict which patients with clinical complete response actually have a pathologic complete response.128 Patients selected for nonoperative management must be examined by a surgeon at a frequent intervals. Additional adjuvant chemotherapy adminis-tered after the decision for a nonoperative approach is another important consideration.128,129 At present, this approach is not recommended outside of a specialty center and/or clinical trial.Stage IV: Distant Metastasis (Tany, Nany, M1) Like stage IV colon carcinoma, survival is limited in patients with distant metastasis from rectal carcinoma. Isolated hepatic Brunicardi_Ch29_p1259-p1330.indd 130123/02/19 2:29 PM 1302SPECIFIC CONSIDERATIONSPART IIand/or pulmonary metastases are rare, but when present may be resected for cure in selected patients.119,120 Some patients will require palliative procedures. Radical resection may be required to control pain, bleeding, or tenesmus, but highly morbid pro-cedures such as pelvic exenteration and sacrectomy should generally be avoided in this setting. Local therapy using cau-tery, endocavitary radiation, or laser ablation may be adequate to control bleeding or prevent obstruction. Intraluminal stents may be useful in the uppermost rectum but often cause pain and tenesmus lower in the rectum. Occasionally, a proximal divert-ing colostomy will be required to alleviate obstruction. A mucus fistula should be created if possible to vent the distal colon. It is critical that the morbidity of any procedure be realistically weighed against potential benefit in these patients with limited life expectancy. The assistance of a palliative care team can be invaluable in this setting.116Follow-Up and SurveillancePatients who have been treated for one colorectal cancer are at risk for the development of recurrent disease (either locally or systemically) or metachronous disease (a second primary tumor). In theory, metachronous cancers should be preventable by using surveillance colonoscopy to detect and remove polyps before they progress to invasive cancer. For most patients, a colonoscopy should be performed within 12 months after the diagnosis of the original cancer (or sooner if the colon was not examined in its entirety prior to the original resection). If that study is normal, colonoscopy should be repeated every 3 to 5 years thereafter.The optimal method of following patients for recurrent cancer remains controversial. The goal of close follow-up observation is to detect resectable recurrence and to improve survival. Re-resection of local recurrence and resection of dis-tant metastasis to liver, lung, or other sites are often technically challenging and highly morbid, with only a limited chance of achieving long-term survival. Thus, only selected patients who would tolerate such an approach should be followed intensively. Because most recurrences occur within 2 years of the original diagnosis, surveillance focuses on this time period. Patients who have undergone local resection of rectal tumors also should be followed with frequent endoscopic examinations (every 3–6 months for 3 years, then every 6 months for 2 years). CEA is often followed every 3 to 6 months for 2 years. CT scans are often performed annually for 5 years, but there are few data to support this practice. More intensive surveillance is appro-priate in high-risk patients such as those with possible Lynch syndrome or T3, N+ cancers. Although intensive surveillance improves detection of resectable recurrences, it is important to note that a survival benefit has never been proven. Therefore, the risks and benefits of intensive surveillance must be weighed and treatment individualized.Treatment of Recurrent Colorectal CarcinomaBetween 20% and 40% of patients who have undergone cura-tive intent surgery for colorectal carcinoma will eventually develop recurrent disease. Most recurrences occur within the first 2 years after the initial diagnosis, but preoperative chemo-radiation therapy may delay recurrence. While most of these patients will present with distant metastases, a small propor-tion will have isolated local recurrence and may be considered for salvage surgery. Recurrence after colon cancer resection usually occurs at the local site within the abdomen or in the liver or lungs. Resection of other involved organs may be nec-essary. Recurrence of rectal cancer can be considerably more difficult to manage because of the proximity of other pelvic structures. If the patient has not received chemotherapy and radiation, then adjuvant therapy should be administered prior to salvage surgery. Radical resection may require extensive resection of pelvic organs (pelvic exenteration with or without sacrectomy). Ideally, the aim of a salvage operation should be to resect all of the tumor with negative margins. However, if the ability to achieve a negative margin is in question, the addi-tion of intraoperative radiation therapy (usually brachytherapy) can help improve local control. Pelvic MRI is useful for identi-fying tumor extension that would prevent successful resection (extension of tumor into the pelvic sidewall, involvement of the iliac vessels or bilateral sacral nerves, sacral invasion above the S2-S3 junction). Patients should also undergo a thorough pre-operative evaluation to identify distant metastases (CT of chest, abdomen, and pelvis, and PET scan) before undergoing such an extensive procedure. Nevertheless, radical salvage surgery can prolong survival in selected patients.Minimally Invasive Techniques for ResectionLaparoscopic colectomy for cancer has been controversial. Early reports of high port site recurrence dampened enthusiasm for this technique.130 The ability to perform an adequate onco-logic resection for cancer has also been questioned. Several tri-als have laid to rest many of these fears. The Clinical Outcomes of Surgical Therapy (COST) Study Group, the Colon Car-cinoma Laparoscopic or Open Resection (COLOR) trial, and the United Kingdom Medical Research Council Conventional versus Laparoscopic-Assisted Surgery in Colorectal Cancer (CLASSICC) trial all have shown oncologic equivalence between open and laparoscopic techniques. In these multi-institutional studies, the rates of cancer recurrence, survival, and quality of life were similar, suggesting that, in the hands of an appropriately trained surgeon, laparoscopic colectomy is appropriate for colon cancer.131-136 The recent introduction of robotic surgery offers an additional minimally invasive approach. Early studies suggest that robotic surgery may be the oncologic equivalent to laparo-scopic surgery for colon cancer.137Laparoscopic surgery for rectal cancer has been more controversial. Multiple studies of laparoscopic total mesorectal excision for rectal cancer have demonstrated decreased blood loss, earlier return of bowel function and shorter length of stay compared with open TME. While a laparoscopic approach to mobilization of the left colon and splenic flexure can be used in rectal resection procedures, laparoscopic TME refers to comple-tion of the pelvic dissection laparoscopically and not through the abdominal extraction site. Technical challenges in the retraction of the rectum and surrounding soft tissues and transection of the distal rectum mandate careful evaluation oncologic outcomes. Two recent randomized controlled trials from the United States (ACOSOG Z6051)138 and Australia and New Zealand (ALaC-aRT: Australasian Laparoscopic Cancer of the Rectum Trial)139 have shown that laparoscopic surgery is not superior to open surgery in this regard. When the totality of evidence from nine randomized trials is evaluated, CRM was positive in 7.9% of laparoscopic and 6.1% of open rectal resections, a difference that was not statistically significant.17 In trials that reported the completeness of mesorectal excision (n = 5), inadequate TME was significantly more likely in laparoscopic (13.2%) com-pared with open (10.4%) resections. Long-term recurrence and 6Brunicardi_Ch29_p1259-p1330.indd 130223/02/19 2:29 PM 1303COLON, RECTUM, AND ANUSCHAPTER 29survival data from ACOSOG and ALaCaRT studies will be needed to determine what role laparoscopy should play in rectal cancer surgery. Two earlier trials, COLOR (COlon cancer Lapa-roscopic or Open Resection) II134 and COREAN (Comparison of Open versus laparoscopic surgery for mid and low Rectal cancer After Neoadjuvant chemoradiotherapy),135 have shown equivalent 3-year recurrence and survival. It is possible that spe-cific subsets of patients are more appropriate for open surgery. For example, ALaCaRT authors thought laparoscopic surgery may be less successful in patients who had neoadjuvant therapy, larger T3 tumors, or higher BMIs, but their study was under-powered to make definitive conclusions in these patients. A laparoscopic approach should not be considered for T4 tumors.The inferior quality of laparoscopic rectal cancer surgery suggested by recent randomized trials is attributed to techni-cal limitations, leading to the suggestion that robotic surgery, with its wristed instruments, fixed platform, and potentially improved visualization could offer an improvement. The results of the ROLARR (Robotic vs Laparoscopic Resection for Rectal Cancer) randomized trial will offer more data on the quality of TME and margins after robotic surgery; however, a trial com-paring open to robotic dissection will also be important.141OTHER NEOPLASMSRare Colorectal TumorsNeuroendocrine Tumors. Neuroendocrine tumors occur most commonly in the gastrointestinal tract, and up to 25% of these tumors are found in the rectum. Well-differentiated neuroendo-crine tumors (also known as carcinoid tumors) are commonly identified on colonoscopy as small (<1 cm) nodules and have a benign clinical course, with overall survival is greater than 80%. However, the risk of malignancy increases with size, and more than 60% of tumors greater than 2 cm in diameter are associated with distant metastases. Rectal neuroendocrine tumors appear to be less likely to secrete vasoactive substances than carcinoids in other locations, and carcinoid syndrome is uncommon in the absence of hepatic metastases. Small carcinoids can be locally resected transanally. Larger tumors, poorly differentiated tumors (such as small cell or large cell neuroendocrine carcinomas), and those with obvious invasion into the muscularis require more radical surgery. Neuroendocrine tumors in the proximal colon are less common and are more likely to be malignant. Size also correlates with risk of malignancy, and tumors less than 2 cm in diameter rarely metastasize. However, the majority of neuroendocrine tumors in the proximal colon present as bulky lesions, and up to two-thirds of patients will have metastatic spread at the time of diagnosis. These tumors should usually be treated with radical resection. Because well-differentiated neuroendocrine tumors are typically slow growing, patients with distant metastases may expect reasonably long survival. Symptoms of carcinoid syndrome can often be alleviated with somatostatin analogues (octreotide) and/or interferon-α. Tumor debulking can offer effective palliation in selected patients.142-144Mixed Adenoneuroendocrine Carcinomas. Mixed adeno-neuroendocrine carcinomas, also known as composite carcinoid carcinomas, adenocarcinoids tumors, amphicrine or collision tumors, have histologic features of both neuroendocrine tumors and adenocarcinomas. The natural history of these tumors more closely parallels that of adenocarcinomas than neuroendocrine tumors, and regional and systemic metastases are common. Carcinoid carcinoma of the colon and rectum should be treated according to the same oncologic principles as followed for man-agement of adenocarcinoma.Lipomas. Lipomas are benign lesions that occur most com-monly in the submucosa of the colon and rectum. The major-ity of lipomas are asymptomatic and discovered incidentally. Small asymptomatic lesions do not require resection. However, larger lesions may occasionally cause bleeding, obstruction, or intussusception, especially when greater than 2 cm in diameter. Larger lipomas should be resected by colonoscopic techniques or by a colotomy and enucleation or limited colectomy.144Lymphoma. Gastrointestinal lymphoma may be primary or generalized/secondary. Primary GI lymphomas occur most fre-quently in the terminal ileum and cecum. Lymphoma involv-ing the colon and rectum is rare, but it accounts for about 10% of all gastrointestinal lymphomas. Presentation, treatment and prognosis differ between patients with lymphoma occurring as a localized entity in the colon and rectum versus those inoccur-ing in patients who have generalized lymphoma with colorectal involvement. Symptoms in isolated rectal lymphoma include bleeding, obstruction, and pain, and these tumors may be clini-cally indistinguishable from adenocarcinomas. The cecum is most often involved, probably as a result of spread from the terminal ileum. Symptoms include bleeding and obstruction. Bowel resec-tion is the treatment of choice for isolated colorectal lymphoma. Adjuvant therapy may be given based on the stage of disease.144Leiomyoma and Leiomyosarcoma. Leiomyomas are benign tumors of the smooth muscle of the bowel wall and occur most commonly in the upper gastrointestinal tract. Most patients are asymptomatic, and lesions are often diagnosed inciden-tally when a mass is seen on endoscopy or felt on digital rec-tal examination. However, large lesions can cause bleeding or obstruction. Because it is difficult to differentiate a benign leio-myoma from a malignant leiomyosarcoma, these lesions should be resected. Recurrence is common after local resection, but most small leiomyomas can be adequately treated with limited resection. Lesions larger than 5 cm should be treated with radi-cal resection because the risk of malignancy is high.Leiomyosarcoma is rare in the gastrointestinal tract. When this malignancy occurs in the large intestine, the rectum is the most common site. Leiomyosarcoma of the rectum is usually low grade, and, as such, can be difficult to differentiate from leiomyoma. Definitive diagnosis is usually made after resection. Symptoms, when they occur, are usually bleeding or obstruc-tion. A radical resection is indicated for most of these tumors. Despite complete resection, recurrence is not uncommon, and prognosis is generally poor.144Gastrointestinal Stromal Tumor (GIST). Gastrointestinal Stromal Tumors (GIST) are most common in the proximal GI tract but do occasionally occur in the colorectum (5–10%) and may be mistaken for leiomyomas. GISTs are mesenchy-mal tumors that arise from the interstitial cells of Cajal. The vast majority (>95%) of GISTs express CD117 (KIT), and as such, are sensitive to tyrosine kinase inhibitors (TKIs), such as imatinib mesylate and sunitinib malate. Risk stratification is based on tumor size and mitotic activity, and 30% to 50% are malignant. Although small GISTs may be asymptomatic and discovered incidentally, larger lesions can cause bleeding, obstruction, or abdominal pain. Treatment of choice is surgi-cal resection (either local excision or radical resection) with Brunicardi_Ch29_p1259-p1330.indd 130323/02/19 2:29 PM 1304SPECIFIC CONSIDERATIONSPART IImicroscopically negative margins, if possible; however, local recurrence is common. For larger marginally resectable tumors, TKIs (imatinib) can be used to shrink the tumor. These agents can also be considered for adjuvant therapy after resection and are useful for treating metastatic disease.144Retrorectal/Presacral TumorsTumors occurring in the retrorectal space are rare. This region lies between the upper two-thirds of the rectum and the sacrum above the rectosacral fascia. It is bound by the rectum anteri-orly, the presacral fascia posteriorly, and the endopelvic fascia laterally (lateral ligaments). The retrorectal space contains mul-tiple embryologic remnants derived from a variety of tissues (neuroectoderm, notochord, and hindgut). As such, tumors that develop in this space are often heterogeneous.Congenital lesions are most common, comprising almost two-thirds of retrorectal lesions. The remainder are classified as neurogenic, osseous, inflammatory, or miscellaneous lesions. Malignancy is more common in the pediatric population than in adults, and solid lesions are more likely to be malignant than are cystic lesions. Inflammatory lesions may be solid or cystic (abscess) and usually represent extensions of infection either in the perirectal space or in the abdomen.Developmental cysts constitute the majority of congenital lesions and may arise from all three germ cell layers. Dermoid and epidermoid cysts are benign lesions that arise from the ecto-derm. Enterogenous cysts arise from the primitive gut. Anterior meningocele and myelomeningocele arise from herniation of the dural sac through a defect in the anterior sacrum. A “scimitar sign” (sacrum with a rounded, concave border without any bony destruction) is the pathognomonic radiographic appearance of this condition.Solid lesions include teratomas, chordomas, neurologic tumors, or osseous lesions. Teratomas are true neoplasms and contain tissue from each germ cell layer. They often contain both cystic and solid components. Teratomas are more com-mon in children than in adults, but when found in adults, 30% are malignant. Chordomas arise from the notochord and are the most common malignant tumor in this region. These are slow-growing, invasive cancers that show characteristic bony destruc-tion. Neurogenic tumors include neurofibromas and sarcomas, neurilemomas, ependymomas, and ganglioneuromas. Osseous lesions include osteomas and bone cysts, as well as neoplasms such as osteogenic sarcoma, Ewing’s tumor, chondromyxosar-coma, and giant cell tumors.Patients may present with pain (lower back, pelvic, or lower extremity), gastrointestinal symptoms, or urinary tract symptoms. Most lesions are palpable on digital rectal examina-tion. While plain X-rays and CT scans often are used to evalu-ate these lesions, pelvic MRI is the most sensitive and specific imaging study. Myelogram is occasionally necessary if there is central nervous system involvement. Treatment is almost always surgical resection. The approach depends in part on the nature of the lesion and its location. Lesions high in the pelvis may be approached via a transabdominal route, whereas low lesions may be resected transsacrally. Intermediate lesions may require a combined abdominal and sacral operation. Although survival is excellent after resection of benign lesions, local recurrence is not uncommon. Prognosis after resection of malignant lesions is highly variable and reflects the biology of the underlying tumor.The role of biopsy in this setting has been controversial. Historically, the recommendation was to avoid biopsy because of the risk of infection or needle tract seeding. This recommen-dation has recently been challenged, especially for large and/or unusual tumors that would be better treated with multimodality neoadjuvant therapy (GIST, sarcoma, metastatic adenocarci-noma). A recent study confirmed the utility of needle biopsy of solid lesions and refuted concerns about needle tract seeding. As such, most solid lesions should be biopsied regardless of resectability. Biopsy or aspiration of cystic lesions, especially meningoceles, should still be avoided because of the risk of infection.144-147Anal Canal and Perianal TumorsCancers of the anal canal are uncommon and account for approx-imately 2% of all colorectal malignancies. Neoplasms of the anal canal have traditionally been divided into those affecting the anal margin (distal to the dentate line) and those affecting the anal canal (proximal to the dentate line) based on lymphatic drainage patterns. Lymphatics from the anal canal proximal to the dentate line drain cephalad via the superior rectal lymphat-ics to the inferior mesenteric nodes and laterally along both the middle rectal vessels and inferior rectal vessels through the ischiorectal fossa to the internal iliac nodes. Lymph from the anal canal distal to the dentate line usually drains to the inguinal nodes. It can also drain to the superior rectal lymph nodes or along the inferior rectal lymphatics to the ischiorectal fossa if primary drainage routes are blocked with tumor (Fig. 29-27).A more clinically useful classification divides anal lesions into those that are perianal (can be completely visualized with gentle eversion of the buttocks) and those that are intra-anal (cannot be completely visualized with gentle eversion of the buttocks). In many cases, therapy depends on whether the tumor is perianal or intra-anal.Squamous Intraepithelial Lesions. Anal canal and peri-anal dysplasia have long had a potpourri of nomenclature. Anal intraepithelial neoplasia (AIN), Bowen’s disease, and carci-noma in situ all refer to human papillomavirus (HPV)–induced Inferiormesenteric a.Superiorrectal a.Middlerectal a.Inferiorrectal a.Common iliac a.Figure 29-27. Lymphatic drainage of the anal canal. a. = artery.Brunicardi_Ch29_p1259-p1330.indd 130423/02/19 2:29 PM 1305COLON, RECTUM, AND ANUSCHAPTER 29dysplasia. Because these entities are pathologically identical, there has been an effort to standardize nomenclature. High-grade squamous intraepithelial lesions (HSIL) include highand intermediate-grade dysplasia, AINII and AINIII, Bowen’s disease, and carcinoma in situ. Low-grade squamous intraepi-thelial lesions (LSIL) includes low-grade dysplasia and AINI. Recently, the terms High-grade AIN (HGAIN; AINIII) and low-grade AIN (LGAIN; AIN I/II) have been suggested.146-148 Both highand low-grade lesions are associated with infection with HPV, especially types 16 and 18.High-grade lesions are precursors to invasive squamous cell carcinoma (epidermoid carcinoma) and may appear as a plaque or may only be apparent with high-resolution anoscopy and application of acetic acid and/or Lugol’s iodine solution. The incidence of both squamous intraepithelial lesions and epidermoid carcinoma of the anus has increased dramatically among human immunodeficiency virus (HIV)–positive men who have sex with men. This increase is thought to result from increased rates of HPV infection along with HIV-induced immu-nosuppression. Treatment of high-grade dysplasia is ablation. Because of a high recurrence and/or reinfection rate, these patients require close surveillance. High-risk patients should be followed with frequent anal Papanicolaou (Pap) smears every 3 to 6 months. An abnormal Pap smear should be followed by an examination under anesthesia and anal mapping using high-resolution anoscopy. High-resolution anoscopy shows areas with abnormal telangiectasias that are consistent with high-grade dysplasia. Many centers now consider this technique for repeated ablation of high-grade lesions to be the optimal method for following these patients.148-150 It should be noted, however, that the practice has not been universally adopted, and it is unclear whether close surveillance in lower-risk (nonimmu-nosuppressed) patients is necessary. Rarely, extensive disease may require resection with flap closure. Medical therapy for HPV has also been proposed. Topical immunomodulators such as imiquimod (Aldara) have been shown to induce regression in some series.151 Topical 5-fluorouracil has also been used in this setting. Finally, the introduction of a vaccine against HPV may help decrease the incidence of this disease in the future.Epidermoid Carcinoma. Epidermoid carcinoma of the anus includes squamous cell carcinoma, cloacogenic carcinoma, tran-sitional carcinoma, and basaloid carcinoma. The clinical behav-ior and natural history of these tumors are similar. Epidermoid carcinoma is a slow-growing tumor and usually presents as an intra-anal or perianal mass. Pain and bleeding may be present. Perianal epidermoid carcinoma may be treated in a similar fash-ion as squamous cell carcinoma of the skin in other locations because wide local excision can usually be achieved without resecting the anal sphincter. Intra-anal epidermoid carcinoma cannot be excised locally, and first-line therapy relies on chemo-therapy and radiation (the Nigro protocol: 5-fluorouracil, mitomycin C, and 30 Gy of external beam radiation). This regimen cures 70% to 80% of these tumors. It is important to note that epidermoid carcinomas continue to respond after com-pletion of chemoradiation. Lesions that persist greater than 3 to 6 months after therapy may represent persistent disease and should be biopsied. Recurrence usually requires radical resec-tion (APR). Metastasis to inguinal lymph nodes is a poor prog-nostic sign.148Verrucous Carcinoma (Buschke-Lowenstein Tumor, Giant Condyloma Acuminata). Verrucous carcinoma is a locally aggressive form of condyloma acuminata. Although these lesions do not metastasize, they can cause extensive local tissue destruction and may be grossly indistinguishable from epider-moid carcinoma. Wide local excision is the treatment of choice when possible, but radical resection may sometimes be required. Topical immunomodulators such as imiquimod (Aldara) may shrink some tumors, but they are almost never curative.151 Very large lesions may respond to external beam radiation, but resec-tion is almost always required.Basal Cell Carcinoma. Basal cell carcinoma of the anus is rare and resembles basal cell carcinoma elsewhere on the skin (raised, pearly edges with central ulceration). This is a slow-growing tumor that rarely metastasizes. Wide local excision is the treatment of choice, but recurrence occurs in up to 30% of patients. Radical resection and/or radiation therapy may be required for large lesions.Adenocarcinoma. Adenocarcinoma of the anus is extremely rare and usually represents downward spread of a low rectal ade-nocarcinoma. Adenocarcinoma may occasionally arise from the anal glands or may develop in a chronic fistula. Radical resection, usually after neoadjuvant chemoradiation, is usually required.Extramammary perianal Paget’s disease is adenocarci-noma in situ arising from the apocrine glands of the perianal area. The lesion is typically plaque-like and may be indistin-guishable from high-grade intraepithelial lesions. Characteristic Paget’s cells are seen histologically. These tumors are often associated with a synchronous gastrointestinal adenocarcinoma, so a complete evaluation of the intestinal tract should be per-formed. Wide local excision is usually adequate treatment for perianal Paget’s disease.Melanoma. Anorectal melanoma is rare, comprising less than 1% of all anorectal malignancies and 1% to 2% of melanomas. Diagnosis is often delayed, and symptoms are attributed to hem-orrhoidal disease. Despite many advances in the treatment of cutaneous melanoma, prognosis for patients with anorectal dis-ease remains poor. Overall 5-year survival is less than 10%, and many patients present with systemic metastasis and/or deeply invasive tumors at the time of diagnosis. A few patients with anorectal melanoma, however, present with isolated local or locoregional disease that is potentially resectable for cure, and both radical resection (APR) and wide local excision have been advocated. Recurrence is common and usually occurs systemi-cally regardless of the initial surgical procedure. Local resection with free margins does not increase the risk of local or regional recurrence, and APR offers no survival advantage over local excision. Because of the morbidity associated with APR, wide local excision is recommended for initial treatment of localized anal melanoma. In some patients, wide local excision may not be technically feasible, and APR may be required if the tumor involves a significant portion of the anal sphincter or is circum-ferential. The addition of adjuvant chemotherapy, biochemo-therapy, vaccines, or radiotherapy may be of benefit in some patients, but efficacy remains unproven.152,153OTHER BENIGN COLORECTAL CONDITIONSRectal Prolapse and Solitary Rectal Ulcer SyndromeRectal Prolapse. Rectal prolapse refers to a circumferential, full-thickness protrusion of the rectum through the anus and has also been called “first-degree” prolapse, “complete” prolapse, or 7Brunicardi_Ch29_p1259-p1330.indd 130523/02/19 2:29 PM 1306SPECIFIC CONSIDERATIONSPART IIprocidentia. Internal prolapse occurs when the rectal wall intus-suscepts but does not protrude and is probably more accurately described as internal intussusception. Mucosal prolapse is a partial-thickness protrusion often associated with hemorrhoidal disease and is usually treated with banding or hemorrhoidectomy.In adults, this condition is far more common among women, with a female-to-male ratio of 6:1. Prolapse becomes more prevalent with age in women and peaks in the sev-enth decade of life. In men, prevalence is unrelated to age. Symptoms include tenesmus, a sensation of tissue protruding from the anus that may or may not spontaneously reduce, and a sensation of incomplete evacuation. Mucus discharge and leak-age may accompany the protrusion. Patients also present with a myriad of functional complaints, from incontinence and diar-rhea to constipation and outlet obstruction.A thorough preoperative evaluation, including colonic transit studies, anorectal manometry, tests of pudendal nerve terminal motor latency, EMG, and cinedefecography, may be useful. The colon should be evaluated by colonoscopy, aircontrast barium enema, or CT colonography to exclude neo-plasms or diverticular disease. Cardiopulmonary condition should be thoroughly evaluated because comorbidities may influence the choice of surgical procedure.The primary therapy for rectal prolapse is surgery, and more than 100 different procedures have been described to treat this condition. Operations can be categorized as either abdominal or perineal. Abdominal operations have taken three major approaches: (a) reduction of the perineal hernia and closure of the cul-de-sac (Moschowitz repair); (b) fixation of the rectum, either with a prosthetic mesh or fascia lata sling (Ripstein and Wells rectopexy; ventral rectopexy) or by suture rectopexy; or (c) resection of redundant sigmoid colon (Fig. 29-28). In some cases, resection is combined with rectal fixation (resection rectopexy). The recently described ventral rectopexy involves dissection of the anterior rectum down to the pelvic floor. Mesh is sutured to the anterior rectum at one end and anchored to the sacral promontory at the other end.154 Abdominal procedures for rectal prolapse are increasingly performed laparoscopically or robotically. Perineal approaches have focused on tightening the anus with a variety of prosthetic materials, reefing the rectal mucosa (Delorme procedure), or resecting the prolapsed bowel from the perineum (perineal rectosigmoidectomy or Altemeier procedure) (Fig. 29-29).Because rectal prolapse occurs most commonly in elderly women, the choice of operation depends in part on the patient’s overall medical condition. Abdominal rectopexy (with or with-out sigmoid resection) offers the most durable repair, with recurrence occurring in less than 10% of patients. Perineal rectosigmoidectomy avoids an abdominal operation and may be preferable in high-risk patients but is associated with a higher recurrence rate. Reefing the rectal mucosa is effective for patients with limited prolapse. Anal encirclement procedures generally have been abandoned.Solitary Rectal Ulcer Syndrome. Solitary rectal ulcer syn-drome and colitis cystica profunda are commonly associated with internal intussusception. Patients may complain of pain, bleeding, mucus discharge, or outlet obstruction. In solitary rec-tal ulcer syndrome, one or more ulcers are present in the distal rectum, usually on the anterior wall. In colitis cystica profunda, nodules or a mass may be found in a similar location. Evalu-ation should include anorectal manometry, defecography, and either colonoscopy or barium enema to exclude other diagnoses. Biopsy of an ulcer or mass is mandatory to exclude malignancy or infection due to cytomegalovirus (CMV) in an immunosup-pressed patient. Nonoperative therapy (high-fiber diet, def-ecation training to avoid straining, and laxatives or enemas) is effective in the majority of patients. Biofeedback has also been reported to be effective in some patients. Surgery (either abdominal or perineal repair of prolapse as described earlier) is reserved for highly symptomatic patients who have failed all medical interventions.VolvulusVolvulus occurs when an air-filled segment of the colon twists about its mesentery. The sigmoid colon is involved in up to 90% of cases, but volvulus can involve the cecum (<20%) or trans-verse colon. A volvulus may reduce spontaneously, but more commonly produces bowel obstruction, which can progress to strangulation, gangrene, and perforation. Chronic constipation may produce a large, redundant colon (chronic megacolon) that predisposes to volvulus, especially if the mesenteric base is narrow.The symptoms of volvulus are those of acute bowel obstruction. Patients present with abdominal distention, nau-sea, and vomiting. Symptoms rapidly progress to generalized abdominal pain and tenderness. Fever and leukocytosis are her-alds of gangrene and/or perforation. Occasionally, patients will report a long history of intermittent obstructive symptoms and distention, suggesting intermittent chronic volvulus.Sigmoid Volvulus. Sigmoid volvulus can often be differenti-ated from cecal or transverse colon volvulus by the appearance of plain X-rays of the abdomen. Sigmoid volvulus produces a characteristic bent inner tube or coffee bean appearance, with the convexity of the loop lying in the right upper quadrant (opposite the site of obstruction). Gastrografin enema shows a 8Figure 29-28. Transabdominal proctopexy for rectal prolapse. The fully mobilized rectum is sutured to the presacral fascia. A. Anterior view. B. Lateral view. If desired, a sigmoid colectomy can be performed con-comitantly to resect the redundant colon.BABrunicardi_Ch29_p1259-p1330.indd 130623/02/19 2:29 PM 1307COLON, RECTUM, AND ANUSCHAPTER 29narrowing at the site of the volvulus and a pathognomonic bird’s beak (Fig. 29-30).Unless there are obvious signs of gangrene or peritoni-tis, the initial management of sigmoid volvulus is resuscitation followed by endoscopic detorsion. Detorsion is usually most easily accomplished by using a rigid proctoscope, but a flexible sigmoidoscope or colonoscope may also be effective. A rec-tal tube may be inserted to maintain decompression. Although these techniques are successful in reducing sigmoid volvulus in the majority of patients, the risk of recurrence is high (up to 40%). For this reason, an elective sigmoid colectomy should be performed after the patient has been stabilized and undergone an adequate bowel preparation.Clinical evidence of gangrene or perforation mandates immediate surgical exploration without an attempt at endoscopic decompression. Similarly, the presence of necrotic mucosa, ulcer-ation, or dark blood noted on endoscopy examination suggests strangulation and is an indication for operation. If dead bowel is present at laparotomy, a sigmoid colectomy with end colostomy (Hartmann’s procedure) may be the safest operation to perform.Cecal Volvulus. Cecal volvulus results from nonfixation of the right colon. In the majority of cases, rotation occurs around the ileocolic blood vessels and vascular impairment occurs early, although 10% to 30% of the cecum folds upon itself (cecal bascule). Plain X-rays of the abdomen show a characteristic kidney-shaped, air-filled structure in the left upper quadrant (opposite the site of obstruction), and a Gastrografin enema confirms obstruction at the level of the volvulus.Unlike sigmoid volvulus, cecal volvulus can almost never be detorsed endoscopically. Moreover, because vascular com-promise occurs early in the course of cecal volvulus, surgical exploration is necessary when the diagnosis is made. Right hemicolectomy with a primary ileocolic anastomosis can usu-ally be performed safely and prevents recurrence. Simple detor-sion or detorsion and cecopexy are associated with a high rate of recurrence.Transverse Colon Volvulus. Transverse colon volvulus is extremely rare. Nonfixation of the colon and chronic consti-pation with megacolon may predispose to transverse colon AFCEDBFigure 29-29. Perineal rectosigmoidectomy shown in lithotomy position. A. A circular incision is made 2 cm proximal to the dentate line. B. The anterior peritoneal reflection is opened. C. The mesentery is divided and ligated. D. The peritoneum may be sutured to the bowel wall. E. The bowel is resected. F. A hand-sewn anastomosis is performed.Brunicardi_Ch29_p1259-p1330.indd 130723/02/19 2:29 PM 1308SPECIFIC CONSIDERATIONSPART IIvolvulus. The radiographic appearance of transverse colon volvulus resembles sigmoid volvulus, but Gastrografin enema will reveal a more proximal obstruction. Although colonoscopic detorsion is occasionally successful in this setting, most patients require emergent exploration and resection.MegacolonMegacolon describes a chronically dilated, elongated, hypertro-phied large bowel. Megacolon may be congenital or acquired and is usually related to chronic mechanical or functional obstruction. In general, the degree of megacolon is related to the duration of obstruction. Evaluation must always include examination of the colon and rectum (either endoscopically or radiographically) to exclude a surgically correctable mechanical obstruction.Congenital megacolon caused by Hirschsprung’s disease results from the failure of migration of neural crest cells to the distal large intestine. The resulting absence of ganglion cells in the distal colon results in a failure of relaxation and causes a functional obstruction. The proximal, healthy bowel becomes progressively dilated. Surgical resection of the aganglionic seg-ment is curative. Although Hirschsprung’s disease primarily is a disease of infants and children, it occasionally presents later in adulthood, especially if an extremely short segment of the bowel is affected (ultrashort-segment Hirschsprung’s disease).Acquired megacolon may result from infection or chronic constipation. Infection with the protozoan Trypanosoma cruzi (Chagas’ disease) destroys ganglion cells and produces both megacolon and megaesophagus. Chronic constipation from slow transit or secondary to medications (especially anticholinergic medications) or neurologic disorders (paraplegia, poliomyelitis, amyotrophic lateral sclerosis, multiple sclerosis) may produce progressive colonic dilatation. Diverting ileostomy or subtotal colectomy with an ileorectal anastomosis is occasionally neces-sary in these patients.Colonic Pseudo-Obstruction (Ogilvie’s Syndrome)Colonic pseudo-obstruction (Ogilvie’s syndrome) is a func-tional disorder in which the colon becomes massively dilated in the absence of mechanical obstruction. Pseudo-obstruction most commonly occurs in hospitalized patients and is associated with the use of narcotics, bed rest, and comorbid disease. Pseudo-obstruction is thought to result from autonomic dysfunction and severe adynamic ileus. The diagnosis is made based on the pres-ence of massive dilatation of the colon (usually predominantly the right and transverse colon) in the absence of a mechanical obstruction. Initial treatment consists of cessation of narcotics, anticholinergics, or other medications that may contribute to ileus. Strict bowel rest and intravenous hydration are crucial. Most patients will respond to these measures. In patients who fail to improve, colonoscopic decompression often is effective. However, this procedure is technically challenging, and great care must be taken to avoid causing perforation. Up to 40% of patients recur. Intravenous neostigmine (an acetylcholines-terase inhibitor), administered as a single 2 mg dose, also is extremely effective in decompressing the dilated colon and is associated with a low rate of recurrence (20%).155 However, neostigmine may produce transient but profound bradycardia and may be inappropriate in patients with cardiopulmonary ABFigure 29-30. Sigmoid volvulus: (A) Illustration and (B) Gastrografin enema showing “bird-beak” sign (arrow). (B. Reproduced with per-mission from James EC, Corry RJ, Perry JCF: Basic Surgical Practice. Philadelphia, PA: Hanley & Belfus; 1987.)Brunicardi_Ch29_p1259-p1330.indd 130823/02/19 2:29 PM 1309COLON, RECTUM, AND ANUSCHAPTER 29disease. Because the colonic dilatation is typically greatest in the proximal colon, placement of a rectal tube is rarely effective. It is crucial to exclude mechanical obstruction (usually with a Gastrografin enema) prior to medical or endoscopic treatment.Ischemic ColitisIntestinal ischemia occurs most commonly in the colon. Unlike small bowel ischemia, colonic ischemia rarely is associated with major arterial or venous occlusion. Instead, most colonic isch-emia appears to result from low flow and/or small vessel occlu-sion. Risk factors include vascular disease, diabetes mellitus, vasculitis, hypotension, and tobacco use. In addition, ligation of the inferior mesenteric artery during aortic surgery predisposes to colonic ischemia. Occasionally, thrombosis or embolism may cause ischemia. Although the splenic flexure is the most com-mon site of ischemic colitis, any segment of the colon may be affected. The rectum is relatively spared because of its rich col-lateral circulation.Signs and symptoms of ischemic colitis reflect the extent of bowel ischemia. In mild cases, patients may have diarrhea (usually bloody) without abdominal pain. With more severe ischemia, intense abdominal pain (often out of proportion to the clinical examination), tenderness, fever, and leukocytosis are present. Peritonitis and/or systemic toxicity are signs of full-thickness necrosis and perforation.The diagnosis of ischemic colitis is often based on the clinical history and physical examination. Plain films may reveal thumb printing, which results from mucosal edema and submucosal hemorrhage. CT often shows nonspecific colonic wall thickening and pericolic fat stranding. Angiography is usually not helpful because major arterial occlusion is rare. While sigmoidoscopy may reveal characteristic dark, hemor-rhagic mucosa, the risk of precipitating perforation is high. For this reason, sigmoidoscopy is relatively contraindicated in any patient with significant abdominal tenderness. Contrast studies (Gastrografin or barium enema) are similarly contraindicated during the acute phase of ischemic colitis.Treatment of ischemic colitis depends on clinical severity. Unlike ischemia of the small bowel, the majority of patients with ischemic colitis can be treated medically. Bowel rest and broad-spectrum antibiotics are the mainstay of therapy, and 80% of patients will recover with this regimen. Hemodynamic parameters should be optimized, especially if hypotension and low flow appear to be the inciting cause. Long-term sequelae include stricture (10–15%) and chronic segmental ischemia (15–20%). Colonoscopy should be performed after recovery to evaluate strictures and to rule out other diagnoses such as inflammatory bowel disease or malignancy. Failure to improve after 2 to 3 days of medical management, progression of symp-toms, and deterioration in clinical condition are indications for surgical exploration. In this setting, all necrotic bowel should be resected. Primary anastomosis should be avoided. Occasion-ally, repeated exploration (a second-look operation) may be necessary.Infectious ColitisPseudomembranous Colitis (Clostridium difficile Colitis).  Pseudomembranous colitis is caused by C difficile, a gram-positive anaerobic bacillus. Clostridium difficile colitis is extremely common and is the leading cause of nosocomially acquired diarrhea. The spectrum of disease ranges from watery diarrhea to fulminant, life-threatening colitis. Clostridium dif-ficile is carried in the large intestine of many healthy adults. Colitis is thought to result from overgrowth of this organism after depletion of the normal commensal flora of the gut with the use of antibiotics. Although clindamycin was the first anti-microbial agent associated with C difficile colitis, almost any antibiotic may cause this disease. Moreover, although the risk of C difficile colitis increases with prolonged antibiotic use, even a single dose of an antibiotic may cause the disease. Immunosup-pression, medical comorbidities, prolonged hospitalization or nursing home residence, and bowel surgery increase the risk.The pathogenic changes associated with C difficile colitis result from production of two toxins: toxin A (an enterotoxin) and toxin B (a cytotoxin). Diagnosis of this disease was tradition-ally made by culturing the organism from the stool. Detection of one or both toxins (either by cytotoxic assays or by immuno-assays) has proven to be more rapid, sensitive, and specific.156 The diagnosis may also be made endoscopically by detection of characteristic ulcers, plaques, and pseudomembranes.157Management should include immediate cessation of the offending antimicrobial agent. Patients with mild disease (diar-rhea but no fever or abdominal pain) may be treated as outpatients with a 10-day course of oral metronidazole. Oral vancomycin is a second-line agent used in patients allergic to metronidazole or in patients with recurrent disease. More severe diarrhea associ-ated with dehydration and/or fever and abdominal pain is best treated with bowel rest, intravenous hydration, and oral met-ronidazole or vancomycin. Proctosigmoiditis may respond to vancomycin enemas. Recurrent colitis occurs in up to 20% of patients and may be treated by a longer course of oral vanco-mycin (up to 1 month) or rifaximin (a rapamycin derivative). Reintroduction of normal flora by ingestion of probiotics or stool transplantation has been suggested as a possible treatment for recurrent or refractory disease. Fulminant colitis, characterized by septicemia and/or evidence of perforation, requires emergent laparotomy. A total abdominal colectomy with end ileostomy may be lifesaving. Over the past decade, C difficile colitis has increased in prevalence, and new, more virulent strains have appeared, making this disease increasingly challenging to treat.157,158Other Infectious Colitides. A variety of other infections with bacteria, parasites, fungi, or viruses may cause colonic inflammation. Common bacterial infections include enterotoxic E coli, C jejuni, Yersinia enterocolitica, S typhi, Shigella, and N gonorrhoeae. Less commonly, Mycobacterium tuberculosis, M bovis, Actinomycosis israelii, or Treponema pallidum (syphi-lis) may cause colitis or proctitis. Parasitic infections such as amebiasis, cryptosporidiosis, and giardiasis are also relatively common. Fungal infections (Candida species, histoplasmosis) are extremely rare in otherwise healthy individuals. The most common viral infections that produce colitic symptoms are HIV, herpes simplex viruses, and CMV.Most symptoms are nonspecific and consist of diarrhea (with or without bleeding), crampy abdominal pain, and mal-aise. A thorough history may offer clues to the etiology (other medical conditions, especially immunosuppression; recent travel or exposures; and ingestions). Diagnosis is usually made by identification of a pathogen in the stool, either by microscopy or culture. Serum immunoassays may also be useful (amebia-sis, HIV, CMV). Occasionally, endoscopy with biopsy may be required. Treatment is tailored to the infection.Brunicardi_Ch29_p1259-p1330.indd 130923/02/19 2:29 PM 1310SPECIFIC CONSIDERATIONSPART IIANORECTAL DISEASESAny patient with anal/perianal symptoms requires a careful his-tory and physical, including a digital rectal examination. Other studies such as defecography, manometry, CT scan, MRI, con-trast enema, endoscopy, endoanal ultrasound, or exam under anesthesia may be required to arrive at an accurate diagnosis.HemorrhoidsHemorrhoids are cushions of submucosal tissue containing venules, arterioles, and smooth muscle fibers that are located in the anal canal (see Fig. 29-4). Three hemorrhoidal cushions are found in the left lateral, right anterior, and right poste-rior positions. Hemorrhoids are thought to function as part of the continence mechanism and aid in complete closure of the anal canal at rest. Because hemorrhoids are a normal part of anorectal anatomy, treatment is only indicated if they become symptom-atic. Excessive straining, increased abdominal pressure, and hard stools increase venous engorgement of the hemorrhoidal plexus and cause prolapse of hemorrhoidal tissue. Bleeding, thrombo-sis, and symptomatic hemorrhoidal prolapse may result.External hemorrhoids are located distal to the dentate line and are covered with anoderm. Because the anoderm is richly innervated, thrombosis of an external hemorrhoid may cause significant pain. It is for this reason that external hemorrhoids should not be ligated or excised without adequate local anes-thetic. A skin tag is redundant fibrotic skin at the anal verge, often persisting as the residua of a thrombosed external hemor-rhoid. Skin tags are often confused with symptomatic hemor-rhoids. External hemorrhoids and skin tags may cause itching and difficulty with hygiene if they are large. Treatment of exter-nal hemorrhoids and skin tags is only indicated for symptomatic relief.Internal hemorrhoids are located proximal to the dentate line and covered by insensate anorectal mucosa. Internal hem-orrhoids may prolapse or bleed, but they rarely become painful unless they develop thrombosis and necrosis (usually related to severe prolapse, incarceration, and/or strangulation). Inter-nal hemorrhoids are graded according to the extent of prolapse. First-degree hemorrhoids bulge into the anal canal and may prolapse beyond the dentate line on straining. Second-degree hemorrhoids prolapse through the anus but reduce spontane-ously. Third-degree hemorrhoids prolapse through the anal canal and require manual reduction. Fourth-degree hemorrhoids prolapse but cannot be reduced and are at risk for strangulation.Combined internal and external hemorrhoids straddle the dentate line and have characteristics of both internal and external hemorrhoids. Hemorrhoidectomy is often required for large, symptomatic, combined hemorrhoids. Postpartum hemorrhoids result from straining during labor, which results in edema, thrombosis, and/or strangulation. Hemorrhoidectomy is often the treatment of choice, especially if the patient has had chronic hemorrhoidal symptoms. Portal hypertension was long thought to increase the risk of hemorrhoidal bleeding because of the anastomoses between the portal venous system (middle and upper hemorrhoidal plexuses) and the systemic venous system (inferior rectal plexuses). It is now understood that hemorrhoidal disease is no more common in patients with portal hypertension than in the normal population. Rectal varices, however, may occur and may cause hemorrhage in these patients. In general, rectal varices are best treated by lowering portal venous pres-sure. Rarely, suture ligation may be necessary if massive bleed-ing persists. Surgical hemorrhoidectomy should be avoided in these patients because of the risk of massive, difficult-to-control variceal bleeding.Treatment Medical Therapy Bleeding from firstand second-degree hem-orrhoids often improves with the addition of dietary fiber, stool softeners, increased fluid intake, and avoidance of straining. Associated pruritus often may improve with improved hygiene. Many over-the-counter topical medications are desiccants and are relatively ineffective for treating hemorrhoidal symptoms.Rubber Band Ligation Persistent bleeding from first-, sec-ond-, and selected third-degree hemorrhoids may be treated by rubber band ligation.Mucosa located 1 to 2 cm proximal to the dentate line is grasped and pulled into a rubber band applier. After firing the ligator, the rubber band strangulates the underlying tissue, causing scarring and preventing further bleeding or prolapse (Fig. 29-31). In general, only one or two quadrants are banded per visit. Severe pain will occur if the rubber band is placed at or distal to the dentate line where sensory nerves are located. Other complications of rubber band ligation include urinary retention, infection, and bleeding. Urinary retention occurs in approximately 1% of patients and is more likely if the ligation has inadvertently included a portion of the internal sphincter. Necrotizing infection is an uncommon, but life-threatening complication. Severe pain, fever, and urinary retention are early signs of infection and should prompt immediate evaluation of the patient usually with an exam under anesthesia. Treatment includes debridement of necrotic tissue, drainage of associated abscesses, and broad-spectrum antibiotics. Bleeding may occur approximately 7 to 10 days after rubber band ligation, at the time when the ligated pedicle necroses and sloughs. Bleeding is usually self-limited, but persistent hemorrhage may require exam under anesthesia and suture ligation of the pedicle.Infrared Photocoagulation Infrared photocoagulation is an effective office treatment for small firstand second-degree hemorrhoids. The instrument is applied to the apex of each hem-orrhoid to coagulate the underlying plexus. All three quadrants may be treated during the same visit. Larger hemorrhoids and hemorrhoids with a significant amount of prolapse are not effec-tively treated with this technique.Sclerotherapy The injection of bleeding internal hemorrhoids with sclerosing agents is another effective office technique for treatment of first-, second-, and some third-degree hemorrhoids. One to 3 mL of a sclerosing solution (phenol in olive oil, sodium morrhuate, or quinine urea) is injected into the submucosa of each hemorrhoid. Few complications are associated with sclero-therapy, but infection and fibrosis have been reported.Excision of Thrombosed External Hemorrhoids Acutely thrombosed external hemorrhoids generally cause intense pain and a palpable perianal mass during the first 24 to 72 hours after thrombosis. The thrombosis can be effectively treated with an elliptical excision performed in the office under local anesthe-sia. Because the clot is usually loculated, simple incision and drainage is rarely effective. After 72 hours, the clot begins to resorb, and the pain resolves spontaneously. Excision is unnec-essary, but sitz baths and analgesics are often helpful.Operative Hemorrhoidectomy A number of surgical proce-dures have been described for elective resection of symptomatic hemorrhoids. All are based on decreasing blood flow to the hem-orrhoidal plexuses and excising redundant anoderm and mucosa.9Brunicardi_Ch29_p1259-p1330.indd 131023/02/19 2:29 PM 1311COLON, RECTUM, AND ANUSCHAPTER 29Closed Submucosal Hemorrhoidectomy The Parks or Fer-guson hemorrhoidectomy involves resection of hemorrhoidal tissue and closure of the wounds with absorbable suture. The procedure may be performed in the prone or lithotomy position under local, regional, or general anesthesia. The anal canal is examined and an anal speculum inserted. The hemorrhoid cush-ions and associated redundant mucosa are identified and excised using an elliptical incision starting just distal to the anal verge and extending proximally to the anorectal ring. It is crucial to identify the fibers of the internal sphincter and carefully brush these away from the dissection in order to avoid injury to the sphincter. The apex of the hemorrhoidal plexus is then ligated and the hemorrhoid excised. The wound is then closed with a running absorbable suture. All three hemorrhoidal cushions may be removed using this technique; however, care should be taken to avoid resecting a large area of perianal skin in order to avoid postoperative anal stenosis (Fig. 29-32).Open Hemorrhoidectomy This technique, often called the Milligan and Morgan hemorrhoidectomy, follows the same principles of excision described earlier, but the wounds are left open and allowed to heal by secondary intention.Whitehead’s Hemorrhoidectomy Whitehead’s hemorrhoid-ectomy involves circumferential excision of the hemorrhoidal cushions just proximal to the dentate line. After excision, the rectal mucosa is then advanced and sutured to the dentate line. While some surgeons still use Whitehead’s hemorrhoidectomy, most have abandoned this approach because of the risk of ectro-pion (Whitehead’s deformity).Procedure for Prolapse and Hemorrhoids/Stapled Hemor-rhoidectomy Procedure for prolapse and hemorrhoids (PPH) is also referred to as a stapled hemorrhoidopexy. Best suited for patients with secondand third-degree hemorrhoids, this out-patient procedure uses a stapling device similar in appearance and mechanism of action to an end-to-end anastomotic (EEA) stapling device used for rectal surgery. Just as with an EEA sta-pler, proximal and distal tissue donuts, in this case consisting of mucosa and submucosa, are generated by the PPH stapler though the primary means by which this procedure provides relief for internal hemorrhoids is by pexying the redundant hemorrhoidal tissue, ligating the venules feeding the hemorrhoidal plexus and fixing redundant mucosa proximal to the dentate line. Several studies suggest that this procedure is safe and effective, that it is associated with less postoperative pain and disability, and that it has an equivalent risk of postoperative complications when compared to excisional hemorrhoidectomy. Complications associated with this procedure include chronic anal pain, bac-teremia, rectovaginal fistula, formation of an obstructing rectal stricture and even rectal perforation. In at least one systematic review comparing outcomes between PPH and excisional hem-orrhoidectomy, overall incidence of complications was similar, ElasticbandsElasticbandsElasticbandsFigure 29-31. Rubber band ligation of internal hemorrhoids. The mucosa just proximal to the internal hemorrhoids is banded.Brunicardi_Ch29_p1259-p1330.indd 131123/02/19 2:29 PM 1312SPECIFIC CONSIDERATIONSPART IIthough the incidence of recurrent hemorrhoids was lower fol-lowing excisional hemorrhoidectomy.159,160Doppler-Guided Hemorrhoidal Artery Ligation Another recent approach to treating symptomatic hemorrhoids is Doppler-guided hemorrhoidal artery ligation (also called trans-anal hemorrhoidal dearterialization). In this procedure, a Dop-pler probe is used to identify the artery or arteries feeding the hemorrhoidal plexus. These vessels are then ligated. Early reports have shown promise, but long-term durability remains to be determined.161Complications of Hemorrhoidectomy. Postoperative pain following excisional hemorrhoidectomy requires analgesia usually with oral narcotics. Nonsteroidal anti-inflammatory drugs, muscle relaxants, topical analgesics, and comfort mea-sures, including sitz baths, are often useful as well. Urinary retention is a common complication following hemorrhoidec-tomy and has been reported to be as high as 10% to 50% in some series. The risk of urinary retention can be minimized by limiting intraoperative and perioperative intravenous flu-ids and by providing adequate analgesia. Pain can also lead to fecal impaction. Risk of impaction may be decreased by pre-operative enemas or a limited mechanical bowel preparation, liberal use of laxatives postoperatively, and adequate pain con-trol. While a small amount of bleeding, especially with bowel movements, is to be expected, massive hemorrhage can occur after hemorrhoidectomy. Bleeding may occur in the immediate postoperative period (often in the recovery room) as a result of inadequate ligation of the vascular pedicle. This type of hemorrhage mandates an urgent return to the operating room where suture ligation of the bleeding vessel will often solve the problem. Bleeding may also occur 7 to 10 days after hemor-rhoidectomy when the necrotic mucosa overlying the vascular pedicle sloughs. While some of these patients may be safely observed, others will require an exam under anesthesia to ligate the bleeding vessel or to oversew the wounds if no specific site of bleeding is identified. Infection is uncommon after hemor-rhoidectomy; however, necrotizing soft tissue infection can occur with devastating consequences. Severe pain, fever, and urinary retention may be early signs of infection. If infection is suspected, emergent examination under anesthesia, drainage of abscess, and/or debridement of all necrotic tissue are required.Long-term sequelae of hemorrhoidectomy include incon-tinence, anal stenosis, and ectropion (Whitehead’s deformity). Many patients experience transient incontinence to flatus, but these symptoms are usually short-lived, and few patients have ABCDEFFigure 29-32. Technique of closed submucosal hemorrhoidectomy. A. The patient is in prone jackknife position. B. A Fansler anoscope is used for exposure. C. A narrow ellipse of anoderm is excised. D. A submucosal dissection of the hemorrhoidal plexus from the underlying anal sphincter is performed. E. Redundant mucosa is anchored to the proximal anal canal, and the wound is closed with a running absorbable suture. F. Additional quadrants are excised to complete the procedure.Brunicardi_Ch29_p1259-p1330.indd 131223/02/19 2:29 PM 1313COLON, RECTUM, AND ANUSCHAPTER 29permanent fecal incontinence. Anal stenosis may result from scarring after extensive resection of perianal skin. Ectropion may occur after Whitehead’s hemorrhoidectomy.Anal FissureA fissure in ano is a tear in the anoderm distal to the dentate line. The pathophysiology of anal fissure is thought to be related to trauma from either the passage of hard stool or prolonged diarrhea. A tear in the anoderm causes spasm of the internal anal sphincter, which results in pain, increased tearing, and decreased blood supply to the anoderm. This cycle of pain, spasm, and ischemia contributes to development of a poorly healing wound that becomes a chronic fissure. The vast major-ity of anal fissures occur in the posterior midline. Ten percent to 15% occur in the anterior midline. Less than 1% of fissures occur off midline.Symptoms and Findings. Anal fissure is extremely common. Characteristic symptoms include tearing pain with defecation and hematochezia (usually described as blood on the toilet paper). Patients may also complain of a sensation of intense and painful anal spasm lasting for several hours after a bowel move-ment. On physical examination, the fissure can often be seen in the anoderm by gently separating the buttocks. Patients are often too tender to tolerate digital rectal examination, anoscopy, or proctoscopy. An acute fissure is a superficial tear of the distal anoderm and almost always heals with medical management. Chronic fissures develop ulceration and heaped-up edges with the white fibers of the internal anal sphincter visible at the base of the ulcer. There often is an associated external skin tag and/or a hypertrophied anal papilla internally. These fissures are more challenging to treat and may require surgery. A lateral loca-tion of a chronic anal fissure may be evidence of an underlying disease such as Crohn’s disease, HIV, syphilis, tuberculosis, or leukemia. If the diagnosis is in doubt or there is suspicion of another cause for the perianal pain such as abscess or fistula, an examination under anesthesia may be necessary.Treatment. Therapy focuses on breaking the cycle of pain, spasm, and ischemia thought to be responsible for development of fissure in ano. First-line therapy to minimize anal trauma includes bulk agents, stool softeners, and warm sitz baths. The addition of 2% lidocaine jelly or other analgesic creams can provide additional symptomatic relief. Nitroglycerin ointment has been used locally to improve blood flow but often causes severe headaches. Both oral and topical calcium channel block-ers (diltiazem and nifedipine) have also been used to heal fis-sures and may have fewer side effects than topical nitrates.162 Newer agents, such as arginine (a nitric oxide donor) and topical bethanechol (a muscarinic agonist), have also been used to treat fissures. Medical therapy is effective in most acute fissures, but it will heal only approximately 50% of chronic fissures.162Botulinum toxin (Botox) causes temporary muscle paraly-sis by preventing acetylcholine release from presynaptic nerve terminals. Injection of botulinum toxin is used in some centers as an alternative to surgical sphincterotomy for chronic fissure. Although there are few long-term complications from the use of botulinum toxin, healing appears to be equivalent to other medical therapies.163,164Surgical therapy has traditionally been recommended for chronic fissures that have failed medical therapy, and lateral internal sphincterotomy is the procedure of choice. The aim of this procedure is to decrease spasm of the internal sphincter by dividing a portion of the muscle. Approximately 30% of the internal sphincter fibers are divided laterally by using either an open (Fig. 29-33) or closed (Fig. 29-34) technique. Healing is achieved in more than 95% of patients using this technique, and most patients experience immediate pain relief. Recurrence occurs in less than 10% of patients, and the risk of incontinence (usually to flatus) ranges from 5% to 15%. Advancement flaps (VY) with or without sphincterotomy have also been reported to successfully treat chronic fissures.Anorectal Sepsis and Cryptoglandular AbscessRelevant Anatomy. The majority of anorectal suppurative disease results from infections of the anal glands (cryptoglan-dular infection) found in the intersphincteric plane. Their ducts traverse the internal sphincter and empty into the anal crypts at the level of the dentate line. Infection of an anal gland results in the formation of an abscess that enlarges and spreads along one of several planes in the perianal and perirectal spaces. The perianal space surrounds the anus and laterally becomes con-tinuous with the fat of the buttocks. The intersphincteric space separates the internal and external anal sphincters. It is continu-ous with the perianal space distally and extends cephalad into the rectal wall. The ischiorectal space (ischiorectal fossa) is located lateral and posterior to the anus and is bounded medially by the external sphincter, laterally by the ischium, superiorly by the levator ani, and inferiorly by the transverse septum. The ischiorectal space contains the inferior rectal vessels and lym-phatics. The two ischiorectal spaces connect posteriorly above the anococcygeal ligament but below the levator ani muscle, forming the deep postanal space. The supralevator spaces lie above the levator ani on either side of the rectum and commu-nicate posteriorly. The anatomy of these spaces influences the location and spread of cryptoglandular infection (Fig. 29-35).As an abscess enlarges, it spreads in one of several direc-tions. A perianal abscess is the most common manifestation and appears as a painful swelling at the anal verge. Spread through the external sphincter below the level of the puborectalis pro-duces an ischiorectal abscess. These abscesses may become extremely large and may not be visible in the perianal region. ClosureInternal sphincterincisedExternalsphincter m.Internalsphincter m.FissureFissure-in-anoADCBFigure 29-33. A through D. Open lateral internal sphincterotomy for fissure in ano. m = muscle.Brunicardi_Ch29_p1259-p1330.indd 131323/02/19 2:29 PM 1314SPECIFIC CONSIDERATIONSPART IIDigital rectal exam will reveal a painful swelling laterally in the ischiorectal fossa. Intersphincteric abscesses occur in the inter-sphincteric space and are notoriously difficult to diagnose, often requiring an examination under anesthesia. Pelvic and supralevator abscesses are uncommon and may result from extension of an intersphincteric or ischiorectal abscess upward or extension of an intraperitoneal abscess downward (Fig. 29-36).Diagnosis. Severe anal pain is the most common presenting complaint. A palpable mass is often detected by inspection of the perianal area or by digital rectal examination. Occasion-ally, patients will present with fever, urinary retention, or lifethreatening sepsis. The diagnosis of a perianal or ischiorectal abscess can usually be made with physical exam alone (either in the office or in the operating room). However, complex or atypical presentations may require imaging studies such as CT or MRI to fully delineate the anatomy of the abscess.Treatment. Anorectal abscesses should be treated by drain-age as soon as the diagnosis is established. If the diagnosis is in question, an examination and drainage under anesthesia are often the most expeditious ways both to confirm the diagnosis and to treat the problem. Delayed or inadequate treatment may occasionally cause extensive and life-threatening suppuration with massive tissue necrosis and septicemia. Antibiotics are only indicated if there is extensive overlying cellulitis or if the patient is immunocompromised, has diabetes mellitus, or has valvular heart disease. Antibiotics alone are ineffective at treat-ing perianal or perirectal infection.Perianal AbscessMost perianal abscesses can be drained under local anesthesia in the office, clinic, or emergency department. Larger, more com-plicated abscesses may require drainage in the operating room. A skin incision is created, and a disk of skin excised to prevent premature closure. No packing is necessary, and sitz baths are started the next day (Fig. 29-37).Ischiorectal AbscessAn ischiorectal abscess causes diffuse swelling in the ischiorectal fossa that may involve one or both sides, forming a “horseshoe” abscess. Simple ischiorectal abscesses are drained through an incision in the overlying skin. Horseshoe abscesses require drainage of the deep postanal space and often require counterin-cisions over one or both ischiorectal spaces (Fig. 29-38).Intersphincteric AbscessIntersphincteric abscesses are notoriously difficult to diagnose because they produce little swelling and few perianal signs of infection. Pain is typically described as being deep and “up inside” the anal area and is usually exacerbated by coughing or sneezing. The pain is so intense that it usually precludes a digital rectal examination. The diagnosis is made based on a high index of suspicion and usually requires an examination Anal fissureSentinel pileADCBFigure 29-34. A through D. Closed lateral internal sphincterotomy for fissure in ano.Brunicardi_Ch29_p1259-p1330.indd 131423/02/19 2:29 PM 1315COLON, RECTUM, AND ANUSCHAPTER 29Levator ani m.Internal sphincter m.Puborectalis anddeep external sphincter m.Superficial externalsphincter m.Subcutaneousexternal sphincter m.PeritoneumUreterSupralevator spaceIschiorectal spacePerianal spacePeritoneumRectorectal spaceRectosacral fasciaSupralevator spaceLevator ani m.Deep postanal spaceSuperficialpostanal spaceABFigure 29-35. Anatomy of perianorectal spaces. (A) Anterior view and (B) lateral view. m = muscle.Internalsphincter m.Perianal spaceabscessLevatorani m.Externalsphincter m.Longitudinal m.Pelvirectal spaceabscessIntersphincteric spaceabscessIschiorectal fossaabscessABFigure 29-36. A and B. Pathways of anorectal infection in perianal spaces. m = muscle.Brunicardi_Ch29_p1259-p1330.indd 131523/02/19 2:29 PM 1316SPECIFIC CONSIDERATIONSPART IIunder anesthesia. Once identified, an intersphincteric abscess can be drained through a limited, usually posterior, internal sphincterotomy.Supralevator AbscessThis type of abscess is uncommon and can be difficult to diag-nose. Because of its proximity to the peritoneal cavity, supral-evator abscesses can mimic intra-abdominal conditions. Digital rectal examination may reveal an indurated, bulging mass above the anorectal ring. It is essential to identify the origin of a supralevator abscess prior to treatment. If the abscess is sec-ondary to an upward extension of an intersphincteric abscess, it should be drained through the rectum. If it is drained through the ischiorectal fossa, a complicated, suprasphincteric fistula may result. If a supralevator abscess arises from the upward extension of an ischiorectal abscess, it should be drained through the ischiorectal fossa. Drainage of this type of abscess through the rectum may result in an extrasphincteric fistula. If the abscess is secondary to intra-abdominal disease, the pri-mary process requires treatment and the abscess is drained via the most direct route (transabdominally, rectally, or through the ischiorectal fossa).Perianal Sepsis in the Immunocompromised PatientThe immunocompromised patient with perianal pain presents a diagnostic dilemma. Because of leukopenia, these patients may develop serious perianal infection without any of the cardinal signs of inflammation. While broad-spectrum antibiotics may cure some of these patients, an exam under anesthesia should not be delayed because of neutropenia. An increase in pain or fever and/or clinical deterioration mandates an exam under anesthesia. Any indurated area should be incised and drained, biopsied to exclude a leukemic infiltrate, and cultured to aid in the selection of antimicrobial agents.165Necrotizing Soft Tissue Infection of the PerineumNecrotizing soft tissue infection of the perineum is a rare, but lethal, condition. Most of these infections are polymicrobial and synergistic. The source of sepsis is commonly an undrained or inadequately drained cryptoglandular abscess or a urogenital infection. Occasionally, these infections may be encountered postoperatively (e.g., after hemorrhoidectomy). Immunocom-promised patients and diabetic patients are at increased risk.Physical examination may reveal necrotic skin, bullae, or crepitus. Patients often have signs of systemic toxicity and may be hemodynamically unstable. A high index of suspicion is necessary because perineal signs of severe infection may be minimal and prompt surgical intervention can be lifesaving.Surgical debridement of all nonviable tissue is required to treat all necrotizing soft tissue infections. Multiple operations may be necessary to ensure that all necrotic tissue has been resected. Broad-spectrum antibiotics are frequently employed, but adequate surgical debridement remains the mainstay of ther-apy. Colostomy may be required if extensive resection of the sphincter is required or if stool contamination of the perineum makes wound management difficult. Despite early recognition and adequate surgical therapy, the mortality of necrotizing peri-neal soft tissue infections remains approximately 50%.ABCFigure 29-37. A through C. Technique of drainage of perianal abscess.Figure 29-38. Drainage of horseshoe abscess. The deep postanal space is entered, incising the anococcygeal ligament. Counter drain-age incisions are made for each limb of the ischiorectal space.Brunicardi_Ch29_p1259-p1330.indd 131623/02/19 2:30 PM 1317COLON, RECTUM, AND ANUSCHAPTER 29surgical treatment is dictated by the location of the internal and external openings and the course of the fistula. The exter-nal opening is usually visible as a red elevation of granu-lation tissue with or without concurrent drainage. The internal opening may be more difficult to identify. Injection of hydrogen peroxide or dilute methylene blue may be helpful. Care must be taken to avoid creating an artificial internal opening (thus often converting a simple fistula into a complex fistula).Simple intersphincteric fistulas can often be treated by fistulotomy (opening the fistulous tract), curettage, and healing by secondary intention (see Fig. 29-40A). “Horseshoe” fistulas usu-ally have an internal opening in the posterior midline and extend anteriorly and laterally to one or both ischiorectal spaces by way of the deep postanal space. Treatment of a transsphincteric fistula depends on its location in the sphincter complex. Fistulas that include less than 30% of the sphincter muscles can often be treated by sphincterotomy without significant risk of major incontinence (see Fig. 29-40B). High transsphincteric fistulas, which encircle a greater amount of muscle, are more safely treated by initial place-ment of a seton. Similarly, suprasphincteric fistulas are usually treated with seton placement (see Fig. 29-40C). Extrasphincteric fistulas are rare, and treatment depends on both the anatomy of the fistula and its etiology. In general, the portion of the fistula outside the sphincter should be opened and drained. A primary tract at the level of the dentate line may also be opened if pres-ent. Complex fistulas with multiple tracts may require numerous procedures to control sepsis and facilitate healing. Liberal use of drains and setons is helpful. Failure to heal may ultimately require fecal diversion (see Fig. 29-40D). Complex and/or non-healing fistulas may result from Crohn’s disease, malignancy, radiation proctitis, or unusual infection. Proctoscopy should be performed in all cases of complex and/or nonhealing fistulas to assess the health of the rectal mucosa. Biopsies of the fistula tract should be taken to rule out malignancy.A seton is a drain placed through a fistula to maintain drain-age and/or induce fibrosis. Cutting setons consist of a suture or a rubber band that is placed through the fistula and intermittently tightened in the office. Tightening the seton results in fibrosis and gradual division of the sphincter, thus eliminating the fis-tula while maintaining continuity of the sphincter. A noncutting seton is a soft plastic drain (often a vessel loop) placed in the fistula to maintain drainage. The fistula tract may subsequently be laid open with less risk of incontinence because scarring pre-vents retraction of the sphincter. Alternatively, the seton may be left in place for chronic drainage. Higher fistulas may be treated by an endorectal advancement flap. Fibrin glue and a variety of collagen-based plugs also have been used to treat persistent fistulas with variable results. A more recent technique, ligation of the intersphincteric fistula tract (LIFT), also shows promise. In this procedure, the fistula is identified in the intersphincteric plane (usually by placement of a lacrimal probe), divided, and the two ends ligated. Early reports have shown success with this technique, but long-term outcome is not yet known.166-168Rectovaginal FistulaA rectovaginal fistula is a connection between the vagina and the rectum or anal canal proximal to the dentate line. Recto-vaginal fistulas are classified as low (rectal opening close to the dentate line and vaginal opening in the fourchette), middle (vaginal opening between the fourchette and cervix), or high (vaginal opening near the cervix). Low rectovaginal fistulas are 10Posterior(curved tracts)Transverse Anal LineAnterior(straight tracts)3 cmExceptionFigure 29-39. Goodsall’s rule to identify the internal opening of fistulas in ano.Fistula In AnoDrainage of an anorectal abscess results in cure for about 50% of patients. The remaining 50% develop a persistent fistula in ano. The fistula usually originates in the infected crypt (internal opening) and tracks to the external opening, usually the site of prior drainage. The course of the fistula can often be predicted by the anatomy of the previous abscess.While the majority of fistulas are cryptoglandular in ori-gin, trauma, Crohn’s disease, malignancy, radiation, or unusual infections (tuberculosis, actinomycosis, and chlamydia) may also produce fistulas. A complex, recurrent, or nonhealing fis-tula should raise the suspicion of one of these diagnoses.Diagnosis. Patients present with persistent drainage from the internal and/or external openings. An indurated tract is often palpable. Although the external opening is often easily identifi-able, identification of the internal opening may be more chal-lenging. Goodsall’s rule can be used as a guide in determining the location of the internal opening (Fig. 29-39). In general, fis-tulas with an external opening anteriorly connect to the internal opening by a short, radial tract. Fistulas with an external open-ing posteriorly track in a curvilinear fashion to the posterior midline. However, exceptions to this rule often occur if an ante-rior external opening is greater than 3 cm from the anal margin. Such fistulas usually track to the posterior midline.Fistulas are categorized based on their relationship to the anal sphincter complex, and treatment options are based on these classifications. An intersphincteric fistula tracks through the distal internal sphincter and intersphincteric space to an external opening near the anal verge (Fig. 29-40A). A trans-sphincteric fistula often results from an ischiorectal abscess and extends through both the internal and external sphincters (Fig. 29-40B). A suprasphincteric fistula originates in the inter-sphincteric plane and tracks up and around the entire external sphincter (Fig. 29-40C). An extrasphincteric fistula originates in the rectal wall and tracks around both sphincters to exit later-ally, usually in the ischiorectal fossa (Fig. 29-40D).Treatment. The goal of treatment of fistula in ano is eradica-tion of sepsis without sacrificing continence. Because fistulous tracks encircle variable amounts of the sphincter complex, Brunicardi_Ch29_p1259-p1330.indd 131723/02/19 2:30 PM 1318SPECIFIC CONSIDERATIONSPART IIcommonly caused by obstetric injuries or trauma from a foreign body. Mid-rectovaginal fistulas may result from more severe obstetric injury, but they also occur after surgical resection of a mid-rectal neoplasm, radiation injury, or extension of an und-rained abscess. High rectovaginal fistulas result from operative or radiation injury. Complicated diverticulitis may cause a colo-vaginal fistula. Crohn’s disease can cause rectovaginal fistulas at all levels, as well as colovaginal and enterovaginal fistulas.Diagnosis. Patients describe symptoms varying from the sen-sation of passing flatus from the vagina to the passage of solid stool from the vagina. Most patients experience some degree of fecal incontinence. Contamination may result in vaginitis. Large fistulas may be obvious on anoscopic and/or vaginal speculum examination, but smaller fistulas may be difficult to locate. Occasionally, a barium enema or vaginogram may identify these fistulas. Endorectal ultrasound may also be useful. With the patient in the prone position, installation of methylene blue into the rectum while a tampon is in the vagina may confirm the presence of a small fistula.Treatment. The treatment of rectovaginal fistula depends on the size, location, etiology, and condition of surrounding tis-sues. Because up to 50% of fistulas caused by obstetric injury heal spontaneously, it is prudent to wait 3 to 6 months before embarking on surgical repair in these patients. If the fistula was caused by a cryptoglandular abscess, drainage of the abscess may allow spontaneous closure.Low and mid-rectovaginal fistulas are usually best treated with an endorectal advancement flap. The principle of this procedure is based on the advancement of healthy mucosa, submucosa, and circular muscle over the rectal opening (the high-pressure side of the fistula) to promote healing (Fig. 29-41). If a sphincter injury is present, an overlapping sphincteroplasty ABCDFigure 29-40. The four major categories of fistula in ano (left side of drawings) and the usual operative procedure to correct the fistula (right side of drawings). A. Intersphincteric fistula with simple low tract. B. Uncomplicated transsphincteric fistula. C. Uncomplicated suprasphinc-teric fistula. D. Extrasphincteric fistula secondary to anal fistula.Brunicardi_Ch29_p1259-p1330.indd 131823/02/19 2:30 PM 1319COLON, RECTUM, AND ANUSCHAPTER 29should be performed concurrently. Fecal diversion is rarely required. High rectovaginal, colovaginal, and enterovaginal fis-tulas are usually best treated via a transabdominal approach. The diseased tissue, which caused the fistula (upper rectum, sigmoid colon, or small bowel), is resected and the hole in the vagina closed. Healthy tissue, such as omentum or muscle, frequently is interposed between the bowel anastomosis and the vagina to prevent recurrence.Rectovaginal fistulas caused by Crohn’s disease, radia-tion injury, or malignancy almost never heal spontaneously. In Crohn’s disease, treatment is based on adequate drainage of perianal sepsis and nutritional support. An endorectal advance-ment flap may be performed if the rectum is spared from active Crohn’s disease. Fistulas resulting from radiation damage are not amenable to local repair with an advancement flap because of damage to the surrounding rectal and vaginal tissues. Such midand high rectovaginal fistulas are occasionally repaired successfully with a transabdominal approach in which healthy tissue (omentum, muscle, or nonradiated bowel) is interposed between the damaged rectum and vagina. Fistulas caused by malignancy should be treated with resection of the tumor. Because differentiating radiation damage from malignancy can be extremely difficult, all fistulas resulting from radiation should be biopsied to rule out the presence of cancer.Perianal DermatitisPruritus Ani. Pruritus ani (severe perianal itching) is a com-mon problem with a multitude of etiologies. Surgically cor-rectable (anatomic) causes include prolapsing hemorrhoids, ectropion, fissure, fistula, and neoplasms. Perianal infection may also present with pruritus ani. Infections may be caused by fungus (Candida species and Epidermophyton organisms), parasites (Enterobius vermicularis [pinworms], Pediculus pubis [a louse], and Sarcoptes scabiei [scabies]), bacteria Probe inrectovaginalfistulaRectal mucosa andinternal sphinctermuscle incisedAttenuatedrectovaginalseptumExcess flap ofmucosa excisedInternal sphinctermuscle mobilizedInternal sphinctermuscle approximatedFlap of mucosaand internalsphincter muscleFigure 29-41. Endorectal advancement flap for rectovaginal fistula. (Reproduced with permission from Gordon PH, Nivatvongs S: Principles and Practice of Surgery for the Colon, Rectum, and Anus, 2nd ed. New York, NY: Marcel Dekker, Inc; 1999.)Brunicardi_Ch29_p1259-p1330.indd 131923/02/19 2:30 PM 1320SPECIFIC CONSIDERATIONSPART II(Corynebacterium minutissimum [erythrasma] and T pallidum [syphilis]), or viruses (HPV [condyloma acuminata]). Antibi-otic use may also cause itching, usually by precipitating fungal infection. Noninfectious dermatologic causes include seborrhea, psoriasis, and contact dermatitis. Contact dermatitis can be par-ticularly troublesome because many over-the-counter topical agents used by patients to relieve itching may exacerbate the problem. Occasionally, systemic diseases such as jaundice and diabetes may present with pruritus ani.Despite the myriad of causes, the majority of pruritus ani is idiopathic and probably related to local hygiene, neurogenic, or psychogenic causes. Treatment focuses on removal of irritants, improving perianal hygiene, dietary adjustments, and avoiding scratching. Biopsy and/or culture may be required to rule out an infectious or dermatologic cause. Hydrocortisone ointment 0.5% to 1.0% can provide symptomatic relief but should not be used for prolonged periods of time because of the risk of dermal atrophy. Skin barriers such as Calmoseptine can also provide relief. Systemic antihistamines or tricyclic antidepressants have also been used with some success.Nonpruritic Lesions. Several perianal skin conditions may present with perianal skin changes. Leprosy, amebiasis, actino-mycosis, and lymphogranuloma venereum produce characteris-tic perianal lesions. Neoplasms such as squamous intraepithelial lesions, Paget’s disease, and invasive carcinomas may also appear first in the perianal skin. Biopsy can usually distinguish these diagnoses.Sexually Transmitted DiseasesBacterial Infections. Proctitis is a common symptom of ano-rectal bacterial infection. Neisseria gonorrhoeae is the most common bacterial cause of proctitis and causes pain, tenes-mus, rectal bleeding, and mucus discharge. Chlamydia tracho-matis infection may be asymptomatic or may produce similar symptoms. Treponema pallidum, the microbe causing syphilis, causes a chancre at the site of inoculation, which may be asymp-tomatic or may present as an atypical fissure (primary syphilis). Condyloma lata are characteristic of secondary syphilis. Chan-croid, caused by Haemophilus ducreyi, is a disease manifested by multiple painful, bleeding lesions. Inguinal lymphadenopathy and fluctuant, draining lymph nodes are characteristic. Donova-nia granulomatis infection produces shiny, red masses on the perineum (granuloma inguinale). Diarrheal illnesses caused by organisms such as Campylobacter or Shigella may also be sexually transmitted. Treatment consists of antimicrobial agents directed against the infecting organism.Parasitic Infections. Entamoeba histolytica is an increas-ingly common sexually transmitted disease. Amebas produce ulcerations in the gastrointestinal mucosa and can infect any part of the gut. Symptoms include diarrhea, abdominal pain, and tenesmus. Giardia lamblia is also common and produces diarrhea, abdominal pain, and malaise.Viral Infections Herpes Simplex Virus Herpes proctitis is extremely common. Proctitis is usually caused by type 2 herpes simplex virus and less commonly by type 1 herpes simplex virus. Patients complain of severe, intractable perianal pain and tenesmus. Pain often precedes the development of characteristic vesicles, and these patients may require an examination under anesthesia to exclude another diagnosis such as an intersphincteric abscess. Diagnosis is confirmed by viral culture of tissue or vesicular fluid.Human Papillomavirus HPV causes condyloma acuminata (anogenital warts) and is associated with squamous intraepithe-lial lesions and squamous cell carcinoma (see previous section, “Anal Canal and Perianal Tumors”). Condylomas occur in the perianal area or in the squamous epithelium of the anal canal. Occasionally, the mucosa of the lower rectum may be affected. There are approximately 30 serotypes of HPV. As previously mentioned, HPV types 16 and 18, in particular, appear to pre-dispose to malignancy and often cause flat dysplasia in skin unaffected by warts. In contrast, HPV types 6 and 11 commonly cause warts, but do not appear to cause malignant degeneration.Treatment of anal condyloma depends on the location and extent of disease. Small warts on the perianal skin and distal anal canal may be treated in the office with topical application of bichloracetic acid or podophyllin. Although 60% to 80% of patients will respond to these agents, recurrence and reinfection are common. Imiquimod (Aldara) is an immunomodulator that was recently introduced for topical treatment of several viral infections, including anogenital condyloma.100 Initial reports suggest that this agent is highly effective in treating condyloma located on the perianal skin and distal anal canal. Larger and/or more numerous warts require excision and/or fulguration in the operating room. Excised warts should be sent for pathologic examination to rule out dysplasia or malignancy. It is impor-tant to note that prior use of podophyllin may induce histologic changes that mimic dysplasia. The recent introduction of a vaccine against HPV holds promise for preventing anogenital condylomas.169,170Human Immunodeficiency Virus See later section, “The Immunocompromised Patient.”Pilonidal DiseasePilonidal disease (cyst, infection) consists of a hair-containing sinus or abscess occurring in the intergluteal cleft. Although the etiology is unknown, it is speculated that the cleft creates a suction that draws hair into the midline pits when a patient sits. These ingrown hairs may then become infected and pres-ent acutely as an abscess in the sacrococcygeal region. Once an acute episode has resolved, recurrence is common.An acute abscess should be incised and drained as soon as the diagnosis is made. Because these abscesses are usually very superficial, this procedure can often be performed in the office, clinic, or emergency department under local anesthetic. Because midline wounds in the region heal poorly, some sur-geons recommend using an incision lateral to the intergluteal cleft. A number of procedures have been proposed to treat a chronic pilonidal sinus. The simplest method involves unroof-ing the tract, curetting the base, and marsupializing the wound. The wound must then be kept clean and free of hair until heal-ing is complete (often requiring weekly office visits for wound care). Alternatively, a small lateral incision can be created and the pit excised. This method is effective for most primary pilo-nidal sinuses. In general, extensive resection should be avoided. Complex and/or recurrent sinus tracts may require more exten-sive resection and closure with a Z-plasty, advancement flap, or rotational flap.Hidradenitis SuppurativaHidradenitis suppurativa is an infection of the cutaneous apo-crine sweat glands. Infected glands rupture and form subcutane-ous sinus tracts. The infection may mimic complex anal fistula disease, but stops at the anal verge because there are no apocrine Brunicardi_Ch29_p1259-p1330.indd 132023/02/19 2:30 PM 1321COLON, RECTUM, AND ANUSCHAPTER 29glands in the anal canal. Treatment involves incision and drain-age of acute abscesses and unroofing of all chronically inflamed fistulas and debridement of granulation tissue. Radical excision and skin grafting are almost never necessary.TRAUMAPenetrating Colorectal InjuryColorectal injury is common following penetrating trauma to the abdomen and has historically been associated with high mortality. In the first half of the 20th century, the mortality rate from colorectal injury was as high as 90%. The introduction of exteriorization of colonic injuries and fecal diversion during World War II dramatically decreased mortality, and this princi-ple has governed the management of large bowel injury for over 50 years. Recently, however, this practice was challenged, and trauma surgeons are increasingly performing primary repairs in selected patients.Management of colonic injury depends on the mechanism of injury, the delay between the injury and surgery, the over-all condition and stability of the patient, the degree of perito-neal contamination, and the condition of the injured colon. A primary repair may be considered in hemodynamically stable patients with few additional injuries and minimal contamination if the colon appears otherwise healthy. Contraindications to pri-mary repair include shock, injury to more than two other organs, mesenteric vascular damage, and extensive fecal contamina-tion. A delay of greater than 6 hours between the injury and the operation also is associated with increased morbidity and mor-tality and is a relative contraindication to primary repair. Inju-ries caused by high-velocity gunshot wounds or blast injuries are often associated with multiple intra-abdominal injuries and tissue loss and therefore are usually treated by fecal diversion after debridement of all nonviable tissue. Patient factors, such as medical comorbidities, advanced age, and the presence of tumor or radiation injury, must also be considered (Table 29-4).Like injuries to the intraperitoneal colon, penetrating trauma to the rectum traditionally has been associated with high morbidity and mortality. Primary repair of the rectum is more difficult than primary repair of the colon, however, and most rectal injuries are associated with significant contamination. For that reason, the majority of penetrating rectal injuries should be treated with proximal fecal diversion. Distal washout (copious irrigation of the rectum) and presacral drains are not routinely recommended.158 Small, clean rectal injuries may be closed pri-marily without fecal diversion in an otherwise stable patient. Intractable rectal bleeding may require angiographic emboliza-tion. Very rarely, hemorrhage or extensive tissue loss (espe-cially if the anal sphincter is severely damaged) may require an emergent APR. However, this operation should be avoided, if at all possible, because of the morbidity associated with an extensive pelvic dissection in a severely injured patient.171Blunt Colorectal InjuryBlunt injury to the colon and rectum is considerably less com-mon than penetrating injury. Nevertheless, blunt trauma can cause colon perforation, and shear injury to the mesentery can devascularize the intestine. Management of these injuries should follow the same principles outlined for management of penetrat-ing injuries. Small perforations with little contamination in a stable patient may be closed primarily; more extensive injury requires fecal diversion. A serosal hematoma alone does not Table 29-4Criteria for use of an ostomyInjuring agent factors High-velocity bullet wounds Shotgun wounds Explosive blast wounds Crush injuryPatient factors Presence of tumor Radiated tissue Medical condition Advanced ageInjury factors Inflamed tissue Advanced infection Distal obstruction Local foreign body Impaired blood supply Mesenteric vascular damage Shock with blood pressure <80/60 mmHg Hemorrhage >1000 mL More than two organs (especially kidney) injured Interval to operation >6 h (pancreatic, splenic, hepatic) Extensive injury requiring resection Major abdominal wall loss Thoracoabdominal penetrationReproduced with permission from Gordon PH, Nivatvongs S: Principles and Practice of Surgery for the Colon, Rectum, and Anus, 2nd ed. New York, NY: Marcel Dekker, Inc; 1999.mandate resection, but the bowel should be carefully inspected to ensure that there is not an associated perforation or significant bowel ischemia.Blunt injury to the rectum may result from significant trauma, such as a pelvic crush injury, or may result from local trauma caused by an enema or foreign body. Crush injuries, especially with an associated pelvic fracture, are often associ-ated with significant rectal damage and contamination. These patients require debridement of all nonviable tissue, proximal fecal diversion, and a distal rectal washout, with or without drain placement. Blunt trauma from an enema or foreign body may produce a mucosal hematoma, which requires no surgical treatment if the mucosa is intact. Small mucosal tears may be closed primarily if the bowel is relatively clean and there is little contamination.Iatrogenic InjuryIntraoperative Injury. The colon and rectum are at risk for inadvertent injury during other procedures, especially during pelvic operations. The key to managing these injuries is early recognition. The vast majority of iatrogenic colorectal injuries may be closed primarily if there is little contamination and if the patient is otherwise stable. Delayed recognition of colorectal injuries may result in significant peritonitis and life-threatening sepsis. In these cases, fecal diversion is almost always required, and the patient may need repeated exploration for drainage of abscesses.Injury From Barium Enema. Colorectal injury from a bar-ium enema is an extremely rare complication associated with a high rate of morbidity and mortality. Perforation with spillage Brunicardi_Ch29_p1259-p1330.indd 132123/02/19 2:30 PM 1322SPECIFIC CONSIDERATIONSPART IIof barium, especially above the peritoneal reflection, may result in profound peritonitis, sepsis, and a systemic inflam-matory response. If the perforation is recognized early, it may be closed primarily and the abdomen irrigated to remove stool and barium. However, if the patient has developed sepsis, fecal diversion (with or without bowel resection) is almost always required. Rarely, a small mucosal injury to the extraperitoneal rectum may be managed with bowel rest, broad-spectrum anti-biotics, and close observation.Colonoscopic Perforation. Perforation is the most common major complication after either diagnostic or therapeutic colo-noscopy. Fortunately, this complication is rare and occurs in less than 1% of procedures. Perforation may result from trauma from the tip of the instrument, from shear forces related to the formation of a “loop” in the colonoscope, or from barotrauma from insufflation. Biopsy or fulguration can also cause perfo-ration. Polypectomy using electrocautery may produce a full-thickness burn, resulting in postpolypectomy syndrome in which a patient develops abdominal pain, fever, and leukocytosis with-out evidence of diffuse peritonitis.Management of colonoscopic perforation depends on the size of the perforation, the duration of time since the injury, the overall condition of the patient, and the underlying diagnosis. A large perforation recognized during the procedure requires surgical exploration. Because the bowel has almost always been prepared prior to the colonoscopy, there is usually little contamination associated with these injuries, and most can be repaired primarily. If there is significant contamination, if there has been a delay in diagnosis with resulting peritonitis, or if the patient is hemodynamically unstable, proximal diversion with or without resection is the safest approach. It is also important to know the indication for and findings at the time of colonos-copy. If the patient has an underlying neoplasm and is stable, definitive resection is best. Occasionally, a patient will develop abdominal pain and localized signs of perforation after what was thought to be an uneventful colonoscopy. Many of these patients will have a “microperforation,” which will resolve with bowel rest, broad-spectrum antibiotics, and close observation. Evidence of peritonitis or any deterioration in clinical condition mandates exploration. Similarly, free retroperitoneal or intra-peritoneal air may be discovered incidentally after colonoscopy. In a completely asymptomatic patient, this finding is thought to result from barotrauma and dissection of air through tissue planes without a free perforation. Many of these patients can be successfully treated with bowel rest and broad-spectrum antibi-otics. Surgical exploration is indicated if any clinical deteriora-tion occurs.Anal Sphincter Injury and IncontinenceThe most common cause of anal sphincter injury is obstetric trauma during vaginal delivery. The risk of sphincter injury is increased by a laceration that extends into the rectum (fourth-degree tear), infection of an episiotomy or laceration repair, prolonged labor, and possibly by use of a midline episiotomy. Sphincter damage may also result from hemorrhoidectomy, sphincterotomy, abscess drainage, or fistulotomy. Patients with incontinence and a suspected sphincter injury can be evaluated with anal manometry, EMG, pudendal nerve motor latency, and endoanal ultrasound. Mild incontinence, even in the presence of a sphincter defect, may respond to dietary changes and/or biofeedback. More severe incontinence may require surgical repair.The anal sphincter can also be injured by penetrating or blunt mechanisms (impalement, blast injury, crush injuries of the pelvis). Because damage to the anal sphincter is not life-threatening, definitive repair of the sphincter is often deferred until other injuries have been repaired and the patient’s clinical condition is stable. Isolated sphincter injuries that do not involve the rectum may be repaired primarily. Rectal injury accompa-nied by sphincter injury should be treated with fecal diversion and distal rectal washout, with or without drain placement. Sig-nificant perineal tissue loss may require extensive debridement and a diverting colostomy.Surgical Repairs. The most common method of repair of the anal sphincter is a wrap-around sphincteroplasty (Fig. 29-42).172 The procedure involves mobilization of the divided sphincter muscle and reapproximation without tension. The internal and external sphincters may be overlapped together or separately. Postanal intersphincteric levatorplasty is less commonly used to repair sphincter defects but may be useful for incontinence caused by prolapse and/or loss of the anorectal angle (see “Continence”). The approach is via the intersphincteric plane posteriorly. It may be performed concomitantly with a perineal repair of rectal prolapse. The levator ani muscle is approximated to restore the anorectal angle, and the puborectalis and external sphincter muscles are tightened with sutures. These elective pro-cedures usually do not require a diverting colostomy.In cases where there has been significant loss of sphincter muscle or in which prior repairs have failed, more complex tech-niques, such as gracilis muscle transposition with or without Inferior rectal nervePudendal nerveFibrotic portion ofexternal sphincterTransverse superficialperineal muscleABCDFigure 29-42. Overlapping sphincteroplasty for incontinence from sphincter disruption. A. The external sphincter muscle with scar at site of injury is mobilized. B. The muscle edges are aligned in an overlapping fashion. C. Mattress sutures are used to approximate the muscle. D. The completed operation.Brunicardi_Ch29_p1259-p1330.indd 132223/02/19 2:30 PM 1323COLON, RECTUM, AND ANUSCHAPTER 29chronic, low-frequency electrostimulation, have been used with some success.173 In this procedure, the gracilis muscle is mobi-lized from the thigh, detached from its insertion on the tibial tuberosity, tunneled through the perineum, and wrapped around the anal canal. Another alternative in patients who have failed other repairs is the artificial anal sphincter. This device consists of an inflatable silastic cuff, a pressure-regulating balloon, and a control pump. Patients deflate the cuff manually to open the anal canal; the cuff then reinflates spontaneously to maintain clo-sure of the anal canal. Frequent infections and erosion can lead to device loss.173,174 Sacral nerve stimulation via an implanted pulse generator is a technique used for neurogenic incontinence when the sphincter is intact.12-14 In some patients, an end stoma provides the best relief for intractable incontinence.176Foreign BodyForeign body entrapment in the rectum is not uncommon. Depending on the level of entrapment, a foreign body may cause damage to the rectum, rectosigmoid, or descending colon. Generalized abdominal pain suggests intraperitoneal perfo-ration. Evaluation of the patient includes inspection of the perineum and a careful abdominal examination to detect any evidence of perforation. Plain films of the abdomen are manda-tory to detect free intra-abdominal air.Foreign bodies lodged low in the rectum may often be removed under conscious sedation with or without a local anes-thetic block. Objects impacted higher in the rectum may require regional or general anesthesia for removal. Only rarely will a laparotomy be required to remove the object, either through manual manipulation of the object to expel from the anus, or via colotomy. After removal of the foreign body, it is crucial to evaluate the rectum and sigmoid colon for injury. Proctos-copy and/or flexible sigmoidoscopy should be performed. A hematoma without evidence of perforation requires no surgical treatment. Perforation of the rectum or sigmoid colon should be managed as described in the preceding sections.THE IMMUNOCOMPROMISED PATIENTHuman Immunodeficiency VirusPatients infected with HIV may present with a myriad of gastro-intestinal symptoms. Diarrhea, in particular, is extremely com-mon. The severity of gastrointestinal disease depends in part on the degree of immunosuppression; however, both ordinary and opportunistic pathogens may affect patients at any stage of the disease. Opportunistic infections with bacteria (Salmonella, Shi-gella, Campylobacter, Chlamydia, and Mycobacterium species), fungi (histoplasmosis, coccidiosis, Cryptococcus), protozoa (toxoplasmosis, cryptosporidiosis, isosporiasis), and viruses (CMV, herpes simplex virus) can cause diarrhea, abdominal pain, and weight loss. CMV in particular may cause severe enterocolitis and is the most common infectious cause of emer-gency laparotomy in acquired immunodeficiency syndrome (AIDS) patients. Clostridium difficile colitis is a major concern in these patients, especially because many patients are main-tained on suppressive antibiotic therapy. The incidence of gas-trointestinal malignancy is also increased in patients with HIV infection.177 Kaposi’s sarcoma is the most common malignancy in AIDS patients and can affect any part of the gastrointestinal tract. Patients may be asymptomatic or may develop bleeding or obstruction. Gastrointestinal lymphoma (usually non-Hodg-kin’s lymphoma) is also common. The incidence of colorectal carcinoma may also be increased in this population, although definitive data are lacking.Perianal disease is extremely common in patients with HIV infection. Because HIV is sexually transmitted, it is com-mon to find concomitant infection with other sexually trans-mitted diseases such as Chlamydia, herpes simplex virus, and HPV (anal condyloma). Anal condyloma in particular are very common, and the incidence of dysplasia (HGAIN) is high in the HIV-infected population.105 Abscesses and fistulas may be more difficult to diagnose in these patients and may be com-plex. Many patients require an examination under anesthesia with biopsy and cultures to determine the etiology of many of these perianal problems. The introduction of highly active anti-retroviral therapy (HAART) has changed the natural history of HIV infection, but it remains to be seen how these medications will affect the incidence and outcome of colorectal disease in this patient population.177IMMUNOSUPPRESSION FOR TRANSPLANTATIONThe gastrointestinal tract is a common site for posttransplanta-tion complications that are responsible for significant morbid-ity and mortality. In these patients, infection and medication are the most common causes of diarrhea. Immunosuppressant medications, in particular, may cause diarrhea. CMV infection is common and may be severe. Clostridium difficile colitis also occurs commonly. Diverticulitis appears to be more common in some populations of transplant patients and may be more likely to present with abscess or free perforation. Elective resection after recovery from one episode of confirmed diverticulitis may be indicated in the transplant population.178 Graft-versus-host disease is unique to transplant patients and often requires endoscopy and biopsy to diagnose gastrointestinal involvement. Patients are subject to the same opportunistic infections outlined earlier; however, sexually transmitted infections and Kaposi’s sarcoma are somewhat less prevalent. Perianal disease is some-what less common in the transplant population than in patients infected with HIV; however, similar infections may occur, and immunosuppression often makes diagnosis and treatment challenging.With increasing long-term survival among transplant recipients, the development of posttransplant malignancy has become a major concern. Posttransplant lymphoprolifera-tive disease is increasingly common and may occur anywhere in the gastrointestinal tract. The risk of colorectal carcinoma is increased in patients with predisposing conditions such as ulcerative colitis. However, immunosuppression alone does not appear to increase the incidence of colorectal cancer, and current screening recommendations are similar to those for the average risk population. In contrast, the incidence of anal squamous cell carcinoma is dramatically increased in transplant patients, and patients with known HPV infection should undergo more vigor-ous screening.THE NEUTROPENIC PATIENTNeutropenic enterocolitis (typhlitis) is a life-threatening prob-lem with a mortality rate of greater than 50%. This syndrome is characterized by abdominal pain and distention, fever, diarrhea (often bloody), nausea, and vomiting in a patient with fewer than 1000 neutrophils/μL blood from any cause (bone marrow transplantation, solid-organ transplantation, or chemotherapy). Its etiology is poorly understood. Histologic features can be Brunicardi_Ch29_p1259-p1330.indd 132323/02/19 2:30 PM 1324SPECIFIC CONSIDERATIONSPART IIseen on biopsy or surgical resection and include a paucity of inflammatory and leukemic infiltrates but with mucosal and submucosal edema, villous sloughing, stromal hemorrhage, and patchy-to-complete epithelial necrosis. CT scan of the abdomen often shows a dilated cecum with pericolic stranding. However, a normal-appearing CT scan does not exclude the diagnosis. Some patients will respond to bowel rest, broad-spectrum anti-biotics, parenteral nutrition, and granulocyte infusion or col-ony-stimulating factors.179 Evidence of perforation, generalized peritonitis, and deterioration in clinical condition are indications for operation.Neutropenic patients often develop perianal pain, and diagnosis may be difficult because of a lack of inflammatory response to infection. While broad-spectrum antibiotics may cure some of these patients, an examination under anesthesia should not be delayed because of neutropenia. An increase in pain or fever and/or clinical deterioration mandates an exam under anesthesia. Any indurated area should be incised and drained, biopsied to exclude a leukemic infiltrate, and cultured to aid in the selection of antimicrobial agents.REFERENCESEntries highlighted in bright blue are key references. 1. Keller J, Fibbe C, Rosien U, et al. Recent advances in capsule endoscopy: development of maneuverable capsules. Expert Rev Gastroenterol Hepatol. 2012;6:561-566. 2. Mang T, Bogoni L, Salganicoff M, et al. Computer-aided detection of colorectal polyps in CT colonography with and without fecal tagging: a stand-alone evaluation. Invest Radiol. 2012;47:99-108. 3. Grady E. Gastrointestinal bleeding scintigraphy in the early 21st Century. J Nucl Med. 2016;57:252-259. 4. Allen TW, Tulchinsky M. Nuclear medicine tests for acute gastrointestinal conditions. Semin Nucl Med. 2013;43:88-101. 5. Garcia-Aguilar J, Pollack J, Lee SH, et al. Accuracy of endorectal ultrasonography in preoperative staging of rectal tumors. Dis Colon Rectum. 2002;45:10-15. 6. Lee JK, Liles EG, Bent S, Levin TR, Corley DA. Accuracy of fecal immunochemical tests for colorectal cancer: systematic review and meta-analysis. Ann Intern Med. 2014;160:171. 7. Imperiale TF, Ransohoff DF, Itzkowitz SH, et al. Multitarget stool DNA testing for colorectal-cancer screening. N Engl J Med. 2014;370(14):1287-1297. 8. Thirunavukarasu P, Talati C, Munjal S, Attwood K, Edge SB, Francescutti V. Effect of incorporation of pretreatment serum carcinoembryonic antigen levels into AJCC staging for colon cancer on 5-year survival. JAMA Surg. 2015;150(8):747-755. doi: 10.1001/jamasurg.2015.0871. PMID: 26083632. 9. Offit K. Genetic prognostic markers for colorectal cancer. N Engl J Med. 2000;342:124-125. 10. Lynch HT, Lynch JF, Lynch PM, et al. Hereditary colorectal cancer syndromes: molecular genetics, genetic counseling, diagnosis and management. Fam Cancer. 2008;7:27-39. This reference is included in an issue of Familial Cancer that is devoted to discussion of hereditary forms of colorectal can-cer. The paper summarizes the evaluation of patients suspected to have familial colorectal cancer with a special emphasis on HNPCC (Lynch Syndrome) and FAP. Recommendations are provided for genetic testing, surveillance strategies, and treatment. 11. FitzHarris GP, Garcia-Aguilar J, Parker SC, et al. Quality of life after subtotal colectomy for slow-transit constipa-tion: both quality and quantity count. Dis Colon Rectum. 2003;46:433-440. 12. Paquette IM, Varma MG, Kaiser AM, Steele SR, Raf-ferty JF. The American Society of Colon and Rectal Sur-geons’ clinical practice guideline for the treatment of fecal incontinence. Dis Colon Rectum. 2015;58:623-636. The Standards Task Force of the American Society of Colon and Rectal Surgeons evaluated existing data on treatment of fecal incontinence based upon quality. The guidelines provided in this manuscript represent evidence based management of this condition. 13. Ganio E, Ratto C, Masin A, et al. Neuromodulation for fecal incontinence: outcome in 16 patients with definitive implant. The initial Italian Sacral Neurostimulation Group (GINS) experience. Dis Colon Rectum, 2001;44:965-970. 14. Forte ML1, Andrade KE, Lowry AC, Butler M, Bliss DZ, Kane RL. Systematic review of surgical treatments for fecal incontinence. Dis Colon Rectum. 2016;59(5):443-469. doi: 10.1097/DCR.0000000000000594 15. Ky AJ, Sonoda T, Milsom JW. One-stage laparoscopic restor-ative proctocolectomy: an alternative to the conventional approach? Dis Colon Rectum. 2002;45:207-210. 16. Lezoche E, Feliciotti F, Paganini AM, et al. Laparoscopic colonic resections versus open surgery: a prospective non-randomized study on 310 unselected cases. Hepatogastroen-terology. 2000;47:697-708. 17. Martinez-Perez A, Cara MC, Brunetti F, de’Angelis N. Patho-logic outcomes of laparoscopic vs. open mesorectal excision for rectal cancer: a systematic review and meta-analysis. JAMA Surg. 2017;8:165665. doi:10.1001/jamasurg.20165665 18. Weeks JC, Nelson H, Gelber S, et al. Short-term quality-of-life outcomes following laparoscopic-assisted colectomy vs. open colectomy for colon cancer: a randomized trial. JAMA. 2002;287:321-328. 19. deSouza AL, Prasad LM, Ricci J, et al. A comparison of open and robotic total mesorectal excision for rectal adenocarci-noma. Dis Colon Rectum. 2011;54:275-282. 20. Biondo S, Frago R, Codina Cazador A, et al. Long-term func-tional results from a randomized clinical study of transverse coloplasty compared with colon J-pouch after low anterior resection for rectal cancer. Surgery. 2013;153:383-392. 21. Heah SM, Seow-Choen F, Eu KW, et al. Prospective, random-ized trial comparing sigmoid vs. descending colonic J-pouch after total rectal excision. Dis Colon Rectum. 2002;45: 322-328. 22. Machado M, Nygren J, Goldman S, et al. Similar outcome after colonic pouch and side-to-end anastomosis in low ante-rior resection for rectal cancer: a prospective randomized trial. Ann Surg. 2003;238:214-220. 23. Ricciardi R, Roberts PL, Marcello PW, Hall JF, Read TE, Schoetz DJ. Anastomotic leak testing after colo-rectal resec-tion: what are the data? Arch Surg. 2009;144(5):407-411. 24. Prytz M, Angenete E, Bock D, Haglind E. Extralevator abdom-inoperineal excision for low rectal cancer—extensive surgery to be used with discretion based on 3 year local recurrence results. Ann Surg. 2016;263(3):516-521. 25. Holm T, Ljung A, Haggmark T, Jurell G, Lagergren J. Extended abdominoperineal resection with gluteus maximus flap reconstruction of the pelvic floor for rectal cancer. Br J Surg. 2007;94:232-238. 26. Farouk R, Pemberton JH, Wolff BG, et al. Functional out-comes after ileal pouch-anal anastomosis for chronic ulcer-ative colitis. Ann Surg. 2000;231:919-926. 27. Bullard KM, Madoff RD, Gemlo BT. Is ileoanal pouch func-tion stable with time? Results of a prospective audit. Dis Colon Rectum. 2002;45:299-304. 28. Segal JP, Ding NS, Worley G, et al. Systematic review with meta-analysis: the management of chronic refractory pouchitis with an evidence-based treatment algorithm. Aliment Pharma-col Ther. 2017;45(5):581-592. doi:10.1111/apt.13905.Brunicardi_Ch29_p1259-p1330.indd 132423/02/19 2:30 PM 1325COLON, RECTUM, AND ANUSCHAPTER 29 29. Sandborn W, McLeod R, Jewell D. Pharmacotherapy for inducing and maintaining remission in pouchitis. Cochrane Database Syst Rev. 2000;2:CD001176. 30. Stocchi L, Pemberton JH. Pouch and pouchitis. Gastroenterol Clin North Am. 2001;30:223-241. 31. Sandborn W, McLeod R, Jewell D. Pharmacotherapy for inducing and maintaining remission in pouchitis. Cochrane Database Syst Rev. 2000;2:CD001176. 32. Tran-Minh ML, Allez M, Gornet JM. Successful treatment with ustekinumab for chronic refractory pouchitis. J Crohns Colitis. 2017;11(9):1156. doi:10.1093/ecco-jcc/jjx018. 33. Kelly OB, Rosenberg M, Tyler AD, et al. Infliximab to treat refractory inflammation after pelvic pouch surgery for ulcer-ative colitis. J Crohns Colitis. 2016;10(4):410-417. doi: 10.1093/ecco-jcc/jjv225 34. Schmid M, Frick JS, Malek N, Goetz M. Successful treat-ment of pouchitis with Vedolizumab, but not fecal micro-biota transfer (FMT), after proctocolectomy in ulcerative colitis. Int J Colorectal Dis. 2017;32(4):597-598. doi: 10.1007/s00384-017-2761-4 35. Cannon JA, Altom LK, Deierhoi RJ, et al. Preoperative oral antibiotics reduce surgical site infection following elective colorectal resections. Dis Colon Rectum. 2012;55:1160-1166. 36. Scarborough JE, Mantyh CR, Sun Z, Migaly J. Com-bined mechanical and oral antibiotic bowel preparation reduces incisional surgical site infection and anastomotic leak rates after elective colorectal resection. Ann Surg. 2015;262(2):331-337. This study assessed the effect of com-bined mechanical and oral antibiotic bowel preparation (prep) and 30-day outcomes after colorectal resection using data from the 2012 Colectomy-Targeted American College of Sur-geons National Surgical Quality Improvement (ACS NSQIP) data (4999 patients). The combination of oral and mechani-cal bowel preparation decreased the incidence of surgical site infection, anastomotic leak, and hospital readmission when compared to mechanical prep alone, oral antibiotic prep alone, or no prep. 37. Cao F, Li J, Li F. Mechanical bowel preparation for elective colorectal surgery: updated systematic review and meta-anal-ysis. Int J Colorectal Dis. 2012;27:803-810. 38. Hadithi M, Cazemier M, Meijer GA, et al. Retrospective anal-ysis of old-age colitis in the Dutch inflammatory bowel dis-ease population. World J Gastroenterol. 2008;14:3183-3187. 39. Bonen DK, Cho JH. The genetics of inflammatory bowel dis-ease. Gastroenterology. 2003;124:521-536. 40. Yamamoto-Furusho JK. Genetic factors associated with the development of inflammatory bowel disease. World J Gastro-enterol. 2007;13:5594-5597. 41. Halme L, Paavola-Sakki P, Turunen U, et al. Family and twin studies in inflammatory bowel disease. World J Gastroenterol. 2006;12:3668-3672. 42. Hugot JP, Chamaillard M, Zouali H, et al. Association of NOD2 leucine-rich repeat variants with susceptibility to Crohn’s disease. Nature. 2001;411:599-603. 43. Sehgal R, Berg A, Hegarty JP, et al. NOD2/CARD15 muta-tions correlate with severe pouchitis after ileal pouch-anal anastomosis. Dis Colon Rectum. 2010;53(11):1487-1494. 44. Sehgal R, Berg A, Polinski JI, et al. Mutations in IRGM are associated with more frequent need for surgery in patients with ileocolonic Crohn’s disease. Dis Colon Rectum. 2012;55(2):115-121. 45. Hoarau G, Mukherjee PK, Gower-Rousseau C, et al. Bac-teriome and mycobiome interactions underscore microbial dysbiosis in familial Crohn’s disease. mBio. 2016;7(5). pii: e01250-16. 46. Strisciuglio C, Duijvestein M, Verhaar AP, et al. Impaired autophagy leads to abnormal dendritic cell-epithelial cell interactions. J Crohns Colitis. 2013;7(7):534-541. 47. Brinar M, Vermeire S, Cleynen I, et al. Genetic variants in autophagy-related genes and granuloma formation in a cohort of surgically treated Crohn’s disease patients. J Crohns Colitis. 2012;6(1):43-50. 48. Strisciuglio C, Duijvestein M, Verhaar AP, et al. Impaired autophagy leads to abnormal dendritic cell-epithelial cell interactions. J Crohns Colitis. 2013;7(7):534-541. 49. Brinar M, Vermeire S, Cleynen I, et al. Genetic variants in autophagy-related genes and granuloma formation in a cohort of surgically treated Crohn’s disease patients. J Crohns Colitis. 2012;6(1):43-50. 50. Tremaine WJ. Is indeterminate colitis determinable? Curr Gastroenterol Rep. 2012;14:162-165. 51. Lakatos PL, Lakatos L, Kiss LS, et al. Treatment of extraintes-tinal manifestations in inflammatory bowel disease. Digestion. 2012;86(suppl 1):28-35. 52. Alfadhli AA, McDonald JW, Feagan BG. Methotrexate for induction of remission in refractory Crohn’s disease. Cochrane Database Syst Rev. 2005;1:CD003459. 53. Hanauer SB, Feagan BG, Lichtenstein GR, et al. Main-tenance infliximab for Crohn’s disease: the ACCENT I randomised trial. Lancet. 2002;359:1541-1549. This study reports a randomized, controlled trial to assess main-tenance therapy with infliximab for Crohn’s Disease. In this trial, 573 patients were treated with intravenous inf-liximab (single dose) and then randomized to repeat infu-sions of infliximab versus placebo. The investigators found that patients who responded to the first infusion of inflix-imab were more likely to stay in remission and discon-tinue corticosteroids when maintained on infliximab every 8 weeks. 54. Sands BE, Blank MA, Patel K, van Deventer SJ; ACCENT II Study. Long-term treatment of rectovaginal fistulas in Crohn’s disease: response to infliximab in the ACCENT II Study. Clin Gastroenterol Hepatol. 2004;2:912-920. 55. Yarur AJ, Kanagala V, Stein DJ, et al. Higher infliximab trough levels are associated with perianal fistula healing in patients with Crohn’s disease. Aliment Pharmacol Ther. 2017;45(7):933-940. 56. Bamias G, Cominelli F. Novel strategies to attenuate immune activation in Crohn’s disease. Curr Opin Pharmacol. 2006;6:401-407. 57. Panaccione R, Ghosh S, Middleton S, et al. Combination therapy with infliximab and azathioprine is superior to mono-therapy with either agent in ulcerative colitis. Gastroenterology. 2014;146(2):392-400.e3. 58. Reinisch W, Sandborn WJ, Hommes DW, et al. Adalimumab for induction of clinical remission in moderately to severely active ulcerative colitis: results of a randomised controlled trial. Gut. 2011;60(6):780-787. 59. Sandborn WJ, van Assche G, Reinisch W, et al. Adalim-umab induces and maintains clinical remission in patients with moderate-to-severe ulcerative colitis. Gastroenterology. 2012;142(2):257-265.e1-e3. 60. Sjöberg M, Magnuson A, Björk J, et al; Swedish Organiza-tion for the Study of Inflammatory Bowel Disease (SOIBD). Infliximab as rescue therapy in hospitalised patients with steroid-refractory acute ulcerative colitis: a long-term fol-low-up of 211 Swedish patients. Aliment Pharmacol Ther. 2013;38(4):377-387. 61. Su C, Lewis JD, Deren JJ, et al. Efficacy of anti-tumor necrosis factor therapy in patients with ulcerative colitis. Am J Gastro-enterol. 2002;97:2577-2584. 62. Actis GC, Bruno M, Pinna-Pintor M, et al. Infliximab for treat-ment of steroid-refractory ulcerative colitis. Dig Liver Dis. 2002;34:631-634. 63. Appau KA, Fazio VW, Shen B, et al. Use of infliximab within 3 months of ileocolonic resection is associated with adverse Brunicardi_Ch29_p1259-p1330.indd 132523/02/19 2:30 PM 1326SPECIFIC CONSIDERATIONSPART IIpostoperative outcomes in Crohn’s patients. J Gastrointest Surg. 2008;12(10):1738-1744. 64. Matsumoto T, Iwao Y, Igarashi M, et al. Endoscopic and chro-moendoscopic atlas featuring dysplastic lesions in surveillance colonoscopy for patients with long-standing ulcerative colitis. Inflamm Bowel Dis. 2008;14:259-264. 65. Wong Kee Song LM, Adler DG, Chand B, et al. Chromoen-doscopy. Gastrointest Endosc. 2007;66:639-649. 66. Heuschen UA, Hinz U, Allemeyer EH, et al. Oneor two-stage procedure for restorative proctocolectomy: ratio-nale for a surgical strategy in ulcerative colitis. Ann Surg. 2001;234:788-794. 67. Hall JF, Roberts PL, Ricciardi R, et al. Long-term follow-up after an initial episode of diverticulitis: what are the predictors of recurrence? Dis Colon Rectum. 2011;54:283-288. 68. Daniels L, de Korte N, Winter D, et al. Overtreatment of sig-moid diverticulitis: plea for a less aggressive approach. Dig Dis. 2012;30:86-91. 69. Li D, Baxter NN, McLeod R, Nathans AB. The decline of elective colectomy following diverticulitis: a population based analysis. Dis Colon Rectum. 2016;4:332-339. 70. Li D, Baxter NN, McLeod RS, Moineddin R, Wilton AS, Nathens AB. Evolving practice patterns in the acute manage-ment of acute colonic diverticulitis: a population-based analysis. Dis Colon Rectum. 2014;57(12):1397-1405. 71. Morris AM, Regebogen SE, Hardima KM. Surgery for diver-ticulitis: a systematic review. JAMA. 2014;311:902-302. 72. Bernini A, Spencer MP, Wong WD, et al. Computed tomog-raphy-guided percutaneous abscess drainage in intestinal disease: factors associated with outcome. Dis Colon Rectum. 1997;40:1009-1013. 73. Schultz JK, Yaqub S, Wallon C, et al. Laparoscopic lavage versus primary resection for acute perforated diverticulitis: the SCANDIV randomized clinical trial. JAMA. 2015;314 (13):1364-1375. 74. Vennix S, Musters GD, Mulder IM, et al. Laparoscopic perito-neal lavage or sigmoidectomy for perforated diverticulitis with purulent peritonitis: a multicenter parallel group randomised open label trial. Lancet. 2015;386:1269-1277. 75. Siegel RL, Miller KD, Fedewa SA, et al. Colorectal cancer statistics, 2017. CA Cancer J Clin. 2017;67(3):177-193. 76. Calle EE, Rodriguez C, Walker-Thurmond K, et al. Overweight, obesity, and mortality from cancer in a prospectively studied cohort of U.S. adults. N Engl J Med. 2003;348:1625-1638. 77. Woodhouse CR. Guidelines for monitoring of patients with ureterosigmoidostomy. Gut. 2002;51(suppl 5):V15-V16. 78. Baxter NN, Tepper JE, Durham SB, et al. Increased risk of rectal cancer after prostate radiation: a population-based study. Gastroenterology. 2005;128:819-824. 79. Smith RA, von Eschenbach AC, Wender R, et al. American Cancer Society guidelines for the early detection of cancer: update of early detection guidelines for prostate, colorec-tal, and endometrial cancers. CA Cancer J Clin. 2001;51: 38-75. 80. Al-Tassan N, Chmiel NH, Maynard J, et al. Inherited vari-ants of MYH associated with somatic G:C–>T:A mutations in colorectal tumors. Nat Genet. 2002;30:227-232. 81. Lefevre JH, Rodrigue CM, Mourra N, et al. Implication of MYH in colorectal polyposis. Ann Surg. 2006;244: 874-879. MYH is a base excision repair gene that removes adenines from DNA that have been mispaired with a nucle-otide product of oxidative reaction (8oxoG). Without MYH, mispaired adenines will lead to somatic transversions G:C→ T:A in genes such as APC or K-ras. The authors reviewed 433 patients who underwent prophylactic surgery for colorectal polyposis over a 25-year time frame and evaluated 31 patients who did not have APC, finding biallelic MYH mutations in 6 patients. They conclude that MYH is a new gene responsible for approximately 1.4% of all adenomatous polyposis and 20% of polyposis without an APC mutation identified. 82. Martin M, Simon-Assmann P, Kedinger M, et al. DCC regu-lates cell adhesion in human colon cancer derived HT-29 cells and associates with ezrin. Eur J Cell Biol. 2006;85: 769-783. 83. Lao VV, Grady WM. Epigenetics and colorectal cancer. Nat Rev Gastroenterol Hepatol. 2011;8:686-700. 84. Ferlitsch M, Moss A, Hassan C, et al. Colorectal polypectomy and endoscopic mucosal resection (EMR): European Society of Gastrointestinal Endoscopy (ESGE) clinical guideline. Endoscopy. 2017;49(3):270-297. doi:10.1055/s-0043-102569. 85. Rex DK, Ahnen DJ, Baron JA, et al. Serrated lesions of the colorectum: review and recommendations from an expert panel. Am J Gastroenterol. 2012;107:1315-1329. An expert panel provide their recommendation after a thorough literature review and 2-day conference. Hyperplastic polyps, sessile ser-rated adenomas/polyps, and traditional serrated adenomas are all included in the category of serrated lesions of the colon. This review outlines the histologic features of these lesions. Sessile serrated adenomas are predominantly flat, often with indistinct borders, right sided. They are associated with inter-val colon adenocarcinomas and are thought to progress to cancer, possibly through a promotor CpG island hypermeth-ylation pathway. The panel recommends that these lesions are completely excised and points to the variability in detection rates between endoscopists, hypothesizing that difficulty in endoscopic detection is related to the high rate of subsequent cancer diagnosis in these patients. 86. Regimbeau JM, Panis Y, Pocard M, et al. Handsewn ileal pouch-anal anastomosis on the dentate line after total proc-tectomy: technique to avoid incomplete mucosectomy and the need for long-term follow-up of the anal transition zone. Dis Colon Rectum. 2001;44:43-50. 87. Remzi F, Fazio VW, Delaney CP, et al. Dysplasia of the anal transitional zone after ileal pouch-anal anastomosis: results of prospective evaluation after a minimum of ten years. Dis Colon Rectum. 2003;46:6-13. 88. Janne PA, Mayer RJ. Chemoprevention of colorectal cancer. N Engl J Med. 2000;342:1960-1968. 89. Steinbach G, Lynch PM, Phillips RK, et al. The effect of cele-coxib, a cyclooxygenase-2 inhibitor, in familial adenomatous polyposis. N Engl J Med. 2000;342:1946-1952. 90. Kasper B, Gruenwald V, Reichardt P, et al. Imatinib induces sustained progression arrest in RECIST progressive desmoid tumours: Final results of a phase II study of the German Inter-disciplinary Sarcoma Group (GISG). Eur J Cancer. 2017;76: 60-67. doi: 10.1016/j.ejca.2017.02.001. 91. Church J, Xhaja X, LaGuardia L, O’Mally M, Burke C, Kalady M. Desmoids and genotype in familial adenomatous polyposis. Dis Colon Rectum. 2015;58(4):444-448. 92. Bulow C, Vasen H, Järvinen H, et al. Ileorectal anastomosis is appropriate for a subset of patients with familial adenomatous polyposis. Gastroenterology. 2000;119:1454-1460. 93. Hampel H, Panescu J, Lockman J, et al. Screening for the Lynch syndrome (hereditary nonpolyposis colorectal cancer). N Engl J Med. 2005;352:1851-1860. 94. Jarvinen HJ, Aarnio M, Mustonen H, et al. Controlled 15-year trial on screening for colorectal cancer in families with hereditary nonpolyposis colorectal cancer. Gastroenterology. 2000;118:829-834. 95. National Quality Forum. Appendix A: Specifications of the National Voluntary Consensus Standards for Breast and Colon Cancer. Available at: https://www.qualityforum.org/Publica-tions/2009/05/National_Voluntary_Consensus_Standards_for_Quality_of_Cancer_Care.aspx. Accessed July 23, 2018. 96. Lieberman DA, Weiss DG, Bond JH, et al. Use of colonos-copy to screen asymptomatic adults for colorectal cancer. Brunicardi_Ch29_p1259-p1330.indd 132623/02/19 2:30 PM 1327COLON, RECTUM, AND ANUSCHAPTER 29Veterans Affairs Cooperative Study Group 380. N Engl J Med. 2000;343:162-168. 97. Pignone M, Rich M, Teutsch SM, et al. Screening for colorec-tal cancer in adults at average risk: a summary of the evidence for the U.S. Preventive Services Task Force. Ann Intern Med. 2002;137:132-141. 98. U.S. Preventive Services Task Force, Bibbins-Domingo K, Grossman DC, et al. Screening for colorectal cancer: US Preventive Services Task Force recommendation statement. JAMA. 2016;315:2564-2575. 99. Mandel JS, Church TR, Bond JH, et al. The effect of fecal occult-blood screening on the incidence of colorectal cancer. N Engl J Med. 2000;343:1603-1607. 100. Hardcastle JD, Armitage NC, Chamberlain J, et al. Fecal occult blood screening for colorectal cancer in the general popula-tion. Results of a controlled trial. Cancer. 1986;58:397-403. 101. Winawer SJ, Flehinger BJ, Schottenfeld D, et al. Screening for colorectal cancer with fecal occult blood testing and sigmoid-oscopy. J Natl Cancer Inst. 1993;85:1311-1318. 102. Levin B, Brooks D, Smith RA, et al. Emerging technologies in screening for colorectal cancer: CT colonography, immu-nochemical fecal occult blood tests, and stool screening using molecular markers. CA Cancer J Clin. 2003;53:44-55. 103. Yee J, Akerkar GA, Hung RK, et al. Colorectal neoplasia: per-formance characteristics of CT colonography for detection in 300 patients. Radiology. 2001;219:685-692. 104. Imperiale TF, Wagner DR, Lin CY, et al. Risk of advanced proximal neoplasms in asymptomatic adults according to the distal colorectal findings. N Engl J Med. 2000;343:169-174. 105. Holme O, Løberg M, Kalager M, et al. Effect of flexible sig-moidoscopy screening on colorectal cancer incidence and mor-tality: a randomized clinical trial. JAMA. 2014;312:606-615. 106. Greene FL, Fleming PD, Fleming ID, et al. AJCC Cancer Staging Manual. Springer: New York; 2002. 107. Chang GJ, Kaiser AM, Mills S, Rafferty JE, Buie WD, on behalf of the Standards Practice Task Force of the American Society of Colon and Rectal Surgeons. Practice parameters for the management of colon cancer. Dis Colon Rectum. 2012;55:831-843. 108. Gunderson LL, Sargent DJ, Tepper JE, et al. Impact of T and N substage on survival and disease relapse in adjuvant rec-tal cancer: a pooled analysis. Int J Radiat Oncol Biol Phys. 2002;54:386-396. 109. Monson JRT, Weiser MR, Buie WD, Chang GJ, Rafferty JF; Prepared by the Standards practice Task Force of the American Society of Colon and Rectal Surgeons. Practice parameters for the management of rectal cancer (revised). Dis Colon Rectum. 2013;56:535-550. 110. Qiu H, Sirivongs P, Rothenberger M, et al. Molecular prognos-tic factors in rectal cancer treated by radiation and surgery. Dis Colon Rectum. 2000;43:451-459. 111. Johnson PM, Porter GA, Ricciardi R, et al. Increasing negative lymph node count is independently associated with improved long-term survival in stage IIIB and IIIC colon cancer. J Clin Oncol. 2006;24:3570-3575. 112. Chang GJ, Rodriguez-Bigas MA, Skibber JM, et al. Lymph node evaluation and survival after curative resec-tion of colon cancer: systematic review. J Natl Cancer Inst. 2007;99:433-441. 113. Ricciardi R, Madoff RD, Rothenberger DA, et al. Population-based analyses of lymph node metastases in colorectal cancer. Clin Gastroenterol Hepatol. 2006;4:1522-1527. 114. Ricciardi R, Baxter NN. Association versus causation versus quality improvement: setting benchmarks for lymph node eval-uation in colon cancer. J Natl Cancer Inst. 2007;99:414-415. 115. Puthillath A, Dunn KB, Rajput A, et al. Safety and efficacy of first-line chemotherapy in unresected metastatic colorectal cancer. Clin Colorectal Cancer. 2007;6:710-715. 116. Francescutti V, Miller A, Satchidanand Y, Alvarez-Perez A, Dunn KB. Management of bowel obstruction in patients with stage IV cancer: predictors of outcome after surgery. Ann Surg Oncol. 2013;20(3):707-714. doi: 10.1245/s10434-012-2662-2. 117. Kashida H, Kudo SE. Early colorectal cancer: concept, diag-nosis, and management. Int J Clin Oncol. 2006;11(1):1-8. 118. Sargent DJ, Marsoni S, Monges G, et al. Defective mismatch repair as a predictive marker for lack of efficacy of fluoro-uracil-based adjuvant therapy in colon cancer. J Clin Oncol. 2010;28:3219-3226. 119. Mahmoud N, Bullard Dunn K. Metastasectomy for stage IV colorectal cancer. Dis Colon Rectum. 2010;53:1080-1092. 120. Demmy TL, Dunn KB. Surgical and nonsurgical therapy for lung metastasis: indications and outcomes. Surg Oncol Clin N Am. 2007;16:579-605. 121. Stitzenberg KB, Sanoff HK, Penn DC, Meyers MO, Tepper JE. Practice patterns and long-term survival for early-stage rectal cancer. J Clin Oncol. 2013;31(34):4276-4282. 122. Taylor FGM, Quirke P, Heald RJ, et al. Preoperative high-res-olution magnetic resonance imaging can identify good prog-nosis stage I, II and III rectal cancer best managed by surgery alone. Ann Surg. 2011;253:711-719. 123. Garcia-Aguilar J, Shi Q, Thomas CR, Jr, et al. A phase II trial of neoadjuvant chemoradiation and local excision for T2N0 rectal cancer: preliminary results of the ACOSOG Z6041 trial. Ann Surg Oncol. 2012;19:384-391. 124. Garcia-Aguilar J, Renfro LA, Chow OS, et al. Organ preserva-tion for clinical T2N0 distal rectal cancer using neoadjuvant chemoradiotherapy and local excision (ACOSOG Z6041): results of an open-label, single-arm, multi-institutional, phase 2 trial. Lancet Oncol. 2015;16(15):1537-1546. 125. Sun Z, Adam MA, Kim J, et al. Determining the optimal timing for initiation of adjuvant chemotherapy after resec-tion for Stage II and III colon cancer. Dis Colon Rectum. 2016;59(2):87-93. 126. Sauer R, Liersch T, Merkel S, et al. Preoperative versus postoperative chemoradiotherapy for rectal cancer. N Engl J Med. 2004;351:1731-1740. The German Rectal Cancer Study Group randomized patients with clinical stage II and III rectal cancer to preoperative or postoperative long-course chemoradiation. The study occurred between 1994 and 2002 and, of note, the approach to staging did not include MRI. Among the 799 patients who were analyzed, fewer local recurrences were seen in patients assigned to preoperative chemoradiation compared with patients assigned to postopera-tive chemoradiation (6% vs. 13%; P = 0.006) at 5 years. The authors also found that in the long term, 72% of local recur-rences were associated with distant metastases. A subgroup analysis showed that the strongest difference in hazard ratios between preoperative and postoperative chemoradiation were in the patients who had intersphincteric or abdominoperineal resections (hazard ratio 2.24; P = 0.03). 127. Cercek A, Garcia-Aguilar J. Rectal cancer: neoadjuvant ther-apy. In: Steele SR, Hull TL, Read TE, Saclarides TJ, Senagore AJ, Whitlow CB, eds. The ASCRS Textbook of Colon and Rectal Surgery. 3rd ed. New York: Springer; 2016:481-494. 128. Smith FM, Wiland H, Mace A, Pai RK, Kalady MF. Clinical criteria underestimate complete pathological response in rec-tal cancer treated with neoadjuvant chemoradiotherapy. Dis Colon Rectum. 2014;57(3):311-315. 129. Sammour T, Price BA, Krause KJ, Chang GJ. Nonoperative management of “watch and wait” for rectal cancer with com-plete clinical response after neoadjuvant chemoradiotherapy: a critical appraisal. Ann Surg Oncol. 2017;24:1904-1915. doi: 10.1245/s10434-017-5841-3. 130. Berends FJ, Kazemier G, Bonjer HJ, et al. Subcutaneous metastases after laparoscopic colectomy. Lancet. 1994; 344:58.Brunicardi_Ch29_p1259-p1330.indd 132723/02/19 2:30 PM 1328SPECIFIC CONSIDERATIONSPART II 131. Jayne DG, Guillou PJ, Thorpe H, et al. Randomized trial of laparoscopic-assisted resection of colorectal carcinoma: 3-year results of the UK MRC CLASICC Trial Group. J Clin Oncol. 2007;25:3061-3068. 132. Jayne DG, Thorpe HC, Copeland J, Quirke P, Brown JM, Guillou PJ. Five-year follow-up of the Medical Research Council CLASICC trial of laparoscopically assisted versus open surgery for colorectal cancer. Br J Surg. 2010;97(11):1638-1645. doi: 10.1002/bjs.7160. This study presents 5-year follow-up from the UK Medical Research Council CLASSIC Trial comparing the safety and efficacy of laparoscopic vs. open surgery for colorectal cancer. Outcomes included overall and disease free survival and local, distant, and port site recurrences. The investigators found no differ-ences between the two groups. They conclude, therefore, that long-term outcomes are not compromised by a laparoscopic approach. 133. Nelson H, Sargent D, Wieand HS, et al; for the Clinical Out-comes of Surgical Therapy Study Group. Laparoscopically assisted colectomy is as safe and effective as open colectomy in people with colon cancer. Abstracted from: A comparison of laparoscopically assisted and open colectomy for colon cancer. N Engl J Med. 2004;350:2050-2059. Cancer Treat Rev. 2004;30(8):707-709. 134. Hazebroek EJ. COLOR: a randomized clinical trial compar-ing laparoscopic and open resection for colon cancer. Surg Endosc. 2002;16:949-953. 135. Jeong SY, Park JW, Nam BH, et al. Open versus laparoscopic surgery for mid-rectal or low-rectal cancer after neoadjuvant chemoradiotherapy (COREAN trial): survival outcomes of an open-label, non-inferiority, randomised controlled trial. Lancet Oncol. 2014;15(7):767-774. 136. Martínez-Pérez A, Carra MC, Brunetti F, de’Angelis N. Pathologic outcomes of laparoscopic vs open mesorectal excision for rectal cancer: a systematic review and meta-analysis. JAMA Surg. 2017;152(4):e165665. doi: 10.1001/jamasurg.2016.5665. 137. Collinson FJ, Jayne DG, Pigazzi A, et al. An international, multicentre, prospective, randomised, controlled, unblinded, parallel-group trial of robotic-assisted versus standard laparo-scopic surgery for the curative treatment of rectal cancer. Int J Colorectal Dis. 2012; 27:233-241. 138. Fleshman J, Branda M, Sargent DJ, et al. Effect of laparo-scopic-assisted resection vs open resection of stage II or III rectal cancer on pathologic outcomes: the ACOSOG Z6051 randomized clinical trial. JAMA. 2015;314(13):1346-1355. 139. Stevenson AR, Solomon MJ, Lumley JW, et al; ALaCaRT Investigators. Effect of laparoscopic-assisted resection vs open resection on pathological outcomes in rectal cancer: the ALaCaRT randomized clinical trial. JAMA. 2015;314(13): 1356-1363. 140. Bonjer HJ, Deijen CL, Abis GA, et al. A randomized trial of laparoscopic versus open surgery for rectal cancer. N Engl J Med. 2015;372(14):1324-1332. 141. Collinson FJ, Jayne DG, Pigazzi A, et al. An international, multicentre, prospective, randomised, controlled, unblinded, parallel-group trial of robotic-assisted versus standard laparo-scopic surgery for the curative treatment of rectal cancer. Int J Colorectal Dis. 2012;27(2):233-241. 142. Rindi G, Arnold R, Bosman FT. Nomenclature and classifica-tion of neuroendocrine neoplasms of the digestive system. In Bosman FT, Carneiro F, Hruban RH, Theise ND, eds. WHO Classification of Tumors of Digestive System. Lyon, France: International Agency for Research on Cancer (IARC) Press; 2010:13-14. 143. Volkan Adsay N, Klimstra DS. Neuroendocrine tumors of the gastrointestinal and pancreatobiliary tracts. In: Odze RD, Goldblum JR, eds. Odze and Goldblum Surgical Pathology of the GI Tract, Liver, Biliary Tract and Pancreas. 3rd ed. Philadelphia: Saunders/Elsevier; 2015. 144. Bullard Dunn KM. Other rectal neoplasms. In: Beck DE, Steele SR, Wexner SD, eds. Fundamentals of Anorectal Surgery. 3rd ed. New York: Springer; 2018. 145. Merchea AL, Hubner M, Wenger D, Rose P, Dozois E. The value of preoperative biopsy in the management of solid pre-sacral tumors. Dis Colon Rectum. 2013;56:756-760. 146. Merchea A, Dozois EJ. Lesions originating within the retrorec-tal space. J Gastrointest Surg. 2014;18(12):2232-2233. 147. Dozois EJ, Jacofsky DJ, Billings BJ, et al. In: Wards CY, Larson DW. Surgical approach and oncologic outcomes fol-lowing multidisciplinary management of retrorectal sarcomas. Ann Surg Oncol. 2011;18(4):983-988. 148. Steele SR, Varma MG, Melton GB, Ross HM, Rafferty JF, Buie WD. Practice parameters for anal squamous neoplasms. Dis Colon Rectum. 2012;55:735-749. 149. Darragh TM, Colgan TJ, Cox JT, et al. The lower anogenital squamous terminology standardization project for HPV-asso-ciated lesions: background and consensus recommendations from the College of American Pathologists and the American Society for Colposcopy and Cervical Pathology. J Low Genit Tract Dis. 2012;16:205-242. 150. Messick CA, Rodriguez-Bigas. Anal dysplasia. Surg Oncol Clin North Am. 2017;26:33-43. The authors review the litera-ture on anal dysplasia with a focus on the natural history and the impact of ablative techniques with high resolution anos-copy on recurrence rates. High-risk patients are categorized as HIV-positive, immunosuppressed transplant recipients, and men who have sex with men. The authors emphasize the lack of literature in patients who are not non–high risk and overall emphasize close follow-up in all patients with high grade squamous intraepithelial lesion (HSIL)/high grade anal intraepithelial neoplasia (HGAIN). 151. Stanley MA. Imiquimod and the imidazoquinolones: mecha-nism of action and therapeutic potential. Clin Exp Dermatol. 2002;27:571-577. 152. Chen H, Cai Y, Liu Y, et al. Incidence, surgical treatment, and prognosis of anorectal melanoma from 1973 to 2011: a population based SEER analysis. Medicine (Baltimore). 2016;95:e2770. 153. Bullard KM, Tuttle TM, Rothenberger DA, et al. Surgi-cal therapy for anorectal melanoma. J Amer Coll Surg. 2003;196:206-211. 154. D’Hoore A, Penninckx F. Laparoscopic ventral recto(colpo)pexy for rectal prolapse: surgical technique and outcome for 109 patients. Surg Endosc. 2006;20:1919-1923. 155. Ponec RJ, Saunders MD, Kimmey MB. Neostigmine for the treatment of acute colonic pseudo-obstruction. N Engl J Med. 1999;341:137-141. 156. Turgeon DK, Novicki TJ, Quick J, et al. Six rapid tests for direct detection of Clostridium difficile and its toxins in fecal samples compared with the fibroblast cytotoxicity assay. J Clin Microbiol. 2003;41:667-670. 157. Bagdasarian N, Rao K, Malani PN. Diagnosis and treatment of Clostridium difficile in adults: a systematic review. JAMA. 2015;313(4):398-408. 158. Cecil JA. Clostridium difficile: changing epidemiology, treat-ment and infection prevention measures. Curr Infect Dis Rep. 2012;14:612-619. 159. Manfredelli S, Montalto G, Leonetti G, et al. Conventional (CH) vs. stapled hemorrhoidectomy (SH) in surgical treat-ment of hemorrhoids. Ten years experience. Ann Ital Chir. 2012;83:129-134. 160. Shao WJ, Li GC, Zhang ZH, Yang BL, Sun GD, Chen YQ. Systematic review and meta-analysis of randomized Brunicardi_Ch29_p1259-p1330.indd 132823/02/19 2:30 PM 1329COLON, RECTUM, AND ANUSCHAPTER 29controlled trials comparing stapled haemorrhoidopexy with conventional haemorrhoidectomy. Br J Surg. 2008;95: 147-160. 161. Schuurman JP, Borel Rinkes IH, Go PM. Hemorrhoidal artery ligation procedure with or without Doppler transducer in grade II and III hemorrhoidal disease: a blinded randomized clinical trial. Ann Surg. 2012;255:840-845. 162. Jonas M, Speake W, Scholefield J. Diltiazem heals glyceryl trinitrate-resistant chronic anal fissures: a prospective study. Dis Colon Rectum. 2002;45:1091-1095. 163. Mentes BB, Irkörücü O, Akin M, et al. Comparison of botu-linum toxin injection and lateral internal sphincterotomy for the treatment of chronic anal fissure. Dis Colon Rectum. 2003;46:232-237. 164. Nelson RL, Thomas K, Morgan J, et al. Nonsurgical therapy for anal fissure. Cochrane Database Syst Rev. 2012;2:CD003431. 165. North JH, Jr, Weber TK, Rodriguez-Bigas MA, et al. The management of infectious and noninfectious anorectal complications in patients with leukemia. J Am Coll Surg. 1996;183:322-328. 166. Jacob TJ, Perakath B, Keighley MR. Surgical interven-tion for anorectal fistula. Cochrane Database Syst Rev. 2010;5:CD006319. This meta-analysis evaluated 10 random-ized trials on outcomes after anorectal fistula procedures, with the ideal procedure stated to be associated with low recurrence rates, minimal incontinence, and good quality of life. Evalu-ated surgical interventions included: fistulotomy, fistulectomy, myo-mucosal advancement flap, fibrin glue, and cutting or loose setons. There were no differences in the procedures compared, except that fibrin glue had more recurrences. Trial sample sizes were noted to be small, and more recently dis-cussed procedures such as the anal fistula plug and Ligation of Intersphincteric Fistula Tract (LIFT) were not evaluated in this review. 167. De Groof EJ, Cabral VN, Buskens CJ, et al. Systematic review of the evidence and consensus on perianal fistula: an analy-sis of national and international guidelines. Colorectal Dis. 2016;18(4):O119-O134. 168. Shanwani A, Nor AM, Amri N. Ligation of the intersphincteric fistula tract (LIFT): a sphincter-saving technique for fistula-in-ano. Dis Colon Rectum. 2010;53:39-42. 169. Gunter J. Genital and perianal warts: new treatment opportuni-ties for human papillomavirus infection. Am J Obstet Gynecol. 2003;189(3 suppl):S3-S11. 170. Palefsky JM. Anal squamous intraepithelial lesions: relation to HIV and human papillomavirus infection. J Acquir Immune Defic Syndr. 1999;21(suppl 1):S42-S48. 171. Bosarge PL, Como JJ, Fox N, et al. Management of penetrat-ing extraperitoneal rectal injuries: an Eastern Association for the Surgery of Trauma practice management guideline. J Trauma Acute Care Surg. 2016;80(3):546-551. 172. Buie WD, Lowry AC, Rothenberger DA, et al. Clinical rather than laboratory assessment predicts continence after anterior sphincteroplasty. Dis Colon Rectum. 2001;44:1255-1260. 173. Baeten CG, Bailey HR, Bakka A, et al. Safety and efficacy of dynamic graciloplasty for fecal incontinence: report of a prospective, multicenter trial. Dynamic Graciloplasty Therapy Study Group. Dis Colon Rectum. 2000;43:743-751. 174. Hussain ZI, Lim M, Stojkovic SG. Systematic review of peri-anal implants in the treatment of faecal incontinence. Br J Surg. 2011;98:1526-1536. 175. Vaizey CJ, Kamm MA, Roy AJ, et al. Double-blind crossover study of sacral nerve stimulation for fecal incontinence. Dis Colon Rectum. 2000;43:298-302. 176. Tan EK, Vaizey C, Cornish J, et al. Surgical strategies for faecal incontinence—a decision analysis between dynamic gracilo-plasty, artificial bowel sphincter, and end stoma. Colorectal Dis. 2008;10:577-586. 177. Cooksley CD, Hwang LY, Waller DK, et al. HIV-related malig-nancies: community-based study using linkage of cancer reg-istry and HIV registry data. Int J STD AIDS. 1999;10:795-802. 178. Goldberg H, Baxter NN, Hertz M, Madoff RD, Ricciardi R, Bullard KM. Colon and rectal complications in heart and lung transplant patients. J Am Coll Surg. 2006;202:55-61. 179. Ullery BW, Pieracci FM, Rodney JRM, Barie PS. Neutropenic enterocolitis. Surg Infect (Larchmt). 2009;10(3):307-314.Brunicardi_Ch29_p1259-p1330.indd 132923/02/19 2:30 PM
Brunicardi_Ch29_p1259-p1330.indd 133023/02/19 2:30 PMThis page intentionally left blankThe AppendixFadi S. Dahdaleh, David Heidt, and Kiran K. Turaga 30chapterHISTORYAlthough anatomists such as Vesalius and Leonardo Da Vinci had written about the appendix, Claudius Amyand in the early 18th century was the first surgeon to describe a successful appendectomy.1 In subsequent centuries, significant progress was made in the diagnosis and management of appendicitis, especially after Chester McBurney advocated for early appen-dectomy in his 1889 publication.2 Famously, the magician Harry Houdini died of a ruptured appendix after suffering a blow to his abdomen. Following the introduction and widespread use of antibiotics in the 1940s, mortality rates improved further. In 1982, Kurt Semm, a gynecologist, reported on the first laparo-scopic appendectomy, which is now the most widely adopted technique.EMBRYOLOGY, ANATOMY, AND HISTOLOGYPreviously considered a vestigial organ, the appendix is now linked to the development and preservation of gut-associated lymphoid tissue (GALT) and to the maintenance of intestinal flora. It has been suggested that appendectomy is associated with increased Clostridium difficile infections and increased subse-quent cancer (colon, esophageal) as a result of microbial altera-tion, although this is currently unproven.3 The protective effect of an early appendectomy against development of ulcerative colitis has been proposed to be mechanistically linked to the release of dimeric forms of IgA from plasma B cells and the Th2 response mediated by IL-13–producing natural killer T cells.4The appendix, along with the ileum and the colon, devel-ops from the midgut and first appears at 8 weeks of gestation. As the gut rotates medially, the cecum becomes fixed in the right lower quadrant, thus determining the final position of the appendix. The appendix is a true diverticulum of the cecum as it contains all the histological layers of the colon, although cer-tain differences in the irregularity of crypts remain. The average appendix measures 6 to 9 cm and derives its blood supply from the appendicular branch of the ileocolic artery. Visceral innerva-tion occurs along the superior mesenteric plexus (T10-L1) and the vagus nerves. The appendix is intraperitoneal and retrocecal in location, but it can be pelvic (30%) and retroperitoneal (7%).5 Grossly, the appendiceal base can be identified by tracing the convergence of the cecal taeneia.ACUTE APPENDICITISInflammation of the appendix is a significant public health prob-lem with a lifetime incidence of 8.6% in men and 6.7% in women, with the highest incidence occurring in the second and third decade of life.6 While the rate of appendectomy in developed countries has decreased over the last several decades, it remains one of the most frequent emergent abdominal operations.7The etiology of appendicitis is perhaps due to luminal obstruction that occurs as a result of lymphoid hyperplasia in pediatric populations; in adults, it may be due to fecaliths, fibro-sis, foreign bodies (food, parasites, calculi), or neoplasia.5,8-10 Early obstruction leads to bacterial overgrowth of aerobic organisms in the early period, and subsequently, it leads to mixed flora. Obstruction generally leads to increased intralumi-nal pressure and referred visceral pain to the periumbilical region.10 It is postulated that this leads to impaired venous drain-age, mucosal ischemia leading to bacterial translocation, and subsequent gangrene and intraperitoneal infection. Escherichia coli and Bacteroides fragilis are the most common aerobic and anaerobic bacteria isolated in perforated appendicitis.11,12 1History 1331Embryology, Anatomy,  and Histology 1331Acute Appendicitis 1331Clinical Diagnosis 1332History / 1332Physical Examination / 1332Laboratory Findings / 1332Imaging / 1332Differential Diagnosis / 1335Management of Appendicitis 1335Uncomplicated Appendicitis / 1332Complicated Appendicitis / 1335Operative Intervention 1335Preoperative Preparation / 1335Operative Technique / 1336Novel Techniques / 1336Negative Exploration / 1336Incidental Appendectomy / 1336Special Circumstances 1337Appendicitis in Children / 1337Appendicitis in Older Adults / 1338Appendicitis in Pregnancy / 1338Chronic or Recurrent Appendicitis / 1338Outcomes and Postoperative  Course 1338Stump Appendicitis / 1338Appendiceal Neoplasms / 1338Gastroenteropancreatic Neuroendocrine Tumors (GEP-NETs or Carcinoid) / 1338Goblet Cell Carcinomas / 1339Lymphomas / 1339Adenocarcinoma / 1339Appendiceal Mucoceles and Mucinous Neoplasms of the Appendix / 1339Pseudomyxoma Peritonei Syndrome / 1340Brunicardi_Ch30_p1331-p1344.indd 133101/03/19 7:05 PM 1332Key Points1 Inflammation of the appendix is a significant public health problem with a lifetime incidence of 8.6% in men and 6.7% in women, with the highest incidence in the second and third decade of life.6 While the rate of appendectomy in devel-oped countries has decreased over the last several decades, it remains one of the most frequent emergent abdominal operations.2 The natural history of appendicitis is unclear, but it appears that progression to perforation is not predictable and that spontaneous resolution is common, suggesting that nonper-forated and perforated appendicitis may, in fact, be different diseases.3 C-reactive protein, bilirubin, Il-6, and procalcitonin have all been suggested to be helpful in the diagnosis of appendicitis, specifically in predicting perforated appendicitis.4 Perforated appendicitis can be managed either operatively or nonoperatively. Immediate surgery is necessary in patients that appear septic, but this is usually associated with higher complications, including abscesses and enterocutaneous fis-tulae, due to dense adhesions and inflammation.5 Single incision appendectomy has not been shown to improve outcomes, including cosmetic outcomes, in prospective randomized studies and has been suggested to have a higher incisional hernia rate.6 While there is no evidence clearly evaluating long-term out-comes of patients undergoing incidental appendectomy with an asymptomatic appendix, the risk of adhesions and future complications after an appendectomy has been suggested to be higher than the risk of future appendicitis and increased economic costs. An incidental appendectomy is currently not advocated.7 Older adult patients are at a higher risk for complications due to their premorbid conditions, and it is prudent to obtain definitive diagnostic imaging prior to taking patients to the operating room.8 Patients with uncomplicated appendicitis do not require fur-ther antibiotics after an appendectomy, while patients with perforated appendicitis are treated with 3 to 7 days of antibiotics.9 The most common mode of presentation for appendiceal car-cinoma is that of acute appendicitis. Patients also may pres-ent with ascites or a palpable mass, or the neoplasm may be discovered during an operative procedure for an unrelated cause.This sequence is not inevitable, however, and some episodes of acute appendicitis may resolve spontaneously. Due to differ-ences in epidemiology, nonperforated and perforated appendicitis are considered different diseases.13 Addition-ally, since not all nonperforated appendicitis progresses to per-forations, it is suggested that the pathogenesis of the two conditions may be different.CLINICAL DIAGNOSISHistoryIt is important to elicit an accurate history from the patient and/or family, in the case of pediatric patients. Inflammation of the visceral peritoneum usually progresses to the parietal perito-neum, presenting with migratory pain, which is a classic sign of appendicitis (likelihood ratio+, 2.06 [1.63–2.60]).14 Inflam-mation can often result in anorexia, nausea, vomiting, and fever (Table 30-1). Regional inflammation can also present with an ileus, diarrhea, small bowel obstruction, and hematuria. Perti-nent negative history (including menstrual) must be obtained to rule out other etiologies of abdominal pain.Physical ExaminationMost patients lay quite still due to parietal peritonitis. Patients are generally warm to the touch (with a low-grade fever, ∼38.0°C [100.4°F]) and demonstrate focal tenderness with guarding. McBurney’s point, which is found one-third of the distance between the anterior superior iliac spine and the umbili-cus, is often the point of maximal tenderness in a patient with an anatomically normal appendix. Certain physical signs with their respective eponyms can be helpful in discerning the location of the appendix: Rovsing’s sign, pain in the right lower quad-rant after release of gentle pressure on left lower quadrant (nor-mal position); Dunphy’s sign, pain with coughing (retrocecal 2appendix); obturator sign, pain with internal rotation of the hip (pelvic appendix); iliopsoas sign, pain with flexion of the hip (retrocecal appendix). In addition, pain with rectal or cervical examinations is also suggestive of pelvic appendicitis.Laboratory FindingsPatients with appendicitis usually have leukocytosis of 10,000 cells/mm3, with a higher leukocytosis associated with gangrenous and perforated appendicitis (∼17,000 cells/mm3). C-reactive pro-tein, bilirubin, Il-6, and procalcitonin have all been sug-gested to help in the diagnosis of appendicitis, specifically in predicting perforated appendicitis.14,15 The authors believe that a white blood cell (WBC) count and a C-reactive protein are two appropriate lab tests to obtain in the initial work up of appendicitis; a pregnancy test is also essential in women of childbearing age. Lastly, a urinalysis can be valuable in ruling out nephrolithiasis or pyelonephritis.ImagingImaging is often utilized to confirm a diagnosis of appendici-tis because a negative operation rate is acceptable in <10% of male patients and <20% of female patients. Routine use of crosssectional imaging somewhat reduces the rate of negative laparot-omies. Imaging studies are most appropriate for patients in whom a diagnosis of appendicitis is unclear or who are at high risk from operative intervention and general anesthesia, such as pregnant patients or patients with multiple comorbidities. Commonly utilized imaging modalities include computerized tomography (CT), ultrasound (US), and magnetic resonance imaging (MRI).CT Scan. A contrast-enhanced CT scan has a sensitivity of 0.96 (95% confidence interval [CI] 0.95–0.97) and specificity of 0.96 (95% CI 0.93–0.97) in diagnosing acute appendicitis.16,17 Features on a CT scan that suggest appendicitis include enlarged lumen and double wall thickness (greater than 6 mm), 3Brunicardi_Ch30_p1331-p1344.indd 133201/03/19 7:05 PM 1333THE APPENDIXCHAPTER 30Table 30-1Signs and symptoms of appendicitis TRUE POSITIVE LIKELIHOOD RATIO95% CONFIDENCE INTERVALTRUE NEGATIVE LIKELIHOOD RATIO95% CONFIDENCE INTERVALDuration of symptoms (hours) >9 >12 >24 >481.010.960.650.490.97–1.050.90–1.040.47–0.900.36–0.670.941.191.471.200.62–1.420.87–1.631.14–1.901.08–1.34Fever1.640.89–3.010.610.49–0.77Gastrointestinal dysfunction Anorexia Nausea Vomiting1.271.151.631.14–1.411.04–1.361.45–1.840.590.720.750.45–0.770.57–0.910.69–0.80Pain Pain migration Pain progression Direct tenderness Indirect tenderness Psoas sign Rebound Percussion tenderness Guarding Rigidity2.061.391.292.472.311.992.862.482.961.63–2.601.29–1.501.06–1.571.38–4.431.36–3.911.61–2.451.95–4.211.60–3.842.43–3.590.520.460.250.710.850.390.490.570.860.40–0.690.27–0.770.12–0.530.65–0.770.76–0.950.32–0.480.37–0.630.48–0.680.72–1.02Temperature (degrees centigrade) >37.7 >38.51.571.870.90–2.760.66–5.320.650.890.31–1.360.71–1.12White blood cells (109/L) ≥10 ≥154.207.202.11–8.354.31–12.000.200.660.10–0.410.56–0.78C-reactive protein (mg/L) >10 >201.972.391.58–2.451.67–3.410.320.470.20–0.510.28–0.81Conclusions: Individually, disease history, clinical findings, and laboratory tests are weak. But when combined, they yield high discriminatory power.Data from Andersson RE: Meta-analysis of the clinical and laboratory diagnosis of appendicitis, Br J Surg. 2004 Jan;91(1):28-37.wall thickening (greater than 2 mm), periappendiceal fat stranding, appendiceal wall thickening, and/or an appendicolith (Fig. 30-1). While there remains a concern of ionizing radia-tion exposure with a CT scan, typical low-dose CT scans result in exposure of 2 to 4 mSv, which is not significantly higher than background radiation (3.1 mSv).18 Recent trials have also suggested that although low-dose CT scans of 2 mSv do not generate high-resolution images, using these lower resolution images does not affect clinical outcomes.19 Intravenous contrast is generally preferred in these studies, but it can be avoided in patients with allergies or low estimated glomerular filtration rate (less than 30 mL/minute for 1.73 m2). Several meta-analyses have suggested that CT scan is more sensitive and specific than ultrasound in diagnosing appendicitis.Ultrasound. Ultrasonography has a sensitivity of 0.85 (95% CI 0.79–0.90) and a specificity of 0.90 (95% CI 0.83–0.95).20 Graded compression ultrasonography is used to identify the anteroposterior diameter of the appendix. An easily compressible appendix <5 mm in diameter generally rules out appendicitis. Features on an ultrasound that suggest appendicitis include a diameter of greater than 6 mm, pain with compression, presence of an appendicolith, increased echogenicity of the fat, and periappendiceal fluid.21 Ultrasound is cheaper and more readily available than CT scan, and it does not expose patients to ionizing radiation, but it is user-dependent and has limited util-ity in obese patients. In addition, graded compression is usually Figure 30-1. McBurney’s point. 1 = anterior superior iliac spine; 2 = umbilicus; x = McBurney’s point.Brunicardi_Ch30_p1331-p1344.indd 133301/03/19 7:05 PM 1334SPECIFIC CONSIDERATIONSPART IITable 30-2Meta-analyses comparing CT scan and US outcomes    AUTHORSUMMARYTERASAWAWESTONDORIAAL-KHAYALVAN RANDENYear 20042005200620072008 No. of studies 222157256 No. of patientsCTUSTotal117215162688NRNR5039NRNR13697NRNR13046NRNR671 SensitivityCTUS94% (CI: 91%–95%)86% (CI: 83%–88%)97% (CI: 95%–98%)87% (CI: 85%–89%)94% (CI: 92%–97%)88% (CI: 86%–90%)93% (CI: 92%–95%)84% (CI: 82%–85%)91% (CI: 84%–95%)78% (CI: 67%–86%)CT more sensitive than US in five of five meta-analysesSpecificityCTUS95% (CI: 93%–96%)81% (CI: 78%–84%)95% (CI: 93%–96%)93% (CI: 92%–94%)94% (CI: 94%–96%)93% (CI: 90%–96%)93 (CI: 92%–94%)96 (CI: 95%–96%)90% (CI: 85%–94%)83% (CI: 76%–88%)CT more specific than US in four of five meta-analysesPositive predictive valueCTUSNRNR94% (CI: 92%–95%)89% (CI: 87%–90%)NRNR90% (CI: 89%–92%)90% (CI: 89%–91%)NRNRCT has superior positive predictive value in one of two meta-analysesNegative predictive valueCTUSNRNR97% (CI: 96%–98%)92% (CI:91%–93%)NRNR96% (CI: 95%–97%)93% (CI: 92%–94%)NRNRCT has superior negative predictive value in both meta-analysesAccuracyCTUSNRNRNRNRNRNR94% (CI: 93%–94%)92% (CI: 92%–96%)NRNRCT is more accurate in the one study reporting resultsCI = confidence interval; CT = computed tomography; NR = not reported; US = ultrasonography.Brunicardi_Ch30_p1331-p1344.indd 133401/03/19 7:05 PM 1335THE APPENDIXCHAPTER 30painful for patients with peritonitis. A comparison of the effi-cacy of ultrasound v. CT scan is found in Table 30-2.MRI. MRI of the abdomen has a sensitivity of 0.95 (95% CI 0.88–0.98) and specificity of 0.92 (95% CI 0.87–0.95) for iden-tification of acute appendicitis.22 MRI is an expensive test that requires significant expertise to perform and interpret and is usually recommended in patients for whom the risk of ionizing radiation outweighs the relative ease of obtaining a contrast CT scan, i.e., pregnant or pediatric patients.Differential DiagnosisCauses of acute abdominal pain that are often confused with acute appendicitis include acute mesenteric adenitis, cecal diverticulitis, Meckel’s diverticulitis, acute ileitis, Crohn’s dis-ease, acute pelvic inflammatory disease, torsion of ovarian cyst or graafian follicle, and acute gastroenteritis. Frequently, no organic pathology is identified. Obtaining an antecedent history of a viral infection (mesenteric adenitis or gastroenteritis) and a cervical exam in women (exquisite tenderness with motion in pelvic inflammatory disease) are essential before planning any intervention. Detailed menstrual history can distinguish mittel-schmerz (no fever or leukocytosis, mid-menstrual cycle pain) and ectopic pregnancies.MANAGEMENT OF APPENDICITISUncomplicated AppendicitisThe preferred approach to manage patients with uncomplicated appendicitis is an appendectomy. Several recent randomized trials and cohort studies have examined the role of nonopera-tive management of adult patients with appendicitis.23,24,25 In each of these well-designed studies with noninferiority as the endpoint, patients were randomized to either receiving antibiot-ics or undergoing an appendectomy, which was frequently per-formed open. A majority of the patients in the nonoperative arm received intravenous antibiotics for a short course followed by a course of a fluoroquinolone and metronidazole, or oral amoxi-cillin/clavulanic acid.23,26,27 Meta-analysis of the published data found that 26.5% of patients in the nonoperative group required an appendectomy within 1 year. In addition, the rate of adverse events following antibiotics therapy was higher (relative risk [RR] 3.18, 95% CI 1.63–6.21, P = 0.0007), and patients who recurred presented more frequently with complicated appen-dicitis (RR 2.52, 95% CI 1.17–5.43, P = 0.02).28,29 Currently, conservative management can be offered to informed patients using techniques of shared decision-making, but it is not the standard modality of management of appendicitis, except in patients with significant phobia of surgery.30 Societal costs and long-term implications of the conservative strategy have not yet been completely evaluated.Timing of Surgery. Emergent surgery is often performed in patients with appendicitis, but studies have evaluated the perfor-mance of urgent surgery (waiting less than 12 hours) in a semi-elective setting after administering antibiotics upon admission. The studies did not reveal any significant difference in outcomes, except for a slightly longer hospital stay in those undergoing urgent surgery.31-33 Currently, delaying surgery less than 12 hours is acceptable in patients with short duration of symptoms (less than 48 hours) and in nonperforated, nongangrenous appendicitis.Approach of Surgery. Numerous meta-analyses comparing laparoscopic to open appendectomy have demonstrated relative equivalence of the techniques, with laparoscopic appendec-tomy resulting in a shorter length of stay (LOS), faster return to work, and lower superficial wound infection rates, especially in obese patients.34,35 Open appendectomy results in shorter operative times and lower intra-abdominal infection rates.36 Costs of the two techniques are relatively similar because of the offset of costs in laparoscopic techniques by shorter LOS. In the United States, laparoscopic appendectomies are increas-ingly utilized.37Complicated AppendicitisPerforated and gangrenous appendicitis and appendicitis with abscess or phlegmon formation are considered complicated conditions. Patients with perforated appendicitis usually pres-ent after 24 hours of onset, although 20% of patients present within 24 hours. Such patients are often acutely ill and dehy-drated and require resuscitation. Usually, the perforated abscess is walled off in the right lower quadrant, although retroperito-neal abscesses including psoas abscess, liver abscesses, fistu-las, and pylephlebitis (portal vein inflammation) can also occur when left untreated.Perforated appendicitis can be managed either operatively or nonoperatively. Immediate surgery is necessary in patients that appear septic, but this is usually associated with higher complications, including abscesses and enterocuta-neous fistulae due to dense adhesions and inflammation. The management of long-duration, complicated appendici-tis is often staged.38,39 Patients are resuscitated and treated with IV antibiotics.40,41 Patients with longstanding perforation are better treated with adequate percutaneous image-guided drain-age.42 This strategy is successful in 79% of patients who achieve complete resolution, which occurs more often in lower-grade abscesses, transgluteal drainage, and with CT(vs. ultrasound-) guided drainage43 Operative intervention is performed in patients who fail conservative management and in patients with free intra-peritoneal perforation.Interval Appendectomy. The majority of patients with perfo-rated appendicitis (80%) have resolution of their symptoms with drainage and antibiotics. There remains debate about the value of performing an interval appendectomy 6 to 8 weeks after the original inflammatory episode.44-46 Proponents of this approach cite the incidence of recurrent appendicitis (7.4%–8.8%) and the presence of appendiceal neoplasms detected on the appendec-tomy (relevant benign lesions 0.7%, malignant lesions 1.3%).47 Opponents cite the high incidence of no future events after a median follow-up of 34 months in 91% of patients. Currently, shared decision-making is necessary before proceeding with an interval appendectomy.39OPERATIVE INTERVENTIONPreoperative PreparationOnce the decision to proceed with surgical intervention is made, patients can be taken to the operating room rather expeditiously. While resuscitative efforts are important in patients who pres-ent with significant dehydration or in a compromised host, the majority of patients can be taken to the operating room within a short interval. Placement of a Foley catheter is optional but not necessary while performing an appendectomy. Preopera-tive antibiotics must be administered at least 30 to 60 minutes prior to skin incision. The choice of antibiotics include cefoxi-tin, ampicillin/sulbactam, and cefazolin plus metronidazole for 4Brunicardi_Ch30_p1331-p1344.indd 133501/03/19 7:05 PM 1336SPECIFIC CONSIDERATIONSPART IIuncomplicated appendicitis. Patients with ß-lactam allergies can be given clindamycin in combination with a fluoroquinolone, gentamicin, or aztreonam. Postoperative antibiotics are usually not necessary.In patients with perforated appendicitis undergoing opera-tive intervention, preoperative antibiotics are necessary to cover gram-negative bacteria and anaerobes. Monotherapy with piper-acillin/tazobactam or combination of cephalosporin with metro-nidazole are reasonable choices. The duration of postoperative antibiotics is generally less than 4 days once complete source control has been achieved (STOP-IT trial).48 Patients with incomplete drainage, persistent catheters, complications from surgery, and uncertain resolution of inflammation might need a longer duration of antibiotics.49Operative TechniqueOpen Appendectomy. An open appendectomy is usually per-formed under general anesthesia, although regional anesthesia can be used. After wide prep and drape, an incision is usually made on McBurney’s point either in an oblique fashion (McBur-ney’s incision) or transverse incision (Rocky-Davis incision). A lower midline laparotomy incision is more appropriate for perforated appendicitis with a phlegmon. A muscle-splitting approach can be utilized to access the peritoneum in patients that are well paralyzed. The bed is positioned in Trendelen-burg’s with the left side down. The appendix is usually readily identified, but if necessary, it can be found by tracing the ante-rior taenia (taenia Liberia) of the cecum distally. We generally ligate the mesentery early to allow better exposure. If the base of the appendix is viable, ligating the appendix is acceptable. This can be imbricated with a Z-stitch or purse string configura-tion, or alternatively the mucosa can be fulgurated. In the event of retraction of the appendiceal artery or unexpected bleeding, the incision can be extended medially (Fowler extension). Skin closure is usually performed in a layered fashion, but in cases with significant abscess or contamination, closure by sec-ondary intention or delayed primary closure has been consid-ered. Recent trials have suggested no difference in surgical site infection rates between primary and delayed primary closure.50 Placement of surgical drains has not been proven to be benefi-cial in multiple clinical trials for either complicated or uncom-plicated appendicitis.51,52Laparoscopic Appendectomy. Patients undergoing laparo-scopic appendectomy are positioned supine with the left arm tucked for better access. Monitors and assistants are positioned appropriately. Access to the peritoneum can be obtained using either the Hasson technique in a periumbilical fashion or with a Verees or optical trocar in the left upper quadrant 3 cm below the costal margin in the midclavicular line. Five-mm ports are usually placed in the suprapubic and left lower quadrant areas. It is also technically feasible to place the third port in the right upper quadrant. The bed is positioned in Trendelenburg, with the left side down to sweep the bowel away. The appendix is grasped and elevated upwards to identify the window between the mesoappendix and the cecum (Fig. 30-2). Occasionally, it is essential to release the mesenteric attachments of the cecum to mobilize a retrocecal or pelvic appendix to obtain this view. Using a Maryland grasper, the window is created, and the mesoappendix is divided with cautery, clip, or a bipolar energy source. The base of the appendix is divided either with an endoscopic stapler or after placing an endoloop. In the case of a nonviable appendix base, a staple line through the cecum that avoids the ileocecal valve might be sufficient, unless sig-nificant inflammation is present. The appendix is retrieved through the midline port in a specimen bag, especially if an appendiceal lesion is suspected. If a periappendiceal phlegmon is encountered or if the operation is being performed for perfo-rated appendicitis, careful sweeping of the bowel with a blunt dissector can release the appendix. It is important to carefully separate adjacent bowel, which can be friable in such settings. Conversion to open surgery should be considered for failure to progress. Typically, once the base of the appendix is identified, it is generally more helpful to divide the stump first. An endo-scopic stapler or endoloop can be used for the base, provided the base is viable. Occasionally, an ileocecectomy is necessary when resection of the base of the appendix or cecum is likely to impinge on the ileocecal valve. The mesoappendix is similarly divided with either a stapler with thin leg length staples, a clip, cautery, or energy device.Novel TechniquesThree novel techniques have been investigated in the performance of an appendectomy: single incision appendectomy, natural orifice transluminal endoscopic surgery (NOTES), and robotic appendec-tomy. Single incision appendectomy has not been shown to improve outcomes, including cosmetic outcomes, in pro-spective randomized studies and has been suggested to have a higher incisional hernia rate.53 NOTES surgery has been shown to have better cosmetic outcome and less postoperative pain in a meta-analysis of NOTES procedures including appendectomies, although only 40 patients were included in the analysis.54 The risk of luminal contamination and closure of enteral or vaginal mucosa remain suboptimal; for this reason, there has not been widespread dissemination of this technique.55 Robotic appendectomy allows flexible motions of intraperitoneal instruments and is therefore superior in ergonomics for the surgeon.56 However, it is extremely expensive and requires larger ports based on most of the current platforms; thus, this technique is also not utilized widely.Negative ExplorationUpon performing a laparoscopy or laparotomy for suspected appendicitis, if one finds no evidence of appendicitis, a thor-ough exploration of the peritoneum must be performed to rule out contributing pathology. A normal appendix is often removed to reduce future diagnostic dilemma.57 Management of incidentally found common conditions is summarized in Table 30-3.Incidental AppendectomyThe practice of prophylactic appendectomy has been considered during other operations to prevent the future risk of appendici-tis.6,58 It is routinely performed in children undergoing chemo-therapy, compromised hosts with an unclear physical exam, patients with Crohn’s disease with a normal cecum, patients traveling to remote places with no urgent care, and in patients undergoing cytoreductive operations for ovarian malignancies.59 While there is no evidence clearly evaluating long-term out-comes of patients undergoing incidental appendectomy with an asymptomatic appendix, the risk of adhesions and future complications after an appendectomy has been suggested to be higher than the risk of future appendicitis and increased economic costs. For these reasons, an incidental appendectomy is currently not advocated. 56Brunicardi_Ch30_p1331-p1344.indd 133601/03/19 7:05 PM 1337THE APPENDIXCHAPTER 30SurgeonAssistantAnesthesiologistFigure 30-2. Operating room setup.SPECIAL CIRCUMSTANCESAppendicitis in ChildrenAlmost 1 in 8 children undergo a workup for the diagnosis of appendicitis.60,61 Of these, infants and young children are most likely to present with perforated disease (51%–100%), while school-age children have lower rates of perforation.62,63,64 While most age groups demonstrate the same symptoms previously described in adults, neonates can also present with abdominal distension and lethargy or irritability. The Pediatric Appendici-tis Score has components similar to the Alvarado Score and is scored of 10 points, with maximum weight (2 points each) for right lower quadrant tenderness and pain with cough, percussion or hopping. A score of 7 or greater indicates that the patient has a high chance of having appendicitis (78%–96% percent).65In the pediatric population, special considerations must be made to exclude relevant differential diagnoses such as intus-susception (currant jelly stools, abdominal mass), gastroenteritis (often no luekocytosis), malrotation (pain out of proportion), pregnancy (ectopic), mesenteric adenitis, torsion of the omen-tum, and ovarian or testicular torsion.Table 30-3Management of Intraoperative Findings Mimicking AppendicitisOvarian TorsionConservative management with detorsion and oophoropexyCrohn’s terminal ileitisAppendectomy if base uninflamedMeckel’s diverticulitisSegmental small bowel resection and primary anastomosisAppendiceal MassLaparoscopic appendectomy/ileocecectomy without capsular disruption or spillage and retrieval in a bagBrunicardi_Ch30_p1331-p1344.indd 133701/03/19 7:05 PM 1338SPECIFIC CONSIDERATIONSPART IIWith regard to the management of children with appen-dicitis, early appendicitis is treated preferably with a laparo-scopic appendectomy, which has better outcomes than open appendectomies in children.66,67 For patients with complicated appendicitis, urgent appendectomy is advocated in the setting of no abscess or mass. Laparoscopic appendectomy appears to retain its benefits in this setting as well.68,69 In the setting of a perforation, antibiotics are continued after surgery for at least 3 days, and preferably 5 days (APSA guidelines).70,71 Manage-ment of perforated appendicitis with abscess is similar to adults, although no adverse effects of an early laparoscopic appendec-tomy have been seen even in this setting.39,72,73,74Nonoperative management of appendicitis has also been studied in children.75-77 It may be safe for children with early presentation (less than 48 hours), limited inflammation (WBC less than 18,000/cu.ml), appendicoliths, and no evidence of rup-ture on imaging.78 Patients are usually administered IV antibi-otics until inflammation reduces and then transitioned to oral antibiotics.79 This is usually effective in reducing inflammation (88%–92%), but has a recurrence rate of 22% at 1 year and increased resource utilization.80Appendicitis in Older AdultsOlder adult patients can have diminished inflammation and thus present with perforation or abscess more frequently.81,82 Such patients are at a higher risk for complications because of their premorbid conditions, and it is more prudent to obtain definitive diagnostic imaging prior to taking patients to the operating room. Laparoscopic appendectomy is safe and might allow patients to reduce pain and their hospital stay.83 Appendicitis in PregnancyAppendicitis occurs in 1 in 800 to 1 in 1000 pregnancies, mostly in the first and second trimesters. Its incidence is rare in the antepartum state, and it can occur in the postpartum state in geriatric pregnancies (maternal age greater than 35 years).84 While the majority of the clinical features are similar, patients can also present with heartburn, bowel irregularity, flatulence, or a change in bowel habits. The point of maximum tender-ness is usually displaced on physical exam. Ultrasonography is the preferred imaging modality, although nonvisualization can occur. Sensitivity can vary from 67% to 100%, and specificity varies from 93% to 96%.39 An alternative imaging modality is MRI, with a sensitivity of 94% and specificity of 97%.85 While CT can be performed in pregnancy, the risk of fetal irradiation leads many practitioners to avoid it unless other modalities are inconclusive.86 When discussing options with the patient and the patient’s family, it is important to note that the risk of fetal loss is up to 36% if appendiceal perforation occurs.87 Therefore, there remains a lower threshold to operate on such patients, with an acceptable negative exploration rate of as high as 30%. Lapa-roscopic appendectomies can be safely performed in pregnant patients, although studies suggest a variable but reproducible higher rate of fetal loss (around 7% vs. 3%) than open tech-niques. Lower intra-abdominal pressures (10–12 mmHg) during insufflation have been suggested to reduce early labor. Nonoper-ative management has also been proposed for pregnant patients, but treatment failure rates have been reported as high as 25%.Chronic or Recurrent AppendicitisPatients with recurrent right lower quadrant abdominal pain not associated with a febrile illness with imaging findings sugges-tive of an appendicolith or dilated appendix are classified as having chronic appendicitis.88 Patients often report resolution of symptoms with an appendectomy. In the absence of imaging abnormalities, prophylactic appendectomy is not encouraged.45OUTCOMES AND POSTOPERATIVE COURSEAppendectomy is a relatively safe procedure with an extremely low mortality rate (less than 1%). The commonest adverse events include soft tissue infections, either superficial or deep (including abscesses). Patients with uncomplicated appendicitis do not require further antibiotics after an appendec-tomy, while patients with perforated appendicitis are treated with 3 to 7 days of antibiotics (4 days from the STOP-IT trial).89 Patients with wound infections can be managed with simple wound opening and packing, and delayed primary closure has not been shown to be beneficial.90 In laparoscopic cases, these are usually the periumbilical ports.91 Patients with deep space abscesses are managed with percutaneous drainage and antibiot-ics. Fistulas (appendicocutaneous or appendicovesicular) are managed conservatively as the first step. Bowel obstructions and infertility are infrequent but reported.Stump AppendicitisAn uncommon complication after surgery is the development of appendicitis in an incompletely excised appendiceal stump (greater than 0.5 cm stump length). Optimal management requires reexcision of the appendiceal base, but diagnosis can be difficult and requires careful assessment of the patient’s history, physical exam, and imaging studies.92 Use of the “appendiceal critical view” (appendix placed at 10 o’clock, taenia coli/libera at 3 o’clock, and terminal ileum at 6 o’clock) and identification of where the taeniae coli merge and disappear is paramount to identifying and ligating the base of the appendix during the ini-tial operation (Fig. 30-3). In patients who have had prior appen-dectomy, a low index of suspicion is important to prevent delay in diagnosis and complications. Prior appendectomy should not be an absolute criterion in ruling out acute appendicitis.Appendiceal NeoplasmsThe incidence of appendiceal neoplasms is estimated at around 1% of all appendectomy specimens, although the true incidence of appendiceal neoplasms is not known.93 Neoplasms that occur in the appendix are predominantly gastroenteropancreatic neu-roendocrine tumors (or GEP-NETs, previously called carci-noids), mucinous neoplasms, or adenocarcinomas.94-96 Almost one-third of the neoplasms of the appendix present with acute appendicitis, while the others are often incidentally detected or are detected after regional spread of disease.97Gastroenteropancreatic Neuroendocrine Tumors (GEP-NETs or Carcinoid)Appendiceal carcinoid tumors are submucosal rubbery masses that are detected incidentally on the appendix.98 Carcinoid tumors of the appendix are relatively indolent but can develop nodal or hepatic metastases.99 Infrequently, these can be associ-ated with a carcinoid syndrome if there are hepatic metastases (2.9%).100 Upon incidental findings of a suspected carcinoid, the surgeon must evaluate the nodal basin along the ileocolic ped-icle and also examine the liver for any signs of metastases. For lesions that are less than 1 cm (95% of all lesions), a negative margin appendectomy is adequate. For tumors 2 cm or larger, a right hemicolectomy is recommended. For lesions 1 to 2 cm in size, there is no consensus on a completion colectomy. A right colectomy is often performed for mesenteric invasion, enlarged 78Brunicardi_Ch30_p1331-p1344.indd 133801/03/19 7:05 PM 1339THE APPENDIXCHAPTER 30Figure 30-3. A and B. Appendiceal critical view.ABnodes, or positive or unclear margins. Measurement of serum chromogranin A is recommended.Goblet Cell CarcinomasThese lesions were mistakenly called goblet cell carcinoids, implying a rather indolent biology, while goblet cell carcinomas are adenocarcinoid with both adenocarcinoma and neuroendocrine features.101,102 Such lesions carry a worse prognosis than carcinoids but slightly better than adenocarcinomas. There is a high risk of peritoneal recurrence in such cases. For incidentally detected lesions, a systematic surveillance of the peritoneum must be per-formed, and a peritoneal cancer index score must be documented if disease is present.103 In the absence of metastatic disease, a right hemicolectomy is generally appropriate, although some advocate for a right colectomy only for tumors 2 cm or larger.104LymphomasAppendiceal lymphomas are rare (1%–3% of lymphomas, usu-ally non-Hodgkin’s) and difficult to diagnose preoperatively (appendiceal diameter can be 2.5 cm or larger).105,106 Manage-ment includes an appendectomy in most cases.AdenocarcinomaPrimary adenocarcinoma of the appendix is a rare neoplasm with three major histologic subtypes: mucinous adenocarcinoma, colonic adenocarcinoma, and adenocarcinoid. The most common mode of presentation for appendiceal carcinoma is acute appendicitis. Patients also may present with ascites or a palpable mass, or the neoplasm may be discovered during an operative procedure for an unrelated cause. The recommended treatment for all patients with adenocarcinoma of the appendix is a formal right hemicolectomy. Appendiceal adenocarcinomas have a propensity for early perforation, although they are not clearly associated with a worsened prognosis. Overall 5-year sur-vival is 55% and varies with stage and grade. Patients with appendiceal adenocarcinoma are at significant risk for both syn-chronous and metachronous neoplasms, approximately half of which will originate from the gastrointestinal tract.Appendiceal Mucoceles and Mucinous Neoplasms of the AppendixThe term appendiceal mucocele broadly describes a mucus-filled appendix that could be secondary to neoplastic or nonneoplastic 9pathologies (mucosal hyperplasia, simple or retention cysts, mucinous cystadenomas, mucinous cystadenocarcinoma). The most common form of presentation is incidental; however, pre-sentation with appendicitis occurs in a third of cases.107,108 On cross-sectional imaging, a low attenuation, round, well encapsu-lated cystic mass in the right or quadrant is often encountered, and features such as wall irregularity and soft tissue thickening are suggestive of a neoplastic process. It is important to carefully assess for the presence of ascites, peritoneal disease, and scal-loping of the liver surface on imaging upon initial evaluation. A reliable diagnosis cannot be established using imaging alone, and it is recommended that surgical excision without capsular disruption is undertaken.109 The importance of careful handling of a mucocele and the avoidance of rupture cannot be overem-phasized because the intraperitoneal spread of neoplastic cells at subsequent development of pseudomyxoma peritonei are nearly certain in cases of adenocarcinoma.110,111 When suspecting a mucinous neoplasm of the appendix, it is imperative to systemat-ically examine the peritoneum and document a peritoneal cancer index score if mucin is present. Biopsies to examine the content of epithelial cell, neoplastic cells, and mucin can be helpful.In cases where a homogeneous cyst without nodularity or signs of dissemination is encountered, laparoscopic excision is acceptable, provided that a stapler is fired across the base of the cecum to avoid a positive margin. The specimen should be placed in a plastic bag and carefully removed through a small incision. In the absence of mesenteric or peritoneal involvement, an appendectomy with concurrent appendiceal lymphadenec-tomy is sufficient, as the chances of lymph node involvement are quite low. If peritoneal spread is evident upon exploration, it is important to obtain biopsies and document the peritoneal dis-ease burden. An appendectomy is acceptable if the patient has acute appendicitis, but suboptimal debulking is discouraged. In addition, colorectal, ovarian, and endometrial cancers can coex-ist in the setting of appendiceal mucoceles, and careful examina-tion of intra-abdominal structures is important.When there is discordance between the primary lesion histology and the peritoneum, the peritoneal histology is usu-ally given priority. For instance, if patients had a neoplasm in the appendix but adenocarcinoma in the peritoneum, the patient would be considered as having adenocarcinoma (AJCC M1b) disease. The recent AJCC 8th edition and the PSOGI 2016 Brunicardi_Ch30_p1331-p1344.indd 133901/03/19 7:05 PM 1340SPECIFIC CONSIDERATIONSPART IITable 30-4AJCC 8th edition and the PSOGI 2016 classification consensus of mucinous neoplasia of the appendixLESIONPERITONEAL DISEASE AT DIAGNOSISPROGNOSISTREATMENTLow-grade appendiceal mucinous neoplasm (LAMN)Confined to the appendixExcellent-curativeNegative margin appendectomy, rarely need ileocecectomyLAMNPeri-appendiceal Acellular mucin dissecting through the wall (t4a) or adjacent organs (t4b)Excellent-low risk of recurrenceNegative margin appendectomy, resection of acellular mucinLAMNPeri-appendiceal Epithelial cells dissecting through the wall (t4a) or adjacent organs (t4b)Excellent-high risk of recurrenceNegative margin appendectomy, peritoneal surveillance with second look laparoscopy vs. HIPECLAMNDistant epithelial cells or acellular mucin (M1a)Low grade mucinous carcinoma peritoneiExcellent-high risk of recurrenceNegative margin appendectomy, omentectomy, HIPECHigh-grade appendiceal mucinous neoplasm (HAMN-rare)Management is identical to a LAMN with risk stratification as shown above but slightly worse prognosis.Mucinous adenocarcinomaConfined to the appendixVery GoodRight hemicolectomyMucinous adenocarcinomaPeritoneal DisseminationHigh grade mucinous carcinoma peritonei with or without signet ring cellsWell Differentiated-Very goodModerately differentiated –GoodPoorly differentiated/signet ring cell histology:10 year survival of 10-20%Cytoreductive surgery and HIPEC, with systemic chemotherapy for high grade histologiesAdenocarcinoma (non-mucinous, including goblet cell histology)Management identical to the mucinous histologies, with more extensive use of systemic chemotherapySerrated Adenoma (rare)Confined to appendixExcellent-curativeAppendectomyAdenoma (rare)Confined to appendixExcellent-curativeAppendectomyData from American College of Surgeons. Amin MB, Edge SB, Greene FL, et al. (Eds.) AJCC Cancer Staging Manual, 8th Ed. Springer New York, 2017 and Carr NJ, Cecil TD, Mohamed F, et al: A Consensus for Classification and Pathologic Reporting of Pseudomyxoma Peritonei and Associated Appendiceal Neoplasia: The Results of the Peritoneal Surface Oncology Group International (PSOGI) Modified Delphi Process, Am J Surg Pathol. 2016 Jan;40(1):14-26.classification consensus has resulted in a therapy-directed clas-sification of mucinous neoplasms of the appendix, summarized in Table 30-4.112Pseudomyxoma Peritonei SyndromePatients with appendiceal mucinous neoplasms develop perito-neal dissemination leading to pseudomyxoma peritonei (PMP) syndrome. This can occur in gastric, ovarian, pancreatic, and colorectal primary tumors as well.111 Patients with this syn-drome can have varied prognosis ranging from curative to pal-liative. Cytoreductive surgery and hyperthermic intraperitoneal chemotherapy (HIPEC) are considered the standard of care for patients with PMP syndrome from appendiceal primaries.113-115Early detection and management of limited peritoneal dis-ease is favorable and preferred as opposed to extensive intra-peritoneal mucin development. The surgical technique involves parietal and visceral peritonectomies, and intraperitoneal administration of heated (42oC [108oF]) chemotherapy (usually mitomycin) in the abdomen. Previously considered a morbid surgery, high volume centers and standardized practices have made the morbidity and mortality similar to any major open GI procedure. This technique can also be performed laparoscopi-cally when the disease is detected early and is low volume.REFERENCESEntries highlighted in bright blue are key references. 1. Amyand C. Of an inguinal rupture, with a pin in the appendix coeci, incrusted with stone; and some observations on wounds in the guts. Phil Trans. 1735;39:329-342. 2. McBurney C. Experience with early operative interference in cases of disease of the vermiform appendix. N Y State Med J. 1889;50:6 and Clostridium difficile colitis: relationships revealed by clinical observations and immunology. World J Gastroenterol. 2013;19:5607-5614. 3. Mohammadi, M, Song, H, Cao, Y: Risk of lymphoid neo-plasms in a Swedish population-based cohort of 337,437 patients undergoing appendectomy. Scand J Gastroenterol 2016;51:583–589. 4. Sahami S, Kooij IA, Meijer SL, Van den Brink GR, Buskens CJ, Te Velde AA. The link between the appendix and ulcerative Brunicardi_Ch30_p1331-p1344.indd 134001/03/19 7:05 PM 1341THE APPENDIXCHAPTER 30colitis: clinical relevance and potential immunological mecha-nisms. Am J Gastroenterol. 2016;111(2):163-169. 5. Prystowsky JB, Pugh CM, Nagle AP. Current problems in sur-gery. Appendicitis. Curr Probl Surg. 2005;42:688-742. 6. Addiss DG, Shaffer N, Fowler BS, Tauxe RV. The epidemiol-ogy of appendicitis and appendectomy in the United States. Am J Epidemiol. 1990;132(5):910-925. 7. Song H, Abnet CC, Andrén-Sandberg A, Chaturvedi AK, Ye W. Risk of gastrointestinal cancers among patients with appendectomy: a large-scale Swedish register-based cohort study during 1970-2009. PLoS One. 2016;11(3):e0151262. 8. Birnbaum BA, Wilson SR. Appendicitis at the millennium. Radiology. 2000;215(2):337-348. 9. Burkitt DP. The aetiology of appendicitis. Br J Surg. 1971;58(9): 695-699. 10. Arnbjornsson E, Bengmark S. Obstruction of the appendix lumen in relation to pathogenesis of acute appendicitis. Acta Chir Scand. 1983;149(8):789-791. 11. Lau WY, Teoh-Chan CH, Fan ST, Yam WC, Lau KF, Wong SH. The bacteriology and septic complication of patients with appendicitis. Ann Surg. 1984;200(5):576-581. 12. Bennion RS, Baron EJ, Thompson JE Jr, et al. The bacteri-ology of gangrenous and perforated appendicitis—revisited. Ann Surg. 1990;211(2):165-171. 13. Andersson R, Hugander A, Thulin A, Nyström, Olaison G. Indications for operation in suspected appendicitis and inci-dence of perforation. BMJ. 1994;308(6921):107-110. 14. Andersson RE. Meta-analysis of the clinical and laboratory diagnosis of appendicitis. Br J Surg. 2004;91(1):28-37. 15. Acharya A, Markar SR, Ni M, Hanna GB. Biomarkers of acute appendicitis: systematic review and cost-benefit trade-off analysis. Surg Endosc. 2017;31(3):1022-1031. 16. Anderson SW, Soto JA, Lucey BC, et al. Abdominal 64-MDCT for suspected appendicitis: the use of oral and IV contrast material versus IV contrast material only. AJR Am J Roentgenol. 2009;193(5):1282-1288. 17. Smith MP, Katz DS, Lalani T, et al. ACR Appropriateness Criteria right lower quadrant pain—suspected appendicitis. Ultrasound Q. 2015;31(2):85-91. 18. Yun SJ, Ryu CW, Choi NY, Kim HC, Oh JY, Yang DM. Com-parison of lowand standard-dose CT for the diagnosis of acute appendicitis: a meta-analysis. AJR Am J Roentgenol. 2017;208(6):W198-W207. 19. LOCAT Group. Low-dose CT for the diagnosis of appendi-citis in adolescents and young adults (LOCAT): a pragmatic, multicentre, randomised controlled non-inferiority trial. Lancet Gastroenterol Hepatol. 2017;2(11):793-804. 20. Keyzer C, Zalcman M, De Maertelaer V, et al. Com-parison of US and unenhanced multi-detector row CT in patients suspected of having acute appendicitis. Radiology. 2005;236(2):527-534. 21. Kessler N, Cyteval C, Gallix B, et al. Appendicitis: evalu-ation of sensitivity, specificity, and predictive values of US, Doppler US, and laboratory findings. Radiology. 2004;230(2):472-478. 22. Barger RL Jr, Nandalur KR. Diagnostic performance of mag-netic resonance imaging in the detection of appendicitis in adults: a meta-analysis. Acad Radiol. 2010;17(10):1211-1216. 23. Vons C, Barry C, Maitre S, et al. Amoxicillin plus clavulanic acid versus appendicectomy for treatment of acute uncom-plicated appendicitis: an open-label, non-inferiority, ran-domised controlled trial. Lancet. 2011;377(9777):1573-1579. 24. Hansson J, Korner U, Khorram-Manesh A, Solberg A, Lundholm K. Randomized clinical trial of antibiotic therapy versus appendicectomy as primary treatment of acute appen-dicitis in unselected patients. Br J Surg. 2009;96(5):473-481. 25. Styrud J, Eriksson S, Nilsson I, et al. Appendectomy versus antibiotic treatment in acute appendicitis. a prospective multicenter randomized controlled trial. World J Surg. 2006;30(6):1033-1037. 26. Di Saverio S, Sibilio A, Giorgini E, et al. The NOTA Study (Non Operative Treatment for Acute Appendicitis): prospec-tive study on the efficacy and safety of antibiotics (amoxi-cillin and clavulanic acid) for treating patients with right lower quadrant abdominal pain and long-term follow-up of conservatively treated suspected appendicitis. Ann Surg. 2014;260(1):109-117. 27. Salminen P, Paajanen H, Rautio T, et al. Antibiotic therapy vs appendectomy for treatment of uncomplicated acute appendicitis: the APPAC randomized clinical trial. JAMA. 2015;313(23):2340-2348. 28. Harnoss JC, Zelienka I, Probst P, et al. Antibiotics versus surgical therapy for uncomplicated appendicitis: system-atic review and meta-analysis of controlled trials (PROS-PERO 2015: CRD42015016882). Ann Surg. 2017;265(5): 889-900. 29. Varadhan KK, Neal KR, Lobo DN. Safety and efficacy of antibiotics compared with appendicectomy for treatment of uncomplicated acute appendicitis: meta-analysis of ran-domised controlled trials. BMJ. 2012;344:e2156. 30. Sartelli M, Viale P, Catena F, et al. 2013 WSES guidelines for management of intra-abdominal infections. World J Emerg Surg. 2013;8(1):3. 31. Ingraham AM, Cohen ME, Bilimoria KY, et al. Effect of delay to operation on outcomes in adults with acute appendicitis. Arch Surg. 2010;145(9):886-892. 32. Abou-Nukta F, Bakhos C, Arroyo K, et al. Effects of delaying appendectomy for acute appendicitis for 12 to 24 hours. Arch Surg. 2006;141(5):504-506; discussion 506-507. 33. Stahlfeld K, Hower J, Homitsky S, Madden J. Is acute appen-dicitis a surgical emergency? Am Surg. 2007;73(6):626-629; discussion 629-630. 34. Katkhouda N, Mason RJ, Towfigh S, et al. Laparoscopic versus open appendectomy: a prospective randomized dou-ble-blind study. Ann Surg. 2005;242(3):439-448; discussion 448-450. 35. Enochsson L, Hellberg A, Rudberg C, et al. Laparoscopic vs open appendectomy in overweight patients. Surg Endosc. 2001;15(4):387-392. 36. Wei HB, Huang JL, Zheng ZH, et al. Laparoscopic versus open appendectomy: a prospective randomized comparison. Surg Endosc. 2010;24(2):266-2699. 37. Nguyen NT, Zainabadi K, Mavandadi S, et al. Trends in uti-lization and outcomes of laparoscopic versus open appendec-tomy. Am J Surg. 2004;188(6):813-820. 38. Simillis C, Symeonides P, Shorthouse AJ, Tekkis PP. A meta-analysis comparing conservative treatment versus acute appendectomy for complicated appendicitis (abscess or phleg-mon). Surgery. 2010;147(6):818-829. 39. Andersson RE, Petzold MG. Nonsurgical treatment of appen-diceal abscess or phlegmon: a systematic review and meta-analysis. Ann Surg. 2007;246(5):741-748. 40. Ciftci AO, Tanyel FC, Büyükpamukçu N, Hicsonmez A. Com-parative trial of four antibiotic combinations for perforated appendicitis in children. Eur J Surg. 1997;163(8):591-596. 41. Schropp KP, Kaplan S, Golladay ES, et al. A randomized clinical trial of ampicillin, gentamicin and clindamycin versus cefotaxime and clindamycin in children with ruptured appen-dicitis. Surg Gynecol Obstet. 1991;172(5):351-356. 42. Andersson RE. The natural history and traditional manage-ment of appendicitis revisited: spontaneous resolution and predominance of prehospital perforations imply that a correct diagnosis is more important than an early diagnosis. World J Surg. 2007;31(1):86-92. 43. St Peter SD, Aguayo P, Fraser JD, et al. Initial laparoscopic appendectomy versus initial nonoperative management Brunicardi_Ch30_p1331-p1344.indd 134101/03/19 7:05 PM 1342SPECIFIC CONSIDERATIONSPART IIand interval appendectomy for perforated appendicitis with abscess: a prospective, randomized trial. J Pediatr Surg. 2010;45(1):236-240. 44. Dixon MR, Haukoos JS, Park IU, et al. An assessment of the severity of recurrent appendicitis. Am J Surg. 2003;186: 718-722; discussion 722. 45. Lai HW, Loong CC, Chiu JH, Chau GY, Wu CW, Lui WY. Interval appendectomy after conservative treatment of an appendiceal mass. World J Surg. 2006;30(3):352-357. 46. Rashid A, Nazir S, Kakroo SM, Chalkoo MA, Razvi SA, Wani AA. Laparoscopic interval appendectomy versus open interval appendectomy: a prospective randomized controlled trial. Surg Laparosc Endosc Percutan Tech. 2013;23(1):93-96. 47. Wright GP, Mater ME, Carroll JT, Choy JS, Chung MH. Is there truly an oncologic indication for interval appendectomy? Am J Surg. 2015;209(3):442-446. 48. Sawyer RG, Claridge JA, Nathens AB, et al. Trial of short-course antimicrobial therapy for intraabdominal infection. N Engl J Med. 2015;372(21):1996-2005. 49. Solomkin JS, Mazuski JE, Bradley JS, et al. Diagnosis and management of complicated intra-abdominal infection in adults and children: guidelines by the Surgical Infection Society and the Infectious Diseases Society of America. Clin Infect Dis. 2010;50(2):133-164. 50. Siribumrungwong B, Chantip A, Noorit P, et al. Comparison of superficial surgical site infection between delayed primary versus primary wound closure in complicated appendicitis: a randomized controlled trial. Ann Surg. 2017;267(4):631-637. 51. Tander B, Pektas O, Bulut M. The utility of peritoneal drains in children with uncomplicated perforated appendicitis. Pediatr Surg Int. 2003;19:548-550. 52. Toki A, Ogura K, Horimi T, et al. Peritoneal lavage versus drainage for perforated appendicitis in children. Surg Today. 1995;25(3):207-210. 53. Ceci F, Orsini S, Tudisco A, et al. Single-incision laparoscopic appendectomy is comparable to conventional laparoscopic and laparotomic appendectomy: our single center single sur-geon experience. G Chir. 2013;34(7-8):216-219. 54. Coomber RS, Sodergren MH, Clark J, Teare J, Yang GZ, Darzi A. Natural orifice translumenal endoscopic surgery applications in clinical practice. World J Gastrointest Endosc. 2012;4(3):65-74. 55. Strickland AD, Norwood MG, Behnia-Willison F, Olakkengil SA, Hewett PJ. Transvaginal natural orifice translumenal endoscopic surgery (NOTES): a survey of women’s views on a new technique. Surg Endosc. 2010;24(10):2424-2431. 56. Akl MN, Magrina JF, Kho RM, Magtibay PM. Robotic appen-dectomy in gynaecological surgery: technique and pathologi-cal findings. Int J Med Robot. 2008;4(3):210-213. 57. Chiarugi M, Buccianti P, Decanini L, et al. “What you see is not what you get.” A plea to remove a ‘normal’ appendix during diagnostic laparoscopy. Acta Chir Belg. 2001;101(5):243-245. 58. Wang HT, Sax HC. Incidental appendectomy in the era of managed care and laparoscopy. J Am Coll Surg. 2001;192(2): 182-188. 59. Fisher KS, Ross DS. Guidelines for therapeutic deci-sion in incidental appendectomy. Surg Gynecol Obstet. 1990;171(1):95-98. 60. Scholer SJ, Pituch K, Orr DP, Dittus RS. Clinical outcomes of children with acute abdominal pain. Pediatrics. 1996;98(4 pt 1): 680-685. 61. Reynolds SL, Jaffe DM. Diagnosing abdominal pain in a pediatric emergency department. Pediatr Emerg Care. 1992;8(3):126-128. 62. Lee SL, Stark R, Yaghoubian A, Shekherdimian S, Kaji A. Does age affect the outcomes and management of pediatric appendicitis? J Pediatr Surg. 2011;46(12):2342-2345. 63. Rothrock SG, Pagane J. Acute appendicitis in children: emer-gency department diagnosis and management. Ann Emerg Med. 2000;36(1):39-51. 64. Colvin JM, Bachur R, Kharbanda A. The presentation of appendicitis in preadolescent children. Pediatr Emerg Care. 2007;23(12):849-855. 65. Bundy DG, Byerley JS, Liles EA, Perrin EM, Katznel-son J, Rice HE. Does this child have appendicitis? JAMA. 2007;298(4):438-451. 66. Bickell NA, Aufses AH Jr, Rojas M, Bodian C. How time affects the risk of rupture in appendicitis. J Am Coll Surg. 2006;202(3):401-406. 67. Nomura O, Ishiguro A, Maekawa T, Nagai A, Kuroda T, Sakai H. Antibiotic administration can be an independent risk factor for therapeutic delay of pediatric acute appendicitis. Pediatr Emerg Care. 2012;28(8):792-795. 68. Aziz O, Athanasiou T, Tekkis PP, et al. Laparoscopic versus open appendectomy in children: a meta-analysis. Ann Surg. 2006;243(1):17-27. 69. Sauerland S, Jaschinski T, Neugebauer EA. Laparoscopic ver-sus open surgery for suspected appendicitis. Cochrane Data-base Syst Rev. 2010;(10):CD001546. 70. Lee SL, Islam S, Cassidy LD, et al. Antibiotics and appendici-tis in the pediatric population: an American Pediatric Surgical Association Outcomes and Clinical Trials Committee system-atic review. J Pediatr Surg. 2010;45(11):2181-2185. 71. Chen C, Botelho C, Cooper A, Hibberd P, Parsons SK. Current practice patterns in the treatment of perforated appendicitis in children. J Am Coll Surg. 2003;196(2):212-221. 72. Bufo AJ, Shah RS, Li MH, et al. Interval appendectomy for perforated appendicitis in children. J Laparoendosc Adv Surg Tech A. 1998;8(4):209-214. 73. Weber TR, Keller MA, Bower RJ, Spinner G, Vierling K. Is delayed operative treatment worth the trouble with perforated appendicitis in children? Am J Surg. 2003;186(6):685-658; discussion 688-689. 74. Nadler EP, Reblock KK, Vaughan KG, Meza MP, Ford HR, Gaines BA. Predictors of outcome for children with perfo-rated appendicitis initially treated with non-operative manage-ment. Surg Infect (Larchmt). 2004;5(4):349-356. 75. Svensson JF, Patkova B, Almström M, et al. Nonoperative treatment with antibiotics versus surgery for acute nonperfo-rated appendicitis in children: a pilot randomized controlled trial. Ann Surg. 2015;261(1):67-71. 76. Ein SH, Langer JC, Daneman A. Nonoperative management of pediatric ruptured appendix with inflammatory mass or abscess: presence of an appendicolith predicts recurrent appendicitis. J Pediatr Surg. 2005;40(10):1612-1615. 77. Lopez ME, Wesson DE. Medical treatment of pediatric appen-dicitis: are we there yet? JAMA Pediatr. 2017;171(5):419-420. 78. Minneci PC, Mahida JB, Lodwick DL, et al. Effectiveness of patient choice in nonoperative vs surgical management of pediatric uncomplicated acute appendicitis. JAMA Surg. 2016;151(5):408-415. 79. Tanaka Y, Uchida H, Kawashima H, et al. Long-term out-comes of operative versus nonoperative treatment for uncom-plicated appendicitis. J Pediatr Surg. 2015;50(11):1893-1897. 80. Steiner Z, Buklan G, Stackievicz R, et al. Conservative treat-ment in uncomplicated acute appendicitis: reassessment of practice safety. Eur J Pediatr. 2017;176(4):521-527. 81. Sheu BF, Chiu TF, Chen JC, Tung MS, Chang MW, Young YR. Risk factors associated with perforated appendicitis in elderly patients presenting with signs and symptoms of acute appendicitis. ANZ J Surg. 2007;77(8):662-666. 82. Young YR, Chiu TF, Chen JC, et al. Acute appendicitis in the octogenarians and beyond: a comparison with younger geri-atric patients. Am J Med Sci. 2007;334(4):255-259.Brunicardi_Ch30_p1331-p1344.indd 134201/03/19 7:05 PM 1343THE APPENDIXCHAPTER 30 83. Harrell AG, Lincourt AE, Novitsky YW, et al. Advantages of laparoscopic appendectomy in the elderly. Am Surg. 2006;72(6):474-480. 84. Andersen B, Nielsen TF. Appendicitis in pregnancy: diag-nosis, management and complications. Acta Obstet Gynecol Scand. 1999;78(9):758-762. 85. Bree RL, Ralls PW, Balfe DM, et al. Evaluation of patients with acute right upper quadrant pain. American College of Radiology. ACR Appropriateness Criteria. Radiology. 2000;215(suppl):153-157. 86. McGory ML, Zingmond DS, Tillou A, Hiatt JR, Ko CY, Cryer HM. Negative appendectomy in pregnant women is associ-ated with a substantial risk of fetal loss. J Am Coll Surg. 2007;205(4):534-540. 87. Cohen-Kerem R, Railton C, Oren D, Lishner M, Koren G. Pregnancy outcome following non-obstetric surgical interven-tion. Am J Surg. 2005;190(3):467-473. 88. Giuliano V, Giuliano C, Pinto F, Scaglione M. Chronic appen-dicitis “syndrome” manifested by an appendicolith and thick-ened appendix presenting as chronic right lower abdominal pain in adults. Emerg Radiol. 2006;12(3):96-98. 89. Andersen BR, Kallehave FL, Andersen HK. Antibiotics versus placebo for prevention of postoperative infection after appen-dicectomy. Cochrane Database Syst Rev. 2003;(2):CD001439. 90. Rucinski J, Fabian T, Panagopoulos G, Schein M, Wise L. Gangrenous and perforated appendicitis: a meta-analytic study of 2532 patients indicates that the incision should be closed primarily. Surgery. 2000;127(2):136-141. 91. Fleming FJ, Kim MJ, Messing S, Gunzler D, Salloum R, Monson JR. Balancing the risk of postoperative surgical infec-tions: a multivariate analysis of factors associated with lapa-roscopic appendectomy from the NSQIP database. Ann Surg. 2010;252(6):895-900. 92. Liang MK, Lo HG, Marks JL. Stump appendicitis: a compre-hensive review of literature. Am Surg. 2006;72(2):162-166. 93. Connor SJ, Hanna GB, Frizelle FA. Appendiceal tumors: retrospective clinicopathologic analysis of appendiceal tumors from 7,970 appendectomies. Dis Colon Rectum. 1998;41(1):75-80. 94. Turaga KK, Pappas SG, Gamblin T. Importance of histologic subtype in the staging of appendiceal tumors. Ann Surg Oncol. 2012;19(5):1379-1385. 95. McGory ML, Maggard MA, Kang H, O’Connell JB, Ko CY. Malignancies of the appendix: beyond case series reports. Dis Colon Rectum. 2005;48(12):2264-2271. 96. Deans GT, Spence RA. Neoplastic lesions of the appendix. Br J Surg. 1995;82(3):299-306. 97. Rutledge RH, Alexander JW. Primary appendiceal malignan-cies: rare but important. Surgery. 1992;111(3):244-250. 98. Moertel CG, Dockerty MB, Judd ES. Carcinoid tumors of the vermiform appendix. Cancer. 1968;21(2):270-278. 99. Rorstad O. Prognostic indicators for carcinoid neuroen-docrine tumors of the gastrointestinal tract. J Surg Oncol. 2005;89(3):151-160. 100. Carr NJ, Sobin LH. Neuroendocrine tumors of the appendix. Semin Diagn Pathol. 2004;21(2):108-119. 101. Tang LH, Shia J, Soslow RA, et al. Pathologic classifi-cation and clinical behavior of the spectrum of goblet cell carcinoid tumors of the appendix. Am J Surg Pathol. 2008;32(10):1429-1443. 102. Pham TH, Wolff B, Abraham SC, Drelichman E. Surgical and chemotherapy treatment outcomes of goblet cell carci-noid: a tertiary cancer center experience. Ann Surg Oncol. 2006;13(3):370-376. 103. Yan TD, Brun EA, Sugarbaker PH. Discordant histology of primary appendiceal adenocarcinoid neoplasms with perito-neal dissemination. Ann Surg Oncol. 2008;15(5):1440-1446. 104. Varisco B, McAlvin B, Dias J, Franga D. Adenocarci-noid of the appendix: is right hemicolectomy necessary? A meta-analysis of retrospective chart reviews. Am Surg. 2004;70(7):593-599. 105. Crump M, Gospodarowicz M, Shepherd FA. Lymphoma of the gastrointestinal tract. Semin Oncol. 1999;26(3):324-337. 106. Pickhardt PJ, Levy AD, Rohrmann CA Jr, et al. Non-Hodg-kin’s lymphoma of the appendix: clinical and CT find-ings with pathologic correlation. AJR Am J Roentgenol. 2002;178(5):1123-1127. 107. Raijman I, Leong S, Hassaram S, Marcon NE. Appen-diceal mucocele: endoscopic appearance. Endoscopy. 1994;26(3):326-328. 108. Hamilton DL, Stormont JM. The volcano sign of appendiceal mucocele. Gastrointest Endosc. 1989;35(5):453-456. 109. Stocchi L, Wolff BG, Larson DR, Harrington JR. Sur-gical treatment of appendiceal mucocele. Arch Surg. 2003;138(6):585-589; discussion 589-590. 110. Smith JW, Kemeny N, Caldwell C, Banner P, Sigurdson E, Huvos A. Pseudomyxoma peritonei of appendiceal origin. The Memorial Sloan-Kettering Cancer Center experience. Cancer. 1992;70(2):396-401. 111. Hinson FL, Ambrose NS. Pseudomyxoma peritonei. Br J Surg. 1998;85(10):1332-1339. 112. Carr NJ, Cecil TD, Mohamed F, et al. A consensus for classi-fication and pathologic reporting of pseudomyxoma peritonei and associated appendiceal neoplasia: the results of the Peri-toneal Surface Oncology Group International (PSOGI) Modi-fied Delphi Process. Am J Surg Pathol. 2016;40(1):14-26. 113. Gough DB, Donohue JH, Schutt AJ, et al. Pseudomyxoma peritonei. Long-term patient survival with an aggressive regional approach. Ann Surg. 1994;219(2):112-119. 114. Stewart JHt, Shen P, Russell GB, et al. Appendiceal neoplasms with peritoneal dissemination: outcomes after cytoreductive surgery and intraperitoneal hyperthermic chemotherapy. Ann Surg Oncol. 2006;13(5):624-634. 115. Sugarbaker PH. New standard of care for appendiceal epi-thelial neoplasms and pseudomyxoma peritonei syndrome? Lancet Oncol. 2006;7(1):69-76.Brunicardi_Ch30_p1331-p1344.indd 134301/03/19 7:05 PM
Brunicardi_Ch30_p1331-p1344.indd 134401/03/19 7:05 PMThis page intentionally left blankLiverDavid A. Geller, John A. Goss, Ronald W. Busuttil, and Allan Tsung 31chapterHistory of Liver Surgery 1346Liver Anatomy 1346Segmental Anatomy / 1346Hepatic Artery / 1348Portal Vein / 1348Hepatic Veins and Inferior Vena Cava / 1349Bile Duct and Hepatic Ducts / 1350Neural Innervation and Lymphatic Drainage / 1350Liver Physiology 1351Bilirubin Metabolism / 1352Formation of Bile / 1352Drug Metabolism / 1352Liver Function Tests / 1352Hepatocellular Injury / 1353Abnormal Synthetic Function / 1353Cholestasis / 1353Jaundice / 1353Molecular Signaling Pathways  in the Liver 1354Acute Phase Reaction / 1354LPS Signaling / 1355Nitric Oxide / 1355Heme Oxygenase System / 1356Toll-Like Receptors / 1357Radiologic Evaluation of  the Liver 1357Ultrasound / 1357Computed Tomography / 1358Magnetic Resonance Imaging / 1359Positron Emission Tomography / 1360Acute Liver Failure 1360Etiology / 1361Clinical Presentation / 1361Diagnosis and Clinical Management / 1361Prognosis / 1362Liver Transplantation / 1362Emerging Technologies / 1362Cirrhosis and Portal  Hypertension 1362Morphologic Classification of Cirrhosis / 1362Etiology of Cirrhosis / 1363Clinical Manifestations of Cirrhosis / 1364Laboratory Findings Associated With Cirrhosis / 1364Liver Biopsy / 1364Hepatic Reserve and Assessment of Surgical Risk in the Cirrhotic Patient / 1365Child-Turcotte-Pugh Score / 1365Model for End-Stage Liver Disease Scoring System / 1365Portal Hypertension / 1365Imaging of the Portal Venous System and Measurement of Portal Venous Pressure / 1366Etiology and Clinical Features of Portal Hypertension / 1366Management of Gastroesophageal Varices / 1367Prevention of Variceal Bleeding / 1367Management of Acute Variceal Hemorrhage / 1367Luminal Tamponade / 1367Transjugular Intrahepatic Portosystemic Shunt / 1367Balloon-Occluded Retrograde Transvenous Obliteration / 1367Surgical Shunting / 1367Nonshunt Surgical Management of Refractory Variceal Bleeding / 1368Hepatic Transplantation / 1368Budd-Chiari Syndrome / 1368Infections of the Liver 1369Pyogenic Liver Abscesses / 1369Amebic Abscesses / 1369Hydatid Disease / 1370Ascariasis / 1371Schistosomiasis / 1371Viral Hepatitis / 1371Evaluation of an Incidental  Liver Mass 1372Hepatic Cysts 1373Congenital Cysts / 1373Biliary Cystadenoma / 1373Polycystic Liver Disease / 1373Caroli’s Disease / 1374Benign Liver Lesions 1374Cyst / 1374Hemangioma / 1375Adenoma / 1375Focal Nodular Hyperplasia / 1376Bile Duct Hamartoma / 1376Malignant Liver Tumors 1376Hepatocellular Carcinoma / 1376Cholangiocarcinoma / 1377Gallbladder Cancer / 1378Metastatic Colorectal Cancer / 1378Neuroendocrine Tumors / 1379Other Metastatic Tumors / 1379Treatment Options for  Liver Cancer 1379Hepatic Resection / 1379Liver Transplantation / 1380Radiofrequency Ablation / 1380Ethanol Ablation, Cryosurgery, and Microwave Ablation / 1380Chemoembolization and Hepatic Artery Pump Chemoperfusion / 1381Yttrium-90 Microspheres / 1381Stereotactic Radiosurgery and Intensity-Modulated Radiation Therapy / 1381Downstaging / 1381Systemic Chemotherapy / 1381Hepatic Resection Surgical  Techniques 1381Nomenclature / 1381Techniques and Devices for Dividing the Hepatic Parenchyma / 1382Steps in Commonly Performed Hepatic Resections / 1383Pringle and Ischemic Preconditioning / 1385Preoperative Portal Vein Embolization / 1385Staged Hepatectomy, ALPPS, and Repeat Hepatic Resection for Recurrent Liver Cancer / 1386Laparoscopic Liver Resection 1386Brunicardi_Ch31_p1345-p1392.indd 134520/02/19 2:36 PM 1346HISTORY OF LIVER SURGERYThe ancient Greek myth of Prometheus reminds us that the liver is the only organ that regenerates. According to Greek mythology, Zeus was furious with the Titan Prometheus because he gave fire to mortals. In return, Zeus chained Prometheus to Mount Caucasus and sent his giant eagle to eat his liver during the day, only to have it regenerate at night. Although this is folk-lore, the principles are correct that after hepatic resection, the remnant liver will hypertrophy over weeks to months to regain most of its original liver mass. It is interesting to note that the ancient Greeks seem to have been aware of this fact, because the Greek word for the liver, h¯epar, derives from the verb h¯epaomai, which means “mend” or “repair.” Hence h¯epar roughly translates as “repairable.”1 The importance of the liver dates back to even biblical times, for the Babylonians (c. 2000 b.c.) considered the liver to be the seat of the soul. There are scattered reports of liver surgery for battlefield injuries, but the first recorded elec-tive hepatic resection was done in 1888 in Germany by Langen-buch. There followed reports of liver resections in the United States (Tiffany, 1890) and Europe (Lucke, 1891), as well as the first large series of hepatic resections by Keen in 1899.2,3 In 1908, Pringle described in Annals of Surgery the “arrest of hepatic hemorrhage due to trauma” by compression of the porta hepatis, a maneuver that now bears his name.4 Possibly due to the potential for massive hemorrhage during liver surgery, very little progress in surgical techniques was recorded for the next half-century. Work by Rex, Cantlie, and others laid the groundwork for experimental and clinical reports in the 1950s by Couinaud, Hjortsjo, Healey, Lortat-Jacob, and Starzl.5,6 These seminal contributions paved the way for the modern era of hepatic resection surgery.LIVER ANATOMYThe liver is the largest organ in the body, weighing approxi-mately 1500 g. It resides in the right upper abdominal cavity beneath the diaphragm and is protected by the rib cage. It is reddish brown and is surrounded by a fibrous sheath known as Glisson’s capsule. The liver is held in place by several ligaments (Fig. 31-1). The round ligament is the remnant of the obliterated umbilical vein and enters the left liver hilum at the front edge of the falciform ligament. The falciform ligament separates the left lateral and left medial segments along the umbilical fissure and anchors the liver to the anterior abdominal wall. Deep in the plane between the caudate lobe and the left lateral segment is the fibrous ligamentum venosum (Arantius’ ligament), which is the obliterated ductus venosus and is covered by the plate of Arantius. The left and right triangular ligaments secure the two sides of the liver to the diaphragm. Extending from the trian-gular ligaments anteriorly on the liver are the coronary liga-ments. The right coronary ligament also extends from the right undersurface of the liver to the peritoneum overlying the right kidney, thereby anchoring the liver to the right retroperitoneum. These ligaments (round, falciform, triangular, and coronary) can be divided in a bloodless plane to fully mobilize the liver to facilitate hepatic resection. Centrally and just to the left of the gallbladder fossa, the liver attaches via the hepatoduodenal and the gastrohepatic ligaments (Fig. 31-2). The hepatoduodenal ligament is known as the porta hepatis and contains the com-mon bile duct, the hepatic artery, and the portal vein. From the right side and deep (dorsal) to the porta hepatis is the foramen of Winslow, also known as the epiploic foramen (see Fig. 31-2). This passage connects directly to the lesser sac and allows com-plete vascular inflow control to the liver when the hepatoduode-nal ligament is clamped using the Pringle maneuver.Segmental AnatomyThe liver is grossly separated into the right and left lobes by the plane from the gallbladder fossa to the inferior vena cava (IVC), known as Cantlie’s line.5 The right lobe typically accounts for 60% to 70% of the liver mass, with the left lobe (and caudate lobe) making up the remainder. The caudate lobe lies to the left and anterior of the IVC and contains three subsegments: Key Points1 When operating on the liver, gallbladder, pancreas, or adjacent organs, recognition of the normal or variant vas-cular and biliary anatomy is essential to avoiding surgical complications.2 The liver is the largest gland in the body and performs a diverse spectrum of functions.3 Computed tomography and magnetic resonance imaging with contrast enhancement constitute the mainstays for the radiologic evaluation of the liver.4 Acute liver failure rapidly progresses to hepatic coma and death even with maximal medical therapy. The only defin-itive treatment is orthotopic liver transplantation.5 Acute variceal bleeding should be managed with aggres-sive resuscitation and prompt endoscopic diagnosis with hemorrhage control. The transjugular intrahepatic por-tosystemic shunt procedure can be considered for cases refractory to medical treatment.6 Common benign lesions of the liver include cysts, hem-angiomas, focal nodular hyperplasia, and hepatocellular adenomas. In most instances, these lesions can be reliably diagnosed by their characteristic features on imaging.7 Many options exist for the treatment of hepatocellular car-cinomas, and these cases are best managed by a multidis-ciplinary liver transplant team.8 Surgical resection is the treatment of choice for hilar chol-angiocarcinoma. Under a protocol with strict eligibility criteria, patients with unresectable tumors can be con-sidered for liver transplantation following neoadjuvant chemoradiation, with survival rates that compare favorably with the rates for resection.9 The resectability of colorectal cancer metastases to the liver is primarily determined by the volume of the future liver remnant and the health of the background liver and not actual tumor number.10 Laparoscopic liver resections can be performed safely by experienced surgeons in selected patients and have been shown to produce short-term patient benefits with com-parable long-term oncologic results compared to open hepatic resections.Brunicardi_Ch31_p1345-p1392.indd 134620/02/19 2:36 PM 1347LIVERCHAPTER 31Figure 31-1. Hepatic ligaments suspending the liver to the diaphragm and anterior abdominal wall.Liver in situForamen ofWinslowGastrohepaticligamentOpen hepato-duodenal ligamentFigure 31-2. In situ liver hilar anatomy with hepatoduodenal and gastrohepatic ligaments. Foramen of Winslow is depicted.Right lobeLeft lobeRight lobeLeft lobeVIIIIVaIVbIIIIIVVIIVIIVCCaudate lobeIIIIVVIIVIIIIVbFigure 31-3. Couinaud’s liver segments (I through VIII) num-bered in a clockwise manner. The left lobe includes segments II to IV, the right lobe includes segments V to VIII, and the caudate lobe is segment I. IVC = inferior vena cava.the Spiegel lobe, the paracaval portion, and the caudate process.7 The falciform ligament does not separate the right and left lobes, but rather it divides the left lateral segment from the left medial segment. The left lateral and left medial segments also are referred to as sections as defined in the Brisbane 2000 terminology, which is outlined later in the section titled “Hepatic Resection.” A significant advance in our understanding of liver anatomy came from the cast work studies of the French surgeon and anatomist Couinaud in the early 1950s. Couinaud divided the liver into eight segments, numbering them in a clockwise direc-tion beginning with the caudate lobe as segment I.6 Segments II and III comprise the left lateral segment, and segment IV is the left medial segment (Fig. 31-3). Thus, the left lobe is made up of the left lateral segment (Couinaud’s segments II and III) and the left medial segment (segment IV). Segment IV can be subdivided into segment IVA and segment IVB. Segment IVA is cepha-lad and just below the diaphragm, spanning from segment VIII to the falciform ligament adjacent to segment II. Segment IVB is caudad and adjacent to the gallbladder fossa. Many anatomy textbooks also refer to segment IV as the quadrate lobe. Quadrate lobe is an outdated term, and the preferred term is segment IV or left medial segment. Most surgeons still refer to segment I as the DiaphragmRight triangularligamentLeft triangularligamentFalciformligamentRoundligamentcaudate lobe, rather than segment I. The right lobe is comprised of segments V, VI, VII, and VIII, with segments V and VIII mak-ing up the right anterior lobe and segments VI and VII making up the right posterior lobe.Brunicardi_Ch31_p1345-p1392.indd 134720/02/19 2:36 PM 1348SPECIFIC CONSIDERATIONSPART IIAdditional functional anatomy was highlighted by Bis-muth based on the distribution of the hepatic veins. The three hepatic veins run in corresponding scissura (fissures) and divide the liver into four sectors.8 The right hepatic vein runs along the right scissura and separates the right posterolateral sector from the right anterolateral sector. The main scissura contains the middle hepatic vein and separates the right and left livers. The left scissura contains the course of the left hepatic vein and separates the left posterior and left anterior sectors.Hepatic ArteryThe liver has a dual blood supply consisting of the hepatic artery and the portal vein. The hepatic artery delivers approximately 25% of the blood supply, and the portal vein approximately 75%. The hepatic artery arises from the celiac axis (trunk), which gives off the left gastric, splenic, and common hepatic arteries (Fig. 31-4). The common hepatic artery then divides into the gastroduodenal artery and the hepatic artery proper. The right gastric artery typically originates off of the hepatic artery proper, but this is variable. The hepatic artery proper divides into the right and left hepatic arteries. This “classic” or standard arterial anatomy is present in only approximately 76% of cases, with the remaining 24% having variable anatomy. It is critical to understand the arterial (and biliary) anatomic variants to avoid surgical complications when operating on the liver, gallbladder, pancreas, or adjacent organs.The most common hepatic arterial variants are shown in Fig. 31-5. Approximately 10% to 15% of the time there is a replaced or accessory right hepatic artery arising from the supe-rior mesenteric artery (SMA). When there is a replacement or accessory right hepatic artery, it travels posterior to the por-tal vein and then takes up a right lateral position before diving into the liver parenchyma. This can be recognized visually on a preoperative computed tomography (CT) or magnetic reso-nance imaging (MRI) scan and confirmed by palpation in the hilum where a separate right posterior pulsation is felt distinct from that of the hepatic artery proper that lies anteriorly in the hepatoduodenal ligament to the left of the common bile duct. In approximately 3% to 10% of cases, there exists a replace-ment (or accessory) left hepatic artery coming off of the left gastric artery and running obliquely in the gastrohepatic liga-ment anterior to the caudate lobe before entering the hilar plate at the base of the umbilical fissure. Other less common variants (approximately 1–2% each) are the presence of both replaced right and replaced left hepatic arteries, as well as a completely replaced common hepatic artery coming off the SMA (see Fig. 31-5). Although not well demonstrated in the illustration, the clue for a completely replaced common hepatic artery com-ing off the SMA is the presence of a strong arterial pulsation to the right of and posterior to the common bile duct, rather than the left side and anterior, in the porta hepatis. Another important point is that the right hepatic artery passes deep and posterior to the common bile duct approximately 88% of the time but crosses anterior to the common bile duct in approximately 12% of cases. The cystic artery feeding the gallbladder usually arises from the right hepatic artery in Calot’s triangle.Portal VeinThe portal vein is formed by the confluence of the splenic vein and the superior mesenteric vein. The inferior mesenteric vein usually drains into the splenic vein upstream from the conflu-ence (Fig. 31-6). The main portal vein traverses the porta hepa-tis before dividing into the left and right portal vein branches. The left portal vein typically branches from the main portal vein outside of the liver with a sharp bend to the left and consists of the transverse portion followed by a 90° turn at the base of the umbilical fissure to become the umbilical portion before enter-ing the liver parenchyma (Fig. 31-7). The left portal vein then divides to give off the segment II and III branches to the left lat-eral segment, as well as the segment IV branches that supply the left medial segment. The left portal vein also provides the domi-nant inflow branch to the caudate lobe (although branches can arise from the main and right portal veins also), usually close to the bend between the transverse and umbilical portions. The division of the right portal vein is usually higher in the hilum and may be close to (or inside) the liver parenchyma at the hilar plate. Twenty percent to 35% of individuals have aberrant por-tal venous anatomy, with portal vein trifurcation or an aberrant branch from the left portal vein supplying the right anterior lobe being the most frequent.The portal vein drains the splanchnic blood from the stom-ach, pancreas, spleen, small intestine, and majority of the colon to the liver before returning to the systemic circulation. The portal vein pressure in an individual with normal physiology is low at 3 to 5 mmHg. The portal vein is valveless, however, and in the setting of portal hypertension, the pressure can be 1Figure 31-4. Arterial anatomy of the upper abdomen and liver, including the celiac trunk and hepatic artery branches. a. = artery; LHA = left hepatic artery; RHA = right hepatic artery.RHALHAHepatic arteryproperRight gastricarteryCommon hepatic arteryLeft gastricarteryCeliac trunkSplenic arteryGastroduodenal arteryBrunicardi_Ch31_p1345-p1392.indd 134820/02/19 2:36 PM 1349LIVERCHAPTER 31quite high (20 to 30 mmHg). This results in decompression of the systemic circulation through portocaval anastomoses, most commonly via the coronary (left gastric) vein, which produces esophageal and gastric varices with a propensity for major hem-orrhage. Another branch of the main portal vein is the superior pancreaticoduodenal vein (which comes off low in an anterior lateral position and is divided during pancreaticoduodenec-tomy). Closer to the liver, the main portal vein typically gives off a short branch (posterior lateral) to the caudate process on the right side. It is important to identify this branch and ligate it during hilar dissection for anatomic right hemihepatectomy to avoid avulsion.Hepatic Veins and Inferior Vena CavaThere are three hepatic veins (right, middle, and left) that pass obliquely through the liver to drain the blood to the suprahe-patic IVC and eventually the right atrium (Fig. 31-8). The right hepatic vein drains segments V through VIII; the middle hepatic vein drains segment IV as well as segments V and VIII; and the left hepatic vein drains segments II and III. The caudate lobe Replaced right hepaticartery from SMA (10%–15%)Replaced left hepatic artery from left gastric artery (3%–10%)Replaced right and replaced left hepatic arteries (1%–2%)Completely replaced commonhepatic artery from SMA (1%–2%)Figure 31-5. Common hepatic artery anatomic variants. SMA = superior mesenteric artery.Coronary v.Portal v.Superior mesenteric v.Inferiormesenteric v.Splenic v.Figure 31-6. Portal vein anatomy. The portal vein is formed by the confluence of the splenic and superior mesenteric veins. The inferior mesenteric vein drains into the splenic vein. The coronary (left gastric) vein drains into the portal vein in the vicinity of the confluence. v. = vein.Main portal veinRightportal veinLeftportal veinUmbilicalportion LPVIIIIIIIVAIVBVVIVIIVIIIVIIITransverseportion LPVFigure 31-7. Anatomy of the left portal vein (LPV). Note the transverse and umbilical portions of the LPV.Brunicardi_Ch31_p1345-p1392.indd 134920/02/19 2:36 PM 1350SPECIFIC CONSIDERATIONSPART IIis unique because its venous drainage feeds directly into the IVC. In addition, the liver usually has a few small, variable short hepatic veins that directly enter the IVC from the undersurface of the liver. The left and middle hepatic veins form a common trunk approximately 95% of the time before entering the IVC, whereas the right hepatic vein inserts separately (in an oblique orientation) into the IVC. There is a large inferior accessory right hepatic vein in 15% to 20% of cases that runs in the hepa-tocaval ligament. This can be a source of torrential bleeding if control of it is lost during right hepatectomy. The hepatic vein branches bisect the portal branches inside the liver parenchyma (i.e., the right hepatic vein runs between the right anterior and posterior portal veins; the middle hepatic vein passes between the right anterior and left portal vein; and the left hepatic vein crosses between the segment II and III branches of the left portal vein).Bile Duct and Hepatic DuctsWithin the hepatoduodenal ligament, the common bile duct lies anteriorly and to the right. It gives off the cystic duct to the gallbladder and becomes the common hepatic duct before divid-ing into the right and left hepatic ducts. In general, the hepatic ducts follow the arterial branching pattern inside the liver. The right anterior hepatic duct usually enters the liver above the hilar plate, whereas the right posterior duct dives behind the right portal vein and can be found on the surface of the caudate pro-cess before entering the liver. The left hepatic duct typically has a longer extrahepatic course before giving off segmental branches behind the left portal vein at the base of the umbilical fissure. Considerable variation exists, and in 30% to 40% of cases, there is a nonstandard hepatic duct confluence with acces-sory or aberrant ducts (Fig. 31-9). The cystic duct itself also has a variable pattern of drainage into the common bile duct. This can lead to potential injury or postoperative bile leakage during cholecystectomy or hepatic resection, and the surgeon needs to expect these variants. The gallbladder sits adherent to hepatic segments IVB (left lobe) and V (right lobe).Neural Innervation and Lymphatic DrainageThe parasympathetic innervation of the liver comes from the left vagus, which gives off the anterior hepatic branch, and the right vagus, which gives off the posterior hepatic branch. The sympathetic innervation involves the greater thoracic splanchnic nerves and the celiac ganglia, although the function of these nerves is poorly understood. The denervated liver after hepatic transplantation seems to function with normal capacity. A common source of referred pain to the right shoulder and scapula as well as the right side or back is the right phrenic Right lobePosteriorsegmentstructuresMiddlehepaticv.Anterior segmentstructuresGall bladderPortal v.Hepatic a.FalciformligamentLeft lobeMedialsegmentstructuresLateralsegmentstructuresMiddle HVRight HVLeft HVIVC and 3 HVsIVC Figure 31-8. Confluence of the three hepatic veins (HVs) and the inferior vena cava (IVC). Note that the middle and left HVs drain into a common trunk before entering the IVC. a. = artery; v. = vein. (Adapted with permission from Cameron JL: Atlas of Surgery. Vol. I, Gallbladder and Biliary Tract, the Liver, Portasystemic Shunts, the Pancreas. Toronto: BC Decker; 1990.)Brunicardi_Ch31_p1345-p1392.indd 135020/02/19 2:36 PM 1351LIVERCHAPTER 31nerve, which is stimulated by tumors that stretch Glisson’s cap-sule or by diaphragmatic irritation.Lymph is produced within the liver and drains via the perisinusoidal space of Disse and periportal clefts of Mall to larger lymphatics that drain to the hilar cystic duct lymph node (Calot’s triangle node), as well as the common bile duct, hepatic artery, and retropancreatic and celiac lymph nodes. This is par-ticularly important for resection of hilar cholangiocarcinoma, which has a high incidence of lymph node metastases. The hepatic lymph also drains cephalad to the cardiophrenic lymph nodes, and the latter can be pathologically identified on a stag-ing CT or MRI scan.LIVER PHYSIOLOGYThe liver is the largest gland in the body and has an extraordi-nary spectrum of functions. These include processes such as storage, metabolism, production, and secretion. One crucial role is the processing of absorbed nutrients through the metabolism of glucose, lipids, and proteins. The liver maintains glucose con-centrations in a normal range over both short and long periods by performing several important roles in carbohydrate metabo-lism. In the fasting state, the liver ensures a sufficient supply of glucose to the central nervous system. The liver can produce glucose by breaking down glycogen through glycogenolysis and by de novo synthesis of glucose through gluconeogenesis from noncarbohydrate precursors such as lactate, amino acids, and glycerol. In the postprandial state, excess circulating glucose is removed by glycogen synthesis or glycolysis and lipogenesis. The liver also plays a central role in lipid metabolism through the formation of bile and the production of cholesterol and fatty acids. Protein metabolism occurs in the liver through amino acid deamination, resulting in the production of ammonia as well as the production of a variety of amino acids. In addition to rpA: Normal bifurcation 57%B: Trifurcation of 3 ducts 12%C: R anterior (C1, 16%) or R posterior (C2, 4%) duct draining into CHDD: R posterior (D1, 5%) or R anterior duct (D2, 1%) draining into the left hepatic ductE: Absence of hepatic duct confluence 3%F: Drainage of R posterior duct into cystic duct 2%rprprprprprprprplhlhlhlhlhlhlhrararararararararaIVIVIIIIIIIIIIIIF2%E3%D6%C20%A57%B12%4%1%1%2%5%16%C2C1D2E2E1D1Figure 31-9. Main variations of hepatic duct confluence. As described by Couinaud in 1957, the bifurcation of the hepatic ducts has a vari-able pattern in approximately 40% of cases. CHD = common hepatic duct; lh = left hepatic; R = right; ra = right anterior; rp = right posterior. (Reproduced with permission from Blumgart LH, Fong Y: Surgery of the Liver and Biliary Tract, 3rd ed, Vol. I. London: Elsevier; 2000.)Brunicardi_Ch31_p1345-p1392.indd 135120/02/19 2:36 PM 1352SPECIFIC CONSIDERATIONSPART IImetabolism, the liver also is responsible for the synthesis of most circulating plasma proteins. Among these proteins are albumin, factors of the coagulation and fibrinolytic systems, and compounds of the complement cascade. Furthermore, the detoxification of many substances through drug metabo-lism occurs in the liver, as do immunologic responses through the many immune cells found in its reticuloendothelial system.9Bilirubin MetabolismBilirubin is the breakdown product of normal heme catabolism. Bilirubin is bound to albumin in the circulation and sent to the liver. In the liver, it is conjugated to glucuronic acid to form bilirubin diglucuronide in a reaction catalyzed by the enzyme glucuronyl transferase, making it water soluble. This glucuro-nide is then excreted into the bile canaliculi. A small amount dissolves in the blood and is then excreted in the urine. The majority of conjugated bilirubin is excreted in the intestine as waste because the intestinal mucosa is relatively impermeable to conjugated bilirubin. However, it is permeable to unconjugated bilirubin and urobilinogens, a series of bilirubin derivatives formed by the action of bacteria. Thus, some of the bilirubin and urobilinogens are reabsorbed in the portal circulation; they are again excreted by the liver or enter the circulation and are excreted in the urine.10Formation of BileBile is a complex fluid containing organic and inorganic sub-stances dissolved in an alkaline solution that flows from the liver through the biliary system and into the small intestine. The main components of bile are water, electrolytes, and a variety of organic molecules including bile pigments, bile salts, phospho-lipids (e.g., lecithin), and cholesterol. The two fundamental roles of bile are to aid in the digestion and absorption of lipids and lipid-soluble vitamins and to eliminate waste products (bilirubin and cholesterol) through secretion into bile and elimination in feces. Bile is produced by hepatocytes and secreted through the biliary system. In between meals, bile is stored in the gallblad-der and concentrated through the absorption of water and elec-trolytes. Upon entry of food into the duodenum, bile is released from the gallbladder to aid in digestion. The human liver can produce about 1 L of bile daily.Bile salts, in conjunction with phospholipids, are respon-sible for the digestion and absorption of lipids in the small intestine. Bile salts are sodium and potassium salts of bile acids conjugated to amino acids. The bile acids are derivatives of cho-lesterol synthesized in hepatocytes. Cholesterol, ingested from the diet or derived from hepatic synthesis, is converted into the bile acids cholic acid and chenodeoxycholic acid. These bile acids are conjugated to either glycine or taurine before secre-tion into the biliary system. Bacteria in the intestine can remove glycine and taurine from bile salts. They can also convert some of the primary bile acids into secondary bile acids by removing a hydroxyl group, producing deoxycholic acid from cholic acid and lithocholic acid from chenodeoxycholic acid.Bile salts secreted into the intestine are efficiently reab-sorbed and reused. Approximately 90% to 95% of the bile salts are absorbed from the small intestine at the terminal ileum. The remaining 5% to 10% enter the colon and are converted to the secondary salts, deoxycholic acid and lithocholic acid. The mixture of primary and secondary bile salts and bile acids is absorbed primarily by active transport in the terminal ileum. The absorbed bile salts are transported back to the liver in the portal vein and reexcreted in the bile. Those lost in the stool are replaced by synthesis in the liver. The continuous process of secretion of bile salts in the bile, their passage through the intestine, and their subsequent return to the liver is termed the enterohepatic circulation.10Drug MetabolismThe liver plays an important role in providing mechanisms for ridding the body of foreign molecules (xenobiotics) that are absorbed from the environment. In most cases, a drug is relatively lipophilic to ensure good absorption. The liver par-ticipates in the elimination of these lipid-soluble drugs by trans-forming them into more readily excreted hydrophilic products. There are two main reactions important for drug metabolism. Phase 1 reactions include oxidation, reduction, and hydrolysis of molecules. These result in metabolites that are more hydro-philic than the original chemicals. The cytochrome P450 system is a family of hemoproteins important for oxidative reactions involving drugs and toxic substances. Phase 2 reactions, also known as conjugation reactions, are synthetic reactions that involve addition of subgroups to the drug molecule. These sub-groups include glucuronate, acetate, glutathione, glycine, sul-fate, and methyl groups. These drug reactions occur mainly in the smooth endoplasmic reticulum of hepatocytes.Many factors can affect drug metabolism in the liver. When the rate of metabolism of a drug is increased (i.e., enzyme induction), the duration of the drug action will decrease. How-ever, when the metabolism of a drug is decreased (i.e., enzyme inhibition), then the drug will circulate for a longer period of time. It is important to note that some drugs may be converted to active products by metabolism in the liver. An example is acetaminophen when taken in larger doses. Normally, acet-aminophen is conjugated by the liver to harmless glucuronide and sulfate metabolites that are water soluble and eliminated in the urine. During an overdose, the normal metabolic path-ways are overwhelmed, and some of the drug is converted to a reactive and toxic intermediate by the cytochrome P450 system. Glutathione normally reacts with this intermediate, leading to the production and subsequent excretion of a harmless prod-uct. However, as glutathione stores are diminished, the reactive intermediate cannot be detoxified and it combines with lipid membranes of hepatocytes, which results in cellular necrosis. Thus, treatment of acetaminophen overdoses consists of replen-ishing glutathione stores by supplementing with sulfhydryl compounds such as acetylcysteine.Liver Function TestsLiver function tests is a term frequently used to refer to mea-surement of the levels of a group of serum markers for evalu-ation of liver dysfunction. Most commonly, levels of aspartate transaminase (AST), alanine transaminase (ALT), alkaline phosphatase (AP), γ-glutamyltranspeptidase (GGT), and biliru-bin are included in this panel. This term is a misnomer, how-ever, because most of these tests measure not liver function but rather cell damage. More accurate measurement of the liver’s synthetic function is provided by serum albumin levels and pro-thrombin time (PT). Although measuring liver enzyme levels is important in the assessment of a patient’s liver disease, these test results can be nonspecific. Thus, evaluation of patients with suspected liver disease should always involve careful interpreta-tion of abnormalities in these liver test results in the context of a thorough history and physical examination. The approach to 2Brunicardi_Ch31_p1345-p1392.indd 135220/02/19 2:36 PM 1353LIVERCHAPTER 31evaluating abnormal laboratory values also can be simplified by categorizing the type of abnormality that predominates (hepa-tocellular damage, abnormal synthetic function, or cholestasis).Hepatocellular InjuryHepatocellular injury of the liver is usually indicated by abnor-malities in levels of the liver aminotransferases AST and ALT. These enzymes participate in gluconeogenesis by catalyz-ing the transfer of amino groups from aspartic acid or alanine to ketoglutaric acid to produce oxaloacetic acid and pyruvic acid, respectively (these enzymes are also referred to as serum glutamic-oxaloacetic transaminase [SGOT] and serum glutamic-pyruvic transaminase [SGPT]). AST is found in liver, cardiac muscle, skeletal muscle, kidney, brain, pancreas, lungs, and red blood cells and thus is less specific for disorders of the liver. ALT is predominately found in the liver and thus is more specific for liver disease. Hepatocellular injury is the trigger for release of these enzymes into the circulation. Common causes of elevated aminotransferase levels include viral hepatitis, alcohol abuse, medications, genetic disorders (Wilson’s disease, hemochroma-tosis, α1-antitrypsin deficiency), and autoimmune diseases.The extent of serum aminotransferase elevations can sug-gest certain etiologies of the liver injury. However, the levels of the enzymes in these tests correlate poorly with the severity of hepatocellular necrosis because they may not be significantly elevated in conditions of hepatic fibrosis or cirrhosis. In alco-holic liver disease, an AST to ALT ratio of >2:1 is common. Mild elevations of transaminase levels can be found in nonal-coholic fatty liver disease, chronic viral infection, or medica-tion-induced injury. Moderate increases in the levels of these enzymes are common in acute viral hepatitis. In conditions of ischemic insults, toxin ingestions (i.e., acetaminophen), and ful-minant hepatitis, AST and ALT levels can be elevated to the thousands.Abnormal Synthetic FunctionAlbumin synthesis is an important function of the liver and thus can be measured to evaluate the liver’s synthetic function. The liver produces approximately 10 g of albumin per day. How-ever, albumin levels are dependent on a number of factors such as nutritional status, renal dysfunction, protein-losing enteropa-thies, and hormonal disturbances. In addition, level of albumin is not a marker of acute hepatic dysfunction due to albumin’s long half-life of 15 to 20 days.Most clotting factors (except factor VIII) are synthesized exclusively in the liver, and thus their levels can also be used as a measure of hepatic synthetic function. Measurements of the pro-thrombin time (PT) and international normalized ratio (INR) are some of the best tests of hepatic synthetic function. PT measures the rate of conversion of prothrombin to thrombin. To standard-ize the reporting of PT and avoid interlaboratory variability, the INR was developed. The INR is the ratio of the patient’s PT to the mean control PT. Because vitamin K is involved in the γ-carboxylation of factors used to measure PT (factors II, VII, IX, and X), values also may be prolonged in other conditions such as vitamin K deficiency and warfarin therapy.CholestasisCholestasis is a condition in which bile flow from the liver to the duodenum is impaired. Disturbances in bile flow may be due to intrahepatic causes (hepatocellular dysfunction) or extrahepatic causes (biliary tree obstruction). Cholestasis often results in the release of certain enzymes and thus can be detected by measur-ing the serum levels of bilirubin, AP, and GGT. Bilirubin is a breakdown product of hemoglobin metabolism. Unconjugated bilirubin is insoluble and thus is transported to the liver bound to albumin. In the liver, it is conjugated to allow excretion in bile. Measured total bilirubin levels can be normal or high in patients with significant liver disease because of the liver’s abil-ity to conjugate significant amounts of bilirubin. Thus, to help aid in the diagnosis of hyperbilirubinemia, fractionation of total bilirubin is usually performed to distinguish between conjugated (direct) and unconjugated (indirect) bilirubin. Indirect bilirubin is a term frequently used to refer to unconjugated bilirubin in the circulation because the addition of another chemical is nec-essary to differentiate this fraction from the whole. Normally, >90% of serum bilirubin is unconjugated. The testing process for conjugated bilirubin, in contrast, is direct without the addi-tion of other agents. The direct bilirubin test measures the lev-els of conjugated bilirubin and δ bilirubin (conjugated bilirubin bound to albumin).The patterns of elevation of the different fractions of bili-rubin provide important diagnostic clues as to the cause of cho-lestasis. In general, an elevated indirect bilirubin level suggests intrahepatic cholestasis, and an elevated direct bilirubin level suggests extrahepatic obstruction. Mechanisms that can result in increases in unconjugated bilirubin levels include increased bilirubin production (hemolytic disorders and resorption of hematomas) or defects (inherited or acquired) in hepatic uptake or conjugation. The rate-limiting step in bilirubin metabolism is the excretion of bilirubin from hepatocytes, so conjugated hyperbilirubinemia can be seen in inherited or acquired dis-orders of intrahepatic excretion or extrahepatic obstruction. Conjugated bilirubin that cannot be excreted accumulates in hepatocytes, which results in its secretion into the circulation. Because conjugated bilirubin is water soluble, it can be found in the urine of patients with jaundice.AP is an enzyme with a wide tissue distribution but is found primarily in the liver and bones. In the liver, it is expressed by the bile duct epithelium. In conditions of biliary obstruction, levels rise as a result of increased synthesis and release into the serum. Because the half-life of serum AP is approximately 7 days, it may take several days for levels to normalize even after resolution of the biliary obstruction.GGT is another enzyme found in hepatocytes and released from the bile duct epithelium. Elevation of GGT is an early marker and also a sensitive test for hepatobiliary disease. Like AP elevation, however, it is nonspecific and can be produced by a variety of disorders in the absence of liver disease. Increased levels of GGT can be induced by certain medications, alcohol abuse, pancreatic disease, myocardial infarction, renal failure, and obstructive pulmonary disease. For this reason, elevated GGT levels are often interpreted in conjunction with other enzyme abnormalities. For example, a raised GGT level with increased AP level supports a liver source.JaundiceJaundice refers to the yellowish staining of the skin, sclera, and mucous membranes with the pigment bilirubin. Hyperbilirubi-nemia usually is detectable as jaundice when blood levels rise above 2.5 to 3 mg/dL. Jaundice can be caused by a wide range of benign and malignant disorders. However, when present, it may indicate a serious condition, and thus knowledge of the differential diagnosis of jaundice and a systematic approach to Brunicardi_Ch31_p1345-p1392.indd 135320/02/19 2:36 PM 1354SPECIFIC CONSIDERATIONSPART IIthe workup of the patient is necessary. Workup of a patient with jaundice is simplified by organizing the possible causes of the disorder into groups based on the location of bilirubin metabo-lism. As mentioned previously, bilirubin metabolism can take place in three phases: prehepatic, intrahepatic, and posthepatic. The prehepatic phase includes the production of bilirubin from the breakdown of heme products and its transport to the liver. The majority of the heme results from red blood cell metabolism and the rest from other heme-containing organic compounds such as myoglobin and cytochromes. In the liver, the insoluble unconjugated bilirubin is then conjugated to glucuronic acid to allow for solubility in bile and excretion. The posthepatic phase of bilirubin metabolism consists of excretion of soluble bilirubin through the biliary system into the duodenum. Dysfunction in any of these phases can lead to jaundice.10Prehepatic. Jaundice as a result of elevated levels of uncon-jugated bilirubin occurs from faulty prehepatic metabolism and usually arises from conditions that interfere with proper conju-gation of bilirubin in the hepatocyte. Insufficient conjugation is often seen in processes that result in excessive heme metabolism. Subsequently, the conjugation system is overwhelmed, which results in unconjugated hyperbilirubinemia. Causes of hemoly-sis include inherited and acquired hemolytic anemias. Inherited hemolytic anemias include genetic disorders of the red blood cell membrane (hereditary spherocytosis and eliptocytosis), enzyme defects (glucose-6-phosphate dehydrogenase deficiency), and defects in hemoglobin structure (sickle cell anemia and thalas-semias). Hemolytic anemias can also be acquired, and these can be further divided into those with immune-mediated and those with non–immune-mediated causes. Immune-mediated hemo-lytic anemias result in a positive finding on a direct Coombs test and have a variety of autoimmune and drug-induced causes. In contrast, direct Coombs test results are negative in nonimmune hemolytic anemias. The causes in this latter category are varied and include drugs and toxins that directly damage red blood cells, mechanical trauma (heart valves), microangiopathy, and infections. Prehepatic dysfunction of bilirubin metabolism also can result from failure in the transport of unconjugated bilirubin to the liver by albumin in any condition that leads to plasma protein loss. A poor nutritional state or excess protein loss as seen in burn patients can lead to elevated levels of unconjugated bilirubin in the circulation and jaundice.Intrahepatic. Intrahepatic causes of jaundice involve the intracellular mechanisms for conjugation and excretion of bile from the hepatocyte. The enzymatic processes in hepatocytes can be affected by any condition that impairs hepatic blood flow and subsequent function of the liver (ischemic or hypoxic events). Furthermore, there are multiple inherited disorders of enzyme metabolism that can result in either unconjugated or conjugated hyperbilirubinemia. Gilbert’s syndrome is a genetic variant characterized by diminished activity of the enzyme glucuronyltransferase, which results in decreased conjugation of bilirubin to glucuronide. It is a benign condition that affects approximately 4% to 7% of the population. Typically, the dis-ease results in transient mild increases in unconjugated bilirubin levels and jaundice during episodes of fasting, stress, or illness. These episodes are self-limited and usually do not require fur-ther treatment. Another inherited disorder of bilirubin conjuga-tion is Crigler-Najjar syndrome. It is a rare disease found in neonates and can result in neurotoxic sequelae from bilirubin encephalopathy.In addition to defects in conjugation, disorders in bilirubin excretion in hepatocytes can also lead to jaundice. Rotor’s syn-drome and Dubin-Johnson syndrome are two uncommon genetic disorders that disrupt secretion of conjugated bilirubin from the hepatocyte into the bile and result in conjugated hyperbilirubi-nemia. There are also multiple acquired conditions that result in inflammation and intrahepatic cholestasis by affecting hepato-cyte mechanisms for conjugation and excretion of bile. Viruses, alcohol abuse, sepsis, and autoimmune disorders all can result in inflammation in the liver with subsequent disruption of bilirubin transport in the liver. In addition, jaundice can also occur from the cytotoxic effects of many medications, including acetamino-phen, oral contraceptives, and anabolic steroids.Posthepatic. Posthepatic causes of jaundice are usually the result of intrinsic or extrinsic obstruction of the biliary duct sys-tem that prevents the flow of bile into the duodenum. There is a wide spectrum of pathologies that may present with obstructive jaundice. Intrinsic obstruction can occur from biliary diseases, including cholelithiasis, choledocholithiasis, benign and malig-nant biliary strictures, cholangiocarcinoma, cholangitis, and disorders of the papilla of Vater. Extrinsic compression of the biliary tree is commonly due to pancreatic disorders. Patients with pancreatitis, pseudocysts, and malignancies can present with jaundice due to external compression of the biliary system. Finally, with the growing armamentarium of endoscopic tools and minimally invasive surgical approaches, surgical complica-tions are becoming more frequent causes of extrahepatic cho-lestasis. Misadventures with surgical clips, retained stones, and inadvertent ischemic insults to the biliary system can result in obstructive jaundice recognized at any time from immediately postoperatively to many years later.MOLECULAR SIGNALING PATHWAYS IN THE LIVERAcute Phase ReactionThe liver is the site of synthesis of acute phase proteins that consists of a group of plasma proteins that are rapidly released in response to inflammatory conditions elsewhere in the body. The synthesis of these proteins in the liver is mediated by a num-ber of inflammatory mediators. Cytokines such as tumor necro-sis factor alpha (TNF-α), interferon-γ (IFN-γ), interleukin-1 (IL-1), interleukin-6 (IL-6), and interleukin-8 (IL-8) are released by inflammatory cells into the circulation at sites of injury and modulate the acute phase response. In response to these cyto-kines, the liver increases synthesis and release of a wide vari-ety of proteins including ceruloplasmin, complement factors, C-reactive protein (CRP), d-dimer protein, alpha 1-antitrysin, and serum amyloid A. There are proteins, such as serum albu-min and transferrin, that also decrease (negative acute phase proteins) in response to inflammation.The acute phase response of the liver can be initiated in response to infection, trauma, or malignancy. The purpose of the release of these proteins from the liver is to contain infectious processes, prevent further tissue damage and to begin repara-tive and regeneration processes to restore body homeostasis. For example, products of the complement pathways can attach to microbes to allow for phagocytosis and act as chemoattractants to the areas of inflammation. CRP is an important acute phase protein that is also involved in the clearance of microorganisms by binding to their membranes and functioning as an opsonin to Brunicardi_Ch31_p1345-p1392.indd 135420/02/19 2:36 PM 1355LIVERCHAPTER 31facilitate phagocytosis. Other proteins such as α1-antitrypsin are protease inhibitors and restrict the protease activity of enzymes of inflammatory cells. Thus, the secretion of acute phase pro-teins from the liver during the acute phase response is an early defense measure against harmful stimuli prior to the full activa-tion of the immune response.11LPS SignalingThe liver is a complex organ with an important function in immune surveillance and clearance of bacteria and their prod-ucts. This function is facilitated by the fact that the liver receives all the drainage of the gastrointestinal tract via the portal blood flow, making it the last barrier preventing bacteria and their toxins from reaching the systemic circulation. The importance of preventing bacteria and their products from reaching the systemic blood stream is evident in patients who are infected with gram-negative bacteria. Gram-negative bacteria infection produces an acute inflammatory reaction that can lead to septic shock and multiple organ failure. The complications of gram-negative sepsis are initiated by endotoxin (lipopolysaccharide [LPS]). LPS is a glycolipid constituent of gram-negative bacte-ria outer membranes composed of a hydrophilic polysaccharide portion and a hydrophobic domain called lipid A. The lipid A structure is the LPS component responsible for the biological effects of LPS. Mere nanogram amounts of LPS injected into humans are needed to result in the manifestations of septic shock. The profound effects of LPS are caused not only by the direct effect of LPS itself but also by the activation of LPS-sensitive cells, resulting in the excessive release of cytokines and other inflammatory mediators.Since sepsis from gram-negative bacterial infection con-tinues to be a major cause of morbidity and mortality, significant efforts have been made to identify the molecules involved in LPS-binding and signaling. Lipopolysaccharide binding protein (LBP), CD14, MD2, and Toll-like receptors have all been iden-tified as important mediators in the pathway of LPS stimulation. LBP is an acute-phase protein synthesized by hepatocytes that binds the lipid A moiety of LPS and forms a soluble LBP-LPS complex. This LBP-LPS complex then interacts with CD14, a receptor identified as important in LPS recognition, resulting in the release of inflammatory cytokines and mediators. Studies have shown that although LBP is important, it is not required for LPS to interact with CD14; however, its presence markedly decreases the concentration of LPS necessary for cellular acti-vation. This may be important especially at the low concentra-tions of LPS found under physiological conditions. CD14 exists in two forms, membrane (mCD14) and soluble (sCD14) form. The interaction of LPS with membrane CD14 or soluble CD14 is important in host clearance of LPS. This interaction is also responsible for the toxic effects of LPS seen in the liver and systemic circulation after the release of inflammatory cytokines and mediators. While membrane CD14 is a membrane protein found on the surface of myeloid lineage and mediates the activa-tion of these cells by LPS, soluble CD14 is found in the serum and enables responses to LPS by cells that do not express CD14. In addition to its important role in the release of LBP as an acute phase reactant during LPS-mediated inflammatory insults, the liver is also one of the major sources of soluble CD14 into the circulation.The binding of the LBP-LPS complex to CD14 is not enough to transduce an intracellular LPS signal. Membrane CD14 is a glycosyl phosphatidylinositol-anchored protein without a membrane-spanning domain. Thus, signaling fur-ther downstream of LPS requires additional elements. In stud-ies using chemically modified, radioiodinated LPS capable of cross-linking to nearby proteins, LPS has been shown to cross-link specifically to two other molecules, TLR4 and MD-2. TLR4 is a member of the family of proteins called Toll-like receptors and has been identified as the transmembrane corecep-tor to CD14. TLR4 was originally identified as the molecular sensor for bacterial LPS when studies demonstrated that muta-tions in the tlr4 gene were responsible for defective LPS sig-naling in mutant mice. Thus, initiation of LPS signal cascade requires the interaction of LPS directly with the heteromeric receptor complex of CD14, TLR4, and MD-2. Activation of this complex senses the presence of bacterial LPS at the cell sur-face and then transmits a signal into the cytoplasm through two distinct pathways. One pathway is dependent upon an adaptor known as myeloid differentiation factor 88 (MyD88). The other pathway is MyD88-independent and relies on an adaptor known as Toll/IL-1 receptor domain-containing adaptor-inducing IFNβ (TRIF).The liver is the main organ involved in the clearance of LPS from the bloodstream and so plays a critical role in the identification and processing of LPS. Kupffer cells are the resident macrophages of the liver and have been shown to par-ticipate in LPS clearance. Studies have demonstrated that the majority of radiolabelled LPS injected intravenously is quickly cleared from the circulation and found in the liver, primarily localized to the Kupffer cells. Kupffer cells also contribute to the inflammatory cascade by producing cytokines in response to LPS. Interestingly, hepatocytes, the parenchymal cells of the liver, also have all the components required for LPS recognition and signaling and can participate in the response to LPS and process LPS for clearance.Although the liver is essential in the host response to gram-negative bacteria infection by contributing to LPS clearance and to the LPS-induced inflammatory reaction, evidence reveals that LPS may actually have a reciprocal role in the pathogenesis of liver disorders. The relationship between LPS and liver disease is not a novel concept. Early studies have shown the correlation between the presence or absence of gut-derived LPS and the development of liver injury. Attempts to eliminate gut-derived LPS have had protective effects in various animal models of liver injury, including alcohol-induced liver disease. Other stud-ies have shown the synergism between LPS and hepatotoxins in worsening liver injury.In summary, the liver is essential in the clearance of LPS, but it can also contribute to the negative systemic effects seen in gram-negative bacterial sepsis by excessive activation of the LPS signaling pathway. In addition, there is evidence that this signaling pathway may participate in the pathogenesis of a vari-ety of liver disease. An understanding and characterization of the LPS pathway within the liver is an important step to under-standing the molecular basis for the lethal effect of LPS during sepsis and liver disorders.12,13Nitric OxideNitric oxide (NO) is a diffusible, free radical gas that was first identified in 1980 as endothelium-derived relaxing factor. Its physiologic and pathophysiologic importance was first discov-ered in the cardiovascular system with its vital role as a vaso-dilator. However, its mediation in a variety of other diverse biological activities has since been discovered. In the liver, the Brunicardi_Ch31_p1345-p1392.indd 135520/02/19 2:36 PM 1356SPECIFIC CONSIDERATIONSPART IIinfluence of NO on normal physiology as well as in states of disease has been extensively studied. The activation of inflam-matory cascades in the liver almost universally includes the upregulation of the inducible or inflammatory isoform of nitric oxide synthase (iNOS) and subsequent NO production. The functions of iNOS and NO in the liver is complex, and a clear dichotomy of their roles in liver dysfunction, whether being pro-tective or detrimental, has been demonstrated.Nitric oxide can be produced by one of three NO synthases: (NOS)-neuronal NOS (nNOS), inducible or inflammatory NOS (iNOS), and endothelial NOS (eNOS). These enzymes catalyze the conversion of l-arginine to NO and l-citrulline. Neuronal and endothelial NOS are constitutively expressed in a wide range of tissues. The activity of iNOS and eNOS are primarily controlled by calcium-mediated signaling that results in transient activation of these enzymes to produce small amounts of NO. Inducible NOS, as the name implies, is not normally expressed in rest-ing states in most tissues but is upregulated by gene transcrip-tion under conditions of stress. In contrast to nNOS and eNOS, the amount of NO produced by iNOS is large and sustained. Although first identified in macrophages, the expression of iNOS has been shown in most cell types if appropriately stimulated. Interestingly, studies on the liver with hepatocytes provided the first evidence that parenchymal cells could express iNOS. It is now known that iNOS can be expressed in all cell types of the liver, but hepatocyte expression appears to be the most promi-nent. Studies have shown that many inflammatory mediators, including cytokines, microbial products, and oxidative stress, are all capable of stimulating iNOS expression in the liver.The chemical action of NO in biological systems has been difficult to study due to its short-lived nature. NO is highly reac-tive with other molecules due to its one unpaired electron. These interactions can either result in nitrosation or oxidation with subsequent varied effects on cellular processes. Nitric oxide can also signal through cyclic nucleotides by activating the soluble isoform of guanylyl cyclase, increasing levels of cGMP. The functions of cGMP include acting as second messengers that transmit signals by activating downstream kinases or through the activation of cyclic nucleotide-gated channels. In addition to cGMP signaling, NO has also been found to modulate the expression of many genes.The role of NO in inflammatory states of the liver is complex and is at times conflicting. Under physiologic condi-tions, NO is important in maintaining hepatic perfusion. How-ever, in inflammatory conditions, such as ischemia/reperfusion (I/R), nitric oxide can play either a protective or harmful role depending on the enzymatic source (inducible versus endothe-lial nitric oxide synthase) and the type of ischemia reperfusion (cold vs. warm). It appears that the low level of constitutively expressed eNOS-derived NO is primarily beneficial in models of I/R injury with vasodilation and subsequent improvement in hepatic microcirculation as the proposed mechanism of protec-tion. Interestingly, activation of iNOS in similar models sug-gests a potentially harmful role for iNOS. Nitric oxide, through its reaction with reactive nitrogen and oxygen intermediates generated in the course of reperfusion injury, can contribute to much of the hepatocellular damage depending on the intracellu-lar ratio of these intermediates to nitric oxide. The production of iNOS and NO are also closely tied to multiple other inflamma-tory mediators in the liver, and activation of these downstream signals may explain some of the detrimental effects of NO in I/R injury of the liver. Thus, given its diverse biological effects as a signaling molecule, it is not surprising that NO plays both pro-tective and potentially harmful role in the setting of hepatic I/R injury. The final effect of NO varies in different liver diseases and depends on the overall hepatic environment. The potential use of NO pharmacologic manipulation to treat hepatic disease will require careful balance of the risks and benefits of this sim-ple, yet extremely complicated, molecule.14,15Heme Oxygenase SystemThe heme oxygenase (HO) is the rate-limiting enzyme in the degradation of heme to yield biliverdin, carbon monoxide (CO), and free iron. The HO system, which is activated in response to multiple cellular stresses, has been shown to be an endogenous cytoprotectant in a variety of inflammatory conditions. There are currently three heme oxygenase isozymes identified. HO-1 is the inducible form of heme oxygenase, while HO-2 and HO-3 are constitutively expressed. The function of HO in heme deg-radation is essential due to the potentially toxic effects of heme. An excess of heme can cause cellular damage from oxidative stress due to its production of reactive oxygen species. Thus, the HO system is an important defense mechanism against free heme-mediated oxidative stress.HO-1 has been shown to be induced in a variety of organs during diverse conditions such as hypoxia, endotoxemia, ischemia/reperfusion (I/R), hyperthermia, and radiation. It is thought that HO-1 is involved in maintaining redox homeostasis during cellular stress. In the liver, HO-1 is thought to normally modulate hepatic microvasculature tone through its generation of CO and, like nitric oxide, its activation of guanylyl cyclase. This important role is demonstrated in animal models of por-tal hypertension where inhibition of HO-1 exacerbates hyper-tension. Since HO-1 is induced as a protective mechanism in response to various stimuli, targeted induction of HO-1 has been studied as a therapeutic strategy for protection against inflam-matory processes. HO-1 overexpression exerts hepatoprotective effects in models of I/R injury, hemorrhagic shock and resus-citation, acetaminophen-induced hepatonecrosis, and sepsis-mediated liver injury.Although HO-1 has been shown to provide protective effects in a variety of inflammatory states, the specific mecha-nisms by which HO-1 mediates its protective effects are remains to be fully elucidated. Originally thought to be only potentially toxic waste, the byproducts generated during heme catabolism now appear to play important roles against cellular stress. The well-known hazardous effects of high doses of CO are attribut-able to its ability to bind hemoglobin and myoglobin, preventing the release of oxygen to tissues. However, only recently have the physiological and beneficial roles of CO been identified. CO is produced in injured tissues via induction of HO-1 and contrib-utes to the attenuation of proinflammatory processes. Similar to NO, CO plays an important role in maintaining the micro-circulation though its activation of soluble guanylyl cyclase and subsequent elevation of intracellular cyclic 3’5’-guanosine monophosphate (cGMP). The signaling activities of cGMP lead to smooth muscle relaxation and inhibition and platelet aggre-gation. In addition, CO has also been shown to inhibit proin-flammatory cytokines (TNF-α, IL-1) and chemokines while simultaneously inducing anti-inflammatory cytokines (IL-10). Exogenous low-dose CO has been shown to protect the liver from I/R injury and endotoxemia.Biliverdin and bilirubin are other metabolites of heme that are also recognized as possible mediators of HO-1’s protective Brunicardi_Ch31_p1345-p1392.indd 135620/02/19 2:36 PM 1357LIVERCHAPTER 31function. The cytosolic enzyme biliverdin reductase catalyzes the reduction of biliverdin to bilirubin. Both biliverdin and bilirubin have important endogenous antioxidant properties. Free iron, the third byproduct of heme oxidation is known to be cytotoxic by catalyzing the production of hydroxyl radicals. However, HO-1 induction is associated with increased levels of ferritin, the free iron sequestering protein. Thus, the increase in ferritin with the subsequent decrease in intracellular concentra-tions of free iron results in a net antioxidant effect. Importantly, both bilirubin and ferritin have been shown to protect against liver injury in a variety of I/R models.In summary, HO-1 is upregulated and protective in mul-tiple conditions of hepatic stress. Until recently, the degradation products of the HO system were thought to only be potentially toxic waste. It now appears that CO, biliverdin/bilirubin, ferritin are important in the maintenance of cellular redox homeostasis and may play a role in the mechanism of hepatoprotection in disease. Studies involving induction of HO-1 expression and use of its metabolic products hold therapeutic promises for novel protective agents against disorders of hepatic inflammation.16,17Toll-Like ReceptorsThe liver is a central regulator of the systemic immune response following acute insults to the body. Not only does it play a cru-cial role in modulating the systemic inflammatory response to infection or injury, it is also subject to injury and dysfunc-tion from these same processes. Recent advances in the study of mechanisms for the activation of the innate immune system have pointed to the Toll-like receptors (TLRs) as a common pathway for immune recognition of microbial invasion and tis-sue injury. By recognizing either microbial products or endog-enous molecules released from damaged sites, the TLR system is capable of alerting the host of danger by activating the innate immune system. Initially, this is manifested by the production of inflammatory mediators and the rapid uptake of invading microbes and their products. When excessive, this inflamma-tory response can contribute to organ damage and dysfunction.To date, 13 TLRs have been described in mice, and 11 in humans. TLRs are a family of proteins that are mammalian homologues to the Drosophila Toll, a protein that functions in development and immunity. The cytoplasmic portion of Toll-like receptors is similar to that of the IL-1 receptor (IL-1R) fam-ily and is called the Toll/IL-1 receptor (TIR) domain. Unlike the IL-1 receptor extracellular portion that consists of an immuno-globulin-like domain, the Toll-like receptors have leucine-rich repeats in their extracellular portion. The TLR receptors have many structural similarities both extracellularly and intracel-lularly, but they differ from each other in ligand specificities, expression patterns, and with some variability in the signaling pathways they activate.The TLR receptors were initially identified as compo-nents of the innate immune system that acted as a front-line defense mechanism against infections. Their recognition of patterns on pathogens, such as microbial peptides, lipopolysac-charide, lipoteichoic acids, bacterial DNA, and single-stranded RNA, resulted in the activation of an inflammatory response meant for controlling the invading organisms. In situations of noninfectious inflammation such as seen in trauma, clinicians have long recognized similar activation of the same inflamma-tory pathways and systemic manifestations. This observation, among others, led to the hypothesis that the immune system is designed to recognize any threats, whether from pathogens or tissue damage, that may lead to disruption of homeostasis. In conditions of sterile inflammation, the activation of immune cells is through the release of endogenous danger molecules, normal cell constituents released by damage or dying cells or components of the extracellular matrix, released by the action of proteases at the site of tissue damage. Recent observations show that both microbial products and endogenous danger molecules can be recognized through the TLR system.Perhaps more than any of the other TLR family members, TLR4 sits at the interface of microbial and sterile inflammation. Whereas the role of TLR4 in the recognition of lipopolysac-charide (LPS) is well established, only recently has it become apparent that TLR4 also participates in the recognition of endogenous danger molecules. In vivo evidence for TLR4-mediated danger signaling comes from studies of acute tissue injury in hemorrhagic shock, trauma, and I/R models. In each case, TLR4-mutant animals exhibited reduced injury or inflam-mation compared to wild-type controls. In efforts to identify the ligands responsible for TLR4-dependent signaling in noninfec-tious insults, multiple molecules have been suggested. These include heat shock proteins, fibrinogen, hyaluronic acid, hepa-ran sulfate, and high mobility group box-1. Although a central role for TLR4 in recognizing tissue injury is building, studies are beginning to suggest that other TLR family members may also participate in the recognition of endogenous molecules released by tissue injury. The very recent realization that certain TLR family members also respond to endogenous molecules released from stressed or damaged tissues points to a molecular basis for a shared mechanism of innate immune activation by infection and injury.18-20RADIOLOGIC EVALUATION OF THE LIVERUltrasoundAbdominal ultrasound is a commonly applied imaging modal-ity used to evaluate abdominal symptoms. Ultrasound tech-nology is based on the pulse-echo principle. The ultrasound transducer converts electrical energy to high-frequency sound energy that is transmitted into tissue. Although some of the ultrasound waves are transmitted through the tissue, some are reflected back, and the ultrasound image is produced when the ultrasound receiver detects those reflected waves. This real-time gray-scale (B-mode) imaging is augmented by Doppler flow imaging. Doppler ultrasound not only can detect the pres-ence of blood vessels but also can determine the direction and velocity of blood flow. Ultrasonography is a useful initial imag-ing test of the liver because it is inexpensive, widely available, involves no radiation exposure, and is well tolerated by patients. It is excellent for diagnosing biliary pathology and focal liver lesions. In addition, liver injury can be evaluated in trauma patients using the focused abdominal sonography for trauma examination. Limitations of ultrasound include incomplete imaging of the liver, most often at the dome or beneath ribs on the surface, and incomplete visualization of lesion boundaries. Moreover, obesity and overlying bowel gas also can interfere with image quality. Thus, ultrasonographically detected masses usually require further evaluation by other imaging modalities due to the lower sensitivity and specificity of ultrasound com-pared with CT and MRI.The advent of contrast-enhanced ultrasound has improved the ability of this modality to differentiate among benign and malignant lesions. The injection of gas microbubble agents can Brunicardi_Ch31_p1345-p1392.indd 135720/02/19 2:36 PM 1358SPECIFIC CONSIDERATIONSPART IIincrease the sensitivity and specificity of ultrasound in detect-ing and diagnosing liver lesions. Microbubbles are <10 μm and, when given intravenously, allow for more effective echo enhancement. Contrast-enhanced ultrasound imaging of the liver improves delineation of liver lesions through identifica-tion of dynamic enhancement patterns and the vascular mor-phology of the lesion. In addition, some agents exhibit a late liver-specific phase in which the bubbles are taken up by cells in the reticuloendothelial system and accumulate in normal liver parenchyma after the vascular enhancement has faded.The use of intraoperative ultrasound of the liver has rap-idly expanded over the years with the increasing number and complexity of hepatic resections being performed.21 It has the ability to provide the surgeon with real-time accurate informa-tion useful for surgical planning. Intraoperative ultrasound is considered the gold standard for detecting liver lesions, and studies have shown that it can identify 20% to 30% more lesions than other preoperative imaging modalities. Impor-tantly, it has been shown to influence surgical management in almost 50% of planned liver resections for malignancies. Applications for intraoperative ultrasound of the liver include tumor staging, visualization of intrahepatic vascular structures (Fig. 31-10), and guidance of resection plane by assessment of the relationship of a mass to the vessels. In addition, biopsy of lesions and ablation of tumors can be guided by intraoperative ultrasound.Ultrasound elastography, also referred to as transient elastography, can be used to assess the degree of fibrosis or cirrhosis in the liver. Low-frequency vibrations transmitted through the liver induce an elastic shear wave that is detected by pulse-echo ultrasonography as the wave propagates through the liver. The velocity of the wave correlates with the stiffness of the organ—the wave travels faster through fibrotic or cirrhotic tissues. Ultrasound elastography has been found in large cohorts of individuals to have a sensitivity of 87% and a specificity of 91% for the diagnosis of cirrhosis when compared with liver biopsy.22 Unlike liver biopsy, ultrasound elastography is non-invasive and can be repeated often without additional risk to the patient. Furthermore, this rapid test can acquire information from a larger area of the tissue relative to needle biopsy, provid-ing a better understanding of the entire hepatic parenchyma and reducing sampling error.Computed TomographyCT produces a digitally processed cross-sectional image of the body from a large series of X-ray images. The introduction of helical (spiral) CT has improved the imaging capabilities of this technique compared to earlier conventional axial CT by combining a continuous patient-table motion with continuous rotation of the CT gantry and allowing rapid acquisition of a volume of data within a single breath hold. With the recent advent of multidetector row CT scanners, high-resolution images can be obtained in submillimeter section thickness within a short scan time, with virtually no penalty in increased radiation dose. Together, these technologic advances have led to reduced motion artifacts due to variations in inspiration, facili-tated optimal contrast delivery, and allowed for the capability to generate high-resolution reformations in any desired plane. In a single examination, modern-day CT scans provide detailed morphologic information on the number, size, distribution, and vascularity of liver lesions, all of which are vital in guiding the clinical management and therapeutic plan.Contrast medium is routinely used in CT evaluation of the liver because of the similar densities of most pathologic liver masses and normal hepatic parenchyma. A CT scan with a dualor triple-phase bolus of intravenous contrast agent is performed to achieve the greatest enhancement of contrast between nor-mal and pathologic tissues.23 Ideally, contrast media should be selectively delivered to either the tumor or the liver, but not both. Radiologists use the dual blood supply of the liver and the hemodynamics of hepatic tumors to achieve this goal. The liver is unique in that it has a dual blood supply. As previously noted, the portal vein supplies approximately 75% of the blood Figure 31-10. Intraoperative liver ultrasound images of the portal veins, hepatic veins, and inferior vena cava (IVC). Upper panel shows the portal vein bifurcation with echogenic Glissonian sheath. The confluence of the three hepatic veins (right hepatic vein [RHV], middle hepatic vein [MHV], and left hepatic vein [LHV]) and the IVC is shown in the middle panel. An accessory LHV is present in this patient. Lower panel is a color Doppler image showing flow.Brunicardi_Ch31_p1345-p1392.indd 135820/02/19 2:36 PM 1359LIVERCHAPTER 31flow and the hepatic artery the remaining 25%. However, many liver tumors receive the majority of their blood supply from the hepatic artery. After injection of the contrast agent, the rapid scan time of helical CT allows for CT sections through the liver in both the arterial dominant phase (20 to 30 seconds after the beginning of contrast delivery) and venous or por-tal dominant phase (60 to 70 seconds after contrast injection) (Fig. 31-11). Thus, many hepatic tumors that derive the major-ity of their blood supply from the hepatic artery as well as other hypervascular lesions are well delineated in the arterial phase. On the other hand, the portal phase provides optimal enhance-ment of the normal liver parenchyma because the majority of its blood supply is derived from the portal vein. This allows for detection of hypovascular lesions because they will appear hypoattenuated in relation to the brighter normal liver paren-chyma. Furthermore, the arterial and portal phase images allow for noninvasive mapping of the hepatic arterial and venous anat-omy, information that is crucial in the preoperative planning for patients undergoing liver surgery.CT cholangiography has emerged as a new imaging modal-ity for biliary disease. This technique usually involves the use of contrast agents, which are excreted by hepatocytes into the bile ducts. CT cholangiography, therefore, provides information on hepatocyte function and bile flow, in addition to high-resolution depiction of the biliary tree. It has compared well to endoscopic retrograde cholangiopancreatography (ERCP) in identifying obstructive biliary disease.24 One of the major advantages of CT cholangiography over other imaging modalities is the abil-ity to depict small nondilated peripheral biliary radicals. This technique may be useful in the context of live liver donation or complex biliary surgery to aid in the preoperative depiction of biliary anatomy. It also may be applicable in the postopera-tive setting for the detection of biliary leakage or obstruction. A limitation of CT cholangiography is that the biliary tree may not be well visualized in patients with excessively dilated bile ducts or in those with hyperbilirubinemia, as bilirubin excretion is impaired in these cases.Magnetic Resonance ImagingMRI is a technique that produces images based on magnetic fields and radio waves. The MRI scanner creates a powerful magnetic field that aligns the hydrogen atoms in the body, and radio waves are used to alter the alignment of this magnetiza-tion. Different tissues absorb and release radio wave energy at different rates, and this information is used to construct an image of the body. Most tissues can be differentiated by differ-ences in their characteristic T1 and T2 relaxation times. T1 is a measure of how quickly a tissue can become magnetized, and T2 measures how quickly it loses its magnetization. As with CT technology, advances in MRI now provide the opportunity to perform single-breath T1-weighted imaging and respiration-triggered T2-weighted imaging. The development of breath-hold imaging techniques has eliminated many of the motion artifacts that previously limited the sensitivity and application of MRI for imaging of the liver. Compared with CT scanning, the major advantages of MRI pertain to higher soft tissue contrast resolution and excellent depiction of fluid-containing structures, while obviating the need for ionizing radiation.As with the iodinated contrast media use in CT scanning, multiple contrast agents have been developed for MRI to increase the difference in signal intensity between normal liver and pathologic lesions. Various gadolinium-based compounds have been used as MRI contrast agents that behave in a manner very similar to iodine in CT. Liver-specific MRI contrast agents also have been developed that rely either on excretion by Kupffer cells, such as ferumoxide (Feridex, Advanced Magnet-ics, Cambridge, MA), or on secretion in bile by hepatocytes, including gadoxetate (Eovist or Primovist, Bayer-Schering, Berlin, Germany). These agents combine the information obtained during a standard MRI with additional functional data, which in turn yields improved detection and characteriza-tion of lesions within the liver.25Just as ultrasound elastography is useful in the diagno-sis of hepatic fibrosis and cirrhosis, magnetic resonance (MR) elastography appears promising as an imaging modality in 3Figure 31-11. Computed tomographic (CT) images of hepatic veins and Couinaud’s liver segments. The images show the three hepatic veins and inferior vena cava (IVC) (upper panel), as well as Couinaud’s liver segments (lower panels). LHV = left hepatic vein; MHV = middle hepatic vein; RHV = right hepatic vein.Brunicardi_Ch31_p1345-p1392.indd 135920/02/19 2:36 PM 1360SPECIFIC CONSIDERATIONSPART IIreducing the need for liver biopsy. In this technique, a vibration device is used to induce a shear wave in the liver. A modified MRI machine detects the shear wave, then generates a color-coded image that depicts the wave velocity, and hence stiffness, throughout the organ. Although preliminary studies have shown that MR elastography can detect cirrhosis with a high degree of accuracy, the clinical utility of this modality, especially given its relatively high cost, remains to be determined.Magnetic resonance cholangiopancreatography (MRCP) enables rapid, noninvasive depiction of both the biliary tree and the pancreatic duct without the use of ionizing radiation or intravenous contrast media. One of the most common clinical indications for MRCP is biliary obstruction. MRCP provides visualization of dilated bile ducts, and the high spatial and con-trast resolution often enables accurate assessment of the level of occlusion in the biliary tree. MRCP also can be enhanced with liver-specific MRI contrast agents that are actively secreted into the bile, but the clinical indications for such studies are still a matter of intensive investigation.26Positron Emission TomographyPositron emission tomography (PET) is a nuclear medicine test that produces images of metabolic activity in tissues by detect-ing gamma rays emitted by a radioisotope incorporated into a metabolically active molecule. Fluorodeoxyglucose (FDG) is the most common metabolic molecule used in PET imaging. Although traditional imaging such as CT, ultrasound, and MRI provide anatomic information, PET offers functional imaging of tissues with high metabolic activity, including most types of metastatic tumors. PET imaging increasingly is used as a tool in the diagnostic evaluation of a patient with potentially resectable hepatic disease. In nonrandomized trials, PET demonstrated bet-ter sensitivity and specificity than CT scanning for the detec-tion of both intrahepatic and extrahepatic disease.27 Integrated PET/CT improves diagnostic accuracy over standard PET or CT alone and has been shown to be sensitive in the detection of liver metastases derived from a wide range of cancers, including colorectal (Fig. 31-12), breast, or lung primaries.27More than 20% of patients with colorectal cancer ini-tially present with hepatic metastasis, and a large percentage of patients undergoing resection for their primary colorectal cancer eventually experience disease recurrence in the liver. The role of FDG-PET/CT in colorectal cancers lies predomi-nantly in tumor staging and follow-up, particularly in the detec-tion of occult intrahepatic metastases or extrahepatic disease. Although hepatic resection of colorectal metastases provides survival rates nearing 50%, the presence of extrahepatic dis-ease is a poor prognosticator and usually precludes aggressive surgical intervention. Thus, accurate information regarding the extent of the disease is necessary for management of patients with colorectal metastases. PET/CT has also been shown to be more accurate than contrast-enhanced CT in tumor surveillance after radiofrequency ablation.28 The sensitivity of FDG-PET, however, is lowered by neoadjuvant chemotherapy, most likely secondary to reduced metabolic activity within the tumor.Although the role of PET/CT in the clinical management of liver metastases has been well-established, its utility in the diagnostic workup of primary liver tumors is still debated. In hepatocellular carcinoma (HCC), FDG uptake correlates with the degree of differentiation—high-grade HCC lesions have increased FDG uptake compared to low-grade HCCs. As a result, the overall sensitivity of FDG-PET/CT in the detection of HCCs is reported to be only 50% to 65%, rendering this modality insufficient when used alone in the diagnosis of primary HCCs. For this reason, dual-tracer PET has been introduced to improve sensitivity in detecting all HCC. This modality combines the use of FDG, which accumulates in poorly differentiated tumors, with 11C-acetate, a tracer preferentially accumulated by well-differentiated HCC lesions. Although the clinical benefits of dual-tracer PET/CT have yet to be fully established, this com-bined modality has the potential to become a valuable tool in the diagnosis and staging of HCC. In cholangiocarcinoma tumors, FDG avidity depends on the morphologic characteristics and location of the lesion. Therefore, FDG-PET and FDG-PET/CT have not been shown to be highly beneficial in the diagnosis of primary cholangiocarcinoma, but they may be beneficial in the detection of regional and distal metastases, which can affect clinical decision making and patient management.ACUTE LIVER FAILUREAcute liver failure (ALF) occurs when the rate and extent of hepatocyte death exceeds the liver’s regenerative capabilities. It was initially described as a specific disease entity in the 1950s. Figure 31-12. Computed tomography (CT)–positron emission tomography (PET) scans before and after resection of liver metastasis from colorectal cancer in a 54-year-old patient. CT scan shows large 10-cm right lobe liver metastasis (left panel), and PET scan findings are strongly positive (middle panel). Two years after right hepatectomy, the patient has no evidence of recurrence and significant hypertrophy of the left lobe (right panel).Brunicardi_Ch31_p1345-p1392.indd 136020/02/19 2:36 PM 1361LIVERCHAPTER 31It also has been referred to as fulminant hepatic failure. ALF is a rare disorder affecting approximately 2000 patients annually in the United States. ALF is defined by the development of hepatic encephalopathy occurring within 26 weeks of severe liver injury in a patient without a history of previous liver dis-ease or portal hypertension.29 The manifestations of ALF may include cerebral edema, hemodynamic instability, increased sus-ceptibility to bacterial and fungal infections, renal failure, coag-ulopathy, and metabolic disturbances. Even with current medical care, ALF can progress rapidly to hepatic coma and death. The most common cause of death is intracranial hypertension due to cerebral edema, followed by sepsis and multisystem organ failure. The causes of ALF, which are the most important variables in determining outcome, are numerous and can include viral infection as well as drug overdose, reaction, and toxicity. It has been determined that the etiologic factor leading to ALF varies according to geographic location.30 Before the introduc-tion of orthotopic liver transplantation (OLT), the chance for survival was <20%. Currently, most series report 5-year survival rates of >70% for affected patients.31EtiologyDifferences in etiology, management, and patient outcomes have been described for various regions of the globe. In the East and developing portions of the world, the most common causes of ALF are viral infections, primarily hepatitis B, A, and E.20 In these areas, there are a relatively small number of drug-induced cases. In contrast, 65% of cases of ALF in the West are thought to be due to drugs and toxins, with acetaminophen (paracetamol) being the most common etiologic agent in the United States, Australia, United Kingdom, and most of Europe. In France and Spain, where acetaminophen sales are restricted, the rate of acetaminophen-induced ALF is quite low.32 Acetaminophen-induced ALF is also uncommon in South America. The U.S. Acute Liver Failure Study Group identified several other causes of ALF, including autoimmune hepatitis, hypoperfusion of the liver (in cardiomyopathy or cardiogenic shock), pregnancy-related conditions, and Wilson’s disease.33 Even with exhaustive efforts to identify a cause, approximately 20% of all cases of ALF remain indeterminate in origin.Clinical PresentationIn a multicenter study involving 17 tertiary care centers and 308 patients in the United States, 73% of all patients with ALF were female, with a median age of 38 years.34 The most common ethnic group affected was whites (74%), followed by Hispanics (9%) and African Americans (3%). Patients were ill for a median of 6 days before the onset of encephalopathy and had a median of 2 days between the onset of jaundice and the development of encephalopathy. Hepatic coma grade at presentation was approximately equally distributed across grades I to IV. Eighty-four percent of the patients in the study were referred from outside hospitals, 40% had a serum creatinine level exceeding 2.0 mg/dL, and 14% had an arterial pH of <7.30. In addition, 44% of the patients acquired a culture-proven infection.Diagnosis and Clinical ManagementWhen the medical history is obtained, it is important to address the possibility of exposure to viral infections, medications, and other possible toxins. The possibility of previous liver disease needs to be explored. The physical examination must assess and document the patient’s mental status as well as attempt to identify findings of chronic liver disease. The initial laboratory examination must evaluate the severity of the ALF as well as attempt to identify the cause (Table 31-1). A liver biopsy should be performed if certain disease entities such as autoimmune hepatitis or lymphoma are a possibility. Because of the asso-ciated coagulopathy, if a liver biopsy is needed, it is usually safest to obtain the tissue via a transjugular approach. Patients with ALF should be admitted to the hospital and monitored fre-quently. Due to the rapidity with which this disease process may progress, a liver transplant center should be contacted, and the affected patient should be transferred to the center early in the evaluation period.If acetaminophen overdose is suspected to have occurred within a few hours of presentation, administration of activated charcoal may be useful to reduce the volume of acetamino-phen present in the gastrointestinal (GI) tract. N-acetylcysteine (NAC), the clinically effective antidote for acetaminophen over-dose, should be administered as early as possible to any patient with suspected acetaminophen-associated ALF.35 NAC also should be administered to patients with ALF of unclear etiol-ogy because replenishing glutathione may be beneficial in this patient population as well.36 NAC can be administered either orally (140 mg/kg initial dose, followed by 70 mg/kg every 4 hours × 17 doses) or via the intravenous route (loading dose of 150 mg/kg, followed by a maintenance dose of 50 mg/kg every 4 hours × 12 doses). For patients who are suspected of having drug-induced hepatotoxicity, it is important to obtain details regarding all prescription and nonprescription drugs, herbs, and dietary supplements that may have been taken in the previous year. Most instances of drug-induced hepatotoxicity occur in the first 6 months after drug initiation. Any suspected offending agent must be discontinued, and an attempt should be made to administer only essential medications.The majority of patients with ALF need to be monitored in the intensive care unit (ICU) setting, and specific attention needs to be given to fluid management, ulcer prophylaxis, hemody-namic monitoring, electrolyte management, and surveillance for and treatment of infection. Surveillance cultures should be performed to identify bacterial and fungal infections as early as possible. Serum phosphorus levels need to be monitored. 4Table 31-1Acute liver failure laboratory evaluationComplete blood countComplete metabolic panelAmylase and lipase levelsLiver function testsProthrombin time/international normalized ratioFactor V levelFactor VII levelArterial blood gas concentrationsArterial serum ammonia levelABO typingAcute hepatitis panelAutoimmune marker levelsCeruloplasmin levelToxicology screeningAcetaminophen levelHIV screeningPregnancy test (females)HIV = human immunodeficiency virus.Brunicardi_Ch31_p1345-p1392.indd 136120/02/19 2:36 PM 1362SPECIFIC CONSIDERATIONSPART IIHypophosphatemia, a sign of hepatic regeneration, may indi-cate a higher likelihood of spontaneous recovery and needs to be corrected via intravenous (IV) administration of phosphate. Sedation should be avoided, and the head of the bed should be elevated at least 30°. Neurologic examinations should be per-formed frequently. Intracranial pressure monitoring is reserved for patients in whom a neurologic examination is no longer reli-able. CT scans of the head should be performed to rule out mass lesion or hemorrhage, but they provide only limited informa-tion regarding increased intracranial pressure. The administra-tion of blood products for thrombocytopenia and prolonged PT is recommended only in the setting of hemorrhage or before invasive procedures. Acute renal failure is a frequent complica-tion in patients with ALF, and efforts should be made to protect renal function by maintaining sufficient perfusion and avoid-ing nephrotoxic medications. Should renal replacement therapy become necessary, continuous venovenous hemodialysis should be used rather than intermittent hemodialysis because continu-ous venovenous hemodialysis provides better hemodynamic and intracranial pressure stability. The most severely affected patients have a poor prognosis with medical management alone and require liver transplantation. Identifying these patients early in the clinical course is important both to maximize the time available to obtain a donor liver allograft for those in need and to avoid transplant in those who will recover without it.PrognosisAccurate identification of ALF patients who will recover spon-taneously is important because of the severe shortage of donor liver allografts and the potential complications of lifelong non-specific immunosuppression. The most widely applied prognos-tic scoring system is the King’s College Hospital ALF criteria.37 This scoring system has separate criteria predicting a poor medical management outcome for acetaminophen-related and non–acetaminophen-related forms of ALF (Table 31-2). Many other prognostic models exist such as the Acute Physiology and Chronic Health Evaluation II (APACHE II) score, the Clichy criteria,38 and actin-free Gc-globulin serum concentration.39 Overall, prognostic scoring systems have proven to have acceptable specificity but low sensitivity in determining patient outcome and therefore should not replace the judgment of an experienced clinician.40Liver TransplantationDespite advances in medical management, OLT remains the only definitive therapy for patients unable to regenerate sufficient hepatocyte mass in a timely manner. The advent of OLT has coincided with a rise in overall ALF survival rates from approxi-mately 20% in the pretransplantation era to >70% at the pres-ent time. One-year posttransplantation survival for patients with ALF has been reported to be as high as 80% to 90%.31 Although these improvements in survival rates are impressive, it should be noted that 10% of patients still die while awaiting OLT, which confirms that the potential for improved patient outcome still has not been realized because of the ongoing liver allograft shortage.Emerging TechnologiesAs mentioned earlier, patient survival could be improved if additional time could be gained for the patient while awaiting liver replacement or hepatocyte regeneration. The development of a support device to replace the acutely failing liver has been a highly sought after (and elusive) goal. Several systems have been tested without definitive evidence of efficacy. Transient improvement in hepatic encephalopathy has been observed in several trials, but improvement in hepatocyte function and long-term benefit have not been realized.41 Liver support trials are dif-ficult to perform due to access to liver replacement, the rarity of affected patients, and the heterogeneous causes and varying levels of disease severity. Therefore, additional data are necessary, and liver support systems should be used only as part of an approved clinical trial. Focus has now shifted toward xenotransplantation,42 organ engineering, and cell transplantation.43 In the meantime, living donation and auxiliary liver transplantation can help over-come the organ shortage.44CIRRHOSIS AND PORTAL HYPERTENSIONCirrhosis, the final sequela of chronic hepatic insult, is char-acterized by the presence of fibrous septa throughout the liver subdividing the parenchyma into hepatocellular nodules (Fig. 31-13).45 Cirrhosis is the consequence of sustained wound healing in response to chronic liver injury. Approximately 40% of cirrhotic patients are asymptomatic, but progressive deteriora-tion leading to the need for liver transplantation or death is typi-cal after the development of end-stage liver disease (ESLD). The complications of ESLD include progressive hyperbilirubinemia, malnutrition, decreased synthetic function of the liver, coagu-lopathy, portal hypertension (i.e., ascites and variceal bleeding), hepatic encephalopathy, and life-limiting fatigue. ESLD car-ries a 5-year mortality of 50%, with 70% of deaths due to liver failure.46 In the United States, cirrhosis accounts for 30,000 deaths per year and is the most common nonneoplastic cause of death among patients with hepatobiliary and digestive diseases. An additional 10,000 to 12,000 deaths occur annually due to HCC, the most rapidly increasing neoplasm in the United States.46Morphologic Classification of CirrhosisMorphologically, cirrhosis can be described as micronodular, macronodular, or mixed. Micronodular cirrhosis is characterized Table 31-2King’s College selection criteria for liver transplantation in acute liver failureCAUSESELECTION CRITERIAAcetaminophenArterial pH < 7.30 irrespective of hepatic coma gradeOrProthrombin time >100 s + serum creatinine level >3.4 mg/dL + grade III or IV hepatic comaNot acetaminophenProthrombin time >100 s irrespective of hepatic coma gradeOrAny three of the following, irrespective of hepatic coma grade: Cryptogenic or drug-induced hepatitis Jaundice to coma interval >7 d Prothrombin time >50 s Serum bilirubin level >17.5 mg/dL Age < 10 y or > 40 yBrunicardi_Ch31_p1345-p1392.indd 136220/02/19 2:36 PM 1363LIVERCHAPTER 31by thick regular septa, small uniform regenerative nodules, and involvement of virtually every hepatic lobule. Macronodular cirrhosis frequently has septa and regenerative nodules of vary-ing sizes. The regenerative nodules consist of irregularly sized hepatocytes with large nuclei and cell plates of varying thick-ness. Mixed cirrhosis is present when regeneration is occurring in a micronodular liver and over time converts to a macronodu-lar pattern. This morphologic categorization is limited, and cir-rhosis is a dynamic process in which nodule size varies over time. The three patterns correlate poorly with etiology, and the same pattern can result from a variety of disease processes. Conversely, a single disease process can demonstrate several morphologic patterns. Irrespective of etiology and morphologic pattern, the cirrhotic liver frequently demonstrates right hepatic lobe atrophy, caudate lobe and left lateral segment hypertrophy, recanalization of the umbilical vein, a nodular surface contour, dilatation of the portal vein, gastroesophageal varices, and sple-nomegaly on radiographic evaluation.Etiology of CirrhosisCirrhosis can result from a wide range of disease processes, including viral, autoimmune, drug-induced, alcohol-induced, nonalcoholic fatty liver disease, and metabolic diseases (Table 31-3). In the diagnosis of alcoholic liver disease, docu-mentation of chronic alcohol abuse is imperative. Liver biopsy will reveal the typical findings of alcoholic hepatitis, including hepatocyte necrosis, Mallory bodies, neutrophil infiltration, and perivenular inflammation.Nonalcoholic fatty liver disease (NAFLD) covers a wide spectrum of disorders including simple fatty liver, nonalcoholic steatohepatitis (NASH), fibrosis/cirrhosis and NASH-associated hepatocellular carcinoma.47 NAFLD is now the most common chronic liver disease worldwide48 and NASH is a progressive form of NAFLD characterized by steatosis with hepatocellular injury and chronic inflammation.49 NASH affects 3% to 5% of the population, and approximately 1 in 10 NASH patients will progress to cirrhosis, thereby placing them at risk for the well-described consequences of cirrhosis, including hepatocellular carcinoma.50 Although hepatocellular carcinoma arises less fre-quently in patients with NASH compared to other liver diseases (e.g., hepatitis C viral infection), the overall higher prevalence and more rapidly increasing incidence of NASH relative to other chronic liver diseases mean that the majority of HCC will arise in the setting of NAFLD in the near future.51,52Patients with nonalcoholic steatohepatitis (NASH) often endorse a history of diabetes mellitus or metabolic syndrome. The diagnosis of NASH requires the demonstration of steato-hepatitis on biopsy, the lack of a history of significant alcohol consumption, and exclusion of other causes of hepatic steatosis. Although cryptogenic cirrhosis, or cirrhosis without an apparent cause, accounted for a third of all cases in the past, this propor-tion has declined over time as it becomes increasingly appar-ent that many of such patients may actually have unrecognized NASH.Due to the high prevalence of fatty liver disease, many patients considered for hepatic surgery will have background hepatic steatosis or steatohepatitis. In addition, chemotherapy treatment (e.g., irinotecan) for colorectal cancer liver metasta-ses induces steatosis and steatohepatitis in the nontumor-bearing liver.53 This has important implications as fatty liver disease can increase morbidity after liver resection.54,55 Thus, under-standing the deleterious effects of steatosis and steatohepatitis Figure 31-13. Histology of cirrhotic liver with regenerating mac-ronodules. Upper panel: Grossly cirrhotic liver. Lower panel: Regenerative nodules and bridging fibrosis representative of cir-rhosis seen on standard light microscopy (hematoxylin and eosin stain).Table 31-3Etiology of cirrhosisViral hepatitis (hepatitis B, C, and D)CryptogenicAlcohol abuseMetabolic abnormalities Iron overload (hemochromatosis) Copper overload (Wilson’s disease) α1-Antitrypsin deficiency Glycogen storage disease (types IA, III, and IV) Tyrosinemia GalactosemiaNonalcoholic fatty liver disease (NAFLD) and nonalcoholic steatohepatitis (NASH)Hepatic vein outflow abnormalities Budd-Chiari syndrome Cardiac failureAutoimmune hepatitisToxins and drugsBrunicardi_Ch31_p1345-p1392.indd 136320/02/19 2:36 PM 1364SPECIFIC CONSIDERATIONSPART IIis crucial for the multidisciplinary care of patients undergoing liver surgery.Chronic hepatitis C infection is the most common cause of chronic liver disease and the most frequent indication for liver transplantation in the United States. The identification of chronic hepatitis C infection is facilitated by serologic assays that detect antibody to hepatitis C and molecular assays that quantify hepatitis C viral RNA. Chronic hepatitis B, on the other hand, can be diagnosed based on the detection of hepatitis B surface antigen (HBsAg) more than 4 to 6 months after initial infection. Additional tests of hepatitis B viral replication, such as the hepatitis B e antigen (HBeAg) and hepatitis B viral DNA, can be used to confirm ongoing infection and to guide appropri-ate antiviral therapy.Autoimmune causes of cirrhosis include primary bili-ary cirrhosis, primary sclerosing cholangitis, and autoimmune hepatitis. Patients with primary biliary cirrhosis may be asymp-tomatic or may present with a history of fatigue, pruritus, and skin hyperpigmentation that is not related to jaundice. Anti-mitochondrial antibodies will test positive in the vast majority of cases. Affected patients also may have marked elevations in serum cholesterol, while hyperbilirubinemia is seen late in the course of the disease. Primary sclerosing cholangitis is a chronic cholestatic disease of the liver associated with ulcer-ative colitis and Crohn’s disease. The clinical presentation can include pruritus, steatorrhea, fat-soluble vitamin deficiencies, and metabolic bone disease. The diagnosis is often established by imaging of the biliary tree, which reveals a characteristic picture of diffuse, multifocal strictures with focal dilation of the bile ducts resulting in a beaded appearance. Complications are common and can include biliary strictures, cholangitis, choleli-thiasis, and cholangiocarcinoma. Autoimmune hepatitis is often accompanied by an elevation in serum globulins, particularly gamma globulins. Liver biopsy will show nonspecific changes such as a portal mononuclear cell infiltrate with the character-istic presence of plasma cells. Many patients with autoimmune hepatitis will respond to treatment with prednisone with or with-out azathioprine.Hereditary hemochromatosis is the most common meta-bolic disorder causing cirrhosis. This entity should be suspected if the patient’s clinical presentation includes skin hyperpigmen-tation, diabetes mellitus, pseudogout, cardiomyopathy, or a fam-ily history of cirrhosis. Elevated plasma ferritin and increased iron saturation levels suggest the presence of iron overload, but these findings also can be seen in other diseases of the liver. Confirmatory testing can be achieved by means of genetic test-ing, liver biopsy, or by assessing the response to phlebotomy. Other uncommon metabolic disorders leading to cirrhosis include Wilson’s disease and α1-antitrypsin deficiency.Clinical Manifestations of CirrhosisThe clinical history associated with cirrhosis can include fatigue, anorexia, weight loss, jaundice, abdominal pain, peripheral edema, ascites, GI bleeding, and hepatic encephalopathy. On physical examination, a number of findings have been described in patients with cirrhosis. Spider angiomata and palmar ery-thema are believed to be caused by alterations in sex hormone metabolism. Finger clubbing may be a consequence of hypo-albuminemia, while the pathogenesis of white nail beds and Dupuytren’s contractures are less well understood. Males may develop features of feminization such as gynecomastia, loss of chest and axillary hair, and testicular atrophy. Splenomegaly is common, whereas the cirrhotic liver itself may be enlarged, nor-mal sized, or small. Ascites and pleural effusion can be seen with fluid accumulation. Portal hypertension can manifest as caput medusae and/or the presence of the Cruveilhier-Baumgarten murmur, a venous hum that can be auscultated in the epigas-trium resulting from collaterals between the portal system and the remnant of the umbilical vein. Jaundice usually does not appear until the bilirubin rises above 2 to 3 mg/dL. Asterixis can be detected in patients with hepatic encephalopathy. Other manifestations include fetor hepaticus, as well as features sug-gestive of malnutrition such as weakness, weight loss, and tem-poral muscle wasting.Although fat stores and muscle mass are reduced, rest-ing energy expenditure is increased. Muscle cramps occur frequently in the cirrhotic patient and are felt to correlate with ascites, low mean arterial pressure, and plasma renin activity. Abdominal hernias are common with ascites and should be electively repaired only in patients with well-compensated cir-rhosis; otherwise, the hernia should be repaired at the time of or after hepatic transplantation. HCC can occur in all forms of cirrhosis, and every cirrhotic patient should undergo screening for the development of HCC every 6 months via imaging and measurement of a serum α-fetoprotein (AFP) level. Cirrhosis is associated with increased cardiac output and heart rate as well as decreased systemic vascular resistance and blood pres-sure. Patients with cirrhosis are more prone to infections due to impaired phagocytic activity of the reticuloendothelial system. Bacterial infections, often of intestinal origin, are common and must be suspected in a patient with unexplained pyrexia or clini-cal deterioration. Spontaneous bacterial peritonitis also is seen in cases of cirrhosis with ascites. Intrinsic drug metabolism is reduced in the cirrhotic liver, and this fact needs to be recog-nized when prescribing medications.Laboratory Findings Associated With CirrhosisLaboratory findings vary in the cirrhotic patient depending on the degree of compensation; however, in general, a number of trends are seen. The cirrhotic patient usually has a mild normo-cytic normochromic anemia. The white blood cell and platelet counts are reduced, and the bone marrow is macronormoblastic. The PT is prolonged and does not respond to vitamin K therapy, and the serum albumin level is depressed. Urobilinogen is pres-ent and urinary sodium excretion is diminished in the presence of ascites. The serum levels of bilirubin, transaminases, and alkaline phosphatase may all be elevated. However, normal liver function test results do not eliminate the possibility of cirrhosis.Liver BiopsyThe diagnosis of cirrhosis can be made in many cases from a constellation of clinical features, laboratory values, and radio-graphic findings. Histopathologic examination of liver tissue is occasionally needed to confirm the diagnosis of cirrhosis and in determining disease etiology, activity, and progression. Liver biopsy can be performed via a percutaneous, transjugular, or laparoscopic approach. If needed, ultrasound or CT guidance can be helpful in obtaining an adequate sample and avoiding other viscera.Various serologic markers of hepatic fibrosis are currently being investigated to help predict the presence of cirrhosis with-out the need for liver biopsy. However, no currently available marker is sufficiently accurate for clinical use. Ultrasound elas-tography, which measures the stiffness of the liver by inducing Brunicardi_Ch31_p1345-p1392.indd 136420/02/19 2:36 PM 1365LIVERCHAPTER 31an elastic shear wave that propagates through the tissue, shows promise as a noninvasive test in identifying patients with advanced fibrosis and cirrhosis. (See earlier section, “Radio-logic Evaluation of the Liver.”)Hepatic Reserve and Assessment of Surgical Risk in the Cirrhotic PatientAssessing the hepatic reserve of the cirrhotic patient is impor-tant because cirrhosis and portal hypertension can have a negative impact on the outcome of nontransplant surgical pro-cedures. Patients with liver disease undergoing surgery are at increased risk for surgical and anesthesia-related complications. The actual risk depends on the type of anesthetic used, the spe-cific surgical procedure performed, and the severity of liver disease. Previous studies have demonstrated that emergency operations, cardiac surgery, hepatic resections, and abdominal surgery, particularly cholecystectomy, gastric resection, and colectomy, generate the highest operative risk among cirrhotic patients. Additionally, preoperative patient characteristics such as anemia, ascites, encephalopathy, malnutrition, hypoalbumin-emia, hypoxemia, infection, jaundice, portal hypertension, and prolonged PT have also been associated with inferior outcomes after surgery. Nontransplant surgical procedures are contraindi-cated in patients with acute fulminant hepatitis and those with severe decompensated chronic hepatitis.A number of laboratory tests have been used to assess hepatic reserve in patients with cirrhosis. Tests of indocyanine green, sorbitol, and galactose elimination capacity as well as the carbon-13 galactose breath test and carbon-13 aminopyrine breath test have all been disappointing clinically due to their dependence on flow to the liver as well as the unavailability and complexity of the tests. The monoethylglycinexylidide (MEGX) test, which measures MEGX formation after the administration of lidocaine, has been shown to be approximately 80% sensitive and specific in diagnosing cirrhosis. However, this test loses both sensitivity and specificity as the serum bilirubin level rises and interferes with the fluorescent readout system.Child-Turcotte-Pugh ScoreThe Child-Turcotte-Pugh (CTP) score was originally developed to evaluate the risk of portocaval shunt procedures performed for portal hypertension and subsequently has been shown to be useful in predicting surgical risks of other intra-abdominal operations on cirrhotic patients (Table 31-4). Numerous studies have demonstrated overall surgical mortality rates of 10% for patients with class A cirrhosis, 30% for those with class B cir-rhosis, and 75% to 80% for those with class C cirrhosis.56 The CTP score is derived from five variables as shown in Table 31-4. The problems with the CTP score are the presence of subjective variables (encephalopathy and ascites), its narrow range (5 to 15 points), and the equal weighting given to each variable. Multiple retrospective studies have demonstrated that perioperative mor-tality and morbidity rates correlate well with the CTP score, and for over 30 years, this measure had been used as the principal predictor of operative risk.Model for End-Stage Liver Disease Scoring SystemThe Model for End-Stage Liver Disease (MELD) is a linear regression model based on three objective laboratory values (INR, bilirubin level, and creatinine level). It was originally developed as a tool to predict mortality after transjugular intrahepatic portosystemic shunt (TIPS) but has been validated and used as the sole method of liver transplant allocation in the United States since 2002. The MELD formula is as follows:MELD Score = 9.57 Ln(SCr) + 3.78 Ln(Tbil) + 11.2 Ln(INR) + 6.43where Ln represents natural logarithm, SCr is serum creatinine level (in milligrams per deciliter), and Tbil is serum bilirubin level (in milligrams per deciliter).A number of studies have examined the relative values of MELD and CTP scores in predicting postoperative mortality in cirrhotic patients undergoing nontransplant surgical procedures. Northup and colleagues demonstrated that MELD score was the only statistically significant predictor of 30-day mortality.57 In this study, mortality increased by approximately 1% for each MELD point up to a score of 20 and by 2% for each MELD point above 20. A comparison of the MELD model with the CTP classification showed good correlation between the two measures in predicting mortality, especially in the setting of emergency surgery.58 In these studies, the relative risk of mortal-ity increased by 14% for each 1-point increase in MELD score. As a result, it has been proposed that patients with a MELD score below 10 can safely undergo elective surgery, those with MELD between 10 and 15 may undergo surgery with caution, while those with MELD scores in excess of 15 should not be subjected to elective surgical procedures.59Portal HypertensionThe portal venous system contributes approximately 75% of the blood and 72% of the oxygen supplied to the liver. In the average adult, 1000 to 1500 mL/min of portal venous blood is supplied to the liver. However, this amount can be significantly increased in the cirrhotic patient. The portal venous system is without valves and drains blood from the spleen, pancreas, gallbladder, and abdominal portion of the alimentary tract into the liver. Tributaries of the portal vein communicate with veins draining directly into the systemic circulation. These collateral communications occur at the gastroesophageal junction, anal canal, falciform ligament, splenic venous bed and left renal vein, and retroperitoneum (Fig. 31-14). The normal portal venous pressure is 5 to 10 mmHg, and at this pressure, very little blood is shunted from the portal venous system into the systemic circulation. As portal venous pressure increases, however, the Table 31-4Child-Turcotte-Pugh (CTP) scoreVARIABLE1 POINT2 POINTS3 POINTSBilirubin level< 2 mg/dL2–3 mg/dL> 3 mg/dLAlbumin level> 3.5 g/dL2.8– 3.5 g/dL< 2.8 g/dLInternational normalized ratio< 1.71.7–2.2> 2.2EncephalopathyNoneControlledUncontrolledAscitesNoneControlledUncontrolledChild-Turcotte-Pugh class Class A = 5–6 points Class B = 7–9 points Class C = 10–15 pointsBrunicardi_Ch31_p1345-p1392.indd 136520/02/19 2:36 PM 1366SPECIFIC CONSIDERATIONSPART IIcollateral communications with the systemic circulation dilate, and a large amount of blood may be shunted around the liver and into the systemic circulation.Imaging of the Portal Venous System and Measurement of Portal Venous PressureThe patency of the portal vein and the nature of the collateral circulation should be established. An understanding of portal vein patency and anatomy is crucial before undertaking porto-systemic shunts, hepatic resection, or hepatic transplantation. The simplest initial investigation is abdominal ultrasonography. A large portal vein suggests portal hypertension but is not diag-nostic. Doppler ultrasound is capable of outlining the anatomy of the portal vein, excluding the presence of thrombosis, and identifying the direction of portal venous blood flow. Doppler ultrasound also is useful in evaluating blood flow through sur-gical shunts and TIPS. Abdominal CT and magnetic resonance angiography both are capable of revealing portal vein anatomy as well as patency. Visceral angiography and portal venography are reserved for cases that cannot be evaluated satisfactorily by noninvasive methods and require further clarification of portal patency or anatomy.The most accurate method of determining portal hyperten-sion is hepatic venography. The most commonly used procedure involves placing a balloon catheter directly into the hepatic vein and measuring the free hepatic venous pressure (FHVP) with the balloon deflated and the wedged hepatic venous pressure (WHVP) with the balloon inflated to occlude the hepatic vein. The hepatic venous pressure gradient (HVPG) is then calcu-lated by subtracting the free from the wedged venous pressure (HVPG = WHVP – FHVP). The HVPG represents the pressure in the hepatic sinusoids and portal vein and is a measure of por-tal venous pressure. Clinically significant portal hypertension is evident when HVPG exceeds 10 mmHg.Etiology and Clinical Features of Portal HypertensionThe causes of portal hypertension can be divided into three major groups: presinusoidal, sinusoidal, and postsinusoidal.60 Although multiple disease processes can result in portal hyper-tension (Table 31-5), in the United States, the most common cause of portal hypertension is usually an intrahepatic one, namely, cirrhosis. The most significant clinical finding asso-ciated with portal hypertension is the development of gastro-esophageal varices, which are mainly supplied by the anterior branch of the left gastric (coronary) vein.a1aFGE1ABbD24cde 3C5Figure 31-14. Intra-abdominal venous flow pathways leading to engorged veins (varices) from portal hypertension. 1, Coro-nary vein; 2, superior hemorrhoidal veins; 3, paraumbilical veins; 4, Retzius’ veins; 5, veins of Sappey; A, portal vein; B, splenic vein; C, superior mesenteric vein; D, inferior mesenteric vein; E, inferior vena cava; F, superior vena cava; G, hepatic veins; a, esophageal veins; a1, azygos system; b, vasa brevia; c, middle and inferior hem-orrhoidal veins; d, intestinal; e, epigastric veins.Table 31-5Etiology of portal hypertensionPresinusoidal Sinistral/extrahepatic  Splenic vein thrombosis  Splenomegaly  Splenic arteriovenous fistula Intrahepatic  Schistosomiasis  Congenital hepatic fibrosis  Nodular regenerative hyperplasia  Idiopathic portal fibrosis  Myeloproliferative disorder  Sarcoid  Graft-versus-host diseaseSinusoidal Intrahepatic  Cirrhosis   Viral infection   Alcohol abuse   Primary biliary cirrhosis   Autoimmune hepatitis   Primary sclerosing cholangitis   Metabolic abnormalityPostsinusoidal Intrahepatic  Vascular occlusive disease Posthepatic  Budd-Chiari syndrome  Congestive heart failure  Inferior vena caval web  Constrictive pericarditisBrunicardi_Ch31_p1345-p1392.indd 136620/02/19 2:36 PM 1367LIVERCHAPTER 31Portal hypertension also results in splenomegaly with enlarged, tortuous, and even aneurysmal splenic vessels. Spleno-megaly is frequently associated with functional hypersplenism, causing leukopenia, thrombocytopenia, and anemia. Ascites occurs in the setting of severe portal hypertension in combina-tion with hepatocyte dysfunction. The umbilical vein may recan-nulate and dilate, leading to visible collaterals on the abdominal wall. Anorectal varices are present in approximately 45% of cirrhotic patients and must be distinguished from hemorrhoids, which do not communicate with the portal system and are not present at increased incidence in patients with portal hyperten-sion. Large spontaneous venous shunts may form between the portal venous system and the left renal vein or the IVC, but these shunts are ineffective in reducing portal venous pressures and preventing bleeding from gastroesophageal varices.Management of Gastroesophageal VaricesThe most significant manifestation and the leading cause of mor-bidity and mortality related to portal hypertension is variceal bleeding. Approximately 30% of patients with compensated cir-rhosis and 60% of patients with decompensated cirrhosis have esophageal varices. One third of all patients with varices will experience variceal bleeding. Each episode of bleeding is associ-ated with a 20% to 30% risk of mortality. If left untreated, 70% of patients who survive the initial bleed will experience recurrent variceal hemorrhage within 2 years of the index hemorrhage.Prevention of Variceal BleedingCurrent measures aimed at preventing variceal bleeding include the administration of nonselective β-blockers and prophylac-tic endoscopic surveillance with variceal band ligation. Meta-analyses have demonstrated that nonselective β-blockers such as propranolol and nadolol reduce the index variceal bleed by approximately 45% and decrease bleeding mortality by 50%.61 However, approximately 20% of patients do not respond to β-blockade, and another 20% cannot tolerate β-blockade due to medication side effects. Endoscopic surveillance with prophy-lactic variceal band ligation has been associated with a lower incidence of a first variceal bleed.62 Variceal band ligation is rec-ommended for patients with medium to large varices, performed every 1 to 2 weeks until obliteration, followed by esophagogas-troduodenoscopy (EGD) 1 to 3 months later and surveillance EGD every 6 months to monitor for recurrence of varices.Management of Acute Variceal HemorrhagePatients with acute variceal hemorrhage should be admitted to an ICU for resuscitation and management. Blood resuscitation should be performed carefully to reach a hemoglobin level of approxi-mately 8 g/dL. Overzealous replacement of blood products and administration of saline can lead to both rebleeding and increased mortality. Administration of fresh frozen plasma and platelets can be considered in patients with severe coagulopathy. Use of recom-binant factor VIIa has not been shown to be more beneficial than standard therapy and therefore is not recommended at this time. Cirrhotic patients with variceal bleeding have a high risk of devel-oping bacterial infections, which are associated with increased risks of rebleeding and mortality. Spontaneous bacterial peritoni-tis accounts for approximately half of these infections, with uri-nary tract infections and pneumonias comprising the remainder. The use of short-term prophylactic antibiotics (e.g., ceftriaxone 1 g/d intravenously) has been shown both to decrease the rate of bacterial infections and to increase survival.Vasoactive medications decrease blood flow to the gastro-esophageal varices and can be initiated as soon as the diagnosis of variceal bleeding is made. Although vasopressin is the most potent available vasoconstrictor, its use is limited by its systemic vasoconstrictive effects that can produce hypertension, myocar-dial ischemia, arrhythmias, ischemic abdominal pain, and limb gangrene. Octreotide, a somatostatin analog, has the advantage that it can be administered for 5 days or longer, and it is currently the preferred pharmacologic agent for initial management of acute variceal bleeding. In addition to pharmacologic therapy, endos-copy with variceal band ligation should be carried out as soon as possible. This combination of pharmacologic and endoscopic therapy has been shown both to improve the initial control of bleeding and to increase the 5-day hemostasis rate.62Luminal TamponadeWhen medical and endoscopic measures fail to control variceal hemorrhage, balloon tamponade using a Sengstaken-Blakemore tube will control refractory bleeding in up to 90% of patients. However, its application is limited due to the potential for com-plications, which include aspiration, airway obstruction, and esophageal perforation due to overinflation or pressure necro-sis. Therefore, the use of a Sengstaken-Blakemore tube should not exceed 36 hours to avoid tissue necrosis, and this treatment modality should only be considered a temporary bridge to more definitive measures of variceal hemorrhage control.Transjugular Intrahepatic Portosystemic ShuntThe TIPS procedure involves implantation of a metallic stent between an intrahepatic branch of the portal vein and a hepatic vein radicle. The needle track is dilated until a portal pressure gradient of ≤12 mmHg is achieved. TIPS can be performed in 95% of patients by an experienced interventional radiolo-gist, controls variceal bleeding in >90% of cases refractory to medical treatment, and should not affect subsequent hepatic transplantation. Possible complications include bleeding either intra-abdominally or via the biliary tree, infections, renal failure, decreased hepatic function, and hepatic encephalopathy, which occur in 25% to 30% of patients after the TIPS procedure. A high rate of thrombosis is seen and can be attributed to inti-mal hyperplasia of the metallic stent. Frequent follow-up with repeated interventions such as dilation or restenting often are needed to maintain TIPS patency.Balloon-Occluded Retrograde Transvenous ObliterationThe balloon-occluded retrograde transvenous obliteration (BRTO) procedure has been used for the specific manage-ment of bleeding gastric varices in patients with spontaneous gastrorenal or splenorenal shunts shown on contrast-enhanced cross-sectional imaging. Using a transjugular or transfemoral approach, a balloon-occlusion catheter is directed through the left renal vein into the spontaneous shunt, which is then obliter-ated with the use of a sclerosing agent. BRTO effectively con-trols hemorrhage from gastric varices and preserves portal flow to the liver, thereby reducing the risk of hepatic encephalopathy relative to TIPS. The occlusion of spontaneous shunts, how-ever, can theoretically exacerbate portal hypertension, precipi-tate hemorrhage from esophageal varices, and exacerbate the accumulation of ascites.Surgical ShuntingThe need for surgical shunts has been reduced since the intro-duction of the TIPS procedure and hepatic transplantation. At this time, the recommendation is that surgical shunts be consid-ered only in patients who have MELD scores of <15, who are 5Brunicardi_Ch31_p1345-p1392.indd 136720/02/19 2:36 PM 1368SPECIFIC CONSIDERATIONSPART IInot candidates for hepatic transplantation, or who have limited access to TIPS therapy and the necessary follow-up. The aim of the surgical shunt is to reduce portal venous pressure, maintain total hepatic and portal blood flow, and avoid the high inci-dence of complicating hepatic encephalopathy. Patient survival is determined by hepatic reserve.The portacaval shunt, as first described by Eck in 1877, either joins the portal vein to the IVC in an end-to-side fashion and completely disrupts portal vein flow to the liver, or joins it in a side-to-side fashion and thereby maintains partial por-tal venous flow to the liver. Currently this shunt is rarely per-formed due to the high incidence of hepatic encephalopathy and decreased liver function resulting from the reduction of portal perfusion. The Eck fistula also makes subsequent hepatic trans-plantation much more technically difficult.The mesocaval shunt uses an 8or 10-mm polytetrafluo-roethylene (PTFE) graft to connect the superior mesenteric vein to the IVC. The mesocaval shunt is technically easier to perform and can be easily ligated during subsequent hepatic transplan-tation. The smaller caliber of the shunt avoids the deleterious effects of portal blood flow deprivation on hepatic function. Small-diameter portosystemic shunts have been reported to reduce the incidence of encephalopathy but at the expense of increased risks of shunt thrombosis and rebleeding.The surgical shunt currently used most often is the distal splenorenal or Warren shunt (Fig. 31-15). This shunt is techni-cally the most difficult to perform. It requires division of the gastroesophageal collaterals and allows venous drainage of the stomach and lower esophagus through the short gastrosplenic veins into the spleen, and ultimately decompresses the left upper quadrant by allowing the splenic vein to drain directly into the left renal vein via an end-to-side splenic to left renal vein anas-tomosis. This shunt has the advantages of being associated with a lower rate of hepatic encephalopathy and decompensation and not interfering with subsequent liver transplantation.Nonshunt Surgical Management of Refractory Variceal BleedingIn the patient with extrahepatic portal vein thrombosis and refractory variceal bleeding, the Sugiura procedure may be considered. The Sugiura procedure consists of extensive devas-cularization of the stomach and distal esophagus along with tran-section of the esophagus, splenectomy, truncal vagotomy, and pyloroplasty. As with performance of surgical shunts, patient survival is dependent on hepatic reserve at the time of the sur-gical procedure. Experience in Western countries is somewhat limited, and a number of modifications have been made to the original Sugiura procedure over time.Hepatic TransplantationPatients with cirrhosis, portal hypertension, and variceal bleed-ing usually die as a result of hepatic failure and not acute blood loss. Therefore, hepatic transplantation must be considered in the patient with ESLD because it represents the patient’s only chance for definitive therapy and long-term survival. Hepatic transplantation also can be considered for the patient with vari-ceal bleeding refractory to all other forms of management. Sur-vival after hepatic transplantation is not affected adversely by the previous performance of endoscopic variceal band ligation, TIPS, or splenorenal or mesocaval shunts. Previous creation of an Eck fistula, however, does make hepatic transplantation much more technically difficult, and therefore this procedure should be avoided in the transplant candidate. In addition to sav-ing the patient’s life, hepatic transplantation reverses most of the hemodynamic and humoral changes associated with cirrhosis.Budd-Chiari SyndromeBudd-Chiari syndrome (BCS) is an uncommon congestive hepatopathy characterized by the obstruction of hepatic venous outflow. The incidence of BCS is 1 in 100,000 of the general population worldwide.63 Patients may present with acute signs and symptoms of abdominal pain, ascites, and hepatomegaly or more chronic symptoms related to long-standing portal hyper-tension. BCS is defined as primary when the obstructive process involves an endoluminal venous thrombosis. BCS is consid-ered as a secondary process when the veins are compressed or invaded by a neighboring lesion originating outside the vein.A thorough evaluation demonstrates one or more throm-botic risk factors in approximately 75% to 90% of patients with primary BCS.63 Primary myeloproliferative disorders, such as Figure 31-15. Surgical shunts for portal hyper-tension. Types of portacaval anastomoses. A. Nor-mal anatomy. B. Side-to-side portacaval shunt. C. End-to-side portacaval shunt. D. Mesocaval shunt. E. Distal splenorenal (Warren) shunt. (Reproduced with permission from Doherty GM, Way LW: Current Surgical Diagnosis and Treatment, 12th ed. New York, NY: McGraw-Hill Education; 2006.)ABCDEBrunicardi_Ch31_p1345-p1392.indd 136820/02/19 2:36 PM 1369LIVERCHAPTER 31essential thrombocythemia or polycythemia rubra, account for approximately 35% to 50% of the primary cases of BCS. All known inherited thrombophilias also have been implicated in the development of BCS. Activated protein C resistance, generally related to factor V Leiden mutation, is present in approximately 25% of patients. Anticardiolipin antibodies, hyperhomocystein-emia, and oral contraceptive use all have been shown to be risk factors for BCS.63Clinically significant BCS is usually the result of obstruc-tion of two or more of the major hepatic veins. The obstruction results in hepatomegaly, liver congestion, and right upper quad-rant pain. In addition, liver perfusion via the portal vein may be decreased, and 70% of affected patients have noninflammatory centrilobular necrosis on biopsy. Although ALF is rare, most patients will go on to develop chronic portal hypertension and ascites. Caudate lobe hypertrophy occurs in approximately 50% of cases and is due to the fact that the caudate lobe has direct venous drainage into the IVC. This caudate lobe hypertrophy, in turn, can result in further obstruction of the IVC.Abdominal ultrasonography is the initial investigation of choice and can demonstrate the absence of hepatic vein flow, spider web hepatic veins, and collateral hepatic veins.64 CT or MRI of the abdomen also is capable of demonstrating hepatic vein thrombosis and evaluating the IVC but is limited in that it cannot show direction of blood flow. The definitive radio-graphic study to evaluate BCS is hepatic venography to deter-mine the presence and extent of hepatic vein thrombus as well as measure IVC pressures.Initial treatment consists of diagnosing and medically managing the underlying disease process and preventing exten-sion of the hepatic vein thrombosis through systemic anticoagu-lation. The BCS-associated portal hypertension and ascites can be medically managed in a manner similar to that in most cir-rhotic patients. Radiologic and surgical intervention should be reserved for patients whose condition is nonresponsive to medi-cal therapy. Percutaneous angioplasty and TIPS, in combination with thrombolytic therapy, are the preferred strategies to restore the outflow of blood from the liver. Thrombolytic therapy alone may be attempted for acute thrombosis. Surgical shunting, namely with the side-to-side portacaval shunt, essentially turns the portal vein into a hepatic outflow tract. Most patients with a portacaval shunt show improvement in hepatic function and fibrosis at 1 year without significant hepatic encephalopathy.64 However, the enthusiasm for this procedure has been curbed due to the relatively high rate of operative mortality and shunt dysfunction. Patients with progressive BCS and manifestations of ESLD will ultimately require hepatic transplantation.INFECTIONS OF THE LIVERThe liver contains the largest portion of the reticuloendothelial system in the human body and is therefore able to handle the continuous low-level exposure to enteric bacteria that it receives through the portal venous system. Due to the high level of retic-uloendothelial cells in the liver, nonviral infections are unusual.Pyogenic Liver AbscessesPyogenic liver abscesses are the most common liver abscesses seen in the United States. They may be single or multiple and are more frequently found in the right lobe of the liver.65 The abscess cavities are variable in size and, when multiple, may coalesce to give a honeycomb appearance. Approximately 40% of abscesses are monomicrobial, an additional 40% are polymicrobial, and 20% are culture-negative. The most com-mon infecting agents are gram-negative bacteria. Escherichia coli is found in two thirds of cases, and other common organ-isms include Streptococcus faecalis, Klebsiella, and Proteus vulgaris. Anaerobic organisms such as Bacteroides fragilis also are seen frequently. In patients with endocarditis and infected indwelling catheters, Staphylococcus and Streptococcus species are more commonly found.In the past, pyogenic liver abscesses often resulted from infections of the intestinal tract such as acute appendicitis and diverticulitis, which then spread to the liver via the portal circu-lation. With improved imaging modalities and earlier diagnosis of these intra-abdominal infections, this particular etiology of pyogenic liver abscesses has become less common. Pyogenic liver abscesses also occur as a result of impaired biliary drain-age, subacute bacterial endocarditis, infected indwelling cath-eters, dental work, or the direct extension of infections such as diverticulitis or Crohn’s disease into the liver. There appears to be an increasing incidence due to infection by opportunis-tic organisms among immunosuppressed patients, including transplant and chemotherapy recipients as well as patients with acquired immunodeficiency syndrome (AIDS).Patients commonly present with right upper quadrant pain and fever. Jaundice occurs in up to one-third of affected patients. A thorough history and physical examination are usually helpful in identifying the underlying cause of the liver abscess. Leuko-cytosis, an elevated sedimentation rate, and an elevated AP level are the most common laboratory findings. Significant abnor-malities in the results of the remaining liver function tests are unusual. Blood cultures will only reveal the causative organism in approximately 50% of cases. Ultrasound examination of the liver reveals pyogenic abscesses as round or oval hypoechoic lesions with well-defined borders and a variable number of internal echoes. CT scan is highly sensitive in the localization of pyogenic liver abscesses, which appear hypodense with periph-eral enhancement and may contain air-fluid levels indicating a gas-producing infectious organism (Fig. 31-16). MRI of the abdomen can also detect pyogenic abscesses with a high level of sensitivity but plays a limited role because of its inability to be used for image-guided diagnosis and therapy.The current cornerstones of treatment include correction of the underlying cause and IV antibiotic therapy. Empiric antibiotic therapy should cover gram-negative and anaerobic organisms; percutaneous needle aspiration and culture of the aspirate may be useful in guiding subsequent antibiotic therapy. IV antibiotic therapy should be continued for at least 8 weeks and can be expected to be effective in 80% to 90% of patients. Placement of a percutaneous drainage catheter is beneficial only for a minority of patients, as most pyogenic abscesses are quite viscous and catheter drainage is often ineffective.Surgical drainage either via the laparoscopic or open approach may become necessary if initial therapies fail. Ana-tomic surgical resection can be performed in patients with recalcitrant abscesses. It must be kept in mind throughout the evaluation and treatment of the presumed pyogenic abscess that a necrotic hepatic malignancy must not be mistaken for a hepatic abscess. Therefore, early diagnosis and progression to surgical resection should be advocated for patients who do not respond to initial antibiotic therapy.Amebic AbscessesEntamoeba histolytica is a parasite that is endemic world-wide, infecting approximately 10% of the world’s population. Brunicardi_Ch31_p1345-p1392.indd 136920/02/19 2:36 PM 1370SPECIFIC CONSIDERATIONSPART IIAmebiasis is most common in subtropical climates, especially in areas with poor sanitation. E histolytica exists as cysts in a vegetative form that are capable of surviving outside the human body. The cystic form passes through the stomach and small bowel unharmed and then transforms into a trophozoite in the colon. Here it invades the colonic mucosa forming typical flask-shaped ulcers, enters the portal venous system, and is carried to the liver. Occasionally, the trophozoite will pass through the hepatic sinusoid and into the systemic circulation, which results in lung and brain abscesses.Amebae multiply and block small intrahepatic portal radi-cles with consequent focal infarction of hepatocytes. They con-tain a proteolytic enzyme that also destroys liver parenchyma. The abscesses formed are variable in size and can be single or multiple. The amebic abscess is most commonly located in the superior-anterior aspect of the right lobe of the liver near the diaphragm and has a necrotic central portion that contains a thick, reddish brown, pus-like material. This material has been likened to anchovy paste or chocolate sauce. Amebic abscesses are the most common type of liver abscesses worldwide.Amebiasis should be considered in patients who have trav-eled to an endemic area and present with right upper quadrant pain, fever, hepatomegaly, and hepatic abscess.46 Leukocytosis is common, whereas elevated transaminase levels and jaundice are unusual. The most common biochemical abnormality is a mildly elevated AP level. Even though this disease process is secondary to a colonic infection, the presence of diarrhea is unusual. Most patients have a positive fluorescent antibody test for E histo-lytica, and test results can remain positive for some time after a clinical cure. This serologic test has a high sensitivity, and therefore amebiasis is unlikely if the test results are negative.Ultrasound and CT scanning of the abdomen are both very sensitive but nonspecific for the detection of amebic abscesses.65 Amebic abscesses usually appear on CT as well-defined low-density round lesions that have enhancement of the wall, some-what ragged in appearance with a peripheral zone of edema. The central cavity may have septations as well as fluid levels. CT scanning is also useful in the detection of extrahepatic involvement.Metronidazole 750 mg three times a day for 7 to 10 days is the treatment of choice and is successful in 95% of cases. Defervescence usually occurs in 3 to 5 days, but the time nec-essary for the abscess to resolve depends on the initial size at presentation and varies from 30 to 300 days.65 Both ultrasound and CT of the liver can be used as follow-up after the initiation of medical therapy. Aspiration of the abscess rarely is needed and should be reserved for patients with large abscesses, those who do not respond to medical therapy, or those who appear to be superinfected. Furthermore, abscesses of the left lobe of the liver at risk for rupture into the pericardium should be treated with aspiration and drainage.Hydatid DiseaseHydatid disease is due to infection by the tapeworm Echinococ-cus granulosus in its larval or cyst stage.66 The tapeworm lives in canids, which are infected by eating the viscera of sheep that contain hydatid cysts. Scolices, contained in the cysts, adhere to the small intestine of dogs and become adult taenia, which attach to the intestinal wall. Each worm sheds approximately 500 ova into the bowel. The infected ova-containing feces of dogs contaminate grass and farmland, and the ova are ingested by intermediate hosts such as sheep, cattle, pigs, and humans. The ova have chitinous envelopes that are dissolved by gastric juice. The liberated ovum then burrows through the intestinal mucosa and is carried by the portal vein to the liver, where it develops into an adult cyst. Most cysts are caught in the hepatic sinusoids, and therefore 70% of hydatid cysts form in the liver. A few ova pass through the liver and are held up in the pul-monary capillary bed or enter the systemic circulation, forming cysts in the lung, spleen, brain, or bones.Hydatid disease is most common in sheep-raising areas, where dogs have access to infected offal. These include South Australia, New Zealand, Africa, Greece, Spain, and the Middle East. Hydatid cysts commonly involve the right lobe of the liver, usually the anterior-inferior or posterior-inferior segments. The uncomplicated cyst may be silent and found only incidentally or at autopsy. Occasionally, the affected patient presents with symptoms such as dull right upper quadrant pain or abdomi-nal distention. Cysts may become secondarily infected, involve other organs, or even rupture, which leads to an allergic or ana-phylactic reaction.The diagnosis of hydatid disease is based on the findings of an enzyme-linked immunosorbent assay (ELISA) for echino-coccal antigens, and results are positive in approximately 85% of infected patients.66 The ELISA results may be negative in an infected patient if the cyst has not leaked or does not contain scolices or if the parasite is no longer viable. Eosinophilia is seen in approximately 30% of infected patients. Ultrasonography and CT scanning of the abdomen are both quite sensitive for detecting hydatid cysts. The appearance of the cysts on images depends on the stage of cyst development. Typically, hydatid cysts are well-defined hypodense lesions with a distinct wall. Ring-like cal-cifications of the pericysts are present in 20% to 30% of cases. As healing occurs, the entire cyst calcifies densely, and a lesion with this appearance is usually dead or inactive. Daughter cysts generally occur in a peripheral location within the main cyst and are typically slightly hypodense compared with the mother cyst. MRI of the abdomen may be useful to evaluate the pericyst, cyst matrix, and daughter cyst characteristics.Unless the cysts are small or the patient is not a suitable candidate for surgical resection, the treatment of hydatid disease Figure 31-16. Computed tomographic scan of pyogenic liver abscesses. Multiple hepatic abscesses are seen in a patient after an episode of diverticulitis. Note the loculated large central abscess as well as the left lateral segment abscess.Brunicardi_Ch31_p1345-p1392.indd 137020/02/19 2:36 PM 1371LIVERCHAPTER 31is surgically based because of the high risk of secondary infec-tion and rupture. Medical treatment with albendazole relies on drug diffusion through the cyst membrane. The concentration of drug achieved in the cyst is uncertain but is better than that of mebendazole, and albendazole can be used as initial treat-ment for small, asymptomatic cysts. For most cysts, surgical resection involving laparoscopic or open complete cyst removal with instillation of a scolicidal agent is preferred and usually is curative. If complete cystectomy is not possible, then formal anatomic liver resection can be undertaken. During surgical resection, caution must be exercised to avoid rupture of the cyst with release of protoscolices into the peritoneal cavity. Perito-neal contamination can result in an acute anaphylactic reaction or peritoneal implantation of scolices with daughter cyst forma-tion and inevitable recurrence.Echinococcus multilocularis occurs in the Northern Hemisphere and can infect the liver in a fashion similar to that described earlier, although the cysts are multilocular. Infection of the lung also is common (alveolar echinococcosis). Canine species such as wolves, foxes, and dogs ingest infected vis-cera of an intermediate host (e.g., rodents, moose) and become infected; humans become infected incidentally by ingesting contaminated food or water. Treatment consists of albendazole; however, infection in the lung produces a more generalized granulomatous reaction, can present in a manner similar to that of a malignancy, and often requires resection.AscariasisAscaris infection is particularly common in the Far East, India, and South Africa. Ova of the roundworm Ascaris lumbricoides arrive in the liver by retrograde locomotion in the bile ducts from the GI tract. The adult worm is 10 to 20 cm long and may lodge in the common bile duct, causing partial bile duct obstruction and secondary cholangitic abscesses. The Ascaris may serve as a nidus for the development of intrahepatic gallstones. The clini-cal presentation in an affected patient may include biliary colic, acute cholecystitis, acute pancreatitis, or hepatic abscesses.67 Plain abdominal radiographs, abdominal ultrasound, and ERCP can demonstrate the Ascaris as linear filling defects within the bile ducts. Occasionally, worms can be seen moving into and out of the biliary tree from the duodenum. Treatment consists of the administration of piperazine citrate, mebendazole, or alben-dazole in combination with endoscopic extraction of the worms. Surgical intervention may become necessary if the Ascaris can-not be removed via ERCP.SchistosomiasisSchistosomiasis affects >200 million people in 74 countries. Hepatic schistosomiasis occurs when emboli of the ova in the intestines reach the liver via the mesenteric venous system. Eggs excreted in the feces hatch in water to release free-swimming embryos, which enter snails and develop into fork-tailed cercar-iae. They then reenter human skin during contact with infected water. They burrow down to the capillary bed and enter the bloodstream, leading to widespread hematogenous dissemina-tion. Those entering the intrahepatic portal system grow rapidly, resulting in a granulomatous reaction. The degree of consequent portal fibrosis is related to the adult worm load.Schistosomiasis has three stages of clinical symptomatol-ogy: the first includes itching after the entry of cercariae through the skin; the second includes fever, urticaria, and eosinophilia; and the third involves hepatic fibrosis followed by presinusoidal portal hypertension. During this third phase, the liver shrinks, the spleen enlarges, and the patient may develop complications of portal hypertension while hepatic function is maintained. Active infection is detected by stool examination. Serologic tests indicate past exposure but do not provide information regarding the timing of infection. A negative serologic test result excludes the presence of schistosomal infection. Serum levels of transaminases are usually normal, but the AP level may be mildly elevated. A decreased serum albumin level is usually the result of frequent GI bleeds and malnutrition.Medical treatment of schistosomiasis includes education on hygiene and the avoidance of infected water. Treatment with praziquantel 40 to 75 mg/kg as a single dose is the treatment of choice for all forms of schistosomiasis and produces few side effects. GI bleeding usually is controlled by endoscopic variceal ligation. However, in a patient with refractory GI portal hyper-tensive bleeding, distal splenorenal shunt or gastric devascular-ization and splenectomy may be considered.Viral HepatitisThe role of the surgeon in the management of viral hepatitis is somewhat limited. However, the disease entities of hepatitis A, B, and C need to be kept in mind during any evaluation for liver disease. Hepatitis A usually results in an acute self-limited ill-ness and only rarely leads to fulminant hepatic failure. Patients can present with fatigue, malaise, nausea, vomiting, anorexic fever, and right upper quadrant abdominal pain. The most com-mon physical findings are jaundice and hepatomegaly. Because the disease is self-limited, the treatment is usually supportive. Patients who develop fulminant infection require aggressive therapy and should be transferred to a center capable of per-forming liver transplantation.Hepatitis B and C, on the other hand, can both lead to chronic liver disease, cirrhosis, and HCC. The prevalence of chronic hepatitis B infection in the U.S. population is estimated to be 0.27%, but hepatitis B remains a major burden in resource-limited countries, accounting for 30% of cirrhosis and 53% of HCC cases. The ultimate goal of treatment for chronic hepati-tis B is viral suppression, thereby preventing the development of clinical outcomes such as cirrhosis, liver failure, and HCC. The cornerstone of current antiviral therapy includes pegylated interferon and nucleoside analogs such as tenofovir or entecavir.68 These agents have been proven to reduce complications of cirrho-sis and HCC and perhaps reverse previous damage to the liver. Interferon therapy produces various side effects including fatigue, flu-like symptoms, mood changes, bone marrow suppression, and stimulation of autoimmunity. On the other hand, the nucleoside analogs are generally well-tolerated by patients. Compared with lamivudine, the nucleoside analogs are less likely to produce resistance and are more likely to be clinically effective. Despite its high rate of viral resistance, lamivudine may be the preferred treatment in some countries because of its relatively low cost.Acute hepatitis C viral (HCV) infection typically devel-ops 2 to 26 weeks after exposure to the virus, and presenting symptoms can include jaundice, nausea, dark urine, and right upper quadrant abdominal pain. Diagnosis is confirmed by testing for the presence of HCV RNA and anti-HCV antibod-ies in the serum; viral RNA is first detectable in the serum by polymerase chain reaction (PCR) within days to weeks follow-ing the exposure, whereas antibodies will not appear until 2 to 6 months after. If the diagnosis of acute hepatitis is established and the virus is not spontaneously cleared within 12 weeks, patients should generally be treated with pegylated interferon Brunicardi_Ch31_p1345-p1392.indd 137120/02/19 2:36 PM 1372SPECIFIC CONSIDERATIONSPART IImonotherapy. High rates of sustained viral response, in excess of 80%, have been achieved with the early treatment of acute HCV infection.69 Unfortunately, patients with acute HCV infec-tion are typically asymptomatic, and the vast majority of cases go undetected. Untreated, most of these patients will eventually develop chronic infection.Chronic HCV infection often follows a progressive course over many years and can ultimately result in cirrhosis, HCC, and the need for liver transplantation. Cirrhosis secondary to hepa-titis C remains the leading indication for liver transplantation in the United States, Europe, and Japan. The decision to treat a patient with chronic HCV infection is complex and involves consideration of multiple factors including the natural history of the disease, stage of fibrosis, and the efficacy and adverse effects related to the treatment regimen. Patients with genotype 1 are now treated with triple-agent therapy including pegylated interferon, ribavirin, and a protease inhibitor. The protease inhibitors telaprevir and boceprevir were recently approved for the treatment of chronic HCV genotype 1 infection, and their addition to the treatment regimen has been shown to increase the rate of sustained viral response from 40% to 70%. These prote-ase inhibitors do no exhibit significant antiviral activity against other HCV genotypes, and therefore genotypes 2, 3, and 4 are treated with interferon and ribavirin alone. Genotypes 2 and 3 are generally more responsive to treatment than genotypes 1 and 4, but the therapeutic response also is dependent on other factors such as baseline viral load, ethnicity, and the patient’s genetic background and compliance with the regimen.EVALUATION OF AN INCIDENTAL LIVER MASSA liver mass often is identified incidentally during a radio-logic imaging procedure performed for another indication. For example, a liver mass may be discovered during evaluation for gallbladder disease or kidney stones. In addition, with advances in imaging technology, previously undetected lesions not infre-quently are now identified. Although many of these lesions are benign and will require no further treatment, the concern for malignancy requires a thorough evaluation. Thus, an orderly approach should be taken to the workup of an incidental liver lesion to minimize unnecessary testing.70The evaluation of an incidental liver mass begins with a history and physical examination (Fig. 31-17). The patient should be asked about abdominal pain, weight loss, previous Figure 31-17. Algorithm for diagnostic workup of an incidental liver lesion. The evaluation includes history and physical examination, blood work, imaging studies, and liver biopsy (if needed). AFP = α-fetoprotein; BUN = blood urea nitrogen; CA 19-9 = cancer antigen 19-9; CBC = complete blood count; CEA = carcinoembryonic antigen; creat = creatinine; CT = computed tomography; EGD = esophagogas-troduodenoscopy; glu = glucose; Gyn = gynecologic; HTN = hypertension; MRI = magnetic resonance imaging; OCP = oral contraceptive pill; PAP = Papanicolaou; US = ultrasound.DiagnosisAbdominal pain/weight lossLiver disease/cirrhosis/alcohol useHepatitis/blood transfusion/tattoosOCP/hormone use/cancer historyJaundice/scleral icterusPalpable mass/hepatomegalyStigmata of portal HTNCBC, platelet countLytes/BUN/creat/glu/albuminLiver function tests/ammoniaCoagulation studiesHepatitis screenTumor markers (CEA, AFP, CA 19-9)USCT or MRI scanNuclear med.AngiogramOccult primary eval.EGDColonoscopyMammogramGyn/PAP smear(Percutaneous or laparoscopic)Liver biopsy (if needed)Additional imaging studiesLaboratory testsHistory and physical examMass identified incidentally by US or CTBrunicardi_Ch31_p1345-p1392.indd 137220/02/19 2:36 PM 1373LIVERCHAPTER 31liver disease, cirrhosis, alcohol use, viral hepatitis, blood trans-fusions, tattoos, oral contraceptive use (in women), and personal or family history of cancer. On physical examination, jaundice, scleral icterus, hepatomegaly, splenomegaly, palpable mass, or stigmata of portal hypertension should be noted. After comple-tion of the history and physical examination, blood work should be performed, including complete blood count; platelet count; measurement of levels of electrolytes, blood urea nitrogen, creatinine, glucose, and albumin; liver function tests; serum ammonia level; coagulation studies; hepatitis screen; and mea-surement of levels of the tumor markers carcinoembryonic anti-gen, AFP, and cancer antigen 19-9.The differential diagnosis for an incidental liver mass includes cysts, benign solid lesions, and primary or metastatic cancers (Table 31-6). Ultrasound or CT is commonly performed to evaluate respiratory or abdominal symptoms, and these imag-ing studies usually lead to the discovery of an incidental liver lesion. Further radiologic evaluation by dualor triple-phase CT scan or MRI is often necessary to fully characterize the extent and nature of the lesion. Different types of liver masses have distinct appearances and patterns of contrast enhancement on these studies, facilitating the clinician in the diagnosis and for-mulation of the treatment plan. The use of liver-specific contrast agents in MRI provides information on hepatocyte function in combination with the structural data obtained during a standard MRI, and yields improved detection and characterization of liver lesions. CT cholangiography or MRCP can be obtained, par-ticularly when visualization of the biliary tract is desired. These modalities may be useful in the depiction of benign or malignant strictures resulting in biliary obstruction. In the evaluation of metastases to the liver from a variety of primary cancers, FDG-PET/CT has emerged as an indispensable tool in disease staging and in the follow-up after treatment. The techniques available for imaging of liver lesions are described in detail earlier in the section “Radiologic Evaluation of the Liver.”Liver biopsy is indicated when biochemical analysis and diagnostic imaging fail to lead to a definitive diagnosis. Percu-taneous liver biopsy with ultrasound or CT guidance is the sim-plest, fastest, and most commonly performed approach to obtain hepatic tissue for histologic examination. Absolute contraindi-cations to percutaneous liver biopsy include significant coagu-lopathy (as in patients with decompensated cirrhosis), biliary Table 31-6Classification of liver lesionsBenign Cyst Hemangioma Focal nodular hyperplasia Adenoma Biliary hamartoma AbscessMalignant Hepatocellular carcinoma Cholangiocarcinoma (bile duct cancer) Gallbladder cancer Metastatic colorectal cancer Metastatic neuroendocrine cancer (carcinoid) Other metastatic cancersdilatation, and suspicion for hemangioma or echinococcal cyst. Obesity and the presence of ascites are relative contraindica-tions that can present a challenge to the percutaneous approach. In these patients, laparoscopic liver biopsy can be considered. The laparoscopic technique is likely to have a higher diagnos-tic yield in cirrhotic patients with ascites and/or coagulopathy, in whom bleeding risk is excessive by the percutaneous route. Laparoscopy also offers the opportunity to stage the extent of disease in patients with various intra-abdominal malignancies.HEPATIC CYSTSCongenital CystsThe majority of hepatic cysts are asymptomatic. Hepatic cysts are usually identified incidentally and can occur at any time throughout life. The most common benign lesion found in the liver is the congenital or simple cyst. The exact prevalence of simple hepatic cysts in the U.S. population is not known, but the female to male ratio is approximately 4:1, and the prevalence is approximately 2.8% to 3.6%.71 Simple cysts are the result of excluded hyperplastic bile duct rests. Simple cysts usually are identified in hepatic imaging studies as thin-walled, homoge-neous, fluid-filled structures with few to no septations. The cyst epithelium is cuboidal and secretes a clear nonbilious serous fluid. With the exception of large cysts, simple cysts are usually asymptomatic. Large simple cysts may cause abdominal pain, epigastric fullness, and early satiety. Occasionally the affected patient presents with an abdominal mass.Asymptomatic simple cysts are best managed conserva-tively. The preferred treatment for symptomatic cysts is ultra-soundor CT-guided percutaneous cyst aspiration followed by sclerotherapy. This approach is approximately 90% effective in controlling symptoms and ablating the cyst cavity. If percu-taneous treatment is unavailable or ineffective, treatment may include either laparoscopic or open surgical cyst fenestration. The laparoscopic approach is being used more frequently and is 90% effective. The excised cyst wall is sent for pathologic analysis to exclude the presence of carcinoma, and the remain-ing cyst wall must be carefully inspected for evidence of neo-plastic change. If such change is present, complete resection is required, either by enucleation or formal hepatic resection.Biliary CystadenomaBiliary cystadenomas are slow-growing, unusual, benign lesions that most commonly present as large lesions in the right lobe of the liver. Although these lesions are usually benign, they can undergo malignant transformation. Patients with biliary cystad-enomas commonly present with abdominal pain. An abdominal mass occasionally can be identified on physical examination. In contrast to simple cysts, biliary cystadenomas have walls that appear thicker with soft tissue nodules and septations that usu-ally enhance. The protein content of the fluid can be variable and can affect the radiographic images on CT and MRI. Surgical resection is the preferred mode of treatment.Polycystic Liver DiseaseAdult polycystic liver disease (PCLD) occurs as an autosomal dominant disease and usually presents in the third decade of life. Approximately 44% to 76% of affected families are found to have mutations of PKD1, and approximately 75% have muta-tions of PKD2.72 The prevalence and number of hepatic cysts Brunicardi_Ch31_p1345-p1392.indd 137320/02/19 2:36 PM 1374SPECIFIC CONSIDERATIONSPART IIare higher in females and increase with advancing age and with increasing severity of renal cystic disease and renal dysfunc-tion. Patients with a small number of cysts or with small cysts (<2 cm) usually remain asymptomatic. In contrast, patients who develop many or large cysts, with a cyst-to-parenchymal vol-ume ratio of >1, usually develop clinical symptoms, including abdominal pain, distension, shortness of breath, and early satiety. Disease progression often results in renal failure and the need for hemodialysis. In most patients, the liver parenchymal vol-ume and synthetic function are preserved despite extensive cystic disease. Hepatic decompensation, variceal hemorrhage, ascites, and encephalopathy develop rarely in patients with PCLD and only in those with massive cystic disease. The most common liver-specific complications associated with PCLD are intracystic hemorrhage, infection, and posttraumatic rup-ture. The most common abnormal biochemical test finding is a modestly elevated γ-glutamyltransferase level, and the most useful imaging tests are CT or MRI of the abdomen, which will demonstrate the characteristic polycystic appearance. Other conditions that may be associated with PCLD include cerebral aneurysm, diverticulosis, mitral valve prolapse, and inguinal hernia.The principal aim of treatment for PCLD is to ameliorate symptoms by decreasing liver volume. Medical therapy options for PCLD remain experimental at this time. Somatostatin ana-logs such as octreotide and lanreotide have been shown to modestly reduce liver volume and are generally well tolerated. Sirolimus and other mammalian target of rapamycin (mTOR) inhibitors possess antiproliferative effects and thus have been postulated to slow disease progression. The effectiveness of these medical measures in relieving symptoms among patients with PCLD, however, remains to be proven.73Cyst aspiration and sclerotherapy entail puncture of a cyst with an aspiration needle followed by injection of a scleros-ing agent that causes destruction of the epithelial lining thereby inhibiting fluid production. Common agents used for sclerosis include ethanol, minocycline, and tetracycline. This technique may be considered if the patient has one or a few dominant cysts, each measuring over 5 cm. Appropriate candidates for sclerotherapy can experience a complete resolution of symp-toms, but patients with numerous cysts often do not improve when this technique is used. This procedure is generally well tolerated, with the most common complication being pain from the instillation of ethanol.Cyst fenestration, or surgical unroofing of the cyst, can be performed via an open or laparoscopic approach in symptomatic patients.74 This approach allows multiple cysts to be treated dur-ing a single procedure, but carries the risk of potential surgical complications, including ascites, pleural effusion, hemorrhage, and biliary leakage. Immediate symptom relief can be achieved in up to 92% of cases, but 22% of patients eventually develop recurrence of their symptoms.Hepatic resection can be considered for PCLD patients with massive hepatomegaly, when fenestration alone is unlikely to significantly reduce liver volume. Appropriate candidates are those with portions of liver that harbor numerous cysts, but have at least one spared segment with predominantly normal liver parenchyma. Because the intrahepatic vascular and biliary anat-omy can be distorted by the cysts, PCLD patients undergoing hepatic resection are at increased risk for hemorrhagic and bili-ary complications. Furthermore, adhesion formation after liver resection can increase the technical complexity of future OLT. Significant symptom relief has been reported in up to 86% of PCLD patients following hepatic resection.OLT represents the only definitive therapy for patients with symptomatic PCLD. This therapeutic option is indicated in patients with severely disabling symptoms that lead to a poor quality of life or in those who have developed untreatable com-plications such as portal hypertension and nutritional depriva-tion. If the patient has severe renal insufficiency from polycystic kidney disease, consideration should be given to combined liver-kidney transplantation. Because of the genetic basis of PCLD, living-donor transplantation should be considered only if the presence of PCLD in the donor can be ruled out.Caroli’s DiseaseCaroli’s disease is a syndrome of congenital ductal plate mal-formations of the intrahepatic bile ducts and is characterized by segmental cystic dilatation of the intrahepatic biliary radicals.74 Caroli’s disease also is associated with an increased incidence of biliary lithiasis, cholangitis, and biliary abscess formation. Caroli’s disease usually occurs in the absence of cirrhosis and is associated with cystic renal disease.75 The most common presenting symptoms include fever, chills, and abdominal pain. Most patients present by the age of 30 years, and males and females are affected equally. Rarely, patients can present later in life with complications secondary to portal hyperten-sion. Approximately 33% of affected patients develop biliary lithiasis, and 7% develop cholangiocarcinoma. The diagnosis of Caroli’s disease is made based on imaging studies. Magnetic resonance cholangiopancreatography, ERCP, and percutaneous transhepatic cholangiography provide more detailed imaging of the biliary tree and confirm communication of the intrahepatic cysts with the biliary tree, which is necessary to solidify the diagnosis. Treatment consists of biliary drainage, with ERCP and percutaneous transhepatic cholangiography serving as first-line therapeutic modalities. If the disease is limited to a single lobe of the liver, hepatic resection can be beneficial. Liver resec-tion can be considered in the patient with hepatic decompensa-tion or unresponsive recurrent cholangitis and possibly in the patient with a small (T1 or T2) cholangiocarcinoma.BENIGN LIVER LESIONSThe liver is an organ that is commonly involved either primarily or secondarily with vascular, metabolic, infectious, and malig-nant processes. Many classification schemes are used to help narrow the differential diagnosis of liver lesions: solid or cystic, single or multiple, cell of origin (hepatocellular, cholangiocel-lular, or mesenchymal), and benign or malignant. Benign liver lesions occur in up to 20% of the general population and are much more common than malignant tumors. The most common benign lesions are cysts, hemangiomas, focal nodular hyperplasia (FNH), and hepatocellular adenomas (see Table 31-6). Many of these lesions have typical features in imaging studies that help confirm the diagnosis.CystHepatic cysts are the most frequently encountered liver lesion overall and are described in detail in the section “Hepatic Cysts.” Cystic lesions of the liver can arise primarily (congeni-tal) or secondarily from trauma (seroma or biloma), infection (pyogenic or parasitic), or neoplastic disease. Congenital cysts are usually simple cysts containing thin serous fluid and are 6Brunicardi_Ch31_p1345-p1392.indd 137420/02/19 2:36 PM 1375LIVERCHAPTER 31reported to occur in 5% to 14% of the population, with higher prevalence in women. In most cases, congenital cysts are differ-entiated from secondary cysts (infectious or neoplastic origin) in that they have a well-defined thin wall and no solid component and are filled with homogeneous, clear fluid. For benign solid liver lesions, the differential diagnosis includes hemangioma, adenoma, FNH, and bile duct hamartoma.HemangiomaHemangiomas (also referred to as hemangiomata) are the most common solid benign masses that occur in the liver. They con-sist of large endothelial-lined vascular spaces and represent congenital vascular lesions that contain fibrous tissue and small blood vessels that eventually grow. They are predominantly seen in women and occur in 2% to 20% of the population. They can range from small (≤1 cm) to giant cavernous hemangiomas (10 to 25 cm). Most hemangiomas are discovered incidentally with little clinical consequence. However, large lesions can cause symptoms as a result of compression of adjacent organs or intermittent thrombosis, which in turn results in further expan-sion of the lesion. Spontaneous rupture (bleeding) is rare, but surgical resection can be considered if the patient is symptom-atic. Resection can be accomplished by enucleation or formal hepatic resection, depending on the location and involvement of intrahepatic vascular structures and hepatic ducts.The majority of hemangiomas can be diagnosed by liver imaging studies. On biphasic contrast CT scan, large hemangio-mas show asymmetrical nodular peripheral enhancement that is isodense with large vessels and exhibit progressive centripetal enhancement fill-in over time (Fig. 31-18). On MRI, hemangio-mas are hypointense on T1-weighted images and hyperintense on T2-weighted images.76 With gadolinium enhancement, hem-angiomas show a pattern of peripheral nodular enhancement similar to that seen on contrast CT scans. Caution should be exercised in ordering a liver biopsy if the suspected diagnosis is hemangioma because of the risk of bleeding from the biopsy site, especially if the lesion is at the edge of the liver.AdenomaHepatic adenomas are benign solid neoplasms of the liver. They are most commonly seen in premenopausal women older than 30 years of age and are typically solitary, although multiple adenomas also can occur. Prior or current use of estrogens (oral contraceptives) is a clear risk factor for development of liver adenomas, although they can occur even in the absence of oral contraceptive use. On gross examination, they appear soft and encapsulated and are tan to light brown. Histologically, adeno-mas lack bile duct glands and Kupffer cells, have no true lobules, and contain hepatocytes that appear congested or vacuolated due to glycogen deposition. On CT scan, adenomas usually have Figure 31-18. Computed tomographic scans showing classic appearance of benign liver lesions. Focal nodular hyperplasia (FNH) is hyper-vascular on arterial phase, isodense to liver on venous phase, and has a central scar (upper panels). Adenoma is hypovascular (lower left panel). Hemangioma shows asymmetrical peripheral enhancement (lower right panel).Brunicardi_Ch31_p1345-p1392.indd 137520/02/19 2:36 PM 1376SPECIFIC CONSIDERATIONSPART IIsharply defined borders and can be confused with metastatic tumors. With venous phase contrast, they can look hypodense or isodense in comparison with background liver, whereas on arterial phase contrast, subtle hypervascular enhancement often is seen (see Fig. 31-18). On MRI scans, adenomas are hyper-intense on T1-weighted images and enhance early after gado-linium injection. With the use of liver-specific MRI contrast agents such as gadoxetate (Eovist or Primovist, Bayer-Schering, Berlin, Germany), hepatic adenomas can be better distinguished from FNH by their enhancement characteristics during the hepa-tobiliary phase of imaging. The new MRI contrast agent, gado-benate dimeglumine (MultiHance, Bracco Diagnostics, Milan, Italy), is eliminated through both renal and biliary excretion. Therefore, liver lesions that contain hepatocytes with intact bili-ary excretion mechanism will take up this contrast agent and be easily distinguished from lesions that do not. This contrast agent has improved our ability to differentiate hepatic adenoma from FNH with a high degree of accuracy.Hepatic adenomas carry a significant risk of spontaneous rupture with intraperitoneal bleeding. The clinical presentation may be abdominal pain, and in 10% to 25% of cases, hepatic adenomas present with spontaneous intraperitoneal hemorrhage. Hepatic adenomas also have a risk of malignant transformation to a well-differentiated HCC. Therefore, it usually is recom-mended that large hepatic adenomas (>4–5 cm) be surgically resected.Focal Nodular HyperplasiaFNH is a solid, benign lesion of the liver believed to be a hyper-plastic response to an anomalous artery. Similar to adenomas, they are more common in women of childbearing age, although the link to oral contraceptive use is not as clear as with adeno-mas. A good-quality biphasic CT scan usually is diagnostic of FNH, on which such lesions appear well circumscribed with a typical central scar (see Fig. 31-18). They show intense homo-geneous enhancement on arterial phase contrast images and are often isodense or invisible compared with background liver on the venous phase. On MRI scans, FNH lesions are hypoin-tense on T1-weighted images and isointense to hyperintense on T2-weighted images. After gadolinium administration, lesions are hyperintense but become isointense on delayed images. The fibrous septa extending from the central scar are also more readily seen with MRI. Unlike adenomas, FNH lesions usually do not rupture spontaneously and have no significant risk of malignant transformation. Therefore, the management of FNH is usually reassurance and prospective observation irrespective of size. Surgical resection can be recommended, however, when patients are symptomatic or when hepatic adenoma or HCC can-not be definitively excluded. Oral contraceptive or estrogen use should be stopped when either FNH or adenoma is diagnosed.Bile Duct HamartomaBile duct hamartomas are typically small liver lesions, 2 to 4 mm in size, visualized on the surface of the liver at laparotomy. They are firm, smooth, and whitish yellow in appearance. They can be difficult to differentiate from small metastatic lesions, and excisional biopsy often is required to establish the diagnosis.MALIGNANT LIVER TUMORSMalignant tumors in the liver can be classified as primary (cancers that originate in the liver) or metastatic (cancers that spread to the liver from an extrahepatic primary site) (see Table 31-6). Primary cancers in the liver that originate from hepato-cytes are known as hepatocellular carcinomas (HCCs or hepa-tomas), whereas cancers arising in the bile ducts are known as cholangiocarcinomas.In the United States, approximately 150,000 new cases of colorectal cancer are diagnosed each year, and the majority of patients (approximately 60%) will develop hepatic metas-tases over their lifetime. Hence, the most common tumor seen in the liver is metastatic colorectal cancer. This compares with approximately 30,000 new cases of HCC diagnosed annually in the United States. Interestingly, in a Western series of 1000 con-secutive new liver cancer patients seen at a university medical center, 47% had HCC, 17% had colorectal cancer metastases, 11% had cholangiocarcinomas, 7% had neuroendocrine metas-tases, and 18% had other tumors.77 Although these figures do not reflect the incidence or prevalence of these liver cancers, they are indicative of referral patterns in a tertiary academic medical center with a large liver transplantation team and active hepatology clinic.Hepatocellular CarcinomaHCC is the fifth most common malignancy worldwide, with an estimated 750,000 new cases diagnosed annually. Because of its high fatality, it is the third most common cause of cancer death worldwide.78 Major risk factors are viral hepatitis (B or C), alcoholic cirrhosis, hemochromatosis, and NASH. In Asia, the risk is as high as 35 to 117 per 100,000 persons per year, whereas in the United States, the risk is only 7 per 100,000 per-sons per year.78 Although cirrhosis is not present in all cases, it has been estimated to be present 70% to 90% of the time. In a person with cirrhosis, the annual conversion rate to HCC is 2% to 6%.79 In patients with chronic HCV infection, cirrhosis usually is present before the HCC develops; however, in cases of hepatitis B virus infection, HCC tumors can occur before the onset of cirrhosis. HCCs are typically hypervascular with blood supplied predominantly from the hepatic artery. Thus, the lesion often appears hypervascular during the arterial phase of CT studies (Fig. 31-19) and relatively hypodense during the delayed phases due to early washout of the contrast medium by the arterial blood. MRI imaging also is effective in character-izing HCC. HCC is variable on T1-weighted images and usu-ally hyperintense on T2-weighted images. As with contrast CT, HCC enhances in the arterial phase after gadolinium injection because of its hypervascularity and becomes hypointense in the delayed phases due to contrast washout. HCC has a tendency to invade the portal vein, and the presence of an enhancing portal vein thrombus is highly suggestive of HCC.The treatment of HCC is complex and is best managed by a multidisciplinary liver transplant team. A complete algorithm for the evaluation and management of HCC is shown in Fig. 31-20. For patients without cirrhosis who develop HCC, resection is the treatment of choice. For patients with Child’s class A cirrhosis with preserved liver function and no portal hypertension, resection also is considered. If resection is not possible because of poor liver function and the HCC meets transplant criteria (discussed later), liver transplantation is the treatment of choice.80,81The Barcelona-Clinic Liver Cancer Group has refined its HCC management strategy and has developed the American Association for the Study of Liver Diseases Practice Guidelines.82 Management guidelines vary slightly in Asia, Europe, the 7Brunicardi_Ch31_p1345-p1392.indd 137620/02/19 2:36 PM 1377LIVERCHAPTER 31United States, and other countries based in part on availability of organ donors for liver transplantation. Living donor liver trans-plantation also is an alternative for patients with HCC awaiting transplantation to avoid dropout as a candidate for cadaveric donor liver transplantation due to tumor progression.81 Specific treatment options are described in the next section.CholangiocarcinomaCholangiocarcinoma, or bile duct cancer, is the second most common primary malignancy of the liver. Cholangiocarcinoma is an adenocarcinoma of the bile ducts; it forms in the biliary epithelial cells and can be subclassified into peripheral (intra-hepatic) bile duct cancer and central (extrahepatic) bile duct cancer. Extrahepatic bile duct cancer can be located distally or proximally. When proximal, it is referred to as a hilar chol-angiocarcinoma (Klatskin’s tumor). Hilar cholangiocarcinoma originates in the wall of the bile duct at the hepatic duct conflu-ence and usually presents with obstructive jaundice rather than an actual liver mass. In contrast, a peripheral (or intrahepatic) cholangiocarcinoma represents a tumor mass within a hepatic lobe or at the periphery of the liver. A biopsy specimen from the cholangiocarcinoma will show adenocarcinoma, but patholo-gists are often unable to differentiate metastatic adenocarcinoma to the liver from primary bile duct adenocarcinoma. Therefore, a search for a primary site should be undertaken in cases in which an incidentally discovered liver lesion is proven to be an adenocarcinoma on biopsy.Hilar cholangiocarcinoma is difficult to diagnose and typi-cally presents as a stricture of the proximal hepatic duct causing painless jaundice. It preferentially grows along the length of the bile ducts, often involving the periductal lymphatics with frequent lymph node metastases. Surgical resection offers the only chance for cure of cholangiocarcinoma.83 The location and extent of tumor dictate the operative approach. In one series of 225 patients with hilar cholangiocarcinoma, 65 (29%) were deemed to have unresectable tumors by initial imaging.84 Of the remaining 160 patients who underwent exploratory surgery with curative intent, 80 (50%) were found to have inoperable tumors. Histologically negative margins, concomitant hepatic resection, and well-differentiated tumor histology were associ-ated with improved outcome after resection. In another series of 61 patients undergoing surgical exploration for hilar cholangio-carcinoma, the 5-year actuarial survival rates for an R0 or R1 resection were 45% and 26%, respectively.85 In a large series reported by Nagino and colleagues, 132 patients with hilar chol-angiocarcinoma underwent extended hepatectomy with resec-tion of the caudate lobe and extrahepatic bile duct, and/or portal vein resection (n = 63) after portal vein embolization.86 The 3and 5-year survival rates were 41.7% and 26.8%, respectively.In the absence of associated primary sclerosing cholangi-tis (PSC), surgical resection is the treatment of choice for hilar cholangiocarcinoma. However, approximately 10% of patients with cholangiocarcinoma have PSC.87 Furthermore, cholangio-carcinoma in the setting of PSC is frequently multicentric and often is associated with underlying liver disease, with eventual cirrhosis and portal hypertension. As a result, experience has shown that resection of cholangiocarcinoma in patients with PSC yields dismal results. This led transplant centers to con-sider OLT for patients with hilar cholangiocarcinoma. The ini-tial results of transplantation were disappointing, however, with high recurrence and overall 3-year survival rates of <30%.88Because the growth of hilar cholangiocarcinoma indicates that this disease spreads in a locoregional manner, a rationale for the use of neoadjuvant chemoradiation was developed by the transplant team at the University of Nebraska in the late 1980s. This was adapted in 1993 by the transplant team at the Mayo Clinic, which led to the current Mayo Clinic protocol.89 The pretransplant Mayo protocol consists of external-beam radiation therapy plus a protracted course of intravenous 5-fluorouracil followed by iridium-192 brachytherapy.90 Patients then undergo an abdominal exploration with staging. If findings are negative, patients are given capecitabine for 2 of every 3 weeks until transplantation. Even after restaging with CT/MRI and endo-scopic ultrasonography, approximately 15% to 20% of patients will have positive findings for tumor on abdominal Figure 31-19. Computed tomographic (CT) images of hepato-cellular carcinoma (HCC) and peripheral cholangiocarcinoma. CT scans reveal a large (upper panel) and small (middle panel) hypervascular HCC. A hypovascular left lobe peripheral cholangio-carcinoma (CholangioCA) is also shown (lower panel).Brunicardi_Ch31_p1345-p1392.indd 137720/02/19 2:36 PM 1378SPECIFIC CONSIDERATIONSPART IIexploration.87,90 The 5-year survival rate for those undergoing transplantation for cholangiocarcinoma at the Mayo Clinic is approximately 70% and compares favorably with the rate for resection.87,90 Current eligibility criteria for this Mayo Clinic protocol include unresectable hilar cholangiocarcinoma or hilar cholangiocarcinoma with PSC. The tumor must have a radial dimension of ≤3 cm with no intrahepatic or extrahepatic metastases, and the patient must not have undergone prior radiation therapy or transperitoneal biopsy.90 Many centers have adopted similar protocols with comparable results.91Peripheral, or intrahepatic, cholangiocarcinoma is less common than hilar cholangiocarcinoma. In a series of 53 patients at Memorial Sloan-Kettering Cancer Center who underwent surgical exploration for a diagnosis of intrahepatic cholangiocarcinoma, 33 (62%) were found to have resectable tumors.92 Actuarial 3-year survival for patients undergoing resection was 55%. Factors predictive of poor survival included vascular invasion, histologically positive margins, and multiple tumors. In a large series in Taiwan, 373 patients with peripheral cholangiocarcinoma underwent surgical treatment from 1977 to 2001. Absence of mucobilia, nonpapillary tumor type, tumor of advanced stage, nonhepatectomy, and lack of postoperative chemotherapy were five independent prognostic factors that adversely affected overall survival.93 Liver transplantation has been performed for peripheral cholangiocarcinoma94; however, currently all but one center in the United States have eschewed this approach because of organ shortages and relatively high recurrence rates.Gallbladder CancerGallbladder cancer is a rare aggressive tumor with a very poor prognosis. Over 90% of patients have associated cholelithia-sis. In one study examining the mode of presentation over a 10-year period from 1990 to 2000 in 44 patients diagnosed with gallbladder cancer, the diagnosis was found to be made preoperatively in 57%, intraoperatively in 11%, and inciden-tally after cholecystectomy in 32%.95 Surgical approaches can be classified into (a) reoperation for an incidental finding of gallbladder cancer after cholecystectomy, and (b) radical resec-tion in patients with advanced disease. The results are dismal for radical resection in patients with advanced disease and positive hilar lymph nodes.96,97 For incidental gallbladder can-cer beyond stage T1, reoperation with central liver resection, hilar lymphadenectomy, and evaluation of cystic duct stump is most commonly performed.98,99 The role of formal lobectomy or extended lobectomy as well as common bile duct resection is more controversial. In a single-center study of 23 patients undergoing attempted curative treatment by surgical resec-tion, survival was 85% at 1 year, 63% at 2 years, and 55% at 3 years.99 In a multicenter study encompassing 115 patients with incidentally discovered gallbladder cancer who underwent re-resection,98 residual disease in the liver was identified in 46% of patients (0% of those with stage T1 disease, 10% of those with T2 tumors, and 36% of those with T3 disease). T stage also was associated with the risk of metastasis to locoregional lymph nodes (lymph node metastasis for T1 of 13%; for T2, 31%; and for T3, 46%). In another study, a German registry of incidental gallbladder cancer identified 439 patients. Patients with tumors staged as T2 or T3 after cholecystectomy had better survival if they underwent reoperation than if they were managed with observation.100 Hence, reoperation should be considered for all patients who have T2 or T3 tumors or for whom the accuracy of staging is in question.Metastatic Colorectal CancerOver 50% to 60% of patients diagnosed with colorectal cancer will develop hepatic metastases during their lifetime. Resection for hepatic metastases has been a routine part of treatment for 8ResectionNoncirrhotic/Child’s ASingle lesionNo metastasisOLTx evaluation1 lesion ˜5 cm3 lesions ˜3 cmChild’s A/B/CNo gross vasc. invasionNo metastasisNot Tx candidateComorbid factors°4 lesionsGross vasc. invasionLN (+) or metastasisLDLT ?Suitable donorPalliative careChild’s CBili °3 HCC IdentifiedResection candidate?Transplant candidate?YesYesNoSorafenibYesYesNoOLTxClinicaltrialsNeoadjuvant therapyRFA/TACE/90 YttriumUNOS list (cadaver)MELD score (? >3 mos)Perc/lap. RFASingle lesion<5 cmChild’s A/BTace/90 YttriumMulti-focal >5 cmChild’s A/B/CBili <3NewagentsFigure 31-20. Algorithm for the management of hepatocellular carcinoma (HCC). The treatment algorithm for HCC begins with determining whether the patient is a resection candidate or liver transplant candidate. Bili = bilirubin level (in milligrams per deciliter); Child’s = Child-Turcotte-Pugh class; lap = laparoscopic; LDLT = living-donor liver transplantation; LN = lymph node; MELD = Model for End-Stage Liver Disease; OLTx = orthotopic liver transplantation; Perc = percutaneous; RFA = radiofrequency ablation; TACE = transarterial chemoemboli-zation; Tx = transplantation; UNOS = United Network for Organ Sharing; vasc. = vascular.Brunicardi_Ch31_p1345-p1392.indd 137820/02/19 2:36 PM 1379LIVERCHAPTER 31colorectal cancer since the publication of a large single-center experience demonstrating its safety and efficacy.101 Predictors of poor outcome in that study included node-positive primary, disease-free interval <12 months, more than one tumor, tumor size >5 cm, and carcinoembryonic antigen level >200 ng/mL. Traditional teaching suggested that hepatic resection for meta-static colorectal cancer to the liver, if technically feasible, should be performed only for fewer than four metastases.102 However, later studies challenged this paradigm. In a series of 235 patients who underwent hepatic resection for metastatic colorectal cancer, the 10-year survival rate of patients with four or more nodules was 29%, nearly comparable to the 32% sur-vival rate of patients with only a solitary tumor metastasis.103 In the Memorial Sloan-Kettering Cancer Center series of 98 patients with four or more colorectal hepatic metastases who underwent resection between 1998 and 2002, the 5-year actu-arial survival was 33%.104 Furthermore, improved chemothera-peutic regimens and surgical techniques have produced aggressive strategies for the management of this disease. Many groups now consider volume of future liver remnant and the health of the background liver, and not actual tumor number, as the primary determinants in selection for an operative approach.105,106 Hence, resectability is no longer defined by what is actually removed, but indications for hepatic resection now center on what will remain after resection.107 Use of neo-adjuvant chemotherapy, portal vein embolization, two-stage hepatectomy, simultaneous ablation, and resection of extrahepatic tumor in select patients have increased the number of patients eligible for a surgical approach.108,109Neuroendocrine TumorsHepatic metastases from neuroendocrine tumors have a protracted natural history and commonly are associated with debilitating endocrinopathies. Several groups have advocated an aggressive surgical approach of debulking surgery, both to control symp-toms and to extend survival.110,111 In a series of 170 patients undergoing resection of hepatic metastases from neuroendocrine tumors between 1977 and 1998 at the Mayo Clinic, overall sur-vival was 61% and 35% at 5 and 10 years, respectively.112 There was no difference in survival between patients with carcinoid tumors and those with islet cell tumors. Major hepatectomy was performed in 91 patients (54%), and recurrence rate was 84% at 5 years. Belghiti’s group has described a two-stage strategy used in 41 patients with a primary neuroendocrine tumor and synchronous bilobar liver metastases.113 In the first stage, the primary tumor is resected and limited resection of metastases in the left hemiliver, combined with right portal vein ligation, is performed. After 8 weeks of hypertrophy, a right hepatec-tomy or extended right hepatectomy (also referred to as a right trisectionectomy; resection of Couinaud’s segments IV, V, VI, VII, and VIII of the liver) is performed.113 In patients treated using this strategy, the 2-, 5-, and 8-year Kaplan-Meier over-all survival rates were 94%, 94%, and 79%, respectively, and disease-free survival rates were 85%, 50%, and 26%, respec-tively. Because systemic therapy has had little success in the treatment of advanced tumors, a broader approach using multi-modal therapy has been used to increase survival and improve hormone-related symptoms. These therapies include radiofre-quency or microwave ablation and intra-arterial therapy with chemoembolization or radioembolization (yttrium-90). Some centers perform liver transplantation for selected patients (carci-noid histology; primary tumor removed with curative resection; primary tumor drained by portal system; ≤50% hepatic paren-chyma involved; good response or stable disease for at least 6 months during pretransplantation period; and age 55 years or younger), although this is not routine.114Other Metastatic TumorsNearly every cancer has the propensity to metastasize to the liver. Historically, enthusiasm was low for resecting metastases other than those from a colorectal cancer primary. This was due in part to the recognition that many other primary cancers (such as breast cancer) represent a systemic disease when liver metas-tases are present. However, more recent studies have shown acceptable 5-year survival rates in the 20% to 40% range for resection of hepatic metastases from breast, renal, and other GI tumors.115,116 In a large study of hepatic resection for non-colorectal, nonendocrine liver metastases in 1452 patients, neg-ative prognostic factors were nonbreast origin, age >60 years, disease-free interval of <12 months, need for major hepatec-tomy, performance of R2 resection, and presence of extrahe-patic metastases.115TREATMENT OPTIONS FOR LIVER CANCERIn general, the major treatment options for liver cancer can be categorized as shown in Table 31-7. The decision making for any given patient is complex and is best managed by a multidis-ciplinary liver tumor board. The treatments listed in Table 31-7 are not mutually exclusive; the important point is to select the most appropriate initial treatment after a complete evaluation. In general, surveillance imaging (CT or MRI) is performed every 3 to 4 months during the first year after diagnosis to observe for response, progression, or recurrence. The treatment plan is indi-vidualized and modified according to the response of the patient.Hepatic ResectionFor primary liver cancers or hepatic metastases, hepatic resection is the gold standard and treatment of choice. Although there are anecdotal reports of long-term survival after ablation and other regional liver therapies, liver resection remains the only real option for cure. For HCC in the setting of cirrhosis, liver trans-plantation also offers the potential for long-term survival, albeit with the consequences of immunosuppression. Hepatic resection 9Table 31-7Treatment options for liver cancerHepatic resectionLiver transplantationAblation techniquesRadiofrequency ablation• Ethanol ablation• Cryoablation• Microwave ablationRegional liver therapies• Chemoembolization/embolization• Hepatic artery pump chemoperfusion• Internal radiation therapy (yttrium-90 internal radiation)External-beam radiation therapy• Stereotactic radiosurgery (CyberKnife, Trilogy, Synergy)• Intensity-modulated radiation therapySystemic chemotherapyMultimodality approachBrunicardi_Ch31_p1345-p1392.indd 137920/02/19 2:36 PM 1380SPECIFIC CONSIDERATIONSPART IIalso has been advocated for HCC in select patients with cirrho-sis before secondary liver transplantation, although not without some controversy.117 Many large series of patients undergoing major hepatectomy now report mortality rates of <5%.118-121 Pre-viously, a 1-cm tumor margin was considered desirable; how-ever, recent studies have reported comparable survival rates with smaller margins.122-124 Technical innovation in liver surgery and a better understanding of perioperative care have even allowed surgeons to perform resections in cases with IVC involvement with extracorporeal liver surgery.125 The technical aspects of anatomic hepatic lobectomies are described later.Liver TransplantationThe rationale supporting OLT for HCC includes the fact that most HCCs (>80%) arise in the setting of cirrhosis.88,126 The cirrhotic liver often does not have enough reserve to tolerate a formal resection. Also, HCC tumors are commonly multifo-cal and are underestimated by current CT or MRI imaging.127 Furthermore, recurrence rates are high at 5 years after resec-tion (>50%). Hence, OLT is an appealing treatment because it removes both the cancer and the cirrhotic liver that leads to can-cer. More than 7000 liver transplantations are performed each year in the United States, with 1-year survival rates approaching 90%. In May 2017, approximately 14,463 patients were on the waiting list for liver transplantation.128Initial series of OLT for HCC reported in the 1990s included advanced cases of HCC, and the 5-year survival rates were only 20% to 50%.88 This compared poorly with overall 5-year survival rates of 70% to 75% for OLT in the Organ Pro-curement and Transplantation Network/United Network for Organ Sharing (OPTN/UNOS) database. Mazzaferro and col-leagues at Milan subsequently showed that survival rates were markedly improved when OLT was limited to patients with early-stage HCC (stage I or stage II) with one tumor ≤5 cm, or up to three tumors no larger than 3 cm, along with the absence of gross vascular invasion or extrahepatic spread.129 Multiple studies have validated these findings, and many groups have proposed an expansion of the Milan criteria.81As noted previously, the 6to 40-point MELD score was adopted by OPTN/UNOS in 2002 for allocation of deceased donor liver organs in the United States. In an attempt to pri-oritize patients with preserved liver function and progressive HCC, patients with stage II HCC are allocated exception points (currently 28 MELD points which activates 6 months after liver transplant listing, increasing every 3 months and capping at 34 points as long as they continue to meet transplant criteria). This allocation has had a positive effect for HCC liver transplant can-didates, leading to decreased waiting list dropout and increased transplant rates with excellent long-term outcomes.130 The goal is to better equate death rates on the liver transplant waiting list for patients with stage I or stage II HCC with rates for patients with chronic liver disease without HCC. Although indications for liver transplantation have increased, the supply of donor liv-ers has failed to keep pace with the numbers of potential recipi-ents. A partial solution has been the use of living donor grafts. This is especially true in Asia where the incidence of HCC is high and the rate of cadaveric donation is low. Living donor grafts include right and left lobes, as well as dual grafts from separate donors to provide adequate hepatic mass to the recipi-ent. The use of living donor grafts also allows for transplant programs to push the boundaries by accepting patients beyond the Milan criteria with good results.112Radiofrequency AblationIn 1891, d’Arsonval discovered that radiofrequency (RF) waves delivered as an alternating electric current (>10 kHz) could pass through living tissue without causing pain or neuromuscular excitation. The resistance of the tissue to the rapidly alternating current produced heat. This discovery contributed to the devel-opment of the surgical application of electrocautery. In 1908, Beer used RF coagulation to destroy urinary bladder tumors. Cushing and Bovie later applied RF ablation to intracranial tumors. In 1961, Lounsberry studied the histologic changes of the liver after RF ablation (RFA) in animal models. He found that RF caused local tissue destruction with uniform necrosis. In the early 1990s, two groups proposed that RFA can be an effective method for destroying unresectable malignant liver tumors.132,133 Both groups found that RFA produced lesions with well-demarcated areas of necrosis without viable tumor cells present. Clinical reports after short-term follow-up sug-gested that RFA was safe and effective in the treatment of liver tumors.134-136 However, Abdalla and colleagues exam-ined data for 358 consecutive patients with colorectal liver metastases treated with curative intent over a 10-year period (1992 to 2002).137 Liver-only recurrence after RFA was four times the rate after resection (44% vs. 11% of patients), and RFA alone or in combination with resection did not provide survival rates comparable to those with resection alone. None-theless, RFA remains a common procedure that can be per-formed by a percutaneous, minimally invasive laparoscopic, or open approach.138,139 It also has been used successfully to ablate small HCCs as a bridge to liver transplantation.140 Results were reported for the first randomized clinical trial involving RFA treatment for HCC in 291 Chinese patients with three or fewer HCC tumors ranging in size from 3 to 7.5 cm.141 Patients were randomly assigned to treatment arms of RFA alone (n = 100), transarterial chemoembolization (TACE) alone (n = 95), or combined TACE plus RFA (n = 96). At a median follow-up of 28.5 months, median survival was 22 months in the RFA group, 24 months in the TACE group, and 37 months in the TACE plus RFA group. Patients treated with TACE plus RFA had sig-nificantly better overall survival than those treated with TACE alone (P <.001) or RFA alone (P <.001). Sucandy and col-leagues examined long-term 5and 10-year overall survival in 320 patients that had hepatic RFA for HCC or colorectal cancer liver metastases (CLM).142 The majority of patients (71%) had a single tumor ablation. Minimum 5-year follow-up was available in 89% patients, with a median follow-up of 115.3 months. In the HCC group, the 5and 10-year overall survivals were 38.5% and 23.4%, respectively, while in the CLM group, the 5and 10-year overall survivals were 27.6% and 15%, respectively.Ethanol Ablation, Cryosurgery, and Microwave AblationPercutaneous ethanol injection has been shown to be a safe and effective treatment for small HCCs.136 The ethanol usually is delivered by percutaneous injection under ultrasound or CT guidance. Percutaneous ethanol injection also is used to treat small HCC tumors as a bridge to liver transplantation in some centers to avoid patient dropout.80 Although cryosurgery was used in the late 1980s and 1990s for ablation of liver tumors, many have abandoned this approach in favor of RFA because of the latter’s fewer side effects and ease of use. Microwave ablation is a thermal ablative technique used in the management of unresectable liver tumors to produce a coagulation necrosis. Brunicardi_Ch31_p1345-p1392.indd 138020/02/19 2:36 PM 1381LIVERCHAPTER 31In a multicenter phase 2 U.S. trial using a 915-MHz micro-wave generator, 87 patients underwent 94 ablation procedures for 224 hepatic tumors.143 Forty-five percent of the procedures were performed using an open approach, 7% laparoscopically, and 48% percutaneously. The average tumor size was 3.6 cm (range, 0.5 to 9.0 cm). At a mean follow-up of 19 months, 47% of the patients were alive with no evidence of disease. Local recurrence at the ablation site occurred in 2.7% of tumors, and regional recurrence occurred in 43% of patients. There were no procedure-related deaths. Further studies are required to define the role of this technology in relation to the other abla-tion options available.Chemoembolization and Hepatic Artery Pump ChemoperfusionChemoembolization is the process of injecting chemotherapeu-tic drugs combined with embolization particles into the hepatic artery that supplies the liver tumor using a percutaneous, trans-femoral approach. It is most commonly used for treatment of unresectable HCC. Three randomized trials and a meta-analysis have shown a survival benefit with chemoembolization.144-147 In a study by Lo and colleagues, 80 Asian patients were randomly assigned to receive either chemoembolization with cisplatin in lipiodol or symptomatic treatment only.144 Chemoembolization resulted in a marked tumor response, and the actuarial survival was significantly better in the chemoembolization group (1and 3-year survival of 57% and 26%, respectively) than in the con-trol group (1and 3-year survival of 32% and 3%, respectively). In another randomized trial, a Barcelona group compared chemoembolization with doxorubicin versus supportive care and showed that chemoembolization significantly improved survival.145 Finally, in a large prospective cohort study of 8510 patients with unresectable HCC in Japan who received trans-catheter arterial lipiodol chemoembolization, the 5-year survival rate was 26% and median survival time was 34 months.146 The TACE-related mortality rate after the initial therapy was 0.5%. Complications of TACE include liver dysfunction or liver fail-ure, hepatic abscess, and hepatic artery thrombosis. Multiple studies also have shown promising results for chemoemboliza-tion with drug-eluting beads in treatment of HCC.148In the 1990s, hepatic artery pump chemoperfusion with floxuridine for colorectal cancer metastases to the liver was used both for treatment of inoperable disease and in the adjuvant setting.149 However, in the modern era of improved chemothera-peutic options, this treatment modality is seldom used outside of a clinical trial.Yttrium-90 MicrospheresSelective internal radioembolization or transarterial radioem-bolization (TARE) is a promising new treatment modality for patients with inoperable primary or metastatic liver tumors. The treatment is a minimally invasive transcatheter therapy in which radioactive microspheres are infused into the hepatic arteries via a transfemoral percutaneous approach. The yttrium-90 micro-spheres are directly injected into the hepatic artery branches that supply the tumor. Once infused, the microspheres deliver doses of high-energy, low-penetration radiation selectively to the tumor. The main indications are inoperable HCC150 and colorec-tal cancer hepatic metastases for which systemic chemotherapy has failed.151,152 In a study involving 137 patients with unresect-able chemorefractory liver metastases treated with radioembo-lization, there was a response rate of 42.8% (2.1% complete response, 40.7% partial response) according to World Health Organization criteria.152 One-year survival rate was 47.8%, and 2-year survival rate was 30.9%. Median survival was 457 days for patients with colorectal tumor metastases, 776 days for those with neuroendocrine tumor metastases, and 207 days for those with noncolorectal, nonneuroendocrine tumor metastases. The two products available in the United States are SIR-Spheres (Sirtex, Sydney, Australia) and TheraSphere (Nordian, Ottawa, Canada).Stereotactic Radiosurgery and Intensity-Modulated Radiation TherapyAlthough stereotactic radiosurgery (with CyberKnife and other systems) is in widespread use for brain and spinal tumors, body application to HCC or metastatic liver tumors has only recently occurred. In a phase 1 study, 31 patients with unresectable HCCs and 10 with unresectable cholangiocarcinomas completed a six-fraction course of stereotactic body radiotherapy.153 The treat-ment was well tolerated, and median survival was 11.7 and 15.0 months for the two groups, respectively. A similar safety profile was observed in a study in the Netherlands.154 Further clinical trials are required to define the future role of stereo-tactic radiosurgery in treatment of HCC and metastatic tumors. Intensity-modulated radiation therapy (IMRT) is another tech-nologic advancement that facilitates the targeted delivery of external-beam radiation. Early clinical data suggested favorable outcomes with IMRT for the treatment of patients with unre-sectable HCC, and ongoing trials are further examining the role of IMRT for these locally advanced tumors.DownstagingIn more advanced-stage patients not eligible for MELD excep-tion points, hepatic-directed therapy including TACE and tumor ablation with radiofrequency, microwave, and ethanol ablation have been found to be effective in shrinking tumors to meet Milan criteria (downstaging). Multiple centers have used down-staging to allow for OLT in patients whose tumors responded and shrank to meet eligibility criteria.155,156Systemic ChemotherapyChemotherapy has not demonstrated great efficacy in patients with HCC, especially in patients with significant cirrhosis. For treatment of HCC, the multikinase inhibitor sorafenib has shown some efficacy in a phase 3 randomized international multicenter trial. The SHARP trial (Sorafenib HCC Assessment Random-ized Protocol) enrolled 602 patients with Child’s class A cir-rhosis and inoperable HCC. At interim analysis, the trial was discontinued because a survival benefit was found in the treat-ment group. The median overall survival for patients receiv-ing sorafenib was 10.7 months versus 7.9 months for patients in the control arm. Based on these findings, sorafenib received accelerated Food and Drug Administration approval for the treatment of advanced unresectable HCC.157 Future studies will likely examine the role of other molecularly targeted agents and combinations of sorafenib with other treatment modalities.HEPATIC RESECTION SURGICAL TECHNIQUESNomenclatureDue to the confusion in language with regard to anatomic descrip-tions of hepatic resections, a common nomenclature was intro-duced at the International Hepato-Pancreato-Biliary Association Brunicardi_Ch31_p1345-p1392.indd 138120/02/19 2:36 PM 1382SPECIFIC CONSIDERATIONSPART IImeeting in Brisbane, Australia, in 2000 (Table 31-8).158,159 The goal was to provide universal terminology for liver anatomy and hepatic resections because there was much overlap among the designations for hepatic lobes, sections, sectors, and segments used by surgeons worldwide (Fig. 31-21). The most common or prevailing anatomic pattern was used as the basis for naming liver anatomy, and the surgical procedure nomenclature adopted for hepatic resections was based on the assigned anatomic ter-minology.160 Adoption of a common language should enable hepatic surgeons to better understand and interpret liver surgery publications from different continents and disseminate their knowledge to the next generation of hepatobiliary surgeons. Nonetheless, even today, the literature is full of both old and new liver resection terminology, so the surgeon in training must be familiar with all the various classifications.Techniques and Devices for Dividing the Hepatic ParenchymaHepatic resection surgery has evolved over the past 50 years. A better understanding of liver anatomy and physiology, coupled with improved anesthesia techniques and widespread use of intraoperative ultrasound, has led to virtually “bloodless” liver surgery in the modern era (the year 2000 to the present). Innova-tions in technology have expanded the list of liver parenchymal transection devices161-163 and hemostatic agents (Table 31-9). Use of each device or agent has a learning curve, and undoubt-edly every experienced hepatic surgeon has his or her personal preferences.One major trend has been the application of vascular sta-pling devices for division of the hepatic and portal veins.164-166 Based on early reports of successful stapling of extrahepatic Table 31-8Brisbane 2000 liver terminologyOLDER HEPATIC RESECTION TERMINOLOGYBRISBANE 2000 HEPATIC RESECTION TERMINOLOGY Right hepatic lobectomy Left hepatic lobectomy Right hepatic trisegmentectomy Left hepatic trisegmentectomy Left lateral segmentectomy Right posterior lobectomy Caudate lobectomy Right hepatectomy or right hemihepatectomy (V, VI, VII, VIII) Left hepatectomy or left hemihepatectomy (II, III, IV) Right trisectionectomy or extended right hepatectomy (or hemihepatectomy, IV, V, VI, VII, VIII) Left trisectionectomy or extended left hepatectomy (or hemihepatectomy, II, III, IV, V, VIII) Left lateral sectionectomy or bisegmentectomy (II, III) Right posterior sectionectomy (VI, VII) Caudate lobectomy or segmentectomy (I)ALTERNATIVE “SECTOR” TERMINOLOGY Right anterior sectorectomy Right posterior sectorectomy or right lateral sectorectomy Left medial sectorectomy or left paramedian sectorectomy (bisegmentectomy, III, IV) Left lateral sectorectomy (segmentectomy, II)IVCRHVMHVVIIVIIIIVaIIVIVIVbIIIFalciform lig.Portal veinIVCLHVIFigure 31-21. Hepatic anatomy. Hepatic segments removed in the formal major hepatic resections are indicated. IVC = inferior vena cava; LHV = left hepatic vein; MHV = middle hepatic vein; RHV = right hepatic vein.Table 31-9Techniques and devices for dividing liver parenchyma and achieving hemostasisBlunt fracture and clipsMonopolar cautery (Bovie)Bipolar cauteryArgon beam coagulatorCUSA ultrasonic dissectorHydro-Jet water-jet dissectorHarmonic Scalpel, AutoSonix ultrasonic transector-coagulatorLigaSure tissue fusion systemSurgRx EnSeal tissue sealing and transection systemGyrus PK cutting forcepsEndovascular staplersTissueLink sealing devicesHabib 4X Laparoscopic sealerInLine bipolar linear coagulatorTopical agents (fibrin glues, Surgicel, Gelfoam, Avitene, Tisseel, Floseal, Crosseal)Brunicardi_Ch31_p1345-p1392.indd 138220/02/19 2:36 PM 1383LIVERCHAPTER 31vessels, stapling devices are now being used in the parenchymal transection phase, which remains a source of potential blood loss due to back bleeding from the middle hepatic vein.167,168 One advantage of the stapling technique is the speed with which the transection can be performed, which minimizes surface bleeding and period of ischemia for the remnant liver. How-ever, a major disadvantage of the stapling technique is the cost of multiple stapler cartridges. This is balanced by the decreased expenses reported with avoidance of ICU admission and blood transfusion, as well as shortened operating room time. Another consideration in the use of staplers for parenchymal transec-tion is the potential for bile leaks. However, in a large series of 101 consecutive right hemihepatectomies performed using the stapling technique, there was only one reported bile leak (1%), which sealed after ERCP.168Steps in Commonly Performed Hepatic ResectionsA fundamental understanding of hepatic anatomy is vital for any surgeon with the desire to perform hepatobiliary surgery. Each hepatic resection surgery can be broken down into a series of orderly steps. The key to being a proficient hepatic surgeon is not to operate swiftly but rather to accomplish the operation by completing the steps in an orchestrated fashion. Mastery of the operative steps coupled with knowledge of liver anatomy and the common anatomic variants provides the foundation for safe hepatic surgery. There are many different techniques and sequences for accomplishing each of the anatomic (and nonana-tomic) hepatic operations. The authors present their preferred approach in a stepwise fashion for right hepatic lobectomy (right hemihepatectomy), left hepatic lobectomy (left hemihepa-tectomy), and left lateral segmentectomy (left lateral sectionec-tomy). Provision of a detailed approach for every type of liver resection is beyond the scope of this chapter, and readers are referred to several excellent descriptions.169Steps Common to All Open Major Hepatic Resections 1. Make the skin incision—right subcostal with or without a partial or complete left subcostal extension across the mid-line, depending on the patient’s habitus and liver/tumor anatomy.2. Open and explore the abdomen, and place a fixed table retractor (e.g., Thompson or Bookwalter).3. Examine the liver with bimanual palpation. Perform liver ultrasound, and confirm the operation to be performed.4. Take down the round and falciform ligaments, and expose the anterior surface of the hepatic veins.5. For a left hepatectomy, divide the left triangular ligament; for a right hepatectomy, mobilize the right lobe from the right coronary and triangular ligaments.6. Open the gastrohepatic ligament, palpate the porta hepatis, and assess for accessory or replaced hepatic arteries.7. Perform a cholecystectomy; leave the gallbladder with the cystic duct intact if the gallbladder is involved by the tumor.Right Hepatic Lobectomy (Right Hepatectomy or Hemihepatectomy) 8. Mobilize the liver from the anterior aspect of the IVC in “piggyback” fashion; ligate the short hepatic veins up to the right hepatic vein (RHV).9. Perform a right hilar dissection—gently lower the hilar plate, then doubly ligate and divide the right hepatic artery (RHA), superior to the right side of the common bile duct.10. Doubly ligate and divide a replaced or accessory RHA if present.11. Expose the portal vein, identifying its right and left branches. There is a small lateral portal vein branch off the right portal vein (RPV) to the caudate lobe that should be controlled and ligated to allow the exposure of additional length on the RPV. Divide the RPV either with a vascular stapler or between vascular clamps.12. Dissect the avascular tissue along the suprahepatic vena cava between the right and middle hepatic veins. Pass a silastic tube of a Jackson-Pratt drain through this gap.13. Notch or divide the caudate process crossing to the right hepatic lobe, and bring the drain up and through this notch.14. Hang the liver over the drain by pulling up as you divide through the liver parenchyma.15. Repeat ultrasound and confirm the transection plane, staying just to the right of the middle hepatic vein (MHV) unless the tumor extends over it.16. Cauterize approximately 1 cm into the liver parenchyma, then switch to a hydro-jet dissection device in combination with Bovie electrocautery and suture ligation.17. Continue parenchymal division until the RHV is encoun-tered. During this division, identification, control, ligation, and transection of the right hepatic duct (RHD) are obtained late in the parenchymal transection process.18. Divide the RHV between vascular clamps and suture ligate the RHV.19. Examine the transected liver edge for bleeding; place a figure-of-eight ligating vascular suture if bleeding is encountered.20. Ensure hemostasis of the transected liver edge with an argon beam coagulator and suture ligation.21. Inspect the transection surface for bile leaks. These should be clipped or suture ligated. Applying a dilute solution of hydro-gen peroxide can facilitate the visualization of bile leaks.22. Inspect the IVC and right retroperitoneal space for hemostasis.23. Perform completion ultrasound to confirm left portal vein (LPV) inflow and outflow in the remaining hepatic veins.24. Fix the proximal falciform ligament back to the diaphragm side with figure-of-eight sutures.25. Apply tissue sealant to the cut surface of the liver, and place a Jackson-Pratt drain in the right subphrenic space and close the abdomen (Fig. 31-22).Comments Although some liver surgeons advocate a one-step division of the entire intrahepatic Glissonian pedicle as described by Launois and Jamieson,170 it is the authors’ prefer-ence to divide the RHA, RHD, and RPV in an extrahepatic fash-ion. As for the transection plane, the key is to perform accurate ultrasound visualization and mapping of the MHV and to stay just to the right of it. Weaving in and out or bisecting the MHV can leading to torrential back bleeding. Also, for bulky right lobe tumors adherent to the diaphragm or retroperitoneum, an anterior approach with division of the parenchyma can be per-formed before right lobe mobilization.152,153Left Hepatic Lobectomy (Left Hepatectomy or Hemihepatectomy)  8. Widely open the gastrohepatic ligament flush with the undersurface of the left lateral section and the caudate lobe. 9. Doubly ligate and divide a replaced or accessory left hepatic artery (LHA) if present.Brunicardi_Ch31_p1345-p1392.indd 138320/02/19 2:36 PM 1384SPECIFIC CONSIDERATIONSPART II10. Clamp the round ligament (ligament teres) and pull it ante-riorly as a handle to expose the left hilum.11. Divide any existing parenchymal bridge between segments III and IVB.12. Dissect the left hilum at the base of the umbilical fissure and lower the hilar plate anterior to the left portal pedicle.13. Incise the peritoneum overlying the hilum from the left side, and doubly ligate the LHA (after test clamping and confirming a palpable pulse in the RHA).14. Dissect the portal vein at the base of the umbilical fissure (it will take a nearly 90° bend from the transverse to the umbilical portion).15. Expose the portal vein, identifying the right and left branches. Control the small portal vein branch off the LPV to the caudate lobe to allow the exposure of additional length. Divide the LPV either with a vascular stapler or between vascular clamps.16. Ligate and divide the ligamentum venosum caudally.17. Identify the long extrahepatic course of the left hepatic duct (LHD) behind the portal vein. Ligate and divide the LHD at the umbilical fissure.18. Fold the left lateral segment up and back to the right, expos-ing the window at the base of the left hepatic vein (LHV) as it enters the IVC. This is facilitated by dividing any loose areolar tissue overlying the ligamentum venosum, which is divided proximally.19. Pass a large, blunt right-angle clamp in the window between the RHV and the MHV, and hug the back of the MHV, aim-ing for the deep edge of the LHV. Do not force it or perfo-rate the IVC or MHV.20. Pass the silastic tube of a Jackson-Pratt drain through this window.21. Notch or divide the caudate process crossing to the left hepatic lobe and bring the drain up and through this notch.22. Hang the liver over the drain by pulling up as you divide through the liver parenchyma.23. Repeat ultrasound and confirm the transection plane on the anterior surface, staying close to the demarcated line. Do not bisect the MHV as it passes tangentially from the left to the right lobe.24. Cauterize down approximately 1 cm in the liver paren-chyma, then switch to a hydro-jet dissection device in com-bination with Bovie electrocautery and suture ligation.25. Continue parenchymal division until the left/middle hepatic veins are encountered.26. Divide the LHV and MHV between vascular clamps and suture the ligate the LHV/MHV.27. Check the transected edge of the liver for surgical bleed-ing; ensure hemostasis of the transected edge with an argon beam coagulator and suture ligation.28. Inspect the transection surface for bile leaks. These should be clipped or suture ligated. Apply dilute solution of hydro-gen peroxide to facilitate the visualization of bile leaks.29. Perform completion ultrasound to confirm RPV inflow and RHV outflow.30. Apply tissue sealant to the transected surface of the liver. Place a Jackson-Pratt drain in the left subphrenic space and close the abdomen (Fig. 31-23).Comments Because the right posterior duct arises from the left hepatic duct (LHD) in approximately 20% of cases (see Fig. 31-9) and the right anterior duct comes off the LHD in approximately 5% of cases,6 it is vital to divide the LHD at the base of the umbilical fissure and not more centrally in the hilum as it bifurcates. If the LHD were divided as it appears to bifurcate from the right hepatic duct, then approximately 20% to Figure 31-22. Completed right hepatic lobectomy (right hepa-tectomy) with the right portal vein, right hepatic artery, and right bile duct ligated and divided. The right hepatic vein is ligated and divided. Middle hepatic vein branches inside the liver are divided.Figure 31-23. Completed left hepatic lobectomy (left hepatec-tomy) resecting segments II, III, and IV.Brunicardi_Ch31_p1345-p1392.indd 138420/02/19 2:37 PM 1385LIVERCHAPTER 3125% of the time, either the right posterior or right anterior duct would be transected. After the LHD is divided as described ear-lier (Step 17), the liver parenchyma is scored and divided hori-zontally approximately 1 cm above the left hilum; the surgeon thus assumes that an aberrant right anterior or posterior duct is coming off the LHD in the hilum and preserves it. Then as the parenchymal transection reaches the left side of the gallblad-der fossa, the transection plane turns vertical to run parallel to Cantlie’s line (or the left edge of the gallbladder bed). The left lobe of the liver will be well demarcated at this point (after the vascular inflow has been divided), which guides the transection plane on the anterior surface. In general, the transection plane should be close to the demarcation line to minimize the amount of devascularized liver remaining. When dividing the LHV and MHV, the surgeon should keep in mind that they have a com-mon trunk approximately 90% of the time. If it is not easy to open the window deep to the MHV and LHV, then division of the MHV and LHV can be accomplished after the parenchymal transection.Left Lateral Segmentectomy (Left Lateral Sectionectomy)  8. Widely open the gastrohepatic ligament flush with the undersurface of the left lateral section and the caudate lobe. 9. Doubly ligate and divide a replaced or accessory LHA if present.10. Clamp the round ligament and pull it anteriorly as a handle to expose the left hilum.11. Divide any existing parenchymal bridge between segments III and IVB.12. Carry the dissection down from the end of the round liga-ment, and the segment III pedicle will be encountered.13. Incise the peritoneal reflection on the left side of the round ligament as it inserts into the umbilical fissure. This will facilitate encircling the segment III and II pedicles, which can be divided separately. When encircling the segment II pedicle, take care to avoid injury to the caudate inflow ves-sels coming off the LPV.14. Divide the liver parenchyma, staying flush on the left side of the falciform ligament using Bovie electrocautery.15. Divide the LHV as the parenchymal transection is complete.16. A Pringle maneuver usually is not required for a left lateral sectionectomy because complete devascularization occurs before transection and little back bleeding is encountered.Comments If the segment III and II LHA branches are large, they can be individually ligated in the left hilum before the pedicles (with portal vein and hepatic duct branches) are taken. If the tumor is more peripheral in the left lateral segment, then the segment III and II pedicles can be divided with a vascular stapler inside the liver during the parenchymal transection.Pringle and Ischemic PreconditioningPringle described clamping of the portal triad a century ago in the landmark paper “Notes on the Arrest of Hepatic Hemorrhage Due to Trauma.”4 Although the Pringle maneuver was initially described for controlling bleeding due to traumatic liver injury, it is commonly used during elective hepatic resections.173,174 The goal is to minimize blood loss and hypotension, which add sig-nificant morbidity to the operation. Furthermore, intraoperative blood transfusion has been shown to be an independent risk fac-tor for increased postoperative infection as well as worse patient survival in some studies. Therefore, all efforts should be made to minimize blood loss during hepatic resection.Although the liver has been shown to tolerate up to 1 hour of warm ischemia, some technical variations of the Pringle maneuver include intermittent vascular occlusion with cycles of approximately 15 minutes on and 5 minutes off. Experimental and clinical studies have demonstrated the efficacy of intermit-tent vascular occlusion in decreasing ischemia/reperfusion injury compared with continuous vascular occlusion, with less eleva-tion of postoperative liver enzyme levels.175 Another variation is selective hemihepatic vascular occlusion, which can reduce the severity of visceral congestion and total liver ischemia. In one prospective trial of total versus selective portal triad clamping, both techniques of inflow clamping were found to be equally effective for patients with normal livers, but greater liver dam-age was observed with total inflow occlusion in patients with cirrhotic livers.176In an attempt to decrease the ischemic damage associated with inflow occlusion, some hepatic surgeons have advocated the use of ischemic preconditioning.177 Ischemic precondition-ing refers to the brief interruption of blood flow to an organ, fol-lowed by a short reperfusion period, and then a more prolonged period of ischemia. In a randomized clinical trial involving 100 patients undergoing major hepatic resection, Clavien and col-leagues reported significantly less liver injury in the group who received ischemic preconditioning with a 10-minute clamp, a 10-minute reperfusion, and then a 30-minute clamp than in those who received a 30-minute clamp alone.178 Patients with steatosis also were especially protected by ischemic preconditioning, and the mechanism was shown to be related in part to preservation of the adenosine triphosphate content of liver tissue.Preoperative Portal Vein EmbolizationThe observation that tumor thrombosis of a major portal vein branch induced ipsilateral lobar atrophy and contralateral lobe hypertrophy led to the concept of intentional preoperative portal vein embolization (PVE) to induce compensatory hypertrophy of the remnant liver. This procedure was first described in the 1980s and is accomplished via a percutaneous, transhepatic route.160,161 Numerous studies have subsequently confirmed that PVE is effective in inducing hypertrophy of nonembolized hepatic segments.86,181 PVE usually is performed in the setting of a planned right trisectionectomy or extended left hepatec-tomy (also referred to as a left trisectionectomy; resection of Couinaud’s segments II, III, IV, V, and VIII of the liver) or extended hepatic lobectomy when it is thought that the patient’s remnant liver will be too small to support liver function. The future liver remnant volume (e.g., the volume of segments II, III, and I) in a patient undergoing a planned right trisectionec-tomy can be directly measured by helical CT and then divided by the total estimated liver volume to calculate the percentage of the future liver remnant. If the future liver remnant is thought to be too small, then PVE should be considered to increase the size of the future liver remnant.182 In general, surgery is planned approximately 4 weeks after PVE to allow adequate time for hypertrophy.There is no universal agreement on what constitutes a future liver remnant adequate to avoid postoperative liver fail-ure. It is thought that 25% to 30% of the total liver volume is ade-quate in patients with a normal liver.183 Vauthey and associates reported that major postoperative complications were increased when the estimated future liver remnant was <25%.184 Farges and colleagues conducted a prospective study to assess the benefits of PVE before right hepatectomy. They demonstrated Brunicardi_Ch31_p1345-p1392.indd 138520/02/19 2:37 PM 1386SPECIFIC CONSIDERATIONSPART IIthat PVE had no beneficial effect on the postoperative course in patients with normal livers but significantly reduced postop-erative complications in patients with chronic liver diseases.185 A larger remnant may be necessary even in patients with nor-mal livers when a complex hepatectomy is planned or when the background liver is steatotic.186 This is especially relevant with the increased incidence of fatty liver disease. A larger remnant may also be needed when patients have received pre-operative chemotherapy. Some have suggested that 40% of the total hepatic volume should remain to minimize postoperative complications in patients who have underlying liver disease or who have received preoperative chemotherapy for colorectal cancer metastases.187,188 In a recent study encompassing 112 patients who underwent PVE, major complications, hepatic insufficiency, length of hospital stay, and 90-day mortality rate were significantly greater in patients with a standardized future liver remnant of ≤20% or a degree of hypertrophy of <5% than in patients with higher values.189 In another study, the authors performed PVE during neoadjuvant chemotherapy for colorec-tal cancer metastases. After a median wait of 30 days after PVE, patients receiving neoadjuvant chemotherapy showed median liver growth of 22% in the contralateral (nonembolized) lobe compared with 26% for those not receiving chemotherapy (not a statistically significant difference), which indicated that liver growth occurs after PVE even when cytotoxic chemotherapy is administered.190 PVE-related complications occur at a relatively low rate and include bleeding, hemobilia, liver abscess, incom-plete embolization, and small bowel obstruction. To augment the ability to increase liver function reserve in patients who have undergone PVE, some groups have added ipsilateral hepatic artery embolization and ipsilateral hepatic vein embolization.191Staged Hepatectomy, ALPPS, and Repeat Hepatic Resection for Recurrent Liver CancerA two-stage hepatectomy is a sequential resection strategy to remove all metastatic liver tumors when it is impossible to resect all disease in a single operative procedure. The first-stage hepatectomy usually consists of clearance of the left hemiliver by nonanatomic resection, followed by right portal vein ligation or embolization to induce left lobe hypertrophy.192,193 This is fol-lowed by a second-stage major right hepatectomy or extended right hepatectomy to resect the right liver metastases. This approach is most commonly used in cases of initially unresect-able colorectal hepatic metastases and has yielded very good results.193Another technique to increase future liver remnant to avoid post-hepatectomy liver failure is known as “Associating Liver Partition and Portal Vein Ligation for Staged Hepatec-tomy (ALPPS)” and was described in 2012. This technique consists of operative portal vein ligation with in situ liver tran-section along the future line of resection leaving the arterial and hepatic vein branches intact.194 There have been several techni-cal modifications to the original description, and this remains a hot topic that is actively debated (ALPPS vs. PVE) at the current liver surgery meetings.The majority of patients undergoing hepatic resection for colorectal cancer metastases experience a recurrence. For those with limited disease recurrence confined to the liver, repeat hepatectomy is a reasonable option and can be performed with low morbidity and mortality in experienced hands.195 In one study, 126 patients who underwent a second liver resection for colorectal cancer metastases had 1-, 3-, and 5-year survival rates of 86%, 51%, and 34%, respectively. By multivariate analysis, the presence of more than one lesion and a tumor size of >5 cm were independent prognostic indicators of reduced survival.196 In another study, 40 patients underwent a second hepatectomy for liver metastases from colorectal cancer and experienced a survival benefit similar to that from the first hepatectomy; how-ever, the results suggested that this approach should be limited to those patients who do not have extrahepatic disease and for whom >1 year has elapsed since the first operation.197 A meta-analysis of 21 studies examining clinical outcomes after first and second liver resections for colorectal cancer metastases showed that repeat hepatectomy was safe and provided a sur-vival benefit equal to that from the first liver resection.198Repeat hepatectomy also has been performed in patients with HCC. Nakajima and colleagues reported on follow-up of 94 patients who underwent curative liver resection for HCC from 1991 to 1996.199 Of these, 57 patients had isolated recur-rent disease in the liver. Twelve of these 57 patients underwent repeat hepatic resection, whereas the other 45 patients received ablation therapy. The overall survival rate in those undergoing a second hepatectomy was 90% at 2 years; however, the disease-free survival rate was only 31% at 2 years, significantly lower than the 62% rate after initial hepatectomy. Likewise, in another group of 84 patients who underwent second hepatectomy for recurrent HCC, the overall 5-year survival rate was 50%, but the recurrence-free survival rate was only 10%.200 In a report of 67 patients undergoing a second resection for HCC, over-all 1-, 3-, and 5-year survival rates were 93%, 70%, and 56%, respectively.201 Multivariate analysis showed that absence of portal invasion at the second resection, single HCC at primary hepatectomy, and disease-free interval of ≥1 year after primary hepatectomy were independent prognostic factors after the sec-ond resection.LAPAROSCOPIC LIVER RESECTIONCherqui and colleagues first reported in 2000 that laparoscopic hepatic surgery was feasible.202 Since this initial report, laparo-scopic liver surgery has expanded from the simple unroofing of hepatic cysts to resection of peripheral benign lesions to formal anatomic lobectomies for malignancy and laparoscopic hepa-tectomy for living donor liver transplantation. While minimally invasive approaches have been widely adopted in other areas of abdominal surgery, there was initial apprehension regarding laparoscopic liver resection (LLR), hampering its widespread adoption.203 Great strides have been made in the past decade with techniques of laparoscopic liver resection,204,205 and two International Laparoscopic Liver Resection Consensus Confer-ences have been convened in Louisville (2008) and Morioko (2014).206,207 Indications for liver resection should not be altered by the availability of minimally invasive liver resection tech-niques. Currently, over 9500 cases of laparoscopic liver resec-tion have been reported worldwide, with over 50% of the cases being done for malignancy.208Pure laparoscopic and hand-assisted laparoscopic liver resection are the two most commonly used techniques for mini-mally invasive liver resection surgery,209,210 while robotic liver resection is being used by several groups.211 Advantages of the hand-port include tactile feedback, facilitation of liver mobiliza-tion, and ease of ability to control bleeding. Also, when doing a large parenchymal resection, the hand-port can be comparable in size to the extraction port utilized in the purely laparoscopic Brunicardi_Ch31_p1345-p1392.indd 138620/02/19 2:37 PM 1387LIVERCHAPTER 31approach. The hand-assisted approach can be ideal for surgeons beginning the transition to laparoscopic liver resection and for more experienced laparoscopic HPB surgeons doing laparo-scopic major hepatectomies or as an alternative to conversion to open surgery.Benefits of laparoscopic liver resection include less blood loss, decreased morbidity, decreased postoperative pain and narcotic requirements, faster return of bowel function, and shorter length of hospital stay compared to open hepatic resection.212 Long-term oncologic outcomes for HCC and CLM have been shown to be comparable for laparoscopic vs. open liver resection using propensity score matching and meta-analysis studies.213-215 The learning curve for laparoscopic liver resection has been reported to be around 60 cases,216 although this may be greater for laparoscopic major hepatectomy.217-219 Cost analy-sis has shown that laparoscopic liver resection is cost effective compared to open liver resection, where the added cost of the operating room disposables are more than offset by the savings associated with ∼50% reduction in the hospital length of stay.221,222Initial experience with laparoscopic living-donor hepatec-tomy for transplantation was with left lateral segmentectomy during liver allograft procurement for pediatric transplants.222 With continued advances in laparoscopic liver surgery, LLR has been applied to adult-to-adult donor right hepatectomy,223,224 although this approach remains controversial.In summary, laparoscopic liver resection can now be per-formed safely by experienced surgeons in selected patients. Compared to open hepatic resection, the laparoscopic approach has benefits of less blood loss, reduced postoperative pain, and a shorter length of hospital stay, with similar oncologic out-comes for resection of HCC and limited colorectal liver metastases.REFERENCESEntries highlighted in bright blue are key references. 1. Wikipedia. Prometheus. Available at: http://en.wikipedia.org/wiki/Prometheus. Accessed July 26, 2018. 2. Keen WW IV. Report of a case of resection of the liver for the removal of a neoplasm, with a table of seventy-six cases of resection of the liver for hepatic tumors. Ann Surg. 1899;30(3):267-283. 3. Fortner JG, Blumgart LH. A historic perspective of liver sur-gery for tumors at the end of the millennium. J Am Coll Surg. 2001;193(2):210-222. 4. Pringle JH V. Notes on the arrest of hepatic hemorrhage due to trauma. Ann Surg. 1908;48(4):541-549. 5. Cantlie J. On a new arrangement of the right and left lobes of the liver. Proc Anat Soc Great Britain Ireland. 1897;32:4-9. 6. Couinaud C. Lobes de segments hepatiques: notes sur l’architecture anatomique et chirurgical de foie. Presse Med. 1954;62(33):709-712. 7. Abdalla EK, Vauthey JN, Couinaud C. The caudate lobe of the liver: implications of embryology and anatomy for surgery. Surg Oncol Clin N Am. 2002;11(4):835-848. 8. Bismuth H. Surgical anatomy and anatomical surgery of the liver. World J Surg. 1982;6(1):3-9. 9. Nordlie RC, Foster JD, Lange AJ. Regulation of glucose pro-duction by the liver. Annu Rev Nutr. 1999;19:379-406. 10. Merriman R. Approach to the patient with jaundice. In: Yamada T, ed. Textbook of Gastroenterology. 4th ed. Philadelphia: Lippincott Williams & Williams; 2003:911. 11. Ramadori G, Christ B. Cytokines and the hepatic acute-phase response. Semin Liver Dis 1999;19(2):141-155. 12. Tsung A, Geller DA. CD14 and Toll Receptor. In: Dufour JF, Clavien PA, eds. Signaling Pathways in Liver Diseases. Berlin: Springer; 2005:165-171. 13. Su GL. Lipopolysaccharides in liver injury: molecular mecha-nisms of Kupffer cell activation. Am J Physiol Gastrointest Liver Physiol. 2002;283:G256-G265. 14. Geller DA, Billiar TR. Molecular biology of nitric oxide syn-thases. Cancer Metastasis Rev. 1998;17:7-23. 15. Prince JM, Billiar TR. Nitric Oxide. In: Dufour JF, Clavien PA, eds. Signaling Pathways in Liver Diseases. Berlin: Springer; 2005:299-310. 16. Tsuchihashi S, Busuttil RW, Kupiec-Weglinski JW. Heme Oxygenase System. In: Dufour JF, Clavien PA, eds. Sig-naling Pathways in Liver Diseases. Berlin: Springer; 2005: 291-298. 17. Zuckerbraun BS, Billiar TR. Heme oxygenase-1: a cellular Hercules. Hepatology. 2003;37:742-744. 18. Akira S, Takeda K. Toll-like receptor signalling. Nat Rev Immunol. 2004;4:499-511. 19. Mollen KP, Anand RJ, Tsung A, Prince JM, Levy RM, Billiar TR. Emerging paradigm: toll-like receptor 4-sentinel for the detection of tissue damage. Shock 2006;26:430-437. 20. Farombi EO, Surh YJ. Heme oxygenase-1 as a potential therapeutic target for hepatoprotection. J Biochem Mol Biol 2006;39:479-491. 21. Kruskal JB, Kane RA. Intraoperative US of the liver: techniques and clinical applications. Radiographics. 2006;26(4):1067-1084. 22. Martinez SM, Crespo G, Navasa M, Forns X. Noninvasive assessment of liver fibrosis. Hepatology. 2011;53(1):325-335. 23. Federle MP, Blachar A. CT evaluation of the liver: principles and techniques. Semin Liver Dis. 2001;21(2):135-145. 24. Hyodo T, Kumano S, Kushihata F, et al. CT and MR cholan-giography: advantages and pitfalls in perioperative evaluation of biliary tree. Br J Radiol. 2012;85(1015):887-896. 25. Ros PR, Davis GL. The incidental focal liver lesion: photon, proton, or needle? Hepatology. 1998;27(5):1183-1190. 26. Wald C, Scholz FJ, Pinkus E, Wise RE, Flacke S. An update on biliary imaging. Surg Clin North Am. 2008;88(6):1195-1220. 27. Wiering B, Krabbe PF, Jager GJ, Oyen WJ, Ruers TJ. The impact of fluor-18-deoxyglucose-positron emission tomogra-phy in the management of colorectal liver metastases. Cancer. 2005;104(12):2658-2670. 28. Sacks A, Peller PJ, Surasi DS, Chatburn L, Mercier G, Sub-ramaniam RM. Value of PET/CT in the management of liver metastases, part 1. AJR Am J Roentgenol. 2011;197(2): W256-W259. 29. Bernal W, Auzinger G, Dhawan A, Wendon J. Acute liver failure. Lancet. 2010;376(9736):190-201. An outstanding review of pathophysiology, treatment, and evidence based outcomes for patients with acute liver failure. 30. Polson J, Lee WM. Etiologies of acute liver failure: location, location, location! Liver Transpl. 2007;13(10):1362. 31. Agopian V, Petrowsky H, Kaldas FM, et al. The evolution of liver transplantation during three decades: analysis of 5347 consecutive liver transplants at a single center. Ann Surg. 2013;258(3):409-421. 32. Escorsell A, Mas A, de la Mata M, Spanish Group for the Study of Acute Liver F. Acute liver failure in Spain: analysis of 267 cases. Liver Transpl. 2007;13(10):1389-1395. 33. Larson AM, Polson J, Fontana RJ, et al. Acetaminophen-induced acute liver failure: results of a United States multi-center, prospective study. Hepatology. 2005;42(6):1364-1372. 34. Ostapowicz G, Fontana RJ, Schiodt FV, et al. Results of a pro-spective study of acute liver failure at 17 tertiary care centers in the United States. Ann Intern Med. 2002;137(12):947-954. 35. Hodgman MJ, Garrard AR. A review of acetaminophen poi-soning. Crit Care Clin. 2012;28(4):499-516.10Brunicardi_Ch31_p1345-p1392.indd 138720/02/19 2:37 PM 1388SPECIFIC CONSIDERATIONSPART II 36. Kortsalioudaki C, Taylor RM, Cheeseman P, Bansal S, Mieli-Vergani G, Dhawan A. Safety and efficacy of N-acetylcysteine in children with non-acetaminophen-induced acute liver fail-ure. Liver Transpl. 2008;14(1):25-30. 37. O’Grady JG, Alexander GJ, Hayllar KM, Williams R. Early indicators of prognosis in fulminant hepatic failure. Gastroen-terology. 1989;97(2):439-445. 38. Bismuth H, Samuel D, Castaing D, et al. Orthotopic liver transplantation in fulminant and subfulminant hepatitis. The Paul Brousse experience. Ann Surg. 1995;222(2):109-119. 39. Antoniades CG, Berry PA, Bruce M, et al. Actin-free Gc globulin: a rapidly assessed biomarker of organ dysfunc-tion in acute liver failure and cirrhosis. Liver Transpl. 2007;13(9):1254-1261. 40. Renner EL. How to decide when to list a patient with acute liver failure for liver transplantation? Clichy or King’s College criteria, or something else? J Hepatol. 2007;46(4):554-557. 41. Faybik P, Krenn CG. Extracorporeal liver support. Curr Opin Crit Care. 2013;19(2):149-153. 42. Ekser B, Gridelli B, Tector AJ, Cooper DK. Pig liver xenotrans-plantation as a bridge to allotransplantation: which patients might benefit? Transplantation. 2009;88(9):1041-1049. 43. Yu Y, Fisher JE, Lillegard JB, Rodysill B, Amiot B, Nyberg SL. Cell therapies for liver diseases. Liver Transpl. 2012;18(1):9-21. 44. Faraj W, Dar F, Bartlett A, et al. Auxiliary liver trans-plantation for acute liver failure in children. Ann Surg. 2010;251(2):351-356. 45. Wanless IR, Nakashima E, Sherman M. Regression of human cirrhosis. Morphologic features and the gen-esis of incomplete septal cirrhosis. Arch Pathol Lab Med. 2000;124(11):1599-1607. 46. Fattovich G, Giustina G, Degos F, et al. Morbidity and mortal-ity in compensated cirrhosis type C: a retrospective follow-up study of 384 patients. Gastroenterology. 1997;112(2):463-472. 47. Rinella ME, Sanyal AJ. Management of NAFLD: a stage-based approach. Nat Rev Gastroenterol Hepatol. 2016:13:196-205. 48. Loomba R, Sanyal AJ. The global NAFLD epidemic. Nat Rev Gastroenterol Hepatol. 2013;10:686-690. 49. Michelotti GA, Machado MV, Diehl AM. NAFLD, NASH and liver cancer. Nat Rev Gastroenterol Hepatol. 2013;10:656-665. 50. Schuppan D, Afdhal NH. Liver cirrhosis. Lancet. 2008;371:838-851. 51. Bhala N, Angulo P, van der Poorten D, et al. The natural his-tory of nonalcoholic fatty liver disease with advanced fibrosis or cirrhosis: an international collaborative study. Hepatology. 2011;54:1208-1216. 52. Sanyal AJ, Banas C, Sargeant C, et al. Similarities and differ-ences in outcomes of cirrhosis due to nonalcoholic steatohepa-titis and hepatitis C. Hepatology. 2006;43:682-689. 53. Lehmann K, Rickenbacher A, Weber A, et al. Chemotherapy before liver resection of colorectal metastases: friend or foe? Ann Surg. 2012;255:237-247. 54. Vetelainen R, van Vliet A, Gouma DJ, van Gulik TM. Steatosis as a risk factor in liver surgery. Ann Surg. 2007;245:20-30. 55. Reddy SK, Marsh JW, Varley PR, et al. Underlying steato-hepatitis, but not simple hepatic steatosis, increased morbid-ity after liver resection: a case-control study. Hepatology. 2012;56(6):221-230. 56. Doberneck RC, Sterling WA, Jr, Allison DC. Morbidity and mortality after operation in nonbleeding cirrhotic patients. Am J Surg. 1983;146(3):306-309. 57. Northup PG, Wanamaker RC, Lee VD, Adams RB, Berg CL. Model for End-Stage Liver Disease (MELD) predicts non-transplant surgical mortality in patients with cirrhosis. Ann Surg. 2005;242(2):244-251. 58. Farnsworth N, Fagan SP, Berger DH, Awad SS. ChildTurcotte-Pugh versus MELD score as a predictor of outcome after elective and emergent surgery in cirrhotic patients. Am J Surg. 2004;188(5):580-583. 59. Hanje AJ, Patel T. Preoperative evaluation of patients with liver disease. Nat Clin Pract Gastroenterol Hepatol. 2007;4(5):266-276. 60. Shah V. Cellular and molecular basis of portal hypertension. Clin Liver Dis. 2001;5(3):629-644. 61. Poynard T, Cales P, Pasta L, et al. Beta-adrenergic-antagonist drugs in the prevention of gastrointestinal bleeding in patients with cirrhosis and esophageal varices. An analysis of data and prognostic factors in 589 patients from four randomized clini-cal trials. Franco-Italian Multicenter Study Group. N Engl J Med. 1991;324(22):1532-1538. 62. Garcia-Pagan JC, Bosch J. Endoscopic band ligation in the treatment of portal hypertension. Nat Clin Pract Gastroenterol Hepatol. 2005;2(11):526-535. 63. Valla DC. The diagnosis and management of the Budd-Chiari syndrome: consensus and controversies. Hepatology. 2003;38(4):793-803. 64. Henderson JM, Warren WD, Millikan WJ, Jr, et al. Surgical options, hematologic evaluation, and pathologic changes in Budd-Chiari syndrome. Am J Surg. 1990;159(1):41-50. 65. Barnes PF, De Cock KM, Reynolds TN, Ralls PW. A com-parison of amebic and pyogenic abscess of the liver. Medicine (Baltimore). 1987;66(6):472-483. 66. Pedrosa I, Saiz A, Arrazola J, Ferreiros J, Pedrosa CS. Hydatid disease: radiologic and pathologic features and complications. Radiographics. 2000;20(3):795-817. 67. Khuroo MS, Zargar SA, Mahajan R. Hepatobiliary and pan-creatic ascariasis in India. Lancet. 1990;335(8704):1503-1506. 68. Scaglione SJ, Lok AS. Effectiveness of hepatitis B treatment in clinical practice. Gastroenterology. 2012;142(6):1360-1368. 69. Corey KE, Mendez-Navarro J, Gorospe EC, Zheng H, Chung RT. Early treatment improves outcomes in acute hepatitis C virus infection: a meta-analysis. J Viral Hepat. 2010;17(3):201-207. 70. Tsung A, Geller DA. Workup of the incidental liver lesion. Adv Surg. 2005;39:331-341. 71. Caremani M, Vincenti A, Benci A, Sassoli S, Tacconi D. Eco-graphic epidemiology of non-parasitic hepatic cysts. J Clin Ultrasound. 1993;21(2):115-118. 72. Tahvanainen P, Tahvanainen E, Reijonen H, Halme L, Kaari-ainen H, Hockerstedt K. Polycystic liver disease is genetically heterogeneous: clinical and linkage studies in eight Finnish families. J Hepatol. 2003;38(1):39-43. 73. Drenth JP, Chrispijn M, Nagorney DM, Kamath PS, Torres VE. Medical and surgical treatment options for polycystic liver disease. Hepatology. 2010;52(6):2223-2230. 74. Robinson TN, Stiegmann GV, Everson GT. Laparo-scopic palliation of polycystic liver disease. Surg Endosc. 2005;19(1):130-132. 75. Caroli J. Disease of the intrahepatic biliary tree. Clin Gastro-enterol. 1972;2:147-161. 76. Yoon SS, Charny CK, Fong Y, et al. Diagnosis, management, and outcomes of 115 patients with hepatic hemangioma. J Am Coll Surg. 2003;197(3):392-402. 77. Geller DA, Tsung A, Marsh JW, Dvorchik I, Gamblin TC, Carr BI. Outcome of 1000 liver cancer patients evaluated at the UPMC Liver Cancer Center. J Gastrointest Surg. 2006;10(1):63-68. 78. International Agency for Research on Cancer. GLOBOCAN 2008. Available at: http://globocan.iarc.fr/. Accessed July 26, 2018. 79. Liaw YF, Tai DI, Chu CM, et al. Early detection of hepatocel-lular carcinoma in patients with chronic type B hepatitis. A prospective study. Gastroenterology. 1986;90(2):263-267. 80. Schwartz M, Roayaie S, Uva P. Treatment of HCC in patients awaiting liver transplantation. Am J Transplant. 2007;7(8):1875-1881.Brunicardi_Ch31_p1345-p1392.indd 138820/02/19 2:37 PM 1389LIVERCHAPTER 31 81. Zarrinpar A, Kaldas F, Busuttil RW. Liver transplantation for hepatocellular carcinoma: an update. Hepatobiliary Pancreat Dis Int. 2011;10(3):234-242. 82. Bruix J, Sherman M, American Association for the Study of Liver Disease. Management of hepatocellular carcinoma: an update. Hepatology. 2011;53(3):1020-1022. BCLC algo-rithm for management of hepatocellular carcinoma (HCC). 83. DeOliveira ML, Kambakamba P, Clavien PA. Advances in liver surgery for cholangiocarcinoma. Curr Opin Gastroen-terol. 2013;29(3):293-298. 84. Jarnagin WR, Fong Y, DeMatteo RP, et al. Staging, resect-ability, and outcome in 225 patients with hilar cholangiocarci-noma. Ann Surg. 2001;234(4):507-519. 85. Hidalgo E, Asthana S, Nishio H, et al. Surgery for hilar chol-angiocarcinoma: the Leeds experience. Eur J Surg Oncol. 2008;34(7):787-794. 86. Nagino M, Kamiya J, Nishio H, Ebata T, Arai T, Nimura Y. Two hundred forty consecutive portal vein embolizations before extended hepatectomy for biliary cancer: surgical outcome and long-term follow-up. Ann Surg. 2006;243(3): 364-372. 87. Gores GJ, Nagorney DM, Rosen CB. Cholangiocarci-noma: is transplantation an option? For whom? J Hepatol. 2007;47(4):455-459. 88. Marsh JW, Geller DA, Finkelstein SD, Donaldson JB, Dvor-chik I. Role of liver transplantation for hepatobiliary malignant disorders. Lancet Oncol. 2004;5(8):480-488. 89. Rea DJ, Heimbach JK, Rosen CB, et al. Liver transplanta-tion with neoadjuvant chemoradiation is more effective than resection for hilar cholangiocarcinoma. Ann Surg. 2005;242(3):451-461. 90. Hassoun Z, Gores GJ, Rosen CB. Preliminary experience with liver transplantation in selected patients with unre-sectable hilar cholangiocarcinoma. Surg Oncol Clin N Am. 2002;11(4):909-921. 91. Darwish Murad S, Kim WR, Harnois DM, et al. Efficacy of neoadjuvant chemoradiation, followed by liver transplanta-tion, for perihilar cholangiocarcinoma at 12 US centers. Gas-troenterology. 2012;143(1):88-98. 92. Weber SM, Jarnagin WR, Klimstra D, DeMatteo RP, Fong Y, Blumgart LH. Intrahepatic cholangiocarcinoma: resect-ability, recurrence pattern, and outcomes. J Am Coll Surg. 2001;193(4):384-391. 93. Jan YY, Yeh CN, Yeh TS, Chen TC. Prognostic analysis of surgical treatment of peripheral cholangiocarcinoma: two decades of experience at Chang Gung Memorial Hospital. World J Gastroenterol. 2005;11(12):1779-1784. 94. Hong JC, Jones CM, Duffy JP, et al. Comparative analysis of resection and liver transplantation for intrahepatic and hilar cholangiocarcinoma: a 24-year experience in a single center. Arch Surg. 2011;146(6):683-689. 95. Smith GC, Parks RW, Madhavan KK, Garden OJ. A 10-year experience in the management of gallbladder cancer. HPB (Oxford). 2003;5(3):159-166. 96. Bartlett DL, Fong Y, Fortner JG, Brennan MF, Blumgart LH. Long-term results after resection for gallbladder can-cer. Implications for staging and management. Ann Surg. 1996;224(5):639-646. 97. Shoup M, Fong Y. Surgical indications and extent of resection in gallbladder cancer. Surg Oncol Clin N Am. 2002;11(4):985-994. 98. Pawlik TM, Gleisner AL, Vigano L, et al. Incidence of finding residual disease for incidental gallbladder carci-noma: implications for re-resection. J Gastrointest Surg. 2007;11(11):1478-1486. 99. Chan SY, Poon RT, Lo CM, Ng KK, Fan ST. Management of carcinoma of the gallbladder: a single-institution experience in 16 years. J Surg Oncol. 2008;97(2):156-164. 100. Goetze TO, Paolucci V. Benefits of reoperation of T2 and more advanced incidental gallbladder carcinoma: analysis of the German registry. Ann Surg. 2008;247(1):104-108. 101. Fong Y, Fortner J, Sun RL, Brennan MF, Blumgart LH. Clini-cal score for predicting recurrence after hepatic resection for metastatic colorectal cancer: analysis of 1001 consecutive cases. Ann Surg. 1999;230(3):309-318. 102. Poston G, Adam R, Vauthey JN. Downstaging or downsizing: time for a new staging system in advanced colorectal cancer? J Clin Oncol. 2006;24(18):2702-2706. 103. Minagawa M, Makuuchi M, Torzilli G, et al. Extension of the frontiers of surgical indications in the treatment of liver metastases from colorectal cancer: long-term results. Ann Surg. 2000;231(4):487-499. 104. Kornprat P, Jarnagin WR, Gonen M, et al. Outcome after hepatectomy for multiple (four or more) colorectal metas-tases in the era of effective chemotherapy. Ann Surg Oncol. 2007;14(3):1151-1160. 105. Charnsangavej C, Clary B, Fong Y, Grothey A, Pawlik TM, Choti MA. Selection of patients for resection of hepatic colorectal metastases: expert consensus statement. Ann Surg Oncol. 2006;13(10):1261-1268. 106. Abdalla EK, Adam R, Bilchik AJ, Jaeck D, Vauthey JN, Mahvi D. Improving resectability of hepatic colorectal metastases: expert consensus statement. Ann Surg Oncol. 2006;13(10):1271-1280. 107. Pawlik TM, Schulick RD, Choti MA. Expanding criteria for resectability of colorectal liver metastases. Oncologist. 2008;13(1):51-64. Summary of the paradigm shift for resection of colorectal cancer liver metastases based on adequate liver remnant rather than actual number of liver tumors. 108. Clavien PA, Petrowsky H, DeOliveira ML, Graf R. Strategies for safer liver surgery and partial liver transplantation. N Engl J Med. 2007;356(15):1545-1559. 109. Adam R, Wicherts DA, de Haas RJ, et al. Patients with initially unresectable colorectal liver metastases: is there a possibility of cure? J Clin Oncol. 2009;27(11):1829-1835. 110. Que FG, Nagorney DM, Batts KP, Linz LJ, Kvols LK. Hepatic resection for metastatic neuroendocrine carcinomas. Am J Surg. 1995;169(1):36-42. 111. Touzios JG, Kiely JM, Pitt SC, et al. Neuroendocrine hepatic metastases: does aggressive management improve survival? Ann Surg. 2005;241(5):776-783. 112. Sarmiento JM, Heywood G, Rubin J, Ilstrup DM, Nagorney DM, Que FG. Surgical treatment of neuroendocrine metasta-ses to the liver: a plea for resection to increase survival. J Am Coll Surg. 2003;197(1):29-37. 113. Kianmanesh R, Sauvanet A, Hentic O, et al. Two-step surgery for synchronous bilobar liver metastases from digestive endo-crine tumors: a safe approach for radical resection. Ann Surg. 2008;247(4):659-665. 114. Mazzaferro V, Pulvirenti A, Coppa J. Neuroendocrine tumors metastatic to the liver: how to select patients for liver trans-plantation? J Hepatol. 2007;47(4):460-466. 115. Adam R, Aloia T, Krissat J, et al. Is liver resection justified for patients with hepatic metastases from breast cancer? Ann Surg. 2006;244(6):897-907. 116. Abbott DE, Brouquet A, Mittendorf EA, et al. Resection of liver metastases from breast cancer: estrogen receptor status and response to chemotherapy before metastasectomy define outcome. Surgery. 2012;151(5):710-716. 117. Jarnagin W, Chapman WC, Curley S, et al. Surgical treatment of hepatocellular carcinoma: expert consensus statement. HPB (Oxford). 2010;12(5):302-310. 118. Belghiti J, Hiramatsu K, Benoist S, Massault P, Sauvanet A, Farges O. Seven hundred forty-seven hepatectomies in the 1990s: an update to evaluate the actual risk of liver resection. J Am Coll Surg. 2000;191(1):38-46.Brunicardi_Ch31_p1345-p1392.indd 138920/02/19 2:37 PM 1390SPECIFIC CONSIDERATIONSPART II 119. Jarnagin WR, Gonen M, Fong Y, et al. Improvement in perioperative outcome after hepatic resection: analysis of 1,803 consecutive cases over the past decade. Ann Surg. 2002;236(4):397-406. 120. Imamura H, Seyama Y, Kokudo N, et al. One thousand fifty-six hepatectomies without mortality in 8 years. Arch Surg. 2003;138(11):1198-1206. 121. Mullen JT, Ribero D, Reddy SK, et al. Hepatic insufficiency and mortality in 1,059 noncirrhotic patients undergoing major hepatectomy. J Am Coll Surg. 2007;204(5):854-862. 122. Hamady ZZ, Cameron IC, Wyatt J, Prasad RK, Toogood GJ, Lodge JP. Resection margin in patients undergoing hepatec-tomy for colorectal liver metastasis: a critical appraisal of the 1 cm rule. Eur J Surg Oncol. 2006;32(5):557-563. 123. Pawlik TM, Vauthey JN. Surgical margins during hepatic sur-gery for colorectal liver metastases: complete resection not mil-limeters defines outcome. Ann Surg Oncol. 2008;15(3):677-679. 124. Andreou A, Aloia TA, Brouquet A, et al. Margin status remains an important determinant of survival after surgical resection of colorectal liver metastases in the era of modern chemotherapy. Ann Surg. 2013;257(6):1079-1088. 125. Hemming AW, Mekeel KL, Zendejas I, Kim RD, Sicklick JK, Reed AI. Resection of the liver and inferior vena cava for hepatic malignancy. J Am Coll Surg. 2013;217:115-124. 126. Schwartz M, Roayaie S, Konstadoulakis M. Strategies for the management of hepatocellular carcinoma. Nat Clin Pract Oncol. 2007;4(7):424-432. Excellent summary of the current strategies for multi-disciplinary management of hepa-tocellular carcinoma (HCC). 127. Duffy JP, Vardanian A, Benjamin E, et al. Liver transplanta-tion criteria for hepatocellular carcinoma should be expanded: a 22-year experience with 467 patients at UCLA. Ann Surg. 2007;246(3):502-509. 128. Organ Procurement and Transplantation Network. Available at: http://www.optn.org. Accessed May 6, 2017. 129. Mazzaferro V, Regalia E, Doci R, et al. Liver transplanta-tion for the treatment of small hepatocellular carcinomas in patients with cirrhosis. N Engl J Med. 1996;334(11): 693-699. Landmark article showing excellent outcomes of liver transplantation for small HCC that established the size and tumor number criteria that was adopted by the MELD system and is now widely accepted. 130. Wiesner RH, Freeman RB, Mulligan DC. Liver transplantation for hepatocellular cancer: the impact of the MELD allocation policy. Gastroenterology. 2004;127(5 suppl 1):S261-S267. 131. de Villa V, Lo CM. Liver transplantation for hepatocellular carcinoma in Asia. Oncologist. 2007;12(11):1321-1331. 132. McGahan JP, Browning PD, Brock JM, Tesluk H. Hepatic ablation using radiofrequency electrocautery. Invest Radiol. 1990;25(3):267-270. 133. Rossi S, Fornari F, Pathies C, Buscarini L. Thermal lesions induced by 480 KHz localized current field in guinea pig and pig liver. Tumori. 1990;76(1):54-57. 134. Curley SA, Izzo F, Delrio P, et al. Radiofrequency ablation of unresectable primary and metastatic hepatic malignancies: results in 123 patients. Ann Surg. 1999;230(1):1-8. 135. Bilchik AJ, Wood TF, Allegra D, et al. Cryosurgical abla-tion and radiofrequency ablation for unresectable hepatic malignant neoplasms: a proposed algorithm. Arch Surg. 2000;135(6):657-662. 136. Poon RT, Ng KK, Lam CM, et al. Learning curve for radio-frequency ablation of liver tumors: prospective analysis of initial 100 patients in a tertiary institution. Ann Surg. 2004;239(4):441-449. 137. Abdalla EK, Vauthey JN, Ellis LM, et al. Recurrence and out-comes following hepatic resection, radiofrequency ablation, and combined resection/ablation for colorectal liver metasta-ses. Ann Surg. 2004;239(6):818-825. 138. Sutherland LM, Williams JA, Padbury RT, Gotley DC, Stokes B, Maddern GJ. Radiofrequency ablation of liver tumors: a systematic review. Arch Surg. 2006;141(2):181-190. 139. Berber E, Siperstein AE. Perioperative outcome after laparo-scopic radiofrequency ablation of liver tumors: an analysis of 521 cases. Surg Endosc. 2007;21(4):613-618. 140. Martin AP, Goldstein RM, Dempster J, et al. Radiofrequency thermal ablation of hepatocellular carcinoma before liver transplantation—a clinical and histological examination. Clin Transplant. 2006;20(6):695-705. 141. Cheng BQ, Jia CQ, Liu CT, et al. Chemoembolization com-bined with radiofrequency ablation for patients with hepato-cellular carcinoma larger than 3 cm: a randomized controlled trial. JAMA. 2008;299(14):1669-1677. 142. Sucandy I, Cheek S, Golas BJ, Tsung A, Geller DA, Marsh JW. Longterm survival outcomes of patients undergoing treatment with radiofrequency ablation for hepatocellular carcinoma and metastatic colorectal cancer liver tumors. HPB (Oxford). 2016;18:756-763. 143. Iannitti DA, Martin RC, Simon CJ, et al. Hepatic tumor abla-tion with clustered microwave antennae: the US Phase II trial. HPB (Oxford). 2007;9(2):120-124. 144. Lo CM, Ngan H, Tso WK, et al. Randomized controlled trial of transarterial lipiodol chemoembolization for unresectable hepatocellular carcinoma. Hepatology. 2002;35(5):1164-1171. 145. Llovet JM, Real MI, Montana X, et al. Arterial embolisation or chemoembolisation versus symptomatic treatment in patients with unresectable hepatocellular carcinoma: a randomised controlled trial. Lancet. 2002;359(9319):1734-1739. 146. Takayasu K, Arii S, Ikai I, et al. Prospective cohort study of transarterial chemoembolization for unresectable hepa-tocellular carcinoma in 8510 patients. Gastroenterology. 2006;131(2):461-469. 147. Sotiropoulos GC, Druhe N, Sgourakis G, et al. Liver transplan-tation, liver resection, and transarterial chemoembolization for hepatocellular carcinoma in cirrhosis: which is the best onco-logical approach? Dig Dis Sci. 2009;54(10):2264-2273. 148. Lewandowski RJ, Geschwind JF, Liapi E, Salem R. Transcath-eter intraarterial therapies: rationale and overview. Radiology. 2011;259(3):641-657. 149. Kemeny N, Huang Y, Cohen AM, et al. Hepatic arterial infusion of chemotherapy after resection of hepatic metastases from colorectal cancer. N Engl J Med. 1999;341(27):2039-2048. 150. Ibrahim SM, Lewandowski RJ, Sato KT, et al. Radioem-bolization for the treatment of unresectable hepatocellu-lar carcinoma: a clinical review. World J Gastroenterol. 2008;14(11):1664-1669. 151. Gulec SA, Fong Y. Yttrium 90 microsphere selective inter-nal radiation treatment of hepatic colorectal metastases. Arch Surg. 2007;142(7):675-682. 152. Sato KT, Lewandowski RJ, Mulcahy MF, et al. Unresectable chemorefractory liver metastases: radioembolization with 90Y microspheres—safety, efficacy, and survival. Radiology. 2008;247(2):507-515. 153. Tse RV, Hawkins M, Lockwood G, et al. Phase I study of indi-vidualized stereotactic body radiotherapy for hepatocellular carcinoma and intrahepatic cholangiocarcinoma. J Clin Oncol. 2008;26(4):657-664. 154. Mendez Romero A, Wunderink W, Hussain SM, et al. Ste-reotactic body radiation therapy for primary and metastatic liver tumors: a single institution phase I-II study. Acta Oncol. 2006;45(7):831-837. 155. Chapman WC, Majella Doyle MB, Stuart JE, et al. Outcomes of neoadjuvant transarterial chemoembolization to downstage hepatocellular carcinoma before liver transplantation. Ann Surg. 2008;248(4):617-625. 156. Yao FY, Kerlan RK, Jr, Hirose R, et al. Excellent outcome following down-staging of hepatocellular carcinoma prior to Brunicardi_Ch31_p1345-p1392.indd 139020/02/19 2:37 PM 1391LIVERCHAPTER 31liver transplantation: an intention-to-treat analysis. Hepatology. 2008;48(3):819-827. 157. Llovet JM, Ricci S, Mazzaferro V, et al. Sorafenib in advanced hepatocellular carcinoma. N Engl J Med. 2008;359(4):378-390. Randomized clinical trial that showed benefits of Sorafenib compared to placebo in advanced HCC and led to FDA drug approval. 158. American Hepato-Pancreato-Biliary Association. IHPBA Brisbane liver terminology. Available at: http://www.ahpba.org/resources/liver.asp. Accessed June 4, 2013. 159. Pang YY. The Brisbane 2000 terminology of liver anatomy and resections. HPB (Oxford). 2002;4(2):99-100; author reply 99. 160. Strasberg SM. Nomenclature of hepatic anatomy and resec-tions: a review of the Brisbane 2000 system. J Hepatobiliary Pancreat Surg. 2005;12(5):351-355. 161. Weber JC, Navarra G, Jiao LR, Nicholls JP, Jensen SL, Habib NA. New technique for liver resection using heat coagulative necrosis. Ann Surg. 2002;236(5):560-563. 162. Geller DA, Tsung A, Maheshwari V, Rutstein LA, Fung JJ, Marsh JW. Hepatic resection in 170 patients using saline-cooled radiofrequency coagulation. HPB (Oxford). 2005;7(3): 208-213. 163. Saiura A, Yamamoto J, Koga R, et al. Usefulness of LigaSure for liver resection: analysis by randomized clinical trial. Am J Surg. 2006;192(1):41-45. 164. McEntee GP, Nagorney DM. Use of vascular staplers in major hepatic resections. Br J Surg. 1991;78(1):40-41. 165. Jurim O, Colonna JO II, Colquhoun SD, Shaked A, Busuttil RW. A stapling technique for hepatic resection. J Am Coll Surg. 1994;178(5):510-511. 166. Kaneko H, Otsuka Y, Takagi S, Tsuchiya M, Tamura A, Shiba T. Hepatic resection using stapling devices. Am J Surg. 2004;187(2):280-284. 167. Schemmer P, Friess H, Hinz U, et al. Stapler hepatectomy is a safe dissection technique: analysis of 300 patients. World J Surg. 2006;30(3):419-430. 168. Balaa FK, Gamblin TC, Tsung A, Marsh JW, Geller DA. Right hepatic lobectomy using the staple technique in 101 patients. J Gastrointest Surg. 2008;12(2):338-343. 169. Blumgart L. Liver resection for benign disease and for liver and biliary disease. In: Blumgart L, ed. Surgery of the Liver and Biliary Tract. 3rd ed. London: WB Saunders; 2000:1639. 170. Launois B, Jamieson GG. The importance of Glisson’s capsule and its sheaths in the intrahepatic approach to resection of the liver. Surg Gynecol Obstet. 1992;174(1):7-10. 171. Azoulay D, Marin-Hargreaves G, Castaing D, Adam R, Savier E, Bismuth H. The anterior approach: the right way for right massive hepatectomy. J Am Coll Surg. 2001;192(3):412-417. 172. Liu CL, Fan ST, Cheung ST, Lo CM, Ng IO, Wong J. Anterior approach versus conventional approach right hepatic resection for large hepatocellular carcinoma: a prospective randomized controlled study. Ann Surg. 2006;244(2):194-203. 173. Makuuchi M, Mori T, Gunven P, Yamazaki S, Hasegawa H. Safety of hemihepatic vascular occlusion during resection of the liver. Surg Gynecol Obstet. 1987;164(2):155-158. 174. Man K, Fan ST, Ng IO, Lo CM, Liu CL, Wong J. Prospective evaluation of Pringle maneuver in hepatectomy for liver tumors by a randomized study. Ann Surg. 1997;226(6):704-711. 175. Belghiti J, Noun R, Malafosse R, et al. Continuous versus intermittent portal triad clamping for liver resection: a con-trolled study. Ann Surg. 1999;229(3):369-375. 176. Figueras J, Llado L, Ruiz D, et al. Complete versus selective portal triad clamping for minor liver resections: a prospective randomized trial. Ann Surg. 2005;241(4):582-590. 177. Clavien PA, Yadav S, Sindram D, Bentley RC. Protec-tive effects of ischemic preconditioning for liver resection performed under inflow occlusion in humans. Ann Surg. 2000;232(2):155-162. 178. Clavien PA, Selzner M, Rudiger HA, et al. A prospective ran-domized study in 100 consecutive patients undergoing major liver resection with versus without ischemic preconditioning. Ann Surg. 2003;238(6):843-850. 179. Kinoshita H, Sakai K, Hirohashi K, Igawa S, Yamasaki O, Kubo S. Preoperative portal vein embolization for hepatocel-lular carcinoma. World J Surg. 1986;10(5):803-808. 180. Makuuchi M, Thai BL, Takayasu K, et al. Preoperative por-tal embolization to increase safety of major hepatectomy for hilar bile duct carcinoma: a preliminary report. Surgery. 1990;107(5):521-527. 181. Abdalla EK, Hicks ME, Vauthey JN. Portal vein emboliza-tion: rationale, technique and future prospects. Br J Surg. 2001;88(2):165-175. 182. Chun YS, Ribero D, Abdalla EK, et al. Comparison of two methods of future liver remnant volume measurement. J Gas-trointest Surg. 2008;12(1):123-128. 183. Abdalla EK, Barnett CC, Doherty D, Curley SA, Vauthey JN. Extended hepatectomy in patients with hepatobiliary malig-nancies with and without preoperative portal vein emboliza-tion. Arch Surg. 2002;137(6):675-680. 184. Vauthey JN, Chaoui A, Do KA, et al. Standardized mea-surement of the future liver remnant prior to extended liver resection: methodology and clinical associations. Surgery. 2000;127(5):512-519. 185. Farges O, Belghiti J, Kianmanesh R, et al. Portal vein emboli-zation before right hepatectomy: prospective clinical trial. Ann Surg. 2003;237(2):208-217. 186. Hemming AW, Reed AI, Howard RJ, et al. Preoperative por-tal vein embolization for extended hepatectomy. Ann Surg. 2003;237(5):686-691. 187. Azoulay D, Castaing D, Smail A, et al. Resection of nonre-sectable liver metastases from colorectal cancer after percu-taneous portal vein embolization. Ann Surg. 2000;231(4): 480-486. 188. Kubota K, Makuuchi M, Kusaka K, et al. Measurement of liver volume and hepatic functional reserve as a guide to decision-making in resectional surgery for hepatic tumors. Hepatology. 1997;26(5):1176-1181. 189. Ribero D, Abdalla EK, Madoff DC, Donadon M, Loyer EM, Vauthey JN. Portal vein embolization before major hepatec-tomy and its effects on regeneration, resectability and out-come. Br J Surg. 2007;94(11):1386-1394. 190. Covey AM, Brown KT, Jarnagin WR, et al. Combined portal vein embolization and neoadjuvant chemotherapy as a treat-ment strategy for resectable hepatic colorectal metastases. Ann Surg. 2008;247(3):451-455. 191. Hwang S, Lee SG, Ko GY, et al. Sequential preoperative ipsi-lateral hepatic vein embolization after portal vein embolization to induce further liver regeneration in patients with hepatobili-ary malignancy. Ann Surg. 2009;249(4):608-616. 192. Jaeck D, Oussoultzoglou E, Rosso E, Greget M, Weber JC, Bachellier P. A two-stage hepatectomy procedure combined with portal vein embolization to achieve curative resection for initially unresectable multiple and bilobar colorectal liver metastases. Ann Surg. 2004;240(6):1037-1049. 193. Adam R, Miller R, Pitombo M, et al. Two-stage hepatec-tomy approach for initially unresectable colorectal hepatic metastases. Surg Oncol Clin North Am. 2007;16(3):525-536. Very useful summary of the two-stage hepatectomy approach for resection of hepatic colorectal cancer metastases. 194. Schnitzbauer AA, Lang SA, Goessmann H, et al. Right portal vein ligation combined with in situ splitting induces rapid left lateral liver lobe hypertrophy enabling 2-staged extended right hepatic resection in small-for-size settings. Ann Surg. 2012;255(3):405-414. Initial paper describing the ALPPS technique to induce massive future liver remnant hypertrophy and outcomes.Brunicardi_Ch31_p1345-p1392.indd 139120/02/19 2:37 PM 1392SPECIFIC CONSIDERATIONSPART II 195. Adam R, Bismuth H, Castaing D, et al. Repeat hepatectomy for colorectal liver metastases. Ann Surg. 1997;225(1):51-60. 196. Petrowsky H, Gonen M, Jarnagin W, et al. Second liver resec-tions are safe and effective treatment for recurrent hepatic metastases from colorectal cancer: a bi-institutional analysis. Ann Surg. 2002;235(6):863-871. 197. Sa Cunha A, Laurent C, Rault A, Couderc P, Rullier E, Saric J. A second liver resection due to recurrent colorectal liver metastases. Arch Surg. 2007;142(12):1144-1149. 198. Antoniou A, Lovegrove RE, Tilney HS, et al. Meta-analysis of clinical outcome after first and second liver resection for colorectal metastases. Surgery. 2007;141(1):9-18. 199. Nakajima Y, Ko S, Kanamura T, et al. Repeat liver resec-tion for hepatocellular carcinoma. J Am Coll Surg. 2001;192(3):339-344. 200. Itamoto T, Nakahara H, Amano H, et al. Repeat hepatec-tomy for recurrent hepatocellular carcinoma. Surgery. 2007;141(5):589-597. 201. Minagawa M, Makuuchi M, Takayama T, Kokudo N. Selec-tion criteria for repeat hepatectomy in patients with recurrent hepatocellular carcinoma. Ann Surg. 2003;238(5):703-710. 202. Cherqui D, Husson E, Hammoud R, et al. Laparoscopic liver resections: a feasibility study in 30 patients. Ann Surg. 2000;232(6):753-762. 203. Reddy SK, Tsung A, Geller DA. Laparoscopic liver resection. World J Surg. 2011;35(7):1478-1486. 204. Nguyen KT, Gamblin TC, Geller DA. World review of laparoscopic liver resection – 2,804 patients. Ann Surg, 2009;250:831-841. Comprehensive review of the indications, techniques, benefits, and outcomes of laparoscopic liver resection. 205. Koffron AJ, Auffenberg G, Kung R, Abecassis M. Evaluation of 300 minimally invasive liver resections at a single institu-tion: less is more. Ann Surg. 2007;246(3):385-392. 206. Buell JF, Cherqui D, Geller DA, et al. The international posi-tion on laparoscopic liver surgery: the Louisville statement, 2008. Ann Surg. 2009;250:825-830. 207. Wakabayashi G, Cherqui D, Geller DA, et al. Recommen-dations for laparoscopic liver resection: a report from the second international consensus conference held in Morioka. Ann Surg. 2015;261:619-629. Up-to-date recommendations from the second international consensus conference consist-ing of a 9-member jury and an expert panel that addressed 17 questions for laparoscopic liver resection. 208. Ciria R, Cherqui D, Geller DA, Briceno J, Wakabayashi G. Comparative short term benefits of laparoscopic liver resec-tion: 9,000 cases and climbing. Ann Surg. 2016;263:761-777. 209. Cardinal JS, Reddy SK, Tsung A, Marsh JW, Geller DA. Lap-aroscopic major hepatectomy: pure laparoscopic approach versus hand-assisted technique. J Hepatobiliary Pancreat Sci. 2013;20:114-119. 210. Cheek SM, Sucandy I, Geller DA. Hand-assisted laparoscopic left hepatectomy: how I do it. J Hepatobiliary Pancreat Sci. 2016;23(12):E30-E32. 211. Tsung A, Geller DA, Sukato DC, et al. Robotic versus lapa-roscopic hepatectomy: a matched comparison. Ann Surg. 2014;259:549-555. 212. Nguyen KT, Marsh JW, Tsung A, Steel JL, Gamblin TC, Geller DA. Comparative benefits of laparoscopic versus open hepatic resection: a critical appraisal. Arch Surg. 2011;146:348-356. 213. Takahara T, Wakabayashi G, Beppu T, et al. Long-term and perioperative outcomes of laparoscopic versus open liver resection for hepatocellular carcinoma with propensity score matching: a multi-institutional Japanese study. J Hepatobiliary Pancreat Sci. 2015;22:721-727. 214. Zhou YM, Shao WY, Zhao YF, Xu DH, Li B. Meta-analysis of laparoscopic versus open resection for hepatocellular carci-noma. Dig Dis Sci. 2011;56(7):1937-1943. 215. Schiffman SC, Kim KH, Tsung A, Marsh JW, Geller DA. Laparoscopic versus open liver resection for metastatic colorectal cancer: a meta-analysis of 610 patients. Surgery. 2015;157:211-222. 216. Vigano L, Laurent A, Tayar C, et al. The learning curve in laparoscopic liver resection: improved feasibility and repro-ducibility. Ann Surg 2009;250:772-782. 217. Brown KM, Geller DA. What is the learning curve for laparoscopic major hepatectomy? J Gastrointest Surg. 2016;20:1065-1071. 218. Dagher I, O’Rourke N, Geller DA, et al. Laparoscopic major hepatectomy: an evolution in standard of care. Ann Surg. 2009;250:856-860. 219. Lin NC, Nitta H, Wakabayashi G. Laparoscopic major hepa-tectomy: a systematic literature review and comparison of 3 techniques. Ann Surg. 2013;257:205-213. 220. Vanounou T, Steel JL, Nguyen KT, Tsung A, Marsh JW, Geller DA, Gamblin TC. Comparing the clinical and economic impact of laparoscopic versus open liver resection. Ann Surg Oncol. 2010;17:998-1009. 221. Cleary SP, Han HS, Yamamoto M, Wakabayashi G, Asbun HJ. The comparative costs of laparoscopic and open liver resec-tion: a report for the 2nd International Consensus Con-ference on Laparoscopic Liver Resection. Surg Endosc. 2016;30(11):4691-4696. 222. Cherqui D, Soubrane O, Husson E, et al. Laparoscopic living donor hepatectomy for liver transplantation in children. Lancet 2002;359:392-396. 223. Koffron AJ, Kung R, Baker T, Fryer J, Clark L, Abecassis M. Laparoscopic-assisted right lobe donor hepatectomy. Am J Transplant. 2006;6:2522-2525. 224. Soubrane O, Perdigao Cotta F, Scatton O. Pure laparo-scopic right hepatectomy in a living donor. Am J Transplant. 2013;13:2467-2471.Brunicardi_Ch31_p1345-p1392.indd 139220/02/19 2:37 PM
Gallbladder and the Extrahepatic Biliary SystemKelly R. Haisley and John G. Hunter 32chapterANATOMYGallbladderThe gallbladder is a pear-shaped sac that measures around 7 to 10 cm long, with an average capacity of 30 to 50 mL. When obstructed, the gallbladder can distend markedly and contain up to 300 mL of fluid. The gallbladder is located in an anatomic fossa on the inferior surface of the liver. Cantle’s line, a vertical plane running from the gallbladder fossa anteriorly to the infe-rior vena cava (IVC) posteriorly divides the liver into right and left lobes. The gallbladder itself is divided into four anatomic areas: the fundus, the body, the infundibulum, and the neck. The fundus is the rounded, blind end that normally extends 1 to 2 cm beyond the liver’s margin and contains most of the smooth muscle of the organ. The body functions as the main storage area and contains most of the elastic tissue allowing for disten-tion. As the body tapers towards the neck of the gallbladder, a mucosal outpouching is present at the junction of the neck and the cystic duct, known as the infundibulum or Hartmann’s pouch. Beyond this, the neck of the gallbladder lies in the deep-est part of the gallbladder fossa and can extend slightly into the free portion of the hepatoduodenal ligament, where it connects with the cystic duct (Fig. 32-1).1The same peritoneal lining that covers the liver extends to cover the fundus and the inferior surface of the gallblad-der. Occasionally, part or all of the gallbladder is embedded deep inside the liver parenchyma (an intrahepatic gallbladder). Rarely, the gallbladder has a complete peritoneal covering on all sides and is suspended in a mesentery off the inferior surface of the liver.The mucosal lining of the gallbladder is formed by a single, highly redundant, simple columnar epithelium that contains cholesterol and fat globules. The mucus secreted into the gall-bladder originates in tubuloalveolar glands that are found in the mucosal lining of the infundibulum and neck of the gallbladder, but are absent from the body and fundus. The epithelial lining of the gallbladder is supported by a lamina propria. The gallblad-der differs histologically from the rest of the gastrointestinal (GI) tract in that it lacks a muscularis mucosa and submucosa. The muscular layer has circular, longitudinal, and oblique fibers, but without well-defined layers. The adventitia contains connective tissue, nerves, vessels, lymphatics, and adipocytes. The gallbladder is covered by serosa except where the gallblad-der is embedded in the liver.The cystic artery that supplies the gallbladder is usually a branch of the right hepatic artery (>90% of the time). The course of the cystic artery may vary, but it nearly always is found within the hepatocystic triangle (triangle of Calot), the area bound by the cystic duct, common hepatic duct, and the inferior edge of the liver. When the cystic artery reaches the neck of the gall-bladder, it divides into anterior and posterior divisions. Venous return is carried either through small veins that enter directly into the liver or, rarely, to a large cystic vein that carries blood back to the portal vein. Gallbladder lymphatics drain into nodes Anatomy 1393Gallbladder / 1393Bile Ducts / 1394Anatomic Variants / 1396Physiology 1396Bile Formation and Composition / 1396Gallbladder Function / 1397Sphincter of Oddi / 1397Diagnostic Studies 1398Blood Tests / 1398Transabdominal Ultrasonography / 1398Computed Tomography / 1398Hepatobiliary Scintigraphy / 1399Magnetic Resonance Imaging / 1399Endoscopic Retrograde Cholangiopancreatography / 1400Endoscopic Choledochoscopy / 1400Endoscopic Ultrasound / 1401Percutaneous Transhepatic Cholangiography / 1401Gallstone Disease 1401Prevalence and Incidence / 1401Natural History / 1401Gallstone Formation / 1402Symptomatic Gallstones / 1404Cholangiohepatitis / 1410Procedural Interventions for Gallstone Disease 1410Percutaneous Transhepatic Cholecystostomy Tubes / 1410Endoscopic Interventions / 1410Cholecystectomy / 1410Common Bile Duct Exploration / 1413Common Bile Duct Drainage Procedures / 1414Other Benign Diseases and Lesions 1414Biliary Dyskinesia and Sphincter of Oddi Dysfunction / 1414Acalculous Cholecystitis / 1415Choledochal (Biliary) Cysts / 1417Primary Sclerosing Cholangitis / 1417Bile Duct Strictures / 1418Injury to the Biliary Tract 1419Gallbladder / 1419Extrahepatic Bile Ducts / 1419Tumors 1421Carcinoma of the Gallbladder / 1421Cholangiocarcinoma / 1423Brunicardi_Ch32_p1393-p1428.indd 139311/02/19 2:42 PM 1394at the neck of the gallbladder. Frequently, a visible lymph node (Lund’s or Mascagni’s node, often referred to as Calot’s node) overlies the insertion of the cystic artery into the gallbladder wall. The gallbladder receives parasympathetic, sympathetic and sensory innervation through nerve fibers running largely through the gastro hepatic ligament. Parasympathetic (cholinergic) fibers arise from the hepatic branches of the vagus nerve to stimulate activity in the gallbladder, bile ducts, and liver. These vagal branches also have peptide-containing nerves contain-ing agents such as substance P, somatostatin, enkephalins, and vasoactive intestinal polypeptide (VIP).2 The sympathetic and sensory braches of the gallbladder, liver, and bile ducts pass through the celiac plexus and control gallbladder relaxation and mediate the pain of biliary colic.Bile DuctsThe extrahepatic biliary tree consists of the right and left hepatic ducts, the common hepatic duct, the cystic duct, and the com-mon bile duct. Exiting the liver, the left hepatic duct is longer than the right and has a greater propensity for dilatation as a consequence of distal obstruction. The two ducts join close to their emergence from the liver to form the common hepatic duct. The common hepatic duct typically extends 1 to 4 cm, has a diameter of approximately 4 mm, and lies anterior to the portal vein and to the right of the hepatic artery.The cystic duct exits the gallbladder and joins the common hepatic duct at an acute angle to form the common bile duct. The segment of the cystic duct immediately adjacent to the gall-bladder neck bears a variable number of mucosal folds called the spiral valves of Heister. While they do not have any valvular function, they can make cannulation of the cystic duct difficult. The length and course of the cystic duct can be quite variable. It may be short or absent and have a high union with the hepatic duct, or it may be long and running parallel to, behind, or spiral-ing around to the common hepatic duct before joining it, some-times as far distally as at the duodenum. Variations of the cystic duct and its point of union with the common hepatic duct are surgically important and misidentification can lead to bile duct injuries (Fig. 32-2).The union of the cystic duct and the common hepatic duct marks the start of the common bile duct. This segment is typi-cally about 7 to 11 cm in length and 5 to 10 mm in diameter, ijoklmabdefgchqrptnsFigure 32-1. Anterior aspect of the biliary anatomy. a = right hepatic duct; b = left hepatic duct; c = common hepatic duct; d = portal vein; e = proper hepatic artery; f = gastroduodenal artery; g = right gastro-epiploic artery; h = common bile duct; i = fundus of the gallbladder; j = body of gallbladder; k = infundibulum of the gallbladder; l = cystic duct; m = cystic artery; n = superior pancreaticoduodenal artery; o = neck of the gallbladder; p = pancreatic duct; q = common hepatic artery; r = right gastric artery; s = ampulla of Vater; t = supraduodenal artery. Note the situation of the hepatic bile duct confluence anterior to the right branch of the portal vein, and the posterior course of the right hepatic artery behind the common hepatic duct.Key Points1 The physiology of the gallbladder, biliary tree, and sphincter of Oddi are regulated by a complex interplay of hormones and neuronal inputs designed to coordinate bile release with food consumption. Dysfunctions related to this activity are linked to the development of gallbladder pathologies as de-scribed in this chapter.2 In Western countries, the most common type of gallstones are cholesterol stones. The pathogenesis of these stones relates to supersaturation of bile with cholesterol and sub-sequent precipitation.3 Laparoscopic cholecystectomy has been demonstrated to be safe and effective, and it has become the treatment of choice for symptomatic gallstones. Knowledge of the various ana-tomic anomalies of the cystic duct and artery is critical in guiding the dissection of these structures and avoiding injury to the common bile duct during cholecystectomy.4 Common bile duct injuries, although uncommon, can be devastating to patients. Proper exposure of the hepatocystic (Calot’s) triangle to obtain the critical view of safety and careful identification of the anatomic structures are keys to avoiding these injuries. Once a bile duct injury is diag-nosed, the best outcomes are seen at large referral centers with experienced biliary surgeons, and patient transfer may be required.5 The main risk factor for gallbladder disease in Western coun-tries is cholelithiasis. The main complications include cho-lecystitis, choledocholithiasis, cholangitis, and biliary pancreatitis. Cholelithiasis is also the major risk factor for the development of gallbladder cancer.6 Carcinomas of the gallbladder or bile ducts generally have a poor prognosis because patients usually present late in the disease process and have poor response to chemotherapy and radiation. Surgery offers the best chance for survival and has good long-term outcomes in patients with early-stage disease.Brunicardi_Ch32_p1393-p1428.indd 139411/02/19 2:42 PM 1395GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32though its diameter can increase slightly with age and follow-ing cholecystectomy. The upper third (supraduodenal portion) passes downward in the free edge of the hepatoduodenal liga-ment, to the right of the hepatic artery and anterior to the portal vein. The middle third (retroduodenal portion) of the common bile duct curves behind the first portion of the duodenum and diverges laterally from the portal vein and the hepatic arteries. The lower third (pancreatic portion) can curve behind the head of the pancreas in a groove, or traverse through it to enter the wall of the second portion of the duodenum. The duct then runs obliquely downward within the wall of the duodenum for 1 to 2 cm before opening on a papilla of mucous membrane (ampulla of Vater), about 10 cm distal to the pylorus.The union of the common bile duct and the main pan-creatic duct follows one of three configurations. In about 70% of people, these ducts unite outside the duodenal wall and tra-verse the duodenal wall as a single duct. In about 20%, they join within the duodenal wall and have a short or no common duct, but open through the same opening into the duodenum. In about 10%, they exit via separate openings into the duodenum, termed pancreas divisum. The sphincter of Oddi, a thick coat of circular smooth muscle, surrounds the common bile duct at the ampulla of Vater (Fig. 32-3). It controls the flow of bile, and in some cases pancreatic juice, into the duodenum.The extrahepatic bile ducts are lined by a columnar mucosa with numerous mucous glands that are concentrated in the com-mon bile duct. A fibro areolar tissue containing scant smooth muscle cells surrounds the mucosa. A distinct muscle layer is not present in the human common bile duct. The arterial supply to the bile ducts is derived from the gastroduodenal and the right hepatic arteries, with major trunks running along the medial and lateral walls of the common duct (sometimes referred to as 3 o’clock and 9 o’clock). The nerve supply to the common bile duct is the same as for the gallbladder, with the density of nerve fibers and ganglia increasing near the sphincter of Oddi.1,2ABCDEFGHFigure 32-2. Variations of the cystic duct anatomy. A. Low junction between the cystic duct and common hepatic duct. B. Cystic duct adher-ent to the common hepatic duct. C. High junction between the cystic and the common hepatic duct. D. Cystic duct drains into right hepatic duct. E. Long cystic duct that joins common hepatic duct behind the duodenum. F. Absence of cystic duct. G. Cystic duct crosses posterior to common hepatic duct and joins it anteriorly. H. Cystic duct courses anterior to common hepatic duct and joins it posteriorly.Pancreatic ductCommonbile duct Sphincterof OddiDuodenumAmpulla ofVaterDuodenal wallFigure 32-3. The sphincter of Oddi.Brunicardi_Ch32_p1393-p1428.indd 139511/02/19 2:43 PM 1396SPECIFIC CONSIDERATIONSPART IIABCDEFFigure 32-5. Variations in the arterial supply to the gallbladder. A. Cystic artery from right hepatic artery, about 80% to 90%. B. Cystic artery off the right hepatic artery arising from the superior mesenteric artery (accessory or replaced), about 10%. C. Two cystic arteries, one from the right hepatic, the other from the common hepatic artery, rare. D. Two cystic arteries, one from the right hepatic, the other from the left hepatic artery, rare. E. The cystic artery branching from the right hepatic artery and running anterior to the common hepatic duct, rare. F. Two cystic arteries arising from the right hepatic artery, rare.Anatomic VariantsThe classic description of the extrahepatic biliary tree and its arteries applies only in about one-third of patients.3 The gall-bladder may have abnormal positions, be intrahepatic, be rudi-mentary (a small, nonfunctional hypoplastic remnant), or have anomalous forms or duplications. A partially or completely intrahepatic gallbladder is associated with an increased inci-dence of cholelithiasis, and may be encountered at the time of cholecystectomy. Isolated congenital absence of the gallblad-der is very rare, with a reported incidence of 0.03%. Before the diagnosis is made, the presence of an intrahepatic gallbladder or anomalous position must first be ruled out. Duplication of the gallbladder with two separate cavities and two separate cystic ducts has an incidence of about one in every 4000 persons. This occurs in two major varieties: the more common form in which each gallbladder has its own cystic duct that empties indepen-dently into the same or different parts of the extrahepatic biliary tree, and the less common variant in which the two cystic ducts merge before they enter the common bile duct. Duplication is only clinically important when some pathologic process affects one or both organs. Even rarer variants include a left-sided gallbladder (often with a cystic duct that empties into the left hepatic or common bile duct), retrodisplacement of the gall-bladder at the posterior-inferior surface of the liver, transverse positioning of the gallbladder, or a floating gallbladder in which the gallbladder is hanging by a mesentery (Fig. 32-4).Additional small bile ducts (of Luschka) may drain directly from the liver fossa into the body of the gallbladder. If present, but not recognized at the time of a cholecystectomy, a bile leak and subsequent accumulation of bile (biloma) may occur in the abdomen. An accessory right hepatic duct occurs in about 5% of cases. Variations in how the common bile duct enters the duode-num are described earlier, in the “Bile Ducts” section.Anomalies of the hepatic artery and the cystic artery are quite common, occurring in as many as 50% of cases. While the right hepatic artery usually originates from the proper hepatic branch of the celiac trunk, up to 20% of patients will have a replaced right hepatic artery coming off the superior mesenteric artery. In about 5% of cases, there are two right hepatic arteries, one from the proper hepatic artery and the other from the superior mesenteric artery (accessory right hepatic artery). While the right hepatic artery typically runs posterior to the bile ducts, variations may allow it to course anterior to the common duct, making it vulnerable during surgical procedures, particularly if it runs par-allel to the cystic duct or in the mesentery of the gallbladder. The cystic artery arises from the right hepatic artery in about 90% of cases, but it may arise from the left hepatic, common hepatic, gastroduodenal, or superior mesenteric arteries (Fig. 32-5).3Figure 32-4. Floating gallbladder suspended on mesenteryPHYSIOLOGYBile Formation and CompositionThe liver produces bile continuously and excretes it into the bile canaliculi. Bile leaves the liver through the right and left hepatic ducts, into the common hepatic duct and then the com-mon bile duct. With an intact sphincter of Oddi, tonic contrac-tion diverts bile flow into the gallbladder for storage, while mealtime stimulation allows for its passage into the duode-num. The normal adult consuming an average diet produces 500 to 1000 mL of bile a day. The secretion of bile is respon-sive to neurogenic, hormonal, and chemical stimuli. Parasym-pathetic stimulation from the hepatic branches of the vagus nerve increases secretion of bile, whereas sympathetic nerve stimulation via the celiac plexus results in decreased bile flow. Hydrochloric acid, partly digested proteins, and fatty acids entering the duodenum from the stomach after a meal stimulate the release of secretin from the S-cells of the duodenum, and increases bile production and flow.Bile is mainly composed of water, mixed with bile salts and acids, cholesterol, phospholipids (lecithin), proteins, and bilirubin. It also contains several minor components such as Brunicardi_Ch32_p1393-p1428.indd 139611/02/19 2:43 PM 1397GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32electrolytes and vitamins. Sodium, potassium, calcium, and chlorine have the same concentration in bile as in plasma or extracellular fluid. The pH of hepatic bile is usually neutral or slightly alkaline, though a high protein diet will shift the bile to a more acidic ph. The primary bile salts, cholate and che-nodeoxycholate, are synthesized in the liver from cholesterol metabolism. They are conjugated there with taurine and glycine and act within the bile as anions (bile acids) that are balanced by sodium. These bile acids are then excreted into the bile by hepatocytes and aid in the digestion and absorption of fats in the intestines.4 About 80% of the secreted conjugated bile acids are reabsorbed in the terminal ileum. The remainder is dehydroxyl-ated (deconjugated) by gut bacteria, forming the secondary bile acids deoxycholate and lithocholate. These are absorbed in the colon and can then be transported back to the liver. Eventu-ally, about 95% of the bile acid pool is reabsorbed, the so-called enterohepatic circulation. Only a small amount (5%) is excreted in the stool, allowing the relatively small quantity of bile acids produced to have maximal effect.The color of the bile is due to the presence of the pigment bilirubin (orange or yellow) and its oxidized form, biliverdin (green), which are the metabolic products of the breakdown of hemoglobin, and are present in bile in concentrations 100 times greater than in plasma. Bilirubin conjugated in the liver can be excreted through the urine as urobilinogen (yellow). Remaining excess bile pigment passes into the intestines where bacteria con-vert it into stercobilinogen (brown), which is excreted through the stool.Gallbladder FunctionThe gallbladder, bile ducts, and the sphincter of Oddi act together to store and regulate the flow of bile. The main function of the gallbladder is to concentrate and store hepatic bile in order to deliver it in a coordinated fashion to the duode-num in response to a meal. Absorption and Secretion. In the fasting state, approxi-mately 80% of the bile secreted by the liver is stored in the gallbladder. This storage is made possible by the fact that the gallbladder mucosa has the greatest absorptive power per unit area of any structure in the body. It rapidly absorbs sodium, chloride, and water against significant gradients, concentrating the bile as much as 10-fold and leading to a marked change in bile composition. This rapid absorptive capacity is one of the protective mechanisms that prevent a potentially dangerous rise in pressure within the biliary system as bile is produced and stored. In addition, gradual relaxation of the gallbladder as well as routine emptying of the gallbladder’s excess bile stores during the fasting period also play a role in maintaining a low resting intraluminal pressure in the biliary tree.The mucosal cells of the gallbladder itself secrete at least two important products into the gallbladder lumen: glycopro-teins and hydrogen ions. The mucosal glands in the infundibu-lum and the neck of the gallbladder secrete mucus glycoproteins that are believed to protect the mucosa from the corrosive action of bile and to facilitate the passage of bile through the cystic duct. This same mucus creates the colorless “white bile” seen in hydrops of the gallbladder as a result of cystic duct obstruction blocking the entry of bile pigments into the gallbladder. The transport of hydrogen ions by the gallbladder epithelium also plays an important role in decreasing the pH of stored bile. This acidification helps prevent the precipitation of calcium salts, which can act as a nidus for stone formation.4Motor Activity. Normal gallbladder filling is facilitated by tonic contraction of the sphincter of Oddi, which creates a small but effective pressure gradient between the bile ducts and the gallbladder. In association with phase II of the interdigestive migrating myenteric motor complex (MMC) in the gut, the gallbladder repeatedly empties small volumes of bile into the duodenum. This process is mediated at least in part by the hormone motilin. In response to a meal, the gallbladder delivers larger volumes to the intestine by a combination of gallbladder contraction and synchronized sphincter of Oddi relaxation. One of the main stimuli to this coordinated effort of gallbladder emp-tying is the hormone cholecystokinin (CCK). CCK is released endogenously from the enteroendocrine cells in the duodenum in response to a meal.5 When stimulated by eating, the gallbladder empties 50% to 70% of its contents within 30 to 40 minutes. Over the following 60 to 90 minutes, the gallbladder gradually refills as CCK levels drop. Other minor hormonal and neural pathways also are involved in the coordinated action of the gall-bladder and the sphincter of Oddi. Defects in the motor activity of the gallbladder that inhibit correct emptying are thought to play a role in cholesterol nucleation and gallstone formation.Neurohormonal Regulation. Neurally mediated reflexes are very important in maintaining the functions of the gallbladder, sphincter of Oddi, stomach, and duodenum to coordinate the flow of bile into the intestines at the correct times. The vagus nerve stimulates contraction of the gallbladder by parasympa-thetic innervation while splanchnic sympathetic nerves from the celiac plexus are inhibitory to its motor activity. For this reason, parasympathomimetic or cholinergic drugs, including nicotine and caffeine, contract the gallbladder. Conversely, anticholiner-gic drugs such as atropine lead to gallbladder relaxation. Antral distention of the stomach causes both gallbladder contraction and relaxation of the sphincter of Oddi.In addition to neural inputs, hormonal receptors are located on the smooth muscles, vessels, nerves, and epithelium of the gallbladder and biliary tree. CCK is a peptide that comes from the enteroendocrine cells of the duodenum and proximal jejunum. CCK is released into the bloodstream in response to the presence of hydrochloric acid, fat, and amino acids in the duodenum.6 CCK has a plasma half-life of 2 to 3 minutes and is metabolized by both the liver and the kidneys. CCK acts directly on smooth muscle receptors of the gallbladder and stimulates gallbladder contraction. It also relaxes the terminal bile duct, the sphincter of Oddi, and the duodenum to allow forward bile flow. CCK stimulation of the gallbladder and biliary tree is also mediated by cholinergic vagal neurons. For this reason, patients who have had a vagotomy may have a diminished response to CCK stimulation, resulting in an increase in the size and volume of the gallbladder.Hormones such as vasoactive intestinal polypeptide (VIP) and somatostatin are potent inhibitors of gallbladder contrac-tion. Patients treated with somatostatin analogues and those with somatostatinomas have a high incidence of gallstones, presum-ably due to the inhibition of gallbladder contraction and empty-ing. Other hormones such as substance P and enkephalin affect gallbladder motility, but their exact physiologic role is less clear.5Sphincter of OddiThe sphincter of Oddi regulates the flow of bile and pancre-atic juice into the duodenum, prevents the regurgitation of duodenal contents into the biliary tree, and diverts bile into 1Brunicardi_Ch32_p1393-p1428.indd 139711/02/19 2:43 PM 1398SPECIFIC CONSIDERATIONSPART IIthe gallbladder. It is a complex structure that is functionally independent from the duodenal musculature and creates a high-pressure zone between the bile duct and the duodenum. The sphincter of Oddi spans approximately 4 to 6 mm in length and has a basal resting pressure of about 13 mmHg above the duodenal pressure. On manometry, the sphincter shows pha-sic contractions with a frequency of about four per minute and amplitude of 12 to 140 mmHg. The spontaneous motility of the sphincter of Oddi is regulated by the interstitial cells of Cajal through intrinsic and extrinsic inputs from hormones and neu-rons acting on the smooth muscle cells.7 Relaxation occurs in response to raising levels of the gastrointestinal hormones CCK, glucagon, and secretin. This leads to diminished amplitude of phasic contractions and reduced basal pressure of the sphinc-ter, allowing increased flow of bile into the duodenum. During fasting, the sphincter of Oddi activity is coordinated with the periodic partial gallbladder emptying that occurs during phase II of the migrating myoelectric motor complexes.8 Pharmacologic administration of certain gastrointestinal hormones, such as glucagon, can temporarily decrease sphincter of Oddi baseline pressure and facilitate diagnostic studies.7DIAGNOSTIC STUDIESA variety of diagnostic modalities are available for the patient with suspected disease of the gallbladder or bile ducts. In 1924, the diagnosis of gallstones was revolutionized by the intro-duction of oral cholecystography by Graham and Cole. For decades, it was the mainstay of investigation for gallstones. It involved oral administration of a radiopaque compound that is absorbed, excreted by the liver, and passed into the gallblad-der. Stones are noted on a film as filling defects in a visualized, pacified gallbladder. In the later half of the 20th century, bili-ary imaging improved dramatically with the development of hepatobiliary scintigraphy (radionucleotide scanning), as well as transhepatic and endoscopic retrograde cholangiography (ERCP), which allowed for more detailed imaging of the bili-ary tree. Later, ultrasonography, computed tomography (CT), and magnetic resonance imaging (MRI) would further improve the ability to image the biliary tract.Blood TestsWhen patients with suspected diseases of the gallbladder or the extrahepatic biliary tree are evaluated, a complete blood count and liver function tests are routinely requested. An elevated white blood cell (WBC) count may indicate or raise suspicion of acute cholecystitis (infection within the gallbladder). If asso-ciated with an elevation of bilirubin, alkaline phosphatase, and transaminases, cholangitis (infection within the biliary tree) should be suspected. Cholestasis (an obstruction to bile flow) is generally characterized by an elevation of conjugated bilirubin and a rise in alkaline phosphatase, but it may have no transa-minitis. Such a pattern may suggest choledocholithiasis (stones in the common bile duct) or an obstructing lesion such as a stricture or cholangiocarcinoma. In patients with simple symp-tomatic cholelithiasis, biliary colic, or chronic cholecystitis (a chronic inflammatory state of the gallbladder without infec-tion), blood tests will often be normal.Transabdominal UltrasonographyTransabdominal ultrasound is the initial investigation of any patient suspected to have disease of the biliary tree.9 It is non-invasive, painless, does not submit the patient to radiation, and can be performed on critically ill patients. Adjacent organs can also frequently be examined at the same time. However, its reliability and interpretation are dependent upon the skills and experience of the operator. In addition, obese patients, patients with ascites, and patients with distended bowel may be difficult to examine with ultrasound as the quality of the images obtained in these situations can be poor.Ultrasound will show stones in the gallbladder with sen-sitivity and specificity of >90%, and can also reliably detect other pathologies of the biliary tree. Stones are acoustically dense and reflect the ultrasound waves back to the ultrasonic transducer. Because stones block the passage of sound waves to the region behind them, they also produce an acoustic shadow (Fig. 32-6). Stones move with changes in position. Polyps, on the other hand, may be calcified and reflect shadows, but they do not move with change in posture. Some stones form a layer in the gallbladder; others a form sediment or sludge. A thickened gallbladder wall, pericholecystic fluid, and local tenderness with direct pressure by the ultrasound probe over the fundus of the gallbladder (sonographic Murphy’s sign) may indicate acute cholecystitis. When a stone obstructs the neck of the gallbladder, the gallbladder may become very large, but thin walled. A contracted, thick-walled gallbladder can be indicative of chronic cholecystitis.The extrahepatic bile ducts are also well visualized by transabdominal ultrasound, with the exception of the retro-duodenal portion. Dilation of the biliary tree in a patient with jaundice suggests an extrahepatic obstruction as the cause for the jaundice. Frequently, the site and, sometimes, the cause of the obstruction can be determined by ultrasound. Small stones in the common bile duct frequently get lodged at the distal end of it, behind the duodenum, and are, therefore, difficult to detect. A dilated common bile duct on ultrasound, small stones in the gallbladder, and a classic clinical presentation allows one to assume that a stone or stones are causing the obstruction. Peri-ampullary tumors can be difficult to diagnose on ultrasound, but above the retroduodenal portion, the level of obstruction and the cause may be visualized quite well. Ultrasound can also be helpful in evaluating tumor invasion and flow in the portal vein, an important guideline for resectability of periampullary tumors.10Computed TomographyAbdominal CT scans are frequently used in the workup of undif-ferentiated abdominal pain and thus often diagnose gallbladder Figure 32-6. An ultrasonography of the gallbladder. White arrows indicate stones within the gallbladder; black arrowheads show acoustic shadows from stones.Brunicardi_Ch32_p1393-p1428.indd 139811/02/19 2:43 PM 1399GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32disease. CT scanning is inferior to ultrasonography in diagnos-ing gallstones but is similar in sensitivity for acute cholecystitis. The major application of CT scan, however, is to define the course and status of the extrahepatic biliary tree and adjacent structures, and to evaluate for alternate causes of a patients clini-cal presentation.11 CT is also the initial test of choice in evaluat-ing patients with suspected malignancy of the gallbladder, the extrahepatic biliary system, or nearby organs such as the head of the pancreas. Use of CT scan is an integral part of the dif-ferential diagnosis of obstructive jaundice of unknown origin (Fig. 32-7).Hepatobiliary ScintigraphyHepatobiliary scintigraphy, or hepatobiliary iminodiace-tic acid (HIDA) scanning, is another option for noninvasive evaluation of the liver, gallbladder, bile ducts, and duode-num that provides both anatomic and functional information. 99mTechnetium-labeled derivatives of iminodiacetic acid are injected intravenously, taken up by the Kupffer cells in the liver, and excreted in the bile. Uptake by the liver is usually detected within 10 minutes, and the gallbladder, bile ducts, and duodenum are typically visualized within 60 minutes in fasting subjects. The primary use of biliary scintigraphy is in the diag-nosis of acute cholecystitis, which appears as a nonvisualized gallbladder, with prompt filling of the common bile duct and duodenum. The lack of gallbladder filling is due to inflamma-tory closure of the cystic duct preventing bile backflow into the gallbladder (Fig. 32-8). Evidence of cystic duct obstruction on biliary scintigraphy is highly diagnostic for acute cholecys-titis. The sensitivity and specificity for the diagnosis are about 95% each. False-positive results can occur in patients in the nonfasting state, those receiving parenteral nutrition, or in the setting of gallbladder stasis, recent narcotic use, or alcoholism. Filling of the gallbladder and common bile duct with delayed or absent filling of the duodenum indicates an obstruction at the ampulla. Biliary leaks as a complication of surgery of the gallbladder or the biliary tree can be confirmed and frequently localized by biliary scintigraphy.12 HIDA scanning with evalu-ation of the gallbladder ejection fraction with or without CCK provocation may also be helpful in diagnosing chronic bili-ary dyskinesia in patients with atypical symptoms. While an ejection fraction of <35% is considered abnormal, the exact interpretations and clinical implications of this finding remain a matter of some debate.13Magnetic Resonance ImagingAvailable since the mid-1990s, MRI provides anatomic details of the liver, gallbladder, and pancreas similar to those obtained from CT. Many MRI techniques (i.e., heavily T2-weighted sequences, pulse sequences with or without contrast materials) can generate high-resolution anatomic images of the biliary tree and the pancreatic duct. MRI with magnetic resonance chol-angiopancreatography (MRCP) offers a focused, noninvasive test for the diagnosis of biliary tract and pancreatic disease (Fig. 32-9).14 It has a sensitivity and specificity of 95% and 89%, respectively, for detecting choledocholithiasis.15 In many centers, MRCP is the preferred imaging modality for precise evaluation of biliary and pancreatic duct pathology, reserving endoscopic retrograde cholangiopancreatography (ERCP) for therapeutic purposes only.Figure 32-7. Computed tomography scan of the upper abdomen from a patient with cancer of the distal common bile duct. The cancer obstructs the common bile duct as well as the pancreatic duct. 1 = the portal vein; 2 = a dilated intrahepatic bile duct; 3 = dilated cystic duct and the neck of the gallbladder; 4 = dilated common hepatic duct; 5 = the bifurcation of the common hepatic artery into the gastroduodenal artery and the proper hepatic artery; 6 = dilated pancreatic duct; 7 = the splenic vein.ABFigure 32-8. HIDA scanning. A. Normal HIDA scan showing filling of the extrahepatic biliary tree and gallbladder (white arrow). B. HIDA san in a patient with acute cholecystitis showing no filling of the gallbladder.Brunicardi_Ch32_p1393-p1428.indd 139911/02/19 2:43 PM 1400SPECIFIC CONSIDERATIONSPART IIEndoscopic Retrograde CholangiopancreatographyWhile the use of endoscopic retrograde cholangiopancrea-tography (ERCP) in biliary disease is particularly valuable for its therapeutic capabilities, its diagnostic role should not be overlooked. Using a side-viewing endoscope, the common bile duct can be cannulated through the ampulla of Vater and a cholangiogram performed using fluoroscopy (Fig. 32-10). The procedure requires at least intravenous (IV) sedation and in some cases general anesthesia. The advantages of ERCP include direct visualization of the ampullary region and direct access to the distal common bile duct for cholangiography or choledochoscopy. The test is rarely needed for uncomplicated gallstone disease. However, for cases of choledocholithiasis, obstructive jaundice, biliary strictures, or cholangitis, ERCP has the advantage of being both diagnostic and therapeutic. If ductal stones are identified on the endoscopic cholangiogram, biliary sphincterotomy and stone extraction can be performed, clearing the common bile duct of stones. If another etiology such as a biliary stricture is found, diagnostic brushings can be obtained at the time of the procedure. In the hands of experts, the success rate of common bile duct cannulation and cholan-giography is >90%. Notable complications of diagnostic ERCP include pancreatitis, which occurs in approximately 3.5% of patients, as well as rare occurrences of bleeding, perforation, or infection (cholangitis).16,17Endoscopic CholedochoscopyThe development of small fiber-optic cameras that can be threaded through endoscopes used for endoscopic retrograde cholangiopancreatography (ERCP) has facilitated the develop-ment of intraductal endoscopy. By providing direct visualiza-tion of the biliary and pancreatic ducts, this technology has been shown to increase the effectiveness of ERCP in the diag-nosis of certain biliary diseases.18 Intraductal endoscopy has been shown to have therapeutic applications that include bili-ary stone lithotripsy and directed stone extraction in high-risk surgical patients.19 It can also allow for direct visualization and sampling of concerning lesions in order to evaluate for malig-nancy (Fig. 32-11). Studies have thus far shown intraductal endoscopy to be safe and effective, though complications such as bile duct perforation, minor bleeding, and cholangitis have Figure 32-9. Magnetic resonance cholangiopancreatography. This view shows the course of the extrahepatic bile ducts (arrow) and the pancreatic duct (arrowheads).BAFigure 32-10. Endoscopic retrograde cholangiography. A. A schematic picture showing the side-viewing endoscope in the duodenum and a catheter in the common bile duct. B. An endoscopic cholangiogram showing stones in the common bile duct. The catheter has been placed through the ampulla of Vater into the distal common bile duct (arrow). Note the duodenal shadow indicated with arrowheads.Brunicardi_Ch32_p1393-p1428.indd 140011/02/19 2:43 PM 1401GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32been described.20 Further refinement of this technology will likely enhance ERCP as a diagnostic and therapeutic tool.Endoscopic UltrasoundEndoscopic ultrasound (EUS) has improved significantly in recent years and offers additional diagnostic utility to the workup of biliary disease. It requires a specialized 30° endo-scope with either a radial or linear ultrasound transducer at its tip. The results are operator dependent and require a skilled endoscopist but offer noninvasive imaging of the bile ducts and adjacent structures. Endoscopic ultrasound can also be used to identify choledocholithiasis. It is useful for evaluation of the retroduodenal potion of the bile duct, which is difficult to visu-alize with transabdominal ultrasonography. Although EUS is less sensitive than ERCP for biliary stones, the technique is less invasive as it does not require cannulation of the sphincter of Oddi. EUS is also of particular value in the evaluation of tumors near or behind the duodenum and their resectability. Using a linear EUS scope that has a biopsy channel, fine-needle aspira-tion (FNA) of tumors or lymph nodes, therapeutic injections, or drainage procedures under direct ultrasonic guidance can be performed.21Percutaneous Transhepatic CholangiographyIn settings in which the biliary tree cannot be accessed endo-scopically, antegrade cholangiography can be performed by accessing the intrahepatic bile ducts percutaneously with a small needle under fluoroscopic guidance. Once the position in a bile duct has been confirmed, a guidewire is inserted and a catheter is passed over the wire (Fig. 32-12). Through the catheter, an antegrade cholangiogram can be obtained and therapeutic inter-ventions such as tissue sampling, biliary drain insertions, or stent placements performed. Percutaneous transhepatic cholangiog-raphy (PTC) can also be performed through previously placed percutaneous biliary drainage tubes, if present. PTC has little role in the management of patients with uncomplicated gallstone disease but can be useful in patients with bile duct strictures or tumors, as it can define the anatomy of the biliary tree proximal to the affected segment. As with any invasive procedure, there are potential risks. For PTC, these are mainly bleeding, cholan-gitis, bile leak, and other catheter-related problems.12GALLSTONE DISEASEPrevalence and IncidenceGallstone disease (cholelithiasis) is one of the most common afflictions of the digestive tract. Autopsy reports show that gallstones are present in between 10% and 15% of adults.22 The prevalence of gallstones is related to many factors, including diet, age, gender, BMI, and ethnic background with increased prevalence in patients of Native American and Latin American descent. Certain conditions also predispose to the development of gallstones including pregnancy, non-HDL hyperlipidemia, Crohn’s disease, and certain blood disorders such as heredi-tary spherocytosis, sickle cell disease, and thalassemia. Sur-geries that alter the normal neural or hormonal regulation of the biliary tree including terminal ileal resection and gastric or duodenal surgery increase the risk of cholelithiasis. Rapid weight loss following bariatric surgery or lifestyle changes can also precipitate gallstone formation by creating an imbal-ance in bile composition. Medications such as somatostatin analogues and estrogen-containing oral contraceptives are also associated with an increased risk of developing gallstones.22 Women are three times more likely to develop gallstones than men, and first-degree relatives of patients with gallstones have a twofold greater prevalence, possibly indicating a genetic predisposition.23Natural HistoryDespite the high prevalence of cholelithiasis, most patients will remain asymptomatic from their gallstones throughout life. For unknown reasons, some patients progress to a symptom-atic stage, with typical symptoms of postprandial right upper quadrant pain (biliary colic) caused by a stone obstructing the cystic duct. In addition to pain, gallstones may progress to cause complications such as acute cholecystitis, choledocholithiasis, cholangitis, gallstone pancreatitis, gallstone ileus, and gallblad-der cancer. Rarely, one of these complications of gallstones may be the initial presenting picture.Gallstones in patients without biliary symptoms are com-monly diagnosed incidentally during unrelated abdominal imag-ing or at the time of surgery for an unrelated diagnosis. Several studies have examined the likelihood of developing biliary colic or developing significant complications of gallstone disease after incidental diagnosis in the asymptomatic patient. About 80% of these patients will remain symptom free.24 However, 2% to 3% will become symptomatic per year (i.e., develop biliary colic). Once symptomatic, patients tend to have recurring bouts of biliary colic. Complicated gallstone disease (cholecystitis, choledocholithiasis, gallstone pancreatitis, etc.) develops in 3% to 5% of symptomatic patients per year.25Because few patients develop complications without previ-ous biliary symptoms, prophylactic cholecystectomy in asymp-tomatic persons with gallstones is rarely indicated.24 Exceptions exist for individuals who will be isolated from medical care for extended periods of time, or in populations with increased risk of gallbladder cancer, in which case a prophylactic cholecys-tectomy may be advisable. The presence of porcelain gallblad-der, marked by significant calcifications thought to be related to Figure 32-11. A view from the choledochoscope showing cholangiocarcinoma.Brunicardi_Ch32_p1393-p1428.indd 140111/02/19 2:43 PM 1402SPECIFIC CONSIDERATIONSPART IIgallstones, is a rare premalignant condition and is an absolute indication for cholecystectomy, even when asymptomatic.Gallstone FormationGallstones form as a result of solids settling out of solution. The major organic solutes in bile are bilirubin, bile salts, phospho-lipids, and cholesterol. Gallstones are classified by their choles-terol content as either cholesterol stones or pigment stones. Pigment stones can be further classified as either black or brown. In Western countries, about 80% of gallstones are cholesterol stones and about 15% to 20% are black pigment stones.22 Brown pigment stones account for only a small percentage. Both types of pigment stones are more common in Asia.Cholesterol Stones. Pure cholesterol stones are uncommon and account for <10% of all stones. They usually occur as a sin-gle large stone with a smooth surface. The majority of choles-terol stones are mixed but are at least 70% cholesterol by weight in addition to variable amounts of bile pigments and calcium. These stones are usually multiple, of variable size, and may be 2SafetywireinsertedExternaldrainagecatheter21-guageneedleBileducttumorGuidewire insertedthrough introducerDrainagecatheterABCDEFFigure 32-12. Schematic diagram of percutaneous transhepatic cholangiogram and drainage for obstructing proximal cholangiocarcinoma. A. Dilated intrahepatic bile duct is entered percutaneously with a fine needle. B. Small guidewire is passed through the needle into the duct. C. A plastic catheter has been passed over the wire, and the wire is subsequently removed. A cholangiogram can be performed through the catheter. D. An external drainage catheter in place. E. Long wire placed via the catheter and advanced past the tumor and into the duodenum. F. Internal stent has been placed through the tumor.Brunicardi_Ch32_p1393-p1428.indd 140211/02/19 2:43 PM 1403GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32Figure 32-13. Gallbladder with cholesterol stones. A. Stones of multiple shapes and sizes. B. Solitary large stone. C. Multiple stones of varying composition. (Reproduced with permission from Slesinger MH, Fordtran JS: Gastrointestinal Diseases. Philadelphia, PA: Elsevier/Saunders; 1989.)100100Moles % Bile salts100808080606060Moles % CholesterolMoles % LecithinMicellarliquidMetastablesupersaturatedzone4040402020200002 or morephasesFigure 32-14. The three major components of bile plotted on triangular coordinates, cholesterol, bile salts and phospholipids (lecithin). A given point represents the relative molar ratios of each. The area labeled “micellar liquid” shows the range of concentrations in which cholesterol is fully solubilized. The shaded area directly above this region corresponds to a metastable zone, supersaturated with cholesterol. Above the shaded area, bile has exceeded the solubilization capacity of cholesterol and precipitation of cholesterol crystals and stones occurs.hard and faceted or irregular, multilobed, and soft (Fig. 32-13). Colors range from whitish yellow to green or black. Most cho-lesterol stones (>90%) are radiolucent, though some have a high calcium carbonate component and become radioopaque.The primary event in the formation of cholesterol stones is supersaturation of bile with cholesterol. Cholesterol is highly nonpolar and its solubility in water and bile depends on the relative concentration of cholesterol, bile salts, and lecithin (the main phospholipid in bile). Cholesterol is secreted into bile and is surrounded by bile salts and phospholipids to form a soluble vesicle complex. When cholesterol hypersecretion is present, either through increased intake or dysfunctional processing, supersaturation occurs. When cholesterol concentrations exceed the ability of the bile salts and phospholipid to maintain solu-bility, the cholesterol precipitates out of solution into a solid, forming a cholesterol stone (Fig. 32-14).26 Cholesterol hyperse-cretion is almost always the cause of supersaturation rather than reduced secretion of phospholipid or bile salts.2Pigmented Stones. Pigmented stones contain <20% choles-terol and are dark because of the presence of calcium bilirubi-nate. Black and brown pigment stones have little in common and should be considered as separate entities.Black pigment stones are usually small, brittle, dark, and sometimes spiculated. They are formed by supersaturation of unconjugated bilirubin within the bile. Deconjugation of bili-rubin occurs normally in bile at a slow rate. Thus, excessive levels of conjugated bilirubin excretion, as occurs in hemolytic disorders like hereditary spherocytosis and sickle cell disease will lead to an increased rate of production of unconjugated bilirubin. Cirrhosis and hepatic dysfunction may also lead to increased secretion of unconjugated bilirubin directly from the liver. The insoluble unconjugated bilirubin will then precipitate with calcium as insoluble calcium bilirubinate, forming a pig-ment stone. Due to their high calcium content, pigment stones are often radiopaque. Like cholesterol stones, they almost always form in the gallbladder. In Asian countries such as Japan, black stones account for a much higher percentage of gallstones than in the Western hemisphere.Brown stones are usually <1 cm in diameter, brownish-yel-low, soft, and often mushy. They may form either in the gallblad-der or in the bile ducts secondary to bacterial infection and bile stasis. Bacteria such as Escherichia coli secrete β-glucuronidase that enzymatically cleaves conjugated bilirubin to produce the insoluble unconjugated bilirubin. This unconjugated bilirubin then precipitates with calcium, and along with dead bacterial cell bodies, forms soft brown stones in the biliary tree. Brown stones are typically found in Asian populations and are associated with stasis secondary to parasite infection with Ascaris lumbricoides BCABrunicardi_Ch32_p1393-p1428.indd 140311/02/19 2:43 PM 1404SPECIFIC CONSIDERATIONSPART II(roundworm) or Clonorchis sinensis (liver fluke). In Western populations, brown stones most often occur as primary bile duct stones in patients with biliary strictures or other common bile duct stones that cause stasis and bacterial contamination.2,27Symptomatic GallstonesSymptomatic Cholelithiasis. Patients with symptomatic gall-stone disease typically present with recurrent attacks of pain. The pain develops when a stone obstructs the cystic duct, resulting in a progressive increase of tension in the gallbladder wall as it contracts in response to a meal. This postprandial right upper quadrant or epigastric pain is often referred to as biliary colic. If untreated, about two-thirds of these patients will develop chronic noninfectious inflammation of the gallbladder wall, termed chronic cholecystitis. The pathologic changes, which often do not correlate well with symptoms, vary from an apparently nor-mal gallbladder with minor chronic inflammation in the mucosa, to a shrunken, nonfunctioning gallbladder with transmural fibro-sis and adhesions to nearby structures. The mucosa is initially normal or hypertrophied but later becomes atrophied, with the epithelium protruding into the muscle coat, leading to the forma-tion of the so-called Aschoff-Rokitansky sinuses.Clinical Manifestations The chief symptom associated with symptomatic cholelithiasis is pain (biliary colic). The pain is con-stant and increases in severity over the first half hour or so after a meal and can last 1 to 5 hours. It is located in the epigastrium or right upper quadrant and frequently radiates to the right upper back or between the scapulae (Fig. 32-15). The pain is severe and comes on abruptly, typically during the night or after a fatty meal. It often is associated with nausea and sometimes vomiting. Patients generally suffer discrete, recurrent attacks of pain, between which they feel well. Physical examination may reveal mild right upper quadrant tenderness during an episode of pain. If the patient is pain free, the physical examination is usually unremarkable. Labora-tory values, such as WBC count and liver function tests, are usu-ally normal in patients with uncomplicated gallstones.Atypical presentations of gallstone disease are common and a high index of suspicion for biliary disease must be main-tained when evaluating patients with abdominal complaints. Association with meals is present in only about 50% of patients. Some patients report milder attacks of pain but relate it to meals. The pain may be located primarily in the back or the left upper or right lower quadrant. Bloating and belching may be present and associated with the attacks of pain. In patients with atypi-cal presentations, other conditions that may be causing upper abdominal pain should be ruled out, even in the presence of gallstones. These include but are not limited to peptic ulcer dis-ease, gastroesophageal reflux disease, herpes zoster, abdominal wall hernias, inflammatory bowel disease, diverticular disease, pancreatitis, liver disease, renal calculi, pleuritic pain, and car-diac pain.When the pain lasts >24 hours without resolving, an impacted stone in the cystic duct or acute cholecystitis (see later “Acute Cholecystitis” section) should be suspected. An impacted stone without cholecystitis will result in what is called hydrops of the gallbladder. Bile will be unable to enter the gall-bladder due to the obstructed cystic duct, but the gallbladder epithelium will continue to secrete mucus, and the gallbladder will become distended with clear-white mucinous material. The gallbladder may be palpable but usually is not tender. Hydrops of the gallbladder may result in edema of the gallbladder wall, inflammation, infection, and perforation. Although hydrops may persist with few consequences, early cholecystectomy is generally indicated to avoid complications.Diagnosis The diagnosis of symptomatic cholelithiasis or chronic cholecystitis depends on the presence of typical symp-toms and the demonstration of stones on diagnostic imaging. An abdominal ultrasound is the standard diagnostic test for gallstones as it is noninvasive and highly sensitive (see earlier “Ultrasonography” section).28 Gallstones are occasionally iden-tified on abdominal CT scans that were obtained as part of a broader workup of abdominal pain. In these cases, if the patient has typical symptoms, it is reasonable to proceed with interven-tion. Stones diagnosed incidentally on CT or plain radiographs in patients without symptoms should be left in place. Occasion-ally, patients with typical attacks of biliary pain have no evi-dence of stones on ultrasound but have evidence of sludge in the gallbladder. If a patient has attacks of typical biliary pain and sludge is detected, cholecystectomy is warranted.In addition to sludge and stones, cholesterolosis and adeno-myomatosis of the gallbladder may cause typical biliary symp-toms and may be detected on ultrasound or CT. Cholesterolosis is caused by the accumulation of cholesterol in macrophages in the 221514764501352441429614396322151911252311353323ABFigure 32-15. A. Sites of the most severe pain during an episode of biliary colic in 107 patients with gallstones (% values add up to >100% because of multiple responses). The subxiphoid and right subcostal areas were the most common sites; note that the left sub-costal area was not an unusual site of pain. B. Sites of pain radiation (%) during an episode of biliary colic in the same group of patients.Brunicardi_Ch32_p1393-p1428.indd 140411/02/19 2:43 PM 1405GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32gallbladder lamina propria, either locally or as polyps. It produces the classic studded macroscopic appearance of a “strawberry gallbladder.” Adenomyomatosis (cholecystitis glandularis prolif-erans) is characterized on microscopy by hypertrophic smooth muscle bundles and by the ingrowths of mucosal glands into the muscle layer (epithelial sinus formation). Granulomatous polyps develop in the lumen at the fundus, and the gallbladder wall is thickened. Septae or strictures may be seen within the gallblad-der. In symptomatic patients, cholecystectomy is the treatment of choice for patients with these conditions.29Treatment Nonsurgical management of gallstone disease using medications or lithotripsy has had disappointing long-term results. These modalities are not considered to be part of the primary treatment algorithm for gallstone disease.30 Surgi-cal cholecystectomy offers the best long-term results for patients with symptomatic gallstones. About 90% of patients with typical biliary symptoms and stones are rendered symp-tom free after cholecystectomy. For patients with atypical symptoms such as dyspepsia, flatulence, belching, bloating, and dietary fat intolerance, the results are not as favorable. The laparoscopic approach has been proven to be safe and effective and has become the standard of care for symptomatic gallstone disease, replacing open cholecystectomy in routine cases.29,31 3Due to the possibility of developing complications related to gallstone disease, patients with symptomatic choleli-thiasis should be offered elective cholecystectomy. While wait-ing for surgery, or if surgery has to be postponed, the patient should be advised to avoid dietary fats and large meals. Dia-betic patients with symptomatic gallstones should be encour-aged to have a cholecystectomy promptly, as they are more prone to developing severe acute cholecystitis. Pregnant women with symptomatic gallstones who cannot be managed expectantly with diet modifications can safely undergo laparo-scopic cholecystectomy. The operation should be performed during the second trimester if possible.Acute Cholecystitis. Acute cholecystitis, or infection of the gallbladder, is associated with gallstones in 90% to 95% of cases. Rarely, acalculous cholecystitis can occur, usually in patients with other acute systemic diseases (see later “Acalculous Chole-cystitis” section). Obstruction of the cystic duct by a gall-stone is the initiating event that leads to gallbladder distention, inflammation, and edema of the gallbladder wall. In <1% of acute cholecystitis, the cause is a tumor obstructing the cystic duct. Why inflammation develops only occasionally with cystic duct obstruction is unknown, but it is probably related to the duration of obstruction. Initially, acute cholecystitis is an inflammatory process, probably mediated by the mucosal toxin lysolecithin, a product of lecithin, as well as bile salts and platelet-activat-ing factor. An increase in prostaglandin synthesis amplifies the inflammatory response. In acute cholecystitis, the gallbladder wall becomes grossly thickened and reddish with subserosal hemorrhages. Pericholecystic fluid often is present. The mucosa may show hyperemia and patchy necrosis. In severe cases, about 5% to 10%, the inflammatory process progresses and leads to ischemia and necrosis of the gallbladder wall. More frequently, the gallstone is dislodged and the inflammation resolves.Not all episodes of uncomplicated acute cholecystitis involve infection. Secondary bacterial contamination is thought to occur in only 15% to 30% of patients. With some severe infections, gangrenous cholecystitis can develop, and an abscess or perforation may occur. When they happen, perforations are usually contained in the subhepatic space by the omentum and adjacent organs. However, free perforation with peritonitis, intrahepatic perforation with intrahepatic abscesses, and per-foration into adjacent organs (duodenum or colon) with cho-lecystoenteric fistula have been described. When gas-forming organisms are part of the secondary bacterial infection, gas may be seen in the gallbladder lumen and in the wall of the gallblad-der on abdominal radiographs and CT scans, an entity called emphysematous cholecystitis.Clinical Manifestations About 80% of patients with acute cholecystitis give a history compatible with chronic cholecysti-tis. Acute cholecystitis often begins as an attack of biliary colic with relapsing and remitting pain in the right upper quadrant or epigastrium that may radiate to the right back or interscapular area. In contrast to biliary colic, the pain of acute cholecystitis does not subside. It is unremitting, may persist for several days, and is usually more severe than the pain associated with uncom-plicated gallstone disease. The patient is often febrile, complains of anorexia, nausea, and vomiting, and may be reluctant to move as the inflammatory process creates focal peritonitis. On physi-cal examination, tenderness and guarding are usually present in the right upper quadrant. A mass, the gallbladder and adherent omentum, is occasionally palpable; however, guarding may pre-vent identification of this. Murphy’s sign, an inspiratory arrest with deep palpation in the right subcostal area, is characteristic of acute cholecystitis.Laboratory evaluation commonly reveals a mild to mod-erate leukocytosis (12,000–15,000 cells/mm3). However, a normal WBC does not rule out the diagnosis. An unusually high WBC count (>20,000 cells/mm3) suggests a complicated form of cholecystitis such as gangrenous cholecystitis, perfo-ration, or associated cholangitis. In uncomplicated acute cho-lecystitis, serum liver chemistries are usually normal, but a mild elevation of serum bilirubin (<4 mg/mL) may be present along with mild elevation of alkaline phosphatase, transami-nases, and amylase.28 Severe jaundice is suggestive of obstruc-tion of the bile ducts. This can be a result of common bile duct stones or severe pericholecystic inflammation secondary to impaction of a stone in the infundibulum of the gallblad-der that mechanically obstructs the bile duct, known as Mir-izzi’s syndrome (Fig. 32-16). In elderly patients and in those with diabetes mellitus, acute cholecystitis may have a subtle Figure 32-16. Mirizzi’s syndrome. Impaction of a large stone in the neck of the gallbladder causing obstruction at the level of the confluence of the cystic duct and common hepatic duct.Brunicardi_Ch32_p1393-p1428.indd 140511/02/19 2:43 PM 1406SPECIFIC CONSIDERATIONSPART IIpresentation resulting in a delay in diagnosis. These patients may also have higher rates of treatment related morbidity com-pared to younger and healthier patients.The differential diagnosis for acute cholecystitis includes but is not limited to peptic ulcer disease, pancreatitis, appen-dicitis, hepatitis, perihepatitis (Fitz-Hugh–Curtis syndrome), myocardial ischemia, pneumonia, pleuritis, and herpes zoster involving the intercostal nerve.Diagnosis Ultrasonography is considered the most useful ini-tial radiologic test for diagnosing acute cholecystitis, with a sen-sitivity and specificity of 70% to 90%. Ultrasound is effective at documenting the presence or absence of stones, and it can show gallbladder wall thickening and pericholecystic fluid, both of which are highly suggestive of acute cholecystitis (Fig. 32-17). Focal tenderness over the gallbladder when compressed by the sonographic probe (sonographic Murphy’s sign) also supports the diagnosis of acute cholecystitis. Biliary scintigraphy (HIDA scanning) may be of help in atypical cases if the diagnosis remains in question after initial workup. Lack of filling of the gallbladder after 4 hours indicates an obstructed cystic duct and, in the clinical setting of suspected acute cholecystitis, confirms the diagnosis with a reported sensitivity above 90%.32 Con-versely, a normal HIDA scan with clear filling of the gallblad-der rules out the diagnosis of acute cholecystitis. CT scans are frequently performed on patients with acute abdominal pain of unknown etiology, as they can evaluate for a number of poten-tial pathologic processes at once. In patients with acute chole-cystitis, a CT scan can demonstrate thickening of the gallbladder wall, pericholecystic fluid, and the presence of gallstones, but it is somewhat less sensitive than ultrasonography.Treatment Patients who present with acute cholecystitis should receive IV fluids, broad-spectrum antibiotics, and anal-gesia. The antibiotics should cover gram-negative enteric organ-isms as well as anaerobes. Although the inflammation in acute cholecystitis may be sterile in some patients, it is difficult to know who is secondarily infected. Therefore, antibiotics have become a standard part of the initial management of acute cho-lecystitis in most centers.Cholecystectomy is the definitive treatment for acute cho-lecystitis. In the past, the timing of cholecystectomy has been a matter of debate. Early cholecystectomy performed within 72 hours of the onset of the illness is preferred over delayed cholecystectomy that is performed 6 to 10 weeks after initial medical treatment and recuperation. Several studies have shown that unless the patient is unfit for surgery, early cholecystectomy should be recommended as soon as possible, as it offers the patient a definitive solution in one hospital admission, quicker recovery times, similar complication rates, and an earlier return to work.33,34Laparoscopic cholecystectomy is the procedure of choice for acute cholecystitis. The conversion rate to an open cholecys-tectomy has fallen in recent years to less than 5% as laparoscopic equipment and experience has improved.35 While laparoscopic cholecystectomy for acute cholecystitis may be more tedious and take longer than an elective cholecystectomy for symp-tomatic cholelithiasis, the laparoscopic approach remains safe and effective, even in the setting of acute and sometimes severe inflammation. Open cholecystectomy must remain an option in particularly difficult cases, or in patients suspected of having prohibitive intraabdominal adhesions, but it is rarely the primary treatment choice.When patients are medically unfit for surgery due to the severity of their illness or medical comorbidities, they can be treated with antibiotics and biliary decompression with cho-lecystostomy tube placement, which is usually effective in stabilizing the patient.36 For those who do recover after chole-cystostomy, the tube can be removed once the track is mature (approximately 4 weeks) and cholangiography through it shows a patent cystic duct. Elective laparoscopic cholecystectomy can be scheduled within approximately 6 to 8 weeks, assum-ing their medical fitness recovers.37 Failure to improve after cholecystostomy may be due to gangrene of the gallbladder or perforation, in which case, damage control surgery may be unavoidable.Choledocholithiasis. Common bile duct (CBD) stones may be small or large, single or multiple, and are found in 6% to 12% of patients with stones in the gallbladder. The incidence increases with age. About 20% to 25% of patients above the age of 60 with symptomatic gallstones have stones in the common bile duct as well as in the gallbladder.38 The vast majority of ductal stones in Figure 32-17. Ultrasonography from a patient with acute cholecystitis. The white arrowheads indicate the thickened gallbladder wall. There are several stones in the gallbladder (white arrows) throwing acoustic shadows (black arrowheads). Trace pericholecystic fluid can be seen surrounding the gallbladder (black arrows).Brunicardi_Ch32_p1393-p1428.indd 140611/02/19 2:43 PM 1407GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32Western countries are formed within the gallbladder and migrate down the cystic duct into the common bile duct. These are clas-sified as secondary CBD stones, in contrast to the primary CBD stones that form in the bile duct itself. Secondary stones are usu-ally cholesterol stones, whereas primary stones are usually of the brown pigment type. The primary stones are associated with biliary stasis and infection, and they are more commonly seen in Asian populations. Biliary stasis leading to the development of primary CBD stones can be caused by biliary strictures, papillary stenosis, tumors, or other (secondary) stones.Clinical Manifestations Choledochal stones may be silent and often are discovered incidentally. They may cause complete or incomplete obstruction, or they may manifest with cholangitis or gallstone pancreatitis. The typical pain caused by a stone in the bile duct is very similar to that of biliary colic caused by impaction of a stone in the cystic duct. Nausea and vomiting are common. Physical examination may be normal, but mild epigas-tric or right upper quadrant tenderness as well as mild icterus are common. The symptoms may also be intermittent, such as pain and transient jaundice caused by a stone that temporar-ily impacts the ampulla but subsequently moves away, acting as a ball valve. A small stone may pass through the ampulla spontaneously with resolution of symptoms. Finally, the stones may become completely impacted, causing severe progressive jaundice. Elevation of serum bilirubin, alkaline phosphatase, and transaminases are commonly seen in patients with bile duct stones. However, in about one-third of patients with common bile duct stones, the liver chemistries are normal, particularly if the obstruction is incomplete or intermittent.Diagnosis Ultrasonography is useful for documenting stones in the gallbladder (if still present), as well as determining the size of the common bile duct. As stones in the bile ducts tend to move down to the distal part of the common duct behind the duodenum, bowel gas can preclude their detection on ultraso-nography. A dilated common bile duct (>8 mm in diameter) on ultrasonography in a patient with gallstones, jaundice, and bili-ary pain is highly suggestive of common bile duct stones. If the presence of bile duct stones is in question, magnetic resonance cholangiopancreatography (MRCP) provides excellent anatomic detail and has a sensitivity and specificity of 95% and 89%, respectively, for detecting choledocholithiasis.14 Endoscopic retrograde cholangiopancreatography (ERCP) is highly effec-tive at diagnosing choledocholithiasis and in experienced hands, cannulation of the ampulla of Vater and diagnostic cholangiog-raphy are achieved in >90% of cases. However, due to the risks associated with the procedure, it is rarely used as a purely diag-nostic modality, rather being reserved for cases in which a thera-peutic intervention such as stone extraction or sphincterotomy is planned. Endoscopic ultrasound has been demonstrated to be as good as ERCP for detecting common bile duct stones (sensitivity of 95% and specificity of 97%). However, EUS has fewer thera-peutic capabilities and requires endoscopic expertise, making it less desirable except in specific clinical senarios.39 Percutaneous transhepatic cholangiography (PTC) is rarely needed in patients with common bile duct stones but can be performed for both diagnostic and therapeutic reasons in patients with contraindica-tions to endoscopic or surgical approaches.Treatment For patients with symptomatic gallstones and sus-pected common bile duct stones, bile duct clearance and cho-lecystectomy are indicated. This may be safely achieved either with preoperative ERCP followed by surgery or by going directly to surgery with intraoperative cholangiogram and common bile duct exploration to address retained stones. Both approaches are considered safe and effective, and no formal recommendation exists to definitively support one over the other.40,41If upfront laparoscopic cholecystectomy is pursued, the surgery should include an intraoperative cholangiogram to doc-ument the presence or absence of bile duct stones. If stones are identified, laparoscopic common bile duct exploration via the cystic duct or with formal choledochotomy allows the stones to be retrieved in the same setting (see “Choledochal Explora-tion” section). If the expertise and/or instrumentation for lapa-roscopic common bile duct exploration are not available, the patient can be awoken and scheduled for ERCP with sphincter-otomy the following day. An open common bile duct explora-tion is an option if the endoscopic and laparoscopic methods are not feasible. If a choledochotomy is performed, primary repair can be considered in large ducts, while smaller ducts should be repaired over a T-tube. To do this, a standard T-tube should be modified by cutting the ends short enough to allow placement within the duct and dividing the T longitudinally to facilitate easy removal from the duct later on (Fig. 32-18). If a common Figure 32-18. T-tube placement. A. A standard T-tube that has been cut and modified for use in the biliary tract. B. The T-tube is placed through a ductotomy in the common bile duct with the defect closed over the tube. The opposite end is brought out through the abdominal wall for decompression of the bile ducts.ABBrunicardi_Ch32_p1393-p1428.indd 140711/02/19 2:43 PM 1408SPECIFIC CONSIDERATIONSPART IIbile duct exploration was performed and a T tube left in place, a T-tube cholangiogram should be obtained before its removal, at least several weeks after its placement.In very severe cases, stones impacted in the ampulla may be unable to be cleared by endoscopic approaches or common bile duct exploration (open or laparoscopic). In these cases, transduodenal sphincterotomy can be considered. If one is entirely unable to disimpact the duct, choledochoduodenostomy or Roux-en-Y choledochojejunostomy may be the only option to restore biliary continuity.42If the stones were left in place at the time of surgery or diagnosed shortly after the cholecystectomy, they are classified as retained. Those diagnosed months or years later are termed recurrent (Fig. 32-19). Retained or recurrent stones following cholecystectomy are best treated endoscopically. A generous sphincterotomy will allow for stone retrieval as well as spon-taneous passage of stones. Alternately, retained stones can be cleared via a mature T-tube tract (4 weeks) if one was placed at the time of surgery. To do this, the T-tube is removed and a catheter passed through the tract into the common bile duct. Under fluoroscopic guidance, the stones can be retrieved with baskets or balloons. A similar approach will allow for stone clearance by percutaneous transhepatic cholecystostomy (PTC) if there is no other way to reach the duct. Repeat surgery should be a last resort if other interventions have failed.Cholangitis. Cholangitis is one of the main complications of choledochal stones. Acute cholangitis is an ascending bac-terial infection associated with partial or complete obstruc-tion of the bile ducts.43 Hepatic bile is sterile, and bile in the bile ducts is kept sterile by continuous antegrade bile flow and by the presence of antibacterial substances in bile, such as immunoglobulin. Mechanical hindrance to bile flow facilitates ascending bacterial contamination from the bowel. Positive bile cultures are common in the presence of bile duct stones as well as with other causes of obstruction. Biliary bacterial contamination alone does not lead to clinical cholangitis; the combination of both significant bacterial contamination and biliary obstruction is required for its development. Gallstones are the most common cause of obstruction in cholangitis. Other causes include primary sclerosing cholangitis, benign and malignant strictures, parasites, instrumentation of the ducts, and indwelling stents, as well as partially obstructed biliary-enteric anastomoses. The most common organisms cultured from bile in patients with cholangitis include E coli, Klebsiella pneumoniae, Streptococcus faecalis, Enterobacter, and Bacteroides fragilis.43Clinical Manifestations Cholangitis may present as anything from a mild, self-limited episode to a fulminant, potentially life-threatening septicemia. Patients with gallstone-induced cholangitis are most commonly older and female. The most common presentation is fever, epigastric or right upper quad-rant pain, and jaundice. These classic symptoms, known as Charcot’s triad, are present in about two-thirds of patients. The illness can progress rapidly with the development of shock and altered mental status, known as Reynolds’ pentad (e.g., fever, jaundice, right upper quadrant pain, septic shock, and mental status changes). However, the presentation may be atypical, with little if any fever, jaundice, or pain. This occurs most commonly in the elderly, who may have unremarkable symptoms until the process is already quite advanced. Patients with indwelling stents are at particularly high risk for cholan-gitis, though rarely become jaundiced as a patent stent will prevent the obstruction of bile flow. On abdominal examina-tion, the findings are indistinguishable from those of acute cholecystitis.44Diagnosis Leukocytosis, hyperbilirubinemia, and elevation of alkaline phosphatase and transaminases are common and, when present, support the clinical diagnosis of cholangitis. Ultraso-nography is helpful, as it will document the presence of gall-bladder stones, demonstrate dilated ducts, and possibly pinpoint a site of obstruction. CT scanning and MRI can show pancreatic and periampullary masses, if present, in addition to the ductal dilatation. However, abdominal imaging will rarely elucidate the exact cause of cholangitis, and the initial diagnosis is gener-ally made clinically.Treatment The initial treatment of patients with cholangi-tis includes broad-spectrum IV antibiotics to cover enteric organisms and anaerobes, fluid resuscitation, and rapid biliary ABFigure 32-19. Retained common bile duct stones. The patient pre-sented 3 weeks after laparoscopic cholecystectomy. A. An ultra-sound shows a normal or mildly dilated common bile duct with a stone. Note the location of the right hepatic artery anterior to the common hepatic duct (an anatomic variation). B. An endoscopic retrograde cholangiography from the same patient shows multiple stones in the common bile duct. Only the top one showed on ultra-sound as the other stones lie in the distal common bile duct behind the duodenum.Brunicardi_Ch32_p1393-p1428.indd 140811/02/19 2:43 PM 1409GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32decompression. This is most often accomplished through ERCP and sphincterotomy. ERCP will show the level and the reason for the obstruction, allow for culture of the bile, permit the removal of stones if present, and accomplish drainage of the bile ducts. Placement of drainage catheters or stents can also be performed if needed. In cases in which ERCP is not available, PTC, EUS, or surgical drainage can be utilized. The selection of the appropriate approach will depend on the type and location of the suspected obstruction as well as the avail-ability of local resources and expertise. Cholecystostomy tubes are not indicated in the acute management of cholangitis as the primary source of the infection is extrinsic to the gallbladder.Patients with cholangitis can deteriorate rapidly and may require intensive care unit monitoring and vasopressor support. However, most patients will respond to biliary decompression and supportive measures. In the current era, acute cholangitis is associated with an overall mortality rate of approximately 5%. When associated with renal failure, cardiac impairment, hepatic abscesses, and malignancies, the morbidity and mortal-ity rates are much higher. Patients who have suffered an episode of acute cholangitis related to gallstone disease should be rec-ommended to undergo elective cholecystectomy approximately 6 weeks after the resolution of their cholangitis.45 Those whose cholangitis was related to another cause of biliary obstruction should be followed and treated for the specific etiology of their obstruction but do not necessarily require cholecystectomy if gallstones were not the causative etiology of their cholangitis. Patients with indwelling stents and cholangitis usually require repeated imaging and stent exchange to mitigate the risk of recurrent infections.Gallstone Pancreatitis. Gallstones in the common bile duct can provoke attacks of acute pancreatitis through transient or persistent obstruction of the pancreatic duct by a stone passing through or impacted in the ampulla. The exact mechanism by which obstruction of the pancreatic duct leads to pancreatitis is unclear, but it may be related to increased ductal pressures causing leakage of pancreatic enzymes into the glandular tissue. The initial management of gallstone pancreatitis is supportive, including admission for bowel rest, IV hydration, and pain control. Antibiotics are not indicated in the absence of signs of infected pancreatic necrosis. Imaging of the biliary tree with ultrasound, CT, or MRCP is essential to confirm the diagnosis. When gallstones are present and the pancreatitis is mild and self-limited, the stone has probably passed. For these patients, a cholecystectomy with intraoperative cholangiogram is indi-cated as soon as the pancreatitis has clinically resolved. It is strongly recommended that cholecystectomy be performed dur-ing the same admission whenever possible due to the high rate of recurrence and increased morbidity of subsequent attacks of pancreatitis.46 If gallstones are present obstructing the duct and the pancreatitis is severe, an ERCP with sphincterotomy and stone extraction may be necessary. This must be balanced with the risk of ERCP-induced pancreatitis and thus is usually only employed if supportive measures are failing.Gallstone Ileus. Gallstone ileus can occur when a large gall-stone erodes through the wall of the gallbladder directly into the intestine via a choledochoenteric fistula (Fig. 32-20A). These stones can then pass through the intestinal tract until they reach an area of fixed obstruction. Proximal stones can become impacted in the pylorus or proximal duodenum causing gastric outlet obstruction (Bouveret syndrome). Those that travel dis-tally may become lodged at surgical anastomoses or the ileoce-cal valve, where they can become impacted and cause small bowel obstruction. Gallstone ileus is responsible for less than 1% of all intestinal obstructions.47 These patients present with symptoms of obstipation, nausea, and abdominal pain. Plain films may show an obstructive bowel gas pattern but may fail to identify a radiolucent stone. Ultrasound evaluation may be lim-ited by extensive bowel gas. CT is highly sensitive and specific for gallstone ileus and will help to determine the location of the obstruction. Management of gallstone ileus focuses on relieving the intestinal obstruction and removing the stone. In cases of very proximal obstructions in the stomach or duodenum, endo-scopic retrieval can be effective. For more distal stones, surgical enterolithotomy can be accomplished either laparoscopically or open. This procedure entails the removal of the stone through ABFigure 32-20. Gallstone Ileus. A. A choledochoenteric fistula has formed between the gallbladder and the duodenum, allowing a gallstone to pass into the intestinal tract. B. Intraoperative photo showing a longitudinal enterotomy and extraction of an impacted stone from the distal small bowel.Brunicardi_Ch32_p1393-p1428.indd 140911/02/19 2:43 PM 1410SPECIFIC CONSIDERATIONSPART IIan enterotomy that is then either repaired or resected depend-ing on its size (Fig. 32-20B). Stones that have successfully traversed the ileocecal valve are likely to pass without further intervention. The role of pursuing cholecystectomy and/or cho-ledochoenteric fistula closure at the time of enterolithotomy or addressing it at a later time remains a topic of debate, but it should be considered to reduce the risk of recurrence.47CholangiohepatitisCholangiohepatitis, also known as recurrent pyogenic cholan-gitis, is endemic to the Orient. It also has been encountered in Asian population in the United States, Europe, and Australia. It affects both sexes equally and occurs most frequently in the third and fourth decades of life. Cholangiohepatitis is caused by bacterial contamination (commonly E coli, Klebsiella spe-cies, Bacteroides species, or Enterococcus faecalis) of the bili-ary tree, and often it is associated with biliary parasites such as Clonorchis sinensis, Opisthorchis viverrini, and A lumbri-coides. Bacterial enzymes cause deconjugation of bilirubin, which precipitates as bile sludge. The sludge and dead bacterial cell bodies form brown pigment stones, the nucleus of which may contain an adult Clonorchis worm, an ovum, or an ascarid. These stones can form throughout the biliary tree and cause par-tial obstructions that contribute to repeated bouts of cholangi-tis, biliary strictures, further stone formation, infection, hepatic abscesses, or liver failure (secondary biliary cirrhosis).48Patients with cholangiohepatitis usually present with pain in the right upper quadrant or epigastrium, fever, and jaundice. Relapsing symptoms are one of the most characteristic features of the disease. The episodes may vary in severity but, without intervention, will gradually lead to malnutrition and hepatic insufficiency. An ultrasound may detect stones in the biliary tree, pneumobilia from infection by gas-forming organisms, liver abscesses, and, occasionally, strictures. The gallbladder may be thickened and inflamed in about 20% of patients but rarely contains gallstones. ERCP or MRCP can be utilized for biliary imaging for cholangiohepatitis. They can detect obstruc-tions and define strictures and stones. ERCP (or PTC if nec-essary) has the additional benefit of allowing for emergent decompression of the biliary tree in the septic patient. Hepatic abscesses may be drained percutaneously. The long-term goal of therapy is to extract stones and debris and relieve strictures. It may take several procedures, and in severe, refractory cases in which stones and strictures cannot be relieved, it may require a hepaticojejunostomy to reestablish biliary–enteric continuity. Occasionally, resection of involved areas of the liver may offer the best form of treatment. Recurrences are common, and the prognosis is poor once hepatic insufficiency has developed.49PROCEDURAL INTERVENTIONS FOR GALLSTONE DISEASEPercutaneous Transhepatic Cholecystostomy TubesIn cases in which a patient with cholecystitis is deemed to be too ill to safely undergo cholecystectomy, a cholecystostomy tube may be placed into the gallbladder to decompress and drain a distended, inflamed, hydropic, or purulent gallbladder.36 Surgi-cal cholecystostomy with a large catheter placed under local anesthesia is rarely required today. Rather, percutaneous tran-shepatic cholecystostomy (PTC) tubes are most often pigtail catheters inserted percutaneously under ultrasound guidance.50 The catheter is inserted over a guidewire that has been passed through the abdominal wall, the liver, and into the gallblad-der (Fig. 32-21). By passing the catheter through the liver, the risk of uncontrolled bile leak around the catheter and into the peritoneal cavity is minimized. The catheter can be removed when the inflammation has resolved and the patient’s condition has improved. A patent cystic duct should be confirmed by a tube cholangiogram prior to its removal. Interval cholecystec-tomy should be considered if the patient’s fitness has improved, particularly in individuals whose etiology of cholecystitis was gallstones.Endoscopic InterventionsEndoscopic advances in the last few decades have made endos-copy and ERCP a valuable therapeutic tool in the management of gallstone disease, particularly in the setting of common bile duct stones or abnormalities. Using a 90-degree side-viewing endoscope, the duodenum can be entered and the ampulla of Vater on the medial wall of the second portion of the duode-num visualized. This can then be cannulated to allow wire and catheter access to the biliary tree, facilitating retrograde chol-angiogram, diagnostic brushings, stenting, dilations, or fluoro-scopically guided basket or balloon retrieval of common bile duct stones. When CBD stones are present, endoscopic sphinc-terotomy should be performed, which will allow for passage of larger stones both at the time of bile duct clearance and in the case of any ongoing choledocholithiasis (Fig. 32-22). In the hands of experts, ERCP has high rates of successful cannulation and bile duct clearance, and it is a safe and tolerable procedure. Debate remains when comparing ERCP to surgical common bile duct exploration in terms of timing and outcomes for choledo-cholithiasis, but both are considered acceptable treatments.41 In special cases, such as the presence of Roux-en-Y anatomy or a previous hepaticojejunostomy, ERCP can be difficult. How-ever, such anatomy does not preclude the option for endoscopic intervention. Laparoscopic-assisted ERCP (in which the rem-nant stomach is accessed surgically and the endoscope passed into the duodenum) or double-balloon ERCP can be utilized to reach the biliary tree.CholecystectomyCholecystectomy is one of the most common abdominal sur-geries performed in Western countries, with over 750,000 Figure 32-21. Percutaneous cholecystostomy. A pigtail catheter has been placed through the abdominal wall, the right lobe of the liver, and into the gallbladder.Brunicardi_Ch32_p1393-p1428.indd 141011/02/19 2:43 PM 1411GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32being performed each year in the United States alone.51 Carl Langenbuch performed the first successful open cholecystectomy in 1882, and for >100 years, it was the standard treatment for symptomatic gallbladder stones. In 1987, laparoscopic chole-cystectomy was introduced by Philippe Mouret in France and quickly revolutionized the treatment of gallstone disease. It not only supplanted open cholecystectomy, but it also more or less ended attempts for noninvasive management of gallstones (such as extracorporeal shock wave or cholangioscopic lithotripsy) or medical therapies (such as bile salts). Laparoscopic cholecystec-tomy offers a cure for gallstones with a minimally invasive pro-cedure, minor pain and scarring, and early return to full activity. Today, laparoscopic cholecystectomy is the treatment of choice for symptomatic gallstones and the complications of gallstone disease.Few absolute contraindications exist to laparoscopic cholecystectomy, but they include hemodynamic instability, uncontrolled coagulopathy, or frank peritonitis. In addition, patients with severe obstructive pulmonary disease (COPD) or congestive heart failure (e.g., cardiac ejection fraction <20%) might not tolerate the increased intraabdominal pressures of pneumoperitoneum with carbon dioxide and may require open cholecystectomy. Conditions formerly believed to be relative contraindications such as acute cholecystitis, gangrene and empyema of the gallbladder, biliary-enteric fistulae, obesity, pregnancy, ventriculoperitoneal shunts, cirrhosis, and previous upper abdominal procedures are now considered risk factors for a potentially difficult cholecystectomy, but they do not preclude an attempt at laparoscopy. While laparoscopic outcomes have steadily improved and laparoscopic cholecystectomy has been shown multiple times to be safe and feasible, conversion to an open operation should always remain an option, and it is not a failure. Conversion to open may be necessary if the patient is unable to tolerate pneumoperitoneum, a complication occurs that cannot be fixed laparoscopically, important anatomic struc-tures cannot be clearly identified, or when no progress is made over a set period of time. In the elective setting, conversion to an open procedure is needed in about 5% of patients.51 Emer-gent procedures or patients with complicated gallstone disease can be more challenging, and the incidence of conversion has been reported to be between 10% and 30%. The possibility of conversion to open should always be discussed with the patient preoperatively.Serious complications of cholecystectomy are rare. The mortality rate for laparoscopic cholecystectomy is about 0.1%. Wound infection and cardiopulmonary complication rates are considerably lower following laparoscopic cholecystectomy than are those for an open procedure.52 While laparoscopic cho-lecystectomy has historically been associated with a higher rate of injury to the bile ducts than the open approach, modern data appears to show this trend disappearing as familiarity with lapa-roscopic techniques and technologies have improved.53Patients undergoing cholecystectomy should have a complete blood count and liver function tests preoperatively. Prophylaxis against deep venous thrombosis with either low molecular weight heparin or compression stockings is indicated. ABCFigure 32-22. An endoscopic sphincterotomy. A. The sphincterotome in place. B. Completed sphincterotomy. C. Endoscopic picture of ampulla before and after sphincterotomy.Brunicardi_Ch32_p1393-p1428.indd 141111/02/19 2:43 PM 1412SPECIFIC CONSIDERATIONSPART IIThe patient should be instructed to empty their bladder before coming to the operating room to avoid the need for urinary cath-eterization. An orogastric tube can be placed if the stomach is distended with gas, but it is generally removed at the end of the operation.Laparoscopic Cholecystectomy. The patient is typically positioned supine with the operating surgeon standing at the patient’s left side. Split-leg positioning with the surgeon stand-ing between the patient’s legs can also provide ergonomic access to the right upper quadrant. Tucking one arm can be helpful if a cholangiogram is planned to allow easier maneu-vering of the fluoroscopy machine around the patient. Pneu-moperitoneum is established with carbon dioxide gas, either with an open technique (Hasson), optical viewing trocar, or closed-needle technique (Veress). Typical access is at the supra-umbilical region, though in the case of previous surgery or scars, alternate access sites should be considered. Once an adequate pneumoperitoneum is established, a 5or 10-mm trocar is inserted through the supraumbilical incision, through which a 5or 10-mm 30° laparoscope is introduced. Traditionally, three additional ports are then placed with a 10or 12-mm port in the epigastrium, a 5-mm port in the right midclavicular line, and a 5-mm port in the right flank (Fig. 32-23). Additional ports may be placed as needed to aid with retraction in difficult cases.Through the lateral-most port, the assistant uses a locking instrument to grasp the gallbladder fundus and retract it over the liver edge and upward towards the patient’s right shoulder. This will help visualize the body of the gallbladder and the hilar area. Exposure may be facilitated by placing the patient ABFCEDFigure 32-23. Laparoscopic cholecystectomy. A. The trocar placement. B. The fundus has been grasped and retracted cephalad to expose the proximal gallbladder and the hepatoduodenal ligament. Another grasper retracts the gallbladder infundibulum posterolaterally to better expose the triangle of Calot (hepatocystic triangle bound by the common hepatic duct, cystic duct, and liver margin). C. Intraoperative photo of the critical view of safety. The hepatocystic triangle has been cleared of fat and fibrous tissue, the lower one-third of the gallbladder is separated from the liver to expose the cystic plate, and two and only two structures are seen entering the gallbladder. D. A clip is being placed on the cystic duct–gallbladder junction. E. A small opening has been made in the cystic duct, and a cholangiogram catheter is being inserted. F. Additional clips have been placed, the cystic duct has been divided, and the cystic artery is being divided.Brunicardi_Ch32_p1393-p1428.indd 141211/02/19 2:43 PM 1413GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32in reverse Trendelenburg position with slight tilting of the table to bring the right side up. Through the midclavicular port, the surgeon uses a grasper in the left hand to retract the gallbladder infundibulum laterally and expose the neck of the gallbladder and hepatoduodenal ligament. It may be necessary to take down any adhesions between the omentum, duodenum, or colon to the gallbladder in order to reach the infundibulum. The majority of the dissection can then be performed with the right hand through the epigastric port, utilizing a combination of electrocautery and sharp and blunt dissection.Dissection starts at the infundibulum of the gallbladder, just above the takeoff of the cystic duct. The peritoneum, fat, and loose areolar tissue around the gallbladder and the cystic duct–gallbladder junction is dissected off and reflected inferi-orly toward the bile duct. This is continued until the gallbladder neck and the proximal cystic duct are clearly identified. The next step is the identification of the cystic artery, which usually runs parallel to and somewhat behind the cystic duct, and often lies behind a prominent lymph node (Lund’s node, often called Calot’s node). At this point, a critical view of safety should be obtained. This requires that the hepatocystic triangle is cleared of fat and fibrous tissue, the lower third of the gallbladder is separated from the liver to expose the cystic plate, and two and only two structures (cystic duct and cystic artery) are going into the gallbladder (see Fig. 32-19).54 At this point, an intraopera-tive cholangiogram can be performed if indicated (see “Intraop-erative Cholangiogram” section).With a critical view of safety obtained, the cystic duct and artery are clipped with two clips at the base and one clip on the gallbladder side. They can then be safely divided. Sometimes, a very dilated cystic duct may be too large for clips. Such ducts can be successfully managed by ligation with an endoloop, lapa-roscopic stapler, or suture closure. Finally, the gallbladder is dissected off the liver bed using electrocautery while watching for potential abnormal posterior branches of ducts or arteries. Before the gallbladder is completely removed from the liver edge, it can be used as a retractor for a final evaluation of the operative field. The surgeon should be sure to evaluate for bleed-ing points or bile staining, and confirm placement of the clips on the cystic duct and artery. The gallbladder is then divided from its final attachments and removed either through the epigastric or umbilical incision, often with the aid of a retrieval bag. The fascial defect and skin incision may need to be enlarged in order to remove the specimen, particularly if the stones are large or the gallbladder is very inflamed. Any bile or blood that has accumulated during the procedure should be cleaned away, and if stones were spilled, they should be retrieved and removed. If the gallbladder was severely inflamed or gangrenous, or if any bile or blood is expected to accumulate, a closed-suction drain can be placed through one of the 5-mm ports and left underneath the right liver lobe close to the gallbladder fossa, though this is not routinely required.Open Cholecystectomy. The same surgical principles apply for laparoscopic and open cholecystectomies. Open cholecystec-tomy has become an uncommon procedure, usually performed either as a conversion from laparoscopic cholecystectomy or as a second procedure in patients who require laparotomy for another reason. The approach can either be through a midline laparotomy, or more commonly through a right subcostal inci-sion. The gallbladder is dissected free from the liver bed, usu-ally starting at the fundus and working proximally toward the hepatocystic triangle. Once the cystic artery and cystic duct have been dissected and clearly identified, they are ligated and divided, and the gallbladder is removed. In particularly difficult cases, in which the gallbladder is partially obliterated or ductal or arterial anatomy cannot be identified, a partial cholecystec-tomy may be performed. This includes removal of as much gall-bladder mucosa as possible and attempted closure of the cystic duct stump with wide drainage of the area.Intraoperative Cholangiogram. Intraoperative cholangio-gram is an optional but valuable tool for evaluating the extra-hepatic bile ducts, identifying common bile duct stones, or clarifying aberrant ductal anatomy. The use of routine versus selective cholangiography remains a topic of debate with a lack of definitive evidence on either side.55-57 However, routine intra-operative cholangiography will detect stones in approximately 7% of patients, and it assists with outlining anatomy and detect-ing injury.58 Selective intraoperative cholangiogram should be performed when the patient has a history of abnormal liver func-tion tests, pancreatitis, jaundice, a large duct and small stones, a dilated duct on preoperative ultrasonography, or if preoperative endoscopic cholangiography for the aforementioned reasons was unsuccessful. Although there is no consensus recommenda-tion on the use of routine versus selective cholangiography, all surgeons performing cholecystectomy should be familiar with the procedure. If a cholangiogram is to be performed, a clip is placed on the proximal cystic duct, and a small incision is made on its anterior surface, just inferior to the clip. A cholangiogram catheter is passed into the cystic duct and secured with a clamp or clip. The fluoroscopy machine is then positioned over the patient and a cholangiogram performed by injection of contrast through the cholangiocatheter during live fluoroscopic dynamic imaging. An ideal cholangiogram includes filling of the right and left hepatic ducts, emptying into the duodenum, and no visualized filling defects (Fig. 32-24). Care must be taken not to introduce air bubbles into the system during contrast injec-tion as these will appear as filling defects on the cholangiogram images. If no contrast is visualized in the duodenum, a dose of glucagon can be utilized to relax the sphincter of Oddi and facilitate contrast flow. Once the cholangiogram is completed, the catheter is removed. Laparoscopic ultrasonography is as accurate as intraoperative cholangiography in detecting com-mon bile duct stones, and it is less invasive. However, it requires more skill to perform and interpret and is not always readily available.59Common Bile Duct ExplorationCommon bile duct stones that are detected preor intraopera-tively may be managed with common bile duct exploration (CBDE) at the time of the cholecystectomy. While preopera-tive ERCP is also an appropriate option for known bile duct stones, laparoscopic CBDE can be used as a primary approach to choledocholithiasis safely and with good outcomes, even in higher risk populations such as the elderly.60 If stones in the duct are small, they may sometimes be simply flushed into the duo-denum with saline irrigation via the cholangiography catheter. This can be facilitated by the administration of IV glucagon to relax the sphincter of Oddi. If irrigation is unsuccessful, several options exist to clear the duct, including fluoroscopic or endo-scopic approaches.With access to the cystic duct by a small ductotomy, a bal-loon catheter is used to dilate the cystic duct, and a wire basket can be passed down the common bile duct under fluoroscopic Brunicardi_Ch32_p1393-p1428.indd 141311/02/19 2:43 PM 1414SPECIFIC CONSIDERATIONSPART IIguidance to catch and remove the stones (Fig. 32-25). Alter-nately, endoscopic evaluation with a flexible choledocho-scope will allow for direct visualization and retrieval of the stones within the common duct. To do this, reliable catheter access must be obtained with an introducer sheath placed either through one of the laparoscopic ports or a new stab incision in the anterior abdominal wall. The cystic duct should first be dilated with a small balloon catheter to allow for passage of the introducer and scope and for effective retrieval of larger stones. Once the scope is within the common bile duct, irrigation is used to distend the lumen. Stones may then be caught in a wire basket under direct visualization or simply pushed into the duo-denum. Once the common bile duct has been cleared of stones, the cystic duct is ligated below the level of the ductotomy and divided, and the cholecystectomy is completed.While the cystic duct is the preferred route of access for common bile duct exploration, occasionally an incision into the common bile duct itself (choledochotomy) is necessary. The flexible choledochoscope is then passed into the duct for visu-alization and clearance of stones. The choledochotomy can be closed primarily of the duct is very large, or over a T-tube. If available, common bile duct exploration can be highly advan-tageous as it provides the opportunity to treat the entirety of the disease in a single event, rather that subjecting patients to multiple procedures. However, the procedure can be techni-cally challenging to perform and requires the availability of the proper equipment and surgical expertise.61Common Bile Duct Drainage ProceduresIn very rare cases in which stones or obstructions cannot be cleared by either ERCP with sphincterotomy or CBDE, and the patient is suffering clinical effects from their common duct stones, an additional choledochal drainage procedure may become necessary. In the case of an open operation, transduodenal sphincterotomy can be attempted by incising the duodenum transversely and cutting the sphincter of Oddi at the 11 o’clock position, taking care to avoid injury to the pancreatic duct. The impacted stones can then be manually removed or simply allowed to pass through the sphincterotomy.Bypass procedures can also be used to restore continu-ity of bile flow in the setting of irretrievable impacted stones. For short distance bypasses, a Choledochoduodenostomy is performed by mobilizing the second part of the duodenum (a Kocher maneuver) and anastomosing it side to side with the common bile duct (Fig. 32-26A-C). If the distance is too great to safely complete a choledochoduodenostomy without ten-sion, a choledochojejunostomy can be done by bringing up a roughly 45-cm limb of jejunum and anastomosing it end to side to the common bile duct (Fig. 32-26D-E). If the entirety of the extrahepatic biliary tree must be bypassed, hepaticojejunostomy allows for drainage of the hepatic ducts directly a loop of jeju-num (Fig. 32-26F-G). These choledochal drainage procedures can also be used to manage common bile duct strictures or as a palliative procedure for malignant obstruction in the periampul-lary region.OTHER BENIGN DISEASES AND LESIONSBiliary Dyskinesia and Sphincter of Oddi DysfunctionBiliary dyskinesia is an umbrella term that refers to disorders affecting the normal motility and function of the gallbladder and sphincter of Oddi. These disorders are becoming increas-ingly recognized as improvements in imaging allow for more detailed evaluations of biliary tract function. Patients with bili-ary dyskinesia may present with typical biliary type symptoms, but without evidence of stones or sludge on abdominal imaging. ABFigure 32-24. A. An intraoperative cholangiogram. The bile ducts are of normal size, with no intraluminal filling defects. The left and the right hepatic ducts are visualized, the distal common bile duct tapers down, and the contrast empties into the duodenum. Cholangiography grasper that holds the catheter and the cystic duct stump partly projects over the common hepatic duct. B. An intraoperative cholangiogram showing a common bile duct stone (arrow) with very little contrast passing into the duodenum.Brunicardi_Ch32_p1393-p1428.indd 141411/02/19 2:43 PM 1415GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32A decreased gallbladder ejection fraction on HIDA scanning (EF <35%) is considered diagnostic of biliary dyskinesia. In these patients, studies suggest that symptoms will be improved or resolved by cholecystectomy in up to 90% of cases.62Sphincter of Oddi dysfunction can occur as a primary pre-sentation of episodic biliary type pain with abnormal liver func-tion tests or as recurrent biliary type pain after cholecystectomy. More severe cases may present with recurrent jaundice or pan-creatitis. If other causes are ruled out, such as retained stones, strictures or periampullary tumors, a stenotic or dyskinetic sphincter of Oddi should be suspected. A benign stenosis of the outlet of the common bile duct is usually associated with inflam-mation, fibrosis, or muscular hypertrophy. The pathogenesis is unclear, but trauma from the passage of stones, sphincter motil-ity disorders, and congenital anomalies have been suggested. A dilated common bile duct that is difficult to cannulate during ERCP or delayed emptying of contrast from the biliary tree after ERCP are useful diagnostic features. Ampullary manometry and specific provocation tests are available in specialized units to aid in the diagnosis. Once identified, sphincterotomy will typi-cally yield good results.63Acalculous CholecystitisAcalculous cholecystitis is an acute inflammation of the gall-bladder that occurs in the absence of gallstones. It is a rare entity that typically develops in critically ill patients in the intensive care unit.64 Patients on parenteral nutrition, with extensive burns, sepsis, major operations, multiple trauma, or prolonged illness with multiple organ system failure are at risk for developing acalculous cholecystitis. The cause is unknown, but gallblad-der distention, bile stasis, and ischemia have been implicated as causative factors. After resection, pathologic examination of the gallbladder wall after an episode of acalculous cholecystitis reveals edema of the serosa and muscular layers, with patchy thrombosis of arterioles and venules.65The ability to recognize the symptoms and signs of acalculous cholecystitis can depend on the condition and mental status of the patient, but acalculous cholecystitis can be similar to acute calculous cholecystitis, with right upper quadrant pain and tenderness, fever, and leukocytosis. In the sedated or unconscious patient, the clinical features are often masked, but fever and elevated WBC count, as well as eleva-tion of alkaline phosphatase and bilirubin, are indications for AIIIIIIEBFGCDFigure 32-25. Laparoscopic common bile duct exploration. I. Transcystic basket retrieval using fluoroscopy. A. The basket has been advanced past the stone and opened. B. The stone has been entrapped in the basket, and together, they are removed from the cystic duct. II. Transcystic choledochoscopy and stone removal. C. The basket has been passed through the working channel of the scope, and the stone is entrapped under direct vision. D. Entrapped stone. E. A view from the choledochoscope with stone captured in basket. III. Choledochotomy and stone removal. F. A small incision is made in the common bile duct. G. The common bile duct is cleared of stones.Brunicardi_Ch32_p1393-p1428.indd 141511/02/19 2:43 PM 1416SPECIFIC CONSIDERATIONSPART IIAIIIIIIBCDEFGFigure 32-26. Biliary enteric anastomoses. There are three types. I. Choledochoduodenostomy. A. The distal common bile duct is opened longitudinally, as is the duodenum. B. Interrupted sutures are placed between the common bile duct and the duodenum. C. Completed cho-ledochoduodenostomy. II. Choledochojejunostomy. D. The common bile duct and small bowel are divided. E. A limb of jejunum is brought up in a Roux-en-Y configuration and anastomosed to the bile duct. III. Hepaticojejunostomy. F. The entire extrahepatic biliary tree has been resected and the reconstruction completed with a Roux-en-Y limb of jejunum. G. Percutaneous transhepatic stents are placed across hepati-cojejunostomy (optional).Brunicardi_Ch32_p1393-p1428.indd 141611/02/19 2:43 PM 1417GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32further investigation. Ultrasonography is usually the diagnos-tic test of choice, as it can be done bedside in the intensive care unit. It can demonstrate the distended gallbladder with thickened wall, biliary sludge, pericholecystic fluid, and the presence or absence of abscess formation. CT scanning can aid in the diagnosis of acalculous cholecystitis and addition-ally allows a more general evaluation of the abdomen and chest to rule out other sources of infection. A HIDA scan can also be useful if it shows nonvisualization of the gallblad-der, but it is less sensitive and can have higher false-positive rates in patients who are in a prolonged fasting state, on total parenteral nutrition, or have liver disease. Once the diagnosis is confirmed, acalculous cholecystitis requires urgent inter-vention as rapid deterioration can occur. This should include early broad-spectrum antibiotics and fluid resuscitation. If the patient is stable to undergo an abdominal operation, lapa-roscopic cholecystectomy is the most definitive treatment, and it can be safely performed even in the setting of severe acute inflammation.64 However, if patients are critically ill and unfit for surgery, percutaneous cholecystostomy is the best treatment choice (see Fig. 32-18). About 90% of patients will improve with a percutaneous cholecystostomy tube. Interval cholecystectomy can be discussed with the patient after they have recovered from their acute illness, but it is not strictly required in the absence of gallstone or other identi-fied gallbladder pathology.Choledochal (Biliary) CystsCholedochal cysts are congenital cystic dilatations of the extra-hepatic and/or intrahepatic biliary tree. They are rare, with an incidence of between 1:100,000 and 1:150,000 in populations of Western countries, but are more common in populations of Eastern countries occurring in as many as 1:1000 individuals. Choledochal cysts affect females three to eight times more often than males. Although frequently found in infancy or childhood, nearly one-half are diagnosed in adults. The cause is unknown, but it is believed that weakness of the bile duct wall and increased pressure secondary to partial biliary obstruction can contribute to biliary cyst formation. More than 90% of patients have an anomalous pancreaticobiliary duct junction, with the pancreatic duct joining the common bile duct outside the duode-nal wall, creating a long common channel (>1.5 cm). This may allow free reflux of pancreatic secretions into the biliary tract, leading to inflammatory changes, increased biliary pressure, and cyst formation. The cysts are lined with cuboidal epithelium and can vary in size from small dilations to giant cystic masses. The typical clinical triad of biliary cysts includes abdominal pain, jaundice, and a palpable mass, though this constellation is seen in less than one-half of patients. Adults may present with chol-angitis. Blood tests will often be normal though elevations of transaminases can be seen in cases of infection or obstruction. Ultrasonography or CT scanning will confirm the diagnosis, but ERCP or MRCP are essential to formally assess the biliary anatomy and to plan the appropriate surgical treatment. The risk of cholangiocarcinoma in patients with choledochal cysts is 20to 30-fold higher than in the general population and varies with the patient’s age and type of cyst. For this reason, excision is recommended whenever possible when high-risk choledochal cysts are diagnosed.Choledochal cysts are classified into five types depend-ing on the location and structure of the cysts. The subcatego-ries of choledochal cysts are defined in Fig. 32-27. Type I cysts (fusiform CBD dilations) are the most common form, account-ing for approximately 50% of cases, and have the highest risk of malignancy (>60%). For types I and II (saccular diverticula of the common bile duct), excision of the cystic dilations in the extrahepatic biliary tree, including cholecystectomy, with either simple cyst excision or duct resection with Roux-en-Y hepaticojejunostomy is ideal. Type III cysts (intraduodenal) cre-ate a treatment challenge as full resection would require pan-creaticoduodenectomy. Given that type III cyst are associated with the lowest malignancy risk of any choledochal cyst (~2%), sphincterotomy and surveillance is generally recommended over formal excision.66 In Type IV (multiple cysts), excision of all cystic tissue and reconstruction is again recommended. For type IVa, which is characterized by multiple cysts with intrahe-patic involvement, additional segmental resection of the liver may be required if intrahepatic stones, strictures, or abscesses are present. Type V choledochal cysts (Caroli disease) are very rare and account for less than 1% of patients with choledochal cysts. These cysts are multiple and can affect the entire liver. In advanced stages, this may result in cirrhosis and liver failure necessitating liver transplantation.Primary Sclerosing CholangitisPrimary sclerosing cholangitis (PSC) is an uncommon disease characterized by inflammatory strictures involving the intrahe-patic and extrahepatic biliary tree. It is a progressive disease that eventually results in secondary biliary cirrhosis. Sometimes, biliary strictures are clearly secondary to bile duct stones, acute cholangitis, previous biliary surgery, or toxic agents, and are termed secondary sclerosing cholangitis. However, primary sclerosing cholangitis is a disease entity of its own, with no clear attributing cause. Autoimmune reaction, chronic low-grade bac-terial or viral infection, toxic reaction, and genetic factors have all been suggested to play a role in its pathogenesis. PSC is commonly associated with other autoimmune diseases includ-ing ulcerative colitis in about two-thirds of patients, Riedel’s thyroiditis, and retroperitoneal fibrosis. The human leukocyte antigen haplotypes HLA-B8, DR3, DQ2, and DRw52A, com-monly found in patients with autoimmune diseases, also are more frequently seen in patients with primary sclerosing chol-angitis than in controls. The mean age of presentation for PSC is 30 to 45 years, and men are affected twice as often as women. Most patients are symptomatic when diagnosed, and may com-plain of intermittent jaundice, fatigue, weight loss, pruritus, or abdominal pain. Initial presentation with acute cholangitis is rare without preceding biliary tract intervention or surgery. A minority of patients are diagnosed incidentally by elevated liver function tests, particular when found in a patient with ulcerative colitis. While the clinical presentation and laboratory results may suggest the PSC, ERCP revealing multiple dilatations and strictures (beading) of the intraand extrahepatic biliary tree confirms the diagnosis. The hepatic duct bifurcation is often the most severely affected segment. A liver biopsy may not be diagnostic, but it is important to determine the degree of hepatic fibrosis and the presence of cirrhosis.The clinical course in sclerosing cholangitis is highly vari-able, but cyclic remissions and exacerbations are typical. Some patients will remain asymptomatic for years, while others prog-ress rapidly with the obliterative inflammatory changes leading to secondary biliary cirrhosis and liver failure. In patients with associated ulcerative colitis, the course of each disease seems independent of the other and colectomy has no effect on the Brunicardi_Ch32_p1393-p1428.indd 141711/02/19 2:43 PM 1418SPECIFIC CONSIDERATIONSPART IIcourse of primary sclerosing cholangitis. Of the patients with sclerosing cholangitis, 10% to 15% will develop cholangio-carcinoma, which can present at any time during the disease process and does not necessarily correlate with the extent of the sclerosing cholangitis or the development of liver failure.67 Cholangiocarcinoma in the setting of PSC frequently follows an aggressive course. Patients need to be followed by serial ERCP and liver biopsies to evaluate for the development of complica-tions such as strictures, cancers, or cirrhosis.There is no known curative treatment for primary scleros-ing cholangitis and medical management is largely supportive. Corticosteroids, immunosuppressants, ursodeoxycholic acid, and antibiotics have been attempted with disappointing results. If biliary strictures occur, they can be dilated and stented either endoscopically or percutaneously. These measures have given short-term improvements in symptoms and serum bilirubin lev-els but provide long-term results in less than half of patients. Surgical management with resection of the extrahepatic biliary tree and hepaticojejunostomy has produced reasonable results in patients with extrahepatic and bifurcation strictures, but without cirrhosis or significant hepatic fibrosis.68 In patients with pri-mary sclerosing cholangitis and advanced liver disease, liver transplantation is the only option. It offers excellent results, with overall 5-year survival as high as 85%. Unfortunately, recur-rence of PSC can occur in 10% to 20% of patients and may require retransplantation.68Bile Duct StricturesBenign bile duct strictures can have numerous causes. However, the vast majority are related to operative injury, most commonly during cholecystectomy. Other causes include fibrosis due to chronic pancreatitis, common bile duct stones, acute cholan-gitis, biliary obstruction due to cholecystolithiasis (Mirizzi’s syndrome), sclerosing cholangitis, cholangiohepatitis, and stric-tures of a biliary-enteric anastomosis. Bile duct strictures that go unrecognized or are improperly managed can lead to severe complications such as recurrent cholangitis, secondary biliary cirrhosis, and portal hypertension.69Bile duct strictures most commonly result in recurrent episodes of cholangitis but may present with isolated jaundice without infection. Liver function tests usually show evidence of cholestasis with elevations of bilirubin and alkaline phosphatase. Imaging with ultrasound or CT can show dilated bile ducts proximal to the stricture, as well as provide informa-tion about the level of the stenosis. MRCP gives more detailed anatomic information about the location and the degree of dilatation. If the diagnosis remains in question, cholangiog-raphy (endoscopic or more rarely percutaneous) will outline the biliary tree, define the stricture and its location, and allow for therapeutic interventions (Fig. 32-28). The treatment of biliary strictures depends on the location and the cause of the stricture. Percutaneous or endoscopic dilatation and/or stent placement will provide good results in more than one half of Type IIIType IIType IType VType IVbType IVaFigure 32-27. Classification of choledochal cysts. Type I, fusiform or cystic dilations of the extrahepatic biliary tree, is the most common type, making up >50% of the choledochal cysts. Type II, saccular diverticulum of an extrahepatic bile duct. Rare, <5% of choledochal cysts. Type III, bile duct dilatation within the duodenal wall (choledochoceles), makes up about 5% of choledochal cysts. Types IVa and IVb, mul-tiple cysts, make up 5% to 10% of choledochal cysts. Type IVa affects both extrahepatic and intrahepatic bile ducts, whereas type IVb cysts affect the extrahepatic bile ducts only. Type V (Caroli disease), intrahepatic biliary cysts, is very rare and makes up 1% of choledochal cysts.Brunicardi_Ch32_p1393-p1428.indd 141811/02/19 2:44 PM 1419GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32patients. For persistent or complex strictures, surgical resec-tion and reconstruction with Roux-en-Y choledochojejunos-tomy or hepaticojejunostomy may be necessary and will result in good or excellent outcomes in 80% to 90% of patients.70 Choledochoduodenostomy may be a choice for strictures in the distal-most part of the common bile duct if a tension free repair can be achieved.INJURY TO THE BILIARY TRACTGallbladderInjuries to the gallbladder itself are uncommon but can occur in the setting of penetrating trauma (gunshot or stab wounds) or medical procedures (liver biopsy or surgery). Nonpenetrating trauma to the gallbladder is extremely rare but can cause con-tusion, avulsion, laceration, rupture, or traumatic cholecystitis. Regardless of the etiology of gallbladder injury, the treatment of choice is cholecystectomy. The prognosis is typically good but depends on the extent of related injury, as damage to nearby organs is not uncommon.Extrahepatic Bile DuctsRarely, penetrating trauma to the extrahepatic bile ducts does occur, and it is usually associated with trauma to other viscera. The vast majority of injuries to the extrahepatic bili-ary system, however, are iatrogenic, usually occurring during cholecystectomy. These injuries are among the most feared and litigated complications in surgery, and can result in sig-nificant morbidity.71,72 Biliary tract injury can also occur during common bile duct exploration, division or mobilization of the duodenum during gastrectomy, or dissection of the hepatic hilum during liver resections.The incidence of bile duct injury during cholecystectomy is estimated to be relatively low (about 0.2%).73 While ini-tial experience with laparoscopic cholecystectomy appeared to show a higher rate of injury to the bile ducts compared to the open approach, these trends appear to be disappearing as lapa-roscopic technology and familiarity with the techniques of the procedure have improved.53 A number of different factors are thought to be associated with bile duct injury during laparo-scopic cholecystectomy. These include acute or chronic inflam-mation, obesity, anatomic variations, and surgical technique. Inadequate exposure or failure to correctly identify structures before ligating or dividing them are the most common causes of significant biliary injury (see “Anatomic Variants” section). Excessive cephalad retraction of the gallbladder may align the cystic duct with the common bile duct, and the latter may then be mistakenly clipped and divided. Careless use of electrocau-tery can lead to thermal injury. Dissection deep into the liver parenchyma may cause injury to intrahepatic ducts, and poor clip placement close to the hilar area or to structures not well visualized can result in a clip across a bile duct.74,75Techniques to avoid injury to the bile ducts during chole-cystectomy are important to understand. The use of an angled, 30° or 45° laparoscope instead of an end-viewing camera will help visualize the anatomic structures, in particular those around the triangle of Calot. An angled scope also will aid in the proper placement of clips. The routine use of intraoperative cholangi-ography during every cholecystectomy as a method to prevent bile duct injury remains controversial.55 Nonetheless, the fre-quency of bile duct injuries is cut by 50% when an intraop-erative cholangiogram is performed. Critical to the successful use of cholangiography is accurate interpretation of the imag-ing. It is important to check that the whole biliary system fills with contrast, including both major ducts on the right and the left hepatic duct, and that there is no extravasation of contrast. While routine use may reduce or limit the extent of injury, or help identify it early, it does not seem to prevent it entirely.76 No consensus recommendation exists on the use of selective versus routine cholangiography.Perhaps the most universally agreed upon method for mitigating the risk of bile duct injury during laparoscopic cholecystectomy is obtaining the critical view of safety. This requires that the hepatocystic triangle is dissected free of fat and fibrous tissue, the lower third of the gallbladder is sepa-rated from the cystic plate, and there are two and only two structures running into the gallbladder, the cystic duct, and the cystic artery (see Fig. 32-23).54 Newer technologies such as fluorescence cholangiography to help identify biliary anatomy intraoperatively have shown promising early results, though large-scale applications remain to be seen.77Diagnosis. Only about 25% of major bile duct injuries (com-mon bile duct or hepatic duct) are recognized at the time of surgery. In these cases, intraoperative bile leakage, recognition of the correct anatomy, or an abnormal cholangiogram led to the diagnosis of a bile duct injury. In those that go unrecognized at the time of surgery, more than half will re-present within the first month postoperatively, though some can present months or years later with strictures, cholangitis, or cirrhosis from a remote bile duct injury.4Figure 32-28. An endoscopic retrograde cholangiography show-ing stricture of the common hepatic duct (arrow). The patient had recently had a laparoscopic cholecystectomy; clips from the opera-tion can be seen projected over the common bile duct.Brunicardi_Ch32_p1393-p1428.indd 141911/02/19 2:44 PM 1420SPECIFIC CONSIDERATIONSPART IIBile duct injuries typically result in either leaks or obstruc-tions related to strictures. Bile leak, most commonly from the cystic duct stump, a transected aberrant right hepatic duct, or a lateral injury to the main bile duct, usually presents with abdom-inal pain, fever, and a mild elevation of liver function tests. If a drain was placed at the time of surgery, bilious fluid may be seen. A CT scan or ultrasound can show either a fluid collection in the gallbladder fossa (biloma), or free fluid (bile) in the peri-toneum (Fig. 32-29A). ERCP (Fig. 32-29B) or HIDA scan can be utilized to better localize the site of the bile leak.Obstruction or stricture should be suspected in patients with progressive elevations of liver function tests or jaundice after cholecystectomy. CT scan or ultrasound can demonstrate the dilated part of the biliary tree, and may identify the level of the bile duct obstruction. MRI cholangiography, if available, provides an excellent, noninvasive delineation of the biliary anatomy both proximal and distal to the injury. Endoscopic or percutaneous cholangiography may also be helpful to confirm the diagnosis, depending on the location and type of injury.Management. The management of bile duct injuries depends on the type, extent, and level of the injury, as well as the tim-ing of its diagnosis. Initial proper treatment of bile duct injury can avoid the development of further complications or bile duct strictures. If an injury is discovered that exceeds the capacity of the available surgical expertise, the patient should be transferred to a tertiary care center. In these situations, drains should be placed in the surgical bed and antibiotics initiated. If a complete obstructive transection has occurred, it may also be necessary to place a percutaneous transhepatic drainage catheter to decom-press the biliary tree prior to transfer.If identified at the time of surgery, bile leaks from small bile ducts (<3 mm) or those draining a single hepatic segment can safely be ligated. If the injured duct is ≥4 mm, however, it is likely to drain multiple segments or an entire lobe and thus needs to be repaired or reimplanted. Minor injuries to the com-mon bile duct or the common hepatic duct are traditionally managed with placement of a T-tube that has been modified by cutting the ends to allow for its placement in and removal from the bile duct (see Fig. 32-18). If the injury is small, the T-tube may be placed through it as if it were a formal choledochotomy. In more extensive injuries, the T-tube should be placed through a separate choledochotomy and the injury closed over the T-tube end to minimize the risk of subsequent stricture formation.Major bile duct injuries identified intraoperatively such as complete transection of the common hepatic or common bile duct are best managed at the time of injury. In many of these major injuries, the bile duct has not only been transected, but a variable length of the duct may have been removed with the surgical specimen. This injury usually requires reconstruction with a biliary-enteric anastomosis, and is best performed as soon as possible following the injury. If there is no or minimal loss of ductal length, a duct-to-duct repair may be done over a T-tube that is placed through a separate incision. In any repair that is chosen, it is critical to perform a tension-free anastomosis to minimize the high risk of postoperative stricture formation.Bile leaks identified postoperatively can usually be man-aged with percutaneous drainage of intra-abdominal fluid col-lections followed by endoscopic biliary stenting. With most leaks, regardless of the location, stenting of the common bile duct will provide a low resistance route for bile flow into the duodenum, decreasing flow through the leak and allowing it to heal. This is particularly effective for leaks from the cystic duct stump. Rarely, surgery is required to repair a large leak if endoscopic interventions have failed or peritonitis is present.Major bile duct injuries diagnosed in the later postopera-tive period may not be amenable to immediate reconstruction due to acute inflammation. They may need to be managed with transhepatic biliary catheter placement for biliary decompres-sion as well as percutaneous drainage of intra-abdominal bile collections, if any. When the acute inflammation has resolved 6 to 8 weeks later, operative repair is performed.Patients with bile duct stricture from an injury or as a sequela of previous repair usually present with either progres-sive elevation of liver function tests or cholangitis. The initial management usually includes endoscopic attempts at dilation or stenting. Balloon dilatation of a stricture usually requires multiple procedures and rarely provides long-term relief. Self-expanding metal or plastic stents can provide temporary or, in the high-risk patient, permanent drainage of the biliary tree. If the stricture is unable to be addressed endoscopically, ABFigure 32-29. A. Computed tomographic scan of a patient with bile leak after cholecystectomy. The short arrows indicate the intraperitoneal collections. Both air and bile are seen in the gallbladder bed (long arrow) as well as a surgical clip. B. An endoscopic retrograde cholangi-ography from the same patient showing contrast extravasation from the cystic duct stump (arrow). Note the filling of the pancreatic duct.Brunicardi_Ch32_p1393-p1428.indd 142011/02/19 2:44 PM 1421GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32percutaneous transhepatic biliary drainage catheter placement may be necessary for decompression, and to define the anat-omy, location and extent of the damage. Definitive treatment of refractory biliary strictures entails resection of the affected segment and reconstruction with a biliary-enteric anastomosis.Outcome. Good results can be expected in the majority of patients with bile duct injuries, with the best results coming when the injury is recognized immediately and repaired by an experienced biliary tract surgeon.78 The perioperative mortality rate is reported to be less than 10%, but common morbidities associated with bile duct repairs include cholangitis, external biliary fistula, bile leak, subhepatic and subphrenic abscesses, and hemobilia. Restenosis of a biliary enteric anastomosis occurs in about 10% of patients, and typically presents within 2 years, but can manifest up to 20 years after the initial procedure. In general, treatment of proximal strictures is associated with a lower success rate than distal ones. The worst results are seen in patients with many operative revisions and in those who have evidence of liver failure or portal hypertension. However, previ-ous repair does not preclude a successful outcome, particularly in patients with good liver function. In the most severe cases, patients with refractory strictures and deteriorating liver func-tion may become candidates for liver transplant.TUMORSCarcinoma of the GallbladderCancer of the gallbladder is a rare malignancy that occurs pre-dominantly in the elderly. It is an aggressive tumor, with a poor prognosis that is usually not diagnosed until it has become advanced and is causing symptoms. The median survival for gallbladder cancer is around 6 months with a reported 5-year survival rate of 5%.79 In a minority of cases, early cancers are identified incidentally following cholecystectomy for cho-lelithiasis, in which case, 5-year survival is over 80%.80Incidence. Gallbladder cancer is the sixth most common GI malignancy in Western countries.80 It accounts for 2% to 4% of all malignant GI tumors, with about 4000 new cases diagnosed annually in the United States. It is two to six times more com-mon in females than males, and the peak incidence is in the seventh decade of life. Its occurrence in random autopsy series is about 0.4%, but 0.3% to 3% of patients undergoing chole-cystectomy for gallstone disease are found incidentally to have gallbladder cancer.80 There are also significant ethnic variations in the incidence of gallbladder cancer, with rates being particu-larly high in native populations of the United States, Mexico, and Chile. The overall incidence of gallbladder cancer in the United States is approximately 1.5 cases per 100,000 residents. For Native American females with gallstones, the incidence is around 7.1 per 100,000. For women in the native populations of Chile, gallbladder cancer occurs in 27.3 per 100,000 individu-als. Asian populations, particularly those of Korean descent, are also at increased risk of developing gallbladder cancer.80Etiology. The pathogenesis of gallbladder cancer has not been fully defined but is likely related to a combination of chronic inflammation, infection, genetics, and environmental exposures such as heavy metals and tobacco. Cholelithiasis is the most important risk factor for gallbladder carcinoma, and up to 85% of patients with carcinoma of the gallbladder have gallstones. However, <3% of patients with gallstones have gallbladder cancer, and the 20-year risk of developing cancer remains low; <0.5% for the overall population and 1.5% for high-risk groups. Larger stones (>3 cm) are associated with a 10-fold increased risk of cancer.81 The risk of developing cancer of the gallblad-der is higher in patients with symptomatic than asymptomatic gallstones, and it is more commonly seen in the setting of cho-lesterol stones.Polypoid lesions of the gallbladder, which are present in as many as 5% of adults, are also associated with increased risk of cancer. This is particularly true for polyps measuring >10 mm, which carry a 25% risk of malignancy.82 Solitary or sessile polys, or those showing rapid growth on serial imaging, particularly if in the presence of gallstones or age >50 are also concerning for malignancy. When such findings are identified, the patient should have their gallbladder removed, even if they are asymptomatic. Polyps that are not removed should be monitored on serial imaging. The finding of a “Porcelain” gallbladder, or dense circumferential calcifications of the gallbladder wall, is associated with an approximately 10% risk of gallbladder car-cinoma. While this condition was previously considered to be an absolute indication for cholecystectomy, more recent studies suggest that given the low rate of malignancy, observation is safe and acceptable. Nevertheless, resection remains a reason-able option, particularly if the patient is symptomatic, and the decision should ultimately be made only after discussing risks and benefits of each approach with the patient.97 Patients with certain types of choledochal cysts also have an increased risk of developing cancer anywhere in the biliary tree, but the inci-dence is highest in the gallbladder and cholecystectomy should be performed with any surgical intervention on the choledochal cyst. Primary sclerosing cholangitis, anomalous pancreatico-biliary duct junction, and exposure to carcinogens (azotoluene, nitrosamines) also are associated with cancer of the gallbladder, and screening with abdominal ultrasound should be considered in these patients.Pathology. Between 80% and 90% of gallbladder cancers are adenocarcinomas. Squamous cell, adenosquamous, oat cell, and other anaplastic lesions rarely occur. The histologic subtypes of gallbladder adenocarcinomas include papillary, nodular, and tubular. Less than 10% are of the papillary type, but these are associated with an overall better outcome, as they are most com-monly diagnosed while localized to the gallbladder. Cancer of the gallbladder can spread through lymphatics, venous drainage, or by direct invasion into the liver parenchyma. Lymphatic flow from the gallbladder drains first to the cystic duct node (Lund’s node or Calot’s node), then pericholedochal and hilar nodes, and finally to the peripancreatic, duodenal, periportal, celiac, and superior mes-enteric artery nodes. The gallbladder veins drain directly into the adjacent liver, usually segments IVb and V, where tumor inva-sion is common (Fig. 32-30). The gallbladder wall differs histo-logically from the intestines in that it lacks a muscularis mucosa and submucosa. Lymphatics are present in the subserosal layer only. Therefore, cancers that have not grown through the muscu-lar layer have minimal risk of nodal disease. Unfortunately, only a small portion of gallbladder cancers (10–25%) are identified while they are still localized to the gallbladder. The majority will already have nodal involvement, extension into adjacent liver, or distant metastasis at the time of diagnosis.80,83Clinical Manifestations and Diagnosis. Signs and symp-toms of carcinoma of the gallbladder are generally indistinguish-able from those associated with cholecystitis and cholelithiasis, and this can lead to delays in treatment or misdiagnosis. These include abdominal discomfort, right upper quadrant pain, nau-sea, and vomiting. Jaundice, weight loss, anorexia, ascites, 5Brunicardi_Ch32_p1393-p1428.indd 142111/02/19 2:44 PM 1422SPECIFIC CONSIDERATIONSPART IIand abdominal masses are less common presenting symptoms. Common misdiagnoses include chronic cholecystitis, acute cho-lecystitis, choledocholithiasis, hydrops of the gallbladder, and pancreatic cancer. Laboratory findings, if abnormal, are most often consistent with biliary obstruction. Ultrasonography often reveals a thickened, irregular gallbladder wall (>3mm) with hypervascularity or a mass replacing the gallbladder. It may also visualize tumor invasion of the liver, lymphadenopathy, or a dilated biliary tree. The sensitivity of ultrasonography in detect-ing gallbladder cancer ranges from 70% to 100%. A CT scan may be helpful in identifying a gallbladder mass and evaluating for nodal spread or local invasion into adjacent organs or vascu-lature. If questions about local invasion remain, MRCP allows for complete assessment of biliary, vascular, nodal, hepatic, and adjacent organ involvement.84 Endoscopic ultrasound (EUS) can be a useful tool in staging and evaluating for local invasion, as well as obtaining tissue diagnosis through fine needle aspiration (FNA). Tissue diagnosis can also be obtained by CT or ultra-sound-guided biopsy of the tumor, though this is not required prior to cholecystectomy if the tumor appears resectable on imaging. In jaundiced patients, a percutaneous transhepatic or endoscopic cholangiogram may be helpful to delineate the extent of biliary tree involvement. The role of PET scanning in gallbladder cancer is yet to be fully defined but can be utilized in both staging and surveillance.Treatment. Surgical resection remains the only curative option for gallbladder cancer. While most patients are unresectable at the time of diagnosis, if preoperative staging suggests a potentially resectable tumor, exploration for tissue diagno-sis, formal pathologic staging, and possible curative resection are warranted.Tumors limited to the lamina propria or muscular layer of the gallbladder (T1) are usually identified incidentally, after laparoscopic cholecystectomy for gallstone disease. There is near universal agreement that simple laparoscopic cholecys-tectomy is an adequate treatment for T1 lesions and results in a near 100% overall 5-year survival rate. When the tumor invades the perimuscular connective tissue without extension beyond the serosa or into the liver (T2 tumors), an extended cholecystectomy should be performed.85 This includes addi-tional resection of liver segments IVb and V, as well as lymph-adenectomy of the cystic duct and pericholedochal, portal, right celiac, and posterior pancreatoduodenal lymph nodes. Given the extent of this operation, an open approach is stan-dard. One-half of patients with T2 tumors are found to have nodal disease on pathologic examination, highlighting the importance of regional lymphadenectomy as part of surgery for T2 cancers.86 For tumors that grow beyond the serosa, or invade the liver or other adjacent organs (T3), there is a higher likelihood of intraperitoneal or distant spread. However, if no peritoneal or nodal involvement is found, complete tumor excision with an extended right hepatectomy and possible cau-date lobectomy with lymphadenectomy must be performed for adequate tumor clearance. In addition, if a T2 or T3 tumor is identified incidentally after laparoscopic cholecystectomy, and the patient is returning to the OR for liver resection and lymph-adenectomy, the previous laparoscopic port sites must also be excised due to the high risk of recurrence in these locations. T4 tumors are those that have grown into major blood vessels or two or more structures outside the liver, and they are typically considered unresectable.Due to the high frequency of late diagnosis, palliative procedures for unresectable cancer, jaundice, or duodenal obstructions remain the most frequently performed surgery for gallbladder cancers. Today, patients with obstructive jaundice can frequently be managed with either endoscopic or percutane-ously placed biliary stents. Various regimens of neoadjuvant, adjuvant, and definitive chemoradiotherapy have been trialed in gallbladder cancer. Overall, benefits have been marginal, but treatment may improve survival time by several months. These therapies can be offered to patients in conjunction with resec-tion for curative intent or as definitive therapy, but no standard recommendation exists for their use.85-87Prognosis. Most patients with gallbladder cancer have unre-sectable disease at the time of diagnosis. The overall 5-year sur-vival rate of all patients with gallbladder cancer is <5%, with a median survival of 6 months.87 However, patients with T1 dis-ease treated with cholecystectomy have an excellent prognosis (85–100% 5-year survival rate). The 5-year survival rate for T2 lesions treated with an extended cholecystectomy (liver segment IVb/V resection) and lymphadenectomy is >70% compared to 25% to 40% for T2 patients treated with simple cholecystec-tomy. Patients with advanced (T3 or T4) but resectable gallblad-der cancer are reported to have 5-year survival rates of 20% to 50%, supporting aggressive resection in those patients who can tolerate surgery. The median survival for patients with distant metastasis at the time of presentation is only 1 to 3 months.Recurrence after resection of gallbladder cancer occurs most commonly in the liver or in the celiac or retropancreatic nodes. The prognosis for recurrent disease is very poor, and the main goal of follow-up is to provide palliative care. The most common problems are pruritus and cholangitis associated with obstructive jaundice, bowel obstruction secondary to carcino-matosis, and pain. Death occurs most commonly secondary to biliary sepsis or liver failure.6Figure 32-30. Computed tomography scan of a patient with gall-bladder cancer. The image shown is at the level of the liver hilum. The portal vein is bifurcating into the left and right portal branch. The tumor has invaded segment IV of the liver (arrowheads) and obstructed the common hepatic duct, resulting in intrahepatic ductal dilatation (arrows).Brunicardi_Ch32_p1393-p1428.indd 142211/02/19 2:44 PM 1423GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32CholangiocarcinomaCholangiocarcinoma is a rare tumor arising from the biliary epithelium and may occur anywhere along the biliary tree. About half are located at the hepatic duct bifurcation (Klatskin tumors), with 40% occurring more distally and 10% being intrahepatic.88 Surgical resection offers the only chance for cure, but unfortunately many patients have advanced disease at the time of diagnosis. Therefore, palliative procedures aimed to provide biliary drainage and prevent liver failure and cholangitis are often the only therapeutic possibilities available.Incidence. The autopsy incidence of bile duct carcinoma is about 0.3%. The overall incidence of cholangiocarcinoma in the United States is about 1 per 100,000 people per year, with approximately 2500 new cases diagnosed annually. The disease has a slight male predominance and an average age of presenta-tion between 50 and 70 years.88Etiology. Most cases of extrahepatic cholangiocarcinoma develop de novo with no identifiable risk factors. However, there is an increased risk of cholangiocarcinoma in patients with choledochal cysts, ulcerative colitis, hepatolithiasis, biliary-enteric anastomoses, hepatitis B and C, cirrhosis, bili-ary tract infections with Clonorchis (liver flukes), and chronic typhoid carriers. Exposure to dietary nitrosamines, Thorotrast, or dioxin also puts patients at increased risk for cholangiocar-cinoma.88 Patients with primary sclerosing cholangitis have a 5% to 10% lifetime risk of developing cholangiocarcinoma with typical disease onset in their 40s. For this reason, these patients require regular screening.67 Features common to most risk factors include biliary stasis, bile duct stones, and infection.Pathology. Over 95% of bile duct cancers are ductal adeno-carcinomas with the vast majority occurring in the extrahepatic biliary tree. Morphologically, they are divided into nodular (the most common type), scirrhous, diffusely infiltrating, or pap-illary. Anatomically, they are divided into distal, perihilar or intrahepatic tumors. Intrahepatic cholangiocarcinomas make up approximately 10% of cases and are typically treated like hepatocellular carcinoma, with hepatectomy when possible and transplant when unresectable. About half of all cholangiocar-cinomas are located in the perihilar region with the remaining 40% occurring more distally in the common bile duct.Perihilar cholangiocarcinomas, also referred to as Klatskin tumors, are further classified based on anatomic loca-tion by the Bismuth-Corlette classification (Fig. 32-31). Type I tumors are confined to the common hepatic duct, but type II tumors involve the bifurcation without involvement of the secondary intrahepatic ducts. Type IIIa and IIIb tumors extend into the right and left secondary intrahepatic ducts, respec-tively. Type IV tumors involve both the right and left secondary intrahepatic ducts.Clinical Manifestations and Diagnosis. Painless jaundice is the most common initial presentation in patients with cholangio-carcinoma. Pruritus, mild right upper quadrant pain, anorexia, fatigue, and weight loss may also be present. Cholangitis is the presenting symptom in about 10% of patients. Except for jaundice, physical examination is usually normal in patients with cholangiocarcinoma. Occasionally, asymptomatic patients are found to have cholangiocarcinoma while being evaluated for elevated liver function tests. Tumor markers, such as CA 125 and carcinoembryonic antigen (CEA), can be elevated in cholangiocarcinoma but tend to be nonspecific because they also increase in other GI and gynecologic malignancies. The tumor marker most commonly used to aid the diagnosis of chol-angiocarcinoma is CA 19-9, which has a sensitivity of 79% and specificity of 98% if the serum value is >129 U/mL.89 How-ever, mild elevations in CA 19-9 can also be seen in cholangitis, biliary obstruction, other GI and gynecologic neoplasms, and patients who lack the Lewis blood type antigen.90The initial workup for suspected cholangiocarcinoma includes abdominal imaging with ultrasound or CT scanning. Perihilar tumors will cause dilatation of the intrahepatic bili-ary tree, but a normal or collapsed gallbladder and extrahepatic bile ducts distal to the tumor. Distal bile duct cancer will lead to dilatation of the extraand intrahepatic bile ducts as well as the gallbladder. Initial imaging is important to determine the level of obstruction and to rule out the presence of bile duct stones as the cause of the obstructive jaundice (Fig. 32-32). It is usually difficult to visualize the tumor itself on ultrasound, CT, or even MRCP, but any of these modalities can provide an outline of biliary anatomy, an estimate of the level of obstruc-tion, evaluation of portal vein patency, and screening for nearby lymphadenopathy. Detailed evaluation of the biliary anatomy and tumor itself is best completed through cholangiography. ERCP is generally adequate, but in cases where the proximal extent of the tumor remains in question, PTC may be required to determine resectability.Tissue diagnosis may be difficult to obtain. Current diag-nostic techniques including fine-needle aspiration (percutaneous or endoscopic), and biliary brushings have been shown to have a low sensitivity in detecting malignancy, anywhere between 15% and 60%. Choledochoscopy with direct visualization and sam-pling of intraluminal masses may be able to improve diagnosis rates but is only available in specialized centers (see Fig. 32-10). Patients with potentially resectable disease should, therefore, be offered surgical exploration based on radiographic findings and clinical suspicion.91Type IIIbType IIType IType IVType IIIaFigure 32-31. Bismuth-Corlette classification of perihilar bile duct tumors (Klatskin tumors).Brunicardi_Ch32_p1393-p1428.indd 142311/02/19 2:44 PM 1424SPECIFIC CONSIDERATIONSPART IITreatment. Surgical excision is the only potentially cura-tive treatment for cholangiocarcinoma. In the past one to two decades, improvements in surgical techniques have resulted in lower mortality and better outcomes for patients undergoing aggressive surgical excision for cholangiocarcinoma.92Despite improvements in ultrasonography, CT scanning, and MRI, more than one-half of patients who are explored are found to have peritoneal implants, nodal or hepatic metastasis, or locally advanced disease that precludes resection. Patients suspected of having resectable disease should first undergo diagnostic laparoscopy. Those who are found to have previously unidentified metastatic disease should undergo cholecystectomy and surgical bypass for biliary decompression.93For curative resection, the location and local exten-sion of the tumor dictates the extent of the surgery required. Distal bile duct tumors are often resectable but may require pancreaticoduodenectomy (Whipple procedure). For patients with distal bile duct cancer found to be unresectable on sur-gical exploration, Roux-en-Y hepaticojejunostomy, chole-cystectomy, and gastrojejunostomy to prevent gastric outlet obstruction should be performed. Perihilar tumors involving the bifurcation or proximal common hepatic duct (Bismuth-Corlette type I or II) with no signs of vascular involvement are candidates for local tumor excision with portal lymphadenec-tomy, cholecystectomy, common bile duct excision, and bilat-eral Roux-en-Y hepaticojejunostomies. If the tumor involves the right or left hepatic duct (Bismuth-Corlette type IIIa or IIIb), right or left hepatic lobectomy, respectively, should also be performed. Frequently, resection of the adjacent caudate lobe is required because of direct extension into caudate bili-ary radicals or parenchyma.91 Type IV Klatskin tumors, those with more extensive involvement of both hepatic ducts and intrahepatic spread, are often considered unresectable or only treatable with liver transplantation.The best outcomes in perihilar cholangiocarcinoma are seen in patients who undergo neoadjuvant chemoradiation followed by liver transplantation. However, there are very strict inclusion criteria for transplantation, and few patients qualify.88 Patients with primary sclerosing cholangitis who develop chol-angiocarcinoma should be treated with liver transplant when-ever possible.Nonoperative biliary decompression can be performed for patients with unresectable disease on initial presentation. Endoscopic placement of expandable metal stents is often the preferred approach. For very proximal or intrahepatic tumors, percutaneous drainage catheters may be necessary to fully decompress the biliary tree (see Fig. 32-12). There is a sig-nificantly higher risk of cholangitis in patients with drainage catheters or stents compared to those with surgical bypasses. In addition, stent occlusion is not uncommon. Nevertheless, operative intervention is not warranted in patients with meta-static disease.94There is no proven role for adjuvant chemotherapy in the treatment of cholangiocarcinoma. Adjuvant radiation therapy has also not been shown to increase either quality of life or survival in resected patients. Patients with unresect-able disease can be offered palliative chemotherapy, typically with gemcitabine and cisplatin, but the response rates are low (10–20%), and the survival benefit is marginal. The combina-tion of radiation and chemotherapy may be more effective than either treatment alone for unresectable disease, but no data from randomized trials are available. Giving chemoradiation to these patients can be difficult because of the high incidence of cholangitis. External-beam radiation has not been shown to be an effective treatment for unresected disease. The use of interstitial (intraoperative) radiation, brachytherapy with iridium-192 via percutaneous or endoscopic stents, and com-bined interstitial and external-beam radiation for unresectable cholangiocarcinoma has been reported with some encouraging results. However, no randomized, prospective trials have been reported.91 Photodynamic therapy has been proposed as a palliative measure for patients with unresectable disease and ABFigure 32-32. A. An endoscopic retrograde cholangiogram in a patient with cancer of the common hepatic duct (arrowheads). The common bile duct is of normal size, as is the cystic duct (arrow), but the proximal biliary tree is dilated. The gallbladder is not visualized because of tumor obstructing its neck. B. An ultrasound from the same patient showing dilated ducts and tumor obstructing the common hepatic duct (arrow). The walls of the bile ducts adjacent to the obstruction are thickened by tumor infiltration (arrowheads).Brunicardi_Ch32_p1393-p1428.indd 142411/02/19 2:44 PM 1425GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32has been found to prolong survival and improve quality of life in patients with biliary stents.95,96Prognosis. Most patients with perihilar cholangiocarcinoma present with advanced, unresectable disease. Median survival in this population is between 5 and 8 months. The most common causes of death are hepatic failure and cholangitis. The overall 5-year survival rate for patients with resectable perihilar cholan-giocarcinoma is between 10% and 30%, but for patients with neg-ative margins, it may be as high as 40%. The operative mortality for perihilar cholangiocarcinoma is 6% to 8%. Patients with distal cholangiocarcinoma are more likely to have resectable disease and improved prognosis compared to perihilar cholangiocarci-noma. The overall 5-year survival rate for resectable distal dis-ease is 30% to 50%, and the median survival is 32 to 38 months. Patients who receive liver transplantation for cholangiocarcinoma can experience 5-year disease free survival rates as high as 68%.The greatest risk factors for recurrence after resection are the presence of positive margins and lymph node–positive tumors. Therapy for recurrent disease concentrates on palliation of symptoms and additional surgery is not recommended for patients with recurrent disease.REFERENCESEntries highlighted in bright blue are key references. 1. Clemente CD. Gray’s Anatomy. Philadelphia: Lea & Febiger; 1985:132. 2. Klein AS, Lillemoe KD, Yeo CJ, et al. Liver, biliary tract, and pancreas. In: O’Leary JP, ed. Physiologic Basis of Surgery. Baltimore: Williams & Wilkins; 1996:441. 3. Molmenti EP, Pinto PA, Klein J, et al. Normal and variant arte-rial supply of the liver and gallbladder. Pediatr Transplant. 2003;7:80-82. 4. Boyer J. Bile secretion—models, mechanisms, and malfunc-tions. A perspective on the development of modern cellular and molecular concepts of bile secretion and cholestasis. J Gastro-enterol. 1996;31:475-481. 5. Geoghegan J, Pappas TN. Clinical uses of gut peptides. Ann Surg. 1997;225:145-154. 6. McDonnell CO, Bailey I, Stumpf T, et al. The effect of cho-lecystectomy on plasma cholecystokinin. Am J Gastroenterol. 2002;97:2189-2192. 7. Woods CM, Mawe GM, Toule J, Saccone GTP. The sphinc-ter of Oddi: understanding its control and function. Neuro-gastroenterol Motil. 2005;17(supp 1):31-40. 8. Yokohata K, Tanaka M. Cyclic motility of the sphincter of Oddi. J Hepato-Biliary-Pancreatic Surg. 2000;7:178-182. 9. Lee HJ, Choi BI, Han JK, et al. Three-dimensional ultraso-nography using the minimum transparent mode in obstruc-tive biliary diseases: early experience. J Ultrasound Med. 2002;21:443-453. 10. Ralls PW, Jeffrey RB, Jr, Kane RA, et al. Ultrasonography. Gastroenterol Clin North Am. 2002;31:801-825. 11. O’Connor OJ, Maher MM. Imaging in cholecystitis. AJR Am J Roentgenol. 2011;196:W367-W374. 12. Wexler RS, Greene GS, Scott M. Left hepatic and common hepatic ductal bile leaks demonstrated by Tc-99m HIDA scan and percutaneous transhepatic cholangiogram. Clin Nucl Med. 1994;19:59-60. 13. Richmond BK, DiBaise J, Ziessman H. Utilization of cholecys-tokinin cholescintigraphy in clinical practice. J Am Coll Surg. 2013;217(2):317-323. 14. Magnuson TH, Bender JS, Duncan MD, et al. Utility of mag-netic resonance cholangiography in the evaluation of biliary obstruction. J Am Coll Surg. 1999;189:63-72. 15. Liu TH, Consorti ET, Kawashima A, et al. Patient evaluation and management with selective use of magnetic resonance cholangiography and endoscopic retrograde cholangiopan-creatography before laparoscopic cholecystectomy. Ann Surg. 2001;234:33-40. 16. Glomsaker T, Hoff G, KvalØy JT, et al. Patterns and predictive factors of complications after endoscopic retrograde cholangio-pancreatography. Br J Surg. 2013;100(3):373-380. 17. Dumonceau JM, Andriulli A, Elmunzer BJ, et al. Prophylaxis of post-ERCP pancreatitis: European Society of Gastrointestinal Endoscopy (ESGE) Guideline—updated June 2014. Endoscopy. 2014;46(9):799-815. 18. Tischendorf JJ, Kruger M, Trautwein C, et al. Cholangioscopic characterization of dominant bile duct stenoses in patients with primary sclerosing cholangitis. Endoscopy. 2006;38:665-669. 19. Hui CK, Lai KC, Ng M, et al. Retained common bile duct stones: a comparison between biliary stenting and complete clearance of stones by electrohydraulic lithotripsy. Aliment Pharmacol Ther. 2003;17:289-296. 20. Tsuyuguchi T, Saisho H, Ishihara T, et al. Long-term follow-up after treatment of Mirizzi syndrome by peroral cholangioscopy. Gastrointest Endosc. 2000;52:639-644. 21. Fabbri C, Luigiano C, Lisotti A, et al. Endoscopic ultrasound-guided treatments: are we getting evidence based—a systematic review. World J Gastroenterol. 2014;20(26):8424-8448. 22. Stinton LM, Shaffer EA. Epidemiology of gallbladder disease: cholelithiasis and cancer. Gut Liver. 2012;6(2):172-187. 23. Nakeeb A, Comuzzie AG, Martin L, et al. Gallstones: genetics versus environment. Ann Surg. 2002;235:842-849. 24. Sakorafas GH, Milingos D, Peros G. Asymptomatic choleli-thiasis: is cholecystectomy really needed? A critical reappraisal 15 years after the introduction of laparoscopic cholecystectomy. Dig Dis Sci. 2007;52:1313-1325. 25. Attili AF, De Santis A, Capri R, et al. The natural history of gallstones: the GREPCO experience. The GREPCO Group. Hepatology. 1995;21:655-660. 26. Strasberg SM. The pathogenesis of cholesterol gallstones a review. J Gastrointest Surg. 1998;2:109-125. 27. Stewart L, Oesterle AL, Erdan I, et al. Pathogenesis of pigment gallstones in Western societies: the central role of bacteria. J Gastrointest Surg. 2002;6:891-903. 28. Trowbridge RL, Rutkowski NK, Shojania KG. Does this patient have acute cholecystitis? JAMA. 2003;289:80-86. 29. Duncan CB, Riall TS. Evidence-based current surgical prac-tice: calculous gallbladder disease. J Gastrointest Surg. 2012;16(11):2011-2025. 30. Menzo EL, Schnall R, Von Rueden D. Lithotripsy in the laparo-scopic era. JSLS. 2005;9(3):358-361. 31. Weber DM. Laparoscopic surgery: an excellent approach in elderly patients. Arch Surg. 2003;138:1083-1088. 32. Kaoutzanis C, Davies E, Leichtle SW, et al. Abdominal ultra-sound versus hepato-imino diacetic acid scan in diagnos-ing acute cholecystitis—what is the real benefit? J Surg Res. 2014:1;188(1):44-52. 33. Hunter JG. Acute cholecystitis revisited: get it while it’s hot. Ann Surg. 1998;227(4):468-469. 34. Ansaloni L, Pisano M, Coccolini F, et al. 2016 WSES guidelines on acute calculous cholecystitis. World J Emerg Surg. 2016;11:25. 35. Sakpal SV, Bindra SS, Chamberlain RS. Laparoscopic cho-lecystectomy conversion rates two decades later. JSLS. 2010;14(4):476-483. 36. Cherng N, Witkowski E, Sneider EB, et al. Use of cholecystos-tomy tubes in the management of patients with primary diagno-sis of acute cholecystitis. JACS. 2012;214:196-201. 37. Chikamori F, Kuniyoshi N, Shibuya S, et al. Early scheduled laparoscopic cholecystectomy following percutaneous transhe-patic gallbladder drainage for patients with acute cholecystitis. Surg Endosc. 2002;16:1704-1707.Brunicardi_Ch32_p1393-p1428.indd 142511/02/19 2:44 PM 1426SPECIFIC CONSIDERATIONSPART II 38. Ko C, Lee S. Epidemiology and natural history of common bile duct stones and prediction of disease. Gastrointest Endosc. 2002;56:S165-169. 39. Giljaca V, Gurusamy KS, Takwoingi Y, et al. Endoscopic ultra-sound versus magnetic resonance cholangiopancreatography for common bile duct stones. Cochrane Database Syst Rev. 2015:26;(2):CD011549. 40. Tranter S, Thompson M. Comparison of endoscopic sphincter-otomy and laparoscopic exploration of the common bile duct. Br J Surg. 2002;89:1495-1504. 41. Dasari BV, Tan CJ, Gurusamy KS, et al. Surgical versus endo-scopic treatment of bile duct stones. Cochrane Database Syst Rev. 2013;(12):CD003327. 42. Lilly MC, Arregui ME. A balanced approach to choledocholi-thiasis. Surg Endosc. 2001;15:467-472. 43. Lipsett PA, Pitt HA. Acute cholangitis. Front Biosci. 2003;8:S1229-S1239. 44. Lillemoe KD. Surgical treatment of biliary tract infections. Am Surg. 2000;66:138-144. 45. Li VK, Yum JL, Yeung YP. Optimal timing of elective lapa-roscopic cholecystectomy after acute cholangitis and sub-sequent clearance of choledocholithiasis. Am J Surg. 2010;200(4):483-488. 46. Johnstone M, Marriott P, Royle TJ, et al. The impact of timing of cholecystectomy following gallstone pancreatitis. Surgeon. 2014;12(3):134-140. 47. Nuño-Guzmán CM, Marín-Contreras ME, Figueroa-Sánchez M, Corona JL. Gallstone ileus, clinical presentation, diag-nostic and treatment approach. World J Gastrointest Surg. 2016;8(1):65-76. 48. Sperling RM, Koch J, Sandhu JS, et al. Recurrent pyogenic chol-angitis in Asian immigrants to the United States: natural history and role of therapeutic ERCP. Dig Dis Sci. 1997;42:865-871. 49. Thinh NC, Breda Y, Faucompret S, et al. Oriental biliary lithia-sis. Retrospective study of 690 patients treated surgically over 8 years at Hospital 108 in Hanoi (Vietnam). Med Trop (Mars). 2001;61:509-511. 50. Akhan O, Akinci D, Ozmen MN. Percutaneous cholecystos-tomy. Eur J Radiol. 2002;43:229-236. 51. Khaitan L, Apelgren K, Hunter J, et al. A report on the Society of American Gastrointestinal Endoscopic Surgeons (SAGES) Outcomes Initiative: what have we learned and what is its potential? Surg Endosc. 2003;17:365-370. 52. Richards C, Edwards J, Culver D, et al. Does using a laparo-scopic approach to cholecystectomy decrease the risk of surgi-cal site infection? Ann Surg. 2003;237:358-362. 53. Halbert C, Pagkratis S, Yang J, et al. Beyond the learning curve: incidence of bile duct injuries following laparoscopic cholecys-tectomy normalize to open in the modern era. Surg Endosc. 2016;30(6):2239-2243. 54. The SAGES Safe Cholecystectomy Program. Strategies for minimizing bile duct injuries: adopting a universal culture of safety in cholecystectomy. Available at:https://www.sages.org/safe-cholecystectomy-program/. Accessed July 28, 2018. 55. Ford JA, Soop M, Du J, Loveday BP, Rodgers M. Systematic review of intraoperative cholangiography in cholecystectomy. Br J Surg. 2012;99(2):160-167. 56. Biffl W, Moore E, Offner P, et al. Routine intraoperative ultra-sonography with selective cholangiography reduces bile duct complications during laparoscopic cholecystectomy. J Am Coll Surg. 2001;193:272-280. 57. Ragulin-Coyne E, Witkowski ER, Chau Z, et al. Is routine intra-operative cholangiogram necessary in the twenty-first century? A national view. J Gastrointest Surg. 2013;17(3):434-442. 58. Flum DR, Dellinger EP, Cheadle A, et al. Intraoperative chol-angiography and risk of common bile duct injury during chole-cystectomy. JAMA. 2003;289:1639-1644. 59. Halpin VJ, Dunnegan D, Soper NJ. Laparoscopic intracorporeal ultrasound versus fluoroscopic intraoperative cholangiography: after the learning curve. Surg Endosc. 2002;16:336-341. 60. Zheng C, Huang Y, Xie E, Xie D, Peng Y, Wang X. Laparo-scopic common bile duct exploration: a safe and definitive treat-ment for elderly patients. Surg Endosc. 2017;31(6):2541-2547. 61. Petelin JB. Laparoscopic common bile duct exploration. Surg Endosc. 2003:Nov;17(11):1705-1715. 62. George J, Baillie J. Biliary and gallbladder dyskinesia. Curr Treat Options Gastroenterol. 2007;10(4):322-327. 63. Linder JD, Klapow JC, Linder SD, et al. Incomplete response to endoscopic sphincterotomy in patients with sphincter of Oddi dysfunction: evidence for a chronic pain disorder. Am J Gastro-enterol. 2003;98:1738-1743. 64. Huffman JL, Schenker S. Acute acalculous cholecystitis: a review. Clin Gastroenterol Hepatol. 2010;8(1):15-22. 65. Ryu JK, Ryu KH, Kim KH. Clinical features of acute acalcu-lous cholecystitis. J Clin Gastroenterol. 2003;36:166-169. 66. Lipsett PA, Pitt HA. Surgical treatment of choledochal cysts. J Hepatobiliary Pancreat Surg. 2003;10:352-359. 67. Hirschfield GM, Karlsen TH, Lindor KD, Adams DH. Primary sclerosing cholangitis. Lancet. 2013;382(9904):1587-1599. 68. Michales A, Levy C. Endoscopic and surgical manage-ment of primary sclerosing cholangitis. Medscape J Med. 2008;10(10):242. 69. Lillemoe KD, Melton GB, Cameron JL, et al. Postoperative bile duct strictures: Management and outcome in the 1990s. Ann Surg. 2000;232:430-431. 70. Melton GB, Lillemoe KD. The current management of postop-erative bile duct strictures. Adv Surg. 2002;36:193-221. 71. Archer SB, Brown DW, Smith CD, et al. Bile duct injury during laparoscopic cholecystectomy: results of a national survey. Ann Surg. 2001;234:549-558. 72. Halbert C, Altieri MS, Yang J, et al. Long-term outcomes of patients with common bile duct injury following laparoscopic cholecystectomy. Surg Endosc. 2016;30(10):4294-4299. 73. Barrett M, Asbun HJ, Chien HL, Brunt LM, Telem DA. Bile duct injury and morbidity following cholecystectomy: a need for improvement. Surg Endosc. 2017. Available at: https://doi .org/10.1007/s00464-017-5847-8. Accessed July 28, 2018. 74. Strasberg SM. Avoidance of biliary injury during laparoscopic cholecystectomy. J Hepatobiliary Pancreat Surg. 2002;9: 543-547. 75. Way LW, Stewart L, Gantert W, et al. Causes and preven-tion of laparoscopic bile duct injuries: analysis of 252 cases from a human factors and cognitive psychology perspective [Comment]. Ann Surg. 2003;237(4):460-469. 76. Halawani HM, Tamim H, Khalifeh F, Mailhac A, Jamali FR. Impact of intraoperative cholangiography on postoperative mor-bidity and readmission: analysis of the NSQIP database. Surg Endosc. 2016;30(12):5395-5403. 77. van den Bos J, Schols RM, Luyer MD, et al. Near-infrared fluorescence cholangiography assisted laparoscopic cholecys-tectomy versus conventional laparoscopic cholecystectomy (FALCON trial): study protocol for a multicentre randomised controlled trial. BMJ Open. 2016;26;6(8):e011668. 78. Melton GB, Lillemoe KD, Cameron JL, et al. Major bile duct injuries associated with laparoscopic cholecystectomy: effect of surgical repair on quality of life. Ann Surg. 2002;235:888-895. 79. Grobmyer SR, Lieberman MD, Daly JM. Gallbladder cancer in the twentieth century: single institution’s experience. World J Surg. 2004;28:47-49. 80. Hundal R, Shaffer EA. Gallbladder cancer: epidemiology and outcome. Clin Epidemiol. 2014;6:99-109. 81. Lowenfels AB, Walker AM, Althaus DP, et al. Gallstone growth, size, and risk of gallbladder cancer: an interracial study. Int J Epidemiol. 1998;18:50-54.Brunicardi_Ch32_p1393-p1428.indd 142611/02/19 2:44 PM 1427GALLBLADDER AND THE EXTRAHEPATIC BILIARY SYSTEMCHAPTER 32 82. Csendes A, Burgos AM, Csendes P, et al. Late follow-up of polypoid lesions of the gallbladder smaller than 10 mm. Ann Surg. 2001;234:657-660. 83. Wagholikar G, Behari A, Krishnani N, et al. Early gallbladder cancer. J Am Coll Surg. 2002;194:137-141. 84. Kim JH, Kim TK, Eun HW. Preoperative evaluation of gall-bladder carcinoma: efficacy of combined use of MR imag-ing, MR cholangiography, and contrast-enhanced dual phase three dimensional MR angiography. J Magn Reson Imaging. 2002;16:676-684. 85. Bartlett DL, Fong Y, Fortner JG, et al. Long-term results after resection for gallbladder cancer. Implications for staging and management. Ann Surg. 1996;224:639-646. 86. Wakai T, Shirai Y, Hatakeyama K. Radical second resection provides survival benefit for patients with T2 gallbladder car-cinoma first discovered after laparoscopic cholecystectomy. World J Surg. 2002;26:867-871. 87. Noshiro H, Chijiiwa K, Yamaguchi K, et al. Factors affecting surgical outcome for gallbladder carcinoma. Hepatogastroen-terology. 2003;50:939-944. 88. Razumilava N, Gores GJ. Cholangiocarcinoma. Lancet. 2014;383(9935):2168-2179. 89. Nehls O, Gregor M, Klump B. Serum and bile markers for chol-angiocarcinoma. Semin Liver Dis. 2004;24:139-154. 90. Siqueira E, Schoen RE, Silverman W, et al. Detecting cholan-giocarcinoma in patients with primary sclerosing cholangitis. Gastrointest Endosc. 2005;56:40-47. 91. Lillemoe KD, Cameron JL. Surgery for hilar cholangiocarci-noma: the Johns Hopkins approach. J Hepatobiliary Pancreat Surg. 2000;7:115-121. 92. Mulholland MW, Yahanda A, Yeo CJ. Multidisciplinary management of perihilar bile duct cancer. J Am Coll Surg. 2001;193(4):440-447. 93. Vollmer CM, Drebin JA, Middleton WD, et al. Utility of staging laparoscopy in subsets of peripancreatic and biliary malignan-cies [Comment]. Ann Surg. 2002;235:1-7. 94. Strasberg SM. ERCP and surgical intervention in pancre-atic and biliary malignancies. Gastrointest Endosc. 2002;56: S213-S217. 95. Ortner ME, Caca K, Berr F, et al. Successful photodynamic therapy for nonresectable cholangiocarcinoma: a randomized prospective study. Gastroenterology. 2003;125:1355-1363. 96. Cheon YK, Lee TY, Lee SM, Yoon JY, Shim CS. Longterm out-come of photodynamic therapy compared with biliary stenting alone in patients with advanced hilar cholangiocarcinoma. HPB (Oxford). 2012;14(3):185-193.97. DesJardins H, Duy L, Scheirey C, Schnelldorfer T. Porcelain Gallbladder: Is Observation a Safe Option in Select Popula-tions? J Am Coll Surg. 2018 Jun;226(6):1064–1069.Brunicardi_Ch32_p1393-p1428.indd 142711/02/19 2:44 PM
Brunicardi_Ch32_p1393-p1428.indd 142811/02/19 2:44 PMThis page intentionally left blankPancreasWilliam E. Fisher, Dana K. Andersen, John A. Windsor, Vikas Dudeja, and F. Charles Brunicardi 33chapterANATOMYThe pancreas is perhaps the most unforgiving organ in the human body, leading most surgeons to avoid even palpating it unless necessary. Situated deep in the center of the abdomen, the pancreas is surrounded by numerous important structures and major blood vessels. Seemingly minor trauma to the pan-creas can result in the release of pancreatic enzymes and cause life-threatening pancreatitis. Therefore, knowledge of the rela-tionships of the pancreas to surrounding structures is critically important for all surgeons to ensure that pancreatic injury is avoided during abdominal surgery.Gross AnatomyThe pancreas is a retroperitoneal organ that lies in an oblique position, sloping upward from the C-loop of the duodenum to the splenic hilum (Fig. 33-1). In an adult, the pancreas weighs 75 to 100 g and is about 15 to 20 cm long. The fact that the pan-creas is situated so deeply in the abdomen and is sealed in the retroperitoneum explains the poorly localized and sometimes ill-defined nature with which pancreatic pathology presents. Patients with pancreatic cancer without bile duct obstruction usually present after months of vague upper abdominal discom-fort, or no antecedent symptoms at all. Due to its retroperitoneal location, pain associated with pancreatitis often is characterized as penetrating through to the back.Regions of the PancreasSurgeons typically describe the location of pathology within the pancreas in relation to four regions: the head, neck, body, and tail. The head of the pancreas is nestled in the C-loop of the duodenum and is posterior to the transverse mesocolon. Just pos-terior to the head of the pancreas lie the vena cava, the right renal artery, and both renal veins. The neck of the pancreas lies directly anterior to the portal vein. At the inferior border of the neck of the pancreas, the superior mesenteric vein joins the splenic vein and then continues toward the porta hepatis as the portal vein. The inferior mesenteric vein often joins the splenic vein near Anatomy1429Gross Anatomy / 1429Regions of the Pancreas / 1429Pancreatic Duct Anatomy / 1432Vascular and Lymphatic Anatomy / 1433Neuroanatomy / 1435Histology and Physiology1435Exocrine Pancreas / 1435Endocrine Pancreas / 1437Islet Distribution / 1439Acute Pancreatitis1439Definition, Incidence, and Epidemiology / 1439Etiology / 1440Gallstones / 1440Alcohol / 1440Iatrogenic / 1441Hereditary Pancreatitis / 1441Tumors / 1441Hyperlipidemia / 1441Drugs / 1441Pathophysiology / 1441Precipitating Events / 1441Intrapancreatic Events / 1442Systemic Events / 1443Management of Acute Pancreatitis / 1443Diagnosis / 1444Pain Management / 1444Predicting Severity / 1444Classification of Severity / 1445Determining Etiology / 1446Fluid Resuscitation / 1446Nutritional Support / 1446Cross-Sectional Imaging / 1446Therapeutic Endoscopic Retrograde Cholangiopancreatography / 1447Antibiotics / 1447Managing Local Complications / 1447Managing Organ Failure / 1448Cholecystectomy / 1449Diabetes / 1449Chronic Pancreatitis1450Definition, Incidence, and Prevalence / 1450Etiology / 1450Genetic Causes / 1450Alcohol / 1451Hyperparathyroidism / 1452Hyperlipidemia / 1452Classification / 1452Chronic Calcific (Lithogenic) Pancreatitis / 1452Chronic Obstructive Pancreatitis / 1453Chronic Inflammatory Pancreatitis / 1454Tropical (Nutritional) Pancreatitis / 1455Asymptomatic Pancreatic Fibrosis / 1455Idiopathic Pancreatitis / 1455Pathology / 1456Presentation, Natural History, and Complications / 1460Complications / 1465Treatment / 1468Pancreatic Neoplasms1480Neoplasms of the Endocrine Pancreas / 1480Insulinoma / 1480Noninsulinoma Hyperinsulinemia Hypoglycemia Syndrome / 1481Gastrinoma / 1481Vasoactive Intestinal Peptide-Secreting Tumor / 1482Glucagonoma / 1482Somatostatinoma / 1483Nonfunctioning Pancreatic Endocrine Tumors / 1483Neoplasms of the Exocrine Pancreas / 1484Workup of Asymptomatic Pancreatic Cystic Neoplasms / 1504Brunicardi_Ch33_p1429-p1516.indd 142901/03/19 6:44 PM 1430Key Points1 Incomplete fusion of the dorsal and ventral pancreatic ducts results in pancreas divisum, but a variety of ductal anomalies can be seen. Magnetic resonance cholangiopancreatography as well as endoscopic retrograde cholangiopancreatography can identify these ductal anomalies, and clarification of the ductal pattern of the pancreas is important before attempts at interventions.2 The “replaced right hepatic artery” occurs in 15% of patients and needs to be identified preoperatively to prevent inadvertent injury with resulting hepatic necrosis. Anomalous hepatic arterial anatomy can result in hepatic ischemia during dissection of the porta hepatis as well. “Thin cut” multidetector computed tomographic images are usually able to identify the relevant arterial and venous patterns around the pancreas.3 Regardless of the etiology, the management of the early phase of acute pancreatitis is critical to achieve a success-ful outcome. Aggressive fluid resuscitation and early enteral feeding both reduce the risk of complications. It is no longer considered appropriate to “rest the pancreas” if the patient can tolerate enteral nutrients.4 Surgical intervention in acute pancreatitis is reserved for patients with infected collections or infected necrosis only, or to relieve an impacted gallstone in the ampulla if endo-scopic or radiologic treatments are unsuccessful. Infection is usually confirmed by a pattern of air in the retroperitoneum on computed tomographic scan or by documentation of bac-teria on Gram’s stain or culture from fine-needle aspiration of a suspected infected fluid collection. Fine-needle aspira-tion of suspicious fluid collections should not be converted to percutaneous drainage unless infection is confirmed and the consensus decision has been made that percutaneous drainage is appropriate for the individual patient.5 The appearance of chronic pancreatitis on computed tomo-graphic scan varies dramatically, and multiple diagnostic studies are usually needed to establish the extent of disease. Calcific pancreatitis is not a marker of alcoholic pancreati-tis alone, and it rarely indicates autoimmune pancreatitis. Endoscopic ultrasound provides a better assessment of the disease than computed tomography and is useful to disclose indolent or unsuspected cancer, which can occur in up to 10% of patients.6 The nidus of inflammation in chronic pancreatitis due to any cause is the head of the gland. Therefore, treatment approaches that address the disease in the head have the best long-term results. The Whipple procedure, the Beger procedure, and the Frey procedure, with or without longitu-dinal duct drainage, are the best surgical options, as all three approaches remove all or most of the disease in the head of the gland. Although the limited pancreatic procedures (Beger/Frey) have a lower initial rate of endocrine dysfunc-tion, the long-term risk of diabetes is more related to the progression of the underlying disease than to the effects of operation. Level 1 studies confirm that the duodenum pre-serving options are associated with a lower immediate mor-bidity and mortality and therefore, in the absence of a mass or concerns about cancer, are better options than a Whipple procedure for chronic pancreatitis.7 The precursor lesion that probably leads to most cases of ductular adenocarcinoma is the ductal epithelial hyperplasia/dysplasia process described by the pancreatic intraepithelial neoplasia classification system. Pancreatic intraepithelial neoplasia 2 and pancreatic intraepithelial neoplasia 3 lesions may be associated with other, nonspecific changes in pancre-atic morphology seen on imaging studies, or they may only be seen histologically. Resection margins for pancreatic neo-plasms should be examined for advanced pancreatic intraep-ithelial neoplasia stage patterns of ductal hyperplasia to ensure adequate resection status.8 A low threshold for ordering a computed tomography scan with “pancreatic protocol” should be maintained for older adult patients with unexplained, persistent, although vague, abdominal pain. New-onset diabetes in an older adult patient, especially if combined with vague abdominal pain, should prompt a search for pancreatic cancer.9 Intraductal papillary mucinous neoplasms are small macro-scopic polypoid or plaque-like adenomas that develop in the main pancreatic duct or in side-branch ducts, and secrete mucin. They are often silent symptomatically but cause char-acteristic appearances of small cyst-like collections of mucus or diffuse dilatation of the main pancreatic duct with mucus. These premalignant lesions may be multifocal or single and can evolve into invasive adenocarcinoma in a similar pattern as with other adenomatous polypoid lesions of the gastroin-testinal tract. They have been diagnosed with increasing fre-quency and account for more than one-third of pancreatic resections at some centers. Main-duct intraductal papillary mucinous neoplasms are an indication for resection; side-branch intraductal papillary mucinous neoplasms have a lower incidence of malignancy and are sometimes followed with serial imaging surveillance.its junction with the portal vein. Sometimes, the inferior mesen-teric vein joins the superior mesenteric vein or merges with the superior mesenteric portal venous junction to form a trifurca-tion (Fig. 33-2). The superior mesenteric artery lies parallel to and just to the left of the superior mesenteric vein. The uncinate process and the head of the pancreas wrap around the right side of the portal vein and end posteriorly near the space between the superior mesenteric vein and superior mesenteric artery. Venous branches draining the pancreatic head and uncinate process enter along the right lateral and posterior sides of the portal vein. There are usually no anterior venous tributaries, and a plane can usually be developed between the neck of the pancreas and the portal and superior mesenteric veins during pancreatic resection, unless the tumor is invading the vein anteriorly. The common bile duct runs in a deep groove on the posterior aspect of the pancreatic head until it passes through the pancreatic parenchyma to join the main pancreatic duct at the ampulla of Vater. The body and tail of the pancreas lie just anterior to the splenic artery and vein. The vein runs in a groove on the back of the pancreas and is fed by multiple fragile venous branches from the pancreatic paren-chyma. These branches must be divided to perform a spleen-sparing distal pancreatectomy. The splenic artery runs parallel and just superior to the vein along the posterior superior edge of the body and tail of the pancreas. The splenic artery often is Brunicardi_Ch33_p1429-p1516.indd 143001/03/19 6:44 PM 1431PANCREASCHAPTER 33Body of pancreasTail of pancreasNeck of pancreasStomachLiverPortal veinSplenic veinGallbladderDuodenumHead of pancreasUncinate processof pancreasLeft kidneyVena cavaDuodenumAortaStomachHead of pancreasLeft kidneySMASMADuodenumJejunum4th portionof duodenumHead of pancreasPortal veinIMVSMVHead of pancreasDuodenumJejunumTail of pancreasStomachLiverPortal veinHead of pancreasDuodenumSMVFigure 33-1. Pancreatic anatomy as seen on computed tomography. Knowledge of the relationship of the pancreas with surrounding structures is important to ensure that injury is avoided during abdominal surgery. IMV = inferior mesenteric vein; SMA = superior mesenteric artery; SMV = superior mesenteric vein.PortalveinSplenicveinInferiormesentericveinSuperiormesentericveinSuperiormesentericveinSuperiormesentericveinInferiormesentericveinInferiormesentericveinSplenicveinSplenicveinPortalveinPortalveinFigure 33-2. Variations in portal venous anatomy. The superior mesenteric vein joins the splenic vein and then continues toward the porta hepatis as the portal vein. The inferior mesenteric vein often joins the splenic vein near its junction with the portal vein, but sometimes joins the superior mesenteric vein; or the three veins merge as a trifurcation to form the portal vein.Brunicardi_Ch33_p1429-p1516.indd 143101/03/19 6:44 PM 1432SPECIFIC CONSIDERATIONSPART IIBlindaccessory duct30%60%Minor papilla10%Dorsal anlageVentral anlageVentral budLiver budLesser oraccessorypapillaGreaterpapillaFusion oftwo ductsBile ductDorsal budDuct ofsantoriniDuct ofwirsungFigure 33-3. Embryology of pancreas and duct variations. The duct of Wirsung from the ventral bud connects to the bile duct, while the duct of Santorini from the larger dorsal bud connects to the duodenum. With gut rotation, the two ducts fuse in most cases such that the majority of the pancreas drains through the duct of Wirsung to the major papilla. The duct of Santorini can persist as a blind accessory duct or drain through the lesser papilla. In a minority of patients, the ducts remain separate, and the majority of the pancreas drains through the duct of Santorini, a condition referred to as pancreas divisum.tortuous. The anterior surface of the body of the pancreas is cov-ered by peritoneum. Once the gastrocolic omentum is divided, the body and tail of the pancreas can be seen along the floor of the lesser sac, just posterior to the stomach.Pancreatic pseudocysts commonly develop in this area, and the posterior aspect of the stomach can form the anterior wall of the pseudocyst, allowing drainage into the stomach. The base of the transverse mesocolon attaches to the inferior margin of the body and tail of the pancreas. The transverse mesoco-lon often forms the inferior wall of pancreatic pseudocysts or inflammatory processes, allowing surgical drainage through the transverse mesocolon. The body of the pancreas is anterior to the aorta at the origin of the superior mesenteric artery. The neck of the pancreas is anterior to the vertebral body of L1 and L2, and blunt anteroposterior trauma can compress the neck of the pancreas against the spine, causing parenchymal and, sometimes, ductal injury. The neck divides the pancreas into approximately two equal halves. The small portion of the pan-creas anterior to the left kidney is referred to as the tail and is nestled in the hilum of the spleen near the splenic flexure of the left colon. Awareness of these anatomic relationships is impor-tant to avoid injury to the pancreatic tail during left colectomy or splenectomy.Pancreatic Duct AnatomyAn understanding of embryology is required to appreciate the common variations in pancreatic duct anatomy. The pancreas is formed by the fusion of a ventral and dorsal bud (Fig. 33-3). The duct from the smaller ventral bud, which arises from the hepatic diverticulum, connects directly to the common bile duct. The duct from the larger dorsal bud, which arises from the duodenum, drains directly into the duodenum. The duct of the ventral anlage becomes the duct of Wirsung, and the duct from the dorsal anlage becomes the duct of Santorini. With gut rotation, the ventral anlage rotates to the right and around the posterior side of the duodenum to fuse with the dorsal bud. The ventral anlage becomes the inferior portion of the pancreatic head and the unci-nate process, while the dorsal anlage becomes the body and tail of the pancreas. The ducts from each anlage usually fuse together in the pancreatic head such that most of the pancreas drains through the duct of Wirsung, or main pancreatic duct, into the common channel formed from the bile duct and pancreatic duct. The length of the common channel is variable. In about one-third of patients, the bile duct and pancreatic duct remain distinct to the end of the papilla, the two ducts merge at the end of the papilla in another one-third, and in the remaining one-third, a true common channel is present for a distance of several millimeters. Commonly, the duct from the dorsal anlage, the duct of Santorini, persists as the lesser pancreatic duct, and sometimes drains directly into the duo-denum through the lesser papilla just proximal to the major papilla. In approximately 30% of patients, the duct of Santorini ends as a blind accessory duct and does not empty into the duodenum. In 10% of patients, the ducts of Wirsung and Santorini fail to fuse.1 This results in the majority of the pancreas draining through the duct of Santorini and the lesser papilla, while the inferior portion of the pancreatic head and uncinate process drains through the duct of Wirsung and major papilla. This nor-mal anatomic variant, which occurs in one out of 10 patients, is referred to as pancreas divisum (see Fig. 33-3). In a minority of these patients, the minor papilla can be inadequate to handle the flow of pancreatic juices from the majority of the gland. This rela-tive outflow obstruction can result in pancreatitis and is some-times treated by sphincteroplasty of the minor papilla.The main pancreatic duct is usually only 2 to 3 mm in diameter and runs midway between the superior and inferior borders of the pancreas, usually closer to the posterior than to the anterior surface. Pressure inside the pancreatic duct is about twice that in the common bile duct, which is thought to prevent reflux of bile into the pancreatic duct. The main pancreatic duct joins with the common bile duct and empties at the ampulla of Vater or major papilla, which is located on the medial aspect of the second portion of the duodenum. The muscle fibers around the ampulla form the sphincter of Oddi, which controls the flow of pancreatic and biliary secretions into the duodenum. Contrac-tion and relaxation of the sphincter is regulated by complex neu-ral and hormonal factors. When the accessory pancreatic duct or lesser duct drains into the duodenum, a lesser papilla can be identified approximately 2 cm proximal to the ampulla of Vater.1Brunicardi_Ch33_p1429-p1516.indd 143201/03/19 6:44 PM 1433PANCREASCHAPTER 33BileductPortalveinAbdominal aortaCeliac trunkSplenic arteryDorsalpancreatic arteryGreatpancreaticarteryCaudalarteryInferiorpancreatic arteryAnterior inferiorpancreaticoduodenal arteryAnterior superiorpancreatico-duodenalarteryPosterior inferiorpancreaticoduodenal arteryPosterior superiorpancreatico-duodenalarteryGastroduodenalarteryHepatic arteryproperCommon hepaticarterySuperiormesenteric arterySpleenDuodenumFigure 33-4. Arterial supply to the pancreas. Multiple arcades in the head and body of the pancreas provide a rich blood supply. The head of the pancreas cannot be resected without devascularizing the duodenum unless a rim of pancreas containing the pancreaticoduodenal arcade is preserved.Vascular and Lymphatic AnatomyThe blood supply to the pancreas comes from multiple branches from the celiac and superior mesenteric arteries (Fig. 33-4). The common hepatic artery gives rise to the gastroduodenal artery before continuing toward the porta hepatis as the proper hepatic artery. The right gastric artery branches off the gastroduodenal artery just superior to the duodenum. The gastroduodenal artery also supplies the superior pancreaticoduodenal artery which divides into the anterior and superior pancreaticoduodenal arteries. These travel inferiorly within the pancreaticoduodenal groove giving off small branches to the duodenum and head of the pancreas. The superior pancreaticoduodenal arteries join the inferior pancreaticoduodenal arteries to complete the arcade. The inferior pancreaticoduodenal artery is a branch off the supe-rior mesenteric artery. Therefore, it is impossible to resect the head of the pancreas without devascularizing the duodenum, unless a rim of pancreas containing the pancreaticoduodenal arcade is preserved. The inferior pancreaticoduodenal artery needs to be controlled when dissecting the head of the pancreas off the SMA during a Whipple procedure. The gastroduodenal artery travels inferiorly anterior to the neck of the pancreas and posterior to the duodenal bulb. A posterior ulcer in the duodenal bulb can erode into the gastroduodenal artery in this location. At the inferior border of the duodenum, the gastroduodenal artery then gives rise to the right gastroepiploic artery then can con-tinue on to join the inferior pancreaticoduodenal artery.Variations in the arterial anatomy occur in one out of five patients. The right hepatic artery, common hepatic artery, or gas-troduodenal arteries can arise from the superior mesenteric artery. In 15% to 20% of patients, the right hepatic artery will arise from the superior mesenteric artery and travel upwards toward the liver along the posterior aspect of the head of the pancreas (referred to as a replaced right hepatic artery). It is important to look for this variation on preoperative com-puted tomographic (CT) scans and in the operating room so the 2replaced hepatic artery is recognized and injury is avoided. The body and tail of the pancreas are supplied by multiple branches of the splenic artery. The splenic artery arises from the celiac trunk and travels along the posterior-superior border of the body and tail of the pancreas toward the spleen. The inferior pancreatic artery usually arises from the superior mesenteric artery and runs to the left along the inferior border of the body and tail of the pancreas, parallel to the splenic artery. Three vessels run perpen-dicular to the long axis of the pancreatic body and tail and con-nect the splenic artery and inferior pancreatic artery. They are, from medial to lateral, the dorsal, great, and caudal pancreatic arteries. These arteries form arcades within the body and tail of the pancreas and account for the rich blood supply of the organ.The venous drainage of the pancreas follows a pattern similar to that of the arterial supply (Fig. 33-5). The veins are usually superficial to the arteries within the parenchyma of the pancreas. There is an anterior and posterior venous arcade within the head of the pancreas. Typically, the superior vein drains directly into the portal vein just above the neck of the pancreas and is often a larger branch of the portal vein which is divided during the Whipple procedure. The posterior infe-rior arcade drains directly into the inferior mesenteric vein at the inferior border of the neck of the pancreas and this is also divided during a Whipple procedure. The anterior inferior pan-creaticoduodenal vein joins the right gastroepiploic vein and the middle colic vein to form a common venous trunk, which enters into the superior mesenteric vein. Traction on the trans-verse colon during colectomy can tear these fragile veins, which then retract into the parenchyma of the pancreas, making control tedious. There also are numerous small venous branches com-ing from the pancreatic parenchyma directly into the lateral and posterior aspect of the portal vein. Venous return from the body and tail of the pancreas drains into the splenic vein.The lymphatic drainage from the pancreas is diffuse and widespread (Fig. 33-6). The profuse network of lymphatic Brunicardi_Ch33_p1429-p1516.indd 143301/03/19 6:44 PM 1434SPECIFIC CONSIDERATIONSPART IIBileductPortal veinLeft gastric veinSplenic veinInferior mesenteric veinMiddle colic veinAnteroinferiorpancreatico-duodenalveinAnterosuperiorpancreatico-duodenalveinPosterosuperiorpancreatico-duodenalveinRightgastroepiploicveinSuperior mesenteric veinAbdominalaortaSpleenFigure 33-5. Venous drainage from the pancreas. The venous drainage of the pancreas follows a pattern similar to the arterial supply, with the veins usually superficial to the arteries. Anterior traction on the transverse colon can tear fragile branches along the inferior border of the pancreas, which then retract into the parenchyma of the pancreas. Venous branches draining the pancreatic head and uncinate process enter along the right lateral and posterior sides of the portal vein. There are usually no anterior venous tributaries, and a plane can usually be developed between the neck of the pancreas and the portal and superior mesenteric veins.Celiaclymph nodeHepaticlymph nodePyloriclymph nodeAnteriorpancreatico-duodenallymph nodePosteriorpancreaticoduodenallymph nodeSuperior mesentericlymph nodeInferiorbodySuperior body Splenic lymphnodeDuodenumSpleenFigure 33-6. Lymphatic supply to the pancreas. The lymphatic drainage from the pancreas is diffuse and widespread, which explains the high incidence of lymph node metastases and local recurrence of pancreatic cancer. The pancreatic lymphatics also communicate with lymph nodes in the transverse mesocolon and mesentery of the proximal jejunum. Tumors in the body and tail of the pancreas are often unresect-able because they metastasize to these lymph nodes. (Reproduced with permission from Bell RH, Rikkers LF, Mulholland M: Digestive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)Brunicardi_Ch33_p1429-p1516.indd 143401/03/19 6:44 PM 1435PANCREASCHAPTER 33SpleenPancreasEsophagusCeliac ganglionRight vagus nerveLeft vagus nerveSplanchnic nervesDuodenumAbdominal aortaFigure 33-7. Innervation of the pancreas. The pancreas has a rich supply of afferent sensory fibers that travel superiorly to the celiac ganglia. Interruption of these somatic fibers with a celiac plexus block can interfere with transmission of pancreatic pain. (Reproduced with permission from Bell RH, Rikkers LF, Mulholland M: Digestive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)vessels and lymph nodes draining the pancreas provides egress to tumor cells arising from the pancreas. This diffuse lymphatic drainage contributes to the fact that pancreatic cancer often presents with positive lymph nodes and a high incidence of local recurrence after resection. Lymph nodes can be palpated along the distal bile duct and posterior aspect of the head of the pan-creas in the pancreaticoduodenal groove, where the mesenteric vein passes under the neck of the pancreas, along the inferior border of the body, at the celiac axis and along the hepatic artery ascending into the porta hepatis, and along the splenic artery and vein. The pancreatic lymphatics also communicate with lymph nodes in the transverse mesocolon and mesentery of the proxi-mal jejunum. Tumors in the body and tail of the pancreas often metastasize to these nodes and lymph nodes along the splenic vein and in the hilum of the spleen.NeuroanatomyThe pancreas is innervated by the sympathetic and parasympathetic nervous systems. The acinar cells responsible for exocrine secretion, the islet cells responsible for endocrine secretion, and the islet vasculature are innervated by both systems. The parasympathetic system stimulates endocrine and exocrine secretion and the sympathetic system inhibits secretion.2 The pancreas is also innervated by neurons that secrete amines and peptides, such as somatostatin, vasoactive intestinal peptide (VIP), calcitonin gene-related peptide (CGRP), and galanin. The exact role of these neurons in pancreatic physiology is uncertain, but they do appear to affect both exocrine and endocrine function. The pancreas also has a rich supply of afferent sensory fibers, which are responsible for the intense pain associated with advanced pancreatic cancer, as well as acute and chronic pancreatitis. These somatic fibers travel superiorly to the celiac ganglia (Fig. 33-7). Interruption of these somatic fibers with a celiac plexus block can stop transmission of pain sensation.HISTOLOGY AND PHYSIOLOGYThe exocrine pancreas accounts for about 85% of the pancreatic mass; 10% of the gland is accounted for by extracellular matrix, and 4% by blood vessels and the major ducts, whereas only 2% of the gland is comprised of endocrine tissue. The endocrine and exocrine pancreas are sometimes thought of as function-ally separate, but these different components of the organ are coordinated to allow an elegant regulatory feedback system for digestive enzyme and hormone secretion. This complex system regulates the type of digestion, its rate, and the processing and distribution of absorbed nutrients. This coordination is facili-tated by the physical approximation of the islets and the exo-crine pancreas, the presence of specific islet hormone receptors on the plasma membranes of pancreatic acinar cells, and the existence of an islet-acinar portal blood system.Although patients can live without a pancreas when insu-lin and digestive enzyme replacement are administered, the loss of this islet-acinar coordination leads to impairments in diges-tive function. Although only approximately 20% of the normal pancreas is required to prevent insufficiency, in many patients undergoing pancreatic resection, the remaining pancreas is not normal, and pancreatic endocrine and exocrine insufficiency can develop with removal of smaller portions of the gland.Exocrine PancreasThe pancreas secretes approximately 500 to 800 mL per day of colorless, odorless, alkaline, isosmotic pancreatic juice. Pan-creatic juice is a combination of acinar cell and duct cell secre-tions. The acinar cells secrete amylase, proteases, and lipases, enzymes responsible for the digestion of all three food types: carbohydrate, protein, and fat. The acinar cells are pyramid-shaped, with their apices facing the lumen of the acinus. Near the apex of each cell are numerous enzyme-containing zymogen Brunicardi_Ch33_p1429-p1516.indd 143501/03/19 6:44 PM 1436SPECIFIC CONSIDERATIONSPART IIAcinar cellsCentroacinar cellsIntercalated ductFigure 33-8. Acinar cell. Zymogen granules fuse with the apical membrane and release multiple enzymes to digest carbohydrates, proteins, and fat. (Reproduced with permission from Bloom W, Fawcett DW: A Textbook of Histology, 10th ed. Philadelphia, PA: Saunders; 1975.)granules that fuse with the apical cell membrane (Fig. 33-8). Unlike the endocrine pancreas, where islet cells specialize in the secretion of one hormone type, individual acinar cells secrete all types of enzymes. However, the ratio of the different enzymes released is adjusted to the composition of digested food through nonparallel regulation of secretion.Pancreatic amylase is secreted in its active form and com-pletes the digestive process already begun by salivary amylase. Amylase is the only pancreatic enzyme secreted in its active form, and it hydrolyzes starch and glycogen to glucose, malt-ose, maltotriose, and dextrins. These simple sugars are trans-ported across the brush border of the intestinal epithelial cells by active transport mechanisms. Gastric hydrolysis of protein yields peptides that enter the intestine and stimulate intestinal endocrine cells to release cholecystokinin (CCK)-releasing pep-tide, CCK, and secretin, which then stimulate the pancreas to secrete enzymes and bicarbonate into the intestine.The proteolytic enzymes are secreted as proenzymes that require activation. Trypsinogen is converted to its active form, trypsin, by another enzyme, enterokinase, which is produced by the duodenal mucosal cells. Trypsin, in turn, activates the other proteolytic enzymes. Trypsinogen activation within the pancreas is prevented by the presence of inhibitors that are also secreted by the acinar cells. A failure to express a normal tryp-sinogen inhibitor, pancreatic secretory trypsin inhibitor (PSTI), also known as serine protease inhibitor Kazal type 1 (SPINK1), is a cause of familial pancreatitis. Inhibition of trypsinogen activation ensures that the enzymes within the pancreas remain in an inactive precursor state and are activated only within the duodenum. Trypsinogen is expressed in several isoforms, and a missense mutation on the cationic trypsinogen, or PRSS1, results in premature, intrapancreatic activation of trypsinogen. This accounts for about two-thirds of cases of hereditary pan-creatitis. Chymotrypsinogen is activated to form chymotrypsin. Elastase, carboxypeptidase A and B, and phospholipase are also activated by trypsin. Trypsin, chymotrypsin, and elastase cleave bonds between amino acids within a target peptide chain, and carboxypeptidase A and B cleave amino acids at the end of peptide chains. Individual amino acids and small dipeptides are then actively transported into the intestinal epithelial cells. Pancreatic lipase hydrolyzes triglycerides to 2-monoglyceride and fatty acid. Pancreatic lipase is secreted in an active form. Colipase is also secreted by the pancreas and binds to lipase, changing its molecular configuration and increasing its activity. Phospholipase A2 is secreted by the pancreas as a proenzyme that becomes activated by trypsin. Phospholipase A2 hydrolyzes phospholipids and, as with all lipases, requires bile salts for its action. Carboxylic ester hydrolase and cholesterol esterase hydrolyze neutral lipid substrates like esters of cholesterol, fat-soluble vitamins, and triglycerides. The hydrolyzed fat is then packaged into micelles for transport into the intestinal epithelial cells, where the fatty acids are reassembled and packaged inside chylomicrons for transport through the lymphatic system into the bloodstream (Table 33-1).The centroacinar and intercalated duct cells secrete the water and electrolytes present in the pancreatic juice. About 40 acinar cells are arranged into a spherical unit called an acinus. Centroacinar cells are located near the center of the acinus and are responsible for fluid and electrolyte secretion. These cells contain the enzyme carbonic anhydrase, which is needed for bicarbonate secretion. The amount of bicarbonate secreted varies with the pancreatic secretory rate, with greater concen-trations of bicarbonate being secreted as the pancreatic secre-tory rate increases. Chloride secretion varies inversely with bicarbonate secretion such that the sum of these two remains constant. In contrast, sodium and potassium concentrations are kept constant throughout the spectrum of secretory rates3 (Fig. 33-9). The hormone secretin is released from cells in the duodenal mucosa in response to acidic chyme passing through the pylorus into the duodenum. Secretin is the major stimulant for bicarbonate secretion, which buffers the acidic fluid entering the duodenum from the stomach. CCK also stimulates bicarbon-ate secretion, but to a much lesser extent than secretin. CCK potentiates secretin-stimulated bicarbonate secretion. Gastrin and acetylcholine, both stimulants of gastric acid secretion, are also weak stimulants of pancreatic bicarbonate secretion.4 Truncal vagotomy produces a myriad of complex effects on the downstream digestive tract, but the sum effect on the exocrine pancreas is a reduction in bicarbonate and fluid secretion.5 The endocrine pancreas also influences the adjacent exocrine pan-creatic secretions. Somatostatin, pancreatic polypeptide (PP), and glucagon are all thought to inhibit exocrine secretion.The acinar cells release pancreatic enzymes from their zymogen granules into the lumen of the acinus, and these pro-teins combine with the water and bicarbonate secretions of the centroacinar cells. The pancreatic juice then travels into small intercalated ducts. Several small intercalated ducts join to form an interlobular duct. Cells in the interlobular ducts contribute fluid and electrolytes to adjust the final concentrations of the pancreatic fluid. Interlobular ducts then join to form about 20 secondary ducts that empty into the main pancreatic duct. Brunicardi_Ch33_p1429-p1516.indd 143601/03/19 6:44 PM 1437PANCREASCHAPTER 33Table 33-1Pancreatic enzymesENZYMESUBSTRATEPRODUCTCarbohydrate Amylase (active)Starch, glycogenGlucose, maltose, maltotriose, dextrinsProtein Endopeptidases  Trypsinogen (inactive) Enterokinase Trypsin (active)  Chymotrypsinogen (inactive) EnterokinaseTrypsin Chymotrypsin (active)  Proelastase (inactive) EnterokinaseTrypsin Elastase (active) Exopeptidases  Procarboxy peptidase A&B (inactive) Enterokinase Carboxypeptidase A&B (active)Cleave bonds between amino acidsCleave amino acids from end of peptide chainsAmino acids, dipeptides—Fat Pancreatic lipase (active) Phospholipase A2 (inactive) Trypsin Phospholipase A2 (active) Cholesterol esteraseTriglyceridesPhospholipaseNeutral lipids2-Monoglycerides, fatty acids——Concentration (mEq/L)18016014012010080604020 000.40.81.21.6Secretory rate (mL/min)Pancreatic juice180160140120100806040200PlasmaNaHCO3ClKNa=151.5HCO3=26.0Cl=110.0K=5.38Figure 33-9. Composition of pancreatic exocrine secretions. Greater concentrations of bicarbonate are secreted at higher secretory rates, and chloride secretion varies inversely with bicarbonate secretion. In contrast, sodium and potassium concentrations are independent of the secretory rate. (Reproduced with permission from Bro-Rasmussen F, Killmann SA, Thaysen JH: The composition of pancreatic juice as compared to sweat, parotid saliva and tears, Acta Physiol Scand. 1956 Sep 26;37(2-3):97-113.)Table 33-2Pancreatic Islet Peptide ProductsHORMONESISLET CELLFUNCTIONSInsulinBetaDecreases gluconeogenesis, glycogenolysis, fatty acid breakdown, and ketogenesisIncreased glycogenesis, protein synthesis and glucose uptakeGlucagonAlphaOpposite effects of insulin; increases hepatic glycogenolysis and gluconeogenesisSomatostatinDeltaInhibits secretion and action of all pancreatic and gut peptides, inhibits cell growthPancreatic PolypeptidePP or FInhibits pancreatic exocrine secretion and facilitates hepatic action of insulinAmylin (IAPP)BetaCounter-regulates insulin secretion and functionPancreastatinBetaDecreases insulin and somatostatin secretion, increases glucagon secretion, decreases exocrine secretionGhrelinEpsilonDecreases insulin secretion and actionPeptide YY (PYY)not knownIncreases insulin secretion and beta cell growthDestruction of the branching ductal tree from recurrent inflam-mation, scarring, and deposition of stones in chronic pancreatitis eventually contributes to destruction of the exocrine pancreas and exocrine pancreatic insufficiency.Endocrine PancreasThere are nearly 1 million islets of Langerhans in the normal adult pancreas. They vary greatly in size from 40 to 900 μm. Larger islets are located closer to the major arterioles and smaller islets are embedded more deeply in the parenchyma of the pancreas. Most islets contain 3000 to 4000 cells of five major types: alpha cells that secrete glucagon, beta-cells that secrete insulin, delta cells that secrete somatostatin, epsilon cells that secrete ghrelin, and PP cells that secrete PP (Table 33-2).Insulin is the best-studied pancreatic hormone. The discovery of insulin in 1920 by Frederick Banting, an orthopedic Brunicardi_Ch33_p1429-p1516.indd 143701/03/19 6:44 PM 1438SPECIFIC CONSIDERATIONSPART IIsurgeon, and Charles Best, a medical student, was recognized with the awarding of the Nobel Prize in Physiology or Medicine. They produced diabetes in dogs by performing total pancreatectomy and then treated them with crude pancreatic extracts from dog and calf pancreata using techniques to prevent the breakdown of insulin by the proteolytic enzymes of the exocrine pancreas. Insulin was subsequently purified and found to be a 56-amino acid peptide with two chains, an alpha and a beta chain, joined by two disulfide bridges and a connecting peptide, or C-peptide. Proinsulin is made in the endoplasmic reticulum and then is transported to the Golgi complex, where it is packaged into granules and the C-peptide is cleaved off. There are two phases of insulin secretion. In the first phase, stored insulin is released. This phase lasts about 5 minutes after a glucose challenge. The second phase of insulin secretion is a longer, sustained release due to ongoing production of new insulin. beta-cell synthesis of insulin is regulated by plasma glucose levels, neural signals, and the paracrine influence of other islet cells. The diagnosis of diabetes is made by using oral and intravenous (IV) glucose tolerance tests. Oral glucose not only enters the bloodstream but also stimulates the release of enteric hormones such as gastric inhibitory peptide (also known as glucose-dependent insulinotropic polypeptide or GIP), glucagon-like peptide-1 (GLP-1), and CCK that augment the secretion of insulin and are therefore referred to as incretins. As a result, oral glucose is a more vigorous stimulus to insulin secretion than IV glucose. In the oral glucose tolerance test (OGTT), the patient is fasted overnight, and a basal glucose value is determined. Forty g/m2 or 75 g of glucose is given orally over 10 minutes. Blood samples are taken every 30 minutes for 2 hours. Normal values and criteria for diabetes vary by age, but essentially all values should be <200 mg/dL, and the 120-minute value should be <140 mg/dL.Insulin secretion by the beta-cell is also influenced by plasma levels of amino acids such as arginine, lysine, leucine, and free fatty acids. Glucagon, GIP, GLP-1, and CCK stimulate insulin release, while somatostatin, amylin, and pancreastatin inhibit insulin release.6 Cholinergic fibers and alpha-sympa-thetic fibers stimulate insulin release, while beta-sympathetic fibers inhibit insulin secretion.Insulin’s glucoregulatory function is to inhibit endogenous (hepatic) glucose production and to facilitate glucose transport into cells, thus lowering plasma glucose levels. Insulin also inhibits glycogenolysis, fatty acid breakdown, and ketone formation, and stimulates protein synthesis. There is a considerable amount of functional reserve in insulin secretory capacity. If the remaining portion of the pancreas is healthy, about 80% of the pancreas can be resected without the patient becoming diabetic.7 In patients with chronic pancreatitis, or other conditions in which much of the gland is diseased, resection of a smaller fraction of the pancreas can result in pancreatogenic, or type 3c diabetes (Table 33-3).Insulin receptors are dimeric, tyrosine kinase–containing transmembrane proteins that are located on all cells. Insulin defi-ciency (seen in type 1 and type 3c diabetes) results in an overex-pression or upregulation of insulin receptors, which causes an enhanced sensitivity to insulin in muscle and adipocytes (and therefore increases the risk of insulin-induced hypoglycemia). Type 2 diabetes is associated with a downregulation of insulin receptors and relative hyperinsulinemia, with resulting insulin resistance. Some forms of diabetes are associated with selected impairments of hepatic or peripheral insulin receptors, such as pancreatogenic or type 3c diabetes (T3cDM) or maturity-onset diabetes of the young (MODY).Glucagon is a 29-amino-acid, single-chain peptide that promotes hepatic glycogenolysis and gluconeogenesis and counteracts the effects of insulin through its hyperglycemic action. Glucose is the primary regulator of glucagon secretion, as it is with insulin, but it has an inhibitory rather than stimulatory effect. Glucagon release is stimulated by hypoglycemia and by the amino acids arginine and alanine. GLP-1 inhibits glucagon secretion in vivo, and insulin and somatostatin inhibit glucagon Table 33-3Clinical and laboratory findings in types of diabetes mellitusPARAMETERTYPE 1TYPE 2TYPE 3C IDDMNIDDMPancreatogenicKetoacidosisCommonRareRareHyperglycemiaSevereUsually mildMildHypoglycemiaCommonRareCommonPeripheral insulin sensitivityNormal or increasedDecreasedIncreasedHepatic insulin sensitivityNormalNormal or decreasedDecreasedInsulin levelsLowHighLowGlucagon levelsNormal or highNormal or highLowPP levelsNormal or low (late)HighLowGIP levelsNormal or lowNormal or highLowGLP-1 levelsNormalNormal or highNormal or highTypical age of onsetChildhood or adolescenceAdulthoodAnyAbbreviations: IDDM = insulin dependent diabetes mellitus; NIDDM = non–insulin-dependent diabetes mellitus; PP = pancreatic polypeptide; GIP = glucose-dependent insulinotropic polypeptide; GLP-1 = glucagon-like peptide 1.Reproduced with permission from Slezak LA, Andersen DK: Pancreatic resection: effects on glucose metabolism, World J Surg. 2001 Apr;25(4):452-460.Brunicardi_Ch33_p1429-p1516.indd 143801/03/19 6:44 PM 1439PANCREASCHAPTER 33secretion in a paracrine fashion within the islet. The same neural impulses that regulate insulin secretion also regulate glucagon secretion, so that the two hormones work together in a balance of actions to maintain glucose levels. Cholinergic and alpha-sympathetic fibers stimulate glucagon release, while beta-sympathetic fibers inhibit glucagon release.8 In pancreatogenic or type 3c diabetes, glucagon responsiveness to a fall in blood glucose is lost, thereby increasing the risk for hypoglycemia.Although originally isolated from the hypothalamus, somatostatin is a peptide that is now known to have a wide ana-tomic distribution, not only in neurons but also in the pancreas, gut, and other tissues. It is a highly conserved peptide hormone, as it is found in lower vertebrates, and is now realized to be of fundamental importance in regulatory processes throughout the body. One gene encodes for a common precursor that is dif-ferentially processed to generate tissue-specific amounts of two bioactive products, somatostatin-14, and somatostatin-28. These peptides inhibit endocrine and exocrine secretion and affect neurotransmission, GI and biliary motility, intestinal absorption, vascular tone, and cell proliferation.Five different somatostatin receptors (SSTRs) have been cloned and the biologic properties of each are different.9 The hexapeptide and octapeptide analogues such as octreotide bind only to SSTR2, SSTR3, and SSTR5. These analogues have a longer serum half-life, and their potent inhibitory effect has been used clinically to treat both endocrine and exocrine disor-ders. For example, octreotide has been shown to decrease fistula output and speed the time it takes for enteric and pancreatic fistulas to close.10Endocrine release of somatostatin occurs during a meal. The major stimulant is probably intraluminal fat. Acidification of the gastric and duodenal mucosa also releases somatostatin in isolated perfused organ preparations. Acetylcholine from the cholinergic neurons inhibits somatostatin release.Pancreatic polypeptide (PP) is a 36-amino-acid, straight-chain peptide discovered by Kimmel in 1968 during the process of insulin purification. Protein is the most potent enteral stimu-lator of PP release, closely followed by fat, whereas glucose has a weaker effect.11 Hypoglycemia, whether or not it is insulin induced, strongly stimulates PP secretion through cholinergic stimulation.12 Phenylalanine, tryptophan, and fatty acids in the duodenum stimulate PP release, probably by inducing CCK, GIP, and secretin release. Vagal stimulation of the pancreas is the most important regulator of PP secretion. In fact, vagotomy eliminates the rise in PP levels usually seen after a meal. This can be used as a test for the completeness of a surgical vagot-omy or for the presence of diabetic autonomic neuropathy.PP has been shown to inhibit choleresis (bile secretion), gallbladder contraction, and secretion by the exocrine pan-creas. However, PP’s most important role is in glucose regu-lation through its regulation of hepatic insulin receptor gene expression. A deficiency in PP secretion due to proximal pan-createctomy, severe chronic pancreatitis, or cystic fibrosis, is associated with diminished hepatic insulin sensitivity due to reduced hepatic insulin receptor availability.13 This effect is reversed by PP administration.14Recent studies have shown that a fifth islet peptide, ghre-lin, is secreted from a distinct population of islet cells, called epsilon cells.15,16 Ghrelin also is present in the gastric fundus in large amounts and stimulates growth hormone secretion via growth hormone releasing hormone release from the pituitary. It is an orexigenic, or appetite-stimulating, peptide the plasma levels of which are increased in obesity. Ghrelin has also been shown to block insulin effects on the liver, and inhibits the beta-cell response to incretin hormones and glucose.17 Therefore, ghrelin secretion from and within the islet may modulate the responses of other islet cells to nutrient and hormonal stimuli.In addition to the five main peptides secreted by the pan-creas, there are a number of other peptide products of the islet cells, including amylin, peptide YY (PYY), and pancreastatin, as well as neuropeptides such as VIP, galanin, and serotonin. Amylin or islet amyloid polypeptide (IAPP) is a 37-amino-acid polypeptide that is predominantly expressed by the pancreatic beta-cells, where it is stored along with insulin in secretory granules.18 The function of IAPP seems to be the modulation or counterregulation of insulin secretion and function. Pancre-astatin is a recently discovered pancreatic islet peptide prod-uct that inhibits insulin, and possibly somatostatin release, and augments glucagon release.19,20 In addition to this effect on the endocrine pancreas, pancreastatin inhibits pancreatic exocrine secretion.21 PYY is structurally related to PP and was initially found in hormone-secreting “L” cells of the small intestine, where it colocalizes with GLP-1. Recently, PYY has been local-ized to the islets22 where it appears to regulate insulin secretion through an autocrine mechanism.Islet DistributionThe beta-cells are generally located in the central portion of each islet and make up about 70% of the total islet cell mass. The other cell types are located predominantly in the periphery. The delta cells are least plentiful, making up only 5%; the 〈-cells make up 10%, and the PP cells make up 15%.23 In contrast to the acinar cells that secrete the full gamut of exocrine enzymes, the islet cells seem to specialize in the secretion of predominantly one hormone. However, individual islet cells can secrete mul-tiple hormones. For example, the beta-cells secrete both insulin and amylin, which counter regulates the actions of insulin. In reality, more than 20 different hormones are secreted by the islets, and the exact functions of this milieu are very complex. There is diversity among the islets depending on their location within the pancreas. The beta and delta cells are evenly distrib-uted throughout the pancreas, but islets in the head and uncinate process (ventral anlage) have a higher percentage of PP cells and fewer alpha cells, whereas islets in the body and tail (dorsal anlage) contain the majority of alpha cells and few PP cells. This is clinically significant because pancreatoduodenectomy removes 95% of the PP cells in the pancreas. This may partially explain the higher incidence of glucose intolerance after the Whipple procedure compared to a distal pancreatectomy with an equivalent amount of tissue resected. In addition, chronic pan-creatitis, which disproportionately affects the pancreatic head, is associated with PP deficiency and pancreatogenic diabetes.24 The relative preponderance of alpha cells in the body and tail of the pancreas explains the typical location of glucagonomas.ACUTE PANCREATITISDefinition, Incidence, and EpidemiologyAcute pancreatitis is an inflammatory disorder of the pancreas that is characterized by edema and, when severe, necrosis. It is a common and challenging disease that can develop local and systemic complications. As such, it ranges from a mild, self-limiting inflammation of the pancreas to severe and critical disease characterized by infected pancreatic necrosis, multiple Brunicardi_Ch33_p1429-p1516.indd 143901/03/19 6:44 PM 1440SPECIFIC CONSIDERATIONSPART IITable 33-4Etiologies of acute pancreatitisAlcoholBiliary tract diseaseHyperlipidemiaHereditaryHypercalcemiaTrauma External Surgical Endoscopic retrograde cholangiopancreatographyIschemia Hypoperfusion Atheroembolic VasculitisPancreatic duct obstruction Neoplasms Pancreas divisum Ampullary and duodenal lesionsInfectionsVenomDrugsIdiopathicReproduced with permission from Townsend CM, Sabiston DC: Sabiston’s Textbook of Surgery: the biological basis of modern surgical practice, 16th ed. Philadelphia, PA: Saunders/Elsevier; 2000.organ failure, and a high mortality.25 The traditional view is that acute pancreatitis completely resolves with no morphological, functional, or symptomatic sequelae. But necrotizing pancreati-tis can leave significant scarring, strictures, and impairment of exocrine and endocrine pancreatic function. The overall clinical outcome has improved over recent decades, even in the absence of specific treatments that target outcome-determining patho-physiology, probably because of a more standardized approach to diagnosis, monitoring, and management.Acute pancreatitis is the most common inpatient princi-pal gastrointestinal discharge diagnosis in the United States (274,119 in 2009), with an increasing incidence (30% since 2000) and is associated with the highest aggregate inpatient costs at 2.6 billion dollars per year.26 The crude mortality rate of 1 per 100,000 population ranks it as the 14th most common overall and the 9th most common noncancer cause of gastrointestinal deaths. Worldwide, the incidence of acute pancreatitis ranges from 5 to 80 per 100,000 population, with the highest incidence recorded in Finland and the United States.27 The incidence of acute pancreatitis also shows significant variation related to the prevalence of etiological factors and ethnicity. The annual inci-dence of acute pancreatitis in Native Americans is 4 per 100,000 population; in whites, it is 5.7; and in blacks it is 20.7.28 Smok-ing is an independent risk factor for acute pancreatitis.29EtiologyMany factors are causally related to the onset of acute pan-creatitis, but the mechanism is often poorly understood. The most common causes are gallstones and alcohol (Table 33-4), accounting for up to 80% of cases, but it is not uncommon to diagnose acute pancreatitis in the absence of these etiological factors (“idiopathic acute pancreatitis”), and it is important that a systematic approach is taken to the identification of other, less common and potentially modifiable factors. The median age at index presentation of acute pancreatitis varies with etiology: with alcoholand drug-induced pancreatitis presenting in the third or fourth decade compared with gallstone and trauma in the sixth decade. The gender difference is probably more related to etiology: in males alcohol is more often the cause while in females it is gallstones.GallstonesEvidence that passage of a gallstone is related to the onset of acute pancreatitis comes from the characteristic transient derangement of liver function tests and the high retrieval rate of gallstones from feces within 10 days of an attack of acute pancreatitis compared with those without acute pancreatitis (88% vs. 11%).30 The mechanism by which small gallstones cause acute pancreatitis in migrating through to the duodenum is not clear. Opie made the seminal observation of a gallstone impacted in the sphincter of Oddi in two fatal cases of acute pancreatitis, which lead to the “common channel” hypothesis. It was proposed that this allowed bile to reflux into the pancre-atic duct, but this cannot be reliably reproduced in experimen-tal models. Another proposal was that transient incompetence caused by the passage of a stone through the sphincter might allow duodenal fluid and bile to reflux into the pancreatic duct, but this is not supported by the failure of this to commonly occur after endoscopic sphincterotomy. A third possibility is that acute pancreatitis is due to the gallstone obstructing the pancreatic duct and leading to ductal hypertension. It has been postulated that this backpressure might lead to minor ductal dis-ruption, extravasation of pancreatic juice into the less alkaline interstitium of the pancreas, and promotion of enzyme activa-tion. When gallstones and other etiological factors cannot be identified, there is still the possibility of finding microlithiasis, seen as birefringent crystals, on bile microscopy.31 This occult microlithiasis is probably responsible for up to half of those with idiopathic acute pancreatitis.AlcoholAlcohol ingestion is associated with acute pancreatitis, and sus-tained alcohol ingestion is associated with recurrent acute pan-creatitis and development of chronic pancreatitis in susceptible individuals who have been drinking for more than a decade. The type of alcohol consumed is less important than the amount consumed (typically 100–150 grams per day) and the pattern of drinking. It is common for patients with alcohol-associated acute pancreatitis to have a history of excess alcohol consumption prior to the first attack. There are several mechanisms by which ethanol causes acute pancreatitis by acting on the acinar and stellate cells.32 The acinar cell metabolizes ethanol by oxidative and nonoxidative pathways, and exhibits changes that predis-pose the cell to autodigestive injury, necroinflammation, and cell death. The stellate cells are activated on exposure to ethanol to a myofibroblast phenotype, stimulating synthesis of proinflam-matory mediators and cytokines. Ethanol causes a brief secretory increase followed by inhibition. The secretory burst coupled with ethanol induced spasm of the sphincter of Oddi probably incites acute pancreatitis. Ethanol also induces ductal permeability, which allows prematurely activated enzymes to cause damage to the pancreatic parenchyma. Ethanol also increases the protein content of pancreatic juice and decreases bicarbonate levels and trypsin inhibitor concentration. The formation of protein plugs may also contribute by causing an obstructive element to pancre-atic outflow, more often seen in chronic pancreatitis.Brunicardi_Ch33_p1429-p1516.indd 144001/03/19 6:44 PM 1441PANCREASCHAPTER 33Figure 33-10. Schema of key loco-regional pathophysiological events in the pancreas and intestine and how they interact to drive the severity and outcome of acute pancreatitis. (Adapted with permission from Flint RS, Windsor JA: The role of the intestine in the pathophysiology and management of severe acute pancreatitis, HPB (Oxford). 2003;5(2):69-85.)IatrogenicAcute pancreatitis can occur due to trauma to the ducts or parenchyma after surgical procedures, including biopsy, bile duct exploration, distal gastrectomy, and splenectomy. As the pancreas is susceptible to ischemia, it can also occur second-ary to splanchnic hypoperfusion with cardiopulmonary bypass, cardiac transplant, hemorrhagic shock, and major trauma. The most common iatrogenic cause is ERCP in which acute pancre-atitis occurs after about 5% to 10% of procedures, and in many series, it is the third most common identified etiological fac-tor. The risk of post-ERCP acute pancreatitis is increased if the contrast agent is infused repeatedly under high pressure by the endoscopist and in patients with sphincter of Oddi dysfunction. Recent evidence demonstrates that the risk can be decreased with prophylactic rectal nonsteroidal drugs,33 and this may be a better strategy than prophylactic pancreatic duct stenting.34Hereditary PancreatitisHereditary pancreatitis is an autosomal dominant disorder usually related to mutations of the cationic trypsinogen gene (PRSS1). Mutations in this gene cause premature activation of trypsinogen to trypsin and causes abnormalities of ductal secre-tion, both of which promote acute pancreatitis. Mutations in the SPINK1 protein, which blocks the active binding site of trypsin, is likely to also have a role in predisposing to acute pancreatitis. Variations in penetration and phenotype are common, and there are many other mutations that have become implicated. Mutant enzymes activated within acinar cells can overwhelm the first line of defense (pancreatic secretory trypsin inhibitor) and resist backup defenses (e.g., proteolytic degradation, enzyme Y, and trypsin itself) allowing activated mutant cationic trypsin to trig-ger the entire zymogen activation cascade.35TumorsA pancreatic or periampullary tumor should be considered in patients with idiopathic acute pancreatitis, especially in those over 50 years old. Approximately 1% to 2% of patients with acute pancreatitis have a pancreatic tumor, and an episode of acute pancreatitis can be the first clinical indicator. Cross-sectional imaging after the resolution of the acute pancreatitis is required.HyperlipidemiaPatients with types I and V hyperlipoproteinemia can experience episodes of abdominal pain, and these often occur in association with marked hypertriglyceridaemia. Lipase is thought to liberate toxic fatty acids into the pancreatic microcirculation, leading to microcirculatory impairment and ischemia. Dietary modifica-tions and drug treatment are used to lower triglycerides.DrugsIsolated cases of acute pancreatitis have been associated with exposure to certain drugs, such as thiazide diuretics, furosemide, estrogen replacement therapy, and steroid therapy in children. In addition, certain chemotherapy agents and anti-immune drugs have been associated with acute pancreatitis, and lipid-based drugs or solutions, such as propofol, have been shown to cause acute pancreatitis.PathophysiologyAcute pancreatitis occurs in various degrees of severity, the determinants of which are multifactorial. The generally prevalent belief today is that pancreatitis begins with the activation of diges-tive zymogens inside acinar cells, which cause acinar cell injury. Studies suggest that the ultimate severity of the resulting pancre-atitis may be determined by the events that occur subsequent to acinar cell injury.36 These include inflammatory cell recruitment and activation, as well as generation and release of cytokines and other chemical mediators that cause systemic inflammation and multiple organ dysfunction/failure (Figure 33-10).Precipitating EventsIn 1896, Chiari proposed that pancreatitis was due to the premature, intrapancreatic activation of digestive enzymes, resulting in “auto-digestion” of the organ. Since then the Brunicardi_Ch33_p1429-p1516.indd 144101/03/19 6:44 PM 1442SPECIFIC CONSIDERATIONSPART IIFigure 33-11. Schematic representation of the acinar cell events in acute pancreatitis. When acinar cells are pathologically stimulated, their lysosomal (L) and zymogen (Z) contents colocalize, and consequently trypsinogen is activated to trypsin by cathepsin B. Increased cytosolic calcium is required for colocalization. Once trypsin has permeabilized the contents of the cytosol, cathepsin B and other contents of these colocalized organelles are released. Once in the cytosol, cathepsin B activates apoptosis by causing cytochrome c to be released from the mitochondria. Activation of PKC results in a sudden activation of nuclear factor kappa beta (NFκβ), which in turn triggers the release of cytokines that attract inflammatory response cells that mediate local and systemic inflammation cascades.intra-acinar activation of zymogens has been demonstrated consistently in multiple animal models of acute pancreatitis and is considered a key precipitating event.37,38 The key role of trypsin activation in acute pancreatitis has gained additional support from recent studies showing that mice lacking trypsinogen-7 (the isoform of trypsinogen that is activated during acute pancreatitis in mice) have significantly less pancreatic injury during acute pancreatitis39 and that intra-acinar expression of active trypsin causes pancreatitis in mice.40 The role of trypsin activation in the pathophysiology of acute pancreatitis has also been suggested by clinical studies. Hereditary pancreatitis is associated with mutations that lead to elevated intracellular trypsin activation,41 and activation of trypsinogen causes clinical pancreatitis.42Significant progress has been made in understanding the mechanisms by which injurious stimuli lead to intra-acinar activation of trypsinogen and autodigestion of the gland (Figure 33-11). Under physiologic conditions, several protective mechanisms have evolved to prevent autodigestion of the pancreas by these enzymes. This includes synthesis of enzymes as inactive precursors, separation of the site of production, and activation of the enzymes and presence of trypsin inhibitors in the pancreas. It is thought that acute pancreatitis occurs when these protective mechanisms are overwhelmed with erroneously activated enzymes, causing injury. It has been shown that intra-acinar activation of trypsinogen goes hand-in-hand with inhibition of acinar secretion.43,44 Furthermore, with injurious stimuli the zymogens responsible for initiating the disease are not secreted outside, but colocalize with cytoplasmic vacuoles that contain lysosomal enzymes such as cathepsin B45 that activate trypsinogen. Thus, inhibition of cathepsin B by pharmacological inhibitors46 or by genetic deletion of cathepsin B eliminates trypsin activation and decreases the severity of pancreatitis in animal models.47 What leads to the colocalization of zymogens and lysosomal hydrolases is unclear, but injurious stimuli leading to sustained cytosolic calcium increase have been indicted. Blocking this calcium increase prevents colocalization and activation of trypsin, and it decreases injury due to pancreatitis.48 Based on these data, pre-ERCP supplementation of magnesium, a natural antagonist of calcium, is currently being evaluated as a strategy to decrease post-ERCP pancreatitis.49 Recent work has led to the novel hypothesis that the lysosomal hydrolase cathepsin B activates trypsinogen to trypsin within the colocalization vacuoles. Trypsin then permeabilizes these colocalization vacuoles causing the release of cathepsin B into the cytosol. Once in the cytosol, cathepsin B initiates apoptotic cell death by permeabilizing mitochondrial membranes, which allows cytochrome C to be released into the cytosol. This initiates the apoptotic cascade and results in the apoptotic death of the acinar cells50 (see Figure 33-11).Intrapancreatic EventsAlthough intra-acinar events initiate acute pancreatitis, events occurring subsequent to acinar cell injury determine the severity of pancreatitis. Activated neutrophils are attracted and activated in the pancreas releasing superoxide (the respiratory burst) and proteolytic enzymes (cathepsins, elastase, and collagenase) that cause further pancreatic injury. In addition, macrophages release cytokines (including tumor necrosis factor-alpha (TNF-α) and interleukins (IL-1, IL-2, IL-6, and IL-8) that mediate local and systemic inflammation.38These inflammatory mediators cause an increased pancre-atic vascular permeability, leading to hemorrhage, edema, and Acinar cell deathTo pancreatic ductTrypsinogenCathepsin BActive trypsinEarly stagesLeaky colocalizedorganellesColocalizationSustainedRise in Ca2+PKC activationInsultSystemic in‘ammationRelease of cytokinesand chemokinesRecruitment ofin‘ammatory cellsLater stagesNF–KBactivationLocal injury: PancreatitisZLBrunicardi_Ch33_p1429-p1516.indd 144201/03/19 6:44 PM 1443PANCREASCHAPTER 33Figure 33-12. Computed tomography scan showing well perfused interstitial edematous acute pancreatitis of the neck and tail of the pancreas with a confluent area of necrosis of the pancreatic body. The pancreas is surrounded by fluid, inflammation, and possible peripancreatic fat necrosis.Table 33-5Local complications of acute pancreatitisCONTENT ACUTE (<4 WEEKS, NO DEFINED WALL)CHRONIC (>4 WEEKS, DEFINED WALL)NO INFECTIONINFECTIONNO INFECTIONINFECTIONFluidAcute pancreatic fluid collection (APFC)Infected APFCPseudocystInfected pseudocystSolid ± fluidAcute necrotic collection (ANC)Infected ANCWalled off necrosis (WON)Infected WONReproduced with permission from Windsor JA, Petrov MS: Acute pancreatitis reclassified, Gut. 2013 Jan;62(1):4-5.microthrombi. Fluid may collect in and around the pancreas. The failure of the pancreatic microcirculation, a feature of more severe acute pancreatitis, results in pancreatic hypoperfusion and necrosis. Acute inflammation of the pancreatic parenchyma and peripancreatic tissues, but with no recognizable necrosis, is termed interstitial edematous pancreatitis.25 When necrosis is present, as evidenced by pancreatic hypoperfusion with contrast CT, it is termed necrotizing pancreatitis (Figure 33-12). The updated morphological definitions and the contrast enhanced CT criteria for the diagnosis of the local complications of acute pancreatitis are in the revised Atlanta statement51 and summa-rized in Table 33-5.52Systemic EventsAn important aspect of the pathophysiology of acute pancre-atitis is the mechanism by which events occurring in the pan-creas induce systemic inflammation and multiorgan failure. The NFκB-dependent inflammatory pathway is an important mechanism (see Figure 33-11). Activation of NFκB parallels trypsin activation in acute pancreatitis but appears to be inde-pendent of it, as it occurs in trypsin knockout mice.39 Sustained calcium increase, which leads to trypsinogen activation, is criti-cal for NFκB activation since attenuation of cytosolic calcium abrogates NFκB activation.53 Once activated, NFκB regulates synthesis of multiple cytokines and chemokines, leading to recruitment of various inflammatory cells that then magnify and propagate systemic inflammation.54 The infiltrating neutrophils can also further augment the pancreatic injury.55,56 Inhibition of many of these cytokines have led to reduced local and systemic injury in animal models of acute pancreatitis. But these results did not translate to clinical improvement.57 New strategies are required to reduce the systemic inflammatory response.58-60Organ failure can develop at any stage of acute pancreati-tis, associated with an overwhelming proinflammatory response early, or later secondary to the development of infected local complications. The drivers of the systemic response are poorly understood, although factors include the elaboration of proin-flammatory cytokines, and it appears that mesenteric lymph, bypassing the liver and containing these constituents, may con-tribute to the development of organ failure61 (see Figure 33-10). The development of pancreatic necrosis, the breakdown of the intestinal barrier, and the suppression of the immune response through the compensatory inflammatory response contribute to the development of infected pancreatic necrosis, the incidence of which peaks in the third to fourth week. This is usually asso-ciated with deterioration in the patient’s condition and may be associated with the late development of the systemic inflam-matory response syndrome (SIRS) and multiorgan dysfunction syndrome/failure (MODS/F).Organ failure is scored using the Marshall or Sequential Organ Failure Assessment (SOFA) systems (Table 33-6). The three organ systems most frequently involved are cardiovas-cular, respiratory, and renal. Multiple organ failure is defined as two or more organs registering two or more points on these scoring systems.51 Monitoring organ failure over time and in response to treatment is important in the care and timing of intervention in these patients.Management of Acute PancreatitisGeneral Considerations. The management of acute pancre-atitis covers a wide spectrum of severity. All patients with sus-pected acute pancreatitis should be admitted to hospital. Those with mild acute pancreatitis usually remain in hospital for less than a week, while those with severe and critical acute pan-creatitis may require many weeks or months of intensive treat-ment. The risk of mortality reflects this spectrum of severity. The risk is less than 1% for those with mild disease, increasing to around 10% for those with moderate disease, but for severe (20–40%) and critical (>50%) disease the mortality risk is much higher. The earlier identification of these high-risk categories and their transfer to specialized centers is an important priority of management.62The management of acute pancreatitis is multidisciplinary, and it is important that this is coordinated care plan is carefully supervised.63 The essential requirements for the management Brunicardi_Ch33_p1429-p1516.indd 144301/03/19 6:44 PM 1444SPECIFIC CONSIDERATIONSPART IITable 33-6Sequential organ failure assessment (SOFA) score in acute pancreatitis 01234Respiration     (PaO2FIO2) (mmHg)>400≤400≤300≤200 with respiratory support≤100 with respiratory supportCoagulation     Platelets (xl01 per μL)>150≤150≤100≤50≤20Liver     Bilirubin (μmol/L)<2020–3233–101102–204>204Cardiovascular     HypotensionNo hypotensionMAP <70 mmHgDopamine ≤5 or dobutamine (any dose)aDopamine >5 or epi ≤0.1a or norepi ≤0.1aDopamine >15 or epi >0.1a or norepi >0.1aCentral nervous system     Glasgow coma score1513–1410–126–9<6Kidney     Creatinine (μmol/L) or urine output<110110–170171–299300–440 or <500 mL/day>440 or <200 mL/dayaAdrenergic agents administered for at least 1 h (doses given in μg/kg per min). A score of 2 or more in any two systems indicates the presence of multiple organ failure.Abbreviations: MAP = mean arterial pressure; Epi = epineptvine; Norepi = norepinephrine.of acute pancreatitis are accurate diagnosis, appropriate triage, high-quality supportive care, and monitoring for and treatment of complications.64DiagnosisThe diagnosis of acute pancreatitis requires the patient to pres-ent with abdominal pain consistent with acute pancreatitis (acute onset of a severe constant epigastric pain that often radiates through to the mid back) and the elevation of serum amylase or lipase (>3 times upper limit of normal). Imaging (usually by contrast-enhanced CT scanning) is only required for the diagnosis of acute pancreatitis when these diagnostic criteria are not met.51 Because of the many causes of hyperamylasemia, it is important to use either the pancreatic isoenzyme of amylase or lipase.63The serum amylase concentration increases almost imme-diately with the onset of disease and peaks within several hours and remains elevated for 3 to 5 days.64 There is no correlation between the extent of serum amylase elevation and severity of pancreatitis; in fact, a milder form of acute pancreatitis is often associated with higher levels of serum amylase compared with that in a more severe form of the disease. It is important to note that hyperamylasemia can also occur in association with other diseases. For example, it can occur in a patient with small bowel obstruction, perforated duodenal ulcer, or other intra-abdominal inflammatory conditions. In contrast, a patient with acute pancreatitis can have a normal serum amylase level, for several different reasons. In patients with hyperlipidemia, values might appear to be normal because of interference with chemical determination of serum amylase by lipids. In some cases, urinary clearance of pancreatic enzymes from the circu-lation increases during pancreatitis, meaning that urinary levels may be more sensitive than serum levels. For these reasons, it is recommended that amylase concentrations also be measured in the urine. Urinary amylase levels usually remain elevated for several days after serum levels have returned to normal. In patients with severe pancreatitis associated with significant necrosis, the pancreas may not have the capacity to release large amounts of enzymes into the circulation. With more severe dis-ease, there is also hemoconcentration from third space fluid loss, and this can affect the serum concentration of amylase.The clinical signs of acute pancreatitis include abdominal tenderness, often with signs of peritonitis in the upper abdomen. Rarely, pancreatic fluid and bleeding from the pancreas into the retroperitoneum may result in a bruise-like discoloration around the umbilicus (Cullen’s sign) or in the flanks (Grey Turner’s sign). Another rare sign is tetany as a result of hypocalcaemia. In addition to hemoconcentration, patients with acute pancreati-tis often have azotemia with elevated blood urea nitrogen and creatinine levels, hyperglycemia, and hypoalbuminemia.Pain ManagementPain is the cardinal symptom of acute pancreatitis, and its relief is a clinical priority. There is a lack of high-quality evidence to guide the choice of analgesic. Because of unpredictable absorption, analgesia should be administered intravenously, at least at the outset and before oral intake has been established. Those with mild pain can usually be managed with a nonsteroidal anti-inflammatory drugs (e.g., metamizole 2 g/8 h IV), while those with more severe pain are best managed with opioid analgesia (e.g., buprenorphine 0.3 mg/4 h IV). Administration of buprenorphine, pentazocine, procaine hydrochloride, and meperidine are all of value in controlling abdominal pain. Morphine is to be avoided because of its potential to cause sphincter of Oddi spasm.Predicting SeverityWhereas classification relates to the present or past severity of acute pancreatitis, prediction is about the future and ultimate severity and outcome of the patient. Accurately predicting acute Brunicardi_Ch33_p1429-p1516.indd 144401/03/19 6:44 PM 1445PANCREASCHAPTER 33Table 33-7Ranson’s prognostic signs of pancreatitisCriteria for acute pancreatitis not due to gallstonesAt admissionDuring the initial 48 h Age >55 y Hematocrit fall >10 points WBC >16,000/mm3 BUN elevation >5 mg/dL Blood glucose >200 mg/dL Serum calcium <8 mg/dL Serum LDH >350 IU/L Arterial PO2 <60 mmHg Serum AST >250 U/dL Base deficit >4 mEq/L  Estimated fluid sequestration >6 LCriteria for acute gallstone pancreatitisAt admissionDuring the initial 48 h Age >70 y Hematocrit fall >10 points WBC >18,000/mm3 BUN elevation >2 mg/dL Blood glucose >220 mg/dL Serum calcium <8 mg/dL Serum LDH >400 IU/L Base deficit >5 mEq/L Serum AST >250 U/dL Estimated fluid sequestration >4 LNote: Fewer than three positive criteria predict mild, uncomplicated disease, whereas more than six positive criteria predict severe disease with a mortality risk of 50%.Abbreviations: AST = aspartate transaminase; BUN = blood urea nitrogen; LDH = lactate dehydrogenase; PO2 = partial pressure of oxygen; WBC = white blood cell count.Data from Ranson JHC. Etiological and prognostic factors in human acute pancreatitis: a review. Am J Gastroenterol. 1982;77:633 and from Ranson JH, Rifkind KM, Roses DF, et al. Prognostic signs and the role of operative management in acute pancreatitis. Surg Gynecol Obstet. 1974;139:69.pancreatitis severity is important in making triage decisions about whether a patient should be transferred to a tertiary hospital or an intensive care unit and in making decisions about fluid therapy and whether an ERCP is indicated, as well as other issues.65 There is a very long history of attempts to find prognostic or predictive markers that accurately stratify the risk, with the most widely used being the Ranson’s criteria (Table 33-7) or modified Glasgow criteria. Both use clinical and biochemical parameters scored over the first 48 hours of admission. When there are three or more positive criteria, the disease is considered “predicted severe.” There are many other approaches to predicting severity. At 24 hours after admission an APACHE II score of 8 or more or a serum C-reactive protein level of >150 mg/dL has a similar accuracy in predicting severity as Ranson’s criteria.66 The more recently proposed Bedside Index for Severity of Acute Pancreatitis (BISAP) is calculated from blood urea nitrogen (> 25 mg/dL), impaired mental status (GCS <15), presence of systemic inflammatory response syndrome, age >60 years, and pleural effusion. Although it has the advantage of simplicity and can be performed within the first 24 hours of admission, it performed no better than other predictors.67 The presence of SIRS also has prognostic significance.68 There remains some controversy as to how important obesity is as a risk factor for severe and critical acute pancreatitis.69 Another approach has been taken in seeking to predict those with the “harmless acute pancreatitis score”70 using three factors that can be determined on admission: absence of rebound tenderness or guarding, normal hematocrit, and normal serum creatinine. The accuracy of this approach appears to be over 90% and triages most patients away from intensive care.Unfortunately, these and many other single and combined predictors of severity have an accuracy of around 70%66. This means that there is misclassification error of 30% that limits the value in predicting the severity of acute pancreatitis in indi-vidual patients. In the absence of any new biomarkers of pancre-atitis severity, making better use of existing predictors through sequencing tests, combining tests, or using artificial neural network methodologies has shown some promise.71 Scoring systems should augment clinical judgment, but not replace it.64 Over the first 2 to 3 days the clinician must be alert to patients with an elevated BUN or creatinine and/or persistent SIRS after adequate fluid resuscitation because these patients are at risk of developing severe acute pancreatitis.64Classification of SeverityAccurately classifying or staging acute pancreatitis severity is important for clinical decision-making, communication, and enrolment into trials. The wide spectrum of pancreatitis severity was not captured in the previous binary classifica-tions (mild or severe). The key determinants of severity are local complications (absent, sterile, or infected) and systemic complications (absent, transient organ failure, persistent organ failure).25,72 Two classification systems have recently been proposed: the three grades (mild, moderately severe, and severe) of the Revised Atlanta Criteria (RAC)51 and the four categories (mild, moderate, severe, critical) of the Determi-nants Based Classification (DBC)73 (Table 33-8). The DBC Table 33-8Definitions for the classification of acute pancreatitis severity according to Revised Atlanta Classification11 and the Determinants Based Classification14. (Transient organ failure has a duration of <48 hours, persistent organ failure has duration of >48 hours.)Determinant Based Classification (2012)Revised Atlanta Classification (2013)MildNo local complicationNo systemic complicationNo local complicationNo systemic complicationModerateSterile local complication and/orTransient organ failureLocal or systemic complications without persistent organ failureorexacerbation of preexisting comorbiditySevereinfected local complicationorPersistent organ failurePersistent organ failure (single or multiple)CriticalInfected local complication and Persistent organ failure-Brunicardi_Ch33_p1429-p1516.indd 144501/03/19 6:44 PM 1446SPECIFIC CONSIDERATIONSPART IITable 33-9The Modified Determinant Based Classification (MDBC) (Acevedo) of acute pancreatitis severity compared with the Revised Atlanta Classification (RAC) and Determinants Based Classification (DBC). Note that the DBC has a narrower definition for local complications than RAC, leading to a slightly broader range of mild acute pancreatitis in this table.RACMild(No OF, No LC)Moderately severe(TOF and/or LC)Severe(POF)DBCMild(No OF, No LC)Moderate(TOF and/or SN)Severe(POF or IN)Critical(POF and IN)MDBC ExcludedGroup 1(TOF and/or SN)Group 2(IN without POF)Group 3(POF without IN)Group 4(POF and IN)Abbreviations: OF = organ failure; LC = local complication; TOF = transient organ failure; POF = persistent organ failure; SN = sterile necrosis; IN = infected necrosis.was developed on the principle of casual inference, derived by meta-analysis, and refined by an international multidis-ciplinary process,73 and both classifications have been inde-pendently validated, which suggests that they are broadly equivalent. More recently a prospective multicenter study has modified the DBC to address the ongoing issue that patients considered to have severe acute pancreatitis represent several subgroups with different morbidity, mortality, and interven-tion profiles74 (Table 33-9).The classification of patient severity is helpful in tracking the clinical trajectory of a patient, and it can be applied on a daily or more frequent basis. It can also be used in retrospect for audit purposes.Determining EtiologyThe history of alcohol ingestion must be ascertained and preferably confirmed with blood ethanol levels. Gallstones should be investigated by ultrasonography. A gallstone etiology is more likely in females over the age of 50 with an elevation of alkaline phosphatase (>300 iu/L), alanine transferase (>100 iu/L), and amylase (>4000 iu/L). In the absence of gallstones and alcohol, a systematic approach to the identification of another factor will include taking a history of drugs, trauma, ERCP, infection, and measuring serum triglycerides, calcium, and others (see Table 33-4).Fluid ResuscitationFluid therapy to restore and maintain circulating blood volume is the most important intervention in the early management of acute pancreatitis75. However, a recent systematic review has shown that the evidence base for fluid therapy is scant,76 and most recommendations are based on expert opinion.64 It is not known which fluid to give, how aggressively to adminis-ter it, or what goal to use to guide and monitor the response to it. While there are proponents for vigorous fluid therapy (5–10 mL per kilogram per hour), especially in the first 24 hours, and for specific resuscitation goals,77 it is prob-ably best to resuscitate with a balanced crystalloid and aim to restore normal blood volume, blood pressure, and urine output. In one study, lactated Ringer’s solution was supe-rior to normal saline in reducing the systemic inflammatory response.78 Caution needs to be exercised in those with car-diac and renal disease and in the elderly, where the risks of over-resuscitation are greater.Nutritional SupportIn contrast to analgesia and fluid therapy, there is a sound evidence base for nutritional support in acute pancreatitis. It is no longer acceptable to “rest the pancreas” by avoiding enteral nutrition, now the mainstay of nutritional support.79 Parenteral nutrition is now known to be more expensive, riskier, and not more effective than enteral nutrition and should only be offered if the patient’s calculated nutritional requirements cannot be achieved by the enteral route. Early initiation of enteral nutrition (within the first 24 hours of admission) is not superior to delaying an oral diet until 72 hours.80 If this is not tolerated over 48 to 72 hours, then nasogastric tube feedings can be started and increased in step-wise fashion over 2 to 3 days.81 The tube can be advanced to the jejunum, by endoscopy or fluoroscopy, if there is evidence of feeding intolerance. A delay in commencing enteral nutrition may contribute to the development of intestinal ileus and feeding intolerance, but aggressive early enteral feeding, particularly before adequate resuscitation, may put the patient at risk of nonocclusive mesenteric ischemia. There is no evidence to support the use of elemental or immune-enhancing formulas over standard polymeric formulas.82 In predicted mild acute pancreatitis the recommencement of oral fluids and then food was delayed until resolution of abdominal pain and normalization of serum levels of amylase, but it appears safe to allow patients to resume intake ad libitum (i.e., patient-controlled nutrition). If after 3 to 5 days there is evidence of feeding intolerance, tube feeding should be commenced.Cross-Sectional ImagingIt may be necessary to perform a CT scan to diagnose acute pancreatitis in patients who are severely ill or in those presenting with undifferentiated abdominal pain. But there is no advantage in using CT scanning to predict the severity of acute pancreatitis.51,63 The primary purpose of cross-sectional imaging is the diagnosis of local complications; in particular, the development and extent of pancreatic necrosis and the different collections (see Table 33-5). CT scanning is also important to guide the insertion of percutaneous drains, now assuming a greater role in the management of the local complications (discussed later). Magnetic resonance imaging (MRI) is superior to CT scanning in detecting any solid content within collections (Figure 33-13). And when a bleed is suspected, in association with a local complication, an arterial phase CT scan (CTa) is useful in detecting a pseudoaneurysm, active bleeding, and/or hematoma.3Brunicardi_Ch33_p1429-p1516.indd 144601/03/19 6:44 PM 1447PANCREASCHAPTER 33ABFigure 33-13. Corresponding computed tomography (CT) (A) and MR (B) images of a patient with a symptomatic pseudocyst. CT image reveals a well circumscribed homogenous collection (arrows) exerting mass effect on antrum of stomach. The T2-weighted MR image clearly distinguishes necrotic pancreas (black arrows) from fluid (white arrows). (Reproduced with permission from Bollen TL: Imaging of acute pancreatitis: update of the revised Atlanta classification, Radiol Clin North Am. 2012 May;50(3):429-445.)Therapeutic Endoscopic Retrograde CholangiopancreatographyRandomized trials have demonstrated that early ERCP (within 24 or 48 hours of admission) reduce complications, but not mortality, in patients with predicted severe gallstone associated acute pancreatitis. While the benefits of this inva-sive modality are clear (e.g., treatment of cholangitis and release of impacted stone), this can be offset by the risks of increasing the severity of pancreatitis, bleeding, cholan-gitis, and perforation. More recent evidence has suggested that early ERCP confers no benefit in the absence of con-comitant cholangitis,83 as the offending common duct stone usually passes before ERCP can be performed. This may be evidenced by improvement in the liver function tests over the first 2 to 3 days. If there is persistent cholestasis, an MRCP can be used to detect a common duct stone and can be used as a prerequisite for attempting an ERCP.84 Persistent cholesta-sis without cholangitis may require an ERCP but not usually in the acute setting.AntibioticsAlthough the use of broad-spectrum antibiotics to treat estab-lished infection in acute pancreatitis is a well-established prac-tice, there has been considerable controversy surrounding the use of prophylactic antibiotics.63 The overuse of antibiotics has been associated with a documented rise in fungal infec-tions and resistant organisms. Overall, it appears that the most recent and generally better designed studies do not support the use of prophylactic antibiotics to reduce the frequency of pancreatic infectious complications, surgical intervention, and death.85Managing Local ComplicationsVigilance is required for the timely and accurate diagnosis of local complications. The decisions regarding how and when to intervene are often difficult. While guided by the information gained by cross-sectional imaging, the decision to intervene is based on the clinical status and trajectory of the patient and the poor response to maximal intensive care support. This means close monitoring of the patient by serial examination, supplemented by regular measurement of inflammatory markers (e.g., C-reactive protein) and a pancreatic protocol CT scan if a local complication is suspected and intervention considered warranted. In practice, intervention is delayed in order to allow demarcation and to reduce the risk of bleeding, disseminated infection, and collateral damage to adjacent organs by an intervention (Figure 33-14). Appreciation of this has resulted in a notable trend toward delayed Figure 33-14. Operative view of infected acute pancreatitis. Peripancreatic infection, characterized by mucopurulent exu-date, extends far beyond the boundaries of the pancreas in the retroperitoneum.Brunicardi_Ch33_p1429-p1516.indd 144701/03/19 6:44 PM 1448SPECIFIC CONSIDERATIONSPART IIStomachPeritoneal spacePeripancreaticfluid collectionwith necrotic tissueEndoscope(with balloon dilatation)PancreasRPOSTERIORLATERAL VIEWNecrotic tissuein snareLStomachSpleenPeripancreaticfluid collectionwith necrotic tissueAccess toretroperitonealspaceCostal marginPancreasPancreasLiverNecrotictissueLong graspingforcepsLaparoscopeStomachSpleenPeripancreaticfluid collectionwith necrotic tissueEndoscopeStomach wallFluid collectionAortaPOSTERIORFigure 33-15. Two minimally invasive interventions for local complications of acute pancreatitis: A. video-assisted retroperitoneal debridement and B. endoscopic transgastric necrosectomy. (Reproduced with permission from Bakker OJ, van Santvoort HC, van Brunschot S, et al: Endoscopic transgastric vs surgical necrosectomy for infected necrotizing pancreatitis: a randomized trial, JAMA. 2012 Mar 14; 307(10):1053-1061.)intervention, now uncommon before 3 to 4 weeks from the onset of symptoms. An important emerging approach is the increasing use of percutaneous catheter drainage in patients with suspected infected collections.86 Fine-needle aspiration is now rarely used to confirm infection because the insertion of a needle at the time of planned drainage allows confirmation of the suspected infection. Preemptive drainage with one or more catheters often produces improvement or stabilization of the patient’s overall clinical status.87 In this way, drainage “buys time” and allows the lesion to become more walled off and safer to treat. Recent data suggests that primary percutaneous catheter drainage may be the only intervention required in a third to a half of patients and that this proportion might increase further if there were a policy of regular catheter exchange, upsizing, and irrigation.87 A proportion of patients do, however, require further treatment when they fail to respond and there is a wide array of minimally invasive options to choose from88 (Figure 33-15). These interventions can be classified on the basis of the method of visualization, route taken to the lesion, and the purpose of the intervention.89 In practice, the approach taken will depend on local expertise and equipment as well as the location and type of the specific local complication. A large Dutch randomized trial has shown that open surgical techniques should only be considered in those who fail to respond to the step-up approach, that is, prior percutaneous drainage and minimally invasive intervention.90 The exception is to be found in the rare situation where an abdominal compartment syndrome requires open decompression, but this is usually earlier than the optimal time to intervene for local complications. A recent landmark randomized trial has compared two minimally invasive techniques, endoscopic transgastric drainage, and the videoscope-assisted retroperitoneal debridement through a flank incision (see Figure 33-15). The data shows that the former approach is superior, although the latter has a role when the walled-off necrosis is remote from the stomach or duodenum, as in the left flank.91The management of an acute noninfected pseudocyst is usually conservative, as about half of these will resolve sponta-neously. When symptoms of pain or the inability to eat persist or infection occurs, intervention is required. The indications for intervention are therefore no longer based on size and duration alone. Pseudocysts persist because of communication with the main pancreatic duct and/or distal ductal stenosis. Percutaneous drainage should be avoided in this situation because of the risk of external pancreatic fistula.92 EUS-guided internal drainage into stomach or duodenum or transpapillary stenting is the pre-ferred approach.Managing Organ FailureThe specific management of multiple organ failure is beyond the scope of this chapter. The early identification of organ dysfunc-tion and failure is important because it is a key determinant of severity and outcome and to facilitate the timely transfer of the patient to an intensive care unit to optimize management, pro-vide organ support and allow more intensive monitoring. The severity of organ failure can be scored (see Table 33-6). The responsiveness of organ failure to resuscitation over the first 48 hours is an important prognostic clue; those that respond have transient organ failure and have a better outlook than those who do not respond and have persistent organ failure.93 Organ failure that develops later in the disease course is usually Brunicardi_Ch33_p1429-p1516.indd 144801/03/19 6:44 PM 1449PANCREASCHAPTER 33Table 33-10Algorithm for the evaluation and management of acute pancreatitis 1. Diagnosis • History of abdominal pain consistent with acute pancreatitis • >3x elevation of pancreatic enzymes • CT scan if required to confirm diagnosis 2. Initial assessment/management (first 4 hrs) • Analgesia • Fluid resuscitation • Predict severity of pancreatitis • Ranson’s criteria • HAPS score • Assess systemic response • SIRS score • SOFA (organ failure) 3. Reassessment/management (4 to 6 hrs) • Assess response to fluid resuscitation • mean arterial pressure • heart rate • urine output • hematocrit • Determine etiology • Ultrasound for gallstones/sludge • History of alcohol consumption • Laboratory evaluation of other causes • MRCP and/or Urgent ERCP if concomitant cholangitis is present • not for cholestasis or predicted severe disease per se • Transfer to ICU or specialist center as needed • Deterioration or failure to respond to initial management • Intensive support for persistent organ failure • Commence enteral nutrition • Once normovolemia restored (usually after 6 hours) • Commence via NG tube if no gastric stasis • No prophylactic antibiotics or probiotics 4. Conservative management and monitoring (at least daily) • Clinical evaluation • Assess cardiovascular, respiratory, and renal function • Detect peritonitis and abdominal compartment syndrome • Daily C-reactive protein • Classify severity (mild, moderate, severe, critical) • Detect intolerance of NG EN • Advance tube for NJ feeding if needed • Consider supplemental parenteral nutrition by day 4 5. Indications for “pancreatic protocol CT scan” (rarely in first week) • For significant clinical deterioration and elevated CRP • For suspicion of local pancreatic complications • For suspected bowel ischemia • For acute bleeding (CTa) (if stable enough and consider embolization) • For abdominal compartment syndrome 6. Invasive intervention • For deteriorating patient with suspected infected local complication • “Step up approach” with initial drain guided by current CT scan (percutaneous or endoscopic drainage) • Delay for 3 to 4 weeks with intensive care support, if possible • If failure to respond or secondary deterioration, repeat CT scan, and select appropriate minimally invasive technique based on available expertise and equipment • Video-assisted retroperitoneal debridement or percutaneous nephroscopic debridement • Endoscopic transluminal debridement • Ongoing large bore drainage and irrigation 7. Indication for laparotomy • Failed “step-up approach” for further debridement/drainage • Acute abdomen (perforation or ischemia) • Severe abdominal compartment syndrome (rarely)secondary to infection of a local complication and should be managed accordingly (see Figure 33-9).CholecystectomyWhile it is widely accepted that cholecystectomy is essential to prevent recurrent gallstone associated pancreatitis, the ques-tion relates to the timing of it. Index cholecystectomy, done in the same admission and prior to discharge, appears safe and can almost always be accomplished laparoscopically.94 But index cholecystectomy is not suitable for all patients, particu-larly some who have had local pancreatic complications, which includes a large inflammatory mass that extends into the porta hepatis. These patients may require an interval cholecystec-tomy after resolution of the inflammatory process. If surgery is required for the management of local complications, then a cholecystectomy is often performed at that time.DiabetesRecent evidence indicates that prediabetes and diabetes are com-mon after acute pancreatitis and occur in nearly 40% of patients after hospital discharge.95 The prevalence of newly diagnosed diabetes is much higher after acute pancreatitis (23%) than the prevalence of diabetes in the general population (4–9%). The risk of diabetes increases by at least twofold after 5 years as compared with 12 months. Interestingly, the severity of acute pancreatitis appears to have minimal effect on risk of diabetes.95 The implica-tion is that patients recovered from an attack of acute pancreatitis may need follow-up and screening for glucose intolerance.The management of acute pancreatitis remains a formidable challenge (Table 33-10) due to the variety and severity of the many associated complications (Table 33-11), and continues to evolve. Although specific treatments for acute pancreatitis remain elusive, progress has been made in the management of pain, fluid resuscitation, antibiotic prophylaxis, enteral nutrition, therapeutic ERCP, and cholecystectomy. Progress has also been made in the intensive care management of systemic complications and in the development of less invasive interventions for the treatment of local complications, particularly infected pancreatic necrosis.4Brunicardi_Ch33_p1429-p1516.indd 144901/03/19 6:44 PM 1450SPECIFIC CONSIDERATIONSPART IITable 33-11Complications of acute pancreatitis I. Local A. Pancreatic phlegmon B. Pancreatic abscess C. Pancreatic pseudocyst D. Pancreatic ascites E. Involvement of adjacent organs, with hemorrhage, thrombosis, bowel infarction, obstructive jaundice, fistula formation, or mechanical obstruction II. Systemic A. Pulmonary 1. Pneumonia, atelectasis 2. Acute respiratory distress syndrome 3. Pleural effusion B. Cardiovascular 1. Hypotension 2. Hypovolemia 3. Sudden death 4. Nonspecific ST-T wave changes 5. Pericardial effusion C. Hematologic 1. Hemoconcentration 2. Disseminated intravascular coagulopathy D. GI hemorrhage 1. Peptic ulcer 2. Erosive gastritis 3. Portal vein or splenic vein thrombosis with varices E. Renal 1. Oliguria 2. Azotemia 3. Renal artery/vein thrombosis F. Metabolic 1. Hyperglycemia 2. Hypocalcemia 3. Hypertriglyceridemia 4. Encephalopathy 5. Sudden blindness (Purtscher’s retinopathy) G. Central nervous system 1. Psychosis 2. Fat emboli 3. Alcohol withdrawal syndrome H. Fat necrosis 1. Intra-abdominal saponification 2. Subcutaneous tissue necrosisReproduced with permission from Isselbacher KJ: Harrison’s Principles of Internal Medicine, 13th ed. New York, NY: McGraw-Hill Education; 1994.CHRONIC PANCREATITISDefinition, Incidence, and PrevalenceChronic pancreatitis is an incurable, chronic inflammatory con-dition that is multifactorial in its etiology, highly variable in its presentation, and a challenge to treat successfully. Autopsy studies indicate that evidence of chronic inflammation, such as fibrosis, duct ectasia, and acinar atrophy is seen in up to 5% of the population,96 although these data are difficult to interpret because many of these changes are also present in asymptomatic elderly patients.97 Population studies suggest a prevalence that ranges from 5 to 40 persons per 100,000 population, with con-siderable geographic variation.98 Differences in diagnostic crite-ria, regional nutrition, alcohol consumption, and medical access account for variations in the frequency of the diagnosis, but the overall incidence of the disease has risen progressively over the past 50 years.EtiologyThere are multiple etiologies of chronic pancreatitis, includ-ing genetic mutations, alcohol exposure, duct obstruction due to trauma, gallstones, and tumors, metabolic diseases such as hyperlipidemia and hyperparathyroidism, and auto-immune dis-ease. In addition, nutritional causes include so-called tropical pancreatitis, which has been thought to result from ingestion of certain starches. A significant number of patients have no discernible cause of the disease despite extensive testing, and are said to have “idiopathic” chronic pancreatitis.Genetic CausesIn 1952, Comfort and Steinberg reported a kindred of “heredi-tary chronic relapsing pancreatitis” after treating the proband, a 24-year-old woman, at the Mayo Clinic.99 Subsequently, familial patterns of chronic, nonalcoholic pancreatitis have been described worldwide, and a familiar pattern has emerged. Typically, patients first present in childhood or adolescence with abdominal pain and are found to have chronic calcific pan-creatitis on imaging studies. Progressive pancreatic dysfunction is common, and many patients present with symptoms due to pancreatic duct obstruction. The risk of subsequent carcinoma formation is increased, reaching a prevalence, in some series, of 40%, but the age of onset for carcinoma is typically >50 years old.100 The disorder is characterized by an autosomal dominant pattern of inheritance, with 80% penetrance and variable expres-sion. The incidence is equal in both sexes.Whitcomb and colleagues,101 and separately LeBodic and associates,102 performed gene-linkage analysis and identified a linkage for hereditary pancreatitis to chromosome 7q35. Subse-quently, the region was sequenced and revealed eight trypsino-gen genes. Mutational analysis revealed a missense mutation resulting in an Arg-to-His substitution at position 117 of the cat-ionic trypsinogen gene, or PRSS1, one of the primary sites for proteolysis of trypsin. This gain-of-function mutation results in an excess production of trypsinogen, which results in persistent and uncontrolled proteolytic activity and autodestruction within the pancreas.103 The position 117 mutation of PRSS1 and an addi-tional mutation, now known collectively as the R122H and N291 mutations of PRSS1, account for about two-thirds of cases of hereditary pancreatitis. Masson and associates described a gain-of-function mutation in the anionic trypsinogen gene, PRSS2, that is also present in some cases.104Similarly, SPINK1, an inflammation-induced trypsin inhibitor secreted in acinar cells, has been found to have a role in hereditary pancreatitis. SPINK1 specifically inhibits trypsin action by competitively blocking the active site of the enzyme. Witt and colleagues investigated96 unrelated children with chronic pancreatitis in Germany and found a variety of SPINK1 mutations in 23% of the patients.105 Several studies have now confirmed an association of loss-of-function SPINK1 mutations with familial and idiopathic forms of chronic pancreatitis, as well as so-called tropical pancreatitis.106,107 SPINK1 mutations Brunicardi_Ch33_p1429-p1516.indd 145001/03/19 6:44 PM 1451PANCREASCHAPTER 33BasolateralmembraneAcinar callKeyZymogensClaudin-2CFTRCalcium regulationCAZymogens: Including;trypsinogens (PRSS1, PRSS2)chymotrypsin C (CTRC)(SPINK1 in“ammation-induced trypsin inhibitor)Calcium sensing receptor (CASR)CFTRDuodenumZymogensecretionAbnormalclaudin-2localizationDuct cellBicarbonateSodiumWaterTrypsinogenZymogensEKTrypsinActive digestiveenzymesCASRFigure 33-16. Schematic model of genetic causes of chronic pan-creatitis. A pancreatic acinus is portrayed showing the pathway for digestive enzymes (zymogens) to be secreted by the acinar cell into the ductal system where water, sodium, and bicarbonate are secreted by the duct and centroacinar (CA) cells. Mutations in at least five genes have been identified as risk factors for chronic pancreatitis: gain-of function mutations in the cationic trypsinogen genes (PRSS1, PRSS2) cause hereditary pancreatitis. Cationic and anionic trypsinogen are normally active in the duodenum by entero-kinase (EK). Premature activation of the trypsin in the acinar cell leads to zymogen activation, local cellular injury, and inflamma-tion. Mutations of the trypsin inhibitors SPINK1 or chymotrypsin C (CTRC), or of the calcium sensing receptor CASR, result in pre-mature activation of trypsinogen. Mutations in the cystic fibrosis transmembrane receptor CFTR results in trypsinogen stasis within the ducts due to insufficient secretion by duct cells. A mutation in claudin-2 (CLDN2) results in abnormal expression in acinar cells, instead of its normal location between duct cells, and is associated with the accelerated development of chronic pancreatitis in alcohol abusers. (Modified with permission from Solomon S, Whitcomb DC: Genetics of pancreatitis: an update for clinicians and genetic coun-selors, Curr Gastroenterol Rep. 2012 Apr;14(2):112-711.)are common in the general population as well, and the frequency of these mutations varies in different cohorts of idiopathic chronic pancreatitis, from 6.4% in France108 to 25.8% in the United States.109 Thus, hereditary pancreatitis results from one or more mutational defects that incapacitate an auto-protective process that normally prevents proteolysis within the pancreas.Cystic fibrosis, originally termed cystic fibrosis of the pancreas, results from a variety of mutations of the cystic fibro-sis transmembrane receptor (CFTR). The CFTR is present in pancreatic duct cells and controls the amount of chloride and bicarbonate secreted into the normally alkaline pancreatic juice. The CFTR gene contains over 4300 nucleotides, divided into 24 exons, which encode a 1480-amino acid protein. Over 1000 polymorphisms have been reported, and many are common. The CFTR mutation associated with the classic pulmonary dis-ease, F508, is rarely observed in chronic pancreatitis. But other CFTR mutations have been noted to be associated with chronic idiopathic pancreatitis, auto-immune pancreatitis, and pancreas divisum, in which the pulmonary, intestinal, and cutaneous manifestations of the disease are silent.110Many studies have been undertaken to determine whether specific genetic abnormalities are associated with alcoholic chronic pancreatitis and which might confer susceptibility to the disease.105 In 2012, a landmark study by Whitcomb and associates demonstrated a likely genetic cause of the predisposition to alcohol-induced chronic pancreatitis in men.111 In a genome-wide association study of more than 2000 patients, these researchers discovered that a common DNA variant on the X chromosome is present in 26% of men without pancreatitis, but jumps to nearly 50% of men diagnosed with alcoholic pancreatitis. The variant involves the claudin 2 (CLDN2) gene, which encodes a tight junction protein normally present in ductal cells. In cases of chronic pancreatitis, the CLDN2 protein is abnormally expressed in acinar cells and may alter the secretory dynamics of enzyme release. The abnormality does not appear to cause pancreatitis, but if pancreatitis occurs for any reason in a person with the CLDN2 variant, it is more likely that the person will develop chronic pancreatitis; the risk is increased even further among alcohol users. Only 10% of women have the X chromosome–linked variant on both X chromosomes, and most women with the CLDN2 variant on one X chromosome appear to be protected from alcoholic chronic pancreatitis by the other X chromosome, if it is normal. Men, with only one X chromosome, have no protection if they inherit a CLDN2 mutation. This helps to explain the high prevalence of alcoholic chronic pancreatitis among men, although the mechanism remains unclear. This study does not demonstrate a genetic cause for all cases of alcohol-related chronic pancreatitis, but it shows that a genetic element contributes to many patients with the disease (Fig. 33-16).AlcoholIn 1878, Friedreich proposed that “a general chronic interstitial pancreatitis may result from excessive alcoholism (drunkard’s pancreas).”112 Since that observation, numerous studies have shown that a causal relationship exists between alcohol and chronic pancreatitis, but the prevalence of alcohol as the etiol-ogy of the disease in Western countries ranges widely, from 38% to 94%113 (Fig. 33-17).There is a linear relationship between exposure to alcohol and the development of chronic pancreatitis.114 The risk of dis-ease is present in patients with even a low or occasional expo-sure to alcohol (1 to 20 g/d), perhaps due to the CLDN2 gene mutation described previously, so there is no threshold level of alcohol exposure below which there is no risk of develop-ing chronic pancreatitis. Furthermore, although the risk of dis-ease is dose related and highest in heavy (>150 g/d, or about 11 1 oz shots, or 12 beers per day) drinkers, the prevalence of chronic pancreatitis among confirmed alcohol abusers is only 5% to 15%.115 However, the duration of alcohol consumption is definitely associated with the development of pancreatic dis-ease. The onset of disease typically occurs between ages 35 to 40 years, after 16 to 20 years of heavy alcohol consumption. Recurrent episodes of acute pancreatitis are typically followed by chronic symptoms after 4 or 5 years.116In their 1946 classic study, Comfort, Gambrill, and Baggenstoss proposed that chronic pancreatitis was the result of multiple episodes of acute inflammation, with residual and Brunicardi_Ch33_p1429-p1516.indd 145101/03/19 6:44 PM 1452SPECIFIC CONSIDERATIONSPART IITimeDegree of pancreatic damage= Episode of acute pancreatitisNecrosis-fibrosis sequenceFigure 33-18. “Multiple hit” theory of the etiology of chronic pancreatitis. Multiple episodes of acute pancreatitis cause progres-sively more organized inflammatory changes that ultimately result in chronic inflammation and scarring. (Reproduced with permission from Apte MV, Wilson JS: Alcohol-induced pancreatic injury, Best Pract Res Clin Gastroenterol. 2003 Aug;17(4):593-612.)Very heavy drinking (15%)Alcohol + genetic (3%)Idiopathic(42%)Genetic(24%)CFTR(14%)CFTR +SPINK1(3%)SPINK1(4%)PRSS1(3%)Hyperlipidemia,Autoimmune,Other (4%)Obstructive(9%)Gallstone /severe AP(3%)Figure 33-17. Etiologies of chronic pancreatitis. (Reproduced with permission from Whitcomb DC: Going MAD: development of a “matrix academic division” to facilitate translating research to personalized medicine, Acad Med. 2011 Nov;86(11):1353-1359.)progressively increasing chronic inflammation.117 Subsequently, Kondo and associates showed that other, additional factors were necessary for repeated exposure to alcohol to cause chronic pancreatitis.118 Regardless of the requirement for other predisposing or facilitative factors, the concept that multiple episodes (or a prolonged course) of pancreatic injury ultimately leads to chronic disease is widely accepted as the pathophysiologic sequence119 (Fig. 33-18).Although direct alcohol exposure to the pancreatic ductal system, or elevated levels of alcohol in the bloodstream, has been shown to alter the integrity and function of pancreatic ducts and acini directly,120 most investigators believe that alco-hol metabolites such as acetaldehyde, combined with oxidant injury, result in local parenchymal injury that is preferentially targeted to the pancreas in predisposed individuals. Repeated or severe episodes of toxin-induced injury activate a cascade of cytokines, which, in turn, induces pancreatic stellate cells (PSCs) to produce collagen and cause fibrosis (Fig. 33-19).A high-protein, low-bicarbonate, low-volume secretory output is seen after chronic alcohol exposure, which may con-tribute to the precipitation of proteins in secondary ducts in the early stages of chronic pancreatitis.121 Calcium is complexed to protein plugs in small ductules, secondary ducts, and, eventu-ally, in the main ductal system, which causes ductal cell injury and obstruction of the secretory system, which further promotes an inflammatory response.Cigarette smoking has been strongly associated with chronic pancreatitis,122 but until recently it was unclear whether this was a causative risk factor. Studies have now shown that smoking actually accelerates the development of alcoholic pancreatitis,123 and the risk of cancer in chronic pancreatitis is increased significantly by smoking. In hereditary pancreatitis, smoking has been found to lower the age of onset of carcinoma by about 20 years.124 Smoking therefore appears to be an inde-pendent risk factor for the late complications of alcoholic pan-creatitis, if not an early cofactor for the development of fibrosis.HyperparathyroidismHypercalcemia is a known cause of pancreatic hypersecretion,125 and chronic hypercalcemia caused by untreated hyperparathyroidism is associated with chronic calcific pancreatitis.126 Hypercalcemia is also a stimulant for pancreatic calcium secretion, which contributes to calculus formation and obstructive pancreatopathy. The treatment is correction of the hyperparathyroidism and assessment of any additional endocrinopathies.HyperlipidemiaIn addition to the risk of acute pancreatitis, hyperlipidemia and hypertriglyceridemia predispose women to chronic pancreatitis when they receive estrogen replacement therapy.127 Fasting tri-glyceride levels <300 mg/dL are below the threshold for this to occur, and the mechanism of estrogen potentiation of hyperlip-idemia-induced chronic pancreatitis is unknown. It is assumed that chronic changes occur after repeated subclinical episodes of acute inflammation. Aggressive therapy of hyperlipidemia is therefore important in perior postmenopausal patients who are candidates for estrogen therapy.ClassificationA major impediment to a better understanding of the etiology, frequency, and severity of chronic pancreatitis has been the dif-ficulty with which investigators and clinicians have struggled to identify a useful classification system. Multiple classification systems have been proposed. The TIGAR-O scheme catego-rizes chronic pancreatitis according to risk factors and etiolo-gies, such as (a) toxic-metabolic, (b) idiopathic, (c) genetic, (d) autoimmune, (e) recurrent and severe acute pancreatitis, or (f) obstructive.128 A recent classification system based on his-topathology as well as etiology was delineated by Singer and Chari.129Chronic Calcific (Lithogenic) PancreatitisThis type is the largest subgroup in the classification scheme proposed by Singer and Chari and includes patients with calcific pancreatitis of most etiologies. Although the majority of patients with calcific pancreatitis have a history of alcohol abuse, stone formation and parenchymal calcification can develop in a variety of etiologic subgroups; hereditary pancreatitis and tropical pan-creatitis are particularly noteworthy for the formation of stone disease. The clinician should therefore avoid the assumption that calcific pancreatitis confirms the diagnosis of alcohol abuse.Brunicardi_Ch33_p1429-p1516.indd 145201/03/19 6:44 PM 1453PANCREASCHAPTER 33Normal pancreasAlcoholMetabolic / oxidative stressSentinel eventAcinar cell injury(+ / – Necrosis)Inflammatory response:proinflammatory(Early)Anti-inflammatory (Later)Alcoholmetabolic/oxidative stressRecurrent acute pancreatitis(RAP)Anti-inflammatoryFibrosisHealedStressRAPNormal (Recovered):Normal:Stellate cells(Inactive)CytokinesChronicpancreatitis:FibrosisEarly acutepancreatitis: NeutrophilLymphocyteMacrophageStellate cell(Active)Collagen, etc.Late acutepancreatitis:M(Anti-inflam-matory)Necrosis = Stress, ETOHxxxxxxxxxxxxxFigure 33-19. The sentinel acute pancreatitis event (SAPE) hypothesis for the development of chronic pancreatitis. A critical episode of acute pancreatitis activates cytokine-induced transformation of pancreatic stellate cells, which results in collagen production and fibrosis. ETOH = ethyl alcohol. (Adapted with permission from Schneider A, Whitcomb DC: Hereditary pancreatitis: a model for inflammatory diseases of the pancreas, Best Pract Res Clin Gastroenterol. 2002 Jun;16(3):347-363.)Chronic Obstructive PancreatitisThis refers to chronic inflammatory changes that are caused by the compression or occlusion of the proximal ductal system by tumor, gallstone, posttraumatic scar, or inadequate duct caliber (as in pancreas divisum). Obstruction of the main pancreatic duct by inflammatory (posttraumatic) or neoplastic processes can result in diffuse fibrosis, dilated main and secondary pan-creatic ducts, and acinar atrophy. The patient may have little in Brunicardi_Ch33_p1429-p1516.indd 145301/03/19 6:44 PM 1454SPECIFIC CONSIDERATIONSPART IINormal pancreasAbsence of duct of SantoriniNormal pancreaswith duct of SantoriniPancreas divisumSmall ductof WirsungPancreas divisumNo duct of WirsungABCDFigure 33-20. Pancreas divisum. Normal pancreatic duct anatomy and the variations of partial or complete pancreas divisum are shown. (Reproduced with permission from Beger HG: The pancreas: an integrated textbook of basic science, medicine, and surgery. London: Blackwell-Science; 1998.)the way of pain symptoms or may present with signs of exo-crine insufficiency. Intraductal stone formation is rare, and both functional and structural abnormalities may improve when the obstructive process is relieved or removed. Trauma to the pan-creas frequently results in duct injury and leakage, which may result in pseudocyst formation as well as local scar formation. Inadequately treated pancreatic trauma may result in persistent inflammatory changes in the distal gland.130Pancreas divisum represents a special case of obstruc-tive pancreatitis. It is the most common congenital anomaly involving the pancreas and occurs in up to 10% of children. It is thought to predispose the pancreas to recurrent acute pan-creatitis and chronic pancreatitis, due to functional obstruction of a diminutive duct of Santorini that fails to communicate with Wirsung’s duct (Fig. 33-20). However, the classic pic-ture of obstructive pancreatopathy with a dilated dorsal duct is unusual in pancreas divisum, so a decompressive opera-tion or a lesser papilla sphincteroplasty is frequently not fea-sible or unsuccessful. Endoscopic stenting through the lesser papilla may result in temporary relief of symptoms, and this response would increase the possibility that a permanent sur-gical or endoscopic intervention will be successful. Although some authors emphasize the pathologic implications of pan-creas divisum,131 others express skepticism that it represents a true risk to pancreatic secretory capacity or contributes to the development of chronic pancreatitis.132,133A recent French study reveals that pancreas divisum is equally prevalent among patients with idiopathic chronic pancreatitis and normal con-trols (7%), and is minimally increased in patients with PRSS1 and SPINK1 mutations. It is accompanied by CFTR mutations in 47% of patients, however, suggesting that the presence of pancreas divisum together with mutational events may increase the susceptibility to pancreatitis.134Chronic Inflammatory PancreatitisChronic inflammatory pancreatitis is characterized by diffuse fibrosis and a loss of acinar elements with a predominant mono-nuclear cell infiltration throughout the gland.A variant of chronic pancreatitis is a nonobstructive, diffusely infiltrative disease associated with fibrosis, a mono-nuclear cell (lymphocyte, plasma cell, or eosinophil) infiltrate, and an increased titer of one or more autoantibodies.135 This type, referred to as autoimmune pancreatitis (AIP), is associated with a variety of illnesses with suspected or proven autoimmune etiology, such as Sjögren’s syndrome, rheumatoid arthritis, and type 1 diabetes mellitus. AIP has been characterized as either type I, with accompanying systemic or multiorgan dysfunction, or type II, which is restricted to the pancreas.Compressive stenosis of the intrapancreatic portion of the common bile duct is frequently seen in both types of AIP, along with symptoms of obstructive jaundice. Increased levels of serum β-globulin or immunoglobulin G4 are also present. Steroid therapy is uniformly successful in ameliorating the dis-ease, including any associated bile duct compression.136 CFTR mutations that result in dislocation of the transmembrane pro-tein have been found in AIP, and steroid therapy results in a nor-malization of the CFTR localization and a resumption of normal chloride and bicarbonate secretion.137 The differential diagnosis includes lymphoma, plasmacytoma (“pseudotumor” of the pan-creas) and diffuse infiltrative carcinoma. Although the diagnosis is confirmed on pancreatic biopsy, presumptive treatment with steroids is usually undertaken, especially when clinical and lab-oratory findings, such as an elevation in IgG4 levels, support the diagnosis. Failure to obtain a cytologic specimen may lead to an unnecessary resectional procedure, and an untreated inflam-matory component may cause sclerosis of the extrahepatic or intrahepatic bile ducts, with eventual liver failure.138Brunicardi_Ch33_p1429-p1516.indd 145401/03/19 6:44 PM 1455PANCREASCHAPTER 33Tropical (Nutritional) PancreatitisChronic pancreatitis is highly prevalent among adolescents and young adults in Indonesia, southern India, and tropical Africa. Abdominal pain develops in adolescence, followed by the development of a brittle form of pancreatogenic diabetes. Parenchymal and intraductal calcifications are seen, and the pancreatic duct stones may be quite large.139 Many of the patients appear malnourished, some present with extreme emaciation, and a characteristic cyanotic coloration of the lips may be seen.140 In addition to protein-caloric malnutrition, toxic products of some indigenous foodstuffs have also been thought to contribute to the disease. Because of the geographic concentration of this early-onset form of chronic pancreatitis, it has been termed tropical pancreatitis, although the exact etiology remains unclear.Clinically, tropical pancreatitis presents much like heredi-tary pancreatitis, and a familial pattern among cases is not unusual. SPINK1 mutations have been documented in 20% to 55% of patients with tropical pancreatitis, and CFTR mutations have been reported as well.106,107 The accelerated deteriora-tion of endocrine and exocrine function, the chronic pain due to obstructive disease, and the recurrence of symptoms despite decompressive procedures characterize the course of disease. As immigrants from the tropical regions increasingly find their way to all parts of the world, an awareness of this severe form of chronic pancreatitis is helpful for those who treat patients with pancreatic disease.Asymptomatic Pancreatic FibrosisPancreatic fibrosis is seen in some asymptomatic elderly patients, in tropical populations, or in asymptomatic alcohol users. There is diffuse perilobar fibrosis and a loss of acinar cell mass, but there is not a main ductular component. In addition, the presence of fibrosis and decreased exocrine function in patients with diabetes has raised the question of whether long-standing diabetes is a cause of chronic pancreatitis.141 Patients with this entity are usually asymptomatic in terms of typical pancreatic pain, and a recent histopathologic study of patients with typi-cal chronic pancreatitis and “diabetic exocrine pancreatopathy” reveals significant differences in morphology, including a virtual absence of duct distortion or obstruction (Fig. 33-21).142 It remains unknown whether this form of chronic inflammation precedes or contributes to the roughly twofold increase in the risk of pancreatic cancer in patients with long-standing diabetes.Idiopathic PancreatitisWhen a definable cause for chronic pancreatitis is lacking, the term idiopathic is used to categorize the illness. Classically, the idiopathic group includes young adults and adolescents who lack a family history of pancreatitis but who may represent indi-viduals with spontaneous gene mutations encoding regulatory proteins in the pancreas. A variable percentage of SPINK1 and CFTR mutations have been described in various studies. In addi-tion, the idiopathic group has included a large number of older patients for whom no obvious cause of recurrent or chronic pan-creatitis can be found.143 However, because the prevalence of biliary calculi increases steadily with age, it is not surprising that, as methods of biliary stone detection have improved, many elderly “idiopathic” pancreatitis patients are found to have bili-ary tract disease.144An increasing number of mutations of the SPINK1 and CFTR genes have been identified in association with various forms of chronic pancreatitis. However, the role of genetic analysis in the management of these patients remains unclear, as guidelines have yet to be developed to allow physicians to use the data consistently. Although the clinical management of patients who harbor a minor CFTR mutation and chronic pan-creatitis, for example, is still dictated by the clinical manifesta-tions of the pancreatitis, recent data suggest that the etiology of chronic pancreatitis, rather than the morphology, may determine the response to surgical treatment.145A shortcoming of these clinical classification systems is the lack of histologic criteria of chronic inflammation due to the usual absence of a biopsy specimen. The differentiation of recurrent acute pancreatitis from chronic pancreatitis with exac-erbations of pain can be difficult to establish and is not facili-tated by the current system. Similarly, cystic fibrosis is known to cause fibrosis and acinar dysfunction but is not included in the classification despite increasing evidence for its possible role in idiopathic chronic pancreatitis.146 Therefore, further refinements in the classification system for chronic pancreatitis Interacinarfibrosis0102030405060708090100AcinaratrophyInterlobularfibrosisStromalinflammationDuctaldistortionDuctalepithelialattenuationIslet amyloidCPDEPFigure 33-21. Comparative frequencies of key histolopathologic features of chronic pancreatitis (CP n = 7) and diabetic exocrine pancrea-topathy (DEP n = 9) (Reproduced with permission from Majumder S, Zhang L, Philip N, et al. Exocrine Pancreatopathy (EP) Associated With Diabetes Mellitus (DM) Is Histologically Distinct From Chronic Pancreatitis (CP): An International Multi-Reader Blinded Study, Gastroenterol 2016 April;150(4) Suppl 1: S191 (abstr).)Brunicardi_Ch33_p1429-p1516.indd 145501/03/19 6:44 PM 1456SPECIFIC CONSIDERATIONSPART IIFigure 33-22. Histology of early chronic pancreatitis. High-power microscopic (40x) histology of chronic pancreatitis shows an infil-tration of mononuclear inflammatory cells throughout the inter-stitium of the pancreas, with little fibrosis. (Used with permission from Rhonda Yantiss, Weill Cornell Medical College.)Figure 33-23. Gross appearance of chronic pancreatitis. Areas of fibrosis and scarring are seen adjacent to other areas within the gland in which the lobar architecture is grossly preserved. A dilated pancreatic duct indicates the presence of downstream obstruction in this specimen removed from a patient with chronic pancreatitis. (Used with permis-sion from Rhonda Yantiss, Weill Cornell Medical College.)Figure 33-24. Histology of severe chronic pancreatitis. High-power microscopic (40x) histologic appearance of advanced chronic pancre-atitis shows extensive sheets of fibrosis and loss of acinar tissue, with preservation of islet tissue in scattered areas. (Used with permission from Rhonda Yantiss, Weill Cornell Medical College.)are needed to allow a better prediction of its clinical course and a more accurate diagnosis of a likely etiologic agent.PathologyHistology. In early chronic pancreatitis, the histologic changes are unevenly distributed and are characterized by induration, nodular scarring, and lobular regions of fibrosis (Fig. 33-22). As the disease progresses, there is a loss of normal lobulation, with thicker sheets of fibrosis surrounding a reduced acinar cell mass and dilatation of ductular structures (Fig. 33-23). The ductular epithelium is usually atypical and may display features of dysplasia, as evidenced by cuboidal cells with hyperplastic features, accompanied by areas of mononuclear cell infiltrates or patchy areas of necrosis. Cystic changes may be seen, but areas of relatively intact acinar elements and normal-appearing islets persist. In severe chronic pancreatitis, there is considerable replacement of acinar tissue by broad, coalescing areas of fibrosis, and the islet size and number are reduced (Fig. 33-24). Small arteries appear thickened, and neural trunks become prominent.147Tropical pancreatitis and hereditary pancreatitis are histo-logically indistinguishable from chronic alcoholic pancreatitis. In obstructive chronic pancreatitis, calculi are absent, although periacinar fibrosis and dilated ductular structures are prominent. In pancreatic lobular fibrosis seen in elderly subjects, small ducts are dilated, sometimes with small calculi trapped within. Hypertrophy of ductular epithelia is thought to cause this small-duct disease, which is accompanied by perilobular fibrosis.148Fibrosis. A common feature of all forms of chronic pancreatitis is the perilobular fibrosis that forms surrounding individual acini, then propagates to surround small lobules, and eventually coalesces to replace larger areas of acinar tissue. The pathogenesis of this process involves the activation of pancreatic stellate cells (PSCs) that are found adjacent to acini and small arteries.149 The extended cytoplasmic processes of PSCs encircle the acini but appear quiescent in the normal gland, where they contain lipid vacuoles and cytoskeletal proteins. In response to pancreatic injury, the PSCs become activated and proliferate (similarly to hepatic stellate cells), lose their lipid vesicles, and transform into myofibroblast-like cells. These cells respond to proliferative factors such as transforming growth factor ®, platelet-derived growth factor, and proinflammatory cytokines that synthesize and secrete type I and III collagen and fibronectin. Studies indicate that vitamin A metabolites, similar to those present in quiescent PSCs, can inhibit the collagen production of activated cultured PSCs.150 This raises the possibility that early intervention may be possible to interrupt or prevent the fibrosis resulting from ongoing activation of PSCs.The overall pathogenic sequence proposed by Schneider and Whitcomb151 whereby alcohol induces acute pancreati-tis and, with ongoing exposure, promotes the development of chronic fibrosis, is summarized in Fig. 33-19. PSCs surround-ing the acinus are activated in acute pancreatitis but may be inactivated by anti-inflammatory cytokines and, in the absence of further injury, may revert to a quiescent state. The role of proinflammatory macrophages, cytokines, and PSCs in models of acute and chronic pancreatitis represents an important area of current research.Stone Formation. Pancreatic stones are composed largely of calcium carbonate crystals trapped in a matrix of fibrillar and other material. The fibrillar center of most stones contains no Brunicardi_Ch33_p1429-p1516.indd 145601/03/19 6:44 PM 1457PANCREASCHAPTER 33calcium but rather a mixture of other metals. This suggests that stones form from an initial noncalcified protein precipitate, which serves as a focus for layered calcium carbonate precipita-tion. The same low molecular weight protein is present in stones and protein plugs and was initially named pancreatic stone pro-tein, or PSP.152 PSP was found to be a potent inhibitor of calcium carbonate crystal growth and has subsequently been renamed lithostathine.153 Independently, a 15-kDa fibrillar protein iso-lated from the pancreas was named pancreatic thread protein, and it has been shown to be homologous with lithostathine. Finally, a protein product of the reg gene, so named because it is expressed in association with regenerating islets in models of pancreatic injury, was isolated and called reg protein and was subsequently found to be homologous with lithostathine.154 The PSP/pancreatic thread protein/reg/lithostathine gene encodes for a 166-amino acid product that undergoes posttranslational modification to produce isoforms present in pancreatic juice. The protein is expressed in all rodents and mammals, both in the pancreas as well as in brain tissue, where it is found in particu-larly high concentrations in pyramidal neurons in Alzheimer’s disease and Down syndrome. It is also found in the renal tubules, which is consistent with its biologic action of prevent-ing calcium carbonate precipitation.Calcium and bicarbonate ions are normally present in pan-creatic juice in high concentrations, and the solubility product of calcium carbonate is greatly exceeded under normal condi-tions. Microcrystals of calcium carbonate can be seen in normal pancreatic juice but are usually clinically silent. Lithostathine is a potent inhibitor of calcium carbonate crystal formation, at a concentration of only 0.1 μmol/L. However, lithostathine con-centrations in normal pancreatic juice are in the range of 20 to 25 μmol/L, so a constant suppression of calcium carbonate crystal formation is present in the normal pancreas.In alcoholics and in patients with alcoholic chronic pan-creatitis, lithostathine expression and secretion are dramati-cally inhibited155 (Fig. 33-25). In addition, elevated levels of precipitated lithostathine in the duct fluid in chronic pancreati-tis patients suggests that the availability of the protein may be further reduced by the action of increased proteases and other proteins present in the duct fluid of alcoholic patients. Increased pancreatic juice protein levels in alcoholic men are reversible by abstinence from alcohol,156 so the availability and effectiveness of lithostathine may be restored in patients with early-stage dis-ease by timely intervention. Nevertheless, calcific stone forma-tion represents an advanced stage of disease, which can further promote injury or symptoms due to mechanical damage to duct epithelium or obstruction of the ductular network.Duct Distortion. Although calcific stone disease is normally a marker for an advanced stage of disease, parenchymal and ductular calcifications do not always correlate with symptoms. Obstructing main duct stones are commonly observed and are thought to be an indication for endoscopic or surgical removal. The ball-valve effect of a stone in a secreting system produces inevitable episodes of duct obstruction, usually accompanied by pain. But some patients with complete duct obstruction have prolonged periods of painlessness. Ductular hypertension has been documented in patients with proximal stenosis of the main pancreatic duct, and prolonged ductular distention after secre-tin administration is taken as a sign of ductular obstruction.157 Although calculus disease and duct enlargement appear together as late stages of chronic pancreatitis, controversy persists over whether they are associated, are independent events, or are caus-ally related.Radiology. Radiologic imaging of chronic pancreatitis assists in four areas: (a) diagnosis, (b) the evaluation of severity of disease, (c) detection of complications, and (d) assistance in determining treatment options.158 With the advent of cross-sectional imaging techniques such as CT and MRI, the contour, content, ductal pattern, calcifications, calculi, and cystic disease of the pancreas are all readily discernible. Transabdominal ultrasonography is frequently used as a screening method for patients with abdominal symptoms or trauma, and the extension of ultrasonic imaging to include endoscopic ultrasound (EUS) and laparoscopic US have resulted in the highest-resolution images that are capable of detecting very small (<1 cm) abnormalities in the pancreas. EUS is now frequently used as a preliminary step in the evaluation of patients with pancreatic disease, and magnetic resonance cholangiopancreatography (MRCP) is increasingly being used to select patients who are candidates for the most invasive imaging method, ERCP. The staging of disease is important in the care of patients, and a combination of imaging methods is usually used (Table 33-12).Ultrasonography is frequently used as an initial imaging method in patients with abdominal symptoms, and changes con-sistent with pancreatic duct dilatation, intraductal filling defects, cystic changes, and a heterogeneous texture are seen in chronic pancreatitis (Fig. 33-26). The sensitivity of transabdominal ultrasonography ranges from 48% to 96%, and it is operator dependent.159 However, the contour, texture, and ductal pattern are usually quite discernible, and it is a reliable method for peri-odic reexamination to determine the efficacy of treatment.EUS has heavily impacted the evaluation and manage-ment of patients with chronic pancreatitis. Although it is more operator dependent than transabdominal ultrasonography, EUS provides not only imaging capability but also adds the capac-ity to obtain cytologic and chemical samples of tissue and fluid aspirated with linear array monitoring (Fig. 33-27). EUS images obtained through a high-frequency (7.5to 12.5-mHz) transducer are able to evaluate subtle changes in 2to 3-mm 50102030µg lithostathine/mg total proteinCCPAlc.OPDControlsFigure 33-25. Lithostathine levels in chronic calcific pancreatitis (CCP) patients, patients with alcohol abuse (Alc.), patients with other pancreatic disease (OPD), and controls. (Reproduced with permis-sion from Beger HG: The pancreas: an integrated textbook of basic science, medicine, and surgery. London: Blackwell-Science; 1998.)Brunicardi_Ch33_p1429-p1516.indd 145701/03/19 6:44 PM 1458SPECIFIC CONSIDERATIONSPART IITable 33-12Cambridge classification of pancreatic morphology in chronic pancreatitisCLASSIFICATIONERCP FINDINGSCT AND US FINDINGSNormalNo abnormal SBDsNormal gland size, shape; homogeneous parenchymaEquivocalMPD normalOne of the following: less than three abnormal SBDs; MPD 2–4 mm; gland enlarged more than two times normal size; heterogeneous parenchymaMildMPD normalTwo or more of the following: less than three abnormal SBDs; MPD 2–4 mm; slight gland enlargement; heterogeneous parenchymaModerate MPD changesSmall cysts <10 mm; MPD irregularitySBD changesFocal acute pancreatitis; increased echogenicity of MPD walls; gland-contour irregularitySevereAny of the above changes plus one or more of the following: cysts <10 mm; intraductal filling defects; calculi; MPD obstruction or stricture; severe MPD irregularity; contiguous organ invasion—Abbreviations: CT = computed tomography; ERCP = endoscopic retrograde cholangiopancreatography; MPD = main pancreatic duct; SBD = side-branch duct; US = ultrasound.Reproduced with permission from Beger HG: The Pancreas. London: Blackwell-Science; 1998.Figure 33-26. Sonography in chronic pancreatitis. Transabdomi-nal sonogram of patient with chronic pancreatitis demonstrates het-erogeneity of the pancreatic parenchyma, dilated ductal systems, and cyst formation. (Reproduced with permission from Bolondi L, Li Bassi S, Gaiani S, et al: Sonography of chronic pancreatitis, Radiol Clin North Am. 1989 Jul;27(4):815-833.)Figure 33-27. Endoscopic ultrasound of chronic pancreatitis. The endoscopic ultrasound appearance of the parenchyma is heteroge-neous, and dilated ducts are seen, indicating early obstructive pan-creatopathy. (Used with permission from Mark Topazian, Division of Digestive Diseases, Department of Medicine, Mayo Clinic.)structures within the pancreas and can detect indolent neoplasms in the setting of chronic inflammation. Small intraductal lesions, intraductal mucus, cystic lesions, and subtle ductular abnormali-ties are recognizable by EUS (Table 33-13). This allows ERCP to be reserved for these patients who require therapeutic maneu-vers, or for the evaluation of more complex problems. EUS is comparable to ERCP in the detection of advanced changes in chronic pancreatitis and may be more sensitive than ERCP in the detection of mild disease.160CT scanning has affected the diagnosis of pancreatic dis-ease more broadly than any other method. With the advent of faster helical CT scanning and CT angiography, visualization of the nature, extent, location, and relative relationships of pancre-atic structures and lesions is possible with great clarity. Duct dil-atation, calculous disease, cystic changes, inflammatory events, and anomalies are all detectable with a resolution of 3 to 4 mm (Fig. 33-28). CT scanning has a false-negative rate of <10% for chronic pancreatitis, but early or mild chronic disease may go undetected by CT imaging. The earliest changes are dilatation of secondary ducts and heterogeneous parenchymal changes, which are detectable by EUS and ERCP. Another drawback of CT scanning is its lower sensitivity for detecting small neo-plasms, which are seen with increased frequency in chronic pancreatitis and may be invisible to all modalities except EUS.An MRI, in both the cross-sectional mode and the coro-nally oriented heavily weighted T2 or high spin ratio imaging Brunicardi_Ch33_p1429-p1516.indd 145801/03/19 6:44 PM 1459PANCREASCHAPTER 33Table 33-13Endoscopic ultrasound features of chronic pancreatitisENDOSCOPIC ULTRASOUND FEATUREIMPLICATIONDuctal changes  Duct size >3 mmDuctal dilation Tortuous pancreatic ductDuctal irregularity Intraductal echogenic fociStones or calcification Echogenic duct wallDuctal fibrosis Side-branch ectasiaPeriductal fibrosisParenchymal changes  Inhomogeneous echo patternEdema Reduced echogenic foci (1–3 mm)Edema Enhanced echogenic fociCalcifications Prominent interlobular septaeFibrosis Lobular outer gland marginFibrosis, glandular atrophy Large, echo-poor cavities (>5 mm)PseudocystReproduced with permission from Catalano MF, Lahoti S, Geenen JE, et al. Prospective evaluation of endoscopic ultrasonography, endoscopic retrograde pancreatography, and secretin test in the diagnosis of chronic pancreatitis, Gastrointest Endosc. 1998 Jul;48(1):11-17.(MRCP) that can disclose fluid-filled ducts and cystic lesions, has added greatly to the imaging options for chronic pancreatitis (Fig. 33-29). The resolution of cross-sectional MRI scanning is now approaching that of CT scanning, although the availability of MRI scanners and the complexity of the images produced have limited their large-scale use for routine imaging of the pancreas. MRCP has been shown to be an effective screening technique for disclosing ductal abnormalities that correlates closely with the contrast-filled ducts imaged by ERCP.161 The advantages of MRCP include its noninvasive methodology and Figure 33-28. Computed tomographic imaging of chronic pancre-atitis. A dilated pancreatic duct is seen, with evidence of intraductal stones and parenchymal calcification. (Reproduced with permission from Forsmark CE: Management of chronic pancreatitis, Gastroen-terology. 2013 Jun;144(6):1282-1291.)Figure 33-29. Coronal T2-weighted magnetic resonance image showing evidence of chronic pancreatitis, including a pancreatic duct dilatation and side-branch clubbing. (Used with permission from Mellena Bridges, MD, Mayo Clinic Jacksonville, Department of Radiology.)its ability to image obstructed ducts that are not opacified by ERCP injection. It is therefore a useful screening study to detect duct abnormalities and to confirm the need for interventional procedures. Oral, IV, and intraductal contrast are unnecessary for MRCP, and its lack of ionizing radiation makes this the saf-est method to image the ductal system in high-risk patients.For the diagnosis and staging of chronic pancreatitis, ERCP is considered to be the gold standard. It also serves as a vehicle that enables other diagnostic and therapeutic maneu-vers, such as biopsy or brushing for cytology, or the use of stents to relieve obstruction or drain a pseudocyst (Fig. 33-30). Figure 33-30. Pancreatic duct stenting. At endoscopic retrograde cholangiopancreatography, a stent is placed in the proximal pan-creatic duct to relieve obstruction and reduce symptoms of pain. Pancreatic duct stents are left in place for only a limited time to avoid further inflammation.Brunicardi_Ch33_p1429-p1516.indd 145901/03/19 6:44 PM 1460SPECIFIC CONSIDERATIONSPART IIFigure 33-31. Pain location in chronic pancreatitis. (Reproduced with permission from Greenfield LJ, Mulholland MW, Oldham KT, et al: Surgery, Scientific Principles and Practice, 3rd ed. Philadelphia, PA: Lippincott Williams & Wilkins; 2001.)Unfortunately, ERCP also carries a risk of procedure-induced pancreatitis that occurs in approximately 5% of patients.161 Patients at increased risk include those with sphincter of Oddi dysfunction and those with a previous history of post-ERCP pancreatitis. Post-ERCP pancreatitis occurs after uncompli-cated procedures, as well as after those that require prolonged manipulation. Severe pancreatitis and deaths have occurred after ERCP. It should be reserved for patients in whom the diagnosis is unclear despite the use of other imaging methods, or in whom a diagnostic or therapeutic maneuver is specifically indicated.Presentation, Natural History, and ComplicationsPresenting Signs and Symptoms. Pain is the most common symptom of chronic pancreatitis. It is usually midepigastric in location but may localize or involve either the left or right upper quadrant of the abdomen. Occasionally, it is perceived in the lower midabdomen but is frequently described as penetrating through to the back (Fig. 33-31). The pain is typically steady and boring, but not colicky. It persists for hours or days and may be chronic with exacerbations caused by eating or drink-ing alcohol. Chronic alcoholics also describe a steady, constant pain that is temporarily relieved by alcohol, followed by a more severe recurrence hours later.Patients with chronic pancreatic pain typically flex their abdomen and either sit or lie with their hips flexed, or lie on their side in a fetal position. Unlike ureteral stone pain or biliary colic, the pain causes the patient to be still. Nausea or vomit-ing may accompany the pain, but anorexia is the most common associated symptom.Pain from chronic pancreatitis has been ascribed to multiple etiologies. Ductal hypertension, due to strictures or stones, may predispose to pain that is initiated or exacerbated by eating. Chronic pain without exacerbation may be related to parenchymal disease or retroperitoneal inflammation with per-sistent neural involvement. Acute exacerbations of pain in the setting of chronic pain may be due to acute increases in duct pressure or recurrent episodes of acute inflammation in the set-ting of chronic parenchymal disease. Nealon and Matin have described these various pain syndromes as being predictive of the response to various surgical procedures.162 Pain that is found in association with ductal hypertension is most readily relieved by pancreatic duct decompression, through endoscopic stenting or surgical decompression.The surgical relief of pain due to obstructive pancreatopa-thy may be dependent on the degree of underlying fibrosis and the etiology of the disease rather than the presence of ductal obstruction, per se, according to a recent studies from Johns Hopkins. Cooper et al studied 35 patients with chronic pain associated with evidence of duct obstruction who were treated with local resection of the pancreatic head and longitudinal pan-creaticojejunostomy (LR-LPJ), or Frey procedure.163 The degree of pain resolution after surgery was compared to the degree of underlying parenchymal fibrosis. After a follow-up that averaged 22 months, patients with more than 80% fibrosis had 100% pain relief, whereas only 60% patients with less than 10% fibrosis experienced substantial or complete pain relief. Subsequently, this group studied 60 patients who had undergone either the Frey procedure or the Whipple procedure for refractory pain due to chronic pancreatitis.145 In addition to histopathologic findings, they also analyzed the etiology of the disease. Of patients with “toxic” etiologies of acquired disease (i.e., a history of alcohol or tobacco abuse), 89% experienced prolonged pain relief, whereas only 39% of those with hereditary or idiopathic disease achieved this result. Further, these results were independent of the degree of pancreatic fibrosis. These findings suggest that the etiology of the disease may be the most important predictor of the ben-efit of a resectional or hybrid procedure, and that patients with idiopathic or hereditary disease might be considered for an alter-native approach, such as total pancreatectomy with islet auto-transplantation (see following section).The pain of chronic pancreatitis may decrease or disappear completely over a period of years, as symptoms of exocrine and endocrine deficiency become apparent.164 This is referred to as burned out pancreatitis and correlates with the progression of disease from a mild or moderate stage to severe destruction of the pancreas. Although this evolution of painful to nonpainful disease is sometimes used as a justification to avoid intervention in painful chronic pancreatitis, noninterventional approaches to the treatment of chronic pancreatitis are inevitably accompanied by the development of narcotic addiction, inability to work, and the sequelae of chronic illness.Although increased ductal pressure, and therefore paren-chymal pressure, has been thought to be the cause of pain in chronic obstructive pancreatitis, the role of chronic inflamma-tion per se, and the development of actual nerve damage in the diseased gland, are also thought to contribute to pain.165 Chronic inflammation results in the infiltration of tissue by macrophages, which secrete prostaglandins and other nociceptive agents that cause chronic stimulation of afferent neural fibers. Inflamma-tory damage to the perineurial layers surrounding the unmyelin-ated pancreatic nerves and a focal infiltration of inflammatory cells around nerves suggest that neural fibers are a target for the cellular response to inflammation in the pancreas.166Strategies to relieve pain are therefore based on three approaches: (a) reducing secretion and/or decompress the secre-tory compartment, (b) resecting the focus of chronic inflamma-tory change, or (c) interrupting the transmission of afferent neural impulses through neural ablative procedures. A trial of antisecre-tory therapy or endoscopic duct drainage may select those patients who will benefit preferentially from a decompressive procedure.Brunicardi_Ch33_p1429-p1516.indd 146001/03/19 6:45 PM 1461PANCREASCHAPTER 33Central Nervous System Abnormalities• Functional reorganization• Central sensitization (cortical)Central NervousSystem Abnormalities• Central sensitization (spinal)Obstructive Abnormalities• Pancreatic duct hypertension• Pancreatic parenchymal hypertension• Pancreas morphologyPancreatic and extrapancreatic complications• Pseudocysts• Duodenal or/and bile duct obstruction• Peptic ulcer• Splenic vein thrombosisAdditional causes• CCK elevation• Increased norepinephrine levels• Mesenteric ischemia (Type 3c diabetes)• Diabetic neuropathy (Type 3c diabetes)Peripheral NervousSystem Abnormalities• Pancreatic nociception• Pancreatic neuropathy and neuroplasticityAdverse effects to treatment• Opioid induced bowel dysfunction• Complications to surgery and endoscopic therapy• Bacterial overgrowth due to changed bowel motilityCentral Nervous System Abnormalities• Impaired inhibitory pain modulationFigure 33-32. Pain mechanisms in chronic pancreatitis. (Reproduced with permission from Demir IE, Tieftrunk E, Maak M, et al: Pain mechanisms in chronic pancreatitis: of a master and his fire, Langenbecks Arch Surg. 2011 Feb;396(2):151-160.)Patients with chronic pain due to chronic pancreatitis are often treated for years with escalating doses of narcotics, which imposes the additional problem of opioid dependency on this population. Further, it is now apparent that the pain pattern of many patients may be described as being either “visceral pain,” caused by inflammation in and around the pancreas, or “central sensitization of pain,” which is a syndrome of increased pain perception and sensitivity caused by the prolonged presence of pain167 (Fig. 33-32). Recent studies have suggested a method to differentiate these pain processes and further suggest that drugs that decrease or ameliorate the central sensitization of pain, such as pregabalin and tramadol, may be especially useful in chronic pancreatitis patients.168 These methods of differential diagnosis of pain syndromes now appear to offer the means by which it is possible to further identify and predict which patients will ben-efit from a surgical approach to chronic pancreatitis.169Malabsorption and Weight Loss. When pancreatic exocrine capacity falls below 10% of normal, diarrhea and steatorrhea develop170 (Fig. 33-33). Patients describe a bulky, foul-smelling, loose (but not watery) stool that may be pale in color and float on the surface of toilet water. Frequently, patients will describe a greasy or oily appearance to the stool, or may describe an “oil slick” on the water’s surface. In severe steatorrhea, an orange, 6040207010255075Fecal fat excretion (g/day)Normal lipase output (%)Figure 33-33. Relationship of lipase output to fat malabsorption. Excess fecal fat appears when the pancreatic lipase output falls below 10% of normal secretory values. (Data from DiMagno EP, Go VL, Summerskill WH. Relations between pancreatic enzyme out-puts and malabsorption in severe pancreatic insufficiency, N Engl J Med. 1973 Apr 19;288(16):813-815.)Brunicardi_Ch33_p1429-p1516.indd 146101/03/19 6:45 PM 1462SPECIFIC CONSIDERATIONSPART IIoily stool is often reported. As exocrine deficiency increases, symptoms of steatorrhea are often accompanied by weight loss. Patients may describe a good appetite despite weight loss or diminished food intake due to abdominal pain.In severe symptomatic chronic pancreatitis, anorexia or nausea may occur with or separate from abdominal pain. The combination of decreased food intake and malabsorption of nutrients usually results in chronic weight loss. As a result, many patients with severe chronic pancreatitis are below ideal body weight.Lipase deficiency tends to manifest itself before trypsin deficiency, so the presence of steatorrhea may be the first func-tional sign of pancreatic insufficiency.171 As pancreatic exocrine function deteriorates further, the secretion of bicarbonate into the duodenum is reduced, which causes duodenal acidification and further impairs nutrient absorption.172 Pancreatic exocrine insufficiency is frequently asymptomatic, however, and pancre-atic exocrine function is difficult to measure, so a diagnosis of chronic pancreatitis is sufficient to justify a trial of pancreatic enzyme supplements. Each meal should be followed by 90,000 United States Pharmacopeia units of lipase, and the metabolic and symptomatic status of the patients should be followed.173Pancreatogenic Diabetes. The islets comprise only 2% of the mass of the pancreas, but they are preferentially conserved when pancreatic inflammation occurs. In chronic pancreatitis, acinar tissue loss and replacement by fibrosis is greater than the degree of loss of islet tissue. Islets are typically smaller than normal and may be isolated from their surrounding vascular network by the fibrosis. With progressive destruction of the gland, endocrine insufficiency commonly occurs. Frank diabetes is seen initially in about 20% of patients with chronic pancreatitis, and impaired glucose metabolism can be detected in up to 70% of patients. In a study of 500 patients with predominantly alcoholic chronic pancreatitis, diabetes developed in 83% within 25 years of the clinical onset of chronic pancreatitis, and more than half of the diabetic patients required insulin treatment.174 Ketoacidosis and diabetic nephropathy are relatively uncommon in pancreato-genic diabetes (see Table 33-3), but retinopathy and neuropathy are seen to occur with a similar frequency as in type 1 and type 2 diabetes.175Pancreatogenic diabetes is most common in cases of chronic pancreatitis, and it is often seen after surgical resec-tion for benign or malignant disease176,177 (Fig. 33-34). Distal Hemochromatosis8%Cystic ÿbrosis4%Pancreatic resection3%Chronic pancreatitis76%Pancreaticneoplasia9%A Distribution of T1DM, T2DM and T3cDMB Distribution of causes of T3cDMT3cDM8%T1DM12%T2DM80%Figure 33-34. Distribution of types of diabetes (A) and causes of type 3c (pancreatogenic) diabetes (B) based on studies of 1922 diabetic patients referred to an academic medical center as reported by Hardt et al. (Data from Hardt PD, Brendel MD, Kloer HU et al: Is pancreatic diabetes (type 3c diabetes) underdiagnosed and misdiagnosed? Diabetes Care. 2008 Feb;31 Suppl 2:S165-S169.)pancreatectomy and Whipple procedures have a higher inci-dence of diabetes than do drainage procedures, and the severity of diabetes is usually worse after subtotal or total pancreatec-tomy. Pancreatogenic, or type 3c diabetes (T3cDM), is seen in cystic fibrosis, in association with pancreatic cancer, and in cases of severe hemochromatosis.178The etiology and pathophysiology of pancreatogenic diabetes is distinct from that of either autoimmune (type 1) or obesity-related (type 2) diabetes. In type 3c diabetes, the loss of functioning pancreatic tissue by disease or surgical removal results in a global deficiency of all three glucoregulatory islet cell hormones: insulin, glucagon, and PP. In addition, there is a paradoxical combination of enhanced peripheral sensitivity to insulin and decreased hepatic sensitivity to insulin.178,179 As a result, insulin therapy is frequently difficult; patients are hyper-glycemic when insulin replacement is insufficient (due to unsup-pressed hepatic glucose production) or hypoglycemic when insulin replacement is barely excessive (due to enhanced periph-eral insulin sensitivity and a deficiency of pancreatic glucagon secretion to counteract the hypoglycemia). This form of diabetes is referred to as brittle diabetes and requires special attention.PP deficiency correlates with the severity of chronic pan-creatitis, and impairments in the hepatic action of insulin are reversed in PP-deficient chronic pancreatitis patients by admin-istration of PP.180 In addition, a study of type 1 and type 3c diabetic patients treated with insulin pump therapy revealed that the addition of a continuous subcutaneous infusion of PP reduced the insulin requirements needed for glycemic control.181 Studies are currently underway to identify a clinically suitable PP analog or PP receptor agonist.Laboratory Studies. The diagnosis of chronic pancreatitis depends on the clinical presentation, a limited number of indirect measurements that correlate with pancreatic function, and selected imaging studies (Table 33-14). The direct measurement of pancreatic enzymes (e.g., lipase and amylase) by blood test is highly sensitive and fairly specific in acute pancreatitis but is seldom helpful in the diagnosis of chronic pancreatitis. The pancreatic endocrine product that correlates most strongly with chronic pancreatitis is the PP response to a test meal (Fig. 33-35). Severe chronic pancreatitis is associated with a blunted or absent PP response to feeding but, as with many other tests, a normal PP response does not rule out the presence of early disease.14Brunicardi_Ch33_p1429-p1516.indd 146201/03/19 6:45 PM 1463PANCREASCHAPTER 33The measurement of pancreatic exocrine secretion requires aspiration of pancreatic juice from the duodenum after nutrient (Lundh test meal) or hormonal (CCK or secretin) stimulation.182,183 Direct aspiration of pancreatic juice by endoscopic cannulation of the duct is performed in some centers, but it is not risk free, comfortable for the patient, or more sensitive than luminal intubation methods.184Indirect tests of pancreatic exocrine function are based on the measurement of metabolites of compounds that are altered (“digested”) by pancreatic exocrine products and can be quantified by serum or urine measurements. A commonly used indirect test is the bentiromide test, in which N-benzoyl-Ltyrosyl-p-aminobenzoic acid is ingested by the subject, and the urinary excretion of the proteolytic metabolite p-aminobenzoic Table 33-14Tests for chronic pancreatitis               I. Measurement of pancreatic products in blood A. Enzymes B. Pancreatic polypeptide   II. Measurement of pancreatic exocrine secretion A. Direct measurements 1. Enzymes 2. Bicarbonate B. Indirect measurement 1. Bentiromide test 2. Schilling test 3. Fecal fat, chymotrypsin, or elastase concentration 4. [14C]-olein absorption III. Imaging techniques A. Plain film radiography of abdomen B. Ultrasonography C. Computed tomography D. Endoscopic retrograde cholangiopancreatography E. Magnetic resonance cholangiopancreatography F. Endoscopic ultrasonography04080120160Time (min)206010014018004080120160200–40IR-pancreatic polypeptide (pmol/L)NLCPFigure 33-35. Pancreatic polypeptide (PP) response to a test meal. Immunoreactive PP (IR-PP) responses in control subjects (NL, n = 6) and patients with severe chronic pancreatitis (CP) accom-panied by PP deficiency (CP, n = 5) are shown. A test meal was administered at 0 minutes. Means ± standard error of the mean are shown. (Reproduced with permission from Brunicardi FC, Chaiken RL, Ryan AS, et al. Pancreatic polypeptide administration improves abnormal glucose metabolism in patients with chronic pancreatitis, J Clin Endocrinol Metab. 1996 Oct;81(10):3566-3572.)acid (PABA) is measured.185 Although the sensitivity of the test is as high as 100% in patients with severe chronic pancreati-tis, it identifies only 40% to 50% of patients with mild disease, and reduced PABA excretion is found in patients with a variety of other GI, hepatic, and renal diseases. The quantification of stool fat has also been used as a measure of pancreatic lipase secretion, either through the direct measurement of total fecal fat levels while the subject consumes a diet of known fat con-tent, or by the measurement of exhaled 14CO2 after ingestion of [14C]-triolein or [14C]-olein. This so-called triolein breath test is less cumbersome than intubation methods and avoids the necessity of stool collections and analysis, but it also has a high false-negative rate.186Fecal levels of chymotrypsin187 and elastase188 have been proposed as simpler, less expensive tests of exocrine function and correlate well with loss of pancreatic function. As with other test methods, however, these tests lose their sensitivity in patients with mild to moderate chronic pancreatitis and may be more sensitive for other causes of pancreatic dysfunction, including cystic fibrosis. Fecal elastase C1 measurements have become widespread in their use, and levels above 200 μg/g are considered normal, whereas levels below 100 μg/g are indica-tive of pancreatic exocrine insufficiency.189 The sensitivity and specificity of fecal elastase C1 measurements fall short of those needed for definitive diagnosis of pancreatic exocrine insuffi-ciency, however.190Radiologic imaging has become the principal method of diagnosis of chronic pancreatitis, with the codification of clas-sification systems that correlate with proven disease. ERCP has been considered the most sensitive radiologic test for the diagnosis of chronic pancreatitis, with specific ERCP findings that are highly correlative with the degree or stage of chronic disease191 (Table 33-15). CT scanning is sensitive for the diag-nosis of chronic pancreatitis when calcification, duct dilata-tion, or cystic disease is present, but it is not accurate in the absence of these findings. CT is helpful as a screening study to guide interventional therapy or other diagnostic modalities,158 although EUS has become the preferred method for the diagno-sis of pancreatic disease and offers the advantage of very-high-resolution images of the pancreatic parenchyma, the main and secondary ductal systems, cystic lesions, and calcific changes. Table 33-15Cambridge classification of chronic pancreatitis by endoscopic retrograde cholangiopancreatographyGRADEMAIN PANCREATIC DUCTSIDE BRANCHESNormalNormalNormalSuggestiveNormal<3 AbnormalMildNormal≥3 AbnormalModerateAbnormal>3 AbnormalSevereAbnormal plus at least one of the following: large cavity, duct obstruction, dilation or duct irregularity, intraductal filing defects Reproduced with permission from Axon AT, Classen M, Cotton PB, et al: Pancreatography in chronic pancreatitis: international definitions, Gut. 1984 Oct;25(10):1107-1112.Brunicardi_Ch33_p1429-p1516.indd 146301/03/19 6:45 PM 1464SPECIFIC CONSIDERATIONSPART II246810060NonalcoholicsPancreatico-duodenectomyalcoholicsAlcoholics; 40–80%distal pancreatectomyAlcoholics; 80–95%distal pancreatectomyYears after surgical procedurePercent surviving1214708090100Figure 33-36. Effect of alcohol use on survival after surgical procedures. The cumulative survival of patients with chronic pancreatitis fol-lowing pancreaticoduodenectomy or distal pancreatectomy is shown for nonalcoholic and alcoholic patients. (Reproduced with permission from Frey CF, Child CG, Fry W. Pancreatectomy for chronic pancreatitis, Ann Surg. 1976 Oct;184(4):403-413.)EUS findings may be inconclusive in mild or “minimal change” pancreatitis, however, and improved criteria for an EUS-based diagnosis are still a work in progress.192 Most importantly, EUS is highly reliable in ruling out pancreatic carcinoma when CT findings are normal or equivocal.Prognosis and Natural History. The prognosis for patients with chronic pancreatitis is dependent on the etiology of the disease, the development of complications, and on the age and socioeconomic status of the patient. The influence of treat-ment is less evident in long-term studies, although the general absence of randomized, prospective trials clouds the issue of whether specific forms of therapy alter the long-term outlook for patients with the disease.Several studies have demonstrated that, although symp-toms of pain decrease over time in about half of the patients, this decline is also accompanied by a progression of exocrine and endocrine insufficiency.193 In general, the likelihood of eventual pain relief is dependent upon the stage of disease at diagnosis, and the persistence of alcohol use in patients with alcoholic chronic pancreatitis. Miyake and colleagues found that pain relief was achieved in 60% of alcoholic patients who suc-cessfully discontinued drinking, but in only 26% who did not.194The long-term survival of patients with chronic pancreatitis is less than for patients without pancreatitis. In an international multicenter study of >2000 patients, Lowenfels and colleagues found that the 10and 20-year survival rates for patients with chronic pancreatitis were 70% and 45%, respectively, compared to 93% and 65% for patients without pancreatitis.195 The mortality risk was found to be 1.6-fold higher in patients who continued to abuse alcohol, compared to those who did not. Continued alcohol abuse has a similar effect on the response to surgical treatment (Fig. 33-36), and results in a twofold increase in mortality over a 10to 14-year follow-up period.195In addition to progressive endocrine and exocrine dysfunc-tion, and the risk of the specific complications outlined here and in Table 33-16, the other significant long-term risk for the patient with chronic pancreatitis is the development of pancre-atic carcinoma.196 There is a progressive, cumulative increased risk of carcinoma development in patients with chronic pancre-atitis, which continues throughout the subsequent lifetime of the patient (Fig. 33-37). The incidence of carcinoma in patients with chronic pancreatitis ranges from 1.5% to 6%,196 which is at least 10-fold greater than that of patients of similar age seen in a hospital setting. In patients with chronic pancreatitis accom-panied by diabetes, the risk of carcinoma has been found to be increased 12to 33-fold compared to healthy, comparably aged controls.197,198 In patients with advanced chronic pancreatitis referred for surgical therapy, indolent, undiagnosed carcinoma can be seen in as many as 10% of patients.199The development of carcinoma in the setting of chronic pancreatitis is no doubt related to the dysregulation of cellu-lar proliferation and tissue repair processes in the setting of chronic inflammation, as is seen throughout the alimentary tract and elsewhere. In the setting of chronic pancreatitis, car-cinoma development can be especially cryptic, and the diagno-sis of early-stage tumors is particularly difficult. Awareness of this risk justifies close surveillance for cancer in patients with chronic pancreatitis. Periodic measurement of tumor markers such as CA19-9, and periodic imaging of the pancreas with CT scan and EUS seem logical in order to detect the development Table 33-16Complications of chronic pancreatitisIntrapancreatic complications Pseudocysts  Duodenal or gastric obstruction  Thrombosis of splenic vein  Abscess  Perforation  Erosion into visceral artery Inflammatory mass in head of pancreas  Bile duct stenosis  Portal vein thrombosis  Duodenal obstruction Duct strictures and/or stones  Ductal hypertension and dilatation Pancreatic carcinomaExtrapancreatic complications Pancreatic duct leak with ascites or fistula Pseudocyst extension beyond lesser sac into mediastinum, retroperitoneum, lateral pericolic spaces, pelvis, or adjacent visceraBrunicardi_Ch33_p1429-p1516.indd 146401/03/19 6:45 PM 1465PANCREASCHAPTER 33Table 33-17Definitions of pancreatic fluid collectionsTERMDEFINITIONPeripancreatic fluid collectionA collection of enzyme-rich pancreatic juice that occurs early in the course of acute pancreatitis, or that forms after a pancreatic duct leak; located in or near the pancreas; it lacks a well-organized wall of granulation or fibrous tissueEarly pancreatic (sterile) necrosisA focal or diffuse area of nonviable pancreatic parenchyma, typically occupying >30% of the gland and containing liquefied debris and fluidLate pancreatic (sterile) necrosisAn organized collection of sterile necrotic debris and fluid with a well-defined margin or wall within the normal domain of the pancreasAcute pseudocystA collection of pancreatic juice enclosed within a perimeter of early granulation tissue, usually as a consequence of acute pancreatitis that has occurred within the preceding 3–4 wkChronic pseudocystA collection of pancreatic fluid surrounded by a wall of normal granulation and fibrous tissue, usually persisting for >6 wkPancreatic abscessAny of the above in which gross purulence (pus) is present, with bacterial or fungal organisms documented to be presentModified with permission from Baron TH, Harewood GC, Morgan DE, et al. Outcome differences after endoscopic drainage of pancreatic necrosis, acute pancreatic pseudocysts, and chronic pancreatic pseudocysts, Gastrointest Endosc. 2002 Jul;56(1):7-17.Years after diagnosis of pancreatitisCumulative incidence of pancreatic cancer (%)12345605101520(1160)(599)(244)(64)Figure 33-37. Cumulative risk of pancreatic cancer in patients with chronic pancreatitis. The number of patients evaluated at different time intervals is shown in parentheses. (Reproduced with permis-sion from Lowenfels AB, Maisonneuve P, Cavallini G, et al. Pancre-atitis and the risk of pancreatic cancer. International Pancreatitis Study Group, N Engl J Med. 1993 May 20;328(20):1433-1437.)of carcinoma in the patient with chronic pancreatitis, although no evidence exists to indicate that this alters the outcome of patients who develop pancreatic cancer. Surgical procedures, particularly drainage procedures performed for presumed chronic pancreatitis, should always include biopsy of the tissue to exclude the diagnosis of malignancy.ComplicationsPseudocyst. A chronic collection of pancreatic fluid surrounded by a nonepithelialized wall of granulation tissue and fibrosis is referred to as a pseudocyst. Pseudocysts occur in up to 10% of patients with acute pancreatitis, and in 20% to 38% of patients with chronic pancreatitis, and thus, they comprise the most com-mon complication of chronic pancreatitis.200-202 The identification and treatment of pseudocysts requires definition of the various forms of pancreatic fluid collections that occur (Table 33-17). In chronic pancreatitis, a pancreatic duct leak with extravasa-tion of pancreatic juice results in a peripancreatic fluid collection (PPFC). Over a period of 3 to 4 weeks, the PPFC is sealed by an inflammatory reaction that leads to development of a wall of acute granulation tissue without much fibrosis. This is referred to as an acute pseudocyst. Acute pseudocysts may resolve spontane-ously in up to 50% of cases, over a course of 6 weeks or longer.203 Pseudocysts >6 cm resolve less frequently than smaller ones but may regress over a period of weeks to months. Pseudocysts are multiple in 17% of patients,202 or they may be multilobulated. They may occur intrapancreatically or extend beyond the region of the pancreas into other cavities or compartments (Fig. 33-38).Pseudocysts may become secondarily infected, in which case they become abscesses. They can compress or obstruct adjacent organs or structures, leading to superior mesenteric-portal vein thrombosis or splenic vein thrombosis.204 They can erode into visceral arteries and cause intracystic hemorrhage or pseudoaneurysms (Fig. 33-39). They also can perforate and cause peritonitis or intraperitoneal bleeding.205Figure 33-38. Extensive pseudocyst disease. A computed tomo-graphic scan in a patient with alcoholic chronic pancreatitis dem-onstrates multiloculated pseudocyst disease.Pseudocysts usually cause symptoms of pain, fullness, or early satiety. Asymptomatic pseudocysts can be managed expectantly and may resolve spontaneously or persist without complication.201,203 Symptomatic or enlarging pseudocysts require treatment, and any presumed pseudocyst without a documented antecedent episode of acute pancreatitis requires investigation to determine the etiology Brunicardi_Ch33_p1429-p1516.indd 146501/03/19 6:45 PM 1466SPECIFIC CONSIDERATIONSPART IIFigure 33-39. Pseudoaneurysm of the gastroduodenal artery. A pseudocyst can erode into an adjacent artery, which results in contained hemorrhage otherwise known as a pseudoaneurysm. A contrast-injected computed tomographic scan reveals active bleed-ing (area marked B) into a pseudocyst (arrows) as a result of this process. (Reproduced with permission from Balthazar EJ: CT diagnosis and staging of acute pancreatitis, Radiol Clin North Am. 1989 Jan;27(1):19-37.)of the lesion, including a cystic neoplasm.205 Although pseudocysts comprise roughly two-thirds of all pancreatic cystic lesions, they resemble cystadenomas and cystadenocarcinoma radiographically. An incidentally discovered cystic lesion should be examined by EUS and aspirated to determine whether it is a true pancreatic cystic neoplasm or a pseudocyst.The timing and method of treatment requires careful con-sideration. Pitfalls in the management of pseudocysts result from the incorrect (presumptive) diagnosis of a cystic neoplasm masquerading as a pseudocyst, a failure to appreciate the solid or debris-filled contents of a pseudocyst that appears to be fluid filled on CT scan, and a failure to document true adherence with an adjacent portion of the stomach before attempting transgas-tric internal drainage.If the pseudocyst has failed to resolve with conserva-tive therapy and symptoms persist, internal drainage is usu-ally preferred to external drainage to avoid the complication of a pancreaticocutaneous fistula. Pseudocysts communicate with the pancreatic ductal system in up to 80% of cases,206 so external drainage creates a pathway for pancreatic duct leak-age to and through the catheter exit site. Internal drainage may be performed with either endoscopic methods (transgastric or transduodenal puncture and multiple stent placements, with or without a nasocystic irrigation catheter), or surgical methods (a true cystoenterostomy, biopsy of cyst wall, and evacuation of all debris and contents). Surgical options include a cystogastros-tomy (Fig. 33-40), a Roux-en-Y cystojejunostomy, or a cysto-duodenostomy. Cystojejunostomy is the most versatile method, and it can be applied to pseudocysts that penetrate into the trans-verse mesocolon, the paracolic gutters, or the lesser sac. Cys-togastrostomy can be performed endoscopically207 (Fig. 33-41), laparoscopically,208 or by a combined laparoscopic-endoscopic method.209Because pseudocysts often communicate with the pan-creatic ductal system, two newer approaches to pseudocyst management are based on main duct drainage, rather than pseu-docyst drainage per se. Transpapillary stents inserted at the time Figure 33-40. Cystogastrostomy drainage of a retrogastric pancre-atic pseudocyst. A larger opening is made through the common wall of a retrogastric pseudocyst, and a portion of the pseudocyst wall is submitted for histologic confirmation of the diagnosis. Suture reinforcement of the communication is performed to avoid the com-plication of bleeding. (Reproduced with permission from Bell RH, Rikkers LF, Mulholland M: Digestive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)StomachFNAneedlePseudocystDuodenumPancreasLiverPseudocystDoublepigtailedstentsPancreasStomachEUSscopeABFigure 33-41. Technique of endoluminal cystogastrostomy. A. Endoscopic ultrasound (EUS)-guided transgastric puncture of pancreatic pseudocyst. B. Transgastric stents placed across fused posterior wall of stomach and anterior wall of pseudocyst. (Repro-duced with permission from Chauhan SS, Forsmark CE. Evidence-based treatment of pancreatic pseudocysts, Gastroenterology. 2013 Sep;145(3):511-5113.)Brunicardi_Ch33_p1429-p1516.indd 146601/03/19 6:45 PM 1467PANCREASCHAPTER 33ABFigure 33-42. Transpapillary drainage of a pancreatic pseudocyst. A. Endoscopic passage of a flexible wire through the major papilla, through the pancreatic duct, and into a communicating pseudocyst. B. Placement of a stent over the wire into the pseudocyst with transpapillary drainage. (Reproduced with permission from Kozarek RA, Brayko CM, Harlan J, et al. Endoscopic drainage of pancreatic pseudocysts, Gastrointest Endosc. 1985 Oct;31(5):322-327.)of ERCP may be directed into a pseudocyst through the ductal communication itself (Fig. 33-42), or they can be left across the area of suspected duct leakage to facilitate decompression and cyst drainage, analogous to the use of common bile duct stents in the setting of a cystic duct leak.206 In a surgical series of patients with chronic pancreatitis, ductal dilatation, and a coex-isting pseudocyst, Nealon and Walser showed that duct drainage alone, without a separate cystoenteric anastomosis, was as suc-cessful as a combined drainage procedure.92 Furthermore, the “duct drainage only” group enjoyed a shorter hospital stay and fewer complications than the group who underwent a separate cystoenterostomy. These observations suggest that transductal drainage may be a safe and effective approach to the manage-ment of pseudocystic disease.The complications of endoscopic drainage of pseudocysts often require surgical intervention. Bleeding from the cystoenterostomy and inoculation of a pseudocyst with failure of resolution and persistence of infection may require surgical treatment. Bleeding risks may be lessened by the routine use of EUS in the selection of the site for transluminal stent placement.210 Endoscopic treatment of pseudocysts requires large-bore catheters or multiple stents and an aggressive approach to management for success to be achieved. Failure of nonsurgical therapy, with subsequent salvage procedures to remove infected debris and establish complete drainage, is associated with increased risks for complications and death.211,212 The most experienced therapeutic endoscopists report a complication rate of 17% to 19% for the treatment of sterile pseudocysts, and deaths as a result of endoscopic therapy have occurred.212 Therefore, the use of endoscopic methods to treat sterile or infected pancreatic necrosis has a higher complication rate and is limited to specialized centers.Resection of a pseudocyst is sometimes indicated for cysts located in the pancreatic tail or when a midpancreatic duct disruption has resulted in a distally located pseudocyst. Distal pancreatectomy for removal of a pseudocyst, with or without splenectomy, can be a challenging procedure in the setting of prior pancreatitis. An internal drainage procedure of the com-municating duct or of the pseudocyst itself should be considered when distal resection is being contemplated.Pancreatic Ascites. When a disrupted pancreatic duct leads to pancreatic fluid extravasation that does not become sequestered as a pseudocyst, but drains freely into the peritoneal cavity, pan-creatic ascites occurs. Occasionally, the pancreatic fluid tracks superiorly into the thorax, and a pancreatic pleural effusion occurs. Referred to as internal pancreatic fistulae, both compli-cations are seen more often in patients with chronic pancreatitis rather than after acute pancreatitis. Pancreatic ascites and pleu-ral effusion occur together in 14% of patients, and 18% have a pancreatic pleural effusion alone.213Patients demonstrate the general demographics of chronic pancreatitis and usually present with a subacute or recent his-tory of progressive abdominal swelling despite weight loss. Pain and nausea are rarely present. The abdominal CT scan discloses ascites and the presence of chronic pancreatitis or a partially collapsed pseudocyst (Fig. 33-43). Paracentesis or thoracente-sis reveals noninfected fluid with a protein level >25 g/L and a markedly elevated amylase level. Serum amylase may also be elevated, presumably from reabsorption across the parietal membrane. Serum albumin may be low, and patients may have Figure 33-43. Pancreatic ascites. Computed tomographic scan of a patient with a ruptured pancreatic pseudocyst resulting in intra-peritoneal pancreatic fluid. (Reproduced with permission from Cameron JL, Cameron AM: Current Surgical Therapy, 11th ed. Philadelphia, PA: Elsevier; 2014.)Brunicardi_Ch33_p1429-p1516.indd 146701/03/19 6:45 PM 1468SPECIFIC CONSIDERATIONSPART IIFigure 33-44. Internal drainage for leaking pancreatic duct. A Roux-en-Y pancreaticojejunostomy is performed at the site of duct rupture to accomplish internal drainage of the pancreatic duct leak. (Reproduced with permission from Beger HG: The Pancreas. London: Blackwell-Science; 1998.)coexisting liver disease. Paracentesis is therefore critical to dif-ferentiate pancreatic from hepatic ascites.ERCP is most helpful to delineate the location of the pan-creatic duct leak and to elucidate the underlying pancreatic duc-tal anatomy. Pancreatic duct stenting may be considered at the time of ERCP, but if nonsurgical therapy is undertaken and then abandoned, repeat imaging of the pancreatic duct is appropriate to guide surgical treatment.Antisecretory therapy with the somatostatin analogue octreotide acetate, together with bowel rest and parenteral nutrition, is successful in more than half of patients.214,215 Reap-position of serosal surfaces to facilitate closure of the leak is considered a part of therapy, and this is accomplished by com-plete paracentesis. For pleural effusions, a period of chest tube drainage may facilitate closure of the internal fistula.214 Surgi-cal therapy is reserved for those who fail to respond to medical treatment. If the leak originates from the central region of the pancreas, a Roux-en-Y pancreaticojejunostomy is performed to the site of duct leakage215 (Fig. 33-44). If the leak is in the tail, a distal pancreatectomy may be considered, or an internal drainage procedure can be performed. The results of surgical treatment are usually favorable if the ductal anatomy has been carefully delineated preoperatively.Pancreatic-Enteric Fistula. The erosion of a pancreatic pseu-docyst into an adjacent hollow viscus can result in a pancreatic-enteric fistula. The most common site of communication is the transverse colon or splenic flexure. The fistula usually presents with evidence of GI or colonic bleeding and sepsis. If the fis-tula communicates with the stomach or duodenum, it may close spontaneously or persist as a pancreatic-enteric fistula. When the fistula involves the colon, operative correction is usually required.215Head-of-Pancreas Mass. In up to 30% of patients with advanced chronic pancreatitis, an inflammatory mass develops in the head of the pancreas.216 The clinical presentation includes severe pain and frequently includes stenosis of the distal common bile duct, duodenal stenosis, compression of the portal vein, and stenosis of the proximal main pancreatic duct (Table 33-18). Mutations and polymorphisms of p53 have been found in these patients, and a focus of ductular carcinoma was found in 3.7% of patients with pancreatic head enlargement in one series.217 It was concluded that an accelerated transformation from hyperplasia to dysplasia exists in patients with pancreatic head enlargement, although the etiology for this process remains unclear.Splenic and Portal Vein Thrombosis. Vascular complications of chronic pancreatitis are fortunately infrequent because they are difficult to treat successfully. Portal vein compression and occlusion can occur as a consequence of an inflammatory mass in the head of the pancreas, and splenic vein thrombosis occurs in association with chronic pancreatitis in 4% to 8% of cases.218 Variceal formation can occur as a consequence of either portal or splenic venous occlusion, and splenic vein thrombosis with gas-tric variceal formation is referred to as left-sided or sinistral por-tal hypertension. Although bleeding complications are infrequent, the mortality risk of bleeding is >20%. When gastroesophageal varices are caused by splenic vein thrombosis, the addition of splenectomy to prevent variceal hemorrhage is prudent when sur-gery is otherwise indicated to correct other problems.TreatmentMedical Therapy. The medical treatment of chronic or recurrent pain in chronic pancreatitis requires the use of analgesics, a cessation of alcohol use, oral enzyme therapy, and the selective use of antisecretory therapy. Interventional procedures to block visceral afferent nerve conduction or to treat obstructions of the main pancreatic duct are also an adjunct to medical treatment.Analgesia. Oral analgesics are prescribed as needed, alone or with analgesia-enhancing agents such as gabapentin.168 Ade-quate pain control usually requires the use of narcotics, but these should be titrated to achieve pain relief with the lowest effective dose. Opioid addiction is common, and the use of long-acting analgesics by transdermal patch together with oral agents for pain exacerbations slightly reduces the sedative effects of high-dose oral narcotics.Table 33-18Signs and symptoms of chronic pancreatitis with and without a pancreatic head massSIGNS AND SYMPTOMSWITH HEAD ENLARGEMENT (n = 138) (%)WITHOUT HEAD ENLARGEMENT (n = 141) (%)Daily severe pain6740Cholestasis4611Duodenal obstruction307Diabetes mellitus1830Vascular involvement158Reproduced with permission from Beger HG: The pancreas: an integrated textbook of basic science, medicine, and surgery. London: Blackwell-Science; 1998.Brunicardi_Ch33_p1429-p1516.indd 146801/03/19 6:45 PM 1469PANCREASCHAPTER 33It is essential for patients to abstain from alcohol. In addition to removing the causative agent, alcohol abstention results in pain reduction or relief in 60% to 75% of patients with chronic pancreatitis.219 Despite this benefit, roughly half of alcoholic chronic pancreatitis patients continue to abuse alcohol.Enzyme Therapy. Pancreatic enzyme administration serves to reverse the effects of pancreatic exocrine insufficiency. Adequate pancreatic enzyme replacement reverses the exo-crine insufficiency seen in most patients, and it prevents sec-ondary complications such as metabolic bone disease due to inadequate absorption of the fat-soluble vitamins A, D, E, and K. In addition, pancreatic enzyme replacement may reduce or alleviate the pain experienced by patients. The choice of enzyme supplement and the dose should be selected based on whether malabsorption or pain (or both) are the indica-tions for therapy220 (Table 33-19). Conventional (nonen-teric-coated) enzyme preparations are partially degraded by gastric acid but are available within the duodenal and jejunal regions to bind to CCK-releasing peptide and downregulate the release of CCK. This theoretically reduces the enteric sig-nal for pancreatic exocrine secretion, which reduces the pres-sure within a partially or completely obstructed pancreatic duct.221 Enteric-coated preparations result in little to no pain relief, presumably due to their reduced bioavailability in the proximal gut. Due to the loss of pancreatic enzymes by acid hydrolysis and proteolysis, relatively large doses are required to achieve effective levels of enzyme within the proximal small bowel. Enteric-coated preparations are protected from acid degradation but are presumably not released in the criti-cal proximal gut in sufficient quantity to inhibit the stimulus for endogenous pancreatic enzyme secretion. Nonalcoholic patients may experience more effective pain relief than alco-holic patients, but it is recommended that all patients with chronic pancreatitis pain begin a trial of nonenteric-coated enzyme supplements together with an acid-suppressive medi-cation for 1 month. If pain relief is achieved, therapy is con-tinued. If enzyme therapy fails, further investigation of the pancreatic ductal system by ERCP guides the therapy based on specific anatomical findings (Fig. 33-45).Antisecretory Therapy. Somatostatin administration has been shown to inhibit pancreatic exocrine secretion and CCK Table 33-19Pancreatic enzyme preparationsPRODUCTFORMULATIONMANUFACTURERLIPASE CONTENT (USP)/PILL OR CAPSULEZenpepEnteric-coated porcineAptalis3000, 5000, 10,000, 15,000, 20,000CreonEnteric-coated porcineAbbott3000, 6000, 12,000, 24,000PancreazeEnteric-coated porcineOrtho-McNeil-Janssen4200, 10,500, 16,800, 21,000PertzyeEnteric-coated porcine mixed with bicarbonate granulesDigestive Care8000, 16,000UltresaEnteric-coated porcineAptalis13,800, 20,700, 23,000ViokaceTablet non-enteric-coated porcineAptalis10,440, 20,880Note: USP = United States Pharmacopeia, the standard for lipase content in the United States. An average meal requires roughly 90,000 USP units of lipase for fat digestion. Enzyme therapy of exocrine deficiency typically begins with a dose of 50,000 USP units per meal with subsequent adjustment.Reproduced with permission from Forsmark CE: Management of chronic pancreatitis, Gastroenterology. 2013 Jun;144(6):1282-1291.release.222 The somatostatin analogue octreotide acetate has therefore been investigated for pain relief in patients with chronic pancreatitis. In a double-blind, prospective, randomized 4-week trial, 65% of patients who received 200 μg of octreotide acetate subcutaneously three times daily reported pain relief, compared with 35% of placebo-treated subjects.223 Patients who had the best results were patients with chronic abdominal pain, suggestive of obstructive pancreatopathy. However, in another trial that used a 3-day duration of treatment, no significant pain relief was observed.224 Anecdotal reports suggest that severe pain exacerbations in chronic pancreatitis can benefit from a combination of octreotide therapy and TPN, and a pilot study of the effectiveness of the sustained-release form of octreotide suggested that it was as effective as three-times-per-day admin-istration of the short-acting form of the drug.225Neurolytic Therapy. Celiac plexus neurolysis with alcohol injection has been an effective form of analgesic treatment in patients with pancreatic carcinoma. However, the use of radio-logically or endoscopically guided celiac plexus blockade in chronic pancreatitis has been disappointing. Due to the risk of alcohol injury and the need for repeated injections, celiac plexus blockade in chronic pancreatitis has used short-acting analgesics or other drugs rather than 50% alcohol. A trial of EUS-guided celiac plexus blockade revealed successful pain relief in 55% of patients, but the benefit lasted beyond 6 months in only 10% of patients.226 The procedure therefore appears safe, but the effect is short lived in those patients who obtain pain relief.Endoscopic Management. The techniques of endoscopic treat-ment of pancreatic duct obstruction, stone disease, pseudocyst formation, pancreatic duct leak, and for the diagnosis and man-agement of associated pancreatic tumors have expanded greatly over the past 20 years. Newer endoscopes with expanded thera-peutic capabilities have been introduced, and the role of EUS and EUS-guided needle and catheter insertion has expanded the abil-ity of the therapeutic endoscopist in the diagnosis and treatment of chronic pancreatitis and its complications.227Pancreatic duct stenting is used for treatment of proxi-mal pancreatic duct stenosis, decompression of a pancreatic duct leak, and for drainage of pancreatic pseudocysts that can be catheterized through the main pancreatic duct. Pancreatic duct stents can induce an inflammatory response within the Brunicardi_Ch33_p1429-p1516.indd 146901/03/19 6:45 PM 1470SPECIFIC CONSIDERATIONSPART IIMake a correct diagnosis • Appropriate history • Corroborating imaging tests • MRI/MRCP • EUS • CT • Functional tests if imaging tests equivocal • Tube-based secretin test • Endoscopic-based secretin test • Assess for alternative diseases and complications and treat if present • Pancreatic cancer or IPMN • Pseudocyst • Bile duct obstruction • Duodenal obstructionMedical therapy • Measure pain severity, character, and impact on QOL • Refer for formal structured smoking and alcohol cessation programs • Counsel on good nutrition and initiate supplementation with vitamin D and calcium • Baseline bone mineral density tasting • Provide information on local and national support groups • Initiate analgesics (starting with Tramadol) • Increase dose and potenay slowly as required • Initiate adjunctive agents in those with persistent pain or requiring higher dosages or potency of narcotics • Pregabalin, Gabapentin • SSRI • SSNRI • Tricyclic antidepressants • Assess for evidence of coexistent exocrine or endocrine insufficiency and treat if present • Fecal elastase or serum trypsin • HgB A1C or GTT • Initiate steroids if autoimmune pancreatitisInflammatory mass in pancreatic head • With or without dilated pancreatic duct • With or without duodenal or biliary obstructionSurgical therapy in ÿt patients • DPPHR • Berger operation • Frey operation • Berne operation • Whipple operationDiscuss options with patient, includingthat data supports superiority of surgery.Surgery remains an option for failure ofendoscopic therapy • Endoscopic therapy • Pancreatic and biliary sphincterotomy • Stricture dilation and stenting • Lithotripsy • Stone extraction • Surgical therapy • Modified Puestow or Frey operation• Continued medical therapy• Surgical therapy • “V-plasty” • Total pancreatectomy, with islet cell autotransplantationDilated pancreatic duct (° 6 mm)Small duct disease (pancreatic duct˛ 6 mm)Treatment effective?Continue treatment with periodicreassessmentYesNoAssess anatomy of pancreas andpancreatic ductFigure 33-45. Management algorithm for chronic pancreatitis. IPMN = intraductal papillary mucinous neoplasm; QOL = quality of life; SSRI = selective serotonin reuptake inhibitor; SSNRI = selective serotonin-norepinephrine reuptake inhibitor; GTT = glucose tolerance test. (Reproduced with permission from Forsmark CE: Management of chronic pancreatitis, Gastroenterology. 2013 Jun;144(6):1282-1291.)Brunicardi_Ch33_p1429-p1516.indd 147001/03/19 6:45 PM 1471PANCREASCHAPTER 33duct, so prolonged stenting is usually avoided. Patients with sphincter of Oddi dyskinesia are at high risk for developing post-ERCP pancreatitis after biliary sphincterotomy, and the prophylactic placement of a pancreatic duct stent or the admin-istration of rectal indomethacin reduces the amylase level and development of pancreatitis after biliary sphincterotomy.33,228 Pancreatic duct leaks are seen in 37% of patients with acute pancreatitis, and pancreatic duct stenting appears to facilitate the resolution of the leak.229 Similarly, pancreatic duct stenting has been used to treat postsurgical pancreatic duct leaks and posttraumatic leaks.229-231Pancreas divisum (see Fig. 33-3) is thought to cause pain and chronic pancreatitis due to functional or mechanical obstruc-tion of the dorsal duct draining exclusively, or predominantly, through the lesser papilla. A study from Marseille reported good long-term results in 24 patients after minor papilla sphinc-terotomy and dorsal duct stenting.232 The number of patients with chronic pain decreased from 83% before stenting to 29% after stenting, but pancreatitis or recurrent papillary stenosis occurred in 38%. Patients that responded best were those with intermittent pain, and this subset may be preferentially treated with endoscopic therapy. Patients with recurrent pain and a dilated dorsal duct may be candidates for internal drainage of the obstructed duct with either an extended Puestow procedure or a Frey procedure (see later in this section).Idiopathic pancreatitis patients have been treated with endoscopic stenting, pancreatic duct sphincterotomy, and endo-scopic stone removal with good results. In a prospective ran-domized trial, 53% of idiopathic recurrent pancreatitis patients in the control group experienced continued episodes of pancre-atitis, although only 11% of the treated patients had continued symptoms.233Extracorporeal shock wave lithotripsy (ESWL) has been used for pancreatic duct stones, together with endoscopic stent-ing and stone removal.234 A single ESWL session was used in 35 patients with pancreatic duct stones, together with 86 ERCP sessions to complete the stone removal process. After 2.4 years, 80% of patients had significant relief of symptoms (Fig. 33-46). Also, endoscopic intraductal lithotripsy can now be performed in some specialized centers. However, due to the tendency for recurrent stone formation, the use of ESWL or endoscopic litho-tripsy for long-term management of calcific pancreatitis remains uncertain.Surgical Therapy Indications and History The traditional approach to surgi-cal treatment of chronic pancreatitis and its complications has maintained that surgery should be considered only when the medical therapy of symptoms has failed. Nealon and Thomp-son published a landmark study in 1993, however, that showed that the progression of chronic obstructive pancreatitis could be delayed or prevented by pancreatic duct decompression.235 No other therapy has been shown to prevent the progression of chronic pancreatitis, and this study demonstrated the role of surgery in the early management of the disease (Table 33-20). Small-duct disease or “minimal change chronic pancreatitis” are causes for uncertainty over the choice of operation, however. Major resections have a high complication rate, both early and late, in chronic alcoholic pancreatitis, and lesser procedures often result in symptomatic recurrence. Therefore, the choice of operation and the timing of surgery are based on each patient’s pancreatic anatomy, the likelihood (or lack thereof) that further ABFigure 33-46. Extracorporeal shock wave lithotripsy treatment of pancreatic duct stones. The endoscopic retrograde cholangiopancrea-tography images are shown (A) before and (B) after extracorporeal shock wave lithotripsy therapy of pancreatic duct obstruction due to calculus formation. (Reproduced with permission from Kozarek RA, Brandabur JJ, Ball TJ, et al. Clinical outcomes in patients who undergo extracorporeal shock wave lithotripsy for chronic calcific pancreatitis, Gastrointest Endosc. 2002 Oct;56(4):496-500.)Table 33-20Effect of surgical drainage on progression of chronic pancreatitisTREATMENT GROUP24-MONTH EVALUATIONOperated (n = 47)Mild to moderate 48 (87%); severe 6 (13%)Nonoperated (n = 36)Mild to moderate 8 (22%); severe 28 (78%)Eighty-three patients with chronic pancreatitis were evaluated by exocrine, endocrine, nutritional, and endoscopic retrograde cholangiopancreatography studies, and all had mild to moderate disease and dilated pancreatic ducts. A Puestow-type duct decompression procedure was performed in 47 patients, and all subjects were restaged by the same methods 24 months later.Reproduced with permission from Nealon WH, Thompson JC. Progressive loss of pancreatic function in chronic pancreatitis is delayed by main pancreatic duct decompression. A longitudinal prospective analysis of the modified puestow procedure, Ann Surg. 1993 May;217(5):458-466.Brunicardi_Ch33_p1429-p1516.indd 147101/03/19 6:45 PM 1472SPECIFIC CONSIDERATIONSPART IIFigure 33-47. Head-of-pancreas mass after Puestow procedure. The computed tomographic appearance of an inflammatory mass occupying the head of the pancreas, which developed 2 years after Puestow decompression of the body and tail of pancreas.medical and endoscopic therapy will halt the symptoms of the disease, and the chance that a good result will be obtained with the lowest risk of morbidity and mortality. Finally, preparation for surgery should include restoration of protein-caloric homeo-stasis, abstinence from alcohol and tobacco, and a detailed review of the risks and likely outcomes to establish a bond of trust and commitment between the patient and the surgeon.Historically, the surgery for chronic pancreatitis before the second half of the 20th century was a true demonstration of trial and error.236 Obtaining good surgical outcomes before the avail-ability of CT scans and ERCP was either the result of serendip-ity or due to the skill and creativity of the surgeon. In 1911, Link described an operation he devised on the spot, when a laparot-omy in a young woman with abdominal pain revealed a fluctu-ant, obstructed pancreatic duct. After performing a dochotomy and evacuating multiple stones, he inserted a rubber tube, and exteriorized the pancreatostomy just above her navel.237 He later described the operation as having been a success for the next 30 years of the patient’s life, during which the patient managed the care of the drainage tube without apparent problems.238With the demonstration in 1942 by Priestley that total pancreatectomy was technically feasible,239 and the report in 1946 by Whipple that proximal pancreatic resection was ben-eficial in (three) patients with chronic pancreatitis,240 the option of surgical resection as treatment for chronic pancreatitis was established. By the mid 1950s, however, growing disappoint-ment with the high risk of resection and the lack of long-term benefit overshadowed the surgical treatment of chronic pancre-atitis. The choice of resection vs. drainage was largely based on surgeon preference until the 1970s, when the widespread adoption of ERCP and CT scans provided the ability to pre-operatively diagnose obstructive and sclerotic disease, and this resulted in the rational selection of operative procedures. During this period, the major drawbacks to surgical therapy remained the recurrence of symptoms despite surgery, the correspond-ing development of an inflammatory (or malignant) mass in the undrained pancreatic head (Fig. 33-47), or the high morbidity and mortality of major resectional procedures that predisposed patients to a cascade of metabolic problems.241Sphincteroplasty The sphincter of Oddi and the pancreatic duct sphincter serve as gatekeepers for the passage of pancreatic juice into the duodenum (Fig. 33-48). Stenosis of either sphincter (scle-rosing papillitis), due to scarring from pancreatitis or from the passage of gallstones, may result in obstruction of the pancreatic duct and chronic pain.242 As gallstone pancreatitis became a popu-lar diagnosis in the 1940s and 1950s, attention was focused on the ampullary region as a possible cause of chronic symptoms, and surgical sphincteroplasty was advocated. Although endoscopic techniques are now used routinely to perform sphincterotomy of either the common bile duct or pancreatic duct, a true (permanent) PancreasCommon bile ductDuodenal wallMajor papillaSphincter of ampullaMucosaSubmucosa Sphincter of pancreatic duct Pancreatic ductSphincter of common bile ductLongitudinal muscleof duodenal wallCircular muscle of duodenal wallFigure 33-48. Schematic diagram of the ampullary, biliary, and pancreatic duct sphincters. The point of merger of the bile duct and pancreatic duct is highly variable, and a true sphincter of the pancreatic duct may be poorly developed. (Reproduced with permission from Yamada T, Alpers DH, Kalloo AN, et al: Textbook of Gastroenterology, 5th ed. Oxford: Wiley-Blackwell; 2009.)Brunicardi_Ch33_p1429-p1516.indd 147201/03/19 6:45 PM 1473PANCREASCHAPTER 33Figure 33-49. Operative sphincteroplasty of the biliary and pan-creatic duct. The ampullary and bile duct sphincters are divided, as is the pancreatic duct sphincter, with suture apposition of the mucosal edges of the incision. sphincteroplasty can only be performed surgically. Transduode-nal sphincteroplasty with incision of the septum between the pan-creatic duct and common bile duct may offer significant relief for the rare patient with a focal obstruction and inflammation isolated to this region (Fig. 33-49).Drainage Procedures After the early reports of success with pancreatostomy for the relief of symptoms of chronic pancreatitis,238 Cattell described pancreaticojejunostomy for relief of pain in unresectable pancreatic carcinoma.243 Shortly thereafter, Duval244 and, separately, Zollinger and associates245 described the caudal Roux-en-Y pancreaticojejunostomy for the treatment of chronic pancreatitis in 1954 (Fig. 33-50). The so-called Duval procedure was used for decades by some surgeons, but it almost invariably failed due to restenosis and segmental obstruction of the pancreas due to progressive scarring. In 1958, Puestow and Gillesby described these segmental narrowings and dilatations of the ductal system as a “chain of lakes,” and proposed a longitudinal decompression of the body and tail of the pancreas into a Roux limb of jejunum246 (Fig. 33-51). Four of Puestow and Gillesby’s 21 initial cases were side-to-side anastomoses, and 2 years after their report, Partington and Rochelle described a much simpler version of the longitudinal, or side-to-side Roux-en-Y pancreaticojejunostomy that became universally known as the Puestow procedure247 (Fig. 33-52).Successful pain relief after the Puestow-type decompres-sion procedure has been reported in 75% to 85% of patients for the first few years after surgery, but pain recurs in >20% of patients after 5 years due to progressive disease even in patients who are abstinent from alcohol.164Figure 33-50. Duval’s caudal pancreaticojejunostomy. (Reproduced with permission from Greenlee HB: The role of surgery for chronic pancreatitis and its complications, Surg Annu. 1983;15:283-305.)Figure 33-51. Puestow and Gillesby’s longitudinal pancreatico-jejunostomy. Originally described as an invaginating anastomosis that drained the entire body and tail, the anastomosis was created after amputating the tail of the gland and opening the duct along the long axis of the gland. (Reproduced with permission from Greenlee HB: The role of surgery for chronic pancreatitis and its complica-tions, Surg Annu. 1983;15:283-305.)With the advent of therapeutic endoscopy and techniques for transluminal stone removal and lithotripsy, multiple series have reported the successful endoscopic treatment of pancreatic duct calculi, although the long-term outcomes of these efforts has been uneven.248-251 Endoscopic removal of pancreatic duct stones is usually coupled to prolonged pancreatic duct stenting, Brunicardi_Ch33_p1429-p1516.indd 147301/03/19 6:45 PM 1474SPECIFIC CONSIDERATIONSPART IIABFigure 33-52. Longitudinal dochotomy in obstructing calcific pancreatitis. A longitudinal pancreatotomy typically discloses seg-mental stenosis of the pancreatic duct and the presence of intra-ductal calculi in a patient with chronic calcific pancreatitis (A). Following mobilization of a Roux limb of jejunum, a longitudinal pancreaticojejunostomy is performed to permit extensive drainage of the pancreatic duct system (B). This technique, described by Partington and Rochelle, is the typical method used for the Puestow procedure. which carries the risk of further inflammation.252,253 Despite the risk of perioperative complications, the surgical management of pancreatic duct stones and stenosis has been shown to be superior to endoscopic treatment in randomized clinical trials in which the long, side-to-side technique of pancreaticojejunos-tomy is used.254-256Resectional Procedures Distal Pancreatectomy For patients with focal inflammatory changes localized to the body and tail, or in whom no significant ductal dilatation exists, the technique of partial (40–80%) dis-tal pancreatectomy has been advocated (Fig. 33-53). Although distal pancreatectomy is less morbid than more extensive resec-tional procedures, the operation leaves untreated a major portion of the gland, and is therefore associated with a significant risk of symptomatic recurrence. It has been a more popular operation in British centers, where its success seems to be greater, perhaps due to the lower incidence of alcoholic chronic pancreatitis.257 However, long-term outcomes reveal good pain relief in only 60% of patients, with completion pancreatectomy required for pain relief in 13% of patients.Laparoscopic distal pancreatectomy has been shown to be feasible for the removal of focal lesions of the distal pancreas,258 but it is more difficult in the setting of chronic pancreatitis.Ninety-Five Percent Distal Pancreatectomy In 1965, Fry and Child proposed the more radical 95% distal pancreatectomy, which was intended for patients with sclerotic (small duct) disease and which attempted to avoid the morbidity of total pancreatectomy by preserving the rim of pancreas in the pancreaticoduodenal groove, along with its associated blood vessels and distal common bile duct.241 The operation was found to be associated with pain relief in 60% to 77% of patients long term, but it is accompanied by a high risk of brittle diabetes, hypoglycemic coma, and malnutrition. Although the operation was the first attempt to resect the pancreatic head while preserving the duodenum and distal bile duct, the extensive degree of metabolic complications led to its failure as viable treatment for the symptoms of pancreatic sclerosis.Proximal Pancreatectomy In 1946, Whipple reported a series of five patients treated with either pancreaticoduodenectomy or total pancreatectomy for symptomatic chronic pancreatitis, with one operative death.240 Subsequently, proximal pancreatectomy or pancreaticoduodenectomy, with or without pylorus preser-vation (Fig. 33-54), has been widely used for the treatment of chronic pancreatitis.259 In the three largest modern (circa 2000) series of the treatment of chronic pancreatitis by the Whipple Splenic arteryFigure 33-53. Distal (spleen-sparing) pancreatectomy. A distal pancreatectomy for chronic pancreatitis is usually performed with en bloc splenectomy, using either an open or laparoscopic tech-nique. In the presence of minimal inflammation, a spleen-sparing version can be performed, as shown here.Brunicardi_Ch33_p1429-p1516.indd 147401/03/19 6:45 PM 1475PANCREASCHAPTER 33procedure, pain relief 4 to 6 years after operation was found in 71% to 89% of patients. However, mortality ranged from 1.5% to 3%, and major complications occurred in 25% to 38% of patients at the Johns Hopkins Hospital,260 the Mayo Clinic,261 and the Massachusetts General Hospital.262 In follow-up, 25% to 48% of patients developed diabetes, and about the same per-centage required exocrine therapy. Advocates of the Whipple procedure as treatment for chronic pancreatitis suggest that the high rate of symptomatic relief outweighs the metabolic conse-quences and the mortality risk of the procedure, but increasingly this approach is being reserved for those patients with suspected occult malignancy.Total Pancreatectomy Priestley and associates first described successful total pancreatectomy in 1944 in a patient with hyperinsulinism,239 and two of Whipple’s original five cases of chronic pancreatitis reported in 1946 were treated with total pancreatectomy.240 Subsequently, surgeons who used total pancreatectomy found that the operation produces no better pain relief for their patients than pancreaticoduodenectomy (about 80–85%). Moreover, the metabolic consequences of total pancreatectomy in the absence of islet cell transplantation can be profound and life-threatening. The patients have a “brittle” form of diabetes in which avoidance of hyperand hypoglycemia is problematic.263 In addition, lethal episodes of hypoglycemia are common in severe apancreatic diabetes. These are due to hypoglycemic unresponsiveness, due to the absence of pancreatic glucagon, and to hypoglycemia unawareness, despite an ongoing need to treat with exogenous insulin.177 In a series of >100 patients treated with total pancreatectomy, Gall and colleagues showed that half of all the late deaths after this operation were due to (iatrogenic) hypoglycemia.264 Despite newer forms of insulin, insulin delivery systems, and continuous blood glucose monitoring systems, severe pancreatogenic diabetes remains an adverse outcome, as complete prevention of the physiologic consequences of total pancreatectomy remains an unfulfilled goal. Even with the growing acceptance of islet auto-transplantation as an adjunct to the procedure (see later in CholedochojejunostomyGastrojejunostomyPancreaticojejunostomyCholedochojejunostomyDuodenojejunostomyPancreaticojejunostomyABFigure 33-54. The pancreaticoduodenectomy (Whipple procedure) can be performed either with the standard technique, which includes distal gastrectomy (A), or with preservation of the pylorus (B). The pylorus-sparing version of the procedure is used most commonly. (Repro-duced from Wu GY, Aziz K, Whalen GF: An Internist’s Illustrated Guide to Gastrointestinal Surgery. Totowa: Humana Press; 2003.)this section), total pancreatectomy itself is now used only rarely for the treatment of refractory chronic pancreatitis.Hybrid Procedures In 1980, Beger and associates described the Duodenum-preserving Pancreatic Head Resection or DPPHR265 (Fig. 33-55), and they published long-term results with DPPHR for the treatment of chronic pancreatitis in 1985266 and again in 1999.267 In 388 patients who were followed for an average of 6 years after DPPHR, pain relief was reportedly maintained in 91%, mortality was <1%, and diabetes developed in 21%, with 11% demonstrating a reversal of their preoperative diabetic sta-tus. These authors also compared the DPPHR procedure with the pylorus-sparing Whipple procedure in a randomized trial of 40 patients with chronic pancreatitis.268 The mortality was reportedly zero in both groups, and the morbidity was also com-parable. Pain relief (over 6 months) was seen in 94% of DPPHR patients, but in only 67% of Whipple patients. Furthermore, the insulin secretory capacity and glucose tolerance were noted to deteriorate in the Whipple group, but they actually improved in the DPPHR patients.The DPPHR requires the careful dissection of the gas-troduodenal artery and the creation of two anastomoses (Fig. 33-56), and it carries a similar complication risk as the Whipple procedure due to the risk of pancreatic leakage and intra-abdominal fluid collections.In 1987, Frey and Smith described the local resection of the pancreatic head with longitudinal pancreaticojejunostomy (LR-LPJ), which included excavation of the pancreatic head, including the ductal structures in continuity with a long dochot-omy of the dorsal duct269 (Fig. 33-57). The Frey procedure pro-vides thorough decompression of the pancreatic head as well as the body and tail of the gland, and a long-term follow-up suggested that improved outcomes are associated with this more extensive decompressive procedure. Frey and Amikura reported their results in 50 patients followed for >7 years, and they found complete or substantial pain relief in 87% of patients. There was no operative mortality, but 22% of patients developed postop-erative complications.270Brunicardi_Ch33_p1429-p1516.indd 147501/03/19 6:45 PM 1476SPECIFIC CONSIDERATIONSPART IICommonbile ductPancreaticductPancreaticremnantABFigure 33-55. The duodenum-preserving pancreatic head resection described by Beger and colleagues. A. The completed resection after transection of the pancreatic neck, and subtotal removal of the pan-creatic head, with preservation of the distal common bile duct and duodenum. B. Completion of the reconstruction with anastomosis to the distal pancreas and to the proximal pancreatic rim by the same Roux limb of jejunum. (Reproduced with permission from Bell RH, Rikkers LF, Mulholland M: Digestive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)Figure 33-56. Intraoperative view of the Beger procedure. The gastroduodenal artery is encircled by a vessel loop. Just below, the intrapancreatic portion of the common bile duct is exposed as it courses toward the ampulla. A rim of well-vascularized pancreatic tissue remains in the duodenal C-loop. Preservation of the posterior branch of the gastroduodenal artery is essential to preserve viability of these structures.Key steps in the performance of the LR-LPJ include pres-ervation of the pancreatic neck as well as the capsule of the posterior pancreatic head. In the pancreaticoduodenectomy and the DPPHR, the pancreatic neck is freed up from the portal and superior mesenteric vein confluence and divided. In the LR-LPJ, the neck of the pancreas is preserved intact as are the body and tail of the pancreas. Not having to divide the pancreatic neck, as in the pancreaticoduodenectomy or DPPHR, reduces the risk of the operation because it avoids intraoperative prob-lems with the venous structures lying posterior to the gland. To reduce the risk of penetrating the posterior capsule of the head, Frey recommended in his 1994 report that the posterior limit of resection be the back wall of the opened duct of Wirsung and duct to the uncinate (Fig. 33-58).Subsequent to Frey’s own modification of the technique, other surgeons have described modifications of the extent or technique of the LR-LPJ. Andersen and Topazian advocated performing the LR-LPJ as it was originally described, in which the entirety of the ducts are excised from the head (Fig. 33-59), and described the use of the ultrasonic aspirator and dissector for this purpose.271 This device permits precise removal of the ducts and adjacent tissue with good visualization and without complications. There is little pancreatic tissue behind these ducts, and the pancreatic capsule is continuously palpated as the dissection proceeds to ensure a safe margin of resection. The intrapancreatic portion of the common bile duct is usually exposed, and avoiding injury to it is enhanced by the ultrasonic aspirator. The majority of the parenchyma of the uncinate pro-cess is spared, and the excavation of the pancreatic head is made contiguous with a generous dochotomy of the dorsal duct. Whether merely unroofing as opposed to removal of the proximal ducts contributes to better pain relief is not known and awaits a randomized trial to compare the two versions of the LR-LPJ. Izbicki and colleagues at the University of Hamburg also recommend a more extensive excavation of the pancreatic head, and they use a technique that they refer to as the Hamburg modification of the LR-LPJ272 (Fig. 33-60). This wider excavation of the pancreatic head is created in continu-ity with the dorsal dochotomy, and it is followed by a single, side-to-side pancreaticojejunostomy.In 2001, Ho and Frey subsequently described merely exca-vating the core of the pancreatic head and draining the exca-vation with a Roux-en-Y pancreaticojejunostomy, but without any effort to include the dorsal duct273,274 (Fig. 33-61). In 2003, Brunicardi_Ch33_p1429-p1516.indd 147601/03/19 6:45 PM 1477PANCREASCHAPTER 33Figure 33-57. Frey procedure. The local resection of the pancreatic head with longitudinal pancreaticojejunostomy (LR-LPJ) provides complete decompression of the entire pancreatic ductal system. Reconstruction is performed with a side-to-side Roux-en-Y pan-creaticojejunostomy. (Reproduced with permission from Bell RH, Rikkers LF, Mulholland M: Digestive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)Figure 33-58. Operative view of excavated head of the pancreas during the Frey procedure. The main pancreatic duct is opened widely down to the level of the ampulla, and the head of the pan-creas is excavated in a conical fashion so as to allow complete decompression of the chronically obstructed and inflamed pancre-atic ducts. (Reproduced with permission from Aspelund G et al. Improved outcomes for benign disease with limited pancreatic head resection, J Gastrointest Surg. 2005 Mar;9(3):400-409.)Figure 33-59. Complete excavation of the pancreatic head and distal pancreatic dochotomy. A true excavation and removal of the proximal ductal system is combined with a distal pancreatic dochotomy. Reconstruction is performed with a single side-to-side Roux-en-Y pancreaticojejunostomy. (Reproduced with permission from Andersen DK, Topazian MD. Pancreatic head excavation: a variation on the theme of duodenum-preserving pancreatic head resection, Arch Surg. 2004 Apr;139(4):375-379.)Brunicardi_Ch33_p1429-p1516.indd 147701/03/19 6:46 PM 1478SPECIFIC CONSIDERATIONSPART IIFigure 33-60. The Hamburg modification of the local resection of the pancreatic head with longitudinal pancreaticojejunostomy. (Reproduced with permission from Shackelford RT, Yeo CJ, Peters JH: Shackelford’s Surgery of the Alimentary Tract. New York, NY: Saunders/Elsevier; 2007.)Farkas and colleagues described a similar excavation of the cen-tral portion of the pancreatic head without any effort to include the duct of the body in the lateral pancreaticojejunostomy,275 and they reported excellent results with what they termed an organ-preserving pancreatic head resection (OPPHR) in a ran-domized comparison to the pylorus-preserving pancreaticoduo-denectomy (PPPD).276This approach was advocated by Gloor and associates in Bern as an alternative to the DPPHR procedure in patients with portal hypertension277 and was described as the Berne modifica-tion of the DPPHR (Fig. 33-62). Köninger and colleagues in Heidelberg subsequently published a randomized, controlled trial of the “Berne” version of the excavation method compared to the “classic” Beger procedure.278 Operative times and length of stay were shorter in the group undergoing excavation of the pancreatic head, while long-term outcomes and quality-of-life scores were identical over 2 years postoperatively.The common element of these variations on the theme of LR-LPJ remains the excavation or “coring out” of the central portion of the pancreatic head. It remains uncertain, however, whether and to what degree the dochotomy needs to be extended into the body and tail. The logical conclusion of all of these efforts is that the head of the pancreas is the nidus of the chronic inflammatory process in chronic pancreatitis and that removal of the central portion of the head of the gland is the key to the successful resolution of pain in the long term.Complications Initial and long-term results of the LR-LPJ demonstrate pain relief that is equivalent to that of pancreati-coduodenectomy and the DPPHR.279,280 The observed mortal-ity rate has been virtually zero, and therefore, less than with the Whipple procedure. Major complications were less with the LR-LPJ (16%) than with pancreaticoduodenectomy (40%) or DPPHR (25%) in one single-site series, and the incidence of new postoperative diabetes after LR-LPJ was 8% with an aver-age follow-up of 3 years.1996Line of enterotomyJejunal limbsecured with 1strow of suturesNormal pancreatic ductPancreatic head cored outABFigure 33-61. Excavation of pancreatic head without longitudinal pancreaticojejunostomy. Comparisons of the Three Operative Procedures: Pancre-aticoduodenectomy (Whipple procedure), DPPHR (Beger procedure), and LR-LPJ (Frey procedure). There has been considerable interest to apply evidence-based methods to the study of the three operations currently advocated for the treat-ment of chronic pancreatitis. The best studies, or level 1 data by the Strength of Recommendation Taxonomy, are prospective, randomized controlled trials comparing two or more operations from a single or multi-institutional study. Retrospective, cohort-based studies are regarded as level 2 data by the Strength of Recommendation Taxonomy criteria.To date, ten published level 1 studies268,276,278-285 and three level 2 studies199,286,287 have examined various comparisons between these three operations. In the level 1 study of Klempa and colleagues281 and that of Buchler et al,288 DPPHR patients had a shorter hospital stay, greater weight gain, less postopera-tive diabetes, and exocrine dysfunction than standard Whipple patients over a 3to 5-year follow-up. Pain control was similar between the two procedures. Similar results were observed in a Brunicardi_Ch33_p1429-p1516.indd 147801/03/19 6:46 PM 1479PANCREASCHAPTER 33Figure 33-62. The Berne modification of the local resection of the pancreatic head with longitudinal pancreaticojejunostomy.recent level 2 retrospective study of 123 patients287 and in the level 1 study by Keck et al.287In a level 1 study of 61 patients randomized to PPPD or LR-LPJ, Izbicki and colleagues found a lower postoperative complication rate associated with the Frey procedure (19%) compared to the PPPD group (53%), and better global quality-of-life scores (71% vs. 43%, respectively).279 Both operations were equally effective in controlling pain over a 2-year follow-up. Similar results were seen in the study by Farkas and associates276 who employed a similar method of excavation of the pancreatic head that their group described as an organ-preserving pancreatic head resection (OPPHR) and found that OPPHR was associated with a shorter operating time, less postoperative morbidity, shorter hospital stay, and better quality of life than PPPD. The superior outcomes of the Frey procedure were found to be durable in a 15-year follow-up study by Bachmann et al285 who found that survival and function were superior after the Frey procedure.Late Morbidity and Mortality In 2005, Izbicki’s group reported on a level 1 study of 74 patients randomized to the DPPHR or LR-LPJ who were then followed for an average of 8.5 years.286 There were no significant differences between the groups with regard to global quality of life, pain scores, late mortality, and exocrine or endocrine insufficiency. The level 1 study by Köninger, which compared the classic DPPHR with excavation of the pancreatic head, showed identical outcomes at 2 years after an initial reduction in morbidity associated with the excavation procedure.278 These results were echoed in the level 2 study by Aspelund and associates, which demonstrated fewer complications with both the DPPHR and LR-LPJ proce-dures compared to pancreaticoduodenectomy, a lower incidence of new diabetes (8%) for both DPPHR and LR-LPJ compared to the Whipple procedure (25%), but no significant differences in outcomes or pain relief between DPPHR and LR-LPJ.199 Finally, level 2 data support the efficacy of both DPPHR and LR-LPJ in patients with dilated as well as nondilated ducts.286,289,290Long-term exocrine and/or endocrine insufficiency in chronic pancreatitis patients treated surgically is a product of the surgical intervention as well as the progression of the underlying disease. Although the short-term (3-year) incidence of new diabe-tes after operation appears less with the LR-LPJ and DPPHR than with the PPPD, the late incidence of diabetes appears similar in all groups. After an average of 7 years of follow-up after LR-LPJ or PPPD, survival, pain relief, and pancreatic function were similar in both groups. The rate of diabetes was slightly lower after LR-LPJ (61%) than after PPPD (65%), but these had both more than doubled from their preoperative status.275-281 Therefore, although the limited pancreatic procedures of DPPHR and LR-LPJ have a lower initial rate of endocrine dysfunction, the long-term risk of diabetes is more related to the progression of the underlying disease than to the effects of operation.The level 1 studies confirm that the duodenum preserving options are associated with a lower immediate morbidity and mortality and therefore, in the absence of a mass or concerns about cancer, are better options than a Whipple procedure for chronic pancreatitis. The choice of LR-LPJ, DPPHR, or OPPHR depends largely on surgeon experience, and the LR-LPJ is most common in the United States.Total Pancreatectomy With Islet Auto-Transplantation Islet cell transplantation for the treatment of diabetes is an attractive adjunct to pancreatic surgery in the treatment of benign pancre-atic disease. Despite the difficulties in recovering islets from a chronically inflamed gland, Najarian and associates demonstrated the utility of autotransplantation of islets in patients with chronic pancreatitis in 1980.291 Subsequently, through refinements in the methods of harvesting and gland preservation, and through standardization of the methods by which islets are infused into the portal venous circuit for intrahepatic engraftment, the suc-cess of total pancreatectomy combined with islet autotransplan-tation has steadily increased to achieve insulin independence in the majority of patients treated in recent series.292,293 Although 2 to 3 million islets are required for successful engraftment in an allogeneic recipient, the auto-transplant recipient can usually achieve long-term, insulin-independent status after engraftment of only 300,000 to 400,000 islets (about one-third to one-half of the number of islets in the normal pancreas).294The ability to recover a sufficient quantity of islets from a sclerotic gland is dependent on the degree of fibrotic dis-ease present, so the selection of patients as candidates for autologous islet transplantation is important. The impressive improvement in quality of life measures and pain relief seen after total pancreatectomy with islet auto-transplantation (TP-IAT) indicate that it is a highly successful form of therapy for some patients (Fig. 33-63).295 The outcomes of TP-IAT are sig-nificantly better in pediatric patients than in adults, largely due to the prevalence of hereditary and idiopathic causes of chronic pancreatitis in pediatric patients.296 These studies suggest that further definition is needed regarding criteria for considering TP-IAT vs. hybrid or resectional procedures for patients with persistent symptoms. With the emerging evidence that hybrid procedures seem to offer better outcomes in patients with toxic etiologies of chronic pancreatitis, and that TP-IAT appears to Brunicardi_Ch33_p1429-p1516.indd 147901/03/19 6:46 PM 1480SPECIFIC CONSIDERATIONSPART II001224364860MonthsEffectNum DF1131252842994299Den DF0.26268.294.840.608<0.001<0.001F statisticP valueAgeTimeAge x TimePrevalence of narcotic use (%)72849610812020406080100Pediatric patientAdultFigure 33-63. Prevalence of narcotic use after total pancreatectomy with islet auto-transplantation (TP-IAT) in adult and pediatric patients. (Reproduced with permission from Chinnakotla S, Beilman GJ, Dunn TB, et al. Factors Predicting Outcomes After a Total Pancreatectomy and Islet Autotransplantation Lessons Learned From Over 500 Cases, Ann Surg. 2015 Oct;262(4):610-622.)preferentially benefit patients with hereditary and idiopathic forms of the disease, the importance of the careful definition of the etiology of chronic pancreatitis, including genetic testing, is steadily increasing.PANCREATIC NEOPLASMSNeoplasms of the Endocrine PancreasNeoplasms of the endocrine pancreas are relatively uncommon but do occur with enough frequency (five cases per million population) that most surgeons will encounter them in an urban practice. The cells of the endocrine pancreas, or islet cells, origi-nate from neural crest cells, also referred to as amine precursor uptake and decarboxylation cells. Multiple endocrine neopla-sia (MEN) syndromes occur when these cells cause tumors in multiple sites. The MEN1 syndrome involves pituitary tumors, parathyroid hyperplasia, and pancreatic neoplasms. Although most pancreatic endocrine tumors are nonfunctional, some are functional, secreting peptide products that produce interesting clinical presentations. Neoplasms of the endocrine pancreas that are not associated with excess hormone levels and a recogniz-able clinical syndrome are considered nonfunctional. Special immunohistochemical stains allow pathologists to confirm the peptide products being produced within the cells of a pancre-atic endocrine tumor. However, the histologic characteristics of these neoplasms do not predict their clinical behavior, and malignancy is usually determined by the presence of local inva-sion and lymph node or hepatic metastases. Unfortunately, most pancreatic endocrine tumors are malignant, but the course of the disease is far more favorable than that seen with pancreatic exo-crine cancer. The key to diagnosing these rare tumors is recogni-tion of the classic clinical syndrome; confirmation is achieved by measuring serum levels of the elevated hormone. Localiza-tion of the tumor can be a challenging step, but once accom-plished, the surgery is relatively straightforward. The goals of surgery range from complete resection, often accomplished with insulinomas, to controlling symptoms with debulking proce-dures. Unresectable disease in the liver is often addressed with chemoembolization.As with pancreatic exocrine tumors, the initial diagnos-tic imaging test of choice for pancreatic endocrine tumors is a multidetector CT scan with four phases of contrast and fine cuts through the pancreas and liver. Neuroendocrine tumors of the pancreas often enhance with contrast. EUS can be superior to CT in localizing these tumors, which can produce dramatic symptoms despite their small (<1 cm) size. In contrast to pan-creatic exocrine tumors, many of the endocrine tumors have somatostatin receptors (SSTRs) that allow them to be detected by a radiolabeled octreotide scan. A radioactive somatostatin analogue is injected intravenously, followed by whole-body radionuclide scanning (Fig. 33-64). The success of this modal-ity in localizing tumors and detecting metastases has decreased the use of older techniques such as angiography and selective venous sampling.InsulinomaInsulinomas are the most common functional pancreatic endocrine neoplasms and present with a typical clinical Brunicardi_Ch33_p1429-p1516.indd 148001/03/19 6:46 PM 1481PANCREASCHAPTER 33syndrome known as Whipple’s triad. The triad consists of symptomatic fasting hypoglycemia, a documented serum glucose level <50 mg/dL, and relief of symptoms with the administration of glucose. Patients can present with a profound syncopal episode or less severe symptoms that are averted by frequent eating. Common symptoms include palpitations, trembling, diaphoresis, confusion or obtundation, and seizure, and family members may report that the patient has undergone a personality change.Routine laboratory studies will uncover a low blood sugar, the cause of all of these symptoms. Serum insulin levels are elevated. C-peptide levels should also be elevated and rule out the unusual case of surreptitious administration of insulin or oral hypoglycemic agents because excess endogenous insulin pro-duction leads to excess C-peptide. The diagnosis can be clinched with a monitored fast in which blood is sampled every 4 to 6 hours for glucose and insulin levels until the patient becomes symptomatic. However, this can be dangerous and must be done with close supervision.Insulinomas are usually localized with CT scanning and EUS. Technical advances in EUS have led to preoperative identification of >90% of insulinomas.297 Visceral angiography with venous sampling is rarely required to accurately localize the tumor. Insulinomas are evenly distributed throughout the head, body, and tail of the pancreas.298 Unlike most endocrine pancreatic tumors, the majority (90%) of insulinomas are benign Figure 33-64. Radioactive octreotide scan demonstrating pancre-atic endocrine tumor in the body of the pancreas (arrow).and solitary, and only 10% are malignant. They are typically cured by simple enucleation. However, tumors located close to the main pancreatic duct and large (>2 cm) tumors may require a distal pancreatectomy or pancreaticoduodenectomy. Intraop-erative US is useful to determine the tumor’s relation to the main pancreatic duct and guides intraoperative decision making. Approximately 90% of insulinomas are sporadic, and 10% are associated with the MEN1 syndrome. Insulinomas associated with the MEN1 syndrome are more likely to be multifocal and have a higher rate of recurrence.Noninsulinoma Hyperinsulinemia Hypoglycemia SyndromeA syndrome of noninsulinoma pancreatogenous hypoglycemia was described by Service et al in 1999.299 The syndrome is asso-ciated with beta-cell hypertrophy, islet hyperplasia and increased beta-cell mass. When these findings are accompanied by ectopic islet tissue, multilobulated islets, and ductuloinsular complexes, the definition of nesideoblastosis is met. Nesideoblastosis accompanied by hyperinsulinism was previously considered a disease of neonates, where subtotal or total pancreatectomy was required to correct potentially fatal neonatal hyperinsulinism. However, dozens of cases of nesideoblastosis associated with hyperinsulinism have now been reported in patients 2 to 5 years after Roux-en-Y gastric bypass for obesity.300 Many of these patients have undergone partial or total pancreatectomy to prevent potentially fatal hypoglycemia. The illness in former bariatric surgery patients appears to result from an idiosyncraticallyprolonged hypersecretion of the incretin hormones GIP and GLP-1 after the gastric bypass. GLP-1 is a potent stimulant of the expression of the transcription factor PDX-1, which nor-mally regulates beta-cell development and growth. The correct treatment of this condition to prevent episodes of hypoglycemia is conversion of the gastric bypass to a form of bariatric proce-dure that restores normal intestinal flow of nutrients, such as the gastric sleeve, or the addition of a restriction element such as an adjustable gastric band. Pancreatic resection without conversion of the Roux-en-Y gastric bypass is not appropriate because this allows the abnormal enteroinsular relationship to continue and hyperinsulinemia persists or recurs after partial pancreatectomy.GastrinomaZollinger-Ellison syndrome (ZES) is caused by a gastrinoma, an endocrine tumor that secretes gastrin, leading to acid hyper-secretion and peptic ulceration. Many patients with ZES present with abdominal pain, peptic ulcer disease, and severe esopha-gitis. However, in the era of effective antacid therapy, the pre-sentation can be less dramatic. Although most of the ulcers are solitary, multiple ulcers in atypical locations that fail to respond to antacids should raise suspicion for ZES and prompt a work-up. At the time of diagnosis, 21% of patients with gastrinoma have diarrhea.The diagnosis of ZES is made by measuring the serum gastrin level. It is important that patients stop taking proton pump inhibitors for this test. In most patients with gastrinomas, the level is >1000 pg/mL. Gastrin levels can be elevated under conditions other than ZES. Common causes of hypergastrin-emia include pernicious anemia, treatment with proton pump inhibitors, renal failure, G-cell hyperplasia, atrophic gastritis, retained or excluded antrum, and gastric outlet obstruction. In equivocal cases, when the gastrin level is not markedly elevated, a secretin stimulation test is helpful.Brunicardi_Ch33_p1429-p1516.indd 148101/03/19 6:46 PM 1482SPECIFIC CONSIDERATIONSPART IIIn 70% to 90% of patients, the primary gastrinoma is found in Passaro’s triangle, an area defined by a triangle with points located at the junction of the cystic duct and common bile duct, the second and third portion of the duodenum, and the neck and body of the pancreas (Fig. 33-65). However, because gastri-nomas can be found almost anywhere, whole-body imaging is required. The test of choice is SSTR (octreotide) scintigraphy in combination with CT. The octreotide scan is more sensitive than CT, locating about 85% of gastrinomas and detecting tumors <1 cm. With the octreotide scan, the need for tedious and techni-cally demanding selective angiography and measurement of gas-trin gradients has declined. EUS is another modality that assists in the preoperative localization of gastrinomas. It is particularly helpful in localizing tumors in the pancreatic head or duodenal wall, where gastrinomas are usually <1 cm in size. A combina-tion of octreotide scan and EUS detects >90% of gastrinomas.It is important to rule out MEN1 syndrome by checking serum calcium levels before surgery because resection of the gastrinoma(s) in these patients rarely results in normalization of serum gastrin concentrations or a prolongation of survival. Only one-fourth of gastrinomas occur in association with the MEN1 syndrome. One-half of patients with gastrinomas will have soli-tary tumors while the remainder will have multiple gastrino-mas. Multiple tumors are more common in patients with MEN1 syndrome. Aggressive surgical treatment is justified in patients with sporadic gastrinomas. If patients have MEN1 syndrome, the parathyroid hyperplasia is addressed with total parathyroid-ectomy and implantation of parathyroid tissue in the forearm.Approximately 50% of gastrinomas metastasize to lymph nodes or the liver and are therefore considered malignant. Patients who meet criteria for operability should undergo exploration for possible removal of the tumor. Although the tumors are submu-cosal, a full-thickness excision of the duodenal wall is performed if a duodenal gastrinoma is found. All lymph nodes in Passaro’s triangle are excised for pathologic analysis. If the gastrinoma is found in the pancreas and does not involve the main pancreatic duct, it is enucleated. Pancreatic resection is justified for solitary Figure 33-65. Passaro’s triangle. The typical location of a gastrinoma is described by this anatomic region, including the head of the pancreas, duodenum, and the lymphatic bed posterior and superior to the duodenum, as originally described by E. Passaro. (Reproduced with permission from Stable BE, Morrow DJ, Passaro E: The gastrinoma triangle: operative implications, Am J Surg. 1984 Jan;147(1):25-31.)gastrinomas with no metastases. A highly selective vagotomy can be performed if unresectable disease is identified or if the gastrinoma cannot be localized. This may reduce the amount of expensive proton pump inhibitors required. In cases in which hepatic metastases are identified, resection is justified if the pri-mary gastrinoma is controlled and the metastases can be safely and completely removed. Debulking or incomplete removal of multiple hepatic metastases is probably not helpful, especially in the setting of MEN1. The application of new modalities such as radiofrequency ablation seems reasonable, but data to sup-port this approach are limited.301 Postoperatively, patients are followed with fasting serum gastrin levels, secretin stimulation tests, octreotide scans, and CT scans. In patients found to have inoperable disease, chemotherapy with streptozocin, doxorubi-cin, and 5-fluorouracil (5-FU) is used. Other approaches such as somatostatin analogues, interferon, and chemoembolization also have been used in gastrinoma with some success.Unfortunately, a biochemical cure is achieved in only about one-third of the patients operated on for ZES. Despite the lack of success, long-term survival rates are good, even in patients with liver metastases. The 15-year survival rate for patients without liver metastases is about 80%, while the 5-year survival rate for patients with liver metastases is 20% to 50%. Pancreatic tumors are usually larger than tumors arising in the duodenum, and more often they have lymph node metastases. In gastrinomas, liver metastases decrease survival rates, but lymph node metastases do not. The best results are seen after complete excision of small sporadic tumors originating in the duodenum. Large tumors associated with liver metastases, located outside of Passaro’s triangle, have the worst prognosis.Vasoactive Intestinal Peptide-Secreting TumorIn 1958, Verner and Morrison first described the syndrome associated with a pancreatic neoplasm secreting VIP. The clas-sic clinical syndrome associated with this pancreatic endocrine neoplasm consists of severe intermittent watery diarrhea leading to dehydration, and weakness from fluid and electrolyte losses. Large amounts of potassium are lost in the stool. The vasoac-tive intestinal peptide-secreting tumor (VIPoma) syndrome is also called WDHA syndrome due to the presence of watery diarrhea, hypokalemia, and achlorhydria. The massive (5 L/d) and episodic nature of the diarrhea associated with the appropriate electrolyte abnormalities should raise suspicion of the diagnosis. Serum VIP levels must be measured on multiple occasions because the excess secretion of VIP is episodic and single measurements might be normal and misleading. A CT scan localizes most VIPomas, although as with all islet cell tumors, EUS is the most sensitive imaging method. Electrolyte and fluid balance is sometimes dif-ficult to correct preoperatively and must be pursued aggressively. Somatostatin analogues are helpful in controlling the diarrhea and allowing replacement of fluid and electrolytes. VIPomas are more commonly located in the distal pancreas and most have spread outside the pancreas. Palliative debulking operations can some-times improve symptoms for a period, along with somatostatin analogues. Hepatic artery embolization also has been reported as a potentially beneficial treatment.302GlucagonomaDiabetes in association with dermatitis should raise the suspi-cion of a glucagonoma. The diabetes usually is mild. The classic necrolytic migratory erythema manifests as cyclic migrations of lesions with spreading margins and healing centers typically on Brunicardi_Ch33_p1429-p1516.indd 148201/03/19 6:46 PM 1483PANCREASCHAPTER 33the lower abdomen, perineum, perioral area, and feet. Patients also complain of an enlarged, sensitive tongue. The diagnosis is confirmed by measuring serum glucagon levels, which are usu-ally >500 pg/mL. Glucagon is a catabolic hormone, and most patients present with malnutrition. The rash associated with glucagonoma is thought to be caused by low levels of amino acids. Preoperative treatment usually includes control of the dia-betes, parenteral nutrition, and octreotide. Like VIPomas, glu-cagonomas are more often in the body and tail of the pancreas and tend to be large tumors with metastases. Again, debulking operations are recommended in good operative candidates to relieve symptoms.SomatostatinomaBecause somatostatin inhibits pancreatic and biliary secretions, patients with a somatostatinoma present with gallstones due to bile stasis, diabetes due to inhibition of insulin secretion, and steatorrhea due to inhibition of pancreatic exocrine secretion and bile secretion. Most somatostatinomas originate in the proximal pancreas or the pancreatoduodenal groove, with the ampulla and periampullary area as the most common site (60%). The most common presentations are abdominal pain (25%), jaundice (25%), and cholelithiasis (19%).303 This rare type of pancreatic endocrine tumor is diagnosed by confirming elevated serum somatostatin levels, which are usually >10 ng/mL. Although most reported cases of somatostatinoma involve metastatic disease, an attempt at complete excision of the tumor and cholecystectomy is warranted in fit patients.Nonfunctioning Pancreatic Endocrine TumorsAlthough some pancreatic endocrine neoplasms secrete one or more hormones and are associated with interesting characteristic clinical syndromes, most are not associated with elevated serum hormone levels that cause symptoms. Pancreatic endocrine tumors are considered functional if they are associated with a clinical syndrome and nonfunctioning if not associated with clinical symptoms. The majority of pancreatic endocrine tumors (PET), also called pancreatic neuroendocrine tumors (pNET), are malignant because they have the potential for uncontrolled growth and metastasis. Immunohistochemical markers such as synaptophysin, chromogranin A (CgA), and neuron-specific enolase can be helpful in the diagnosis, but the gross histology is not a reliable predictor of biologic behavior. CgA is used by some as a serum marker to monitor patients for disease recur-rence or response to treatment, but the test performs poorly for this purpose. Patients often present similar to patients with pancreatic adenocarcinoma with vague pain or weight loss, but pNETs are increasingly discovered incidentally when imaging is performed for another reason. The tumor frequently enhances with arterial contrast (Fig. 33-66). Sometimes a cystic compo-nent is seen due to central necrosis. Octreoscan (somatostatin receptor scintigraphy) can be helpful to stage the disease. Sur-gical resection is typically recommended in fit patients in the absence of metastatic disease. For patients with tumors in the body and tail of the pancreas, this typically includes splenec-tomy. Enucleation and splenic preservation, although tempting in small tumors, fails to remove regional lymph nodes.With advances in imaging, small indolent pNETs are being discovered with increasing frequency, and some surgeons are considering observation in these cases.304 There are several argu-ments in favor of observation of small (<2 cm) nonfunctional pNETs, particularly in MEN-1 patients. Pancreatic resection has significant morbidity and mortality. In the setting of MEN-1, resection is rarely curative, and most patients require reopera-tion. Also, the survival of these patients, even with metastatic dis-ease, is generally excellent at least compared to pancreatic ductal adenocarcinoma. However, the 5-year survival with metastatic pNET is only 16% and radical surgery with curative intent is the standard of care, particularly in sporadic cases that are fit surgical candidates where the primary tumor can be completely excised.Adjuvant treatment after resection is withheld in the absence of radiographically demonstrable metastatic disease even if CgA levels remain elevated. Although these tumors have a slow growth pattern compared to pancreatic ductal adenocar-cinoma, many patients with pNETs will die of their disease even after an apparent complete resection, making surveillance after complete resection important. CT scan and or octreotide scan is recommended annually for 5 years after resection.ABCFigure 33-66. Pancreatic neuroendocrine tumor (PNET) demonstrating enhancement during arterial phase of computed tomography scan. Pancreatic head PNET seen in (left) sagital, (middle) coronal, and (right) lateral views of the abdomen.Brunicardi_Ch33_p1429-p1516.indd 148301/03/19 6:46 PM 1484SPECIFIC CONSIDERATIONSPART IIIncomplete resection (debulking) for locally advanced or metastatic pNETs of the pancreas is controversial because of the favorable survival duration of patients without surgery. How-ever, in carefully selected fit patients with a pNET in the head of the pancreas and minimal disease in the liver, a pancreaticoduo-denectomy with wedge resection of the liver metastasis might be appropriate because this avoids the morbidity of gastroin-testinal hemorrhage and biliary and gastric outlet obstruction before death from the metastatic disease. The role of cytoreduc-tive surgery in metastatic pNET is controversial, but consensus guidelines agree that aggressive resection of the primary tumor, regional lymph nodes, and liver/distant metastases should be pursued if greater than 90% of the tumor burden can be resected, which is the case in only about 10% of patients with metastatic disease.Treatment of metastatic pancreatic neuroendocrine cancer requires a multidisciplinary approach often including a com-bination of cytoreductive surgery when appropriate, directed therapy for the treatment of liver metastases when possible, and systemic medical therapy. Local ablative therapies include radiofrequency ablation (RFA), cryotherapy, microwave coagu-lation, and ethanol injection, although RFA is the most popular and widely studied. These therapies can be performed percuta-neously or during surgery via laparotomy or laparoscopy, can be repeated, and have been shown to complement resection of the primary tumor and amenable liver metastases; making pallia-tive surgery possible for patients that would otherwise not meet criteria. This approach often improves symptoms and 5-year survival is improved to 48%.305Transarterial chemoembolization (TACE) can be employed as palliative therapy in patients with liver metastases not amenable to surgical resection and/or ablation. It relies on the principle that metastatic tumor cells derive the majority of their oxygen supply from the hepatic artery as opposed to hepa-tocytes, which receive oxygen primarily from the portal vein. Performed via angiography, embolization may be performed alone (bland embolization) or in combination with chemothera-peutic agents (chemoembolization). Radioembolization, the selective distribution of radioactive yttrium-90 microspheres into the peritumoral vasculature via branches of the hepatic artery, is another alternative.Somatostatin analogs can inhibit release of hormones from functional pNETS and reduce diarrhea in patients with VIPo-mas, glucagonomas, and somatostatinomas, and it can also help the rash of glucagonomas. Somatostatin analogs such as octreotide (Sandostatin LAR Depot), lanreotide (Somatuline Depot), and a new analog pasireotide (Sifnifor LAR) are also used to slow the growth of some functional and nonfunctional pNETS. Disease seen on an octreotide scan has somatostatin receptors and would be expected to respond. Patients with unre-sectable disease are often treated with somatostatin analogs first before targeted therapy and cytotoxic chemotherapy are utilized because the side effects are minimal.Some targeted drugs can be helpful in treating advanced pNETs that progress despite somatostatin analogs. Sunitinib (Sutent) attacks new blood vessel growth and other targets that help cancer cells grow. Everolimus (Afinitor) works by block-ing a cell protein known as mammalian target of rapamycin (mTOR) and the VEGF pathway, which normally helps cells grow and divide. These targeted agents induce stabilization much more frequently than response, but they tend to carry fewer side effects than traditional cytotoxic chemotherapy. Cytotoxic chemotherapy for pNETS is usually reserved for large tumors or quickly growing tumors that are causing symptoms, or tumors that progressed despite somatostatin analogs and targeted ther-apy. Platinum-based chemotherapy does, however, remain the standard of care for high-grade (poorly differentiated) pNET, yielding high response rates but typically short-lived benefit. The newer cytotoxic combination of capecitabine and temozolo-mide has shown activity in well-differentiated pNET.306Neoplasms of the Exocrine PancreasEpidemiology and Risk Factors. It is estimated that in 2017, 53,670 Americans will be diagnosed with pancreatic cancer and 43,090 will die from the disease. Overall, pancreatic cancer has the worst prognosis of all malignancies with a 5-year survival rate of only 7.2%.307 The incidence of pancreatic cancer continues to increase, perhaps related to the increased incidence of risk factors such as obesity and diabetes, and as a result, it is predicted that pancreatic cancer will become the leading cause of cancer deaths in the United States by 2050. Pancreatic cancer recently surpassed breast cancer and is now the third leading cause of cancer death behind lung and colorectal cancer. Despite its ubiquity, this dis-ease is extremely difficult to treat, and its exact cause is unknown. However, epidemiologic studies linking various environmental and host factors provide some clues. Recent discoveries using modern molecular biologic techniques have also improved our understanding of the causes of pancreatic cancer. The etiology of pancreatic cancer likely involves a complex interaction of genetic and environmental factors. These factors will become more fully understood as DNA sequencing is used to screen populations at risk for developing pancreatic cancer.Pancreatic cancer is more common in older adults with most patients being 75 to 84 years old. Pancreatic cancer is more common in African Americans and slightly more com-mon in men than women. The risk of developing pancreatic cancer is two to three times higher if a parent or sibling had the disease. Another risk factor that is consistently linked to pan-creatic cancer is cigarette smoking. Smoking increases the risk of developing pancreatic cancer by at least twofold due to the carcinogens in cigarette smoke.308 Coffee and alcohol consump-tion have been investigated as possible risk factors, but the data are inconsistent. As in other GI cancers, diets high in fat and low in fiber, fruits, and vegetables are thought to be associated with an increased risk of pancreatic cancer.Diabetes has been known to be associated with pancreatic cancer for many years. In fact, glucose intolerance is present in 80% of patients with pancreatic cancer, and approximately 20% have overt diabetes, a much greater incidence than would be expected to occur by chance. Preexisting type 2 diabetes increases the risk for development of pancreatic cancer by about twofold.309 The new onset of diabetes also can be an early mani-festation of otherwise occult pancreatic cancer. Thus, the new onset of diabetes, or a sudden increase in insulin requirement in an older adult patient with preexisting diabetes, should provoke concern for the presence of pancreatic cancer.Recent epidemiologic studies have confirmed the fact that patients with chronic pancreatitis, especially familial pan-creatitis, have an increased risk of developing pancreatic can-cer.124,196-198 Large, retrospective cohort studies of patients with pancreatitis have revealed up to a 20-fold increase in risk for pancreatic cancer. This increased risk seems to be independent of the type of pancreatitis, a finding consistent with the fact that most studies have shown little effect of alcohol ingestion per se Brunicardi_Ch33_p1429-p1516.indd 148401/03/19 6:46 PM 1485PANCREASCHAPTER 33on the risk of pancreatic carcinoma. The mechanisms involved in carcinogenesis in patients with preexisting pancreatitis are unknown. However, the mutated K-ras oncogene, which is pres-ent in most cases of pancreatic cancer, has been detected in the ductal epithelium of some patients with chronic pancreatitis.Genetics of Pancreatic Cancer. Pancreatic carcinogenesis probably involves multiple mutations that are inherited and acquired throughout aging. The K-ras oncogene is currently thought to be the most commonly mutated gene in pancreatic cancer, with approximately 90% of tumors having a mutation.310 This prevalent mutation is present in precursor lesions and is therefore thought to occur early and be essential to pancre-atic cancer development. K-ras mutations can be detected in DNA from serum, stool, pancreatic juice, and tissue aspirates of patients with pancreatic cancer, suggesting that the presence of this mutation or others may provide the basis for diagnostic testing in select individuals. The HER2/neu oncogene, homolo-gous to the epidermal growth factor receptor (EGFr), is over-expressed in pancreatic cancers.310 This receptor is involved in signal transduction pathways that lead to cellular proliferation. Multiple tumor-suppressor genes are deleted and/or mutated in pancreatic cancer, including p53, p16, and DPC4 (Smad 4), and in a minority of cases, BRCA2.311 Most pancreatic cancers have three or more of the aforementioned mutations.The genetic landscape of pancreatic adenocarcinoma has recently been investigated using exome capture technol-ogy combined with the SOLiD or Illumina next generation sequencing platforms and copy number analysis. Detailed analysis of 99 tumors reaffirmed the importance of the already known mutations such as KRAS, TP53, CDKN2A, SMAD4, MLL3, TGFBR2, ARID1A, and SF3B1 in pancreatic cancer and identified eight novel significantly mutated genes involved in chromatin modification (EPC1 and ARID2), DNA dam-age repair (ATM) and other mechanisms (ZIM2, MAP2K4, NALCN, SLC16A4, and MAGEA6). Pathway-based analysis of recurrently altered genes also revealed the involvement of axon-guidance genes, particularly SLIT/ROBO signaling, in pancreatic carcinogenesis.312 Rapid and sensitive sequencing techniques will hopefully lead to better diagnostic and thera-peutic approaches for pancreatic cancer.It is estimated that up to 10% of pancreatic cancers occur as a result of an inherited genetic predisposition. A family his-tory of pancreatic cancer in a first-degree relative increases the risk of pancreatic cancer by about twofold. Rare familial cancer syndromes that are associated with an increased risk of pancreatic cancer include BRCA2, the familial atypical multiple mole–melanoma syndrome, hereditary pancreati-tis, familial adenomatous polyposis (FAP), hereditary non-polyposis colorectal cancer, Peutz-Jeghers syndrome, and ataxia-telangiectasia.311Pathology. Pancreatic cancer probably arises through a stepwise progression of cellular changes, just as colon cancer progresses by stages from hyperplastic polyp to invasive cancer. Systematic histologic evaluation of areas surrounding pancreatic cancers has revealed the presence of precursor lesions that have been named pancreatic intraepithelial neoplasia (Fig. 33-67). Three stages of pancreatic intraepithelial neoplasia have been defined. These lesions demonstrate the same oncogene mutations and loss of tumor-suppressor genes found in invasive cancers, the frequency of these abnormalities increasing with progressive cellular atypia and architectural disarray.313 The ability to detect these precursor lesions in humans at a stage where the cancer can still be prevented or cured is an important goal of current pancreatic cancer research.About two-thirds of pancreatic adenocarcinomas arise within the head or uncinate process of the pancreas; 15% are in the body, and 10% are in the tail, with the remaining tumors demonstrating diffuse involvement of the gland. Tumors in the pancreatic body and tail are generally larger at the time of diagnosis, and therefore, less commonly resectable. Tumors in the head of the pancreas are typically diagnosed earlier because they cause obstructive jaundice. Ampullary carci-nomas, carcinomas of the distal bile duct, and periampullary duodenal adenocarcinomas present in a similar fashion to pan-creatic head cancer but have a slightly better prognosis, prob-ably because early obstruction of the bile duct and jaundice leads to the diagnosis.In addition to ductal adenocarcinoma, which makes up about 75% of nonendocrine cancers of the pancreas, there are a variety of less common types of pancreatic cancer. Adenosquamous carcinoma is a variant that has both glandular and squamous differentiation. The biologic behavior of this lesion is unfortunately no better than the typical ductal adenocarcinoma.314 Acinar cell carcinoma is an uncommon type of pancreatic cancer that usually presents as a large tumor, often 10 cm in diameter or more, but the prognosis of patients with these tumors may be better than with ductal cancer.Diagnosis and Staging. Exact pathologic staging of pancre-atic cancer is important because it allows accurate quantitative assessment of results and comparisons between institutions. The tumor-node-metastasis (TNM) staging of pancreatic cancer was updated by the American Joint Committee on Cancer in 2017 (AJCC) (Table 33-21).The important changes in the staging include more stratification for tumor size and stratification for number of lymph nodes involved. In the new system, tumors ≤2 cm remain as T1 lesions but are subcategorized as T1a (≤0.5 cm), T1b (>0.5–>1 cm), and T1c (1–2 cm). Tumors that are >2–≤4 cm are categorized as T2, and tumors >4 cm are categorized as T3. Tumors that involve the celiac axis, superior mesenteric artery, and/or common hepatic artery are still categorized as T4 regardless of size. Metastasis in one to three regional lymph nodes is considered N1 disease, and involvement of ≥4 regional lymph nodes is N2. Patients without nodal involvement (N0) are stages IA, IB, and IIA based on tumor size (T1–T3, respectively). Patients with one to three regional lymph nodes involved (N2) are stage IIB regardless of tumor size. All patients with N2 disease without distant metastases are considered stage III regardless of tumor size. Patients with vascular involvement (T4) are stage III regardless of nodal involvement, and patients with distant metastases are, of course, stage IV.Ten percent of pancreas cancer cases are diagnosed while the cancer is still confined to the primary site (localized stage); 29% are diagnosed after the cancer has spread to regional lymph nodes or directly beyond the primary site; 52% are diagnosed after the cancer has already metastasized (distant stage); and for the remaining 9%, the staging information was unknown. The corresponding 5-year relative survival rates were 31.5% for localized, 11.5% for regional, 2.7% for distant, and 5.1% for unstaged. The overall 5-year relative survival rate for patients with pancreatic cancer for 2007 to 2013 from Surveillance, Epidemiology, and End Results (SEER) was 8.2%.3077Brunicardi_Ch33_p1429-p1516.indd 148501/03/19 6:46 PM 1486SPECIFIC CONSIDERATIONSPART IINormalPanIN-1APanIN-1BPanIN-2KI-67, Topo˜˜°, 14-3-3˛p53, DPC4, BRCA2Cyclin D1MesothelinMucin 1Mucin 1p16PSCA, Mucin5, FascinTelomere K-rasshorteningPanIN-3InvasionABCDFigure 33-67. Pancreatic intraepithelial neoplasia (PanIN). Histology (top panel) showing grades PanIN-1A (A), PanIN-1B (B), PanIN-2 (C), and PanIN-3 (D), and schema of correlation of histology with mutational events (bottom panel) showing cumulative abnormalities of tumor-promoter and tumor suppressor factors such as kRAS, p53, etc, and their corresponding cellular phenotype. (Reproduced with permis-sion from Hruban RH, Takaori K, Klimstra DS, et al: An illustrated consensus on the classification of pancreatic intraepithelial neoplasia and intraductal papillary mucinous neoplasms, Am J Surg Pathol. 2004 Aug;28(8):977-987.)The most critical deficit in the ability to treat pancreatic cancer effectively is the lack of tools for early diagnosis. The pancreas is situated deep within the abdomen, and the early symptoms of pancreatic cancer often are too vague to raise sus-picion of the disease. Ultimately, the majority of patients present with pain and jaundice. On physical examination, weight loss is evident and the skin is icteric; a distended gallbladder is palpa-ble in about one-fourth of patients. More fortunate patients have tumors situated such that biliary obstruction and jaundice occurs early and prompts diagnostic tests. Unfortunately, however, the vast majority of patients are not diagnosed until weight loss has occurred—a sign of advanced disease.Although it is often taught that carcinoma of the pancreas presents with painless jaundice (to help distinguish it from cho-ledocholithiasis), this aphorism is not accurate. Most patients do experience pain as part of the symptom complex of pancreatic cancer, and it is often the first symptom. Therefore, awareness of the way pancreatic pain is perceived may help clinicians sus-pect pancreatic cancer. The pain associated with pancreatic can-cer is usually perceived in the epigastrium but can occur in any Brunicardi_Ch33_p1429-p1516.indd 148601/03/19 6:46 PM 1487PANCREASCHAPTER 33the serum of patients with pancreatic cancer. Serum levels are elevated in about 75% of patients with pancreatic cancer. How-ever, CA19-9 is also elevated in about 10% of patients with benign diseases of the pancreas, liver, and bile ducts.15 CA19-9 is thus neither sufficiently sensitive nor specific to allow an early diagnosis of pancreatic cancer. Despite the fact that many tumor markers such as CA19-9 have been studied, there are still no effective screening tests for pancreatic cancer. Research tak-ing advantage of recent advances in genomics, gene expression analysis, and proteomics has demonstrated thousands of genes and corresponding proteins that are differentially expressed in pancreatic tumors that have potential for early detection of pan-creatic cancer.316 Some of these proteins would be expected to be expressed at the cell surface or in pancreatic juice and may become useful as biomarkers for pancreatic cancer in the future.In patients presenting with jaundice, a reasonable first diagnostic imaging study is abdominal ultrasound. If bile duct dilation is not seen, hepatocellular disease is likely. Demonstra-tion of cholelithiasis and bile duct dilation suggests a diagnosis of choledocholithiasis, and the next logical step would be ERCP to clear the bile duct. In the absence of gallstones, malignant obstruction of the bile duct is likely, and a CT scan rather than ERCP would be the next logical step. For patients suspected of having pancreatic cancer who present without jaundice, a CT scan should be the first test.The current diagnostic and staging test of choice for pan-creatic cancer is a multidetector, dynamic, contrast-enhanced CT scan, and the techniques for obtaining high-quality images are constantly improving (Fig. 33-68). The accuracy of CT scan-ning for predicting unresectable disease is about 90% to 95%.317 In contrast, CT scanning is less accurate in predicting resect-able disease. CT scanning will miss small liver metastases, and predicting arterial involvement is sometimes difficult. CT find-ings that indicate a tumor is unresectable include involvement of ≥180° of the celiac axis, hepatic or superior mesenteric artery, enlarged lymph nodes outside the boundaries of resection, asci-tes, and distant metastases (e.g., liver). Invasion of the superior mesenteric vein or portal vein is not in itself a contraindication to resection as long as the veins are patent. Tumors are consid-ered “borderline resectable” if there is abutment of ≤180 degrees of the circumference of the SMA, celiac axis, or hepatic artery or if there is a short segment of vein occlusion. Also, patients with CT findings suspicious for metastatic disease, like 1 mm liver lesions too small to characterize or biopsy, are considered “borderline resectable” as are patients with multiple comorbidi-ties or marginal performance status. There is growing consensus that neoadjuvant treatment should be considered in all patients with any radiographic evidence of extension to adjacent vascu-lar structures.Currently, multidetector CT is probably the single most versatile and cost-effective tool for the diagnosis and staging of pancreatic cancer. Abdominal MRI provides essentially the same information as CT scanning. Positron emission tomog-raphy scanning in locally advanced lesions may help rule out distant metastases. EUS can be used to detect small pancreatic masses that could be missed by CT scanning and is commonly used when there is a high suspicion for pancreatic cancer but no mass is identified by the CT scan. EUS has the added advan-tage of providing the opportunity for transluminal biopsy of pancreatic masses, although a tissue diagnosis before pancreati-coduodenectomy is not required. However, in specific patients a histologic diagnosis may be necessary such as for those in a part of the abdomen, and often, but not always, penetrates to the back. When questioned in retrospect, patients often recall mild and vague pain for many months before diagnosis. A low thresh-old for ordering a CT scan with “pancreatic protocol” should be maintained for elderly patients with unex-plained, persistent, although vague, abdominal pain. As men-tioned previously, new-onset diabetes in an elderly patient, especially if combined with vague abdominal pain, should prompt a search for pancreatic cancer.Unfortunately, at this time there is no sensitive and spe-cific serum marker to assist in the timely diagnosis of pan-creatic cancer. With jaundice, direct hyperbilirubinemia and elevated alkaline phosphatase are expected but do not serve much of a diagnostic role other than to confirm the obvious. With long-standing biliary obstruction, the prothrombin time will be prolonged due to a depletion of vitamin K, a fat-soluble vitamin dependent on bile flow for absorption. CA19-9 is a mucin-associated carbohydrate antigen that can be detected in 8Table 33-21Staging of pancreatic cancerTumor (T)TXTumor cannot be assessedT1Tumor limited to the pancreas,* <2 cmT2Tumor limited to the pancreas,* 2–4 cmT3Tumor limited to the pancreas,* >4 cm; or tumor invading the duodenum or common bile ductT4Tumor invading adjacent organs (stomach, spleen, colon, adrenal gland) or the wall of large vessels (celiac axis or the superior mesenteric artery)Regional Lymph Node (N)NXRegional lymph nodes cannot be assessedN0No regional lymph node involvementN1Regional lymph node involvementDistant Metastasis (M)M0No distant metastasisM1Distant metastasis M1aMetastasis confined to liver M1bMetastases in at least one extrahepatic site (e.g., lung, ovary, nonregional lymph node, peritoneum, bone) M1cBoth hepatic and extrahepatic metastasesTUMORNODEMETASTASISSTAGET1N0M0IT2N0M0IIT3N0M0IIT4N0M0IIIAny TN1M0IIIAny TAny NM1IVUsed with the permission of the American College of Surgeons. Amin MB, Edge SB, Greene FL, et al. (Eds.) AJCC Cancer Staging Manual, 8th Ed. Springer New York, 2017.Brunicardi_Ch33_p1429-p1516.indd 148701/03/19 6:46 PM 1488SPECIFIC CONSIDERATIONSPART IIPortal veinStomachHepaticarteryCeliac axisSplenic veinDilated pancreatic ductin body of pancreasGallbladderPortal veinPortal veinVena cavaDilated bile ductwith stentBody of pancreasGallbladderSplenoportalconfluenceDuodenumMass in headof pancreasMass in head,uncinate processof pancreasSMASMASMADuodenumBile duct stentFat plane between massin head of pancreasand portal veinFigure 33-68. Computed tomography scan demonstrating resectable pancreatic cancer. SMA = superior mesenteric artery.neoadjuvant clinical trial or before chemotherapy in advanced tumors. EUS is a sensitive test for portal/superior mesenteric vein invasion, although it is somewhat less effective at detect-ing superior mesenteric artery invasion. When all of the current staging modalities are used, their accuracy in predicting resect-ability has improved.As imaging continuously improves and high-quality imag-ing is always obtained before surgery, the chance of bringing a patient to the operating room with the intent of a curative resec-tion and finding upon exploration that the patient has unresect-able disease is becoming increasingly uncommon.In an attempt to avoid such futile laparotomies, prelimi-nary laparoscopy has been advocated for patients with disease felt to be resectable by CT imaging (Fig. 33-69). Diagnostic laparoscopy with the use of US is reported to improve the accu-racy of predicting resectability to about 98%.318 The technique involves more than simple visualization with the scope and requires the placement of multiple ports and manipulation of the tissues. A general exploration of the peritoneal surfaces is carried out. The ligament of Treitz and the base of the transverse mesocolon are examined for tumor. The gastrocolic ligament is incised, and the lesser sac is examined. The ultrasound probe is used to examine the liver, porta hepatis and the portal vein, the celiac axis, and the superior mesenteric artery.The percentage of patients in whom a positive laparoscopy helps avoid a nontherapeutic laparotomy varies from 10% to 30% in carcinoma of the head of the pancreas, but it may be as high as 50% in patients with tumors in the body and tail of the gland. Resection for pancreatic cancer is being approached laparoscopically, particularly for tumors in the body and tail of the pancreas thus eliminating the need for any separate stag-ing laparoscopy procedure. Also, as the quality of CT scanning has improved, the value of routine diagnostic laparoscopy has decreased. The morbidity of diagnostic laparoscopy is less than that of laparotomy, and the procedure can be performed on an outpatient basis. Patients who are found to have unresectable disease recover more rapidly from a laparoscopy than a lapa-rotomy and can receive palliative chemotherapy and radiation sooner. The potential immunosuppressive effects of a major surgical procedure also are avoided, as well as the negative psy-chologic impact of a major painful operation with little benefit.Biliary obstruction can be relieved with an endoscopic approach in almost all cases. When large (10F) plastic stents are used, most patients do not require replacement for about 3 months. Metallic wall stents last about 5 months on average and usually fail only with tumor ingrowth.319 Keeping in mind that patients with unresectable pancreatic cancer usually live <1 year, the requirement for numerous stent changes is unlikely.Diagnostic laparoscopy is possibly best applied to patients with pancreatic cancer on a selective basis. Diagnostic laparos-copy will have a higher yield in patients with large tumors (T3, Figure 33-69. Liver metastases identified at diagnostic laparoscopy.Brunicardi_Ch33_p1429-p1516.indd 148801/03/19 6:46 PM 1489PANCREASCHAPTER 33>4 cm), tumors located in the body or tail, patients with equivo-cal findings of metastasis or ascites on CT scan, and patients with other indications of advanced disease such as marked weight loss or markedly elevated CA19-9 (>1000 U/mL). An algorithm for the diagnosis, staging, and treatment of pan-creatic cancer is shown in Fig. 33-70. In practice, many of these patients are selected for neoadjuvant chemotherapy and then undergo restaging CT and staging laparoscopy prior to surgery.Palliative Surgery and Endoscopy. Most patients with pan-creatic cancer (85–90%) have disease that clearly precludes surgical resection. For these patients, appropriate and effective palliative treatment is critical to the quality of their remaining life. Because of the poor prognosis of the disease, it is not appro-priate to use invasive, toxic, and expensive regimens in patients with extremely advanced disease and poor performance status. When patients do desire antineoplastic therapy, it is important to encourage them to enroll in clinical trials so that therapeutic advances can be made. In general, there are three clinical prob-lems in advanced pancreatic cancer that require palliation: pain, jaundice, and duodenal obstruction. The mainstay of pain con-trol is oral narcotics. Sustained-release preparations of morphine sulfate are frequently used. Invasion of retroperitoneal nerve trunks accounts for the severe pain experienced by patients with advanced pancreatic cancer. A celiac plexus nerve block can control pain effectively for a period of months, although the procedure sometimes needs to be repeated.320Jaundice is present in the majority of patients with pan-creatic cancer, and the most troublesome aspect for the patient is the accompanying pruritus. Biliary obstruction may also lead to cholangitis, coagulopathy, digestive symptoms, and hepato-cellular failure. In the past, surgeons traditionally performed a biliary and enteric bypass when unresectable disease was found at laparotomy. This is an increasingly uncommon situation for the surgeon because locally advanced unresectable disease is now detected by high-quality preoperative imaging. Metastatic disease is also more reliably predicted by preoperative imaging and, in select cases, staging laparoscopy.In current practice, jaundice is usually palliated by an endoscopic biliary stent, often prior to surgical referral. Duo-denal obstruction is usually a late event in pancreatic cancer and occurs in only about 20% of patients.321 In cases of biliary and duodenal obstruction, several options need to be consid-ered. Endoscopic metallic duodenal stents are an option, but the patient’s poor prognosis, the cost, and the fact that duodenal stents often do not result in ideal palliation has to be considered. The results of three RCTs examining endoscopic metallic stent-ing for malignant gastric outlet obstruction demonstrated that major and minor complications were comparable to gastrojeju-nostomy but time to tolerating oral intake and hospital stay was shorter.322 Robot-assisted laparoscopic biliary-enteric bypass is now available at many centers. Although this should result in similar palliation as an open bypass and may be associated with more rapid recovery, the potential complications, the patient’s life expectancy, and cost of this procedure must be considered. As many patients today already have a bile duct stent in place by the time of referral to a surgeon, it is not clear that operative biliary bypass is required. In patients with extensive metastases, an alternative short-term palliative option to consider in patients with gastric outlet obstruction is a percutaneous endoscopic gas-trostomy tube or gastrojejunal feeding tube that allows decom-pression of the stomach and feeding into the jejunum.If an operative bypass is performed, choledochojejunos-tomy is the preferred approach. Although an easy procedure to perform, choledochoduodenostomy is felt to be unwise because of the proximity of the duodenum to tumor. Some have discour-aged the use of the gallbladder for biliary bypass; however, it CT scanQuad phaseMultidetectorFine cutsUnresectablemassCT or EUSguided biopsyClinicaltrialResectable massNo mass butsuspicion remainsClinical trialDiagnosticlaparoscopy(selective)EUS biopsydiagnosticlaparoscopyNeoadjuvantclinicaltrialERCP / EUSObserve/reimageWhippleprocedureFigure 33-70. Diagnostic and treatment algorithm for pancreatic cancer. If computed tomography (CT) scan demonstrates a potentially resectable tumor, patients are offered participation in a clinical trial after histologic confirmation by CT or endoscopic ultrasound (EUS)-guided biopsy. If CT scan demonstrates resectable disease, diagnostic laparoscopy is used selectively in patients with tumors in the body/tail, equivocal findings of metastasis or CT scan, ascites, high CA19-9, or marked weight loss. Patients also have diagnostic laparoscopy if they elect to participate in a neoadjuvant clinical trial. In cases where no mass is demonstrated on CT scan, but suspicion of cancer remains, EUS or endoscopic retrograde cholangiopancreatography (ERCP) with brushings are performed, and the CT may be repeated after an interval of observation.Brunicardi_Ch33_p1429-p1516.indd 148901/03/19 6:46 PM 1490SPECIFIC CONSIDERATIONSPART IIis suitable as long as the cystic duct clearly enters the common duct well above the tumor. The jejunum is brought anterior to the colon, if possible, rather than retrocolic, where the tumor potentially would invade the bowel sooner. Some surgeons use a loop of jejunum with a jejunojejunostomy to divert the enteric stream away from the biliary-enteric anastomosis. Others use a Roux-en-Y limb with the gastrojejunostomy located 50 cm downstream from the hepaticojejunostomy (Fig. 33-71). Poten-tial advantages of the defunctionalized Roux-en-Y limb include the ease with which it will reach up to the hepatic hilum, prob-able decreased risk of cholangitis, and easier management of biliary anastomotic leaks. If a gastrojejunostomy is performed, it should be placed dependently and posterior along the greater Figure 33-71. Biliary-enteric bypass to palliate unresectable pan-creatic cancer. (Reproduced with permission from Bell RH, Rikkers LF, Mulholland M: Digestive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)Figure 33-72. Expandable metallic biliary stent. After ERCP cannulation of the distal bile duct (left) the stent is advanced over the cannula and placed across the obstruction in the distal bile duct (right).curvature to improve gastric emptying, and a vagotomy should not be performed. Endoscopic stents are definitely not as dura-ble as a surgical bypass. Recurrent obstruction and cholangitis is more common with stents and results in inferior palliation. However, the endoscopic approach is associated with consider-ably less initial morbidity and mortality than surgical bypass. Expandable metallic wall stents have superior patency and pro-vide better palliation than plastic stents (Fig. 33-72).If an initial diagnostic laparoscopy reveals a contraindica-tion to the Whipple procedure, such as liver metastases, it is not appropriate to perform a laparotomy simply to create a biliary bypass. In such a patient, it is better to place an endoscopic stent. In contrast, in the uncommon scenario where a laparotomy has already been performed as part of the assessment of resectability and the Whipple procedure is not possible, a surgical bypass is usually performed. However, if the patient has a functioning endoscopic stent already in place, it may be reasonable to forego surgical bypass.Chemotherapy and Radiation for Locally Advanced/ Metastatic Disease. Patients with locally advanced unresectable disease are treated with chemotherapy and possibly radiation, and patients with stage IV metastatic disease are treated with systemic chemotherapy. The role of RT in unresectable, locoregionally advanced pancreas cancer remains controversial. RT may slow the progression of local disease and possibly alleviate or prevent symptoms including pain, biliary obstruction, bleeding, and bowel obstruction. However, the likelihood of micrometastatic distant disease is high, treatment is not expected to be curative, and radiation can result in toxicity. Stereotactic body radiotherapy (SBRT) has been used to limit toxicity by targeting high-dose short-course radiation to enhance local response prior to surgery. In a phase 2 multi-institutional trial evaluating gemcitabine and SBRT in patients with locally advanced unresectable pancreatic cancer, 10% of patients with locally advanced disease who would not have been candidates for initial surgery were deemed to have resectable tumors following therapy, and 8% ultimately underwent R0 and node-negative resection.323 A number of chemotherapy regimens are available for pancreatic cancer, but the results are not impressive. Gemcitabine (Gemzar) was approved by the U.S. Food and Drug Administration (FDA) for use in pancreatic cancer in 1996. In patients with unresectable pancreatic cancer, gemcitabine results in symptomatic Brunicardi_Ch33_p1429-p1516.indd 149001/03/19 6:46 PM 1491PANCREASCHAPTER 33improvement, improved pain control and performance status, and weight gain.324 However, survival is improved by only 1 to 2 months. Prior to gemcitabine, 5-fluorouracil (5-FU) was used as the standard treatment for unresectable pancreatic cancer. Both of these drugs are still used today. 5-FU or capecitabine (Xeloda), a similar but orally administered drug, are frequently used as a radiosensitizer during radiation therapy. Single-agent gemcitabine is still commonly used in patients with a poor performance status.Erlotinib (Tarceva) was approved in 2005 based on very minimal improvement in overall survival in combination with gemcitabine.325 The study showed that erlotinib in combination with gemcitabine results in a statistically significant improve-ment in overall survival in patients with advanced pancreatic cancer in the first-line setting. Although the absolute benefit in overall survival was modest with a median survival difference between the two arms of only 2 weeks.FOLFIRINOX, a combination of three chemotherapy drugs (5-FU/leucovorin, irinotecan, and oxaliplatin) is now commonly used as first-line treatment for metastatic pancreatic adenocarcinoma in patients with a relatively good performance status. In 2010, a Phase 3 clinical trial showed positive results for patients treated with FOLFIRINOX.326 The objective response rate was improved from 9% to 32%, and median overall survival of patients with metastatic pancreatic cancer improved from 7 to 11 months, but the improvement was associated with increased toxicity, so patient selection is important. Patients treated with FOLFIRINOX may experience more severe side effects than those treated with gemcitabine alone, so this combination is usu-ally reserved for patients with a good performance status.In 2013, another combination therapy was approved as first-line treatment for metastatic pancreatic adenocarcinoma.327 Albumin-bound paclitaxel (Abraxane) was approved to be used in combination with gemcitabine (Gemzar). The median overall survival was improved to 8.5 months in the nabpaclitaxel–gemcitabine group as compared with 6.7 months in the gemcitabine group. Progression-free survival and the response rate were also improved. Rates of peripheral neuropathy and myelosuppression were increased, but this regimen is less toxic than FOLFIRINOX.In 2015, Irinotecan (ONIVYDE), in combination with 5-FU (fluorouracil) and leucovorin, was approved as treatment for met-astatic pancreatic adenocarcinoma that has progressed following treatment with a gemcitabine based therapy.328 The median over-all survival in patients assigned to nanoliposomal irinotecan plus fluorouracil and folinic acid was 6.1 months vs. 4.2 months with fluorouracil and folinic acid. Common side effects for this second-line therapy were neutropenia, diarrhea, vomiting, and fatigue.These results may warrant treatment in patients who understand the benefits and risks. However, the lack of signifi-cant survival advantage should encourage physicians to refer motivated patients for experimental protocols because it is only through continued clinical research that more meaningful treat-ments for pancreatic cancer will be developed.Ablation for Locally Advanced Unresectable Disease.  Persistent arterial vascular encasement after neoadjuvant therapy contraindicates resection. Irreversible electroporation utilizes delivery of high-voltage millisecond electrical pulses resulting in permanent disruption of the cellular membranes and subsequent apoptosis. This process leads to cell death, but does not injure the extracellular matrix, thus allowing cellular tumor ablation while preserving structural components of tissues. Collagen-based structures such as vessels or the pancreatic duct are not disrupted. Furthermore, because IRE is not based on thermal damage of cancer cells, the heat-sink phenomenon is not a concern, and even lesions abutting large vessels can be ablated with radical intent. Irreversible electroporation using the Nanoknife is reported to enable treatment of pancreatic tumors abutting vascular structures without compromise of the vessels or concern for the heat sink effect of nearby blood flow.329 Martin has created a registry and accumulated multi-institutional data on 200 patients with locally advanced pancreatic cancer showing OS of 28.3 months for patients with borderline resectable pancreatic cancer and 23.2 months in patients with unresectable pancreatic cancer. Those numbers compare favorably with the survival of patients treated with chemoradiation alone, which is 13 months in historical controls.330 This modality is new, but these early reports indicate it may be safe in combination with chemotherapy and are of particular interest because of the potential to down stage and offer surgery to patients initially diagnosed with locally advanced unresectable disease. It is also important to understand that a significant learning curve exists to achieve safety and optimization of the technique. Proper patient selection, technical ability with intraoperative ultrasound to allow precise IRE electrode bracketing, and standardization of the IRE energy delivery is important. Randomized prospective trials are needed before adoption of this technique can be expanded.Surgical Resection: Pancreaticoduodenectomy. In a patient with appropriate clinical and/or imaging indications of pancreatic cancer, a tissue diagnosis before performing a pancreaticoduo-denectomy is not essential. Although percutaneous CT-guided biopsy is usually safe, complications such as hemorrhage, pan-creatitis, fistula, and abscess can occur. Tumor seeding along the subcutaneous tract of the needle is uncommon. Likewise, FNA under EUS guidance is safe and well tolerated. The prob-lem with preoperative or even intraoperative biopsy is that many pancreatic cancers are not very cellular and contain a significant amount of fibrous tissue, so a biopsy may be misinterpreted as showing chronic pancreatitis if it does not contain malignant glandular cells. In the face of clinical and radiologic preoperative indications of pancreatic cancer, a negative biopsy should not preclude resection. In patients who are not candidates for resec-tion because of metastatic disease, biopsy for a tissue diagnosis becomes important because these patients may be candidates for palliative chemotherapy trials. It is especially important to make an aggressive attempt at tissue diagnosis before surgery in patients whose clinical presentation and imaging studies are more suggestive of alternative diagnoses such as pancreatic lym-phoma or pancreatic islet cell tumors. These patients might avoid surgery altogether in the case of lymphoma or warrant an aggres-sive approach in the case of islet cell carcinoma.Pancreaticoduodenectomy can be performed through a midline incision from xiphoid to umbilicus or through a bilat-eral subcostal incision. The initial portion of the procedure is an assessment of resectability. The liver and visceral and parietal peritoneal surfaces are thoroughly assessed. The gastrohepatic omentum is opened, and the celiac axis area is examined for enlarged lymph nodes. The base of the transverse mesocolon is examined for tumor involvement.The ascending and hepatic flexure of the colon are mobi-lized off the duodenum and head of the pancreas and reflected medially. A Kocher maneuver is performed by dissecting behind Brunicardi_Ch33_p1429-p1516.indd 149101/03/19 6:46 PM 1492SPECIFIC CONSIDERATIONSPART IIthe head of the pancreas. The superior mesenteric vein is identi-fied early in the case and dissected up toward the inferior border of the neck of the pancreas. The gastroepiploic vein and artery are ligated to prevent any traction injury. Often, the middle colic vein and right gastroepiploic vein share a common trunk before entering into the superior mesenteric vein. Knowledge of this anatomy helps reduce injury to the veins and unnecessary blood loss. The relation of the tumor to the superior mesenteric vein and artery cannot be accurately assessed by palpation at this point and is not completely determined until later in the opera-tion when the neck of the pancreas is divided and the surgeon is committed to resection. Mesenteric vascular involvement is best determined by a high quality preoperative CT scan.It is important to assess for an aberrant right hepatic artery, which is present in 20% of patients. The aberrant artery com-monly arises from the superior mesenteric artery posterior to the pancreas and ascends parallel and adjacent to the superior mesenteric and portal veins. The presence of an aberrant right hepatic artery should be apparent on the preoperative CT scan and can be identified intraoperatively by palpation on the back side of the hepatoduodenal ligament, where a prominent pulse will be felt posterior and to the right of the portal vein.The porta hepatis is examined. Enlarged or firm lymph nodes that can be swept down toward the head of the pancreas with the specimen do not preclude resection. If the assessment phase reveals no contraindications to the Whipple procedure (Table 33-22), the resection phase commences.If the pylorus is to be preserved, the stomach and proximal duodenum are mobilized off the pancreas, preserving the gastroepiploic vessels down to the pylorus. The proximal hepatic artery is identified usually by removing a lymph node that commonly lies just anterior to the artery. The hepatic artery is dissected and traced toward the porta hepatis. The gastroduodenal branch of the hepatic artery is identified. A test clamping is performed to ensure that a strong pulse remains in the proper hepatic artery before division of the gastroduodenal artery. In cases of celiac occlusion, flow comes from the superior mesenteric artery and retrograde through the gastroduodenal artery to the proper hepatic artery. Ligation of the gastroduodenal in this case would be equivalent to hepatic artery ligation. A bypass to the hepatic artery would be required. Once the test clamping is negative and the gastroduodenal artery is divided, the hepatic artery is retracted medially, and the common bile duct is retracted laterally to reveal the anterior surface of the portal vein behind them. Dissection is performed only on the anterior surface of the vein. If there is no tumor involvement, the neck of the Table 33-22Findings at explorationFindings contraindicating resection Liver metastases (any size) Celiac lymph node involvement Peritoneal implants Hepatic hilar lymph node involvementFindings not contraindicating resection Invasion at duodenum or distal stomach Involved peripancreatic lymph nodes Involved lymph nodes along the porta hepatis that can be swept down with the specimenpancreas will separate from the vein easily. A large, blunt-tipped clamp is a safe instrument to use for this dissection. The tunnel under the neck of the pancreas can then be completed mostly under direct vision from inferior and superior.The gallbladder is then mobilized from the liver, the cystic duct and artery are ligated, and the gallbladder is removed. The common hepatic duct is circumferentially dissected. Either the duodenum is divided 2 cm distal to the pylorus (which defines the procedure as a pylorus-preserving pancreaticoduodenectomy, or PPPD) or the antrum is divided, as classically described by Whipple. The jejunum is divided beyond the ligament of Treitz, and the mesentery is ligated until the jejunum can be delivered posterior to the superior mesenteric vessels from left to right.The common hepatic duct is then divided usually just above the entrance of the cystic duct, and the bile duct is dis-sected down to the superior margin of the duodenum. Inferior traction on the distal bile duct opens the plane to make visible the anterior portion of the portal vein. The pancreatic neck is divided anterior to the portal vein (Fig. 33-73). The use of cau-tery is avoided in the area of the pancreatic duct. The pancreatic head and uncinate process then are dissected off of the right lateral aspect of the superior mesenteric vein, ligating the fragile branches draining the head and uncinate process into the portal vein (Fig. 33-74). The uncinate process is then dissected off of the posterior and lateral aspect of the superior mesenteric artery. This can be the most tedious portion of the operation, Figure 33-73. Division of the pancreatic neck. The pancreatic neck is separated from the anterior surface of the portal vein and then divided. If there is no tumor involvement, the neck of the pan-creas will separate from the vein easily. A large, blunt-tipped clamp is a safe instrument to use for this dissection. (Reproduced with per-mission from Bell RH, Rikkers LF, Mulholland M: Digestive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)Brunicardi_Ch33_p1429-p1516.indd 149201/03/19 6:46 PM 1493PANCREASCHAPTER 33Figure 33-74. Dissection of the pancreatic head and uncinate pro-cess. The pancreatic head and uncinate process are dissected off of the right lateral aspect of the superior mesenteric vein and portal vein by ligating the fragile venous branches. (Reproduced with per-mission from Bell RH, Rikkers LF, Mulholland M: Digestive Tract Surgery: A Text and Atlas. Philadelphia, PA: Lippincott Williams & Wilkins; 1996.)but thoroughly clearing all tissue from the mesenteric vessels helps avoid incomplete resection. The wound is irrigated and meticulous hemostasis is assured at this point because the view of the portal vein area and retroperitoneum is more difficult after the reconstruction phase is completed.The reconstruction involves anastomoses of the pancreas first, then the bile duct, and, finally, the duodenum or stomach. There are various techniques for the pancreatic anastomoses. After the pancreatic anastomosis is completed, the choledocho-jejunostomy is performed about 10 cm down the jejunal limb from the pancreatic anastomosis. This is usually performed in an end-to-side fashion with one layer of interrupted sutures. The duodenojejunostomy or gastrojejunostomy is performed another 10 to 15 cm downstream from the biliary anastomosis, using a two-layer technique.Pancreaticoduodenectomy With Vascular Resection.  Accurate staging of pancreatic cancer with a high-quality pre-operative CT scan is extremely important. Involvement of the superior mesenteric artery, the celiac axis, or hepatic artery indicate a T4/stage 3 tumor that is locally advanced and unre-sectable. However, involvement of the portal vein or superior mesenteric vein does not necessarily preclude resection as long as there is a patent superior mesenteric vein-portal vein conflu-ence. Reconstruction can often be accomplished with a primary anastomosis of the vein. When resection of more than 2 cm of vein is required, an interposition graft such as the internal jugu-lar vein can be used for a tension-free reconstruction.In a systematic review of 28 retrospective studies from high-volume pancreas centers, the morbidity, mortality, and survival outcome after undertaking extended pancreaticoduodenectomy with vascular resection for pancreatic cancer with venous involvement and/or limited arterial involvement was acceptable.331 Another more recent report from five teaching hospitals demonstrated that the Whipple procedure combined with vascular resection and reconstruction could achieve complete removal of tumors without significantly increasing the mortality rate, and the median survival time was higher than that of patients who underwent palliative treatment.332 However, contrary to the findings of analyses from expert pancreas centers, a retrospective cohort analysis using the National Surgical Quality Improvement Program data from 2005 to 2009 demonstrated increased 30-day postoperative morbidity and mortality in pancreaticoduodenectomy with vein resection when compared with pancreaticoduodenectomy alone.333 These data indicate that pancreaticoduodenectomy with vascular resection is only a reasonable option when it is performed after neoadjuvant therapy and at very-high-volume centers where the morbidity of the operation can be kept to a minimum.Minimally Invasive Pancreatectomy. Laparoscopic distal pancreatectomy has been proven to be safe and is appropriate for essentially all indications for pancreatectomy. This approach is associated with decreased blood loss and quicker recovery. Centrally located lesions near the splenoportal confluence must be approached laparoscopically with caution. Robotic technology may make dissection and control of major vessels in this area easier and perhaps safer. Interest in laparoscopic pancreaticoduodenectomy is increasing throughout the United States with some early adopters reporting excellent outcomes comparable to the open procedure.334 Early results indicate this technique is feasible, but considerable expertise is required in both open pancreatic resection as well as advanced laparoscopic techniques to achieve these outcomes. Whether the advantages seen in other areas of minimally invasive surgery apply to the Whipple procedure is an area of current investigation.Variations and Controversies. The preservation of the pylorus has several theoretical advantages, including preven-tion of reflux of pancreaticobiliary secretions into the stomach, decreased incidence of marginal ulceration, normal gastric acid secretion and hormone release, and improved gastric function. Patients with pylorus-preserving resections have appeared to regain weight better than historic controls in some studies. Return of gastric emptying in the immediate postoperative period may take longer after the pylorus-preserving operation, and it is controversial whether there is any significant improve-ment in long-term quality of life with pyloric preservation.335-336Techniques for the pancreaticojejunostomy include end-to-side or end-to-end and duct-to-mucosa sutures or invagination (Fig. 33-75). Pancreaticogastrostomy has also been investigated.Some surgeons use stents, glue to seal the anastomosis, or octreotide to decrease pancreatic secretions. No matter what com-bination of these techniques is used, the clinically significant pan-creatic leakage rate is always about 10%. Therefore, the choice of techniques depends more on the surgeon’s personal experience.Traditionally, most surgeons place drains around the pan-creatic and biliary anastomoses because disruption of the pan-creaticojejunostomy cannot be avoided in one out of 10 patients. Brunicardi_Ch33_p1429-p1516.indd 149301/03/19 6:46 PM 1494SPECIFIC CONSIDERATIONSPART IIThis complication can lead to the development of an upper abdominal abscess or can present as an external pancreatic fis-tula. Usually, a pure pancreatic leak is controlled by the drains and will eventually seal spontaneously. Combined pancreatic and biliary leaks are cause for concern because bile will activate the pancreatic enzymes. In its most virulent form, disruption leads to necrotizing retroperitoneal infection, which can erode major arteries and veins of the upper abdomen, including the exposed portal vein and its branches or the stump of the gastro-duodenal artery. Impending catastrophe is often preceded by a small herald bleed from the drain site. Depending on the clinical situation, such an event is an indication to perform an angio-gram or return the patient to the operating room to widely drain the pancreaticojejunostomy and to repair the involved blood vessel. Open packing may be necessary to control diffuse necro-sis and infection. Some studies have questioned the practice of routine drain placement after pancreatectomy with reliance on postoperative percutaneous drainage when leaks occur.337 How-ever, a randomized, controlled, multicenter trial showed that patients who develop a leak after pancreaticoduodenectomy are ABCDEFigure 33-75. Techniques for pancreaticojejunostomy. A to D. Duct-to-mucosa, end-to-side E. Intraoperative photographs of end-to-side pancreaticojejunostomy. F to J. End-to-end invagination. K to O. End-to-side invagination.Brunicardi_Ch33_p1429-p1516.indd 149401/03/19 6:46 PM 1495PANCREASCHAPTER 33FGHIJFigure 33-75. (Continued)at a substantially increased risk of mortality if a drain was not placed at the time of resection.337 In contrast, the outcome does not seem to be as dramatically affected by drain placement in the setting of distal pancreatectomy.338 In the absence of a fis-tula, drains should be removed early in the postoperative period, preferably by postoperative day 5.339Many patients with pancreatic cancer are malnourished preoperatively and suffer from gastroparesis in the immedi-ate postoperative period. Routine placement of a feeding jeju-nostomy tube and gastrostomy tube has become less common, and most surgeons use these tubes selectively. Gastrostomy tubes may decrease the length of stay in patients who might Brunicardi_Ch33_p1429-p1516.indd 149501/03/19 6:46 PM 1496SPECIFIC CONSIDERATIONSPART IIKLNOMFigure 33-75. (Continued)be predicted to have severe gastroparesis. Jejunostomy tubes are certainly not benign and can result in leaks and intestinal obstruction. However, parenteral nutrition is also associated with serious complications such as line sepsis, loss of gut muco-sal integrity, and hepatic dysfunction. Enteric tubes should be considered in patients at risk such as malnourished patients who have received neoadjuvant chemotherapy.Because of the high incidence of direct retroperitoneal invasion and regional lymph node metastasis at the time of surgery, trails of more extended resections including extension of the pancreatic resection to the middle body of the pancreas, segmental resection of the portal vein, if necessary, resection of retroperitoneal tissue along the right perinephric area, and lymphadenectomy to the region of the celiac plexus were exam-ined. In the hands of experienced surgeons, these techniques are associated with greater blood loss but no increase in mortality. However, improved survival has not been demonstrated. Total pancreatectomy has also been considered in the past. Although pancreatic leaks are eliminated, major morbidity from brittle diabetes and exocrine insufficiency outweigh any theoretical benefit.Pancreatic cancer can recur locally after pancreaticoduo-denectomy. Intraoperative radiotherapy (IORT) delivers radia-tion to the operative bed at the time of resection. Radiation to Brunicardi_Ch33_p1429-p1516.indd 149601/03/19 6:46 PM 1497PANCREASCHAPTER 33surrounding normal areas is minimized, but the radiation is delivered all in one setting, rather than in fractionated doses over time. Favorable results were recently reported among a series of patients with locally advanced unresectable or border-line-resectable PDAC who received intensive neoadjuvant treat-ment followed by exploratory laparotomy and IORT.340Complications of Pancreaticoduodenectomy. The operative mortality rate for pancreaticoduodenectomy has decreased to <5% in high-volume centers (where individual surgeons perform more than 15 cases per year), suggesting that patients in rural areas would benefit from referral to large urban centers.341-342 The most common causes of death are sepsis, hemorrhage, and cardiovascular events. Postoperative complications are unfortunately still very common and include delayed gastric emptying, pancreatic fistula, and hemorrhage.Delayed gastric emptying is common after pancreatico-duodenectomy and is treated conservatively as long as complete gastric outlet obstruction is ruled out by a contrast study. In the acute phase, intravenous erythromycin may help, but the prob-lem usually improves with time.Considerable attention has been focused on the preven-tion of pancreatic leak after pancreas resection. Modifications of the anastomotic technique (end-to-side or end-to-end, duct-to-mucosa, or invaginated), the use of jejunum or the stomach for drainage, the use of pancreatic duct stents, the use of octreotide, and various sealants have all been evaluated.Long-acting synthetic analogues of somatostatin have been evaluated as a pharmacologic therapy to reduce pancreatic secretion and the rate of pancreatic fistula after pancreatic resec-tion. Some European studies supported benefit particularly in selected higher risk patients, while previous North American tri-als concluded there was no benefit.343-349 A recent single-center, randomized trial with pasireotide (a newer analog) suggested potential benefit.350Many technical modifications to the classic pancreaticodu-odenectomy have been described. However, numerous technical variations to the pancreaticoenteric anastomosis have not clearly demonstrated an objective method to consistently decrease the rate of clinically significant postoperative pancreatic fistula, which in most series is about 10%. Yeo compared the incidence of pancreatic fistula in patients who had a pancreaticoduode-nectomy with reconstruction via a pancreaticogastrostomy or pancreaticojejunostomy.351 There was no significant difference between the two techniques in the incidence of pancreatic fis-tula. A recent meta-analysis summarized the results of 16 trials comparing pancreaticogastrostomy to pancreaticojejunostomy. All of the observational clinical studies reported superiority of pancreaticogastrostomy over pancreaticojejunostomy, most likely influenced by publication bias. In contrast, all random-ized prospective trials failed to show advantage of a particular technique, suggesting both techniques provide equally good results.352Other options to consider when performing the pancre-atic anastomosis are the duct-to-mucosa vs. the invagination techniques. Some surgeons choose the technique at the time of operation, depending on the size of the pancreatic duct and the texture of pancreas favoring invagination when the duct is small and the pancreatic texture is soft.353 Other surgeons use the same technique every time. The duct-to-mucosa anastomosis results in a low pancreatic fistula rate, particularly in patients with a large pancreatic duct and a fibrotic pancreas.354Use of a pancreatic duct stent across the anastomosis has been suggested as a means of preventing a pancreatic leak and as an aid in technical precision. Both internal stenting as well as external stenting have been practiced. A recent Cochrane analysis of eight randomized, controlled trials failed to iden-tify any convincing evidence of benefit with internal or external pancreatic duct stents.355 Some previous studies indicated that stents might be harmful. A recent multicenter randomized trial comparing external to internal pancreatic duct stents during pan-creaticoduodenectomy showed a lower rate of pancreatic fistula with internal stents, so this controversy is likely to continue.356Reconstruction with an isolated Roux-en-Y pancreatico-enteric anastomosis has been suggested as a method do decrease postoperative pancreatic leak.357-358 The logic behind this tech-nical modification is that the use of separate Roux-en-Y limbs for biliary and pancreatic secretions may protect the pancreatic anastomosis from activated pancreatic enzymes. However, data is limited, and this is not a common practice.Avoiding the pancreatic anastomosis altogether by ductal ligation or occlusion has also been evaluated as a potential technique to reduce the rate of postoperative pancreatic fistula.359-360 Ductal occlusion with neoprene or prolamine, which are nonresorbable glues, has been abandoned due to pancreatic atrophy and loss of exocrine function. Duct occlusion in pancreaticojejunostomy significantly increases the risk of endocrine insufficiency without a decrease in the postoperative complication rate. To avoid long-term loss of function, absorbable glues, such as fibrin glue, have been evaluated to limit the action of pancreatic enzymes until the anastomosis is healed. Fibrin glue has been used for both duct occlusion and has also been applied to the surface of the pancreatic stump and anastomotic site without clear improvement in pancreatic fistula rate. The effect of BioGlue applied to the anastomotic surface after the Whipple procedure and pancreatic stump after distal pancreatectomy was evaluated in a retrospective cohort study. There were no statistically significant differences in the incidence or severity grades of postoperative pancreatic fistulas.361 A randomized prospective trial of application of fibrin glue to the surface of the pancreaticojejunostomy in high-risk patients did not reduce the incidence of pancreatic fistula or total complications after pancreaticoduodenectomy.362If not combined with a biliary leak, pancreatic fistula, although serious, can usually be managed conservatively. In about 95% of cases, reoperation is not indicated, and prolonged drainage, using drains placed in the original operation or percu-taneously after resection, results in spontaneous closure of the fistula.363Hemorrhage can occur either intraoperatively or postop-eratively. Intraoperative hemorrhage typically occurs during the dissection of the portal vein. A major laceration of the portal vein can occur at a point in the operation at which the portal vein is not yet exposed. Temporary control of hemorrhage is gener-ally possible in this situation by compressing the portal vein and superior mesenteric vein against the tumor with the surgeon’s left hand behind the head of the pancreas. An experienced assis-tant is needed to divide the neck of the pancreas to the left of the portal vein and achieve proximal and distal control. Sometimes, the vein can be sutured closed with minimal narrowing. Other times, a segmental resection and interposition graft (internal jugular vein) may be needed.Postoperative hemorrhage can occur from inadequate liga-ture of any one of numerous blood vessels during the procedure. Brunicardi_Ch33_p1429-p1516.indd 149701/03/19 6:46 PM 1498SPECIFIC CONSIDERATIONSPART IIHemorrhage can also occur due to digestion of retroperitoneal blood vessels due to a combined biliary-pancreatic leak. Uncom-monly, a stress ulcer, or later, a marginal ulcer, can result in GI hemorrhage. Typically, a vagotomy is not performed when pan-creaticoduodenectomy is performed for pancreatic cancer, but patients are placed on proton pump inhibitors.Outcome and Value of Pancreaticoduodenectomy for Cancer. Survival figures indicate that perhaps few patients are cured indefinitely of pancreatic cancer with pancreaticoduode-nectomy. This has led to a nihilistic view toward patients with this disease which has further contributed to poor outcomes. Using the National Cancer Data Base (1995–2004), Bilimoria reported on 9559 patients with early stage potentially resect-able tumors (pretreatment clinical Stage I: T1N0M0 and T2N0M0).364 Multivariate models were employed to identify factors predicting failure to undergo surgery and assess the impact of pancreatectomy on survival. This study identified a striking underuse of pancreatectomy in the United States. Of clinical stage I patients, 71.4% (6823/9559) did not undergo surgery; 6.4% (616/9559) were excluded due to comorbidi-ties; 4.2% (403/9559) refused surgery; 9.1% (869/9559) were excluded due to age; and 38.2% (3644/9559) with potentially resectable cancers were not offered surgery. Patients were less likely to undergo surgery if they were older than 65 years, were black, were on Medicare or Medicaid, had pancreatic head lesions, earned lower annual incomes, or had less education. Patients were less likely to receive surgery at low-volume and community centers. Patients who were not offered surgery had worse survival than patients who underwent resection. Over-all survival from PDAC would significantly increase if more patients with stage I tumors were identified and offered surgery at high-volume centers (Fig. 33-76).Although pancreaticoduodenectomy may be performed with the hope of the rare cure in mind, the operation more importantly provides better palliation than any other treatment, and it is the only modality that offers any meaningful improve-ment in survival. If the procedure is performed without major complications, many months of palliation are usually achieved. However, it is the surgeon’s duty to make sure patients and their families have a realistic understanding of the true goals of pan-creaticoduodenectomy in the setting of pancreatic cancer.Adjuvant Chemotherapy and Radiation. Small studies in the 1980s suggested that adjuvant chemotherapy with 5-FU combined with radiation improves survival by about 9 months after pancreatic resection for pancreatic adenocarcinoma.365 Subsequent, noncontrolled studies have reinforced that concept; however, the data have been criticized due to the low number of patients and low dose of radiation therapy that was given. In addition, gemcitabine has replaced 5-FU as standard therapy in pancreatic cancer but is thought to be too toxic when given with radiotherapy without dose reduction. A recent large European multicenter trial concluded that there was no value to chemo-radiotherapy, although the study suggested the possibility that chemotherapy alone might have survival benefit.366 Random-ized trials have failed to resolve the debate regarding the role of adjuvant radiation therapy in resectable pancreas cancer. A reasonable consideration in a disease with high rates of distant metastases is to begin with adjuvant chemotherapy, followed by radiation therapy in patients who do not progress, particularly in patients where there may be increased concern about local recurrence such as in patients with close margins.Remarkable results in adjuvant therapy were reported by the Virginia Mason Clinic with combination 5-FU, cisplatinum, interferon-〈, and external beam radiation.367 Although the toxic-ity was high (42% hospitalized for GI toxicity), the promising results prompted larger confirmatory studies. Unfortunately, one such study was stopped due to toxicity, and this protocol has not been widely adopted. More recent results with FOLFIRINOX in the setting of metastatic disease have encouraged clinical tri-als using this regimen in the adjuvant setting, which are cur-rently underway (ClinicalTrials.gov identifier: NCT02172976). Nevertheless, pending further study, it is typical in the United States for patients with acceptable functional status to receive some form of adjuvant chemotherapy and sometimes chemora-diotherapy after surgery.Neoadjuvant Treatment. There are several potential advan-tages to the use of chemotherapy or chemoradiation before an attempt at surgical resection. For example, it avoids the risk that adjuvant treatment is delayed by complications of surgery. Neoadjuvant treatment also may decrease the tumor burden at operation, increasing the rate of resectability and killing some tumor cells before they can be spread intraoperatively. Another potential advantage is that it allows patients with occult meta-static disease to avoid the morbidity of pancreatic resection. As many as 20% of patients treated with neoadjuvant chemoradia-tion develop metastatic disease detected by restaging CT and do not go on to surgery. This approach may separate patients into a subset likely to benefit from resection and a subset in whom sur-gery would be unlikely to provide clinical benefit. Preoperative chemoradiation has been shown not to increase the periopera-tive morbidity or mortality of pancreaticoduodenectomy. It may even decrease the incidence of pancreatic fistula. Prospective randomized trials investigating this concept are ongoing but are difficult to complete due to the high number of patients who fail to complete or receive a full course of either therapy. Studies have shown that neoadjuvant therapy is associated with a lower rate of lymph node positivity and improved survival is achieved among the patients who do not develop disease progression dur-ing neoadjuvant therapy and go on to resection. Neoadjuvant therapy should be considered an acceptable alternative to sur-gery first followed by adjuvant therapy for resectable pancre-atic cancer. Patients should be encouraged to consider available 000.20.40.6Cause-specific survival0.81.0Performed, med. survival = 36 months (N = 724)Refused, med. survival = 7 months (N = 82)1020304050Months60708090Figure 33-76. Effect of surgery on survival in early stage pan-creas cancer. Survival comparison for cases (combined stages IA and IB) for which resection was recommended, and resection was either performed or refused. (Reproduced with permission from Chiari ST, Kelly K, Hollingsworth MA, et al. Early detection of sporadic pancreatic cancer: summative review, Pancreas. 2015 Jul;44(5):693-712.)Brunicardi_Ch33_p1429-p1516.indd 149801/03/19 6:46 PM 1499PANCREASCHAPTER 33clinical trials of neoadjuvant therapy for resectable pancreatic cancer.368 Unfortunately, a recent trial attempting to random-ize patients with resectable pancreatic cancer to neoadjuvant versus adjuvant therapy failed to demonstrate an advantage for the neoadjuvant approach. However, the study was inconclu-sive because it was stopped after 73 of a planned 254 patients due to slow accrual, with only 66 eligible for analysis. Other trials are ongoing. The NEOPA trial (ClinicalTrials.gov iden-tifier: NCT01900327) is a prospectively randomized phase 3 trial of patients receiving neoadjuvant chemoradiation followed by curative surgery vs. primary surgery followed by adjuvant therapy with a primary endpoint of 3-year overall survival.369Most pancreatic surgeons agree that neoadjuvant chemo-therapy, and perhaps chemoradiotherapy, should be offered to patients with locally advanced but resectable disease (vein involvement) and to patients with “borderline resectable dis-ease” (abutment of ≤180 degrees of the circumference of the SMA, celiac axis, or hepatic artery or if there is a short segment of vein occlusion, CT findings suspicious for metastatic disease, like 1 mm liver lesions too small to characterize or biopsy, and patients with multiple comorbidities or marginal performance status). This strategy acknowledges the fact that these patients are at high risk of early distant recurrence and/or R1 resection with early local recurrence. Neoadjuvant treatment helps select the right patients for surgery and may reduce the incidence of a margin positive resection.Postoperative Surveillance. Recurrence after successful resection usually manifests as hepatic metastases. Adjuvant che-motherapy with or without radiation is usually administered for 6 months. During this time period, patients are monitored with frequent physical examinations and laboratory tests, including CA19-9. CT scans are typically ordered every 3 months in the first 2 years after resection or when a rising CA19-9 or new symptoms suggest recurrence. Surgical therapy for recurrent disease is usually reserved only for select patients with lim-ited disease who remain reasonable operative candidates who develop symptomatic gastric outlet or bowel obstruction.Ampullary and Periampullary Cancer. Ampullary cancers need to be distinguished from periampullary cancers. The ampulla is the junction of the biliary and pancreatic ducts within the duodenum. Periampullary cancer includes tumors arising from the distal bile duct, duodenal mucosa, or pancreas just adjacent to the ampulla, and the ampulla can be overgrown by cancers that arise from these adjacent areas, making it impos-sible to determine the true site of origin. Clinically, the term periampullary cancer is, therefore, a nonspecific term used to refer to a variety of tumors arising at the intersection of these four sites. The term ampullary cancer is more specific and is reserved for tumors that arise at the ampulla. Based on their location, ampullary cancers are usually detected relatively early due to the appearance of jaundice and have a more favorable prognosis. The ampulla of Vater is lined by an epithelial layer that transitions from pancreatic and biliary ductal epithelium to duodenal mucosal epithelium. Ampullary adenocarcinomas can therefore have an intestinal and/or pancreaticobiliary his-tologic morphology, with the former having a better progno-sis. Patients with ampullary cancer have a 10-year survival of about 35%, which is a much better prognosis than patients with pancreatic adenocarcinoma. The difference in survival is not entirely explained by an earlier presentation and lower inci-dence of lymph node metastases. There are biologic, particularly molecular, differences between ampullary and pancreatic adenocarcinoma of the pancreas.370 Intestinal type ampullary cancers have a lower incidence of EGFr and mutant p53 over-expression, and fewer activating K-ras mutations. These tumors are more likely to have genetic changes similar to colon cancer such as microsatellite instability and adenomatous polyposis coli mutations.Management of Periampullary Adenomas. Benign tumors such as ampullary adenomas can also originate at the ampulla. The accuracy of endoscopic biopsy in distinguishing ampullary cancer from benign adenoma is poor, with false-negative rates from 25% to 56% even if sphincterotomy precedes the biopsy. However, benign villous adenomas of the ampullary region can be excised locally. This technique is applicable only for small tumors (approximately 2 cm or less) with no evidence of malig-nancy upon biopsy. EUS may help to accurately determine if there is invasion into the duodenal wall. In the absence of inva-sion, adenomas may be amenable to an endoscopic or trans-duodenal excision. A longitudinal duodenotomy is made and the tumor is excised with a 2to 3-mm margin of normal duo-denal mucosa. In some centers, small periampullary adenomas can also be removed endoscopically. A preoperative diagnosis of cancer is a contraindication to transduodenal excision, and pancreaticoduodenectomy should be performed. Likewise, if final pathologic examination of a locally excised tumor reveals invasive cancer, the patient should be returned to the operat-ing room for a pancreaticoduodenectomy. An important sub-set of patients are those with FAP who develop periampullary or duodenal adenomas. These lesions have a high incidence of harboring carcinoma and frequently recur unless the mucosa at risk is resected. A standard (not pylorus-sparing) Whipple is the procedure of choice in FAP patients with periampullary lesions.Cystic Neoplasms of the Pancreas. A cystic neoplasm needs to be considered when a patient presents with a fluid-containing pancreatic lesion. Asymptomatic cystic neoplasms of the pancreas may be more frequent than previously recognized and are being identified with increasing frequency as the use of abdominal CT scanning and MRI has increased. Pancreatic cysts are now thought to be present in about 9% of the popula-tion age 80 and older.371 When symptoms are clearly attributable to a pancreatic cyst, resection is indicated in patients who are fit candidates for surgery. However, management of asymp-tomatic pancreatic cysts is nuanced and can trigger significant anxiety for patients and their surgeons. Invasive surveillance and aggressive surgical intervention can cause harm, decrease quality of life, and increase costs. While the overall risk that an incidental pancreatic cyst is malignant is very low (about 1 in 10,000), the risks of surgery are very significant with a 2% to 5% mortality and 30% to 40% morbidity. However, some of these neoplasms slowly undergo malignant transformation and thus represent an opportunity for surgical cure, which is uncom-mon after transformation to invasive pancreatic adenocarci-noma. The dilemma for the surgeon is to identify the minority of cysts that pose a significant risk and provide individual patients with an accurate assessment of their unique risk-benefit ratio of resection vs. surveillance.Surveillance programs are of questionable value in patients who are not candidates for surgery due to age and or multiple comorbidities and limited life expectancy. Surgeons also need to clearly explain to the patient the risks and benefits of surveil-lance itself. MRI is the preferred surveillance imaging modality Brunicardi_Ch33_p1429-p1516.indd 149901/03/19 6:46 PM 1500SPECIFIC CONSIDERATIONSPART IIover computed tomography because MRI does not expose the patient to radiation and better demonstrates the structural rela-tionship between the pancreatic duct and associated cyst. Also, MRI is less invasive than EUS. EUS is therefore reserved for further evaluation of higher risk cysts. Another problem to con-front is when to stop surveillance in a cyst that has been stable during observation. Some clinicians stop following after 5 years but data is lacking to guide this decision. In addition, patients who have undergone resection of a pancreatic cystic neoplasm with high grade dysplasia may warrant continued surveillance after surgery particularly when there is a possible field effect such as in IPMN or concern that all of the disease has not been resected. Individualized decision-making and multidisciplinary input is ideal.372Pseudocysts. The most common cystic lesion of the pancreas is the pseudocyst, which, of course, has no epithelial lining and is a nonneoplastic complication of pancreatitis or pancreatic duct injury. As discussed in “Complications of Chronic Pancreatitis,” the diagnosis is usually straightforward from the clinical history. Although not usually necessary, analysis of pseudocyst fluid would reveal a high amylase content. The danger comes in mistaking a cystic pancreatic neoplasm for a pseudocyst and incorrectly draining a cystic neoplasm into the GI tract rather than resecting the neoplasm. For this reason, biopsy of the pseudocyst wall is a requirement in the management of pancreatic pseudocysts.Cystadenoma. Serous cystadenomas are essentially considered benign tumors without malignant potential. Serous cystadenocarcinoma has been reported very rarely (<1%). Therefore, malignant potential should not be used as an argument for surgical resection, and the majority of these lesions can be safely observed in the absence of symptoms due to mass effect or rapid growth. The average rate of growth is about 0.5 cm per year. About 50% of cystadenomas are asymptomatic and detected as an incidental finding. Most symptomatic patients have mild upper abdominal pain, epigastric fullness, or moderate weight loss. Occasionally, cystadenomas can grow to a size capable of producing jaundice or GI obstruction due to mass effect (Fig. 33-77). For symptomatic patients with serous cystadenoma, surgical resection is indicated. For lesions in the tail, splenectomy is not necessary, given the benign nature of the tumor. In appropriate candidates, a laparoscopic approach to distal pancreatectomy with or without splenic preservation can be considered. These cysts are frequently found in older women in which pancreatic resection for a benign neoplasm should be avoided in the absence of significant symptoms. All regions of the pancreas are affected, with half in the head/uncinate process, and half in the neck, body, or tail of the pancreas. They have a spongy appearance, and multiple small cysts (microcystic) are more common than larger cysts (macrocystic or oligocystic). These lesions contain thin serous fluid that does not stain positive for mucin and is low in CEA (<200 ng/mL). Typical imaging characteristics include a well-circumscribed cystic mass, small septations, fluid close to water density, and sometimes, a central scar with calcification. If a conservative management is adopted, it is important to be sure of the diagnosis. EUS-FNA should yield nonviscous fluid with low CEA and amylase levels, and if cells are obtained, which is rare, they are cuboidal and have a clear cytoplasm.Mucinous Cystadenoma and Cystadenocarcinoma. Muci-nous cystic neoplasms (MCNs) encompass a spectrum ranging from benign but potentially malignant to carcinoma with a very aggressive behavior (Table 33-23). There is often heterogene-ity within the lesions with benign and malignant-appearing regions, making it impossible to exclude malignancy with biopsy. MCNs are commonly seen in perimenopausal women, and about two-thirds are located in the body or tail of the pan-creas. Like cystadenomas, most MCNs are now incidental find-ings identified during imaging performed for other reasons. When symptoms are present, they are usually nonspecific and include upper abdominal discomfort or pain, early satiety, and weight loss. On imaging studies, the cysts have thick walls and do not communicate with the main pancreatic duct (Fig. 33-78). There may be nodules or calcifications within the wall of the cyst. The cysts are lined by tall columnar epithelium that fills the cyst with viscous mucin. The submucosal layer consists of a highly cellular stroma of spindle cells with elongated nuclei similar to the “ovarian stroma,” which is a key pathologic feature distinguishing these lesions. Elevated CEA levels in the fluid (≥200 ng/mL) are consistent with mucinous lesions and may suggest malignant transformation.373 Solid areas may con-tain atypical cells or invasive cancer, and extensive sampling of the specimen is necessary to accurately predict prognosis. Figure 33-77. Mucinous cystic neoplasm in tail of pancreas.Table 33-23World Health Organization classification of primary tumors of the exocrine pancreas A. Benign 1. Serous cystadenoma (16%) 2. Mucinous cystadenoma (45%) 3. Intraductal papillary-mucinous adenoma (32%) 4. Mature cystic teratoma B. Borderline 1. Mucinous cystic tumor with moderate dysplasia 2. Intraductal papillary mucinous tumor with moderate dysplasia 3. Solid pseudopapillary tumor C. Malignant 1. Ductal adenocarcinoma 2. Serous/mucinous cystadenocarcinoma (29%) 3. Intraductal mucinous papillary tumorBrunicardi_Ch33_p1429-p1516.indd 150001/03/19 6:46 PM 1501PANCREASCHAPTER 33NoYes<1 cm1–2 cm2–3 cm>3 cmNoNoa. Pancreatitis may be an indication for surgery for relief of symptoms.b. Differential diagnosis includes mucin. Mucin can move with change in patient position, may be dislodged oncyst lavage and does not have Doppler ’ow. Features of true tumor nodule include lack of mobility, presence ofDoppler ’ow and FNA of nodule showing tumor tissuec. Presence of any one of thickened walls, intraductal mucin or mural nodules is suggestive of main ductinvolvement. In their absence main duct involvement is inconclusive.d. Studies from Japan suggest that on follow-up of subjects with suspected BD-IPMN there is increased incidenceof pancreatic ductal adenocarcinoma unrelated to malignant transformation of the BD-IPMN(s) being followed.However, it is unclear if imaging surveillance can detect early ductal adenocarcinoma, and, if so, at what intervalsurveillance imaging should be performed.Are any of the following high-risk stigmata of malignancy present?i) obstructive jaundice in a patient with cystic lesion of the head of the pancreas,ii) enhancing solid component within cyst, iii) main pancreatic duct ‰10 mm in sizeAre any of the following worrisome features present?Clinical: PancreatitisaImaging: i) cyst ‰3 cm, ii) thickened/enhancing cyst walls, iii) main duct size 5–9 mm, iii) non-enhancingmural nodule iv) abrupt change in caliber of pancreatic duct with distal pancreatic atrophy.What is the size of largest cyst?InconclusiveIf yes, perform endoscopic ultrasoundConsidersurgery,if clinicallyappropriateAre any of these features present?i) Deÿnite mural nodule(s)bii) Main duct features suspicious for involvementciii) Cytology: suspicious or positive for malignancyCT/MRIin 2–3 yearsdCT/MRIyearly × 2 years,then lengthenintervalif no changedEUS in 3–6 months, thenlengthen interval alternating MRIwith EUS as appropriate.dConsider surgery in young,ÿt patients with need forprolonged surveillanceClose surveillance alternatingMRI with EUS every 3–6 months.Strongly consider surgery in young,ÿt patientsYesFigure 33-78. Algorithm for management of pancreatic cystic neoplasms. CEA = carcinoembryonic antigen; CT = computed tomography; ERCP = endoscopic retrograde cholangiopancreatography; EUS = endoscopic ultrasound; FNA = fine-needle aspiration; Hx = history; IPMN = intraductal papillary mucinous neoplasm of the pancreas; MCN = mucinous cystic neoplasm; MRCP = magnetic resonance cholangiopancreatography. (Reproduced with permission from Tanaka M, Adsay V, Chari S, et al. International consensus guidelines 2012 for the management of IPMN and MCN of the pancreas, Pancreatology. 2012 May-Jun;12(3):183-197.)Resection is the treatment of choice for most mucin-producing cystic tumors. Malignancy cannot be ruled out without removal and extensive sampling of the entire tumor. Malignancy has been reported in 6% to 36% of MCNs. Current thinking is that all of these tumors will eventually evolve into cancer if left untreated. However, for individual patients, the surgeon is often faced with a difficult decision. The risk of pancreas surgery in an older patient with multiple comorbidities and a relatively short life expectancy regardless of their pancreatic cyst is frequently weighed against the potential future risk that the cyst, particularly a small cyst, will transform into an incurable invasive cancer.The utility of detailed DNA analysis of pancreatic cyst fluid to diagnose mucinous and malignant cysts has been evalu-ated in the PANDA study.374 The study concluded that cyst fluid K-ras mutation was helpful in the diagnosis of mucinous cysts with a 96% specificity. Components of DNA analysis detect-ing malignant cysts included allelic loss amplitude over 82% and high DNA amount. The criteria of high amplitude K-ras mutation followed by allelic loss showed maximum specificity (96%) for malignancy. However, this test lacks sensitivity. In clinical practice, the surgeon must take all of these complemen-tary factors into consideration when determining the malignant potential of a pancreatic cystic neoplasm.Because most MCNs are located in the body and tail of the pancreas, distal pancreatectomy is the most common treatment. For small lesions, it may be appropriate to preserve the spleen, but splenectomy ensures removal of the lymph node basin that can potentially be involved. It is very important not to rupture the cyst during resection, and the tumor should be removed intact, not morselized. Therefore, a laparoscopic approach may not be appropriate for larger lesions. Completely resected MCNs without atypia are usually cured especially if small (<3 cm). Even patients with moderate dysplasia or carcinoma in situ are usually cured by complete resection. Noninvasive MCNs require no surveillance after resection. For MCNs with an associated invasive carcinoma, prognosis depends on the extent of the invasive component, tumor stage, and resectability. The 2-year survival rate and 5-year survival rate of patients with Brunicardi_Ch33_p1429-p1516.indd 150101/03/19 6:46 PM 1502SPECIFIC CONSIDERATIONSPART IIresected MCN with an associated invasive carcinoma are about 67% and 50%, respectively.375Intraductal Papillary Mucinous Neoplasm. Intraductal papillary mucinous neoplasms (IPMNs) usually occur within the head of the pancreas and arise within the pancreatic ducts. The ductal epithelium forms a papillary projection into the duct, and mucin production causes intraluminal cystic dilation of the pancreatic ducts (Fig. 33-79). Imaging studies demonstrate diffuse dilation of the pancreatic duct, and the pancreatic parenchyma is often atrophic due to chronic duct obstruction. However, classic features of chronic pancreatitis, such as calcification and a beaded appearance of the duct, are not present. At ERCP, mucin can be seen extruding from the ampulla of Vater, a so-called fish-eye lesion that is virtually diagnostic of IPMN (Fig. 33-80). Initial reports suggested a male predominance, but more recent series indicate an equal distribution. Patients are usually in their seventh to eighth decade of life and present with abdominal pain or recurrent pancreatitis, thought to be caused by obstruction of the pancreatic duct by thick mucin. Some patients 9Figure 33-79. Computed tomography appearance of massive mul-tiseptated serous cystadenoma in head of pancreas with central stel-late scar (left) and resected specimen (right).Figure 33-80. Intraductal papillary mucinous neoplasm histology. Papillary projections of ductal epithelium resemble villous morphology and contain mucin-filled vesicles. (Reproduced with permission from Asiyanbola B, Andersen DK. IPMN. Editorial Update. accesssurgery.com McGraw-Hill Education; 2008.)(5–10%) have steatorrhea, diabetes, and weight loss secondary to pancreatic insufficiency.Some IPMNs primarily involve the main pancreatic duct, while others involve the branch ducts. The mean fre-quency of malignancy in main duct IPMN (MD-IPMN) is 62% (Fig. 33-81). Considering this high incidence of malignant lesions and the low 5-year survival rates (31–54%), interna-tional consensus guidelines recommend resection for all surgi-cally fit patients with MD-IPMN.372 If the margin is positive for high-grade dysplasia, additional resection should be attempted to obtain at least moderate-grade dysplasia at the surgical margin.The surgical management of IPMNs is complicated by the fact that the lesion itself is small and preoperative imaging stud-ies show a dilated pancreatic duct but not necessarily the mass. Mucus can dilate the duct proximal and distal to the lesion. Fur-thermore, these lesions can spread microscopically along the duct, and there can be skip areas of normal duct between the diseased portions. Therefore, thorough preoperative imaging including EUS, MRCP, or ERCP, and sometimes pancreatic ductoscopy, which can also be repeated intraoperatively, is use-ful (see Fig. 33-80). The surgeon needs to be prepared to extend the resection, if necessary, based on intraoperative findings and frozen section of the margin. Extending the resection to the point of total pancreatectomy is controversial due to the mor-bidity of this operation. Like MCNs, the IPMNs require careful histologic examination of the entire specimen for an invasive cancer (Fig. 33-82).Survival of patients with IPMN, even when malignant and invasive, can be quite good. As with MCN, patients with bor-derline tumors or carcinoma in situ are usually cured. For this reason, if recurrence occurs in the remaining pancreas, further resection is warranted because several series have shown that some of these cases are salvageable. Patients with IPMN are also at risk for other malignancies and should undergo colonos-copy and close surveillance.Branch-duct type IPMNs (BD-IPMN) are often found in the uncinate process, are sometimes asymptomatic, and are less frequently associated with malignant transformation (6–46%). Asymptomatic, small suspected BD-IPMNs are frequently Brunicardi_Ch33_p1429-p1516.indd 150201/03/19 6:47 PM 1503PANCREASCHAPTER 33ABCFigure 33-81. Intraductal papillary mucinous neoplasm (IPMN). A. Examples of “fish-eye deformity” of IPMN. Mucin is seen extruding from the ampulla. B. Mucin coming from pancreatic duct when neck of pancreas is transected during Whipple procedure (left). Intraoperative pancreatic ductoscopy to assess the pancreatic tail (right). C. Views of pancreatic duct during ductoscopy; normal (left) and IPMN (right).Brunicardi_Ch33_p1429-p1516.indd 150301/03/19 6:47 PM 1504SPECIFIC CONSIDERATIONSPART IIobserved with serial imaging. High-risk features such as mural nodules, a dilated main duct, positive cytology or cyst fluid CEA >200 need to be ruled out. In the absence of these fea-tures, continued observation with serial imaging is appropriate, especially in patients who are not ideal operative candidates. The mean frequency of invasive cancer in resected BD-IPMN is 18%. BD-IPMN mostly occurs in elderly patients, and the annual malignancy rate is only 2% to 3%. These factors support conservative management with follow-up in patients who do not have any symptoms or risk factors predicting malignancy such as mural nodule, rapidly increasing cyst size, and high-grade atypia in cytology. There is insufficient data to support immediate resection for all BD-IPMNs <3 cm without “high-risk stigmata” and “worrisome features.” Branch-duct IPMNs ≥3 cm should be resected.372Four histologic subtypes of IPMNs have been character-ized: gastric, intestinal, pancreatobiliary, and oncocytic. Most of BD-IPMNs are composed of gastric-type epithelium. However, intestinal type is more common in MD-IPMN. In a recent report, the four subtypes of IPMNs were associated with significant dif-ferences in survival.376 Patients with gastric-type IPMN had the best prognosis, whereas those with intestinal and pancreatobili-ary type had a bad prognosis.Workup of Asymptomatic Pancreatic Cystic NeoplasmsIncidentally discovered asymptomatic pancreatic cystic neo-plasms are evaluated by MRI with MRCP to check for “high-risk stigmata or worrisome features.” An enhancing solid component or main pancreatic duct (MPD) dilation ≥10 mm are considered “high-risk stigmata.” Cysts ≥3 cm, thickened enhancing cyst walls, nonenhancing mural nodules, MPD size of 5 to 9 mm, abrupt change in the MPD caliber with distal pancreatic atrophy, and lymphadenopathy are considered “worrisome features.” All cysts with high risk stigmata are resected. All cysts with wor-risome features and cysts > 3 cm without worrisome features are further evaluated with EUS. If EUS shows a definite mural nodule, main duct features suspicious for involvement or the cytology is positive or suspicious for malignancy, then resection is recommended. In the absence of worrisome features, no fur-ther initial work-up is recommended, but surveillance is still required.The interval between surveillance imaging is based on the size of the cyst with a lengthening of the interval once sta-bility is established. Patients with noninvasive MCNs require no surveillance after resection, but patients with IPMNs need surveillance after resection. In the absence of residual lesions, repeat MRI at 2 and 5 years may be reasonable. If there is low or moderate-grade dysplasia at the margin, MRI every 6 months is recommended.Resection is indicated in all surgically fit patients with MD-IPMN, and additional resection is indicated if there is high-grade dysplasia at the margin. Resection is also indicated in all surgically fit patients with MCN. BD-IPMN <3 cm without wor-risome features or high-risk stigmata can undergo surveillance.When patients are deemed unacceptable for resection due to comorbidities, ablation of the cyst can be considered. How-ever, at this time, cyst ablation is considered experimental and should be done as part of a clinical trial. Gastroenterologists have limited experience with injection of a cytotoxic agent into the cyst in an attempt to ablate the cyst epithelium. Ethanol has been used and more recently this has been combined with paclitaxel. The combination of ethanol and paclitaxel injection resulted in elimination of the cysts, as determined by CT scan-ning, in 29 out of 47 (62%) of patients in a median follow-up period of 21.7 months.377Recently, the American Gastroenterological Association (AGA) published guidelines for asymptomatic mucinous cysts (http://www.gastro.org/guidelines/pancreatic-cysts) that are different from all previously published guidelines in the following areas: 2-year interval for cyst of any size undergoing surveillance, stopping surveillance after 5 years if no change, surgery only if more than one concerning feature on MRI confirmed on EUS and only in centers with high volumes of pancreatic surgery, and no surveillance after surgery if no invasive cancer or dysplasia. Although based on extensive literature review and synthesis, these recommendations have resulted in significant controversy because, in an effort to reduce the costs of health care delivery and perhaps decrease inadvertent harm to patients, they advocate less frequent follow-up and a higher threshold before offering EUS and/or surgery.Solid-Pseudopapillary Tumor. Solid-pseudopapillary tumors are rare and typically occur in young women. Previous names for this entity include, solid and cystic, solid and papillary, cystic and papillary, and papillary-cystic tumor. They are typically well circumscribed on CT (Fig. 33-83). The cysts are not true epithelial-lined cysts but rather represent a necrotic/degenerative process. Histology may be similar to neuroendocrine tumors, but they do not stain positive for neuroendocrine markers such as chromogranin. Most are cured by resection, but liver and peritoneal metastases have been reported.Other Cystic Neoplasms. Rarely, typical ductal adenocarci-noma of the pancreas may undergo cystic degeneration due to central necrosis. Occasionally, this will create difficulty in the proper preoperative diagnosis and should be kept in mind when deciding to conservatively follow a cystic pancreatic neoplasm. It is more common, 5% to 10%, for neuroendocrine tumors of the pancreas to contain cysts. These cysts are filled with sero-sanguineous fluid rather than necrotic debris. Lymphoepithelial Figure 33-82. Operative specimen of pancreas with multifocal intraductal papillary mucinous neoplasms (black arrow) and a focus of invasive adenocarcinoma (white arrow). (Reproduced with permission from Asiyanbola B, Andersen DK. IPMN. Editorial Update. accesssurgery.com McGraw-Hill Education; 2008.)Brunicardi_Ch33_p1429-p1516.indd 150401/03/19 6:47 PM 1505PANCREASCHAPTER 33Figure 33-83. Abdominal computed tomographic scan of a 25-year-old woman demonstrating a well-circumscribed cystic lesion with septation in body/tail of pancreas. At surgery, the tumor was adherent to the splenic artery. Pathologic diagnosis was solid-pseudopapillary carcinoma.cysts of the pancreas usually occur in men in their fifth to sixth decade. These benign lesions may be unilocular or multilocular and vary widely in size. The contents of the cyst are also vari-able and may be thin serous fluid or cheesy/caseous material if there is increased keratin formation. A substantial number of patients with von Hippel-Lindau syndrome develop pancreatic cysts that resemble serous cystadenomas. There may be mul-tiple lesions scattered throughout the pancreas. Patients with polycystic kidney and hepatic disease may also develop benign pancreatic cysts (cystadenomas). With all of these rare cystic neoplasms, careful clinical history, high-quality pancreatic imaging, and sampling of the cyst fluid for analysis will guide proper treatment.Pancreatic Lymphoma. Lymphoma can affect the pancreas. Primary involvement of the pancreas with no disease outside the pancreas also occurs. The clinical presentation often is similar to pancreatic adenocarcinoma, with vague abdominal pain and weight loss. Identification of a large mass often involving the head and body of the pancreas should raise suspicion. Percuta-neous or EUS-guided biopsy will confirm the diagnosis in most cases. If the diagnosis cannot be confirmed preoperatively, lapa-roscopic exploration and biopsy are indicated.378 There is no role for resection in the management of pancreatic lymphoma. Endoscopic stenting to relieve jaundice followed by chemo-therapy is the standard treatment, and long-term remission is often achieved.REFERENCESEntries highlighted in bright blue are key references. 1. Silen W. Surgical anatomy of the pancreas. Surg Clin North Am. 1964;44:1253. 2. Havel PJ, Taborsky GJ, Jr. The contribution of the autonomic nervous system to changes of glucagon and insulin secretion during hypoglycemic stress. Endocr Rev. 1989;10:332-350. 3. Davenport HW. Pancreatic secretion. In: Davenport HN, ed. Physiology of the Digestive Tract. 5th ed. Chicago: Year Book Medical Publishers; 1982:143. 4. Valenzuela JE, Weiner K, Saad C. Cholinergic stimulation of human pancreatic secretion. Dig Dis Sci. 1986;31:615-619. 5. Konturek SJ, Becker HD, Thompson JC. Effect of vagotomy on hormones stimulating pancreatic secretion. Arch Surg. 1974;108:704-708. 6. Ebert R, Creutzfeldt W. Gastrointestinal peptides and insulin secretion. Diabetes Metab Rev. 1987;3:1-26. 7. Leahy JL, Bonner-Weir S, Weir GC. Abnormal glucose regulation of insulin secretion in models of reduced B-cell mass. Diabetes. 1984; 33:667-673. 8. Brunicardi FC, Sun YS, Druck P, et al. Splanchnic neural regulation of insulin and glucagon secretion in the isolated perfused human pancreas. Am J Surg. 1987;153:34-40. 9. Yamada Y, Post SR, Wang K, et al. Cloning and functional characterization of a family of human and mouse somatostatin receptors expressed in brain, gastrointestinal tract, and kidney. Proc Natl Acad Sci U S A. 1992;89:251-255. 10. Voss M, Pappas T. Pancreatic fistula. Curr Treat Options Gastroenterol. 2002;5:345-353. 11. Floyd JC, Jr, Fajans SS, Pek S. Regulation in healthy subjects of the secretion of human pancreatic polypeptide, a newly recognized pancreatic islet polypeptide. Trans Assoc Am Physicians. 1976;89:146-158. 12. Adrian TE, Bloom SR, Besterman HS, et al. Mechanism of pancreatic polypeptide release in man. Lancet. 1977;1:161-163.Brunicardi_Ch33_p1429-p1516.indd 150501/03/19 6:47 PM 1506SPECIFIC CONSIDERATIONSPART II 13. Kono T, Wang XP, Fisher WE, Andersen DK, Brunicardi FC. Pancreatic Polypeptide (PP). In: L Martini, ed. Encyclopedia of Endocrine Diseases. Volume 3. Philadelphia: Elsevier; 2004:488-496.          14. Andersen DK. Mechanisms and emerging treatments of the metabolic complications of chronic pancreatitis. Pancreas. 2007;35:1-5. 15. Wierup N, Svensson H, Mulder H, Sundler F. The ghrelin cell: anovel developmentally regulated islet cell in the human pancreas. Regul Pept. 2002;107:63-69. 16. Prado CL, Pugh-Bernard AE, Elghazi L, Sosa-Pineda B, Sussel L. Ghrelin cells replace insulin-producing beta cells in two mouse models of pancreas development. Proc Natl Acad Sci U S A. 2004;101:2924-2429. 17. Sun Y, Asnicar M, Saha PK, Chan L, Smith RG. Ablation of ghrelin improves the diabetic but not obese phenotype of ob/ob mice. Cell Metab. 2006;3:379-386. 18. Westermark P, Wilander E, Westermark GT, et al. Islet amyloid polypeptide-like-immunoreactivity in the islet B-cells of type 2 (non-insulin-dependent) diabetic and non-diabetic individuals. Diabetologia. 1987;30:887-892. 19. Tatemoto K, Efendic S, Mutt V, Makk G, Feistner GJ, Barchas JD. Pancreastatin, a novel pancreatic peptide that inhibits insulin secretion. Nature. 1986;324:476-478. 20. Efendic S, Tatemoto K, Mutt V, Quan C, Chang D, Ostenson CG. Pancreastatin and islet hormone release. Proc Natl Acad Sci U S A. 1987:84:7257-7260. 21. Funakoshi A, Miyasaka K, Nakamura R, Kitani K, Tatemoto K. Inhibitory effect of pancreastatin on pancreatic exocrine secretion in the conscious rat. Reg Peptides. 1989;25: 157-166. 22. Bottcher G, Sjoberg J, Ekman R, et al. PYY in the mammalian pancreas: Immunocytochemical localization and immunochemical characterization. Regul Pept. 1993; 43:115-130. 23. Gorelick FS, Jamieson JD. Structure-function relationship of the pancreas. In: Johnson LR, ed. Physiology of the Gastrointestinal Tract. New York: Raven Press; 1981:773. 24. Kennedy FP. Pathophysiology of pancreatic polypeptide secretion in human diabetes mellitus. Diabetes Nutr Metab. 1990;2:155. 25. Petrov MS, Shanbhag S, Chakraborty M, Phillips AR, Windsor JA. Organ failure and infection of pancreatic necrosis as determinants of mortality in patients with acute pancreatitis. Gastroenterology. 2010;139:813-820. 26. Peery AF, Dellon ES, Lund J, et al. Burden of gastrointestinal disease in the United States: 2012 update. Gastroenterology. 2012;143(5):1179-1187. 27. Banks PA. Epidemiology, natural history, and predictors of disease outcome in acute and chronic pancreatitis. Gastrointesi Endosc. 2002;56(6 suppl):S226-S230. 28. Akhtar AJ, Shaheen M. Extrapancreatic manifestations of acute pancreatitis in African-American and Hispanic patients. Pancreas. 2004;29(4):291-297. 29. Lowenfels AB, Maisonneuve P. Acute pancreatitis: is smoking a risk factor for acute pancreatitis. Nat Rev Gastroenterol Hepatol. 2011;8(11):603-604. 30. Acosta JM, Ledesma CL. Gallstone migration as a cause of acute pancreatitis. N Engl J Med. 1974;290(9):484-487. 31. Lee SP, Nicholls JF, Park HZ. Biliary sludge as a cause of acute pancreatitis. N Engl J Med. 1992;326(9):589-593. 32. Lankisch PG, Apte M, Banks PA. Acute pancreatitis. Lancet. 2015;386(9988):85-96. 33. Elmunzer BJ, Scheiman JM, Lehman GA, et al. A randomized trial of rectal indomethacin to prevent post-ERCP pancreatitis. N Engl J Med. 2012; 66:1414-1422. 34. Akbar A, Abu Dayyeh BK, Baron TH, Wang Z, Altayar O, Murad MH. Rectal non-steroidal anti-inflammatory drugs are superior to pancreatic duct stentsin preventing pancreatitis after endoscopic retrograde cholangiopancreatography: a network meta-analysis. Clin Gastroenterol Hepatol. 2013;13: 778-783. 35. Whitcomb DC. Genetics of alcoholic and nonalcoholic pancreatitis. Curr Opin Gastroenterol. 2012;28(5):501-506. 36. Saluja A, Steer M. Pathophysiology of pancreatitis. Role of cytokines and other mediators of inflammation. Digestion. 1999;60:27-33. 37. Hofbauer B, Saluja AK, Lerch MM, et al. Intra-acinar cell activation of trypsinogen during caerulein-induced pancreatitis in rats. Am J Physiol. 1998;275(2 pt 1):G352-G362. 38. Saluja AK, Lerch MM, Phillips PA, Dudeja V. Why does pancreatic overstimulation cause pancreatitis? Annu Rev Physiol. 2007;69:249-269. 39. Dawra R, Sah RP, Dudeja V, et al. Intra-acinar trypsinogen activation mediates early stages of pancreatic injury but not inflammation in mice with acute pancreatitis. Gastroenterol. 2011;141(6):2210-2217 e2212. 40. Gaiser S, Daniluk J, Liu Y, et al. Intracellular activation of trypsinogen in transgenic mice induces acute but not chronic pancreatitis. Gut. 2011;60(10):1379-1388. 41. Whitcomb DC, Gorry MC, Preston RA, et al. Hereditary pancreatitis is caused by a mutation in the cationic trypsinogen gene. Nat Genet. 1996;14(2):141-145. 42. Kloppel G, Dreyer T, Willemer S, et al. Human acute pancreatitis: its pathogenesis in the light of immunocytochemical and ultrastructural findings in acinar cells. Virchows Arch A Pathol Anat Histopathol. 1986;409(6):791-803. 43. Saluja A, Saluja M, Villa A, et al. Pancreatic duct obstruction in rabbits causes digestive zymogen and lysosomal enzyme colocalization. J Clin Invest. 1989;84(4):1260-1266. 44. Saluja AK, Saluja M, Printz H, Zavertnik A, Sengupta A, Steer ML. Experimental pancreatitis is mediated by low-affinity cholecystokinin receptors that inhibit digestive enzyme secretion. Proc Natl Acad Sci. 1989;86(22):8968-8971. 45. Saluja A, Hashimoto S, Saluja M, et al. Subcellular redistribution of lysosomal enzymes during caerulein-induced pancreatitis. Am J Physiol. 1987;253(4 pt 1):G508-G516. 46. Van Acker GJ, Saluja AK, Bhagat L, et al. Cathepsin B inhibition prevents trypsinogen activation and reduces pancreatitis severity. Am J Physiol Gastrointest Liver Physiol. 2002;283(3):G794-G800. 47. Halangk W, Lerch MM, Brandt-Nedelev B, et al. Role of cathepsin B in intracellular trypsinogen activation and the onset of acute pancreatitis. J Clin Invest. 2000;106(6):773-781. 48. Saluja AK, Bhagat L, Lee HS, et al. Secretagogue-induced digestive enzyme activation and cell injury in rat pancreatic acini. Am J Physiol. 1999;276(4 pt 1):G835-G842. 49. Fluhr G, Mayerle J, Weber E, et al. Pre-study protocol Mag-PEP: a multicentre randomized controlled trial of magnesium sulphate in the prevention of post-ERCP pancreatitis. BMC Gastroenterol. 2013;13(1):11. 50. Talukdar R, Sareen A, Zhu H, et al. Release of cathepsin B in cytosol causes cell death in acute pancreatitis. Gastroenterology. 2016;151(4):747-758. 51. Banks PA, Bollen TL, Dervenis C, et al. Classification of acute pancreatitis—2012: revision of the Atlanta classification and definitions by international consensus. Gut. 2013;62(1): 102-111. 52. Windsor JA, Petrov MS. Acute pancreatitis reclassified. Commentary. Gut. 2013;62(1):4-5. 53. Hietaranta AJ, Singh VP, Bhagat L, et al. Water immersion stress prevents caerulein-induced pancreatic acinar cell nf-kappa b activation by attenuating caerulein-induced intracellular Ca2+ changes. J Biol Chem. 2001;276(22):18742-18747. 54. Hofbauer B, Saluja AK, Bhatia M, et al. Effect of recombinant platelet-activating factor acetylhydrolase on two models Brunicardi_Ch33_p1429-p1516.indd 150601/03/19 6:47 PM 1507PANCREASCHAPTER 33of experimental acute pancreatitis. Gastroenterology. 1998;115:1238-1247. 55. Korhonen JT, Dudeja V, Dawra R, Kubes P, Saluja A. Neutrophil extracellular traps provide a grip on the enigmatic pathogenesis of acute pancreatitis. Gastroenterology. 2015;149(7):1682-1685. 56. Merza M, Hartman H, Rahman M, et al. Neutrophil extracellular traps induce trypsin activation, inflammation, and tissue damage in mice with severe acute pancreatitis. Gastroenterology. 2015;149(7):1920-1931. 57. Abu-Zidan FM, Windsor JA. Lexipafant and acute pancreatitis: a critical appraisal of the clinical trials. European Journal of Surgery. 2002;168:215-219. 58. George J, Dixit A, Sareen A, et al. Therapeutic ADAM 10 and 17 inhibition reduces local and systemic inflammation in acute pancreatitis. Pancreas. 2016;45(10):1506-1507. 59. Dixit A, George J, Ryu Y, Cheema H, Dudeja V, Dawra R, Saluja AK. 2016. Blocking P2 receptor by suramin reduces the severity of acute pancreatitis. Pancreas. 2016;45(10): 1502-1503. 60. Windsor JA, Escott A, Brown L, Phillips AJP. Novel strategies for the treatment of acute pancreatitis based on the determinants of severity. J Gastroenterol Hepatol. 2017;32(11):1796-1803. 61. Fanous MYZ, Phillips AJP, Windsor JA. Mesenteric lymph: the bridge to future management of critical illness. J Pancreas. 2007;8(4):374-399. 62. Working Party of British Society of Gastroenterology, Association of Surgeons of Great Britain and Ireland, Pancreatic Society of Great Britain and Ireland, Association of Upper GI Surgeons of Great Britain and Ireland. UK guidelines for the management of acute pancreatitis. Gut. 2005;54(suppl 3):iii1-iii9. 63. IAP/APA evidence-based guidelines for the management of acute pancreatitis. Pancreatology. 2013;13(4 suppl 2): e1-e15. 64. Forsmark CE, Vege SS, Wilcox CM. Acute pancreatitis. N Engl J Med. 2016;375(20):1972-1981. 65. Windsor JA, Johnson CD, Petrov MS, Layer P, Garg PK, Papachristou GI. Classifying the severity of acute pancreatitis: towards a way forward. Pancreatology. 2015;15(2): 101-104. 66. Whitcomb DC. Acute pancreatitis. N Engl J Med. 2006; 354:2142-2150. 67. Papachristou GI, Muddana V, Yadav D, et al. Comparison of BISAP, Ranson’s APACHE II, and CTSI scores in predicting organ failure, complications and mortality in acute pancreatitis. Am J Gastroenterol. 2010;105(2):435-441. 68. Mofidi R, Duff MD, Wigmore SJ, et al. Association between early systemic inflammatory response, severity of multiorgan dysfunction and death in acute pancreatitis. Br J Surg. 2006;93:738-744. 69. Chen SM, Xiong GS, Wu SM. Is obesity an indicator of complications and mortality in acute pancreatitis? An updated meta-analysis. J Dig Dis. 2012;13:244-251. 70. Lankisch PG, Weber-Dany B, Hebel K, Maisonneuve P, Lowenfels AB. The Harmless Acute Pancreatitis Score: a clinical algorithm for rapid initial stratification of non-severe disease. Clin Gastroenterol Hepatol. 2009;7:702-705. 71. Windsor JA. Assessment of the severity of acute pancreatitis: no room for complacency. Pancreatology. 2008;8(2): 105-109. 72. Petrov MS, Windsor JA. Classification of the severity of acute pancreatitis: how many categories make sense? Am J Gastroenterol. 2010;105(1):74-77. 73. Dellinger EP, Forsmark CE, Layer P, et al. Determinants-based classification of acute pancreatitis severity: an international multidisciplinary consultation. Ann Surg. 2012;256: 875-880. 74. Acevedo-Piedra NG, Moya-Hoyo N, Rey-Riveiro M, et al. Validation of the determinant-based classification and revision of the Atlanta classification systems for acute pancreatitis. Clin Gastroenterol Hepatol. 2014;12:311-316. 75. Gardner TB, Vege, SS, Pearson RK, Chari ST. Fluid resuscitation in acute pancreatitis. Clin Gastroenterol Hepatol. 2008;6:1070-1076. 76. Haydock M, Mittal A, Petrov M, Windsor JA. Fluid therapy in acute pancreatitis—anybody’s guess. Ann Surg. 2013; 257(2):182-188. doi: 10.1097/SLA.0b013e31827773ff 77. Wilms H, Mittal A, Haydock MD, van den Heever M, Devaud M, Windsor JA. A systematic review of goal directed fluid therapy: rating of evidence for goals and monitoring methods. J Crit Care. 2014;29(2):204-209. 78. Wu BU, Hwang JQ, Gardner TB, et al. Lactated Ringer’s solution reduces systemic inflammation compared with saline in patients with acute pancreatitis. Clin Gastroenterol Hepatol. 2011;9(8):710-717. 79. Al-Omran M, Albalawi ZH, Tashkandi MF, Al-Ansary LA. Enteral versus parenteral nutrition for acute pancreatitis. Cochrane Database Syst Rev. 2010;20(1):CD002837. doi: 10.1002/14651858 80. Bakker OJ, van Brunschot S, van Santvoort HC, et al. Early versus on-demand nasoenteric tube feeding in acute pancreatitis. N Engl J Med. 2014;371:1983-1993. 81. Singh N, Sharma B, Sharma M, et al. Evaluation of early enteral feeding through nasogastric and nasojejunal tube in severe acute pancreatitis: a noninferiority randomized controlled trial. Pancreas. 2012;41(1):153-159. 82. Petrov MS, Loveday BP, Pylypchuk RD, McIlroy K, Phillips AR, Windsor JA. Systematic review and meta-analysis of enteral nutrition formulations in acute pancreatitis. Br J Surg. 2009;96:1243-1252. 83. Petrov MS, van Santvoort HC, Besselink MG, et al. Early endoscopic retrograde cholangiopancreatography versus conservative management in acute biliary pancreatitis without cholangitis: a meta-analysis of randomized trials. Ann Surg. 2008;247(2):250-257. 84. Kraft M, Lerch MM. Gallstone pancreatitis: when is endoscopicretrograde cholangiopancreatography truly necessary? Curr Gastroenterol Rep. 2003;5:125-132. 85. Wittau M, Mayer B, Scheele J, et al. Systematic review and meta-analysis of antibiotic prophylaxis in severe acute pancreatitis. Scand J Gastroenterol. 2011;46(3): 261-270. 86. Windsor JA. Infected pancreatic necrosis: drain first, but do it better. HPB (Oxford). 2011;13(6):367-368. 87. Van Baal MC, van Santvoort HC, Bollen TL, et al. Systematic review of percutaneous catheter drainage as primary treatment for necrotizing pancreatitis. Br J Surg. 2011;98(1):18-27. 88. Freeman M, Werner J, van Santvoort HC, et al. Interventions for necrotizing pancreatitis: summary of a multidisciplinary consensus conference. Pancreas. 2012;41:1176-1194. 89. Loveday BP, Petrov MS, Connor S, et al. A comprehensive classification of invasive procedures for treating the local complications of acute pancreatitis based on visualization, route and purpose. Pancreatology. 2011;11(4):406-413. 90. Van Santvoort HC, Besselink MG, Bakker OJ, et al. A step-up approach or open necrosectomy for necrotizing pancreatitis. N Engl J Med. 2010;362(16):1491-1502. 91. Bakker OJ, van Santvoort HC, van Brunschot S, et al. Endoscopic transgastric versus surgical necrosectomy for infected necrotizing pancreatitis: a randomized trial. JAMA. 2012;307:1053-1061. 92. Nealon WH, Walser E. Main pancreatic ductal anatomy can direct choice of modality for treating pancreatic pseudocysts (surgery versus percutaneous drainage). Ann Surg. 2002;235(6): 751-758.Brunicardi_Ch33_p1429-p1516.indd 150701/03/19 6:47 PM 1508SPECIFIC CONSIDERATIONSPART II 93. Johnson CD, Abu-Hilal M. Persistent organ failure during the first week as a marker of fatal outcome in acute pancreatitis. Gut. 2004;53:1340-1344. 94. Van Baal MC, Besselink MG, Bakker OJ, et al. Timing of cholecystectomy after mild biliary pancreatitis: a systematic review. Ann Surg. 2012;255(5):860-866. 95. Das SLM, Singh PP, Phillips ARJ, Murphy R, Windsor JA, Petrov MS. Newly diagnosed diabetes mellitus after acute pancreatitis: a systematic review and meta-analysis. Gut. 2014;63(5):818-831. 96. Skyhoj J, Olsen T. The incidence and clinical relevance of chronic inflammation in the pancreas in autopsy material. Acta Pathol Microbiol Scand. 1978;86:361-365. 97. Zdankiewicz PD, Andersen DK. Pancreatitis in the elderly. In: Rosenthal R, Katlic M, Zenilman ME, eds. Principles and Practice of Geriatric Surgery. New York: Springer-Verlag; 2001:740. 98. Worning H. Incidence and prevalence of chronic pancreatitis. In: Beger HG, Buchler M, Ditschuneit H, eds. Chronic Pancreatitis. Berlin: Springer-Verlag; 1990:8. 99. Comfort MW, Steinberg AG. Pedigree of a family with hereditary chronic relapsing pancreatitis. Gastroenterol. 1952;21:54-63. 100. Tomsik H, Gress T, Adler G. Hereditary pancreatitis. In: Beger HG, et al, eds. The Pancreas. London: Blackwell-Science; 1998:355. 101. Whitcomb DC, Preston RA, Aston CE, et al. A gene for hereditary pancreatitis maps to chromosome 7q35. Gastroenterology. 1996;110:1975-1980. 102. Le Bodic L, Bignon JD, Raguenes O, et al. The hereditary pancreatitis gene maps to long arm of chromosome 7. Hum Mol Genet. 1996;5:549-554. 103. Whitcomb DC. Hereditary diseases of the pancreas. In: Yamada T, Alpers DH, Laine L, et al, eds. Textbook of Gastroenterology. 4th ed. Philadelphia: Lippincott Williams & Wilkins; 2002:2147. 104. Masson E, Le Marechal C, Delcenserie R, et al. Hereditary pancreatitis caused by a double gain-of-function trypsinogen mutation. Hum Genet. 2008;123:521-529. 105. Witt H, Luck W, Hennies HC, et al. Mutations in the gene encoding the serine protease inhibitor, Kazal type 1 are associated with chronic pancreatitis. Nat Genet. 2000; 25:213-216. 106. Hassan Z, Mohan V, Ali L, et al. SPINK1 is a susceptibility gene for fibrocalculous pancreatic diabetes in subjects from the Indian subcontinent. Am J Hum Genet. 2002;71:964-968. 107. Schneider A, Suman A, Rossi L, et al. SPINK1/PSTI mutations are associated with tropical pancreatitis and type II diabetes mellitus in Bangladesh. Gastroenterol. 2002;123:1026-1030. 108. Chen JM, Mercier B, Audrezet MP, et al. Mutational analysis of the human pancreatic secretory trypsin inhibitor (PSTI) gene in hereditary and sporadic chronic pancreatitis. J Med Genet. 2000;37:67. 109. Pfutzer RH, Barmada MM, Brunskill AP, et al. SPINK1/PSTI polymorphisms act as disease modifiers in familial and idiopathic chronic pancreatitis. Gastroenterol. 2000;119:615-623. 110. Cohn JA, Friedman KJ, Noone PG, Knowles MR, Silverman LM, Jowell PS. Relation between mutations of the cystic fibrosis gene and idiopathic pancreatitis. N Engl J Med. 1998;339:653-658. 111. Whitcomb DC, LaRusch J, Krasinskas AM, et al. Com-mon genetic variants in the CLDN2 and PRSS1-PRSS2 loci alter risk for alcohol-related and sporadic pancreatitis. Nat Genet. 2012;44(12):1349-1356. 112. Friedreich N. Disease of the pancreas. In: Ziemssen H, ed. Cyclopedia of the Practice of Medicine. New York: William Wood; 1878:549. 113. Worning H. Alcoholic chronic pancreatitis. In: Beger HG, et al, eds. The Pancreas. London: Blackwell Sciences; 1998:672. 114. Durbec JP, Sarles H. Multicenter survey of the etiology of pancreatic diseases. Relationship between the relative risk of developing chronic pancreatitis and alcohol, protein, and lipid consumption. Digestion. 1978;18:337-350. 115. Lankisch PG, Lowenfels AB, Maisonneuve P. What is the risk of alcoholic pancreatitis in heavy drinkers? Pancreas. 2002;25:411-412. 116. Layer P, Yamamoto H, Kalthoff L, Clain JE, Bakken LJ, DiMagno EP. The different courses of early and late-onset idiopathic and alcoholic chronic pancreatitis. Gastroenterol. 1994;107:1481-1487. 117. Comfort MW, Gambrill EE, Baggenstoss AH. Chronic relapsing pancreatitis. A study of twenty-nine cases without associated disease of the biliary or gastro-intestinal tract. Gastroenterology. 1968;4:760-765. 118. Kondo T, Hayakawa T, Shibata T, et al. Aberrant pancreas is not susceptible to alcoholic pancreatitis. Int J Pancreatol. 1991;8:245-252. 119. Apte MV, Wilson JS. Alcohol-induced pancreatic injury. Best Pract Res Clin Gastroenterol. 2003;17:593-612. 120. Niebergall-Roth E, Harder H, Singer MV. A review: acute and chronic effects of ethanol and alcoholic beverages on the pancreatic exocrine secretion in vivo and in vitro. Alcohol Clin Exp Res. 1998;22:1570-1583. 121. Sarles H, Bernard JP, Johnson C. Pathogenesis and epidemiology of chronic pancreatitis. Annu Rev Med. 1989;40:453-468. 122. Imoto M, DiMagno EP. Cigarette smoking increases the risk of pancreatic calcification in late-onset but not early-onset idiopathic chronic pancreatitis. Pancreas. 2000;21:115-119. 123. Rebours V, Vullierme MP, Hentic O, et al. Smoking and the course of recurrent acute and chronic alcoholic pancreatitis: adose-dependent relationship. Pancreas. 2012;41(8):1219-1224. 124. Lowenfels AB, Maisonneuve P, Whitcomb DC. Risk factors for cancer in hereditary pancreatitis. International Hereditary Pancreatitis Study Group. Med Clin North Am. 2000;84:565-575. 125. Goebell H, Steffen C, Baltzer G, et al. Stimulation of pancreatic secretion of enzymes by acute hypercalcaemia in man. Eur J Clin Invest. 1973;3:98-104. 126. Bess MA, Edis AJ, van Heerden JA. Hyperparathyroidism and pancreatitis. Chance or a causal association? JAMA. 1980;243:246-247. 127. Glueck CJ, Lang J, Hamer T, et al. Severe hypertriglyceridemia and pancreatitis when estrogen replacement therapy is given to hypertriglyceridemic women. J Lab Clin Med. 1994; 123:59-64. 128. Etemad B, Whitcomb DC. Chronic pancreatitis: diagnosis, classification, and new genetic developments. Gastroenterol. 2001;120:682-707. 129. Singer MV, Chari ST. Classification of chronic pancreatitis. In: Beger HG, et al, eds. The Pancreas. London: Blackwell-Science; 1998:665. 130. Othersen HB, Jr, Moore FT, Boles ET. Traumatic pancreatitis and pseudocyst in childhood. J Trauma. 1968;8:535-546. 131. Warshaw AL. Pancreas divisum and pancreatitis. In: Beger HG, et al, eds. The Pancreas. London: Blackwell-Science; 1998:364. 132. Delhaye M, Engelholm L, Cremer M. Pancreas divisum: congenital anatomic variant or anomaly? Contribution of endoscopic retrograde dorsal pancreatography. Gastroenterol. 1985;89:951-958. 133. Sugawa C, Walt AJ, Nunez DC, et al. Pancreas divisum: is it a normal anatomic variant? Am J Surg. 1987;153:62-67.Brunicardi_Ch33_p1429-p1516.indd 150801/03/19 6:47 PM 1509PANCREASCHAPTER 33 134. Bertin C, Pellitier AL, Vullierme MP, et al. Pancreas divisum is not a cause of pancreatitis itself but acts as a partner of genetic mutations. Am J Gastroenterol. 2012;107(2):311-317. 135. Yoshida K, Toki F, Takeuchi T, Watanabe S, Shiratori K, Hayashi N. Chronic pancreatitis caused by an autoimmune abnormality. Proposal of the concept of autoimmune pancreatitis. Dig Dis Sci. 1995;40:1561-1568. 136. Ito T, Nakano I, Koyanagi S, et al. Autoimmune pancreatitis as a new clinical entity. Three cases of autoimmune pancreatitis with effective steroid therapy. Dig Dis Sci. 1997;42:1458-1468. 137. Ko SB, Mizuno M, Yatabe Y, et al. Corticosteroids cor-rect aberrant CFTR localization in the duct and generate acinar cells in auto-immune pancreatitis. Gastroenterol. 2010;138(5):1988-1996. 138. Stathopoulos G, Nourmand AD, Blackstone M, et al. Rapidly progressive sclerosing cholangitis following surgical treatment of pancreatic pseudotumor. J Clin Gastroenterol. 1995;21:143-148. 139. Mohan V, Pitchumoni CS. Tropical chronic pancreatitis. In: Beger HG, et al, eds. The Pancreas. London: Blackwell-Science; 1998:688. 140. Pitchumoni CS, Jain NK, Lowenfels AB, DiMagno EP. Chronic cyanide poisoning: unifying concept for alcoholic and tropical pancreatitis. Pancreas. 1988;3:220-222. 141. Mohapatra S, Majumder S, Smyrk TC, et al. Diabetes mellitus is associated with an exocrine pancreatopathy. Conclusions from a review of literature. Pancreas. 2016;45(8):1104-1110. 142. Majumder S, Zhang L, Philip N, et al. Exocrine pancreatopathy (EP) associated with diabetes mellitus (DM) is histologically distinct from chronic pancreatitis (CP): an international mulit-reader blinded study. Gastroenterol. 2016;150(4)suppl 1:S191 (abstr). 143. Layer P, Kalthoff L, Clain JE, et al. Nonalcoholic chronic pancreatitis: two diseases? Dig Dis Sci. 1985;30:980-985. 144. Ammann RW. Chronic pancreatitis in the elderly. Gastroenterol Clin North Am. 1990;19:905-914. 145. Sinha A, Patel YA, Cruise M, et al. Preditors of post-operative pain relief in patients with chronic pancreatitis undergoing the Frey or Whipple procedure. J Gastrointest Surg. 2016;20:734-740. 146. Cohn JA, Bornstein JD, Jowell PS, et al. Cystic fibrosis mutations and genetic predisposition to idiopathic chronic pancreatitis. Med Clin North Am. 2000;84:621-631. 147. Kloppel G, Maillet B. Pathology of chronic pancreatitis. In: Beger HG, et al, eds. The Pancreas. London: Blackwell-Science; 1998:720. 148. Nagai H, Ohtsubo K. Pancreatic lithiasis in the aged. Its clinicopathology and pathogenesis. Gastroenterol. 1984;86:331-338. 149. Apte MV, Wilson JS. Stellate cell activation in alcoholic pancreatitis. Pancreas. 2003;27:316-320. 150. McCarroll J, Phillips P, Santucci N, et al. Vitamin A induces quiescence in culture-activated pancreatic stellate cells—potential as an antifibrotic agent. Pancreas. 2003;27:396 (abstr). 151. Schneider A, Whitcomb DC. Hereditary pancreatitis: a model for inflammatory diseases of the pancreas. Best Pract Res Clin Gastroenterol. 2002;16:347-363. 152. Guy O, Robles-Diaz G, Adrich Z, Sahel J, Sarles H. Protein content of precipitates present in pancreatic juice of alcoholic subjects and patients with chronic calcifying pancreatitis. Gastroenterology. 1983;84:102-107. 153. Sarles H, Dagorn JC, Giorgi D, Bernard JP. Renaming pancreatic stone protein as “lithostathine.” Gastroenterol. 1990;99:900-901. 154. Watanabe T, Yonekura H, Terazono K, Yamamoto H, Okamoto H. Complete nucleotide sequence of human reg gene and its expression in normal and tumoral tissues. The reg protein, pancreatic stone protein, and pancreatic thread protein are one and the same product of the gene. J Biol Chem. 1990;265:7432-7439. 155. Giorgi D, Bernard JP, Rouquier S, Iovanna J, Sarles H, Dagorn JC. Secretory pancreatic stone protein messenger RNA. Nucleotide sequence and expression in chronic calcifying pancreatitis. J Clin Invest. 1989;84:100-106. 156. Goggin P, Johnson P. Pancreatic stones. In: Beger HG, et al, eds. The Pancreas. London: Blackwell-Science; 1998:711. 157. Warshaw AL, Simeone J, Schapiro RH, Hedberg SE, Mueller PE, Ferrucci JT, Jr. Objective evaluation of ampullary stenosis with ultrasonography and pancreatic stimulation. Am J Surg. 1985;149:65-72. 158. Freeny P. Radiology. In: Beger HG, et al, eds. The Pancreas. London: Blackwell-Science; 1998:728. 159. Catalano MF, Lahoti S, Geenen JE, et al. Prospective evaluation of endoscopic ultrasonography, endoscopic retrograde pancreatography, and secretin test in the diagnosis of chronic pancreatitis. Gastrointest Endosc. 1998;48:11-17. 160. Kahl S, Glasbrenner B, Leodolter A, Pross M, Schulz HU, Malfertheiner P. EUS in the diagnosis of early chronic pancreatitis: a prospective follow-up study. Gastrointest Endosc. 2002;55:507-511. 161. Freeman ML, DiSario JA, Nelson DB, et al: Risk factors for post-ERCP pancreatitis: a prospective, multicenter study. Gastrointest Endosc. 2001;54:425-434. 162. Nealon WH, Matin S. Analysis of surgical success in preventing recurrent acute exacerbations in chronic pancreatitis. Ann Surg. 2001;233:793. 163. Cooper M, Makary MA, Ng Y, et al. Extent of pancreatic fibrosis as a determinant of symptom resolution after the Frey procedure: a clinico-pathologic analysis. J Gastrointest Surg. 2013;17(4):682-687. 164. Ammann RW, Akovbiantz A, Largiader F, et al. Course and outcome of chronic pancreatitis. Longitudinal study of a mixed medical-surgical series of 245 patients. Gastroenterol. 1984;86:820-828. 165. Bockman DE, Buchler M, Malfertheiner P, et al. Analysis of nerves in chronic pancreatitis. Gastroenterol. 1988;94: 1459-1469. 166. Anaparthy R, Pasricha PJ. Pain and chronic pancreatitis: is it the plumbing or the wiring? Curr Gastroenterol Rep. 2008;10(2):101-106. 167. Poulsen JL, Olesen SS, Frøkjaer et al. Pain and chronic pan-creatitis: a complex interplay of multiple mechanisms. World J Gastroenterol. 2013;19:7282-7291. 168. Olesen SS, Juel J, Graversen C, et al. Pharmacological pain management in chronic pancreatitis. World J Gastroenterol. 2013;19:7292-7301. 169. Grosen K, Olesen AE, Gram M, et al. Predictors of opioid effi-cacy in patients with chronic pain: a prospective multicenter observational cohort study. PLoS One. 2017;12(2): e0171723. 170. DiMagno EP, Go VL, Summerskill WH. Relations between pancreatic enzyme outputs and malabsorption in severe pancreatic insufficiency. N Engl J Med. 1973;288:813-815. 171. Rothenbacher D, Low M, Hardt PD, et al. Prevalence and determinants of exocrine pancreatic insufficiency among older adults: results of a population-based study. Scand J Gastroenterol. 2005;40(6):697-704. 172. Dutta SK, Russell RM, Iber FL. Influence of exocrine pancreatic insufficiency on the intraluminal pH of the proximal small intestine. Dig Dis Sci. 1979;24:529-534. 173. DiMagno MJ, DiMagno EP. Chronic pancreatitis. Curr Opin Gastroenterol. 2012;28(5):523-531. 174. Malka D, Hammel P, Sauvanet A, et al. Risk factors for diabetes mellitus in chronic pancreatitis. Gastroenterol. 2000;119(5):1324-1332.Brunicardi_Ch33_p1429-p1516.indd 150901/03/19 6:47 PM 1510SPECIFIC CONSIDERATIONSPART II 175. Couet C, Genton P, Pointel JP, et al. The prevalence of retinopathy is similar in diabetes mellitus secondary to chronic pancreatitis with or without pancreatectomy and in idiopathic diabetes mellitus. Diabetes Care. 1985;8:323-328. 176. Hardt P, Brendel MD, Kloer HU, Bretzel RG. Is pancreatic diabetes (type 3c diabetes) underdiagnosed and misdiagnosed? Diabetes Care. 2008;31(suppl 2):S165-S169. 177. Slezak LA, Andersen DK. Pancreatic resection: effects on glucose metabolism. World J Surg. 2001;25:452-460. 178. Cui Y, Andersen DK. Pancreatogenic diabetes: special considerations for management. Pancreatol. 2011;11: 279-294. 179. Seymour NE, Volpert AR, Lee EL, Andersen DK, Hernandez C. Alterations in hepatocyte insulin binding in chronic pancreatitis: effects of pancreatic polypeptide. Am J Surg. 1995;169:105-109, discussion 110. 180. Brunicardi FC, Chaiken RL, Ryan AS, et al. Pancreatic polypeptide administration improves abnormal glucose metabolism in patients with chronic pancreatitis. J Clin Endocrinol Metab. 1996;81(10):3566-3572. 181. Rabiee A, Galiatsatos P, Salas-Carrillo R, et al. Pancreatic polypeptide administration enhances insulin sensitivity and reduces the insulin requirement of patients on insulin pump therapy. J Diabetes Sci Technol. 2011;5(6):1521-1528. 182. Gyr K, Agrawal NM, Felsenfeld O, Font RG. Comparative study of secretin and Lundh tests. Am J Dig Dis. 1975;20:506-512. 183. Somogyi L, Cintron M, Toskes PP. Synthetic porcine secretin is highly accurate in pancreatic function testing in individuals with chronic pancreatitis. Pancreas. 2000;21:262-265. 184. Denyer ME, Cotton PB. Pure pancreatic juice studies in normal subjects and patients with chronic pancreatitis. Gut. 1979;20:89-97. 185. Tanner AR, Fisher D, Ward C, et al. An evaluation of the one-day NBT-PABA/14C-PABA in the assessment of pancreatic exocrine insufficiency. Digestion. 1984;29:42-46. 186. Brugge W, Goff JS, Allen N. Development of a dual label Schilling test for pancreatic exocrine function based on the differential absorption of cobalamin malabsorption in pancreatic insufficiency. J Clin Invest. 1978;61:47-54. 187. Haverback B, Dyce B, Gutentag P. Measurement of trypsin and chymotrypsin in stool: a diagnostic test for pancreatic exocrine function. Gastroenterology. 1986;44:588-597. 188. Gullo L, Ventrucci M, Tomassetti P, Migliori M, Pezzilli R. Fecal elastase 1 determination in chronic pancreatitis. Dig Dis Sci. 1999;44:210-213. 189. Hardt PD, Hauenschild A, Nalop J, et al. High prevalence of exocrine pancreatic insufficiency in diabetes mellitus. A multicenter study screening fecal elastase 1 concentrations in 1,021 diabetic patients. Pancreatol. 2003;3:395-402. 190. DiMagno MJ, DiMagno EP. Chronic pancreatitis. Curr Opin Gastroenterol. 2010;26:490-498. 191. Axon AT, Classen M, Cotton PB, et al. Pancreatography in chronic pancreatitis: international definitions. Gut. 1984; 25:1107-1112. 192. Catanzaro A, Richardson S, Veloso H, et al. Long-term follow-up of patients with clinically indeterminate suspicion of pancreatic cancer and normal EUS. Gastrointest Endosc. 2003;58: 836-840. 193. Lowenfels AB, Maisonneuve P, Cavallini G, et al. Prognosis of chronic pancreatitis: an international multicenter study. International Pancreatitis Study Group. Am J Gastroenterol. 1994;89:1467-1471. 194. Miyake H, Harada H, Kunichika K, Ochi K, Kimura I. Clinical course and prognosis of chronic pancreatitis. Pancreas. 1987;2:378-385. 195. Frey CF, Child CG, Fry W. Pancreatectomy for chronic pancreatitis. Ann Surg. 1976;184:403-413. 196. Lowenfels AB, Maisonneuve P, Cavallini G, et al. Pancreatitis and the risk of pancreatic cancer. International Pancreatitis Study Group. N Engl J Med. 1993:328(20): 1433-1437. 197. Liao KF, Lai SW, Li CI, Chen WC. Diabetes mellitus correlates with increased risk of pancreatic cancer: a population-based cohort study in Taiwan. J Gastroenterol Hepatol. 2012;27(4): 709-713. 198. Brodovicz KG, Kou TD, Alexander CM, et al. Impact of dia-betes duration and chronic pancreatitis on the associa-tion between type 2 diabetes and pancreatic cancer risk. Diab Obes Metab. 2012;14:1123-1128. 199. Aspelund G, Topazian MD, Lee JH, Andersen DK. Improved outcomes for benign disease with limited pancreatic head resection. J Gastrointest Surg. 2005;9:400-409. 200. Sankaran S, Walt AJ. The natural and unnatural history of pancreatic pseudocysts. Br J Surg. 1975;62:37-44. 201. Yeo CJ, Bastidas JA, Lynch-Nyhan A, Fishman EK, Zinner MJ, Cameron JL. The natural history of pancreatic pseudocysts documented by computed tomography. Surg Gynecol Obstet. 1990;170:411-417. 202. Goulet RJ, Goodman J, Schaffer R, Dallemand S, Andersen DK. Multiple pancreatic pseudocyst disease. Ann Surg. 1984;199:6-13. 203. Vitas GJ, Sarr MG. Selected management of pancreatic pseudocysts: operative versus expectant management. Surgery. 1992;111:123-130. 204. Warshaw AL, Jin GL, Ottinger LW. Recognition and clinical implications of mesenteric and portal vein obstruction in chronic pancreatitis. Arch Surg. 1987;122:410-415. 205. Warshaw AL, Rattner DW. Timing of surgical drainage for pancreatic pseudocyst. Clinical and chemical criteria. Ann Surg. 1985;202:720-724. 206. Baron TH, Harewood GC, Morgan DE, et al. Outcome differences after endoscopic drainage of pancreatic necrosis, acute pancreatic pseudocysts, and chronic pancreatic pseudocysts. Gastrointest Endosc. 2002;56:7-17. 207. Kozarek RA, Brayko CM, Harlan J, et al. Endoscopic drainage of pancreatic pseudocysts. Gastrointest Endosc. 1985;31:322-327. 208. Bell RH, Jr. Atlas of pancreatic surgery. In: Bell RH, Jr, Rikkers LF, Mulholland MW, eds. Digestive Tract Surgery. A Text and Atlas. Philadelphia: Lippincott-Raven; 1996:963. 209. Park AE, Heniford BT. Therapeutic laparoscopy of the pancreas. Ann Surg. 2002;236:149-158. 210. Hawes RH. Endoscopic management of pseudocysts. Rev Gastroenterol Disord. 2003;3:135-141. 211. Heider R, Meyer AA, Galanko JA, et al. Percutaneous drainage of pancreatic pseudocysts is associated with a higher failure rate than surgical treatment in unselected patients. Ann Surg. 1999;229:781-787. 212. Rao R, Fedorak I, Prinz RA. Effect of failed computed tomography-guided and endoscopic drainage on pancreatic pseudocyst management. Surgery. 1993;114:843-847, discussion 847-849. 213. Lipsett PA, Cameron JL. Internal pancreatic fistula. Am J Surg. 1992;163:216-220. 214. Uchiyama T, Suzuki T, Adachi A, et al. Pancreatic pleural effusion: case report and review of 113 cases in Japan. Am J Gastroenterol. 1992;87:387-391. 215. Lipsett PA, Cameron JL. Treatment of ascites and fistulas. In: Beger HG et al, eds. The Pancreas. London: Blackwell-Science; 1998:788. 216. Beger H, Schlosser W, Poch B, et al. Inflammatory mass in the head of the pancreas. In: Beger HG et al, eds. The Pancreas. London: Blackwell-Science; 1998:757.Brunicardi_Ch33_p1429-p1516.indd 151001/03/19 6:47 PM 1511PANCREASCHAPTER 33 217. Friess H, Yamanaka Y, Buchler M, et al. A subgroup of patients with chronic pancreatitis overexpress the c-erb B-2 protooncogene. Ann Surg. 1994;220:183-192. 218. Sakorafas GH, Sarr MG, Farley DR, et al. The significance of sinistral portal hypertension complicating chronic pancreatitis. Am J Surg. 2000;179:129-133. 219. Amann ST, Toskes PP. Analgesic treatment. In: Beger HG et al, eds. The Pancreas. London: Blackwell-Science; 1998:766. 220. Forsmark CE. Management of chronic pancreatitis. Gastroenterol. 2013;144:1282-1291. 221. Halgreen H, Pedersen NT, Worning H. Symptomatic effect of pancreatic enzyme therapy in patients with chronic pancreatitis. Scand J Gastroenterol. 1986;21:104-108. 222. Hildebrand P, Ensinck JW, Gyr K, et al. Evidence for hormonal inhibition of exocrine pancreatic function by somatostatin 28 in humans. Gastroenterol. 1992;103:240-247. 223. Toskes PP, Forsmark CE, DeMeo MT, et al. A multicenter controlled trial of octreotide for pain of chronic pancreatitis. Pancreas. 1993;8:774. 224. Malfertheiner P, Mayer D, Buchler M, et al. Treatment of pain in chronic pancreatitis by inhibition of pancreatic secretion with octreotide. Gut. 1995;36:450-454. 225. Lieb JG, Shuster JJ, Theriaque D, et al. A pilot study of octreotide LAR vs. octreotide tid for pain and quality of life in chronic pancreatitis. J Pancreas. 2009;10:518-522. 226. Gress F, Schmitt C, Sherman S, et al. Endoscopic ultrasound-guided celiac plexus block for managing abdominal pain associated with chronic pancreatitis: a prospective single center experience. Am J Gastroenterol. 2001;96:409-416. 227. Jacob L, Geenen JE, Catalano MF, Geenen DJ. Prevention of pancreatitis in patients with idiopathic recurrent pancreatitis: aprospective nonblinded randomized study using endoscopic stents. Endoscopy. 2001;33:559-562. 228. Aizawa T, Ueno N. Stent placement in the pancreatic duct prevents pancreatitis after endoscopic sphincter dilation for removal of bile duct stones. Gastrointest Endosc. 2001;54:209-213. 229. Lau ST, Simchuk EJ, Kozarek RA, et al. A pancreatic ductal leak should be sought to direct treatment in patients with acute pancreatitis. Am J Surg. 2001;181:411-415. 230. Canty TG, Sr, Weinman D. Management of major pancreatic duct injuries in children. J Trauma. 2001;50:1001-1007. 231. Kim HS, Lee DK, Kim IW, et al. The role of endoscopic retrograde pancreatography in the treatment of traumatic pancreatic duct injury. Gastrointest Endosc. 2001;54:49-55. 232. Heyries L, Barthet M, Delvasto C, et al. Long-term results of endoscopic management of pancreas divisum with recurrent acute pancreatitis. Gastrointest Endosc. 2002;55:376-381. 233. Gabbrielli A, Mutignani M, Pandolfi M, et al. Endotherapy of early onset idiopathic chronic pancreatitis: results with long-term follow-up. Gastrointest Endosc. 2002;55:488-493. 234. Kozarek RA, Brandabur JJ, Ball TJ, et al. Clinical outcomes in patients who undergo extracorporeal shock wave lithotripsy for chronic calcific pancreatitis. Gastrointest Endosc. 2002;56:496-500. 235. Nealon WH, Thompson JC. Progressive loss of pancreatic function in chronic pancreatitis is delayed by main pancreatic duct decompression. A longitudinal prospective analysis of the modified puestow procedure. Ann Surg. 1993;217:458-466; discussion 466-468. 236. Andersen DK, Frey CF. The evolution of the surgery for chronic pancreatitis. Ann Surg. 2010;251(1):18-32. 237. Link G. The treatment of chronic pancreatitis by pancreatostomy: a new operation. Ann Surg. 1911;53:768-782. 238. Link G. Long term outcome of pancreatostomy for chronic pancreatitis. Ann Surg. 1935;101:287. 239. Priestley JT, Comfort MW, Radcliffe J. Total pancreatectomy for hyperinsulinism due to an islet-cell adenoma: survival and cure at sixteen months after operation presentation of metabolic studies. Ann Surg. 1944;119:211-221. 240. Whipple AO. Radical surgery for certain cases of pancreatic fibrosis associated with calcareous deposits. Ann Surg. 1946;124:991-1008. 241. Fry WJ, Child CG III. Ninety-five per cent distal pancreatectomy for chronic pancreatitis. Ann Surg. 1965;162:543-549. 242. Moody FG, Calabuig R, Vecchio R, et al. Stenosis of the sphincter of Oddi. Surg Clin North Am. 1990;70:1341-1354. 243. Cattell RB. Anastomosis of the duct of Wirsung in palliative operation for carcinoma of the head of the pancreas. Surg Clin North Am. 1947;27:636-643. 244. Duval MK, Jr. Caudal pancreatico-jejunostomy for chronic relapsing pancreatitis. Ann Surg. 1954;140:775-785. 245. Zollinger RM, Keith LM, Jr, Ellison EH. Pancreatitis. N Engl J Med. 1954;251:497-502. 246. Puestow CB, Gillesby WJ. Retrograde surgical drainage of pancreas for chronic relapsing pancreatitis. AMA Arch Surg. 1958;76:898-907. 247. Partington PF, Rochelle RE. Modified Puestow procedure for retrograde drainage of the pancreatic duct. Ann Surg. 1960;152:1037-1043. 248. Eleftheriadis N, Dinu F, Delhaye M. Long-term outcome after pancreatic stenting in severe chronic pancreatitis. Endoscopy. 2005;37:223-230. 249. Gabbrielli A, Pandolfi M, Mutignani M, et al. Efficacy of main pancreatic-duct endoscopic drainage in patients with chronic pancreatitis, continuous pain, and dilated duct. Gastrointest Endosc. 2009;61:576-581. 250. Morgan DE, Smith JK, Hawkins K, Wilcox CM. Endoscopic stent therapy in advanced chronic pancreatitis: relationships between ductal changes, clinical response, and stent patency. Am J Gastroenterol. 2003;98:821-826. 251. Rosch T, Daniel S, Scholz M, et al. Endoscopic treatment of chronic pancreatitis: a multicenter study of 1000 patients with long-term follow-up. Endoscopy. 2002;34:765-771. 252. Ponchon T, Bory RM, Hedelius F, et al. Endoscopic stenting for pain relief in chronic pancreatitis: results of a standardized protocol. Gastrointest Endosc. 1995;42:452-456. 253. Vitale GC, Cothron K, Vitale EA, et al. Role of pancreatic duct stenting in the treatment of chronic pancreatitis. Surg Endosc. 2004;18:1431-1434. 254. Bradley EL III. Long-term results of pancreatojejunostomy in patients with chronic pancreatitis. Am J Surg. 1987;153:207-213. 255. Cahen DL, Gouma DJ, Nio Y, et al. Endoscopic versus surgical drainage of the pancreatic duct in chronic pancreatitis. N Engl J Med. 2007;356:676-684. 256. Dite P, Ruzicka M, Zboril V, Novotny I. A prospective randomized trial comparing endoscopic and surgical therapy for chronic pancreatitis. Endoscopy. 2003;35:553-558. 257. Aldridge MC, Williamson RC. Distal pancreatectomy with and without splenectomy. Br J Surg. 1991;78:976-979. 258. Khanna A, Koniaris LG, Nakeeb A, et al. Laparoscopic spleen-preserving distal pancreatectomy. J Gastrointest Surg. 2005;9:733-738. 259. Traverso LW, Longmire WP, Jr. Preservation of the pylorus in pancreaticoduodenectomy. Surg Gynecol Obstet. 1978; 146:959-962. 260. Huang JJ, Yeo CJ, Sohn TA, et al. Quality of life and outcomes after pancreaticoduodenectomy. Ann Surg. 2000;231:890-898. 261. Sakorafas GH, Farnell MB, Nagorney DM, et al. Pancreato-duodenectomy for chronic pancreatitis: long-term results in 105 patients. Arch Surg. 2000;135:517-522; discussion 523. 262. Jimenez RE, Fernandez-del Castillo C, Rattner DW, et al. Outcome of pancreaticoduodenectomy with pylorus Brunicardi_Ch33_p1429-p1516.indd 151101/03/19 6:47 PM 1512SPECIFIC CONSIDERATIONSPART IIpreservation or with antrectomy in the treatment of chronic pancreatitis. Ann Surg. 2000;231:293-300. 263. Mannell A, Adson MA, McIlrath DC, et al. Surgical management of chronic pancreatitis: long-term results in 141 patients. Br J Surg. 1988;75:467-472. 264. Gall FP, Muhe E, Gebhardt C. Results of partial and total pancreaticoduodenectomy in 117 patients with chronic pancreatitis. World J Surg. 1981;5:269-275. 265. Beger HG, Witte C, Krautzberger W, et al. Experiences with duodenum-sparing pancreas head resection in chronic pancreatitis. Chirurg. 1980;51:303-307. 266. Beger HG, Krautzberger W, Bittner R, et al. Duodenum-preserving resection of the head of the pancreas in patients with severe chronic pancreatitis. Surgery. 1985;97:467. 267. Beger HG, Schlosser W, Friess HM, et al. Duodenum-preserving head resection in chronic pancreatitis changes the natural course of the disease: a single-center 26-year experience. Ann Surg. 1999;230:512-519; discussion 519. 268. Buchler MW, Friess H, Muller MW, et al. Randomized trial of duodenum-preserving pancreatic head resection versus pylorus-preserving Whipple in chronic pancreatitis. Am J Surg. 1995;169:65-69; discussion 69-70. 269. Frey CF, Smith GJ. Description and rationale of a new operation for chronic pancreatitis. Pancreas. 1987;2:701-707. 270. Frey CF, Amikura K. Local resection of the head of the pancreas combined with longitudinal pancreaticojejunostomy in the management of patients with chronic pancreatitis. Ann Surg. 1994;220:492-504; discussion 504-507. 271. Andersen DK, Topazian MD. Pancreatic head excavation: a variation on the theme of duodenum-preserving pancreatic head resection. Arch Surg. 2004;139:375-379. 272. Izbicki JR, Strate T, Yekebas EE, et al. Chronic pancreatitis. In: Yeo CJ, Dempsey DT, Klein AS, et al, eds. Shackleford’s Surgery of the Alimentary Tract. 6th ed. New York: Saunders; 2007:1218. 273. Ho HS, Frey CF. The Frey procedure: combined local resection of the head of the pancreas with longitudinal pancreaticojeju-nostomy. Operat Tech Gen Surg. 2001;4:153-167. 274. Ho HS, Frey CF. The Frey procedure: local resection of pancreatic head combined with lateral pancreaticojejunostomy. Arch Surg. 2001;136:1353-1358. 275. Farkas G, Leindler L, Daroczi M, et al. Organ-preserving pancreatic head resection in chronic pancreatitis. Br J Surg. 2003;90:2-32. 276. Farkas G, Leindler L, Daroczi M, Farkas G, Jr. Prospective randomised comparison of organ-preserving pancreatic head resection with pylorus-preserving pancreaticoduodenectomy. Langenbecks Arch Surg. 2006;391:338-342. 277. Gloor B, Friess H, Uhl W, et al. A modified technique of the Beger and Frey procedure in patients with chronic pancreatitis. Dig Surg. 2001;18:21-25. 278. Koninger J, Seiler CM, Sauerland S, et al. Duodenum-preserving pancreatic head resection—a randomized controlled trial comparing the original Beger procedure with the Berne modification (ISRCTN No. 50638764). Surgery. 2008;143:490-498. 279. Izbicki JR, Bloechle C, Broering DC, et al. Extended drainage versus resection in surgery for chronic pancreatitis: a prospective randomized trial comparing the longitudinal pancreaticojejunostomy combined with local pancreatic head excision with the pylorus-preserving pancreatoduodenectomy. Ann Surg. 1998;228:771-779. 280. Strate T, Bachmann K, Busch P, et al. Resection vs. drainage in treatment of chronic pancreatitis: long-term results of a randomized trial. Gastroenterology. 2008;134:1406-1411. 281. Klempa I, Spatny M, Menzel J, et al. Pancreatic function and quality of life after resection of the head of the pancreas in chronic pancreatitis. A prospective, randomized comparative study after duodenum preserving resection of the head of the pancreas versus Whipple’s operation. Chirurg. 1995;66:350-359. 282. Izbicki JR, Bloechle C, Knoefel WT, et al. Drainage versus resection in surgical therapy of chronic pancreatitis of the head of the pancreas: a randomized study. Der Cherurg. 1997;68:369-377. 283. Strate T, Taherpour Z, Bloechle C, et al. Long-term follow-up of a randomized trial comparing the Beger and Frey procedures for patients suffering from chronic pancreatitis. Ann Surg. 2005;241:591-598. 284. Keck T, Adam U, Makowiec F, et al. Shortand long-term results of duodenum preservation versus resection for the management of chronic pancreatitis: a prospective randomized study. Surg. 2012;152(3)suppl 1:S95-S102. 285. Bachmann K, Tomkoetter L, Kutup A, et al. Is the Whipple procedure harmful for long-term outcomes of chronic pancreatitis? 15 year follow-up comparing the outcome after PPPD and Frey procedures in chronic pancreatitis. Ann Surg. 2013;258:815-821. 286. Zheng Z, Xiang G, Tan C, et al. Pancreaticoduodenectomy vs. duodenum-preserving pancreatic head resection for the treatment of chronic pancreatitis. Pancreas. 2012;41:147-152. 287. Riediger H, Adam U, Fischer E, et al. Long-term outcome after resection for chronic pancreatitis in 224 patients. J Gastrointest Surg. 2007;11:949-959; discussion 959-960. 288. Buchler MW, Friess H, Bittner R, et al. Duodenum-preserving pancreatic head resection: long-term results. J Gastrointest Surg. 1997;1:13-19. 289. Ramesh H, Jacob G, Lekha V, Venugopal A. Ductal drainage with head coring in chronic pancreatitis with small-duct disease. J Hepatobiliary Pancreat Surg. 2003;10:366-372. 290. Shrikhande SV, Kleeff J, Friess H, et al. Management of pain in small duct chronic pancreatitis. J Gastrointest Surg. 2006;10:227-233. 291. Najarian JS, Sutherland DE, Baumgartner D, et al. Total or near total pancreatectomy and islet autotransplantation for treatment of chronic pancreatitis. Ann Surg. 1980;192:526-542. 292. Robertson RP, Lanz KJ, Sutherland DE, et al. Prevention of diabetes for up to 13 years by autoislet transplantation after pancreatectomy for chronic pancreatitis. Diabetes. 2001;50:47-50. 293. Sutherland DE, Radosevich DM, Bellin, MD, et al. Total pancreatectomy and islet autotransplantation for chronic pancreatits. J Am Coll Surg. 2012;214:409-426. 294. Rastellini C. Donor and recipient selection in pancreatic islet transplantation. Curr Opin Organ Transplant. 2002;7:196-201. 295. Chinnakotla S, Beilman GJ, Dunn TB, et al. Factors predicting outcomes after a total pancreatectomy and auto-transplantation leesons learned from over 500 cases. Ann Surg. 2015; 262:610-622. 296. Chinnakotla S, Bellin MD, Schwarzenberg SJ, et al. Total pancreatectomy and islet autotransplantation in children for chronic pancreatitis: indication, surgical techniques, post-operative management, and long-term out-comes. Ann Surg. 2014;260:56-64. 297. Richards ML, Gauger PG, Thompson NW, Kloos RG, Giordano T. Pitfalls in the surgical treatment of insulinoma. Surgery. 2002;132:1040-1049; discussion 1049. 298. Howard TJ, Stabile BE, Zinner MJ, Chang S, Bhagavan BS, Passaro E, Jr. Anatomic distribution of pancreatic endocrine tumors. Am J Surg. 1990;159:258-264. 299. Service FJ, Natt N, Thompson GB, et al. Noninsulinoma pancreatogenous hypoglycemia: a novel syndrome of hyper-insulinemic hypoglycemia in adults independent of mutations in Kir6.2 and SUR1 genes. J Clin Endocrinol Metab. 1999;84: 1582-1589.Brunicardi_Ch33_p1429-p1516.indd 151201/03/19 6:47 PM 1513PANCREASCHAPTER 33 300. Cui YF, Elahi D, Andersen DK. Advances in the etiology and management of hyperinsulinemic hypoglycemia after Roux-en-Y gastric bypass. J Gastrointest Surg. 2011; 15(10):1879-1888. 301. Deol ZK, Frezza E, DeJong S, Pickleman J. Solitary hepatic gastrinoma treated with laparoscopic radiofrequency ablation. JSLS. 2003;7:285-289. 302. Case CC, Wirfel K, Vassilopoulou-Sellin R. Vasoactive intestinal polypeptide-secreting tumor (VIPoma) with liver metastases: dramatic and durable symptomatic benefit from hepatic artery embolization, a case report. Med Oncol. 2002;19:181-187. 303. Tanaka S, Yamasaki S, Matsushita H, et al. Duodenal somatostatinoma: a case report and review of 31 cases with special reference to the relationship between tumor size and metastasis. Pathol Int. 2000;50:146-152. 304. Falconi M, Bartsch DK, Eriksson B, et al. ENETS Consensus Guidelines for the management of patients with digestive neuroendocrine neoplasms of the digestive system: well-differentiated pancreatic non-functioning tumors. Neuroendocrinology. 2012;95:120-134. 305. Mazzaglia PJ, Berber E, Milas M, et al. Laparoscopic radiofrequency ablation of neuroendocrine liver metastases: a 10-year experience evaluating predictors of survival. Surgery. 2007;142:10-19. 306. Kotteas EA, Syrigos KN, Saif MW. Profile of capecitabine/temozolomide combination in the treatment of well-differentiated neuroendocrine tumors. Onco Targets Ther. 2016;9:699-704. 307. Howlader N, Noone AM, Krapcho M, et al, eds. SEER Cancer Statistics Review, 1975-2014. Bethesda, MD: National Cancer Institute. Available at: https://seer.cancer.gov/csr/1975_2014/. Accessed July 30, 2018. 308. Gold EB, Goldin SB. Epidemiology of and risk factors for pancreatic cancer. Surg Oncol Clin N Am. 1998;7:67-91. 309. Fisher WE. Diabetes. Risk factor for the development of pancreatic cancer or manifestation of the disease? World J Surg. 2001;25:503-508. 310. Jean M, Lowy A, Chiao P, et al. The Molecular Biology of Pancreatic Cancer. New York: Springer-Verlag; 2002. 311. Berger D, Fisher W. Inherited Pancreatic Cancer Syndromes. New York: Springer-Verlag; 2002. 312. Biankin AV, Waddell N, Kassahn KS, et al. Pancreatic cancer genomes reveal aberrations in axon guidance pathway genes. Nature. 2012;491(7424):399-405. 313. Biankin AV, Kench JG, Dijkman FP, et al. Molecular pathogenesis of precursor lesions of pancreatic ductal adenocarcinoma. Pathology. 2003;35(1):14-24. 314. Wilentz RE, Hruban RH. Pathology of cancer of the pancreas. Surg Oncol Clin N Am. 1998;7:43-65. 315. Ritts R, Pitt H. CA19-9 in pancreatic cancer. Surg Oncol Clin N Am. 1998;7:93-101. 316. Kung-Kai Kuo, Chao-Jen Kuo, Chiang-Yen Chiu, et al. Quantitative proteomic analysis of differentially expressed protein profiles involved in pancreatic ductal adenocarcinoma pancreas. 2016;45(1):71-83. 317. Shailesh V Shrikhande, Savio George Barreto, Mahesh Goel, Supreeta Arya. Multimodality imaging of pancreatic ductal adenocarcinoma: a review of the literature. HPB (Oxford). 2012;14(10):658-668. 318. Kim HJ, Conlon KC. Laparoscopic Staging. New York: Springer-Verlag; 2002. 319. Shah RJ, Howell DA, Desilets DJ, et al. Multicenter randomized trial of the spiral Z-stent compared with the Wallstent for malig-nant biliary obstruction. Gastrointest Endosc. 2003;57:830-836. 320. Lillemoe K, Cameron JL, Kaufman HS, Yeo CJ, Pitt HA, Sauter PK. Chemical splanchnicectomy in patients with unresectable pancreatic cancer. A prospective randomised trial. Ann Surg. 1993;217:447-455. 321. Singh SM, Reber HA. Surgical palliation for pancreatic cancer. Surg Clin North Am. 1989;69:599-611. 322. Nagaraja V, Eslick GD, Cox MR. Endoscopic stenting versus operative gastrojejunostomy for malignant gastric outlet obstruction-a systematic review and meta-analysis of randomized and non-randomized trials. J Gastrointest Oncol. 2014;5(2):92-98. 323. Herman J, Chang D, Goodman K, et al. Phase 2 multi-institutional trial evaluating gemcitabine and stereotactic body radiotherapy for patients with locally advanced unresectable pancreatic adenocarcinoma. Cancer. 2015;121(7):1128-1137. 324. Casper ES, Green MR, Kelsen DP, et al. Phase II trial of gem-citabine (2,2’-difluorodeoxycytidine) in patients with adeno-carcinoma of the pancreas. Invest New Drugs. 1994;12:29-34. 325. Moore MJ, Goldstein D, Hamm J, et al. National Cancer Institute of Canada Clinical Trials Group. Erlotinib plus gemcitabine compared with gemcitabine alone in patients with advanced pancreatic cancer: a phase III trial of the National Cancer Institute of Canada Clinical Trials Group. J Clin Oncol. 2007;25(15):1960-1966. 326. Conroy T, Desseigne F, Ychou M, et al. Folfirinox versus gemcitabine for metastatic pancreatic cancer. N Engl J Med. 2011;364(19):1817-1825. 327. Von Hoff DD, Ervin T, Arena FP, et al. Increased survival in pancreatic cancer with nab-paclitaxel plus gemcitabine. N Engl J Med. 2013;369(18):1691-1703. doi:10.1056/NEJMoa1304369 328. Wang-Gillam A, Li CP, Bodoky G, et al. Nanoliposomal irinotecan with fluorouracil and folinic acid in metastatic pancreatic cancer after previous gemcitabine-based therapy (NAPOLI-1): a global, randomised, open-label, phase 3 trial. Lancet. 2016;387(10018):545-557. 329. Martin RC II, McFarland K, Ellis S, et al. Irreversable electroporation therapy in the management of locally advanced pancreatic adenocarcinoma. J Am Coll Surg. 2012; 215:361-369. 330. Martin RC, Kwon D, Chalikonda S, et al. Treatment of 200 locally advanced (Stage III) pancreatic adenocarcinoma patients with irreversible electroporation: safety and efficacy. Ann Surg. 2015;262(3):486-494. 331. Chua TC, Saxena A. Extended pancreaticoduodenectomy with vascular resection for pancreatic cancer: a systematic review. J Gastrointest Surg. 2010;14:1442-1452. 332. Gong Y, Zhang L, He T, et al. Pancreaticoduodenectomy combined with vascular resection and reconstruction for patients with locally advanced pancreatic cancer: a multicenter, retrospective analysis. PLoS One. 2013;8(8):e70340. doi:10.1371/journal.pone.0070340 333. Castleberry AW, Ci MM, White RR, et al. The impact of vascular resection on early postoperative outcomes after pancreaticoduodenectomy: an analysis of the American College of Surgeons National Surgical Quality Improvement Program Database. Ann Surg Oncol. 2012;19:4068-4077. 334. Zureikat AH, Postlewait LM, Liu Y, et al. A multi-institutional comparison of perioperative outcomes of robotic and open pancreaticoduodenectomy. Ann Surg. 2016;264(4):640-649. 335. Yamaguchi K, Kishinaka M, Nagai E, et al. Pancreatoduo-denectomy for pancreatic head carcinoma with or with-out pylorus preservation. Hepatogastroenterol. 2001;48: 1479-1485. 336. Ohtsuka T, Yamaguchi K, Ohuchida J, et al. Comparison of quality of life after pylorus-preserving pancreatoduodenectomy and Whipple resection. Hepatogastroenterol. 2003; 50:846-850.Brunicardi_Ch33_p1429-p1516.indd 151301/03/19 6:47 PM 1514SPECIFIC CONSIDERATIONSPART II 337. Van Buren G, Bloomston M, Hughes SJ, et al. A ran-domized prospective multicenter trial of pancreatico-duodenectomy with and without routine intraperitoneal drainage. Ann Surg. 2014;259(4):605-612. doi: 10.1097/SLA.0000000000000460 338. Van Buren G, Bloomston M, Schmidt CR, et al. A prospective randomized multicenter trial of distal pancreatectomy with and without routine intraperitoneal drainage. Ann Surg. 2017;266(3):421-431. doi: 10.1097/SLA.0000000000002375 339. Bassi C1, Molinari E, Malleo G, et al. Early versus late drain removal after standard pancreatic resections: results of a prospective randomized trial. Ann Surg. 2010;252(2):207-214. doi: 10.1097/SLA.0b013e3181e61e88 340. Keane FK, Wo JY, Ferrone CR, et al. Intraoperative radiotherapy in the era of intensive neoadjuvant chemotherapy and chemoradiotherapy for pancreatic adenocarcinoma. Am J Clin Oncol. Post Author Corrections: October 12, 2016. 341. Birkmeyer JD, Finlayson SR, Tosteson AN, et al. Effect of hospital volume on in-hospital mortality with pancreaticoduodenectomy. Surgery. 1999;125(3):250-256. 342. Gordon TA, Bowman HM, Tielsch JM, et al. Statewide regionalization of pancreaticoduodenectomy and its effect on in-hospital mortality. Ann Surg. 1998;228:71-78. 343. Buchler M, Friess H, Klempa I, et al. Role of octreotide in the prevention of postoperative complications following pancreatic resection. Am J Surg. 1992;163:125-130; discussion 130-131. 344. Montorsi M, Zago M, Mosca F, et al. Efficacy of octreotide in the prevention of pancreatic fistula after elective pancreatic resections: a prospective, controlled, randomized clinical trial. Surgery. 1995;117:26-31. 345. Pederzoli P, Bassi C, Falconi M, et al. Efficacy of octreotide in the prevention of complications of elective pancreatic surgery. Italian Study Group. Br J Surg. 1994;81:265-269. 346. Barnett SP, Hodul PJ, Creech S, et al. Octreotide does not prevent postoperative pancreatic fistula or mortality following pancreaticoduodenectomy. Am Surg. 2004;70:222-226; discussion 227. 347. Hesse UJ, DeDecker C, Houtmeyers P, et al. Prospectively randomized trial using perioperative low-dose octreotide to prevent organ-related and general complications after pancreatic surgery and pancreatico-jejunostomy. World J Surg. 2005;29:1325-1328. 348. Lowy AM, Lee JE, Pisters PW, et al. Prospective, randomized trial of octreotide to prevent pancreatic fistula after pancreaticoduodenectomy for malignant disease. Ann Surg. 1997;226:632-641. 349. Suc B, Msika S, Piccinini M, et al. Octreotide in the prevention of intra-abdominal complications following elective pancreatic resection: a prospective, multicenter randomized controlled trial. Arch Surg. 2004;139:288-294; discussion 295. 350. Allen PJ, Mithat G, Brennan MF, et al. Pasireotide for postoperative pancreatic fistula. N Engl J Med. 2014;370: 2014-2022. doi:10.1056/NEJMoa1313688 351. Yeo CJ, Cameron JL, Maher MM, et al. A prospective ran-domized trial of pancreaticogastrostomy versus pancreati-cojejunostomy after pancreaticoduodenectomy. Ann Surg. 1995;222(4):580-588; discussion 588-592. 352. Wente MN, Shrikhande SV, Muller MW, et al. Pancreaticojejunostomy vs. pancreaticogastrostomy: systematic review and meta-analysis. Am J Surg. 2007;193:171-183. 353. Suzuki Y, Fujino Y, Tanioka Y, et al. Selection of pancreaticojejunostomy techniques according to pancreatic texture and duct size. Arch Surg. 2002;137:1044-1047; discussion 1048. 354. Reid-Lombardo KM, Farnell MB, Crippa S, et al. Pancreatic anastomotic leakage after pancreaticoduodenectomy in 1,507 patients: a report from the Pancreatic Anastomotic Leak Study Group. J Gastrointest Surg. 2007;11:1451-1458. 355. Dong Z, Xu J, Wang Z, Petrov MS. Stents for the prevention of pancreatic fistula following pancreaticoduodenectomy. Cochrane Database Syst Rev. 2016;(5):CD008914. doi: 10.1002/14651858.CD008914.pub3 356. Jang JY, Chang YR, Kim SW, et al. Randomized multicentre trial comparing external and internal pancreatic stenting during pancreaticoduodenectomy. Br J Surg. 2016;103(6):668-675. doi: 10.1002/bjs.10160. 357. Sutton CD, Garcea G, White SA, et al. Isolated Roux-loop pancreaticojejunostomy: a series of 61 patients with zero postoperative pancreaticoenteric leaks. J Gastrointest Surg. 2004;8:701-705. 358. Yang YM, Tian XD, Zhuang Y, et al. Risk factors of pancreatic leakage after pancreaticoduodenectomy. World J Gastroenterol. 2005;11:2456-2461. 359. Di Carlo V, Chiesa R, Pontiroli AE, et al. Pancreatoduodenectomy with occlusion of the residual stump by Neoprene injection. World J Surg. 1989;13:105-110; discussion 110-111. 360. Tran K, Van Eijck C, Di Carlo V, et al. Occlusion of the pancreatic duct versus pancreaticojejunostomy: a prospective randomized trial. Ann Surg. 2002;236:422-428, discussion 428. 361. Fisher WE, Chai C, Hodges SE, Wu MF, Hilsenbeck SG, Brunicardi FC. Effect of BioGlue on the incidence of pancreatic fistula following pancreas resection. J Gastrointest Surg. 2008;12:882-890. 362. Lillemoe KD, Cameron JL, Kim MP, et al. Does fibrin glue sealant decrease the rate of pancreatic fistula after pancreaticoduodenectomy? Results of a prospective randomized trial. J Gastrointest Surg. 2004;8:766-772, discussion 772-774. 363. Kazanjian KK, Hines OJ, Eibl G, Reber HA. Management of pancreatic fistulas after pancreaticoduodenectomy: results in 437 consecutive patients. Arch Surg. 2005;140:849-854, discussion 854-856. 364. Bilimoria KY, Bentrem DJ, Ko CY, et al. National failure to operate on early stage pancreatic cancer. Ann Surg. 2007;246(2):173-180. doi: 10.1097/SLA.0b013e3180691579 365. Group GTS. Further evidence of effective adjuvant combined radiation and chemotherapy following curative resection of pancreatic cancer. Cancer. 1997;59:2006-2010. 366. Neoptolemos JP, Dunn JA, Stocken DD, et al. Adjuvant chemoradiotherapy and chemotherapy in resectable pancreatic cancer: a randomised controlled trial. Lancet. 2001;358:1576-1585. 367. Rocha FG1, Hashimoto Y, Traverso LW, et al. Interferon-based adjuvant chemoradiation for resected pancreatic head cancer: long-term follow-up of the Virginia Mason Protocol. Ann Surg. 2016;263(2):376-384. doi: 10.1097/SLA.0000000000001190 368. Russo S, Saif MW. Neoadjuvant therapy for pancreatic cancer: an ongoing debate. Therap Adv Gastroenterol. 2016;9(4):429-436. 369. Tachezy M, Gebauer F, Petersen C, et al. Sequential neoadjuvant chemoradiotherapy (CRT) followed by curative surgery vs. primary surgery alone for resectable, non-metastasized pancreatic adenocarcinoma: NEOPA—a randomized multicenter phase III study (NCT01900327, DRKS00003893, ISRCTN82191749). BMC Cancer. 2014;14:411. 370. Gingras MC, Covington KR, Chang DK, et al. Ampullary cancers harbor ELF3 tumor suppressor gene mutations and exhibit frequent WNT dysregulation. Cell Rep. 2016;14(4):907-919. 371. Laffan TA, Horton KM, Klein AP, et al. Prevalence of unsuspected pancreatic cysts on MDCT. AJR Am J Roentgenol. 2008;191(3):802-807. doi: 10.2214/AJR.07.3340 372. Tanaka M, Adsay V, Chari S, et al. International consensus guidelines 2012 for the management of IPMN and MCN of the pancreas. Pacreatology. 2012(12):183-197.Brunicardi_Ch33_p1429-p1516.indd 151401/03/19 6:47 PM 1515PANCREASCHAPTER 33 373. Brugge WR, Lewandrowski K, Lee-Lewandrowski E, et al. Diagnosis of pancreatic cystic neoplasms: a report of the cooperative pancreatic cyst study. Gastroenterology. 2004;126:1330-1336. 374. Khalid A, Zahid M, Finkelstein SD, et al. Pancreatic cyst fluid DNA analysis in evaluating pancreatic cysts: a report of the PANDA study. Gastrointest Endosc. 2009;69:1095-1102. 375. Yoon WJ, Brugge WR. Pancreatic cystic neoplasms: diagnosis and management. Gastroenterol Clin North Am. 2012;41(1):103-118. 376. Furukawa T, Hatori T, Fujita I, et al. Prognostic relevance of morphological types of intraductal papillary mucinous neoplasms of the pancreas. Gut. 2011;60(4):509-516. 377. Brugge WR. Management and outcomes of pancreatic cystic lesions. Dig Liver Dis. 2008;40(11):854-859. 378. Boni L, Benevento A, Dionigi G, Cabrini L, Dionigi R. Primary pancreatic lymphoma. Surg Endosc. 2002;16:1107-1108.Brunicardi_Ch33_p1429-p1516.indd 151501/03/19 6:47 PM
Brunicardi_Ch33_p1429-p1516.indd 151601/03/19 6:47 PMThis page intentionally left blankThe SpleenAdrian E. Park, Eduardo M. Targarona, Adam S. Weltz, and Carlos Rodriguez-Otero Luppi 34chapterHISTORICAL BACKGROUNDThe spleen has been the subject of man’s musings since almost the establishment of the written word. It has been largely mis-understood, often maligned, and certainly underappreciated as a major organ for more than two millennia. The ancients, pre-sumably through patient observation and occasional anatomic exploration, often consigned the spleen to a vestigial role.Our current understanding of the central role played by the spleen in regulating the immune system and influencing meta-bolic and endocrine functions has been built upon knowledge gleaned only over the past few decades. Our early notions of the spleen as a dispensable filter of blood or seat of emotion have been dispelled as our understanding of its structure and function has evolved, informing our surgical approach to this worthy and fascinating organ. Many of the “founding fathers of medicine” have weighed in on the anatomy and function of the spleen over the centuries. Hippocrates in the fourth century BC was one of the first to write on the spleen.1-3 He taught broadly on the need for balance and equilibrium between the patient and his environment. Illness arose from disharmony in nature, particularly among the patient’s four humors: blood, phlegm, black bile (melancholia), and yellow bile. Hippocrates wrote of a direct connection between the brain and spleen and its particu-lar association with the black bile. These ideas would influence thinking about the role of the spleen for more than 1000 years.2Aristotle, later in the same era, famously stated that, “Nature makes nothing in vain,” yet held the spleen to be an organ of minor importance whose main role was to counterbal-ance the liver.4 He also described how the “hot character” of the spleen aided in digestion.Galen, in the second century AD, engaged in more seri-ous anatomic investigation espousing the early belief that func-tion followed structure. His investigations, though pioneering, lacked sufficient rigor, evidenced by his contention that black bile or melancholia flowed from the liver to the spleen and then through the short gastric vessels into the stomach to be excreted. The influence of Galen’s teaching endured for more than 1200 years. All the more remarkable considering the cur-rent hallowed measure of influence of surgical publication, the impact factor, which is most commonly calculated using a 2-year frame of reference.5,6In the early 17th century, several physician scientists, Mal-pighi being the most prominent, began testing hypotheses on splenic function by splenectomizing dogs. He reportedly fol-lowed several dogs 5 years postoperatively, noting their healthy survival though apparent ravenous hunger and enhanced sexual appetites. The spleen, still in the era of “balanced humors,” was thus felt to play a role in balancing various appetites as well. In addition to melancholy, the spleen became associated with anger and, paradoxically, was also seen as the “seat of laughter.”7The claim for the first human splenectomy may have pre-dated that of canine splenectomy. Andriano Zaccavello was credited in 1549 with having performed a splenectomy on a middle-aged woman. This claim remains shrouded in contro-versy, and the indication for the surgery and whether in fact splenectomy was performed have been called into question. The patient apparently survived, but may in fact have under-gone resection of an ovarian cyst rather than her spleen!8 Most patients who underwent splenectomy in the three centuries that followed fared badly. The vast majority of splenectomies per-formed were partial. Most of these patients required surgery for Historical Background 1517Embryology and Anatomy 1518Physiology and  Pathophysiology 1520Indications for Splenectomy 1522Benign Disorders / 1524Malignant Conditions / 1527Miscellaneous Disorders and Lesions / 1529Imaging for Evaluation of  Size and Pathology 1532Preoperative Considerations 1532Vaccination and Patient Education / 1532Deep Vein Thrombosis Prophylaxis / 1533Splenectomy Techniques 1533Patient Preparation / 1533Open Splenectomy / 1533Laparoscopic Splenectomy / 1534Hand-Assisted Splenectomy / 1534Single-Incision Laparoscopic Surgery Splenectomy / 1535Robotic Splenectomy / 1536Partial Splenectomy / 1536Inadvertent Intraoperative Splenic Injury / 1538Preoperative Grading Score to Predict Technical Difficulty in Laparoscopic Splenectomy / 1536Splenectomy Outcomes 1538Overwhelming Postsplenectomy Infection / 1538Complications / 1539Hematologic Outcomes / 1539Cancer / 1539Ultrasound / 1540Computed Tomography / 1540Plain Radiography / 1540Magnetic Resonance Imaging / 1540Angiography / 1541Nuclear Imaging / 1541Brunicardi_Ch34_p1517-p1548.indd 151723/02/19 2:36 PM 1518left upper quadrant stab wounds sustained in battles or duels resulting in partial or complete splenic prolapse.9It was in the early 18th century that the growing body of anatomic microstructural knowledge began to turn the tide on the long-held theory of health and disease deriving from a balance of the four humors. William Henson believed the spleen to be a ductless vascular gland similar to the thyroid and adrenals. In 1777, he wrote of the lymphatic nature of the spleen and its filtering function and even suggested its role in hematopoiesis.10Rudolf Virchow, one of the first to discover leukemia, implicated the spleen as figuring prominently in all leukemia patients. He suspected that the spleen was responsible for gen-erating the leukocytes in large quantities in these patients. There soon followed an enthusiastic effort by surgeons to cure leu-kemia by splenectomy. Dr. Thomas Bryant performed the first splenectomy in 1866 in a patient with leukemia. The patient died, as did all 14 patients who underwent splenectomy for leukemia over the next 15 years. After his second consecutive mortality in this setting, Bryant declared that “the operation is physiologically unsound & surgically unsafe for leukemia and should not be performed.”11 In 1908, Johnson reported a series of 99 splenectomies for leukemia with an 85% mortality rate. Unfortunately, it took several decades for his words to be heeded.In 1916, a medical student from Prague named Paul Kaznelson wrote on the key role played by the spleen in the destruction of platelets leading to the first reported (and success-ful) splenectomy for a patient with idiopathic thrombocytopenia purpura.2As surgeons’ experience with the procedure grew, the associated morbidity and mortality decreased. By 1920, the Mayo Clinic reported that splenectomy had a reduced mortality rate of 11%.1O’Donnell in 1929 was the first to describe fatal post-splenectomy sepsis in a child who had undergone the sur-gery for hemolytic anemia.3 It took Springer’s 1973 review of almost 2800 postsplenectomy patients and the 2.5% inci-dence of sepsis-induced mortality (vs. 0.01% in the general population) to reorient surgeons to more conservative splenic procedures.2,3The advent of minimally invasive surgery and laparo-scopic splenectomy in the early 1990s represented a clear advance, benefitting the patient through this evolution of sur-gical technique. Most large series of laparoscopic splenectomy for benign and malignant indication now report a mortality rate of <1%.12,13 As even more contemporary research reveals the spleen to play a central role in immune, metabolic, and endocrine function, it follows that the surgeon’s role going forward will be to preserve this organ and its functions when-ever possible.EMBRYOLOGY AND ANATOMYConsisting of an encapsulated mass of vascular and lymphoid tissue, the spleen is the largest reticuloendothelial organ in the body. Arising from the primitive mesoderm as an outgrowth of the left side of the dorsal mesogastrium, by the fifth week of gestation, the spleen is evident in an embryo 8 mm long.Development begins through the formation of the splanch-nic mesodermal plate, derived from the mesoderm, at embryonic day 12. The embryonic spleen is first colonized by erythroid and myeloid progenitor cells at 2 weeks of gestation. Follow-ing soon thereafter, the hematopoietic stem cells take up resi-dence in the forming spleen.14 The spleen assumes an important hematopoietic role until the fifth month of gestation. After birth, splenic erythropoietic function may persist in some hematologic disorders.15Key Points1 The human spleen plays a key immunologic role in defense against a number of organisms, particularly encapsulated bacteria.2 The spleen can cause significant morbidity and/or hema-tologic disturbance if it becomes hyperfunctioning (hyper-splenism) or hypertrophied (splenomegaly).3 There is a broad spectrum of nontraumatic diseases for which elective splenectomy can be curative or palliative. They can be broadly categorized as red blood cell disor-ders and hemoglobinopathies, white blood cell disorders, platelet disorders, bone marrow disorders, infections and abscesses, cysts and tumors, storage diseases and infiltra-tive disorders, and miscellaneous conditions.4 Inadvertent intraoperative splenic injury is a scenario for which every abdominal surgeon should be prepared. Avail-ability of a predetermined algorithm, with emphasis on the patient’s condition, facilitates intraoperative decision making.5 Partial splenectomy may be a suitable alternative to total splenectomy for certain conditions of hypersplen-ism or splenomegaly, particularly in children in whom preservation of splenic immunologic function is especially important.6 Preoperative splenic artery embolization for elective sple-nectomy has benefits and disadvantages. It may be most suitable in cases of enlarged spleen. Conclusive evidence is lacking.7 Vaccination of the splenectomized patient remains the most effective prevention strategy against OPSI. Preopera-tive vaccination before elective splenectomy is most prudent.8 Laparoscopic splenectomy provides equal hematologic outcomes with decreased morbidity compared with the open operation. The laparoscopic approach has emerged as the standard for elective, nontraumatic splenectomy.9 Overwhelming postsplenectomy infection (OPSI) is an uncommon but potentially grave disease. Children and those undergoing splenectomy for hematologic malig-nancy are at elevated risk.10 Antibiotic prophylactic strategies against OPSI vary widely. Data regarding their use are lacking.Brunicardi_Ch34_p1517-p1548.indd 151823/02/19 2:36 PM 1519THE SPLEENCHAPTER 34The organ continues its differentiation and migration to the left upper quadrant, where it comes to rest with its smooth, diaphragmatic surface facing posterosuperiorly.16The most common anomaly of splenic embryology is the accessory spleen. Present in up to 20% of the population, one or more accessory spleens may also occur in up to 30% of patients with hematologic disease. Over 80% of accessory spleens are found in the region of the splenic hilum and vascu-lar pedicle. Other locations for accessory spleens in descending order of frequency are the gastrocolic ligament, the pancreas tail, the greater omentum, the stomach’s greater curve, the splenocolic ligament, the small and large bowel mesentery, the left broad ligament in women, and the left spermatic cord in men (Fig. 34-1).10,16The abdominal surface of the diaphragm separates the spleen from the lower left lung and pleura and the ninth to eleventh ribs. The visceral surface faces the abdominal cavity and contains gastric, colic, renal, and pancreatic impressions. Spleen size and weight vary with age, with both diminishing in the elderly and in those with underlying pathologic conditions. The average adult spleen is 7 to 11 cm in length and weighs 150 g (range, 70–250 g).The spleen’s superior border separates the diaphragmatic surface from the gastric impression of the visceral surface and often contains one or two notches, which are particularly pro-nounced when the spleen is greatly enlarged.Of particular clinical relevance, the spleen is suspended in position by several ligaments and peritoneal folds to the colon (splenocolic ligament), the stomach (gastrosplenic liga-ment), the diaphragm (phrenosplenic ligament), and the kidney, ABCDEFGFigure 34-1. Sites where accessory spleens are found in order of importance. A. Hilar region, 54%; B. pedicle, 25%; C. tail of pan-creas, 6%; D. splenocolic ligament, 2%; E. greater omentum, 12%; F. mesentery, 0.5%; G. left ovary, 0.5%.Gastrosplenic ligamentLesser sacGreater omentumSplenocolic ligamentSustentaculum lienisPhrenicocolic ligamentFigure 34-2. Suspensory ligaments of the spleen.adrenal gland, and tail of the pancreas (splenorenal ligament) (Fig. 34-2). In a related historical footnote it was widely held less than 200 years ago that a “wandering spleen” led women to experience hypochondria. Dietl in 1863 finally clarified that “it was not a patient’s temperament but rather relaxation, exten-sion or the hypoplasia of splenic ligaments that made a spleen wander.”17 The gastrosplenic ligament contains the short gas-tric vessels; the remaining ligaments are avascular, with rare exceptions, such as in patients with portal hypertension. The relationship of the pancreas to the spleen also has important clinical implications. In cadaveric anatomic series, the tail of the pancreas has been demonstrated to lie within 1 cm of the splenic hilum 75% of the time and to actually abut the spleen in 30% of patients.2The spleen derives most of its blood from the splenic artery, the longest and most tortuous of the three main branches of the celiac artery. The splenic artery can be characterized by the pattern of its terminal branches. The distributed type of splenic artery is the most common (70%) and is distinguished by a short trunk with many long branches entering over three-fourths of the spleen’s medial surface. The less common magis-tral type of splenic artery (30%) has a long main trunk dividing near the hilum into short terminal branches, and these enter over 25% to 30% of the spleen’s medial surface. The spleen also receives some of its blood supply from the short gastric vessels that branch from the left gastroepiploic artery running within the gastrosplenic ligament. The splenic vein joins the superior mesenteric vein to form the portal vein and accommodates the major venous drainage of the spleen.When a normal, freshly excised spleen is sectioned, the cut surface is finely granular and predominantly dark red with whit-ish nodules distributed liberally across its expanse. This gross observation reflects the spleen’s microstructure. The splenic parenchyma is composed of two main elements: the red pulp, constituting approximately 75% of total splenic volume, and the white pulp (Fig. 34-3). At the interface between the red and white pulp is the narrow marginal zone.Brunicardi_Ch34_p1517-p1548.indd 151923/02/19 2:36 PM 1520SPECIFIC CONSIDERATIONSPART IIBlood enters the red pulp through cords comprised of fibro-blasts and reticular fibers, which contain many macrophages and lack an endothelial lining. The blood then passes from these “open” cords to venous sinuses, which are surrounded and sepa-rated by the same reticulum, and ultimately drains into tributar-ies of the splenic vein. An understanding of the microanatomy of these sinuses has elucidated the mechanical filtration function of the spleen. Unlike the cords of the red pulp, the sinuses of the red pulp are lined by endothelial cells. These cells contain unique stress fibers that connect the endothelial cells and that contain actin and myosin–like filaments capable of producing a sliding action. When activated, these filaments can create slits or gaps between the endothelial cells through which blood can then pass from the cords.14 Aging erythrocytes with stiffer mem-branes get stuck trying to pass into the sinus and are phagocy-tized by macrophages within the red pulp.15The red pulp thus serves as a dynamic filtration system, enabling macrophages to remove microorganisms, cellular debris, antigen-antibody complexes, and senescent erythrocytes from the circulation.Around the terminal millimeters of splenic arterioles, a periarticular lymphatic sheath replaces the native adventitia of the vessel. The sheath is comprised of T lymphocytes and intermittent aggregations of B lymphocytes or lymphoid fol-licles. When antigenically stimulated, the follicles, serving as centers of lymphocyte proliferation, develop germinal centers, which regress as the stimulus or infection subsides. This white pulp consists of nodules that normally are ≤1 mm in size but can increase to several centimeters when nodules coalesce, as occurs in certain lymphoproliferative disorders. At the junction between the white and red pulp is the marginal zone, where lymphocytes are more loosely aggregated.As well as serving as a transit area, the marginal zone is home to its own unique population of cells. Notably two spe-cific types of macrophages reside there, marginal zone macro-phages and marginal zone metallophilic macrophages. The former play an important role in the targeting and clearance of certain bacterial pathogens. The latter have been shown to be the main producers of interferons A and B in response to a viral challenge.14PHYSIOLOGY AND PATHOPHYSIOLOGYThe spleen is contained by a 1to 2-mm thick capsule. In humans, the capsule is rich in collagen and contains some elas-tin fibers. Many mammals have splenic capsules and trabecu-lae with abundant smooth muscle cells, which upon autonomic stimulation contract to expel large volumes of stored blood into the general circulation. The human splenic capsule and trabecu-lae, by contrast, contain few or no smooth muscle cells.Total splenic inflow of blood is approximately 250 to 300 mL/min. Blood flows through successively tapering arteries to arterioles, traverses the white pulp, crosses the marginal zone, and enters the red pulp. From that entry, the flow rate through the spleen may vary greatly. Animal studies measuring the tran-sit times of isotopically labeled blood through the spleen have revealed three distinct velocities of flow. Humans have long been recognized to have both a fast or closed circulation—with blood passing directly from arterioles into venous sinuses—and a slower or open circulation. Most of the spleen’s filtration func-tion occurs via the slower circulation. During open circulation, blood percolates through the reticular space and splenic cords, thus gaining access through gaps or slits in the endothelial cell lining to the sinuses as previously described. Flowing into and out of the venous sinuses through these gaps, the blood is exposed to extensive contact with splenic macrophages. These are responsible for the innate immune response of the spleen, which occurs largely within the marginal zone. The white pulp, by contrast, is involved only in adaptive immunity. In addition, because the passage of plasma through these spaces does not slow in a similar manner, a temporary and unique adhesive con-tact between blood cells and components of the splenic cord may occur. That there is a selective slowing of blood cell flow versus plasma flow is further evidenced by the fact that within the spleen, the erythrocyte concentration (hematocrit) is twice that of the general circulation. During this contact with splenic macrophages, it is likely that the removal of both cellular debris and senescent blood cells occurs.18The process by which the spleen removes erythrocyte inclusions, such as Heinz bodies (intracellular altered hemo-globin), without cell lysis while red blood cells travel through the spleen is not well understood. The spleen acts as the major site for clearance from the blood of damaged or aged red blood cells and, in addition, has a part in the removal of abnormal white blood cells and platelets. A minimum of 2 days of the erythrocyte’s 120-day life cycle is spent sequestered in the spleen. Daily, approximately 20 mL of aged red blood cells are removed. Evidence suggests that, as erythrocytes age, previ-ously undetected antigens on their surfaces may attach to auto-antibodies in the circulation; then macrophages may bind to the antibodies and initiate phagocytosis. It is probable that the erythrocyte is damaged over time by multiple passages through the spleen as well as delayed transit through the congested and relatively hypoxic and acidotic environment of the splenic cords.The spleen can also serve as an extra medullary site for hematopoiesis, if required. Another role played by the spleen is in recycling iron. Erythrocytes in large numbers are destroyed intravascularly throughout the body. The released hemoglobin is then bound to haptoglobin, which is ultimately scav-enged from the circulation in the spleen.191Trabeculae (depicted as both capsular and white lined material)Splenic capsuleRed pulpWhite pulpFigure 34-3. Splenic architecture. (Used with permission from Ivan George, University of Maryland School of Medicine.)Brunicardi_Ch34_p1517-p1548.indd 152023/02/19 2:36 PM 1521THE SPLEENCHAPTER 34The spleen plays a vital, although not indispensable, role in host defense evidenced by the healthy survival of splenec-tomized patients. Both innate and adaptive immune responses (historically categorized as cell-mediated and humoral immu-nity) occur within the spleen.In addition to the previously noted activities of the mar-ginal zone macrophages, marginal zone B cells serve to detect circulating pathogens and respond quickly to either differenti-ate into immunoglobulin M (IgM)–producing plasma cells or to function as antigen-presenting cells (APCs), which facilitate pathogen removal and destruction.It is APC entry in the white pulp in particular that is key to the initiation of the adaptive immune response. Antigens are thus presented to immunocompetent centers within the lymphoid follicles. This gives rise to the elaboration of immunoglobulins (predominantly IgM). After an antigen challenge, such an acute IgM response results in the release of opsonic antibodies from the white pulp of the spleen. Antigen clearance is then facilitated by the splenic and hepatic reticuloendothelial systems.The structure and immunophysiology of the white pulp is very similar to that of lymph nodes, with the notable difference being that material enters the lymph node in the lymph whereas it is delivered to the white pulp in the blood.20The spleen also produces opsonins, tuftsin, and proper-din. Circulating monocytes are converted within the red pulp into fixed macrophages that account for the spleen’s remarkable phagocytic activity.The spleen also appears to be a major source of the protein properdin, important in the initiation of the alternate pathway of complement activation. The splenic reticuloendothelial system is better able to clear bacteria that are poorly or inadequately opsonized from the circulation than is the hepatic reticuloendo-thelial system. Encapsulated bacteria generally fit such a pro-file, hence the risk posed by pneumococcus and Haemophilus influenzae to an asplenic patient. There appears to be sufficient physiologic capacity within the complement cascade to with-stand the loss of tuftsin and properdin production without an increase in patient vulnerability after splenectomy.21-23In patients with chronic hemolytic disorders, splenic tissue may become permanently hypertrophied. The reticular spaces of the red pulp become distended with macrophages engorged with the products of erythrocyte breakdown, and splenomegaly can result. It is important to distinguish between splenomegaly and hypersplenism, two similar but distinct terms that are critical to understand when discussing splenic pathology. Splenomegaly refers simply to abnormal enlargement of the spleen. Splenomeg-aly is described variably within the surgical literature as moderate, massive, and hyper, which reflects a lack of con-sensus. Most would agree, however, that splenomegaly applies to organs weighing ≥500 g and/or averaging ≥15 cm in length.Massive splenomegaly similarly lacks a consensus defini-tion but has been described variably as spleens >1 kg in mass or >22 cm in length (Fig. 34-4).9 Spleens palpable below the left costal margin are thought to be at least double normal size, with an estimated weight of ≥750 g.24There is not a single, universally accepted standard, but most would agree that an ex vivo mass of >1 kg or a pole-to-pole length of >15 cm generally qualifies as splenomegaly. Hypersplenism often is found in association with splenomegaly but is not synonymous with it. Hypersplenism is defined as the presence of one or more cytopenias in the context of a normally functioning bone marrow.2ABCFigure 34-4. Splenomegaly. A. Computed tomography (CT) scan. B. Three-dimensional reconstruction of CT scan. C. Postoperative specimen.Brunicardi_Ch34_p1517-p1548.indd 152123/02/19 2:36 PM 1522SPECIFIC CONSIDERATIONSPART IIDisorders causing hypersplenism can be categorized as either (a) those in which increased destruction of abnormal blood cells occurs in an intrinsically normal spleen (e.g., hemolytic anemias) or (b) primary disorders of the spleen resulting in increased sequestration and destruction of normal blood cells (e.g., infiltrative disorders).The life cycles of cellular elements vary widely in human blood. A neutrophil in circulation has a normal half-life of approximately 6 hours. The spleen’s role in the normal clearance of neutrophils is not well established. It is clear that hypersplen-ism may result in neutropenia through sequestration of normal white blood cells or the removal of abnormal ones. Platelets, on the other hand, generally survive in the circulation for 10 days. Under normal circumstances, a third of the total platelet pool is sequestered in the spleen. Thrombocytopenia may result from excessive sequestration of platelets as well as accelerated platelet destruction in the spleen. Splenomegaly may result in sequestration of up to 80% of the platelet pool. The spleen may also contribute to the immunologic alteration of platelets, which leads to thrombocytopenia in the absence of splenomegaly (e.g., idiopathic thrombocytopenic purpura [ITP]).25The immunologic functions of the spleen are consistent with those of other lymphoid organs. It is a site of bloodborne antigen presentation and the initiation of Tand B-lymphocyte activities involved in humoral and cellular immune responses. Alteration of splenic immune function often gives rise to anti-body production, which results in blood cell destruction.Although the spleen contributes to the process of eryth-rocyte maturation, in adult humans there is little evidence of normal hematopoietic function. The spleen does have a minor role in hematopoiesis in the fourth month in the human fetus, and reactivation can occur in childhood if the bone marrow fails to meet the hematologic needs. Splenic hematopoiesis giving rise to abnormal red blood cells is seen in adults with myelopro-liferative disorders. In addition, in response to some anemias, elements of the red pulp may revert to hematopoiesis.INDICATIONS FOR SPLENECTOMYGenerally speaking, splenectomy is performed for the purposes of cure or palliation of hematological disease including condi-tions of hypersplenism, to relieve the mass effect and symptoms associated with splenomegaly, to control infection or hemorrhage and finally to diagnose splenic pathology. For the purposes of this chapter, we will divide these indications into the following categories: (a) benign conditions, including red blood cell disor-ders, hemoglobinopathies, and platelet disorders (Table 34-1a); (b) malignant conditions, including white blood cell disorders, bone marrow disorders (myeloproliferative disorders) and tumors of the spleen (Table 34-1b); and (c) miscellaneous conditions and lesions of the spleen including infections and abscesses, cysts, vascular anomalies, and more (Table 34-1c). We will conclude this chapter with a brief discussion on splenic salvage.Overall, the most common indication for splenectomy is trauma to the spleen, whether external trauma (blunt or penetrat-ing) or iatrogenic injury (e.g., at the time of other operations). Inadvertent intraoperative injury to the spleen, necessitating removal, also called “incidental splenectomy” is discussed in a 3Table 34-1aIndications for and expected response to splenectomy in various benign diseases, including red blood cell disorders, hemoglobinopathies, and platelet disordersDISEASE/CONDITIONINDICATIONS FOR SPLENECTOMYRESPONSE TO SPLENECTOMYEssential thrombocythemiaOnly for advanced disease (i.e., transformation to myeloid metaplasia or AML) with severe symptomatic splenomegalyRelief of abdominal pain and early satietyGlucose-6-phosphate dehydrogenase deficiency (G6PD)Excessive transfusion requirements; failure of medical therapy (controversial)May be curativeHereditary spherocytosisHemolytic anemia, recurrent transfusions, intractable leg ulcersImproves or eliminates anemiaIdiopathic thrombocytopenic purpura (ITP)Failure of medical therapy, recurrent disease75%–85% rate of long-term responsePolycythemia veraOnly for advanced disease (i.e., transformation to myeloid metaplasia or AML) with severe symptomatic splenomegalyRelief of abdominal pain and early satietyPyruvate kinase deficiencyOnly in severe cases, recurrent transfusionsDecreased transfusion requirement, palliative onlySickle cell diseaseHistory of acute sequestration crisis, splenic symptoms, or infarction (consider concomitant cholecystectomy)Palliative, variable responseThalassemiaExcessive transfusion requirements, symptomatic splenomegaly, infarction, or hypersplenismDiminished transfusion requirements, relief of symptomsThrombotic thrombocytopenic purpura (TTP)Excessive plasma exchange requirementTypically curativeWarm-antibody autoimmune hemolytic anemiaFailure of medical (steroid) therapy60%–80% response rate, recurrences commonBrunicardi_Ch34_p1517-p1548.indd 152223/02/19 2:36 PM 1523THE SPLEENCHAPTER 34Table 34-1bIndications for and expected response to splenectomy in various malignant diseases, including white blood cell disorders, myeloproliferative disorders, and nonhematologic tumors of the spleenDISEASE/CONDITIONINDICATIONS FOR SPLENECTOMYRESPONSE TO SPLENECTOMYAcute myeloid leukemia (AML)Intolerable symptomatic splenomegalyRelief of abdominal pain and early satietyChronic lymphocytic leukemia (CLL)Cytopenias and anemia75% response rateChronic myelogenous leukemia (CML)Symptomatic splenomegalyRelief of abdominal pain and early satietyChronic myelomonocytic leukemia (CMML)Symptomatic splenomegalyRelief of abdominal pain and early satietyMyelofibrosis (agnogenic myeloid metaplasia)Severe symptomatic splenomegaly76% clinical response at 1 y, high risk of hemorrhagic, thrombotic, and infectious complications (26%)Hairy cell leukemiaSevere symptomatic splenomegaly, severe transfusion requirements; failure of medical therapyCurativeHodgkin’s lymphomaSurgical staging in selected casesVariedNon-Hodgkin’s lymphomaCytopenias, symptomatic splenomegalyImproved complete blood count values, relief of symptomsMetastatic tumor of the spleen (most commonly breast, lung, and melanoma)If symptomatic, or as part of cancer treatmentVariedPrimary tumor of the spleenFor diagnosis and treatment of cancerVariedTable 34-1cIndications for and expected response to splenectomy in various miscellaneous conditionsDISEASE/CONDITIONINDICATIONS FOR SPLENECTOMYRESPONSE TO SPLENECTOMYAbscess of the spleenMultiloculated, or failure of conservative measures for unilocularCurativeAmyloidosisSymptomatic splenomegalyImproves symptoms; does not correct underlying diseaseFelty’s syndromeNeutropenia80% durable response rateGaucher’s diseaseHypersplenismImproves cytopenias; does not correct underlying diseaseNiemann-Pick diseaseSymptomatic splenomegalyImproves symptoms; does not correct underlying diseasePortal/sinistral hypertensionSplenic vein thrombosis, symptomatic splenomegalyPalliativeSarcoidosisHypersplenism or symptomatic splenomegalyImproves symptoms and cytopenias; does not correct underlying diseaseSplenic artery aneurysmBest for distal lesions near splenic hilumCurativeSymptomatic nonparasitic cystsPartial splenectomy for small cysts; unroofing for large cystsCurativeSymptomatic parasitic cystsTherapy of choiceCurative; exercise caution not to spill cyst contentsWandering spleenAbdominal pain or splenomegaly (venous congestion)CurativeTraumatic ruptureGrades 4/5, or failure of conservative management of lower gradesCurativeBrunicardi_Ch34_p1517-p1548.indd 152323/02/19 2:36 PM 1524SPECIFIC CONSIDERATIONSPART IIlater section. Management of splenic injury in the trauma patient is also beyond the scope of this chapter and discussed else-where. The most common indications for elective splenec-tomy are malignancy and hematologic autoimmune disorders, principally, idiopathic thrombocytopenic purpura (ITP) and autoimmune hemolytic anemia (AIHA).Benign DisordersRed Blood Cell Disorders Congenital Hereditary Spherocytosis. Hereditary spherocytosis (HS) is the most common type of hemolytic anemia for which splenectomy is indicated and the third most common type of congenital hemo-lytic anemia overall.26 HS results from an inherited dysfunction or deficiency in one of the erythrocyte membrane proteins (alpha or beta spectrin, ankyrin, band 3 protein, or protein 4.2). The result-ing destabilization of the membrane lipid bilayer allows a patho-logic release of membrane lipids. The red blood cell assumes a more spherical, less deformable shape, and the spherocytic eryth-rocytes are sequestered and destroyed in the spleen and hemolytic anemia ensues. HS is inherited primarily (70–80% of the time) in an autosomal dominant fashion; the estimated prevalence in Western populations is roughly 1 in 2000.26Patients with typical HS forms may have mild jaundice. Splenomegaly usually is palpable on physical examination. Laboratory examination reveals varying degrees of anemia: patients with mild forms of the disease may not have anemia; patients with moderate to severe forms may have hemoglobin levels as low as 4 to 6 g/dL. The mean corpuscular volume is typically low to normal or slightly decreased. For screening, a combined elevated mean corpuscular hemoglobin concentra-tion and an elevated erythrocyte distribution width are an excel-lent predictor. Other laboratory indicators of HS include those providing evidence of rapid red blood cell destruction, includ-ing elevated reticulocyte count, elevated lactate dehydrogenase level, and increased level of unconjugated bilirubin. Sphero-cytes are readily apparent on peripheral blood film.Risks and benefits should be assessed carefully before splenectomy and cholecystectomy are performed for HS.27 The main indications are moderate to severe symptomatic hemo-lytic anemia, growth retardation, skeletal changes, leg ulcers, and extramedullary hemopoietic tumors in young patients.26,28 If gallstones coexist with spherocytosis, the gallbladder should be removed, but prophylactic cholecystectomy without gall-stones is controversial. Near total splenectomy is advocated in children. Dramatic clinical improvement—despite persistent hemolysis—usually occurs after splenectomy in patients with moderate to severe disease. Because children can be affected with HS, the timing of splenectomy is important and is aimed at reducing the diminutive possibility of overwhelming postsple-nectomy sepsis. Delaying such an operation until the patient is between the ages of 4 and 6—unless the anemia and hemolysis accelerate—is recommended by most experts.29Red Blood Cell Enzyme Deficiencies. Red blood cell enzyme deficiencies associated with hemolytic anemia may be classified into two groups: deficiencies of enzymes involved in glycolytic pathways, such as pyruvate kinase deficiency, and deficien-cies of enzymes needed to maintain a high ratio of reduced to oxidized glutathione in the red blood cell, protecting it from oxidative damage, such as glucose-6-phosphate dehydrogenase (G6PD) deficiency.304Pyruvate Kinase Deficiency Pyruvate kinase (PK) deficiency is the most common glycolytic defect causing congenital nons-pherocytic hemolytic anemia.31 Since its first description in the early 1960s, vast amounts of information have been elucidated about the genetic diversity of the disease, red blood cell clear-ance, long-term complications and treatment options includ-ing transfusion and splenectomy. PK deficiency affects people worldwide, with a slight preponderance among those of Northern European or Chinese descent. Its estimated prevalence in the Caucasian population is 51 per million.32,33 Clinical manifesta-tions of the disease vary widely, from transfusion-dependent severe anemia in early childhood to well-compensated mild ane-mia in adolescents or adults. Prenatal hydrops fetalis has also been reported.31 Pyruvate kinase enzyme activity is the gold standard for initial diagnostic testing or by detection of spe-cific mutations at the complementary DNA or genomic level. Splenomegaly is common, and in severe cases, splenectomy can alleviate transfusion requirements.31 As with other disorders that cause hemolytic anemia in children, splenectomy should be delayed if possible to at least 4 years of age to reduce the risk of postsplenectomy infection.Glucose-6-Phosphate Dehydrogenase Deficiency The most common red blood cell enzyme deficiency overall is G6PD deficiency. It is far more prevalent than PK deficiency with more than 400 million people affected worldwide, although most experience only moderate health risks and no longevity reduction.34 Clinical manifestations—chronic hemolytic ane-mia, acute intermittent hemolytic episodes, or no hemolysis—depend on the variant of G6PD deficiency. The mainstay of therapy is avoidance of drugs known to precipitate hemolysis in patients with G6PD deficiency. Transfusions are given in cases of symptomatic anemia. Conventional wisdom is that splenectomy is not indicated in this disease, and certainly the overwhelming majority of patients with G6PD deficiency will neither require nor benefit from splenectomy. However, one report described a small case series of six symptomatic G6PD deficiency patients who had severe hemolytic anemia and required transfusion, all of whom were identified to share a common mutation at exon 10. All underwent splenectomy. A complete response occurred in four patients (transfusion requirement eliminated), and a partial response occurred in one patient (transfusion requirement reduced); no follow-up data were provided for the remaining patient. This study indi-cates that for a carefully select group of patients with severe hemolytic anemia attributable to G6PD deficiency, splenec-tomy may be of benefit, although more data is needed before strong recommendation can be made.34Acquired Warm-Antibody Autoimmune Hemolytic Anemia. Autoim-mune hemolytic anemias (AIHAs) are characterized by the destruction of red blood cells, whose erythrocyte life span is diminished by autoantibodies leveled against antigens. AIHA is classified as either primary or secondary, depending on whether an underlying cause, such as a disease or toxin, is iden-tified. AIHA is also divided into “warm” and “cold” catego-ries, based on the temperature at which the autoantibodies exert their effect.35 In cold-agglutinin disease, severe symptoms are uncommon and splenectomy is almost never indicated; there-fore, this entity is not discussed further in this section. However, warm-antibody AIHA has clinical consequences with which the surgeon should be familiar.Brunicardi_Ch34_p1517-p1548.indd 152423/02/19 2:36 PM 1525THE SPLEENCHAPTER 34Warm-antibody AIHA, although occurring primarily in midlife, can affect individuals at all ages. The disorder is more common among women, and fully half of warm-antibody AIHA cases are idiopathic. Clinical presentation may be acute or gradual. Findings include mild jaundice and symptoms and signs of anemia. One-third to one-half of patients present with splenomegaly. Sometimes in such cases the spleen is palpable on physical examination. The diagnosis relies on demonstrat-ing hemolysis as indicated by anemia, reticulocytosis, and/or products of red blood cell destruction, including bilirubin, in the blood, urine, and stool. A positive result on direct Coombs’ test confirms the AIHA diagnosis by distinguishing autoimmune from other forms of hemolytic anemia.Treatment of AIHA depends on the severity of the disease and whether it is primary or secondary. Severe symptomatic anemia demands prompt attention, often requiring red blood cell transfusion. The mainstay treatment for both primary and secondary forms of symptomatic, unstable AIHA remains longterm corticosteroid administration.36 Therapy should continue until a response is noted by a rise in hematocrit and fall in reticu-locyte count, which generally occurs within 3 weeks.Clinical response to splenectomy for AIHA varies, and the evidence from a number of small case series is conflicting. For example, one 2004 series reported a favorable response to splenectomy in patients with AIHA secondary to chronic lym-phocytic leukemia, whereas more recent series found no benefit from splenectomy in patients with AIHA secondary to systemic lupus erythematosus or inflammatory bowel disease.37,38Favorable responses to splenectomy have been reported in patients with warm-antibody AIHA, with a recent series show-ing complete remission of refractory AIHA following lapa-roscopic splenectomy at 35-month follow-up in patients over 60 years old.36 Transient responses are more common, how-ever, and many patients eventually experience hemolysis again despite splenectomy.37,38 The decision regarding splenectomy in the case of AIHA should be individualized based on careful consideration of the clinical history and frank discussion with the patient. It is considered as a third-line therapy after failure of steroids or anti-CD20 antibody administration.39Hemoglobinopathies. Sickle cell disease is an inherited chronic hemolytic anemia that results from the mutant sickle cell hemoglobin (HbS) within the red blood cell and is inher-ited in an autosomal dominant fashion. Persons who inherit an HbS gene from one parent (heterozygous) are carriers; those who inherit an HbS gene from both parents (homozygous) have sickle cell anemia.40In sickle cell disease, the underlying abnormality is the mutation of adenine to thymine in the sixth codon of the β-globin gene, which results in the substitution of valine for glutamic acid as the sixth amino acid of the β-globin chain. Mutant β chains included in the hemoglobin tetramer create HbS. Deoxy-genated HbS is insoluble and becomes polymerized and sickled. The subsequent lack of deformability of the red blood cell, in addition to other processes, results in microvascular congestion, which may lead to thrombosis, ischemia, and tissue necrosis. The disorder is characterized by painful intermittent episodes.Sequestration occurs in the spleen, with splenomegaly resulting early in the disease course. In most patients, subse-quent infarction of the spleen and autosplenectomy occur at some later time. The most frequent indications for splenectomy in sickle cell disease are recurrent acute sequestration crises, hypersplenism, and splenic abscess. The occurrence of one major acute sequestration crisis, characterized by rapid painful enlargement of the spleen and circulatory collapse, generally is considered sufficient grounds for splenectomy. Both partial and total splenectomy have been shown to control clinical symp-toms in children but may not change hematologic parameters.41 Preoperative preparation should include special attention to adequate hydration and avoidance of hypothermia.Transfusions are often indicated for anemia, for mod-erately severe episodes of acute chest syndrome (i.e., a new infiltrate on chest radiograph associated with new symptoms, such as fever, cough, sputum production, or hypoxia), and pre-operatively before splenectomy. Patients experiencing stroke or a severe crisis may require hydration and an exchange trans-fusion, which may be performed manually or with automated apheresis equipment. Hydroxyurea is an oral chemotherapeutic agent that upregulates fetal hemoglobin, which interferes with polymerization of HbS and thus reduces the sickling process.42Thalassemia. Thalassemia is the term for a group of inherited disorders of hemoglobin synthesis prevalent among people of Mediterranean extraction and classified according to the hemo-globin chain (α, β, or γ) affected. As a group, the thalassemias are the most common genetic diseases known to arise from a single gene defect.43,44 Most forms of this disorder are inherited in Mendelian recessive fashion from asymptomatic carrier par-ents. In the so-called thalassemia belt that extends throughout the shores of the Mediterranean as well as through the Arabian Peninsula, Turkey, Iran, India, and southeastern Asia, the inci-dence of thalassemia is between 2.5% and 15%. However, thal-assemias have been found in people of all ethnic origins.44In all forms of thalassemia, the primary defect is absent or reduced production of hemoglobin chains. From this abnormal-ity, two significant consequences arise: (a) reduced functioning of hemoglobin tetramers, yielding hypochromia and microcy-tosis; and (b) unbalanced biosynthesis of individual α and β subunits, which results in insoluble red blood cells that cannot release oxygen normally and may precipitate with cell aging. Both underproduction of hemoglobin and excess production of unpaired hemoglobin subunits contribute to thalassemia-associated morbidity and mortality.A diagnosis of thalassemia major (homozygous form) is made by demonstrating hypochromic microcytic anemia asso-ciated with randomly distorted red blood cells and nucleated erythrocytes (target cells) on peripheral blood smear.7 Elevated reticulocyte count and white blood cell count are among the associated findings. Because α chains are needed to form both fetal hemoglobin and adult hemoglobin, α-thalassemia becomes symptomatic in utero or at birth. By contrast, β-thalassemia becomes symptomatic at 4 to 6 months because β chains are involved only in adult hemoglobin synthesis.The clinical spectrum of the thalassemias is wide. Heterozygous carriers of the disease are usually asymptomatic. Homozygous individuals, on the other hand, typically present before 2 years of age with pallor, growth retardation, jaundice, and abdominal swelling due to liver and spleen enlargement. Among other characteristics of thalassemia major are intractable leg ulcers, head enlargement, frequent infections, and the need for periodic blood transfusions. Untreated individuals usually die in late infancy or early childhood from severe anemia.7Treatment for thalassemia involves red blood cell transfu-sions to maintain a hemoglobin level of >9 mg/dL, along with Brunicardi_Ch34_p1517-p1548.indd 152523/02/19 2:36 PM 1526SPECIFIC CONSIDERATIONSPART IIintensive parenteral chelation therapy with deferoxamine. Sple-nectomy is indicated for patients with excessive transfusion requirements (>200 mL/kg per year), discomfort due to spleno-megaly, or painful splenic infarction. Careful assessment of the risk-benefit ratio is essential. Thalassemia patients are at high risk for pulmonary hypertension after splenectomy; however, the precise pathophysiology of this sequela remains unclear.45,46 The increase in infectious complications is likely to be due to a coexisting immune deficiency, in large part brought about by iron overload, which may be associated both with the thalas-semia itself and with transfusions. The disproportionately high rate of overwhelming postsplenectomy infection in thalassemia patients has led some investigators to consider partial splenec-tomy in children; some success in reducing mortality has been reported.47 However, splenectomy should be delayed until after the age of 4 years unless it is absolutely necessary.Platelet Disorders Idiopathic Thrombocytopenic Purpura Idiopathic thrombo-cytopenic purpura (ITP), also called immune thrombocytopenic purpura, is an autoimmune disorder characterized by a low platelet count and mucocutaneous and petechial bleeding. The low platelet count stems from premature removal of platelets opsonized by antiplatelet immunoglobulin G autoantibodies produced in the spleen. This clearance occurs through the inter-action of platelet autoantibodies with Fc receptors expressed on tissue macrophages, predominantly in the spleen and liver. The estimated incidence of ITP is 100 persons per million annually, about one-half of whom are children.48 Adult-onset and child-hood-onset ITP are strikingly different in their clinical course and management.Patients with ITP typically present with petechiae or ecchymoses, although some experience major bleeding from the outset. Bleeding may occur from mucosal surfaces in the form of gingival bleeding, epistaxis, menorrhagia, hematuria, or even melena. The severity of bleeding frequently corresponds to the deficiency in platelets: Patients with counts greater than 50,000/mm3 usually present with incidental findings; those with counts between 30,000 and 50,000/mm3 often have easy bruis-ing; those with platelet counts between 10,000 and 30,000/mm3 may develop spontaneous petechiae or ecchymoses; and those with counts less than 10,000/mm3 are at risk for internal bleeding.48 The incidence of major intracranial hemorrhage is approximately 1%, and it usually occurs early in the disease course. The duration of the bleeding helps to distinguish acute from chronic forms of ITP. Children often present at a young age (peak age of approximately 5 years) with sudden onset of petechiae or purpura several days to weeks after an infectious illness. In contrast, adults experience a more chronic form of disease with an insidious onset. Splenomegaly is uncommon with ITP in both adults and children, and its occurrence should prompt a search for a separate cause of thrombocytopenia. Up to 10% of children, however, have a palpable spleen tip.Diagnosis of ITP is based on exclusion of other possibili-ties in the presence of a low platelet count and mucocutane-ous bleeding. Other diseases resulting in secondary forms of ITP, such as systemic lupus erythematosus, antiphospholipid syndrome, lymphoproliferative disorders, human immunodefi-ciency virus (HIV) infection, and hepatitis C, should be identi-fied and treated when present. In addition, any history of use of a drug known to cause thrombocytopenia, such as certain antimicrobials, anti-inflammatories, antihypertensives, and 5Table 34-2Second-line treatment options for immune thrombocytopeniaSplenectomyAdvantages• Effective, time-honored treatment• Most effective response (overall 88%, partial 22%, complete 66%)Disadvantages• Risk of overwhelming postsplenectomy infection• Increased risk of thrombotic events• Morbidity and mortality associated with an operationRituximabAdvantages• Nonsurgical• Good experience since 1999• Initial immediate response 63%• 31% response at 2 yearsDisadvantages• Severe toxicity in 2%–6%Thrombopoietin Receptor AgonistAdvantages• Nonsurgical• Oral agent self-administered weekly• 80% response rateDisadvantages• Long-term treatment required• Potential toxicity• Long-term data lacking at this timeantidepressants, should be sought. In addition to low platelet count, another laboratory finding characteristic of ITP is the presence of large, immature platelets (megakaryocytes) on peripheral blood smear.The usual first line of therapy is oral prednisone at a dos-age of 1.0 to 1.5 mg/kg per day.49,50 No consensus exists as to the optimal duration of steroid therapy, but most responses occur within the first 3 weeks. Response rates range from 50% to 75%, but relapses are common. IV immunoglobulin, given at 1.0 g/kg per day for 2 to 3 days, is indicated for internal bleeding when platelet counts remain less than 5000/mm3, when extensive pur-pura exists, or to preoperatively boost platelets. IV immunoglob-ulin is thought to impair clearance of immunoglobulin G–coated platelets by competing for binding to tissue macrophage recep-tors. An immediate response is common, but a sustained remis-sion is not. The medical approach to ITP has been modified with the advent of rituximab and thrombopoietin receptor agonists.51 Therapeutic recommendations are summarized in Table 34-2. Splenectomy is selectively indicated for failure of medical ther-apy, for prolonged use of steroids with undesirable effects, and in selected cases after first relapse.7 Prolonged use of steroids can be defined in various ways, but a persistent need for more than 10 to 20 mg/d for 3 to 6 months to maintain a platelet count of greater than 30,000/mm3 generally prompts referral for sple-nectomy. Splenectomy is an effective option for refractory ITP and provides a permanent response without subsequent need for steroids in 75% to 85% of patients. Two recent reviews and meta-analyses have assessed the global results of splenectomy for ITP, specifically after the use of laparoscopic techniques. Brunicardi_Ch34_p1517-p1548.indd 152623/02/19 2:36 PM 1527THE SPLEENCHAPTER 34In 2004, Kojouri and colleagues reviewed 135 case series from 1966 to 2004, pooling 4955 patients.51 The long-term plate-let count response was assessed, as was the ability to predict response and the incidence of complications. Complete response was achieved in 66% of cases with a follow-up ranging from 1 to 153 months, and complete and partial responses occurred in as many as 88% of patients, regardless of the duration of follow-up. They also analyzed 12 preoperative demographic, clinical, and laboratory parameters and found no predictive capability of platelet response in any of them. Mortality was very low (1%), and morbidity was 10%. Limitations of this review included old case series and a low percentage of laparoscopic splenectomies. In a 2009 systemic review involving 1223 patients, Mikhael and colleagues evaluated the shortand long-term outcomes after laparoscopic splenectomy.52 The conversion rate to open sur-gery was 5.6%, and the immediate nonresponder rate was 8.2%; however, eventually a clinical response was achieved in 72% of the patients on long-term follow-up (5 years). The initial con-cerns regarding the potential for missing accessory spleens, lon-ger operative times, and increased cost related to laparoscopic versus open splenectomy have been resolved. Laparoscopy is now the approach of choice for elective splenectomy for ITP, with recent studies showing improved short-term results and comparable long-term results to conventional open splenectomy in this condition.53-56In children with ITP, the course is typically self-limited, with durable and complete remission in greater than 70% of patients regardless of therapy. Because of the good prognosis without treatment, the decision to intervene surgically is contro-versial and is largely to obviate intracranial hemorrhage as dis-cussed earlier. Thus, children with typical ITP—and certainly those without hemorrhage—are managed principally by obser-vation, with short-term therapy in select cases.57 Urgent sple-nectomy, in conjunction with aggressive medical therapy, may play a role in the rare circumstance of severe, life-threatening bleeding in both children and adults.Thrombotic Thrombocytopenic Purpura Thrombotic throm-bocytopenic purpura (TTP) is a serious disorder characterized by thrombocytopenia, microangiopathic hemolytic anemia, and neurologic complications. Abnormal platelet clumping occurs in arterioles and capillaries, reducing the lumen of these vessels and predisposing the patient to microvascular thrombotic epi-sodes. The reduced lumen size also causes shearing stresses on erythrocytes, which leads to deformed red blood cells subject to hemolysis. Hemolysis may also be due in part to sequestration and destruction of erythrocytes in the spleen. Research has dem-onstrated that the underlying abnormality is likely related to the persistence of unusually large multimers of von Willebrand fac-tor associated with platelet clumping in the patient’s blood.58,59TTP occurs in approximately 3.7 individuals per million, but this rare disorder’s dramatic clinical sequelae and favorable response to early therapy demand an understanding of its clini-cal presentation to ensure an early diagnosis. Clinical features of the disorder include petechiae, fever, neurologic symptoms, renal failure, and, infrequently, cardiac symptoms such as heart failure or arrhythmias. Petechial hemorrhages in the lower extremities are the most common presenting sign. Along with fever, patients may experience flu-like symptoms, malaise, or fatigue. Neurologic changes range from generalized headaches to altered mental status, seizures, and even coma. Generally, however, the mere presence of petechiae and thrombocytopenia is sufficient to lead to the diagnosis of TTP and consideration of treatment.The diagnosis is confirmed by the peripheral blood smear, which shows schistocytes, nucleated red blood cells, and baso-philic stippling. Although other conditions such as tight aortic stenosis or prosthetic valves may lead to the presence of schis-tocytes, these conditions generally are not accompanied by thrombocytopenia. TTP may be distinguished from autoimmune causes of thrombocytopenia, such as Evans’ syndrome (ITP and autoimmune hemolytic anemia) or systemic lupus erythemato-sus, by a negative result on Coombs’ test.Plasma exchange is the first-line therapy for TTP. This treatment consists of the daily removal of a single volume of the patient’s plasma and its replacement with fresh-frozen plasma until the thrombocytopenia, anemia, and associated symptoms are corrected. Therapy is then tapered over 1 to 2 weeks.40 Splenectomy should be considered in patients who experience relapse or who require multiple plasma exchanges to control severe symptoms, and generally is well tolerated without sig-nificant morbidity.59,60Malignant ConditionsWhite Blood Cell Disorders. The role of splenectomy in patients with white blood cell disorders varies. As for the myelogenous diseases mentioned previously, splenectomy for white blood cell disorders can be effective therapy for symp-tomatic splenomegaly and hypersplenism, improving some clinical parameters but generally not altering the course of the underlying disease or long-term prognosis. Historically, sple-nectomy has played a role during surgical staging for Hodg-kin’s disease, although this practice has become largely obsolete with the advent of imaging technologies (Computed tomogra-phy [CT] scan and 18F-fluorodeoxyglucose positron emission tomography [18F-FDG PET]).61-63 Careful consideration of the intended benefits of splenectomy must be weighed against the significant perioperative and postsplenectomy risks in this often complex patient population.64Hairy Cell Leukemia Hairy cell leukemia (HCL) is an uncom-mon blood disorder, representing only 2% of all adult leukemias. HCL is characterized by splenomegaly, pancytopenia, and large numbers of abnormal lymphocytes in the bone marrow. These lymphocytes contain irregular hair-like cytoplasmic projections identifiable on the peripheral smear. Many HCL patients have few symptoms and require no specific therapy. Splenectomy for HCL was historically performed as a palliative procedure, alleviating the symptoms associated with splenomegaly and normalizing peripheral blood counts in the majority of patients, but not leading to morphological bone marrow remissions. However, with the advent of diverse new drugs (e.g., ritux-imab, pentostatin, cladribine), splenectomy has become rarely performed.65 Splenectomy should be considered after exhaustive systemic therapy or for those with nontraumatic rupture, and it has also been used to treat pregnant women with HCL to delay onset of chemotherapy.66Hodgkin’s Lymphoma Hodgkin’s Lymphoma (HL) is a dis-order of the lymphoid system characterized by the presence of Reed-Sternberg cells (which actually form the minority of the Hodgkin’s tumor). More than 90% of patients with HL pres-ent with lymphadenopathy above the diaphragm. Lymph nodes can become particularly bulky in the mediastinum, which may result in shortness of breath, cough, or obstructive pneumonia. Brunicardi_Ch34_p1517-p1548.indd 152723/02/19 2:36 PM 1528SPECIFIC CONSIDERATIONSPART IILymphadenopathy below the diaphragm is rare on presen-tation but can arise with disease progression. The spleen is often an occult site of spread, but massive splenomegaly is not common. In addition, large spleens do not necessarily signify involvement.62Four major histologic types exist: lymphocyte predomi-nance type, nodular sclerosis type, mixed cellularity type, and lymphocyte depletion type. The histologic type, along with location of disease and symptomatology, influence survival for patients with HD. Stage I disease is limited to one anatomic region; stage II disease is defined by the presence of two or more contiguous or noncontiguous regions on the same side of the diaphragm; stage III disease involves disease on both sides of the diaphragm, but limited to lymph nodes, spleen, and Waldeyer’s ring (the ring of lymphoid tissue formed by the lin-gual, palatine, and nasopharyngeal tonsils); and stage IV disease includes involvement of the bone marrow, lung, liver, skin, gas-trointestinal tract, or any organ or tissue other than the lymph nodes or Waldeyer’s ring.62Staging laparotomy for HL is less commonly performed in the current era of minimally invasive surgery and advanced imaging techniques. More liberal use of diagnostic tools (CT scan and 18F-FDG PET) and chemotherapy for patients with HL has drastically reduced the indications for surgical staging. Current indications for surgical staging include clini-cal suspicion of lymphoma without evidence of peripheral disease or patients requiring restaging for suspicion of failure after chemotherapy.62,67Non-Hodgkin’s Lymphoma Non-Hodgkin’s lymphoma (NHL) encompasses all malignancies derived from the lymphoid sys-tem except classic HL.63 A proliferation of any one of the three predominant lymph cell types—natural killer cells, T cells, or B cells—may be included in the category of NHL. Because of the wide net cast by NHL, the clinical presentations of the dis-orders under its umbrella vary. The subentities of NHL may be clinically classified into nodal or extranodal, as well as indolent, aggressive, and very aggressive groups. Patients with indolent lymphomas may present with mild or no symptoms and seek medical attention for a swollen lymph node, whereas the aggres-sive and very aggressive lymphomas create easily noticeable symptoms, such as pain, swelling due to obstruction of vessels, fever, and night sweats. Surgical staging is no longer indicated for NHL because the combination of history and physical exam-ination, chest radiograph and abdominal/pelvic CT scan, biopsy of involved lymph nodes (including laparoscopically directed nodal and liver biopsies), and bone marrow biopsy is suffi-cient.63 Splenomegaly exists in some, but not all, forms of NHL. Splenectomy does not alter the natural history of the disease, but it is indicated in cases where a diagnosis cannot be established by obtaining peripheral tissue and clinical suspicion remains or for management of symptoms related to an enlarged spleen as well as for improvement of cytopenias.68-72Chronic Lymphocytic Leukemia Chronic lymphocytic leuke-mia (CCL) is currently considered a subtype of NHL. The main characteristic of CLL is a progressive accumulation of old and nonfunctional lymphocytes.63,73 Symptoms of CLL are nonspe-cific and include weakness, fatigue, fever without illness, night sweats, and frequent bacterial and viral infections. The most fre-quent finding is lymphadenopathy. When the spleen is enlarged, it may be massive or barely palpable below the costal margin. Splenectomy is indicated to improve cytopenias and was shown to be 75% effective in a combined group of patients who had either CLL or nonmalignant HD.29 Splenectomy may facilitate chemotherapy in patients whose cell counts were prohibitively low before spleen removal. Palliative splenectomy also is indi-cated for symptomatic splenomegaly.Bone Marrow Disorders (Myeloproliferative Disorders).  The myeloproliferative disorders are characterized by an abnor-mal growth of cell lines in the bone marrow. They include chronic myeloid leukemia, acute myeloid leukemia, chronic myelomono-cytic leukemia, essential thrombocythemia, polycythemia vera, and myelofibrosis, also known as agnogenic myeloid metaplasia (see “Myelofibrosis [Agnogenic Myeloid Metaplasia]” later in this chapter). The common underlying problem leading to sple-nectomy in these disorders is symptomatic splenomegaly. Symp-toms due to splenomegaly are due to mass effect and consist of early satiety, poor gastric emptying, heaviness or pain in the left upper quadrant, and even diarrhea. Hypersplenism, when it occurs in these conditions, usually is associated with splenomeg-aly. Splenectomy performed in the setting of the myeloprolifera-tive disorders is generally for treatment of the pain, early satiety, and other symptoms of splenomegaly. Radiation has been used since 1903 to treat symptomatic splenomegaly in myeloprolif-erative disorders, but today it is principally used in situations in which splenectomy is not an option.Chronic Myelogenous Leukemia Chronic myelogenous leu-kemia (CML) is a disorder of the primitive pluripotent stem cells in the bone marrow that results in a significant increase in erythroid, megakaryotic, and pluripotent progenitors in the peripheral blood smear. The genetic hallmark is a transposition between the bcr gene on chromosome 9 and the abl gene on chromosome 22. CML accounts for 7% to 15% of all leukemias, with an incidence of 1.5 in 100,000 in the United States.44 It is often asymptomatic, but CML can cause fatigue, anorexia, sweating, and left upper quadrant pain and early satiety sec-ondary to splenomegaly. Enlargement of the spleen is found in roughly one-half of patients with CML. Current therapy includes imatinib or allogeneic stem cell transplantation. Splenectomy is indicated to relieve symptoms of massive splenomegaly, but it does not prevent blast crisis or alter the disease process.45,70Acute Myeloid Leukemia Like CML, acute myeloid leu-kemia (AML) involves the abnormal growth of stem cells in the bone marrow. Unlike CML, AML has a presentation that is more rapid and dramatic. The proliferation and accumula-tion of hematopoietic stem cells in the bone marrow and blood inhibit the growth and maturation of normal red blood cells, white blood cells, and platelets. Death usually results within weeks to months if AML goes untreated. The incidence of AML is approximately 9200 new cases each year in the United States, and it accounts for 1.2% of all cancer deaths.74 Patients with other myeloproliferative disorders, such as polycythemia vera, primary thrombocytosis, or myeloid metaplasia, are at increased risk for leukemic transformation to AML. Presenting signs and symptoms of AML include a viral-like illness with fever, malaise, and frequently bone pain due to the expansion of the medullary space. Standard treatment is combined induction therapy with daunorubicin, cytarabine, and stem cell transplan-tation. Splenectomy is indicated in AML only in the uncom-mon circumstance that left upper quadrant pain and early satiety become unbearable. The benefit must be weighed against the heightened risk of postsplenectomy infection in AML patients immunocompromised due to neutropenia and chemotherapy.74Brunicardi_Ch34_p1517-p1548.indd 152823/02/19 2:36 PM 1529THE SPLEENCHAPTER 34Chronic Myelomonocytic Leukemia Like CML and AML, chronic myelomonocytic leukemia (CMML) is characterized by a proliferation of hematopoietic elements in the bone marrow and blood. CMML differs from CML in that it is associated with monocytosis in the peripheral smear (>1 × 103 monocytes/mm3) and in the bone marrow. Splenomegaly occurs in one-half of these patients, and splenectomy can result in symptomatic relief.75Essential Thrombocythemia Essential thrombocythemia (ET) represents abnormal growth of the megakaryocyte cell line, resulting in increased levels of platelets in the bloodstream. The diagnosis is made after the exclusion of other chronic myeloid disorders such as CML, polycythemia vera, and myelofibrosis that may also present with thrombocytosis.76 Clinical manifesta-tions of ET include vasomotor symptoms, thrombohemorrhagic events, recurrent fetal loss, and the transformation to myelofi-brosis with myeloid metaplasia or AML. Hydroxyurea is used to reduce thrombotic events in ET but does not alter transforma-tion to myelofibrosis or leukemia. Splenomegaly occurs in one-third to one-half of patients with ET. Splenectomy is not felt to be helpful in the early stages of ET and is best reserved for the later stages of disease, when myeloid metaplasia has devel-oped.69 Even in these circumstances, candidates should be cho-sen selectively because significant bleeding has been reported to complicate splenectomy in these patients.Polycythemia Vera Polycythemia vera (PV) is a clonal, chronic, progressive myeloproliferative disorder characterized by an increase in red blood cell mass, frequently accompanied by leukocytosis, thrombocytosis, and splenomegaly. Patients with PV typically enjoy longer survival than those affected by hematologic malignancies but remain at risk for transformation to myelofibrosis or AML. The disease is rare, with an annual incidence of 5 to 17 cases per million population.76,77 Physical findings include ruddy cyanosis, conjunctival plethora, hepato-megaly, splenomegaly, and hypertension. Treatment should be tailored to the risk status of the patient and ranges from phle-botomy and aspirin administration to the use of chemothera-peutic agents. As in ET, splenectomy is not helpful in the early stages of disease and is best reserved for patients with late-stage disease in whom myeloid metaplasia has developed and spleno-megaly-related symptoms are severe.76,77Myelofibrosis (Agnogenic Myeloid Metaplasia) The term myelofibrosis may be used to describe either the generic condi-tion of fibrosis of the bone marrow (which may be associated with a number of benign and malignant disorders) or a specific, chronic, malignant hematologic disease associated with sple-nomegaly, the presence of red blood cell and white blood cell progenitors in the bloodstream, marrow fibrosis, and extramed-ullary hematopoiesis, otherwise known as agnogenic myeloid metaplasia (AMM). AMM also can be referred to as myeloscle-rosis, idiopathic myeloid metaplasia, and osteosclerosis. In this chapter, the term myelofibrosis is synonymous with AMM.In AMM, fibrosis of the bone marrow is believed to be a response to a clonal proliferation of hematopoietic stem cells. Marrow failure is common. The true incidence of AMM is unknown due to the scarcity of epidemiologic data, but one study estimated its U.S. incidence at 1.46 per 100,000 popula-tion.78-80 The diagnosis is made by a careful examination of the peripheral blood smear and bone marrow. Nucleated red blood cells and immature myeloid elements in the blood are present in 96% of cases and strongly suggest the diagnosis. Teardrop poikilocytosis is another frequent finding. Care must be taken, however, to exclude a history of a primary neoplasm (such as lymphoma or adenocarcinoma of the stomach, lung, prostate, or breast) or tuberculosis because patients with these conditions may develop secondary myelofibrosis.Treatment depends on symptoms: Asymptomatic patients are closely followed, whereas symptomatic patients undergo therapeutic intervention targeted to their symptoms. The only curative therapy is allogeneic bone marrow transplantation in younger, high-risk patients. Supportive therapy for clinically symptomatic anemia includes steroids, danazol, erythropoietin, or blood transfusion.78,80 Splenomegaly-related symptoms are best treated with splenectomy. Although some chemotherapeu-tic agents (busulfan, hydroxyurea, interferon-α) and low-dose radiation can reduce splenic size, their discontinuation usually results in rapid splenic regrowth.A thorough preoperative workup must precede sple-nectomy in patients with AMM. The candidate must possess acceptable cardiac, pulmonary, hepatic, and renal reserve for the operation. The coagulation system should be examined; testing should include measurement of coagulation factors V and VIII and fibrin split products, platelet count, and bleeding time. Low platelet counts may require administration of ste-roids and/or platelet transfusion at the time of surgery. Sple-nectomy provides durable, effective palliation for nearly all patients with AMM, although postoperative complications are more common in patients with AMM than in those with other hematologic indications. The Mayo Clinic recently published its 30-year experience with 314 myelofibrosis patients who underwent splenectomy. Nearly half of the operations (49%) were performed to alleviate the mechanical symptoms of sple-nomegaly; the remainder were undertaken to manage anemia, thrombocytopenia, or portal hypertension. Response to splenec-tomy was 76% overall at 1 year; overall complication rate was 28%, including 21 perioperative deaths.80 Thrombosis, hemor-rhage, and infection complications were common, with preop-erative thrombocytopenia an independent predictor of mortality risk. These data underscore the severity of this malignancy and emphasize the need for careful patient selection when consider-ing splenectomy in AMM.79Tumors and Metastasis. Primary tumors of the spleen are typ-ically benign or malignant variants of vascular neoplasms. The most common primary tumors of the spleen are sarcomas, many of which have been linked to various environmental and occu-pational exposures such as vinyl chloride or thorium dioxide. Isolated splenic metastases are extremely unusual but may occur in the setting of a concomitant carcinoma.81 Lung carcinoma is the tumor that most commonly spreads to the spleen, although, colorectal, ovarian, and melanoma may also metastasize to the spleen.82,83 If after a thorough examination, an isolated splenic metastasis is confirmed, a laparoscopic splenectomy with intact spleen retrieval may be considered.81-83Miscellaneous Disorders and LesionsInfections and Abscesses. Primary infections of the spleen although uncommon in immunocompetent adults, are particu-larly reported in the immunocompromised population or those with a history of intravenous recreational drug abuse.84,85 The potential effects of certain systemic infections on the spleen merit close attention, mostly because of the dreaded risk of spontaneous splenic rupture. Infectious mononucleosis due to Brunicardi_Ch34_p1517-p1548.indd 152923/02/19 2:36 PM 1530SPECIFIC CONSIDERATIONSPART IIeither Epstein-Barr virus or cytomegalovirus infection imparts a small but often-discussed risk of spontaneous splenic rup-ture in both adults and children. The true incidence may be underreported, however. Recent case reports abound in the lit-erature regarding spontaneous splenic rupture due to a variety of infectious causes (malaria, Listeria infection, fungal infec-tions, dengue, and Q fever, to name a few) as well as a vari-ety of neoplastic and other noninfectious causes (lymphoma, angiosarcoma, amyloidosis, pregnancy). The presumed patho-physiologic mechanism is infiltration of the splenic paren-chyma with inflammatory cells, which distorts the architecture and fibrous support system of the spleen and thins the splenic capsule.86 In this setting, splenic rupture can occur spontane-ously or after a seemingly minor external trauma or even a Valsalva maneuver.Abscesses of the spleen are uncommon, with an incidence reported to be 0.14% to 0.7%.87-89 They occur more frequently in tropical locations, where they are associated with throm-bosed splenic vessels and infarction in patients with sickle cell anemia. Five distinct mechanisms of splenic abscess formation have been described: (a) hematogenous infection; (b) contigu-ous infection; (c) hemoglobinopathy; (d) immunosuppression, including HIV infection and chemotherapy; and (e) trauma. The presentation of splenic abscess frequently is delayed, with most patients enduring symptoms for 16 to 22 days before diagno-sis. Clinical manifestations include fever, left upper quadrant pain, leukocytosis, and splenomegaly in about one-third of patients. The diagnosis is confirmed by ultrasound or CT scan, which has a 95% sensitivity and specificity. Common organ-isms are aerobic microbes (streptococci and Escherichia coli), but other microorganisms have also been isolated (Mycobac-terium tuberculosis and Salmonella typhi). Upon discovery of a splenic abscess, broad-spectrum antibiotics should be initi-ated, with adjustment to more specific therapy based on culture results and continuation of treatment for a minimum of 14 days. Splenectomy is the operation of choice, but percutaneous and open drainage are options for patients who either cannot toler-ate splenectomy or where the clinical scenario warrants splenic preservation, particularly in children.90 Percutaneous drainage is often successful for patients with unilocular disease and may result in avoidance of splenectomy. Patients with multilocular disease will often require multiple drains and therefore often benefit from total splenectomy.Cysts. Splenic cysts (Fig. 34-5) can be categorized according to a number of criteria; one clinically relevant scheme is to char-acterize true splenic cysts as either parasitic or nonparasitic.86Parasitic Infections. Parasitic infection is the most common cause of splenic cysts worldwide, and the majority are due to Echinococcus species. These cysts are more commonly found in areas where the pathogen is endemic. Symptoms, when present, generally are related to the presence of a mass lesion in the left upper quadrant or a lesion that impinges on the stomach. Ultra-sound can establish the presence of a cystic lesion and occasion-ally incidentally detect asymptomatic lesions as well. Serologic testing for echinococcal antibodies can confirm or exclude the cystic lesion as parasitic, an important piece of informa-tion when planning operative therapy. Symptomatic parasitic cysts are best treated with splenectomy. Avoidance of spillage of parasitic cyst contents into the peritoneal cavity to avoid the possibility of anaphylactic shock is an important principle in surgical management despite its rare occurrence.91Cysts resulting from trauma are termed pseudocysts due to their lack of an epithelial cell lining. Less common examples of nonparasitic cysts are dermoid, epidermoid, and epithelial cysts.92 The treatment of nonparasitic cysts depends on whether or not they produce symptoms. Asymptomatic nonparasitic cysts may be observed with close follow-up by ultrasound to exclude significant growth or expansion. Patients should be advised of the risk of cyst rupture with even minor abdominal trauma if they elect nonoperative management for large cysts. Small symptomatic nonparasitic cysts may be excised with splenic preservation, and large symptomatic nonparasitic cysts may be unroofed. Both of these operations may be performed laparoscopically.86Storage Diseases and Infiltrative Disorders Gaucher’s Disease Gaucher’s disease is an inherited lipid stor-age disorder characterized by the deposition of glucocerebroside in cells of the macrophage-monocyte system. The underlying abnormality is a deficiency in the activity of a lysosomal hydro-lase. Abnormal glycolipid storage results in organomegaly, particularly hepatomegaly and splenomegaly.93,94 Patients with Gaucher’s disease frequently experience symptoms related to splenomegaly, including early satiety and abdominal discom-fort, and to hypersplenism, including thrombocytopenia, normo-cytic anemia, and mild leukopenia. These latter findings occur as a result of excessive sequestration of formed blood elements in the spleen. Other symptoms in patients with Gaucher’s dis-ease include bone pain, pathologic fractures, and jaundice. Splenectomy may alleviate hematologic abnormalities in these patients with hypersplenism, but it does not correct the underly-ing disease process.95Niemann-Pick Disease Niemann-Pick disease is an inherited disorder of abnormal lysosomal storage of sphingomyelin and cholesterol in cells of the macrophage-monocyte system. Four types of the disease (A, B, C, and D) exist, with unique clinical presentations. Types A and B result from a deficiency in lyso-somal hydrolase and are the forms most likely to demonstrate splenomegaly with its concomitant symptoms. Symptoms of splenomegaly are relieved by splenectomy.Amyloidosis Amyloidosis is a disorder of abnormal extra-cellular protein deposition and protein conformation disorder associated with a clonal plasma cell dyscrasia. There are mul-tiple forms of amyloidosis, each with its own individual clini-cal presentation, and the severity of disease may range from asymptomatic to multiorgan failure. Patients with primary amy-loidosis, associated with plasma cell dyscrasia, have splenic involvement in approximately 5% of cases. Secondary amy-loidosis, associated with chronic inflammatory conditions, also may present with an enlarged spleen and even spontaneous rup-ture.96 Symptoms of splenomegaly are relieved by splenectomy.Sarcoidosis Sarcoidosis is an inflammatory disease of young adults characterized by noncaseating granulomas in affected tissues. Signs and symptoms of the disease range in severity and typically are nonspecific, such as fatigue and malaise. Any organ system may be involved. The most commonly involved organ is the lung, followed by the spleen. Splenomegaly occurs in approximately 25% of patients. Massive splenomegaly (>1 kg) is rare with a reported incidence of 3%.97,98 Other affected tissues include the lymph nodes, eyes, joints, liver, spleen, and heart. When splenomegaly occurs and causes symp-toms related to size or hypersplenism, splenectomy effectively relieves symptoms and corrects hematologic abnormalities such Brunicardi_Ch34_p1517-p1548.indd 153023/02/19 2:36 PM 1531THE SPLEENCHAPTER 34as anemia and thrombocytopenia. Spontaneous splenic rupture has been reported in sarcoidosis.94Splenic Artery Aneurysm Although splenic artery aneurysm is rare, it is the most common visceral artery aneurysm. Women are four times more likely to be affected than men. The aneu-rysm usually arises in the middle to distal portion of the splenic artery.99,100 Indications for treatment include presence of symp-toms, pregnancy, intention to become pregnant, and presence of pseudoaneurysms associated with inflammatory processes. Aneurysm resection or ligation alone is acceptable for amenable lesions in the mid-splenic artery, but distal lesions in close prox-imity to the splenic hilum should be treated with concomitant splenectomy. An excellent prognosis follows elective treatment. Splenic artery embolization has been used to treat splenic artery aneurysm; however, this may result in painful splenic infarction or abscess.Portal Hypertension Portal hypertension can result from numerous causes but is usually due to liver cirrhosis. Sple-nomegaly and splenic congestion often accompany portal hypertension, which leads to sequestration and destruction of circulating cells in the spleen. Splenectomy is not indicated for hypersplenism per se in patients with portal hypertension as there is no correlation between the degree of pancytopenia and long-term survival in these patients.7 In rare circumstances in which splenectomy is required to reduce bleeding from esopha-geal varices exacerbated by thrombocytopenia, a concomitant splenorenal shunt procedure may be performed to decompress the portal system.Sinistral hypertension secondary to splenic vein thrombo-sis, on the other hand, is potentially curable with splenectomy. Patients that are bleeding from isolated gastric varices who have normal liver function test results, especially those with a pre-vious history of pancreatitis, should be examined for splenic vein thrombosis and treated with splenectomy if findings are positive.Idiopathic portal hypertension (IPH) is extremely rare, and it is characterized by the absence of cirrhosis or other clear etiologies such as hepatic or portal vein thrombosis, cardiac failure, or hematologic disorders.101-104 Hypersplen-ism often develops in these patients due to hyperactivity of the spleen; defined as a triad of splenomegaly, pancytopenia, 6ACBDFigure 34-5. A. Computed tomography (CT) scan of giant splenic cyst. B. Three-dimensional CT reconstruction of splenic cyst. C and D. Macroscopic aspect of a multicystic spleen lesion.Brunicardi_Ch34_p1517-p1548.indd 153123/02/19 2:37 PM 1532SPECIFIC CONSIDERATIONSPART IIand normocellularity of bone marrow warranting intervention by way of splenic artery embolization or splenectomy. Par-tial splenic embolization (PSE) has recently been utilized with good success in prohibitively high operative risk patients with severe hypersplenism.105Felty’s Syndrome The triad of rheumatoid arthritis, spleno-megaly, and neutropenia is called Felty’s syndrome. It exists in approximately 3% of all patients with rheumatoid arthritis, two-thirds of whom are women. Immune complexes coat the surface of white blood cells, which leads to their sequestration and clear-ance in the spleen with subsequent neutropenia. This neutro-penia (<2000 neutrophils/mm3) increases the risk for recurrent infections and often drives the decision for splenectomy. The size of the spleen is variable, from nonpalpable in 5% to 10% of patients to massively enlarged upwards of 4 times heavier than normal in others. Corticosteroids, hematopoietic growth factors, methotrexate, and splenectomy have all been used to treat the neutropenia of Felty’s syndrome. More recently, ritux-imab has been tried as a second line agent in refractory Felty’s syndrome.106,107Overall response to splenectomy is excellent, with >80% of patients showing a durable increase in white blood cell count. More than one-half of patients who had infections before surgery may clear their infections after surgery.108 Besides symptomatic neutropenia, other indications for sple-nectomy include transfusion-dependent anemia and profound thrombocytopenia.Wandering Spleen A very uncommon anatomic abnormality is the “wandering spleen.” In this condition, the spleen “floats” inside the abdominal cavity due to an anomaly during embryo-genesis and may present itself in a variety of ways includ-ing acute abdomen.109 The wandering spleen is not normally attached to adjacent viscera in the splenic fossa. This may lead to splenic torsion and infarction. Splenopexy or splenectomy may be required.110Partial Splenectomy and Splenic Salvage. The increased awareness of asplenia-related life-threatening complications such as overwhelming postsplenectomy infection (OPSI) has led to the development of parenchyma sparing splenic resec-tions for select patients and disorders. The first successful partial splenectomy was reported in 1979 by Shapiro and was followed by Uranus who would perform the first laparoscopic partial splenectomy in 1995.111,112 Previously, many surgeons had been reluctant to perform partial splenectomy because of the technical difficulties and bleeding risk. However, with a better understanding of the segmental vascular anatomy of the spleen and the development of improved laparoscopic skills and technologies, laparoscopic partial splenectomy has been used successfully in patients with hematologic diseases such as hereditary spherocytosis in children, who may benefit the most from splenic preservation, as well as for benign splenic cysts.113-119 The technique of partial splenectomy will be dis-cussed later in this chapter.IMAGING FOR EVALUATION OF SIZE AND PATHOLOGYThorough assessment of anatomic detail and functional status of the spleen are essential for proper surgical planning. Spe-cial preoperative consideration needs to be given to patients with splenomegaly because minimally invasive methods of resection may be fraught with additional difficulty in patients with very large spleens, even in skilled hands. Other indica-tions for splenic imaging include trauma, investigations of left upper quadrant pain, characterization of splenic lesions such as tumors, cysts, and abscesses, and guidance for percutaneous procedures.165,166Preoperative imaging of the spleen is primarily performed to obtain an accurate assessment of the splenic volume in order to confirm and document splenomegaly as well as to exclude any large splenic lesion that could affect the surgical resection plane. Identification of the presence of accessory spleens in the preoperative setting is also important, although lack of acces-sory tissue on the imaging should not preclude a thorough intra-operative search.The guidelines of the European Association for Endo-scopic Surgery suggest that for all patients in whom splenec-tomy is indicated, preoperative imaging should be obtained.24 Two of the most commonly used imaging modalities include ultrasound and CT, both enabling measurement of splenic size and volume. When desired, the splenic volume may be calcu-lated using a formula for the volume of a prolate ellipsoid:Volume (cc) = length (cm) × width (cm) × height (cm) × 0.52.64Other imaging modalities, although not as commonly used, include nuclear medicine studies and magnetic resonance imaging (MRI).PREOPERATIVE CONSIDERATIONSAs part of preoperative discussion prior to splenectomy, patients should be consulted on potential complications associated with this procedure, including overwhelming postsplenectomy sepsis, splenic vein thrombosis, bleeding, arterial thrombosis (myocardial infarction, stroke), deep vein thrombosis, and pul-monary hypertension.Vaccination and Patient EducationConsidering that infection is the most common complication, patient education and vaccinations against encapsulated pathogens are the mainstay of preventive therapy.52,120 Although rare, the most feared and extreme infectious complica-tion is overwhelming postsplenectomy sepsis (OPSI). (See later section, “Overwhelming Postsplenectomy Infection,” for detailed discussion.) Patients undergoing splenectomy for hematologic or malignant indications have the greatest risk, whereas patients who undergo splenectomy for trauma or iatro-genic injury have the lowest risk. OPSI is more common in the pediatric population, with 4.4% of children less than 16 years of age versus 0.9% of adults developing this life-threatening condi-tion. The risk has been observed to be the greatest in the first 2 years after splenectomy; however, asplenic patients remain at lifelong risk.121-123 Considering that the spleen is the site for spe-cial adaptation of macrophages that target encapsulated organ-isms, asplenic patients are at higher risk of infection caused by Streptococcus pneumoniae (responsible for >50% of OPSI), H influenzae type b, Neisseria meningitidis, and Capnocytoph-aga canimorsus (transmitted by dog bites).124In the setting of elective splenectomy, patients should be vaccinated two weeks prior to surgery to optimize anti-gen recognition and processing. If splenectomy is performed emergently, vaccinations can be administered postoperatively and consideration should be given to delaying administration 7Brunicardi_Ch34_p1517-p1548.indd 153223/02/19 2:37 PM 1533THE SPLEENCHAPTER 34for 2 weeks to avoid the transient immunosuppression asso-ciated with surgery. International guidelines also recommend annual influenza vaccine for asplenic patients. The influenza vaccination provides protection from influenza syndrome and secondary bacterial infection. This immunization is associated with a 54% reduced risk of death compared with unimmunized asplenic persons.125Preoperative and postoperative patient education regard-ing OPSI is paramount because patients with OPSI may rap-idly progress from a febrile illness to circulatory collapse and death within a matter of hours. In one study, 28% of asplenic patients were unaware of the potential infection risks, and the main reasons for this lack of awareness were that correct advice was not given or that that advice was forgotten.121,126 The use of currently available vaccines against pneumococcus and other encapsulated organisms has led to a drop in the overall inci-dence of OPSI to <1%. The mechanism by which vaccination protects asplenic patients is not entirely understood. Serum anti-body titers do not necessarily correspond to clinical immunity. Moreover, antibody levels after pneumococcus vaccination decline steadily within 5 to 10 years. Revaccination is reason-ably recommended for these patients, although the efficacy of this measure is not proven.121-124,126Deep Vein Thrombosis ProphylaxisDeep vein thrombosis (DVT) after splenectomy is not infre-quent, especially in cases involving splenomegaly and myelo-proliferative disorders.76 Risk of portal vein thrombosis (PVT) may reach 50% for patients presenting with both splenomegaly and myeloproliferative disorders.127,128Postsplenectomy PVT typically presents with anorexia, abdominal pain, leukocytosis, and thrombocytosis. Effective PVT treatment is possible by maintaining a high index of sus-picion, achieving early diagnosis with contrast enhanced CT, and starting anticoagulation immediately. DVT prophylaxis, including use of sequential compression devices and subcu-taneous administration of heparin (5000 U), should be initi-ated for patients undergoing splenectomy.16,77 Each patient’s risk factors for DVT should be evaluated, and when elevated risk exists (obesity, history of prior venous thromboembolism, known hypercoagulable state, older age), a postoperative anti-thrombotic regimen of up to two weeks of low molecular weight heparin should be maintained.SPLENECTOMY TECHNIQUESPatient PreparationAssessment of the potential need for transfusion of blood products and optimization of preoperative coagulation status are necessary. It is the authors’ practice to order blood typing and antibody screening tests for normosplenic patients under-going elective splenectomy. Anemic patients should be trans-fused before surgery to a hemoglobin level of 10 g/dL. In more complex cases, including patients with splenomegaly, at least 2 to 4 units of cross-matched blood should be available at the time of surgery. Thrombocytopenia may be transiently cor-rected with platelet transfusions. Thrombocytopenic patients preferably should not undergo transfusion before the day of surgery and ideally not before the intraoperative ligation of the splenic artery. Several authors recommended a platelet count of 30 × 109 / L before the surgery; this may require treatment with IV immunoglobulin or oral corticosteroids if the platelets are below this number. Pooled normal human immunoglobulin is effective in elevating the platelet count in approximately 75% of patients.129-131Patients who have been maintained on corticosteroid therapy preoperatively should receive parenteral corticosteroid therapy perioperatively. Bowel preparation is not routinely performed for patients undergoing elective splenectomy. All splenectomy patients do receive DVT prophylaxis, as discussed previously. After endotracheal intubation, a nasogastric (NG) tube is inserted for stomach decompression.Open SplenectomyAlthough laparoscopic surgery increasingly has achieved acceptance as the standard approach for normosplenic patients requiring splenectomy, open splenectomy (OS) is still widely practiced. The largest published series is a report of the Nationwide Inpatient Sample (NIS), where of 37,006 nontrau-matic splenectomies identified during a 6-year study period (2005–2010), 81.4% of those cases were approached by open surgery.132Traumatic rupture of the spleen continues as the most common indication for OS. Several other clinical scenarios favor an OS approach, including massive splenomegaly, ascites, portal hypertension, multiple prior operations, extensive splenic irradiation, and possible splenic abscess.During OS, the patient is placed in the supine position with the surgeon situated at the patient’s right. A left subcostal incision paralleling the left costal margin and lying two finger-breadths below it is preferred for most elective splenectomies. A midline incision is optimal for exposure when the spleen is ruptured or massively enlarged. The spleen is mobilized by dividing ligamentous attachments, usually beginning with the splenocolic ligament (Fig. 34-6). In patients with signifi-cant splenomegaly, once lesser sac access has been achieved through either the gastrosplenic or gastrohepatic attachments, ligating the splenic artery in continuity along the superior bor-der of the pancreas may be preferable. This maneuver may serve several purposes: allowing safer manipulation of the Figure 34-6. Splenocolic ligament is divided at the beginning of open splenectomy.Brunicardi_Ch34_p1517-p1548.indd 153323/02/19 2:37 PM 1534SPECIFIC CONSIDERATIONSPART II5-mm cephalad working port5-mm camera port with 30’ scope2-mm accessory port (flank)10/12-mm caudad working portFigure 34-7. Patient positioning and trocar placement for laparoscopic splenectomy.spleen and dissection of the splenic hilum, facilitating some shrinkage of the spleen, and providing an autotransfusion of erythrocytes and platelets. Further medial mobilization of the spleen is achieved by incising its lateral peritoneal attachments, most notably the splenophrenic ligament. Then follows indi-vidual ligation and sequential division of the short gastric ves-sels, steps that if carefully executed reduce the risk of these vessels’ retracting and bleeding. Splenic hilar dissection then takes place. Whenever possible, care should be taken to dis-sect and individually ligate the splenic artery and vein (in that order) before dividing them. As noted in the discussion of splenic anatomy, the tail of the pancreas lies within 1 cm of the splenic hilum in 75% of patients; therefore, during hilar dissec-tion, great care must be taken to avoid injuring the pancreas. Once the spleen is excised, hemostasis is secured by irrigating, suctioning, and scrupulously inspecting the bed of dissection. The splenic bed is not routinely drained. A thorough search for accessory spleens must be undertaken when a hematologic disorder has occasioned splenectomy. At the completion of sur-gery, the nasogastric tube is removed.Laparoscopic SplenectomyLaparoscopic splenectomy (LS) has become the procedure of choice over the last two decades, since it has been first described Delaitre and Maignien in 1991.133 In fact, LS is now the gold standard for elective splenectomy in patients with normal-sized spleens. In experienced hands, LS is associated with decreased intraoperative blood loss, shorter hospital length of stay, and lower morbidity rates when compared to OS.134,135 Since the introduction of the lateral approach, most LS proce-dures are now performed with the patient in the right lateral decubitus position (Fig. 34-7).136 A midway “double-access” technique in which the patient is in a 45° right lateral decubitus position has also been advocated. This positioning permits con-comitant surgery, such as laparoscopic cholecystectomy, more easily than does the lateral approach. The double-access 8technique requires the placement of five or six trocars. The lateral approach routinely involves the use of three or four trocars posi-tioned as shown in Fig. 34-7. Use of an angled (30° or 45°) lapa-roscope (2, 5, or 10 mm) greatly facilitates the procedure. Exposure of the vital anatomy in a manner that allows for a more intuitive sequence of dissection, paralleling that of OS, may be considered an additional advantage of the lateral approach.Placement of trocars in the left upper quadrant should be performed under laparoscopic visualization, particularly if any degree of splenomegaly exists, because the latter can sig-nificantly reduce the available operating space. As with OS, the splenocolic ligament and the lateral peritoneal attachments are divided with resultant medial mobilization of the spleen. The short gastric vessels may be divided usually with hemo-static energy sources such as ultrasonic dissection, diathermy, or radiofrequency ablation. With the lower pole of the spleen gently retracted, the splenic hilum is accessible to further appli-cations of clips or an endovascular stapling device. The splenic artery and vein are divided separately when possible. Good long-term outcomes, however, are increasingly being achieved with mass hilar stapling (Fig. 34-8). Using the lateral approach with the spleen thus elevated, the surgeon can easily visualize the tail of the pancreas and avoid injury when placing the endo-vascular stapler within the sack and allows piecemeal extrac-tion; a blunt instrument should be used to disrupt and remove the spleen to avoid the risk of sack rupture, spillage of contents, and subsequent splenosis (Fig. 34-9 and Fig. 34-10).Hand-Assisted SplenectomyWhen LS is performed in patients with splenomegaly, there have been reports of high rates of both complications and con-version to open splenectomy.137 Hand-assisted laparoscopic surgery (HALS) has been described as an alternative to the LS approach.24,138,139 Spleens greater than 22 cm in craniocau-dal length or 19 cm in width may benefit from HALS over a purely laparoscopic approach.139 It has been reported that the Brunicardi_Ch34_p1517-p1548.indd 153423/02/19 2:37 PM 1535THE SPLEENCHAPTER 34Figure 34-8. Splenic hilum can be divided laparoscopically en masse once the spleen has been rotated medially having been mobi-lized from its lateral attachments.ABFigure 34-9. Spleen extraction. A. Spleen is placed into a ripstop nylon bag before morcellation. B. Splenic morcellation.use of this technique has resulted in a marked reduction in aver-age operative time for patients with massive splenomegaly (146 vs. 295 minutes). Although HALS does require a small incision (7–8 cm) for hand insertion and specimen extraction, no differences in length of stay were observed when comparing these patients to those managed purely laparoscopically.139When performing HALS splenectomy, patient position-ing is similar to that of LS (Fig. 34-11). For patients with mas-sive spleens, lateral positioning is altered slightly, such that the patient is placed supine with the left side elevated at 45°. Depending on the hand dominance of the surgeon, the hand-assist device can be placed in either a midline position for right-hand dominant or a subcostal position for left-hand dominant surgeons. A 7to 8-cm incision should be made 2 to 4 cm caudal to the inferior pole of the enlarged spleen. The hand-assisted technique allows for a tactile feedback and atraumatic manipu-lation of the enlarged spleen.The nondominant hand provides medial retraction and rotation of the spleen through a hand-assist port, while the domi-nant hand carries out the dissection using laparoscopic instru-ments. The anterior and posterior attachments of the spleen are taken down as in the laparoscopic approach, and the hilar pedicle is ligated using an endoscopic vascular stapler.Single-Incision Laparoscopic Surgery SplenectomySingle-incision laparoscopic surgery (SILS) splenectomy emphasizes the concept of surgery through one small transab-dominal incision rather than the standard multiple trocar sites, with theoretical benefits of less pain and better cosmetics. The incision can be hidden periumbilically and is used as the specimen extraction site at the end of the case. This approach for solid organs poses several technical challenges. Since all instruments are closely aligned together, “fencing” of instru-ments and the laparoscope and limited degrees of movement are commonly encountered. The spleen, being a solid organ, cannot be grasped, and thus retraction may be more challeng-ing in these cases. Furthermore, it has been reported that peri-umbilical port position may result in technical challenges when dealing with high body mass index or tall patients, precluding Brunicardi_Ch34_p1517-p1548.indd 153523/02/19 2:37 PM 1536SPECIFIC CONSIDERATIONSPART IIFigure 34-10. Morcellation and extraction of the spleen within nylon sac extending through the 10-mm trocar site. (Reproduced with per-mission from Park A, Marcaccio M, Sternbach M, et al: Laparoscopic vs open splenectomy, Arch Surg. 1999 Nov;134(11):1263-1269.)the surgeon from adequately reaching the spleen. Other alter-natives to single port placements have been reported, although to date, no proven benefits of SILS splenectomy have been demonstrated.140-142Robotic SplenectomyThe da Vinci surgical robot (Intuitive Surgical, Sunnyvale, CA) was cleared by the U.S. Food and Drug Administration (FDA) for use in humans in the year 2000 and has been applied to clinical practice in a variety of abdominal procedures includ-ing splenectomy since 2002.143,144 The term robotic surgery, referencing the da Vinci device should more accurately be described as computer assisted surgery (CAS), as it requires a surgeon sitting at a console controlling distant end effectors. A truly robotic, automated system has not yet been devised nor deployed to perform splenectomy. The reported advantages of CAS have inspired many surgeons to investigate its potential and to broaden its application in the minimally invasive surgery armamentarium. Some of these advantages include increased degrees of freedom as compared to standard “straight-stick” lap-aroscopy, improved optics including three-dimensional imag-ing of the operative field, improved instrument stabilization and reduction in hand tremor, and finally purported enhanced ergonomic and comfort factors for the operating surgeon.145-147 However, detractors of this emerging technology cite high capi-tal expenses as well as on-going disposable costs and the loss of haptic feedback as major downsides of CAS such that the benefits of the robotic platform are still not fully clear in the extant literature. Recent studies suggest that ergonomic ben-efits of robotic surgery may not be as pronounced as previously thought, as “robotic surgeons” still manifested chronic pain related to poor ergonomics.148There have been few published works comparing conven-tional laparoscopic splenectomy to CAS splenectomy. In one recent retrospective case-matched analysis, the authors com-pared hospital length of stay, operating room times and cost between these two groups. Although they were able to conclude that the application of CAS was feasible and safe for splenec-tomy, they cited a nearly 30-minute increase in operative time and over $4000 increase in cost of the procedures.149 This is consistent with a prior study supporting the notion that robotic-assisted splenectomy takes longer and is more costly than con-ventional laparoscopic surgery.150Splenectomy has also been reported using a single-incision CAS approach.151 However, this procedure is likely associated with an even steeper learning curve than traditional multiport robotic-assisted splenectomy, which calls into question the util-ity of this technique.Robotic splenectomy has been performed in the pediatric population, also proving feasibility and safety, but much like the adult population, larger series are needed to determine the true benefits of this procedure as compared to conventional laparo-scopic splenectomy in children.152The role of CAS in the patient requiring more complex surgery, for example, partial splenectomy or resection of a mas-sive spleen, is yet to be determined. At present there appears to be no argument supporting the application of CAS over standard laparoscopy for routine splenectomy in terms of clinical or cost advantage. The entry into the market of competing devices is likely to favorably alter these considerations.Partial SplenectomyThe past few decades have witnessed ever-widening endorse-ment for and practice of partial splenectomy. This technique, initially reported in the early 18th century, is particularly indi-cated to minimize the risk of postsplenectomy sepsis in children. Certain lipid storage disorders leading to splenomegaly (e.g., Gaucher’s disease), some forms of traumatic splenic injury (blunt and penetrating), spherocytosis in children, and focal benign splenic lesions are amenable to treatment with partial splenectomy.153 Both the laparoscopic and open approaches for partial splenectomy have been well described.153 The spleen must be adequately mobilized, and the splenic hilar vessels attached to the targeted segment, ligated, and divided. The devascularized segment of spleen is transected along an obvi-ous line of demarcation.A useful technical tip is to transect the parenchyma 1 cm inside the ischemic demarcation line to minimize blood loss.154 Bleeding from the cut surface of the spleen usually is limited and can be controlled by various methods, including cauter-ization, argon coagulation, or application of direct hemostatic agents such as cellulose gauze and fibrin glue.Inadvertent Intraoperative Splenic InjuryInadvertent intraoperative injury to the spleen is a noted occur-rence in the surgical literature, familiar to and dreaded by the abdominal surgeon. The true incidence is unknown. The gravity of such injury is not to be underestimated. Significant short-term morbidity is associated with injury to the spleen, including increased blood loss, need for transfusion, and pro-longed hospital stay.155Intraoperative injury to the spleen has been linked with numerous operations, such as gastric fundoplication, colectomy, Brunicardi_Ch34_p1517-p1548.indd 153623/02/19 2:37 PM 1537THE SPLEENCHAPTER 34BCAFigure 34-11. A. Patient table placement for hand-assisted laparoscopic splenectomy (HALS) in case of splenomegaly. B and C. Intraopera-tive images of HALS.Brunicardi_Ch34_p1517-p1548.indd 153723/02/19 2:37 PM 1538SPECIFIC CONSIDERATIONSPART IIparaesophageal hernia repair, nephrectomy, and abdominal and pelvic vascular surgery. There are also reports of splenic injuries after endoscopic procedures, such as colonoscopy.Improper traction on the spleen against its peritoneal attachments is the most common mechanism of intraopera-tive injury. Capsular tears are the most common type of injury, but parenchymal lacerations and subcapsular hematomas also occur. The lower pole is more commonly injured, owing to its orientation and the greater concentration of peritoneal attach-ments found here.As with all hemorrhage, prompt temporary control of bleeding should be obtained by direct compression of the spleen itself, packing of the left upper quadrant, compression of the vessels at the splenic hilum, or pressure on the splenic artery at the superior pancreatic margin. The spleen should then be mobi-lized from its peritoneal attachments and the nature of the injury assessed. Overall, the patient’s condition is the primary deter-minant of whether splenic salvage can be attempted, although hilar injury is best managed by splenectomy. When dealing with capsular tears (most common injury), strong consideration should be given to splenorrhaphy techniques: application of topical hemostatics, suture plication of disrupted parenchyma with or without omental buttress, and the use of bioabsorbable mesh sheets.The time-honored surgical tenets of liberal exposure and visualization are particularly germane to the avoidance of splenic injury. Incisions and approaches must be tailored to both patient circumstances and surgeon experience. There is some evidence to support the assertion that use of the lapa-roscopic approach may reduce the incidence of splenic injury for certain operations. As with all hemorrhage, prompt tempo-rary control of bleeding is required. Direct compression of the spleen itself, packing of the left upper quadrant, compression of the vessels at the splenic hilum, or pressure on the splenic artery at the superior pancreatic margin can slow or stop hem-orrhage and allow more deliberate consideration of manage-ment options.The type of injury plays a role as well; it has been sug-gested that hilar injury is best managed by splenectomy.80 Bar-ring these unfavorable circumstances, however, and recalling that the majority of intraoperative splenic injuries are capsular tears, it is reasonable to expect that splenic preservation can be achieved in many appropriately selected situations. Presented with one of these situations, the surgeon has at his or her dis-posal a number of useful and well-described splenorrhaphy techniques: application of topical hemostatics, suture plication of disrupted parenchyma with or without omental buttress, and the use of bioabsorbable mesh sheets.Currently, incidental splenectomies during laparoscopic procedures such as colorectal resections are rare events, but they are associated with worse short-term outcomes.156Preoperative Grading Score to Predict Technical Difficulty in Laparoscopic SplenectomyA splenectomy grading system based on preoperative parame-ters was developed to predict the surgical difficulty and morbid-ity for elective laparoscopic splenectomies.157,158 Preoperative data concerning demographic, clinical, pathological, anatomi-cal, laboratory and radiological factors were compared with three surgical outcomes: operative time, intraoperative bleeding, and surgical conversion. Four preoperative parameters (male Table 34-3Difficulty ScoreAge≤40 years040–60 years1≥60 years2GenderFemale0.5Male1Pathology groupITP0.5Other benign1Malignant2Spleen weighta<400 gr1400–1000 gr3>1000 gr5Difficulty gradeLow≤4Medium4–6High≥6Note: Minimum possible score: 2 points; maximum possible score: 10 points.aSpleen weight formula: width (cm) × length (cm) × height (cm) × 0.6 = splenic weight in grams.gender, age, type of pathology, and spleen weight) were found to be associated with a difficult splenectomy (Table 34-3). This grading score is simple to calculate from the physical examina-tion, laboratory tests, and US or CT images and could be highly practical in a daily clinical setting. It could facilitate training and development of skills while simultaneously fostering dissemina-tion of laparoscopic procedures.SPLENECTOMY OUTCOMESChanges in blood composition resulting from splenectomy include the appearance of Howell-Jolly bodies and siderocytes. After splenectomy, leukocytosis and increased platelet counts are common as well. Although platelet counts most often rise within 2 days, they may not peak for several weeks in patients with preoperative thrombocytopenia (see “Hematologic Out-comes” later). Similarly, within 1 day after splenectomy, the white blood cell count typically rises, and such elevation may continue for several months.Overwhelming Postsplenectomy InfectionThe prevalence of asplenia in the United States is estimated to be 1 million; which is comparable to the number of patients carrying the human immunodeficiency virus (HIV).185,186 As with other forms of immunodeficiency, asplenic patients bear an increased susceptibility to specific types of infections for the remainder of their lives. Asplenic patients are at highest risk for infection with encapsulated organisms, most commonly Streptococcus pneumoniae, but also Haemophilus influenza Brunicardi_Ch34_p1517-p1548.indd 153823/02/19 2:37 PM 1539THE SPLEENCHAPTER 34(in particular subtype B) and Neisseria meningitides.21,185-192 Although the overwhelming majority of splenectomized patients experience no ill consequence from the absence of their spleen, the potentially catastrophic consequences of overwhelming postsplenectomy infection (OPSI) demand lifelong vigilance and intimate knowledge of appropriate precautions and preven-tative measures.ComplicationsComplications of splenectomy may be classified as pulmonary, hemorrhagic, infectious, pancreatic, and thromboembolic.12,159 Left lower lobe atelectasis is the most common complication after OS; pleural effusion and pneumonia also can occur. Hem-orrhage can occur intraoperatively or postoperatively, present-ing as subphrenic hematoma. Transfusions have become less common since the advent of LS, although the indication for operation influences the likelihood of transfusion as well. Sub-phrenic abscess and wound infection are among the periopera-tive infectious complications. The placement of a drain in the left upper quadrant may be associated with postoperative sub-phrenic abscess and is not routinely recommended. Pancreati-tis, pseudocyst, and pancreatic fistula are among the pancreatic complications that may result from intraoperative trauma to the pancreas during dissection of the splenic hilum.Hematologic OutcomesThe results of splenectomy may be appraised according to the level of hematologic response (e.g., rise in platelet and hemo-globin levels) in those disorders in which the spleen contributes to the hematologic problem. Hematologic responses may be divided into initial and long-term responses. For thrombocyto-penia, an initial response typically is defined as a rise in plate-let count within several days of splenectomy. Reported series demonstrate the effectiveness of LS in providing a long-term platelet response in approximately 80% of individuals with ITP (Table 34-4). These results are consistent with the long-term success rate associated with OS.For chronic hemolytic anemias, a rise in hemoglobin levels to >10 g/dL without the need for transfusion signifies a successful response to splenectomy. By this criterion, splenec-tomy has been reported to be successful for the vast majority of patients with chronic hemolytic anemia. For hemolytic anemia due to spherocytosis, the success rate is usually higher, ranging from 90% to 100%.Splenectomy results also may be examined in terms of surgical and postsurgical characteristics, including operative time, recovery time, and morbidity and mortality rates, all of which tend to vary according to hematologic indication (see Tables 34-4 and 34-5).12Results of few prospective, randomized trials comparing LS and OS have been published. However, several recent meta-analyses of published comparative series including 38 papers with more than 2914 patients indicate that the laparoscopic approach typically results in longer operative times, shorter hos-pital stays, lower morbidity rates, similar blood loss, and similar mortality rates compared with OS.12,120,136 Questions of the cost effectiveness of LS persist, although analysis of this issue is hindered by a lack of universally accepted metrics as well as a paucity of recent objective data. Proponents of LS argue that the generally higher operating room charges are offset by the reduced hospital stay and presumably shorter time of lost productivity.160-162 For those institutions with experienced per-sonnel and technical capability, the laparoscopic approach has emerged as the standard for elective, nontraumatic splenectomy.CancerA Taiwanese population-based study found that individuals who had splenectomy have higher risks of developing certain types of cancer (adjusted hazard ratios were 2.64 and 1.29 for nontraumatic and traumatic reasons, respectively). Splenectomy patients were found to have significantly higher risks in esopha-gus, stomach, liver, other head and neck, non-Hodgkin’s lym-phoma, and leukemia cancers. Although the exact mechanism for the possible association between splenectomy and cancer remains unclear, a plausible explanation is that the spleen is thought to be involved in immunological defenses and provides active response through humoral and cell-mediated pathways and that splenectomy may impair immune surveillance in the host.163,164Table 34-4Outcome after splenectomyOUTCOME VARIABLESTUDIES (N)PATIENTS (N)POOLED RESULTS AND CIPMortality382914–0.01 (–0–02, 0)1Complications Pooled382914–0.11 (–0.16, –0.05)<.00001 Minor362914–0.03 (–0.05, –0.01).13 Severe362745–0.07 (–0.11, –0.03)<.00001 Thrombosis352695–0.01 (–0.02, 0.01)1 Organ injury3426390.01 (–0, 0.02)1Acces. spleen2921350.02 (–0.01, 0.05).87Operative time18137057.4 min (43.3, 71.4)<.00001Blood loss10759–41 mL (–87, 4.71)<.00001Length of stay201566–2.48 d (–2.89, –2.07)<.00001Reproduced with permission from Bai YN, Jiang H, Prasoon P. A meta-analysis of perioperative outcomes of laparoscopic splenectomy for hematological diseases, World J Surg. 2012 Oct;36(10):2349-2345.Brunicardi_Ch34_p1517-p1548.indd 153923/02/19 2:37 PM 1540SPECIFIC CONSIDERATIONSPART IIUltrasoundUltrasound is the least invasive mode of splenic imaging. It is rapid, relatively easy to perform, and does not expose the patient to ionizing radiation. It is often the first imaging modality used to evaluate the spleen in a trauma patient, although questions of sensitivity and specificity remain.133,167 In the elective setting, such as for routine diagnostic purposes or for preoperative plan-ning, it is the least costly modality available, and the sensitivity of ultrasound for detecting textural lesions of the spleen can be quite good in experienced hands.168When examining a normal spleen, differentiation between red and white pulp is not possible, and a homogeneous acous-tic echotexture should be visualized. Splenic artery and vein patency may be assessed using Doppler imaging. Splenic artery anatomy has been classified commonly into two patterns: dis-tributed and magistral. This variability in vascular distribution visualized by Doppler imaging becomes important when there is consideration of performing a partial splenectomy due to the possibility of segmental blood flow and its effect on area of resection.Percutaneous ultrasound-guided procedures for splenic disease (e.g., cyst aspiration, biopsy), historically avoided due to the risk of hemorrhage and other complications, are becom-ing more common as the safety of these procedures has become increasingly demonstrated.165,166Computed TomographyCT affords a high degree of resolution and detail of the splenic parenchyma, vasculature, and its relationship to neighboring structures, making it the preferred imaging modality for many surgeons. CT has become an invaluable tool in the evaluation and management of the blunt trauma patient, and standardized scoring systems for splenic trauma based on CT images now aid in management decisions.169 In the nontrauma setting, CT is extremely useful for assessment of splenomegaly, identification of solid and cystic lesions, and guidance of percutaneous pro-cedures.3 The use of iodinated contrast material adds diagnostic clarity to CT imaging of the spleen, although at the cost of, the small but real risks, possible renal impairment or allergic reac-tions. Three-dimensional reconstruction after CT scan may help to predict the difficulty of the procedure and to choose the best surgical approach.170,171The appearance of normal splenic tissue on a noncon-trast CT is uniform parenchymal attenuation with values ranging between 40 and 60 Hounsfield units (HU).172 On a contrast-enhanced CT, the appearance of the spleen depends largely on the timing of the intravenous bolus administration of contrast material. Due to the different rates of flow through the red and white pulp, the spleen appears heterogeneously enhanc-ing during the first minute after initiation of intravenous admin-istration of contrast material during the arterial and early portal venous phases.23 The frequency of these artifacts increases with advancing patient age. When evaluating for splenic abscess, a contrast-enhanced CT should be utilized.64,173Three-dimensional CT volumetry is a novel modality that measures the volume of the spleen. This tool may be of some benefit in planning technically challenging cases involving sple-nomegaly. A recent retrospective review of laparoscopic sple-nectomy patients who underwent CT volumetry preoperatively demonstrated a higher conversion rate when the spleen was measured to be greater than 2700 cc.170 This information may aid in proper informed consent as well as preoperative planning to assist in determination of which patients may benefit from a minimally invasive or open surgical approach.139Plain RadiographyRarely is plain radiography used for primary splenic imaging. Plain films can indirectly provide an outline of the spleen in the left upper quadrant or suggest splenomegaly by revealing dis-placement of adjacent air-filled structures (e.g., the stomach or splenic flexure of the colon). Plain films may also demonstrate splenic calcifications. Splenic calcifications often are found in association with splenomegaly but are otherwise a nonspe-cific finding. Splenic calcifications can indicate a number of benign, neoplastic, or infectious processes, including phlebo-lith, splenic artery aneurysm, sickle cell changes, tumors (e.g., hemangioma, hemangiosarcoma, lymphoma), echinococcosis, or tuberculosis.168Magnetic Resonance ImagingAlthough MRI offers excellent detail and versatility in abdomi-nal imaging, it is more expensive than CT scan or ultrasound and offers no obvious advantage for primary imaging of the spleen. MRI can be a valuable adjunct to the more commonly used imaging techniques when splenic disease is suspected but not definitively diagnosed.168,173Magnetic resonance (MR) signal characteristics of the spleen are related to the relative ratio of red and white pulp and the relationship of the timing of the intravenous (IV) contrast bolus and the time of image acquisition. The spleen will gener-ally have a homogeneous MR signal on noncontrast images. Table 34-5Laparoscopic splenectomy results by hematologic indicationITP (N = 151)TTP (N = 7)ANEMIA (N = 40)MALIGNANCY (N = 28)OR time (min)128146149165EBL (mL)13796116238LOS (days)2.23.02.22.6Conversions from LS to OS3 (2%)1 (14%)1 (3%)1 (4%)Complications14 (9%)01 (3%)3 (11%)EBL = estimated blood loss; ITP = idiopathic thrombocytopenic purpura; LOS = length of hospital stay; LS = laparoscopic splenectomy; OR = operating room; OS = open splenectomy; TTP = thrombotic thrombocytopenic purpura.Data from Brunicardi FC, Andersen DK, Billiar TR, et al: Schwartz’s Principles of Surgery, 8th ed. New York, NY: McGraw-Hill; 2005.Brunicardi_Ch34_p1517-p1548.indd 154023/02/19 2:37 PM 1541THE SPLEENCHAPTER 34On contrast MRI, the spleen appears to have heterogeneous enhancement during the arterial phase of contrast enhancement.AngiographyAngiography of the spleen most commonly refers to inva-sive arterial imaging, and when it is combined with thera-peutic splenic arterial embolization (SAE), there are multiple applications for this procedure: localization and treatment of hemorrhage in select trauma patients; delivery of a variety of therapies in patients with cirrhosis or portal and sinistral hyper-tension and in transplant patients; and adjunct (or, more con-troversially, as an alternative) to splenectomy for treatment of hematologic disorders such as ITP or hypersplenism.174-176 Preoperative or intraoperative SAE for elective splenectomy is also a common, although not universal, practice. Few pro-spective data have been published in the last 5 years on pre-operative SAE.177 Preoperative SAE is purported not only to facilitate less intraoperative blood loss but also possibly to allow a laparoscopic approach in patients whose spleens had previ-ously been considered too large for, or otherwise not amenable to, safe laparoscopic resection. Limited success in using partial SAE as an alternative to therapeutic splenectomy in chronic ITP has been previously reported.178 Its detractors argue that the need for increased analgesics and occasional extended hospital stay preoperatively, the possibility of pancreatitis, and the well-described risks of invasive arteriography associated with the passage of wires and catheters through the vasculature, may negate any presumed benefits of preoperative SAE.Nuclear ImagingRadioscintigraphy with technetium-99m sulfur colloid demon-strates splenic location and size. It may be especially helpful in locating accessory spleens after unsuccessful splenectomy for ITP and has recently proven useful in diagnosing splenosis.179,180 Unfortunately, no conclusive outcome benefit has been shown for preoperative technetium scanning before splenectomy.52,181 When dealing with diseases of platelet sequestration, indium-labeled autologous platelet scanning (ILAPS) demonstrates whether platelet sequestration is predominantly in the spleen, liver, or both. This becomes important in deciding whether or not a patient will benefit from a splenectomy. ILAPS is a nuclear imaging modality in which autologous platelets are reinfused into the patient after ex vivo labeling. Subsequent scintigraphy demonstrates the site(s) of platelet sequestration and clearance. It has been proposed that patients with purely or predominantly splenic sequestration determined by ILAPS may be more likely to respond to splenectomy than those exhibiting hepatic, mixed, or diffuse patterns.176An emerging and novel application for spleen scintigraphy may be as a noninvasive method to diagnose nonalcoholic ste-atohepatitis (NASH). Conventional imaging methods are reli-able for the detection of moderate to severe fatty changes in the liver, though they are not reliable for detecting NASH or hepatic fibrosis. NASH, which may lead to cirrhosis, can result from nonalcoholic fatty liver disease (NAFLD), the most common cause of steatosis. With the alarming rise of obesity worldwide, NAFLD is also increasingly common with prevalence rang-ing from 6.3% to 33%.15,182 The diagnosis of progression from NAFLD to NASH has been dependent on histologic assessment of tissue obtained from liver biopsy. Characteristics unique to NASH have been reported, among them the association of splenic enlargement, not seen to a similar degree in NAFLD.13In addition, the ratio of liver-to-spleen uptake determined by scintigraphy has been found to be predictably altered in NASH patients. The liver-to-spleen uptake ratio is significantly decreased in NASH patients, but not NAFLD patients, leading some to conclude that technetium-99m-phytate scintigraphy is a reliable tool to differentiate NASH from NAFLD.183 Although additional studies are needed to identify the role of these nuclear medicine studies in prognostication and monitoring of those patients at high risk for the development of NASH, recent stud-ies show promise in this regard.184Microbiology and Pathogenesis. Life-threatening infec-tion in the asplenic patient is attributable to four main factors: loss of splenic macrophages, diminished tuftsin production, loss of the spleen’s reticuloendothelial screening function, and dysregulated coagulation.187 In the normal host, these factors work in concert to eliminate opsonized bacteria from the blood-stream. This system is particularly suited for the removal of encapsulated bacteria, whose polysaccharide coating is a natu-ral defense against opsonization (S pneumoniae, H influenzae, and N meningitidis are the classic examples). Infections with protozoa that invade the red blood cell, such as Babesia microti (transmitted by tick bites), Ehrlichia, and Plasmodium, occur more frequently in splenectomized individuals than in normal hosts. Other potential infectious bacterial sources include group A streptococci, C canimorsus (transmitted by dog bites), group B streptococci, Enterococcus species, Bacteroides species, Salmonella species, and Bartonella species.124 In the absence of the spleen, elimination of these pathogens from the bloodstream falls solely to the liver, a process that has been demonstrated to be less effective.12,126 Further, the pathophysiology of infection in asplenic patients has also been implicated in their increased risk of thrombosis and pulmonary hypertension.187More recently, the bacterial patterns of splenectomy sepsis have been changing. After the introduction of vaccinations and new oral antibiotics, postsplenectomy patients can suffer from diverse strains of bacterial infection, which are not strictly cor-related with the splenic function. In recent cohort series, gram negative bacteria are prevalent, representing 45% to 50% of infections in asplenic patients.193,194 In vaccinated patients, the rate of sepsis by pneumococcus is very low. In fact, encapsulated bacteria, such as S pneumoniae, N meningitidis, and H influenzae, were rarely encountered in those series in whom vaccination was routinely adopted.193-196Sepsis by uncommon bacteria as well by protozoa infec-tions such as malaria and babesiosis are also known to affect asplenic patients.196-200Clinical Features. OPSI is uniformly fatal without treat-ment, and thus sepsis in a splenectomized patient is a medical emergency.21,187,192 Therefore, any clinical suggestion of infec-tion, including seemingly isolated fevers, must be viewed with a high index of suspicion and treated empirically as thorough investigation proceeds. OPSI may begin with a relatively mild-appearing prodrome of symptoms. In addition to fever, nonspe-cific symptoms such as malaise, myalgias, headache, vomiting, diarrhea, abdominal pain, and others should be viewed with alarm in the asplenic patient. This process can progress rapidly to fulminant bacteremic septic shock, with hypotension, anuria, and disseminated intravascular coagulation.The true incidence of OPSI is not precisely known because defining criteria vary among published series. Overall lifetime risk remains low, ranging from <1% to 5%.12,21,126,201 Among 9Brunicardi_Ch34_p1517-p1548.indd 154123/02/19 2:37 PM 1542SPECIFIC CONSIDERATIONSPART IIthose who develop OPSI, some characteristics can be identified that impart greater risk. Reason for splenectomy is the single most influential determinant of OPSI risk. Case series demon-strate that those who undergo splenectomy for hematologic dis-ease (malignancy, myelodysplasia, or hemoglobinopathy) are far more susceptible to OPSI than patients who undergo sple-nectomy for trauma or iatrogenic reasons. Age is also an impor-tant consideration, with children 5 years of age or less and adults 50 years or older being at elevated risk. Finally, time interval from spleen removal must be considered. A large number of OPSI cases occur many years to decades after splenectomy.186,189 This observation underscores both the threat of this lethal dis-ease and the need for lifelong vigilance.Antibiotics and the Asplenic Patient. Antibiotic therapy for the asplenic patient can be considered in three contexts: therapy for established or presumed infections, prophylaxis in anticipation of invasive procedures (e.g., dental procedures), and general prophylaxis. The most critical action in the treat-ment of established or presumed OPSI is the immediate use of broad-spectrum intravenous antibiotics, ideally after the collec-tion of blood cultures. Vancomycin provides broad-spectrum Gram-positive coverage, including coverage against penicillin-resistant S pneumonia.190 Ceftriaxone should be added to include Gram-negative coverage for N meningitidis and H influenza.190 Early implementation of antibiotics and goal-directed therapy for sepsis can significant reduce mortality rates.21,191 For the lat-ter two indications, unfortunately, evidence supporting efficacy is scant, and guidelines for antibiotic prophylaxis are not uni-form. Optimal duration of chemoprophylaxis in children also remains unclear; however, a daily dose of antibiotics until 5 years of age or at least 5 years after splenectomy are commonly recommended, although some advocate continuation into at least early adulthood.121,122,192 Concerns regarding compliance and bacterial resistance have been raised, which have led some authors to suggest that lifelong daily antibiotic prophylaxis be recommended only for those patients whose antibody titers fail to respond appropriately to vaccination or, alternately, that asplenic patients be advised to carry at all times a reserve sup-ply of antibiotic to be self-administered at the earliest sign of infection.122 Considering the grave consequences of OPSI and its relatively low incidence, controlled trials resulting in mean-ingful data on this issue seem unlikely to be performed.Education. Several risk management strategies are com-monly recommended to patients following splenectomy, including wearing a medical bracelet, carrying a laminated medical alert card, possessing a medical letter with specific empiric therapy instructions (including drug names and dos-ages), and keeping a 5-day supply of standby antibiotics, par-ticularly when travel is anticipated.187,189 The need for a high index of suspicion, prompt action, and aggressive education of the patient, family, and medical providers cannot be overstated in asplenic patients.REFERENCESEntries highlighted in bright blue are key references. 1. Moynihan B. The surgery of the spleen. Br J Surg. 1921 Jan 22; 1(3134):114-6. 2. McClusky DA, 3rd, Skandalakis LJ, Colborn GL, Skandalakis JE. Tribute to a triad: history of splenic anatomy, physiology, and surgery—part 1. World J Surg. 1999;23(3):311-325. 3. McClusky DA, 3rd, Skandalakis LJ, Colborn GL, Skandalakis JE. Tribute to a triad: history of splenic anatomy, physiology, and surgery-part 2. World J Surg. 1999;23(5):514-526. 4. Aristotle. De Paribus Animalium [On the Parts of Animals]. Cambridge: Harvard University Press; 1961. 5. Garfield E. Citation indexes for science; a new dimension in documentation through association of ideas. Science. 1955;122(3159):108-111. 6. Cameron BD. Trends in the usage of ISI bibliometric data: uses, abuses, and implications. Libraries and the Academy. 2005;5(1):105-125. 7. Foster M. Lectures on the History of Physiology During the Sixteenth, Seventeenth, and Eighteenth Centuries. Vol 164. Cambridge: Cambridge University Press; 1901. 8. Wilkins BS. The spleen. Br J Haematol. 2002;117(2):265-274. 9. Morgenstern L. A history of splenectomy. In: Hiatt JR, Phillips EH, Morgenstern L, eds. Surgical Disease of the Spleen. New York: Springer; 1997. 10. Gray H. On the Structure and Use of the Spleen. London: J.W. Parker and Son; 1854. 11. Bryant T. Case of excision of the spleen for an enlargement of the organ, attended with leucocythaemia, with remarks. Guys Hosp Rep. 1867;13(412). 12. Bickenbach KA, Gonen M, Labow DM, et al. Indications for and efficacy of splenectomy for haematological disorders. Br J Surg. 2013;100(6):794-800. 13. Musallam KM, Khalife M, Sfeir PM, et al. Postoperative out-comes after laparoscopic splenectomy compared with open splenectomy. Ann Surg. 2013;257(6):1116-1123. 14. Mebius RE, Kraal G. Structure and function of the spleen. Nat Rev Immunol. 2005;5(8):606-616. 15. Tarantino G, Savastano S, Capone D, Colao A. Spleen: a new role for an old player? World J Gastroenterol. 2011;17(33):3776-3784. 16. Morgenstern L, Skandalakis JE. Anatomy and embryology of the spleen. In: Hiatt JR, Phillips EH, Morgenstern L, eds. Surgical Diseases of the Spleen. Vol 15. Berlin/Heidelberg: Springer-Verlag; 1997. 17. Magowska A. Wandering spleen: a medical enigma, its natural history and rationalization. World J Surg. 2013;37(3):545-550. 18. Bratosin D, Mazurier J, Tissier JP, et al. Cellular and molecular mechanisms of senescent erythrocyte phagocytosis by macro-phages. A review. Biochimie. 1998;80(2):173-195. 19. Knutson M, Wessling-Resnick M. Iron metabolism in the reticuloendothelial system. Crit Rev Biochem Mol Biol. 2003;38(1):61-88. 20. Nolte MA, Belien JA, Schadee-Eestermans I, et al. A con-duit system distributes chemokines and small blood-borne molecules through the splenic white pulp. J Exp Med. 2003;198(3):505-512. 21. Di Sabatino A, Carsetti R, Corazza GR. Post-splenectomy and hyposplenic states. Lancet. 2011;378(9785):86-97. 22. Spelman D, Buttery J, Daley A, et al. Guidelines for the pre-vention of sepsis in asplenic and hyposplenic patients. Intern Med J. 2008;38(5):349-356. 23. Davies JM, Lewis MP, Wimperis J, et al. Review of guidelines for the prevention and treatment of infection in patients with an absent or dysfunctional spleen: prepared on behalf of the British Committee for Standards in Haematology by a work-ing party of the Haemato-Oncology task force. Br J Haematol. 2011;155(3):308-317. 24. Habermalz B, Sauerland S, Decker G, et al. Laparoscopic splenectomy: the clinical practice guidelines of the European Association for Endoscopic Surgery (EAES). Surg Endosc. 2008;22(4):821-848. 25. Pozo AL, Godfrey EM, Bowles KM. Splenomegaly: investigation, diagnosis and management. Blood Rev. 2009;23(3):105-111.Brunicardi_Ch34_p1517-p1548.indd 154223/02/19 2:37 PM 1543THE SPLEENCHAPTER 34 26. Iolascon A, Andolfo I, Barcellini W, et al. Recommendations regarding splenectomy in hereditary hemolytic anemias. Haematologica. 2017;102(8):1304-1313. 27. Schilling RF. Risks and benefits of splenectomy versus no splenectomy for hereditary spherocytosis—a personal view. Br J Haematol. 2009;145(6):728-732. 28. Barcellini W, Bianchi P, Fermo E, et al. Hereditary red cell membrane defects: diagnostic and clinical aspects. Blood Transfus. 2011;9(3):274-277. 29. Casale M, Perrotta S. Splenectomy for hereditary spherocy-tosis: complete, partial or not at all? Expert Rev Hematol. 2011;4(6):627-635. 30. Prchal JT, Gregg XT. Red cell enzymopathies. In: Hoffman R, ed. Hematology: Basic Principles and Practice. Vol 561. 3rd ed. New York: Churchill Livingstone; 2001. 31. Grace RF, Zanella A, Neufeld EJ, et al. Erythrocyte pyru-vate kinase deficiency: 2015 status report. Am J Hematol. 2015;90(9):825-830. 32. Beutler E, Gelbart T. Estimating the prevalence of pyruvate kinase deficiency from the gene frequency in the general white population. Blood. 2000;95(11):3585-3588. 33. Carey PJ, Chandler J, Hendrick A, et al. Prevalence of pyru-vate kinase deficiency in northern European population in the north of England. Northern Region Haematologists Group. Blood. 2000;96(12):4005-4006. 34. Hamilton JW, Jones FG, McMullin MF. Glucose-6phosphate dehydrogenase Guadalajara—a case of chronic non-spherocytic haemolytic anaemia responding to splenec-tomy and the role of splenectomy in this disorder. Hematology. 2004;9(4):307-309. 35. Michel M. Classification and therapeutic approaches in auto-immune hemolytic anemia: an update. Expert Rev Hematol. 2011;4(6):607-618. 36. Giudice V, Rosamilio R, Ferrara I, Seneca E, Serio B, Selleri C. Efficacy and safety of splenectomy in adult autoimmune hemolytic anemia. Open Med (Wars). 2016;11(1):374-380. 37. Hill J, Walsh RM, McHam S, Brody F, Kalaycio M. Lapa-roscopic splenectomy for autoimmune hemolytic anemia in patients with chronic lymphocytic leukemia: a case series and review of the literature. Am J Hematol. 2004;75(3):134-138. 38. Plikat K, Rogler G, Scholmerich J. Coombs-positive autoim-mune hemolytic anemia in Crohn’s disease. Eur J Gastroen-terol Hepatol. 2005;17(6):661-666. 39. Rigal D, Meyer F. Autoimmune haemolytic anemia: diagnosis strategy and new treatments (in French). Transfus Clin Biol. 2011;18(2):277-285. 40. Rees DC, Williams TN, Gladwin MT. Sickle-cell disease. Lancet. 2010;376(9757):2018-2031. 41. Rice HE, Englum BR, Rothman J, et al. Clinical outcomes of splenectomy in children: report of the splenectomy in congenital hemolytic anemia registry. Am J Hematol. 2015;90(3):187-192. 42. Al-Salem AH. Indications and complications of splenec-tomy for children with sickle cell disease. J Pediatr Surg. 2006;41(11):1909-1915. 43. Rachmilewitz EA, Giardina PJ. How I treat thalassemia. Blood. 2011;118(13):3479-3488. 44. Phrommintikul A, Sukonthasarn A, Kanjanavanit R, Nawarawong W. Splenectomy: a strong risk factor for pul-monary hypertension in patients with thalassaemia. Heart. 2006;92(10):1467-1472. 45. Sheikha AK, Salih ZT, Kasnazan KH, et al. Prevention of overwhelming postsplenectomy infection in thalassemia patients by partial rather than total splenectomy. Can J Surg. 2007;50(5):382-386. 46. Dedeoglu S, Bornaun H. Pulmonary hypertension in chil-dren with beta thalassemia major, are splenectomy and high-ferritin levels related or not? J Pediatr Hematol Oncol. 2017;39(4):259-265. 47. Cines DB, Blanchette VS. Immune thrombocytopenic purpura. N Engl J Med. 2002;346(13):995-1008. 48. George JN. Sequence of treatments for adults with primary immune thrombocytopenia. Am J Hematol. 2012;87(suppl 1): S12-S15. 49. Rodeghiero F, Besalduch J, Michel M, Provan D, Grotzinger K, Thompson G. Treatment practices in adults with chronic immune thrombocytopenia—a European perspective. Eur J Haematol. 2010;84(2):160-168. 50. Auger S, Duny Y, Rossi JF, Quittet P. Rituximab before splenectomy in adults with primary idiopathic thrombo-cytopenic purpura: a meta-analysis. Br J Haematol. 2012; 158(3):386-398. 51. Kojouri K, Vesely SK, Terrell DR, George JN. Splenectomy for adult patients with idiopathic thrombocytopenic purpura: a systematic review to assess long-term platelet count responses, prediction of response, and surgical complications. Blood. 2004;104(9):2623-2634. 52. Mikhael J, Northridge K, Lindquist K, Kessler C, Deuson R, Danese M. Short-term and long-term failure of laparoscopic splenectomy in adult immune thrombocyto-penic purpura patients: a systematic review. Am J Hematol. 2009;84(11):743-748. 53. Szold A, Kais H, Keidar A, Nadav L, Eldor A, Klausner JM. Chronic idiopathic thrombocytopenic purpura (ITP) is a surgi-cal disease. Surg Endosc. 2002;16(1):155-158. 54. Keidar A, Feldman M, Szold A. Analysis of outcome of laparoscopic splenectomy for idiopathic thrombocyto-penic purpura by platelet count. Am J Hematol. 2005; 80(2):95-100. 55. Tada K, Ohta M, Saga K, et al. Long-term outcomes of lapa-roscopic versus open splenectomy for immune thrombocyto-penia. Surg Today. 2018;48(2):180-185. 56. Guan Y, Wang S, Xue F, et al. Long-term results of splenec-tomy in adult chronic immune thrombocytopenia. Eur J Haematol. 2017;98(3):235-241. 57. Ahmed R, Devasia AJ, Viswabandya A, et al. Long-term outcome following splenectomy for chronic and persistent immune thrombocytopenia (ITP) in adults and children: sple-nectomy in ITP. Ann Hematol. 2016;95(9):1429-1434. 58. Dubois L, Gray DK. Case series: splenectomy: does it still play a role in the management of thrombotic thrombocytope-nic purpura? Can J Surg. 2010;53(5):349-355. 59. Targarona EM. Spleen, hematological disorders. In: Matteotti R, Becker JM, Ashley SM, eds. Minimally Invasive Surgical Oncology: State-of-the-Art Cancer Management. New York: Springer Verlag; 2011. 60. Joly BS, Coppo P, Veyradier A. Thrombotic thrombocytopenic purpura. Blood. 2017;129(21):2836-2846. 61. Townsend W, Linch D. Hodgkin’s lymphoma in adults. Lancet. 2012;380(9844):836-847. 62. Shankland KR, Armitage JO, Hancock BW. Non-Hodgkin lymphoma. Lancet. 2012;380(9844):848-857. 63. Habermann TM, Rai K. Historical treatments of in hairy cell leukemia, splenectomy and interferon: past and current uses. Leuk Lymphoma. 2011;52(suppl 2):18-20. 64. Chow KU, Luxembourg B, Seifried E, Bonig H. Spleen Size is Significantly Influenced by Body Height and Sex: Estab-lishment of Normal Values for Spleen Size at US with a Cohort of 1200 Healthy Individuals. Radiology, 2016;279(1): 306-313. 65. Casaccia M, Torelli P, Cavaliere D, et al. Laparoscopic lymph node biopsy in intra-abdominal lymphoma: high diagnostic accuracy achieved with a minimally invasive pro-cedure. Surg Laparosc Endosc Percutan Tech. 2007;17(3): 175-178. 66. Thompson PA, Ravandi F. How I manage patients with hairy cell leukaemia. Br J Haematol. 2017;177(4):543-556.Brunicardi_Ch34_p1517-p1548.indd 154323/02/19 2:37 PM 1544SPECIFIC CONSIDERATIONSPART II 67. Shanshal M, Haddad RY. Chronic lymphocytic leukemia. Dis Mon. 2012;58(4):153-167. 68. Bennett M, Schechter GP. Treatment of splenic marginal zone lymphoma: splenectomy versus rituximab. Semin Hematol. 2010;47(2):143-147. 69. Matutes E, Oscier D, Montalban C, et al. Splenic marginal zone lymphoma proposals for a revision of diagnostic, staging and therapeutic criteria. Leukemia. 2008;22(3):487-495. 70. Misiakos EP, Bagias G, Liakakos T, Machairas A. Laparo-scopic splenectomy: current concepts. World J Gastrointest Endosc. 2017;9(9):428-437. 71. Weledji EP, Orock GE. Surgery for non-Hodgkin’s lymphoma. Oncol Rev. 2015;9(1):274. 72. Weledji EP. Benefits and risks of splenectomy. Int J Surg. 2014;12(2):113-119. 73. Ferrara F, Schiffer CA. Acute myeloid leukaemia in adults. Lancet. 2013;381(9865):484-495. 74. Jabbour E, Kantarjian H. Chronic myeloid leukemia: 2012 update on diagnosis, monitoring, and management. Am J Hematol. 2012;87(11):1037-1045. 75. Tefferi A. Polycythemia vera and essential thrombocythemia: 2012 update on diagnosis, risk stratification, and management. Am J Hematol. 2012;87(3):285-293. 76. Logan MS, Watson CM, Nottingham JM. Symptomatic sple-nomegaly in polycythemia vera: a review of the indications for splenectomy and perioperative considerations. Am Surg. 2009;75(5):363-368. 77. Tefferi A. How I treat myelofibrosis. Blood. 2011;117(13): 3494-3504. 78. Mesa R. Myeloproliferative disorder-associated massive sple-nomegaly. Clin Adv Hematol Oncol. 2008;6(4):278, 281-272. 79. Cervantes F. Myelofibrosis: biology and treatment options. Eur J Haematol Suppl. 2007;(68):13-17. 80. Mesa RA, Nagorney DS, Schwager S, Allred J, Tefferi A. Palliative goals, patient selection, and perioperative platelet management: outcomes and lessons from 3 decades of sple-nectomy for myelofibrosis with myeloid metaplasia at the Mayo Clinic. Cancer. 2006;107(2):361-370. 81. Lopez Monclova J, Targarona Soler E, Peraza Solis Y, et al. Laparoscopic approach for isolated splenic metastasis: com-prehensive literature review and report of 6 cases. Surg Lapa-rosc Endosc Percutan Tech. 2013;23(1):21-24. 82. Gatenby PA, Mudan SS, Wotherspoon AC. Splenectomy for non-haematological metastatic malignant disease. Langen-becks Arch Surg. 2011;396(5):625-638. 83. Cox TM, Aerts JM, Belmatoug N, et al. Management of non-neuronopathic Gaucher disease with special reference to pregnancy, splenectomy, bisphosphonate therapy, use of bio-markers and bone disease monitoring. J Inherit Metab Dis. 2008;31(3):319-336. 84. Lee WS, Choi ST, Kim KK. Splenic abscess: a single insti-tution study and review of the literature. Yonsei Med J. 2011;52(2):288-292. 85. Divyashree S, Gupta N. Splenic abscess in immunocompetent patients managed primarily without splenectomy: a series of 7 cases. Perm J. 2017;21:16-139. 86. Comitalo JB. Laparoscopic treatment of splenic cysts. JSLS. 2001;5(4):313-316. 87. Chun CH, Raff MJ, Contreras L, et al. Splenic abscess. Medicine (Baltimore). 1980;59(1):50-65. 88. Nelken N, Ignatius J, Skinner M, Christensen N. Changing clinical spectrum of splenic abscess. A multicenter study and review of the literature. Am J Surg. 1987;154(1):27-34. 89. Ooi LL, Leong SS. Splenic abscesses from 1987 to 1995. Am J Surg. 1997;174(1):87-93. 90. Choudhury SR, Debnath PR, Jain P, et al. Conservative man-agement of isolated splenic abscess in children. J Pediatr Surg. 2010;45(2):372-375. 91. Neumayr A, Troia G, de Bernardis C, et al. Justified concern or exaggerated fear: the risk of anaphylaxis in percutaneous treat-ment of cystic echinococcosis-a systematic literature review. PLoS Negl Trop Dis. 2011;5(6):e1154. 92. Ingle SB, Hinge Ingle CR, Patrike S. Epithelial cysts of the spleen: a minireview. World J Gastroenterol. 2014;20(38):13899-13903. 93. Guggenbuhl P, Grosbois B, Chales G. Gaucher disease. Joint Bone Spine. 2008;75(2):116-124. 94. Xiao GQ, Zinberg JM, Unger PD. Asymptomatic sar-coidosis presenting as massive splenomegaly. Am J Med. 2002;113(8):698-699. 95. Zimran A, Belmatoug N, Bembi B, et al. Demographics and patient characteristics of 1209 patients with Gaucher dis-ease: descriptive analysis from the Gaucher Outcome Survey (GOS). Am J Hematol. 2018;93(2):205-212. 96. Kapoor P, Singh E, Radhakrishnan P, Mehta P. Splenectomy in plasma cell dyscrasias: a review of the clinical practice. Am J Hematol. 2006;81(12):946-954. 97. Fordice J, Katras T, Jackson RE, et al. Massive splenomegaly in sarcoidosis. South Med J. 1992;85(7):775-778. 98. Bachmeyer C, Fayand A, Georgin-Lavialle S, et al. Mas-sive splenomegaly indicating sarcoidosis. Am J Med. 2017;130(4):e141-e142. 99. Obuchi T, Sasaki A, Nakajima J, Nitta H, Otsuka K, Wakabayashi G. Laparoscopic surgery for splenic artery aneu-rysm. Surg Laparosc Endosc Percutan Tech. 2009;19(4):338-340. 100. Sadat U, Dar O, Walsh S, Varty K. Splenic artery aneu-rysms in pregnancy—a systematic review. Int J Surg. 2008;6(3):261-265. 101. Harmanci O, Bayraktar Y. Clinical characteristics of idiopathic portal hypertension. World J Gastroenterol. 2007;13(13):1906-1911. 102. Romano M, Giojelli A, Capuano G, Pomponi D, Salvatore M. Partial splenic embolization in patients with idiopathic portal hypertension. Eur J Radiol. 2004;49(3):268-273. 103. Boyer JL, Sen Gupta KP, Biswas SK, et al. Idiopathic por-tal hypertension. Comparison with the portal hypertension of cirrhosis and extrahepatic portal vein obstruction. Ann Intern Med. 1967;66(1):41-68. 104. Okuda K, Nakashima T, Okudaira M, et al. Anatomical basis of hepatic venographic alterations in idiopathic portal hyper-tension. Liver. 1981;1(4):255-263. 105. Ozturk O, Eldem G, Peynircioglu B, et al. Outcomes of partial splenic embolization in patients with massive splenomegaly due to idiopathic portal hypertension. World J Gastroenterol. 2016;22(43):9623-9630. 106. Puksic S, Mitrovic J, Morovic-Vergles J. Rituximab: a safe treatment in a patient with refractory felty syndrome and recurrent infections. J Clin Rheumatol. 2017;23(1):70-71. 107. Narvaez J, Domingo-Domenech E, Gomez-Vaquero C, et al. Biological agents in the management of Felty’s syn-drome: a systematic review. Semin Arthritis Rheum. 2012;41(5): 658-668. 108. Rashba EJ, Rowe JM, Packman CH. Treatment of the neutro-penia of Felty syndrome. Blood Rev. 1996;10(3):177-184. 109. Singh S, Raidoo S, Kuo K, Resnick K. Wandering spleen. A case of spontaneous hemoperitoneum in an HIV-positive patient with recurrent tuboovarian abscess. J Reprod Med. 2015;60(7-8):359-361. 110. Montenovo MI, Ahad S, Oelschlager BK. Laparoscopic splenopexy for wandering spleen: case report and review of the literature. Surg Laparosc Endosc Percutan Tech. 2010;20(5):e182-184. 111. Morgenstern L, Shapiro SJ. Techniques of splenic conserva-tion. Arch Surg. 1979;114(4):449-454. 112. Uranus S, Pfeifer J, Schauer C, et al. Laparoscopic partial splenic resection. Surg Laparosc Endosc. 1995;5(2):133-136.Brunicardi_Ch34_p1517-p1548.indd 154423/02/19 2:37 PM 1545THE SPLEENCHAPTER 34 113. Smith ST, Scott DJ, Burdick JS, Rege RV, Jones DB. Laparoscopic marsupialization and hemisplenectomy for splenic cysts. J Laparoendosc Adv Surg Tech A. 2001;11(4): 243-249. 114. Fan H, Zhang D, Zhao X, Pan F, Jin ZK. Laparoscopic partial splenectomy for large splenic epidermoid cyst. Chin Med J (Engl). 2011;124(11):1751-1753. 115. Mouttalib S, Rice HE, Snyder D, et al. Evaluation of par-tial and total splenectomy in children with sickle cell dis-ease using an Internet-based registry. Pediatr Blood Cancer. 2012;59(1):100-104. 116. Buesing KL, Tracy ET, Kiernan C, et al. Partial splenectomy for hereditary spherocytosis: a multi-institutional review. J Pediatr Surg. 2011;46(1):178-183. 117. Hery G, Becmeur F, Mefat L, et al. Laparoscopic partial sple-nectomy: indications and results of a multicenter retrospective study. Surg Endosc. 2008;22(1):45-49. 118. Dutta S, Price VE, Blanchette V, Langer JC. A laparoscopic approach to partial splenectomy for children with hereditary spherocytosis. Surg Endosc. 2006;20(11):1719-1724. 119. Szczepanik AB, Meissner AJ. Partial splenectomy in the management of nonparasitic splenic cysts. World J Surg. 2009;33(4):852-856. 120. Bai YN, Jiang H, Prasoon P. A meta-analysis of perioperative outcomes of laparoscopic splenectomy for hematological dis-orders. World J Surg. 2012;36(10):2349-2358. 121. Jones P, Leder K, Woolley I, Cameron P, Cheng A, Spelman D. Postsplenectomy infection strategies for prevention in gen-eral practice. Aust Fam Physician. 2010;39(6):383-386. 122. Denholm JT, Jones PA, Spelman DW, Cameron PU, Woolley IJ. Spleen registry may help reduce the incidence of overwhelming postsplenectomy infection in Victoria. Med J Aust. 2010;192(1):49-50. 123. Holdsworth RJ, Irving AD, Cuschieri A. Postsplenectomy sep-sis and its mortality rate: actual versus perceived risks. Br J Surg. 1991;78(9):1031-1038. 124. Waghorn DJ. Overwhelming infection in asplenic patients: current best practice preventive measures are not being fol-lowed. J Clin Pathol. 2001;54(3):214-218. 125. Bonanni P, Grazzini M, Niccolai G, et al. Recommended vac-cinations for asplenic and hyposplenic adult patients. Hum Vaccin Immunother. 2017;13(2):359-368. 126. Taylor MD, Genuit T, Napolitano LM. Overwhelming post-splenectomy sepsis and trauma: time to consider revaccina-tion? J Trauma. 2005;59(6):1482-1485. 127. Targarona EM. Portal vein thrombosis after laparoscopic splenectomy: the size of the risk. Surg Innov. 2008;15(4): 266-270. 128. Ruiz-Tovar J, Priego P. Portal vein thrombosis after splenic and pancreatic surgery. Adv Exp Med Biol. 2017;906: 241-251. 129. British Committee for Standards in Haematology Gen-eral Haematology Task F. Guidelines for the investigation and management of idiopathic thrombocytopenic pur-pura in adults, children and in pregnancy. Br J Haematol. 2003;120(4):574-596. 130. Martin Arnau B, Turrado Rodriguez V, Tartaglia E, Bollo Rodriguez J, Targarona EM, Trias Folch M. Impact of preop-erative platelet count on perioperative outcome after laparo-scopic splenectomy for idiopathic thrombocytopenic purpura. Cir Esp. 2016;94(7):399-403. 131. Rijcken E, Mees ST, Bisping G, et al. Laparoscopic sple-nectomy for medically refractory immune thrombocytope-nia (ITP): a retrospective cohort study on longtime response predicting factors based on consensus criteria. Int J Surg. 2014;12(12):1428-1433. 132. Matharoo GS, Afthinos JN, Gibbs KE. Trends in splenectomy: where does laparoscopy stand? JSLS. 2014;18(4). 133. Myers J. Focused assessment with sonography for trauma (FAST): the truth about ultrasound in blunt trauma. J Trauma. 2007;62(6 suppl):S28. 134. Park A, Marcaccio M, Sternbach M, Witzke D, Fitzgerald P. Laparoscopic vs open splenectomy. Arch Surg. 1999; 134(11):1263-1269. 135. Winslow ER, Brunt LM. Perioperative outcomes of lapa-roscopic versus open splenectomy: a meta-analysis with an emphasis on complications. Surgery. 2003;134(4):647-653; discussion 654-645. 136. Park A, Gagner M, Pomp A. The lateral approach to laparo-scopic splenectomy. Am J Surg. 1997;173(2):126-130. 137. Pietrabissa A, Morelli L, Peri A, et al. Laparoscopic treatment of splenomegaly: a case for hand-assisted laparoscopic surgery. Arch Surg. 2011;146(7):818-823. 138. Patel AG, Parker JE, Wallwork B, et al. Massive splenomeg-aly is associated with significant morbidity after laparoscopic splenectomy. Ann Surg. 2003;238(2):235-240. 139. Kercher KW, Matthews BD, Walsh RM, Sing RF, Backus CL, Heniford BT. Laparoscopic splenectomy for massive spleno-megaly. Am J Surg. 2002;183(2):192-196. 140. Monclova JL, Targarona EM, Vidal P, et al. Single incision versus reduced port splenectomy—searching for the best alternative to conventional laparoscopic splenectomy. Surg Endosc. 2013;27(3):895-902. 141. Vatansev C, Ece I, Jr. Single incision laparoscopic splenec-tomy with double port. Surg Laparosc Endosc Percutan Tech. 2009;19(6):e225-e227. 142. Barbaros U, Dinccag A. Single incision laparoscopic splenectomy: the first two cases. J Gastrointest Surg. 2009;13(8):1520-1523. 143. Maeso S, Reza M, Mayol JA, et al. Efficacy of the Da Vinci surgical system in abdominal surgery compared with that of laparoscopy: a systematic review and meta-analysis. Ann Surg. 2010;252(2):254-262. 144. Chapman WH, 3rd, Albrecht RJ, Kim VB, Young JA, Chitwood WR, Jr. Computer-assisted laparoscopic splenec-tomy with the da Vinci surgical robot. J Laparoendosc Adv Surg Tech A. 2002;12(3):155-159. 145. Moore LJ, Wilson MR, Waine E, Masters RS, McGrath JS, Vine SJ. Robotic technology results in faster and more robust surgical skill acquisition than traditional laparoscopy. J Robot Surg. 2015;9(1):67-73. 146. Park BS, Ryu DY, Son GM, Cho YH. Factors influenc-ing on difficulty with laparoscopic total extraperitoneal repair according to learning period. Ann Surg Treat Res. 2014;87(4):203-208. 147. Smith CD, Farrell TM, McNatt SS, Metreveli RE. Assessing laparoscopic manipulative skills. Am J Surg. 2001;181(6):547-550. 148. Lee GI, Lee MR, Green I, Allaf M, Marohn MR. Surgeons’ physical discomfort and symptoms during robotic surgery: a comprehensive ergonomic survey study. Surgical endoscopy. 2017;31(4):1697-1706. 149. Gelmini R, Franzoni C, Spaziani A, Patriti A, Casciola L, Saviano M. Laparoscopic splenectomy: conventional versus robotic approach—a comparative study. J Laparoendosc Adv Surg Tech A. 2011;21(5):393-398. 150. Bodner J, Kafka-Ritsch R, Lucciarini P, Fish JH, 3rd, Schmid T. A critical comparison of robotic versus conventional laparo-scopic splenectomies. World J Surg. 2005;29(8):982-985; discussion 985-986. 151. Corcione F, Bracale U, Pirozzi F, Cuccurullo D, Angelini PL. Robotic single-access splenectomy using the Da Vinci Single-Site(R) platform: a case report. Int J Med Robot. 2014;10(1):103-106. 152. Klein MD, Langenburg SE, Kabeer M, Lorincz A, Knight CG. Pediatric robotic surgery: lessons from a clinical experience. J Laparoendosc Adv Surg Tech A. 2007;17(2):265-271.Brunicardi_Ch34_p1517-p1548.indd 154523/02/19 2:37 PM 1546SPECIFIC CONSIDERATIONSPART II 153. Wang X, Wang M, Zhang H, Peng B. Laparoscopic partial splenectomy is safe and effective in patients with focal benign splenic lesion. Surg Endosc. 2014;28(12):3273-3278. 154. de la Villeon B, Zarzavadjian Le Bian A, Vuarnesson H, et al. Laparoscopic partial splenectomy: a technical tip. Surg Endosc. 2015;29(1):94-99. 155. Cadili A, de Gara C. Complications of splenectomy. Am J Med. 2008;121(5):371-375. 156. Isik O, Aytac E, Ashburn J, et al. Does laparoscopy reduce splenic injuries during colorectal resections? An assess-ment from the ACS-NSQIP database. Surg Endosc. 2015;29(5):1039-1044. 157. Rodriguez-Otero Luppi C, Targarona Soler EM, Balague Ponz C, et al. Clinical, anatomical, and pathological grading score to predict technical difficulty in laparoscopic splenectomy for non-traumatic diseases. World J Surg. 2017;41(2):439-448. 158. Gonçalves D, Morais M, Costa-Pinho A, Bessa-Melo R, Graca L, Costa-Maia J. Validation of a difficulty grading score in laparoscopic splenectomy. J Laparoendosc Adv Surg Tech A. 2018;28(3):242-247. 159. James AW, Rabl C, Westphalen AC, Fogarty PF, Posselt AM, Campos GM. Portomesenteric venous thrombosis after lapa-roscopic surgery: a systematic literature review. Arch Surg. 2009;144(6):520-526. 160. Li B, Liu J, Shangguan Y, Liu B, Qi Y. Laparoscopy-assisted small incision splenectomy and open splenectomy in the treatment of hematologic diseases: a single-institution com-parative experience. Surg Laparosc Endosc Percutan Tech. 2013;23(3):309-311. 161. Zhou J, Liu P, Yin Z, Zhao Y, Wang X. Safety and cost-effectiveness analysis of laparoscopic splenectomy by secondary pedicle division using monopolar electrocautery. Hepatogastroenterology. 2013;60(126):1302-1306. 162. Cordera F, Long KH, Nagorney DM, et al. Open versus laparoscopic splenectomy for idiopathic thrombocytope-nic purpura: clinical and economic analysis. Surgery. 2003; 134(1):45-52. 163. Sun LM, Chen HJ, Jeng LB, Li TC, Wu SC, Kao CH. Sple-nectomy and increased subsequent cancer risk: a nationwide population-based cohort study. Am J Surg. 2015;210(2): 243-251. 164. Kristinsson SY, Gridley G, Hoover RN, Check D, Landgren O. Long-term risks after splenectomy among 8,149 cancer-free American veterans: a cohort study with up to 27 years follow-up. Haematologica. 2014;99(2):392-398. 165. McInnes MD, Kielar AZ, Macdonald DB. Percutaneous image-guided biopsy of the spleen: systematic review and meta-analysis of the complication rate and diagnostic accu-racy. Radiology. 2011;260(3):699-708. 166. Singh AK, Shankar S, Gervais DA, Hahn PF, Mueller PR. Image-guided percutaneous splenic interventions. Radio-graphics. 2012;32(2):523-534. 167. Zarzaur BL, Kozar RA, Fabian TC, Coimbra R. A survey of American Association for the Surgery of Trauma member practices in the management of blunt splenic injury. J Trauma. 2011;70(5):1026-1031. 168. Kamaya A, Weinstein S, Desser TS. Multiple lesions of the spleen: differential diagnosis of cystic and solid lesions. Semin Ultrasound CT MR. 2006;27(5):389-403. 169. Thompson BE, Munera F, Cohn SM, et al. Novel computed tomography scan scoring system predicts the need for inter-vention after splenic injury. J Trauma. 2006;60(5):1083-1086. 170. Filicori F, Stock C, Schweitzer AD, et al. Three-dimensional CT volumetry predicts outcome of laparoscopic splenectomy for splenomegaly: retrospective clinical study. World J Surg. 2013;37(1):52-58. 171. Berindoague R, Targarona EM, Balague C, et al. Can we pre-dict immediate outcome after laparoscopic splenectomy for splenomegaly? Multivariate analysis of clinical, anatomic, and pathologic features after 3D reconstruction of the spleen. Surgical innovation. 2007;14(4):243-251. 172. Vancauwenberghe T, Snoeckx A, Vanbeckevoort D, Dymarkowski S, Vanhoenacker FM. Imaging of the spleen: what the clinician needs to know. Singapore Med J. 2015;56(3):133-144. 173. Karakas HM, Tuncbilek N, Okten OO. Splenic abnormali-ties: an overview on sectional images. Diagn Interv Radiol. 2005;11(3):152-158. 174. Dent D, Alsabrook G, Erickson BA, et al. Blunt splenic injuries: high nonoperative management rate can be achieved with selective embolization. J Trauma. 2004;56(5): 1063-1067. 175. Koconis KG, Singh H, Soares G. Partial splenic emboliza-tion in the treatment of patients with portal hypertension: a review of the english language literature. J Vasc Interv Radiol. 2007;18(4):463-481. 176. Cuker A, Cines DB. Evidence-based mini-review: is indium-labeled autologous platelet scanning predictive of response to splenectomy in patients with chronic immune thrombo-cytopenia? Hematology Am Soc Hematol Educ Program. 2010;2010:385-386. 177. Wu Z, Zhou J, Pankaj P, Peng B. Comparative treatment and literature review for laparoscopic splenectomy alone versus preoperative splenic artery embolization splenectomy. Surg Endosc. 2012;26(10):2758-2766. 178. Mousa A, Armbruster J, Adongay J, AbuRahma AF. Splenic artery embolization as a treatment option for chronic pancyto-penia secondary to hypersplenism: a case report and review of literature. Vasc Endovascular Surg. 2012;46(6):501-503. 179. Williams G, Rosen MP, Parker JA, Kolodny GM. Splenic implants detected by SPECT images of Tc-99m labeled damaged red blood cells. Clin Nucl Med. 2006;31(8): 467-469. 180. Lui EH, Lau KK. Intra-abdominal splenosis: how clinical his-tory and imaging features averted an invasive procedure for tissue diagnosis. Australas Radiol. 2005;49(4):342-344. 181. Balague C, Vela S, Targarona EM, et al. Predictive factors for successful laparoscopic splenectomy in immune thrombocy-topenic purpura: study of clinical and laboratory data. Surg Endosc. 2006;20(8):1208-1213. 182. Sweet PH, Khoo T, Nguyen S. Nonalcoholic fatty liver dis-ease. Prim Care. 2017;44(4):599-607. 183. Bolton-Maggs PH, Langer JC, Iolascon A, Tittensor P, King MJ; General Haematology Task Force of the British Committee for Standards in Haematology. Guidelines for the diagnosis and management of hereditary spherocytosis—2011 update. Br J Haematol. 2012;156(1):37-49. 184. Tovo CV, de Mattos AZ, Coral GP, Branco FS, Suwa E, de Mattos AA. Noninvasive imaging assessment of non-alcoholic fatty liver disease: focus on liver scintigraphy. World J Gastro-enterol. 2015;21(15):4432-4439. 185. Rubin LG, Schaffner W. Clinical practice. Care of the asplenic patient. N Engl J Med. 2014;371(4):349-356. 186. Theilacker C, Ludewig K, Serr A, et al. Overwhelming post-splenectomy infection: a prospective multicenter cohort study. Clin Infect Dis. 2016;62(7):871-878. 187. O’Neal HR, Jr, Niven AS, Karam GH. Critical illness in patients with asplenia. Chest. 2016;150(6):1394-1402. 188. Chong J, Jones P, Spelman D, Leder K, Cheng AC. Over-whelming post-splenectomy sepsis in patients with asplenia and hyposplenia: a retrospective cohort study. Epidemiol Infect. 2017;145(2):397-400. 189. Sinwar PD. Overwhelming post splenectomy infection syndrome—review study. Int J Surg. 2014;12(12):1314-1316. 190. Lynch AM, Kapila R. Overwhelming postsplenectomy infec-tion. Infect Dis Clin North Am. 1996;10(4):693-707.Brunicardi_Ch34_p1517-p1548.indd 154623/02/19 2:37 PM 1547THE SPLEENCHAPTER 34 191. Brigden ML. Overwhelming postsplenectomy infection still a problem. West J Med. 1992;157(4):440-443. 192. Dionne B, Dehority W, Brett M, Howdieshell TR. The asplenic patient: post-insult immunocompetence, infection, and vacci-nation. Surg Infect (Larchmt). 2017;18(5):536-544. 193. Dendle C, Sundararajan V, Spelman T, Jolley D, Woolley I. Splenectomy sequelae: an analysis of infectious outcomes among adults in Victoria. Med J Aust. 2012;196(9):582-586. 194. Ejstrud P, Kristensen B, Hansen JB, Madsen KM, Schonhey-der HC, Sorensen HT. Risk and patterns of bacteraemia after splenectomy: a population-based study. Scand J Infect Dis. 2000;32(5):521-525. 195. Edgren G, Almqvist R, Hartman M, Utter GH. Splenectomy and the risk of sepsis: a population-based cohort study. Ann Surg. 2014;260(6):1081-1087. 196. Leone G, Pizzigallo E. Bacterial infections following splenec-tomy for malignant and nonmalignant hematologic diseases. Mediterr J Hematol Infect Dis. 2015;7(1):e2015057. 197. Yu RK, Shepherd LE, Rapson DA. Capnocytophaga canimor-sus, a potential emerging microorganism in splenectomized patients. Br J Haematol. 2000;109(4):679. 198. Sica S, Di Mario A, Salutari P, et al. Morganella morganii pericarditis after resolvent splenectomy for immune pan-cytopenia following allogeneic bone marrow transplanta-tion for acute lymphoblastic leukemia. Clin Infect Dis. 1995;21(4):1052-1053. 199. Demar M, Legrand E, Hommel D, Esterre P, Carme B. Plas-modium falciparum malaria in splenectomized patients: two case reports in French Guiana and a literature review. Am J Trop Med Hyg. 2004;71(3):290-293. 200. Rosner F, Zarrabi MH, Benach JL, Habicht GS. Babesiosis in splenectomized adults. Review of 22 reported cases. Am J Med. 1984;76(4):696-701. 201. Okabayashi T, Hanazaki K. Overwhelming postsplenectomy infection syndrome in adults—a clinically preventable disease. World J Gastroenterol. 2008;14(2):176-179.Brunicardi_Ch34_p1517-p1548.indd 154723/02/19 2:37 PM
Brunicardi_Ch34_p1517-p1548.indd 154823/02/19 2:37 PMThis page intentionally left blankAbdominal Wall, Omentum, Mesentery, and RetroperitoneumScott Kizy and Sayeed Ikramuddin 35chapterABDOMINAL WALLGeneral ConsiderationsIncision and closure of the abdominal wall is among the most common surgical procedures performed. Knowledge of its lay-ered anatomy is critical in the management of surgical patients. Cranially defined by the costal margin and xiphoid process and caudally ending over the pubic bones of the pelvis, the abdomi-nal wall provides support and protection to the peritoneal and retroperitoneal organs.Surgical AnatomyEmbryologically, the abdominal wall is derived from the meso-derm and envelops the future abdominal contents as bilateral migrating layers originating from the paravertebral area. The leading bars of these sheets fuse in the midline as the linea alba at 7 weeks after gestation and reach the umbilicus at 8 weeks.The abdominal wall consists of nine distinct layers: skin, subcutaneous tissue, superficial fascia, external oblique muscle, internal oblique muscles, transversus abdominus muscle, trans-versalis fascia, preperitoneal adipose tissue, and peritoneum. The subcutaneous tissue is composed of superficial adipose tis-sue that is contiguous with Camper’s fascia anteriorly. Deep to this, Scarpa’s fascia consists of a fibrous matrix of tissue that fuses with the anterior layer of fascia of the flank and back.The muscles of the abdominal wall consist of the rectus abdominus medially and the external oblique, internal oblique, and transversus abdominis laterally. The rectus abdominus is a paired longitudinal muscle spanning the length of the abdomen. Divided by the linea alba, both rectus muscles originate at the pubic symphysis and crest and insert on the xiphoid process, the fifth and sixth ribs, and the seventh costal cartilage. Three ten-dinous insertions cross the rectus muscle along its length. The muscle is contained within an aponeurotic sheath formed from the fusion of differing components of the lateral fascial layers.Laterally, the three muscular layers (external oblique, internal oblique, and transversus abdominis) have obliquely oriented fibers relative to one another. The external oblique arises from the eighth rib and inserts medially into the linea alba and anterior iliac crests. The fibers of this muscular layer travel medial and caudal from its insertion. The internal oblique originates from the thoracolumbar fascia. Its fibers travels cra-nially and anteriorly, inserting on the lower costal margin and the xiphoid process. The deep muscular layer, the transversus abdominis muscle, begins at the costal margin and lumbar fas-cia, runs horizontally and anteriorly, and inserts on the linea alba, xiphoid process, and pubis symphysis (Fig. 35-1).Altogether, these muscular layers provide fascial aponeu-rotic sheaths anteriorly. These fascial layers provide variable contributions to the separate layers of the rectus sheath and ultimately fuse in the midline as the linea alba. The rectus sheath that encloses the rectus muscles has differing composi-tions above and below the arcuate line. The anterior rectus sheath is composed of the external oblique aponeurosis through-out its length. The internal oblique aponeurosis is bilaminar and contributes to the anterior and posterior rectus sheaths above the arcuate line. Below this line, the internal aponeurosis contrib-utes only to the anterior rectus sheath. The transversus abdomi-nis aponeurosis contributes the posterior rectus sheath above the arcuate line and the anterior rectus sheath below the arcuate line. Therefore, below the arcuate line, all the aponeurotic layers of the lateral musculature form the anterior sheath, leaving the transversalis fascia as the only posterior fascial covering. This layer is a weak fibrous layer separated from the peritoneum by preperitoneal fat (Fig. 35-2).Along the posterior abdominal wall are folds correspond-ing to underlying vasculature and embryologic remnants. The median umbilical fold is formed by the obliterated urachus trav-eling from the dome of the bladder to the umbilicus in the mid-line. The bilateral medial folds are formed by remnants of the umbilical arteries. Lastly, the lateral folds are associated with the inferior epigastric vessels.The deep blood supply of the abdominal wall is supplied mostly from the inferior and superior epigastric arteries. The superior epigastric artery is the final branch of the internal tho-racic artery. It enters the rectus sheath below the costal margin 1Abdominal Wall 1549General Considerations / 1549Surgical Anatomy / 1549Physiology / 1550Abdominal Surgical Incisions and Closure / 1550Congenital Abnormalities / 1553Acquired Abnormalities / 1554Omentum 1557Surgical Anatomy / 1557Physiology / 1558Acquired Disorders / 1558Mesentery 1559Surgical Anatomy / 1559Sclerosing Mesenteritis / 1559Mesenteric Cysts / 1560Mesenteric Tumors / 1561Retroperitoneum 1561Surgical Anatomy / 1561Retroperitoneal Infections / 1561Retroperitoneal Fibrosis / 1562Brunicardi_Ch35_p1549-p1566.indd 154912/02/19 9:58 AM 1550Key Points1 There are differences in the anatomic structure in the rectus sheath above and below the arcuate line. Below the arcuate line, all the lateral fascial layers combine and travel anteriorly forming the anterior rectus sheath and leaving the posterior aspect of the lower portion of the rectus muscles without an aponeurotic covering. Above the arcuate line, the posterior rectus sheath is formed by a portion of the internal oblique aponeurosis and the transversus abdominus sheath, and the anterior rectus sheath is formed by the remaining fibers of the internal oblique and the external oblique aponeuroses.2 Two randomized trials have found that closure of midline incisions with small fascial stitches of five to eight mm length and five mm width is beneficial in preventing inci-sional hernias of the abdominal wall.3 Primary repair of ventral incisional hernias results in high recurrence rates, and repair utilizing other methods, includ-ing prosthetic mesh and component separation, are preferred techniques of repair.4 Laparoscopic incisional hernia repair results in similar recur-rence rates and wound infections, compared to open repair. Laparoscopic repair may result in a faster recovery and shorter hospitalization; however, there may be an increase in bowel injury when compared to an open repair.5 Desmoid tumors should be monitored for asymptomatic patients as there is a possibility of spontaneous regression. For patients with rapidly growing or symptomatic tumors resection is recommended. If complete pathologic resection is not achievable without significant morbidity, more modest resection is recommended along with treatment with adju-vant therapies.6 The omentum provides an immunogenic and fibrotic response to foreign stimuli, allowing the abdomen to wall off infections preventing diffuse peritonitis.7 The role of surgery in the treatment of sclerosing mesenteri-tis is minimal and is most often undertaken to obtain tissue for diagnosis. Most cases should be treated medically with surgical interventions reserved for cases of bowel obstruc-tion and ischemia.8 Surgical interventions for retroperitoneal fibrosis include obtaining tissue for pathologic diagnosis, relieving ureteral obstructions via ureterolysis or ureteral stenting, and reliev-ing vascular obstructions via endovascular stenting of affected vessels. Most cases are treated successfully with the use of steroids.and travels along the posterior surface of the anterior sheath and forms an anastomosis with the inferior epigastric artery at the umbilicus. The inferior epigastric artery arises from the external iliac artery. These arteries provide a collateral circula-tion between the vasculature of the upper and lower extremities (Fig. 35-3). The abdominal wall is also supplied by branches of the subcostal and lumbar arteries. Superficially, the abdominal wall subcutaneous and skin tissue is supplied by branches of the superficial epigastric arteries, femoral arteries, superficial exter-nal pudendal, and superficial circumflex arteries. Venous drain-age of the abdominal wall is variable but typically follows the aforementioned arteries. Above the umbilicus, the lymphatics of the abdominal wall drain into the superficial axillary nodes. Below the umbilicus, these drain into the inguinal nodes. Lym-phatics near the umbilicus can drain along the falciform liga-ment toward the hepatic nodes.Innervation of the abdominal wall is segmental, leading to a dermatomal sensory pattern. Afferent branches of the T4 to L1 nerve roots provide sensation of the abdominal wall (see Fig. 35-3). The muscles of the abdominal wall are inner-vated by the efferent branches of spinal nerves T6 to T12.PhysiologyAside from providing protection of the intraabdominal and retroperitoneal organs, the abdominal wall muscles assist with flexion, extension, and rotation of the torso along with the muscles of the back and trunk. Working as a unit, the rectus muscles and external/internal obliques activate to flex the trunk anteriorly and laterally. Rotation of the torso is performed by simultaneous stimulation of the contralateral external oblique and ipsilateral internal oblique. To rotate the torso to the right requires simultaneous contraction of the right internal oblique muscle and left external oblique muscle, and vice versa for leftward rotation. Altogether, the muscles of the abdominal wall can act to raise intraabdominal pressure providing assistance with respiration, coughs, defecation, uri-nation, and parturition.Abdominal Surgical Incisions and ClosureKnowledge of the abdominal wall anatomy is an important aspect of safe entry into the abdomen. The goal of an efficacious incision is to provide adequate exposure to perform the proce-dure with minimal perturbation of the abdominal wall function.Incisions for open abdominal surgery are generally located in proximity to operative targets. There are two general types of incisions: longitudinal or transverse/oblique (Fig. 35-4). There does not appear to be differences in early or late postoperative complications or recovery time between these two types of inci-sions. However, transverse incisions may be associated with lower incisional hernia rates but higher rates of wound infec-tions. Overall, without clear evidence of superiority the choice of incision remains a surgeon-dependent decision. Several retractor systems can be used to provide exposure using these open incisions. Examples include the Bookwalter, Omni-Tract, and Thompson retractors (Fig. 35-5).The most common longitudinal incision is the midline incision. Providing access to most intraabdominal organs and some retroperitoneal structures, the midline incision is carried down to the linea alba to allow access to the abdomen with mini-mal injury to skeletal muscles, nerves, and vessels. Paramedian longitudinal incisions are made lateral to the midline through the rectus sheath or in the pararectus location. These incisions restrict access to the contralateral abdomen and pelvis and risk damage to the musculature, vessels, and nerves.Closure of the midline incision requires reapproximation without undue tension or strangulation of the tissue to prevent Brunicardi_Ch35_p1549-p1566.indd 155012/02/19 9:58 AM 1551ABDOMINAL WALL, OMENTUM, MESENTERY, AND RETROPERITONEUMCHAPTER 35perioperative dehiscence or incisional hernia formation. Clas-sically, the midline fascia of the incision is closed using sutures placed 1 cm from the edge and a width of 1 cm apart. Two European randomized controlled trials demonstrated reduced rates of incisional hernia with shorter stitch width (5–8 mm) compared to the standard 1 cm stitches. Studies are ongoing in the United States at this time. Several studies have evaluated the use of prophylactic mesh implanta-tion in the closure of the midline incision. While these studies demonstrate reduced incisional hernia formation in the short-term, more long-term data is needed to determine the inci-dence of mesh-related complications. Furthermore, the optimal location of mesh implantation and type of mesh used are still being evaluated.When performing a transverse or oblique incision, a sur-geon can either divide or separate the muscle fibers of the abdom-inal wall. The classic McBurney’s incision for appendectomy, an oblique incision performed one-third of the way from the iliac spine to the umbilicus, is an example of a muscle-splitting approach. A subcostal incision can be used to access the upper abdomen, liver, gallbladder, spleen, pancreas, or adrenals. On closure of these incisions, two layers must be approximated. The deep layer includes the internal oblique, transversus abdominus muscle, and the transversalis fascia. The superficial layer includes the anterior aponeurotic tissue of the rectus sheath medially and the external muscle/aponeurosis laterally. A bilateral subcostal incision, or a chevron incision, can be used to access organs of the upper abdomen and diaphragm. A Mercedes-Benz modification includes a midline incision superiorly, providing further access to the upper abdomen or the lower mediastinum.Pelvic procedures are commonly performed through a Pfannenstiel incision. This incision is performed via a trans-verse skin incision carried down to the anterior rectus sheath. The sheath is also transversely incised and dissected off the underlying rectus muscle. The rectus muscles are separated, and access through the transversalis fascia is performed lon-gitudinally. Closure of this incision requires approximation of the peritoneum and rectus muscles and closure of the anterior rectus sheath.Laparoscopic port site incision placement must be care-fully planned based on approach angles and working distances both to the operative site and between ports. Placement of a 278910789106511L1L2L31010(A) Anterior view(B) Rectus abdominis (RA)(C) External oblique (EO) (layer 1)(D) Internal oblique (IO) (layer 2)(E) Transversus abdominis (layer 3)Lateral viewsEOIliac crestIntertendinousband (IT)RAIOTARSRSRSEOEOEORAITRAITRAITRALinea albaPyramidalisITITFigure 35-1. Muscles of the anterior abdominal wall. A. The anterior abdominal wall musculature is shown with the rectus sheath reflected on the left side. B. Rectus abdominis. C. External oblique. D. Internal oblique. E. Transversus abdominus. (Reproduced with permission from Moore KL, Agur AM: Essential Clinical Anatomy, 5th edition. Philadelphia, PA: Lippincott Williams & Wilkins; 2014.)Brunicardi_Ch35_p1549-p1566.indd 155112/02/19 9:58 AM 1552SPECIFIC CONSIDERATIONSPART IInasogastric tube and Foley catheter may help to decompress the stomach and bladder reducing injury to these structures on entry. Initial entry into the abdomen may be completed using the open Hasson or closed Veress needle techniques. The Hasson tech-nique involves direct visualization and systematic opening of each fascial layer encountered on entry. The closed technique utilizes the Veress needle to access the abdomen in a controlled fashion. Access to the peritoneum is confirmed using one or a combination of several techniques (saline drop method or measurement of intraabdominal pressure), and gas insuffla-tion is begun. The abdomen can then be accessed using either a visual entry port or a nonvisualized entry port at the site of the needle track or an alternative site. Choice of entry method is still controversial and based on surgeon preference. Retrospec-tive reviews suggest that complications may be lower using the Hasson technique, but randomized trials (although small) have not found significant differences in techniques.Abdominal incisions can lead to significant patient mor-bidity. Complications include hematomas/seromas, surgical site infections, fascial dehiscence, incisional hernias, and nerve injuries among others. In general, minimizing opera-tive incision lengths to only that which is necessary for a safe operation is prudent to reduce these complications and morbidity.Right externaloblique muscleFibers of rightexternal obliqueaponeurosisFibers of leftinternal obliqueaponeurosisFibers passing from superficial to deep(and vice versa) at linea albaLeft internaloblique muscleIntermuscular exchange of fibers between aponeuroses ofcontralateral external and internal oblique muscles.Fibers of left externaloblique aponeurosis,which run deep on theright side and runningsuperficially on the leftsideDeep fibers of left external oblique aponeurosisUmbilical ringDeep fibers of right external oblique aponeurosisIntramuscular exchange of superficial and deepfibers within aponeuroses of contralateralexternal oblique muscles. Transverse sections(B) Anterior view(A) Anterior viewsLineaalbaRectus abdominisAponeurosisof externalobliqueAponeurosisof internalobliqueAponeurosisof transversusabdominisParietal peritoneumSkinTransversus abdominisInternal obliqueExternal obliqueDeep membranous layerof subcutaneoustissueTransversalis fasciaExtraperitoneal fatRectussheathLinea alba(note fibers passingfrom superficial to deep,and vice versa, as inright side of figure A)Superficial fatty layer ofsubcutaneoustissueInvesting (deep) fascia:SuperficialIntermediateDeepFigure 35-2. Fiber direction and cross-sectional anatomy of the abdominal wall. A. Muscular and aponeurosis fiber direction of external and internal obliques. B. Cross-sectional anatomy of the anterior abdominal wall above and below the arcuate line. The posterior leaf of the rectus sheath exists above the arcuate line. Below this line, all aponeurotic sheaths converge and travel anterior to the rectus muscles, leaving the posterior rectus uncovered by a fascial layer. (Reproduced with permission from Moore KL, Agur AM: Essential Clinical Anatomy, 5th edition. Philadelphia, PA: Lippincott Williams & Wilkins; 2014.)Brunicardi_Ch35_p1549-p1566.indd 155212/02/19 9:58 AM 1553ABDOMINAL WALL, OMENTUM, MESENTERY, AND RETROPERITONEUMCHAPTER 35Congenital AbnormalitiesThe folds of mesodermal cells that form the abdominal wall lay-ers begin to form in the early weeks after gestation. The folds develop in the cephalic, caudal, and right/left lateral directions and converge at the umbilicus around 8 weeks. At around 6 weeks of development the contents of the abdominal cavity outgrow the space allowed by the surrounding layers of the Thoraco-abdominalnerves (T7-T11)Lateral cutaneous branchof subcostal nerve (T12)Anterior cutaneous branchof subcostal nerve (T12)Iliohypogastric nerve (L1)Ilio-inguinal nerve (L1)Xiphoid processAnterior superior iliac spine (ASIS)AnteriorcutaneousbranchesLateralcutaneousbranchesInguinal ligamentSuperiorepigastric a.External obliqueInternal oblique TransversusabdominisInferior epigastric a.Deep circumflexiliac a.Superficialepigastric a.Superficialcircumflex iliac a.External iliac a.Femoral a.Transversalis fasciaMusculophrenic a.11th posteriorintercostal a.10th posteriorintercostal a.Subcostal a.Internal thoracic a.Anterior viewFigure 35-3. Neurovascular anatomy of the anterior abdominal wall. The right image demonstrates the arteries of the deep abdominal wall. The superior epigastric and inferior epigastric form an anastomosis along the posterior aspect of the rectus muscle. The image on the left demonstrates the dermatomal distribution of cutaneous nerves of the abdominal wall. (Reproduced with permission from Moore KL, Agur AM: Essential Clinical Anatomy, 5th edition. Philadelphia, PA: Lippincott Williams & Wilkins; 2014.)CDEFHGABFigure 35-4. Various open abdominal wall incisions. A. Mid-line incision. B. Paramedian incision. C. Right subcostal incision and “saber slash” extension (dashed line). D. Bilateral subcostal incision (also chevron incision) with “Mercedes Benz” extension (dashed line). E. Rocky-Davis incision and Weir extension (dashed line). F. McBurney incision. G. Transverse incision. H. Pfannen-stiel incision.Figure 35-5. Thompson retractor for exposure of intra-abdominal structures utilizing an upper midline incision.Brunicardi_Ch35_p1549-p1566.indd 155312/02/19 9:58 AM 1554SPECIFIC CONSIDERATIONSPART IIabdominal wall, resulting in temporary herniation of the abdom-inal contents through a central defect. At this time, the vitelline duct (omphalomesenteric duct) and allantois also pass through the central defect. The vitelline duct serves as a conduit to the embryologic midgut and the yolk sac. As the midgut develops outside of the abdomen, it undergoes a 270° counterclockwise rotation and reenters the abdomen at around 12 weeks. Failure of the midgut to reenter the abdomen leads to the congenital abdominal wall defect known as an omphalocele, in which the contents of the defect protrude through an open umbilicus and are covered by an amniotic/peritoneal membrane. Gastroschisis, on the other hand, results from either malformation or disrup-tion of the abdominal wall, either from genetic defects or vas-cular compromise. Gastroschisis presents as protruding viscera through a defect lateral to the umbilicus (usually along the right side) without the amniotic sac covering.The vitelline duct usually involutes at around the eighth to ninth week after gestation. Failure of vitelline duct regression can lead to several abnormalities depending on the spectrum of involution. This spectrum includes total persistence of the vitel-line duct leading to omphalomesenteric fistula causing drainage of intestinal contents at the umbilicus, to partial closure leading to omphalomesenteric cyst. If the vitelline remnant persists at the ileal border, a Meckel’s diverticulum forms. The vitelline duct may also persist as a fibrous attachment of the intestine to the abdominal wall predisposing the patient to bowel obstruc-tions. Fistulas, cysts, and fibrous attachments should be resected when diagnosed.The urachus is the proximal portion of the allantois form-ing as the bladder descends into its pelvic position. The urachus closes and forms the median umbilical ligament of the abdomi-nal wall as previously described. Failure of the urachus to close results in urinary fistula or cyst. These are treated by urachal excision and closure of the bladder defect.Acquired AbnormalitiesAbdominal Wall Hernias. A protrusion or bulge of abdomi-nal contents through the abdominal wall muscle/fascia repre-sents an abdominal wall hernia. This may be present at birth or acquired from weakening or disruption of the overlying fascia, or from failed healing of a surgical incision. Hernias may present as asymptomatic bulges that increase with Val-salva maneuvers, or with significant discomfort. On physical exam, the patient’s abdominal wall should be evaluated with the patient both standing and in the recumbent position. Her-nias may reduce spontaneously or with manual pressure. If a hernia is incarcerated, it cannot be reduced and generally requires surgical correction. If intestine is incarcerated in the hernia defect, bowel obstruction may ensue, which represents a surgical emergency. Incarcerated hernias present with sig-nificant pain, nausea, and vomiting. A hernia is considered strangulated if blood supply to its contents is compromised. Localized ischemia may lead to infarction and eventual perfo-ration if left untreated.Nonincisional hernias are named based on their location on the abdominal wall. Epigastric hernias are defects in the abdominal wall located between the umbilicus and the xiphoid process. These hernias are usually small but may be associ-ated with multiple defects. They result from multiple factors, including muscle weakness, congenitally weakened epigastric fascia, or increases in intra-abdominal pressure. Epigastric hernias rarely contain bowel and usually contain portions of the omentum or falciform ligament. Given the rarity of incarcera-tion, repair of an epigastric hernia is indicated for symptomatic patients only. Laparoscopic repair can be attempted, but this type of hernia usually can be managed with a small incision where the defect is closed with interrupted sutures.Umbilical hernias may be congenital or acquired. Umbili-cal hernias are common in newborns, especially in premature infants. Closure of an umbilical defect occurs after birth as the muscles of the rectus abdominis grow toward one another. Most umbilical hernias close spontaneously by 5 years of age and can be monitored as they will spontaneously resolve. Indications for repair include incarceration, symptomatic hernia, failure to decrease in size or if the defect fails to close by the age of 5 years.In adults, umbilical hernias form because of increased abdominal pressure due to pregnancy, obesity, or ascites. Females are at higher risk for this type of hernia than men. Small, asymptomatic hernias may be followed clinically. How-ever, if an umbilical hernia enlarges in size, causes symptoms, or incarcerates surgical treatment should be offered. Hernias can be repaired laparoscopically or with an open procedure. Mesh should be employed for large defects where the fascial edges cannot be approximated without tension. In this case, mesh should be placed as a sublay technique (below the fascia) and sutured in place to prevent migration.Patients with cirrhosis and associated ascites with an umbilical hernia pose a significant clinical dilemma. Umbilical defects enlarge in these patients because of high intra-abdominal pressure associated with uncontrolled ascites. With severe liver disease, these patients are at high risk of operative complica-tions. Most hernias contain ascites; however, omentum and bowel may also enter the defect. Given the high pressure, skin breakdown may ensue leading to hernia rupture or weeping as well as risk of spontaneous bacterial peritonitis. All attempts should be made to control the patient’s ascites prior to repair. Therefore, asymptomatic patients should be managed conserva-tively with aggressive management of ascites. Liver transplant candidates should undergo repair at the time of transplanta-tion as pretransplant repair has high morbidity and mortality. Patients with incarcerated hernias or with thinning or ruptured skin overlying the hernia should be treated emergently.Hernias that occur along the arcuate line are known as Spigelian hernias. While rare, these hernias form due to the anatomic weakness of lack of a posterior rectus sheath below the arcuate line. As the hernia develops, peritoneum that passes through the arcuate line will pass laterally toward the external oblique muscle given the overlying aponeurosis (Fig. 35-6). Most patients present with pain and swelling in the mid to lower abdomen. Incarceration is common as up to 20% of patients present with a nonreducible hernia. Given the high rate of incar-ceration, surgical repair is usually recommended. Either open or laparoscopic repair can be performed. The defect is closed by approximating the medial and lateral edges of the transversalis fascia to the rectus sheath.Incisional Hernias. Hernias that develop at sites of pre-vious abdominal incisions are known as incisional hernias. Hernias can develop at the site of any previous abdominal incision. Up to 20% of midline incisions will develop her-nias eventually. Vertical incisions may have a higher risk of hernia formation than transverse or oblique incisions. Upper Brunicardi_Ch35_p1549-p1566.indd 155412/02/19 9:58 AM 1555ABDOMINAL WALL, OMENTUM, MESENTERY, AND RETROPERITONEUMCHAPTER 35abdominal incisions are also at higher risk than lower inci-sions. Laparoscopic port sites may also develop hernias. The etiology of incisional hernias is complex. Several patient-derived factors increase the risk of hernia, including diabe-tes, immunosuppressant use, obesity, smoking, malnutrition, and connective tissue disorders. Local operative factors may also be implicated, including technique, wound infection, or high tension at the time of closure. Hernias can develop up to 10 years after surgery but normally occur in the early postop-erative period. Incisional hernias can present as asymptom-atic bulges or with severe discomfort. Multiple hernias can be present along the length of the incision. Elective surgery should be recommended in patients who are symptomatic. Small defects pose a higher risk of incarceration and should be repaired. To improve operative outcome, patient associated factors, including smoking and obesity, should be remedied prior to surgical repair.Surgical management of incisional hernias include either primary tissue or mesh repairs. Hernias can also be repaired via a laparoscopic or open approach. Simple suture repair is associ-ated with recurrence rates as high as 54%. A Cochrane review of several randomized controlled trials found that open mesh repair improved hernia recurrence rates when compared to simple closure (33% with simple repair vs. 16% with mesh repair). Mesh repairs are, however, associated with a higher rate of infections.To reduce tension at the suture line associated with pri-mary suture repair Ramirez described the components separa-tion technique in 1990. This procedure entails dividing portions of the bilateral external oblique aponeuroses forming musculo-fascial advancement flaps. The posterior rectus sheath can also be incised, allowing up to 10 cm of medial mobilization and ten-sionless approximation of the midline fascia. This technique can cause large skin flaps and initially had high rates of infection. Overtime, techniques have been developed to decrease flap for-mation and decreased rates of surgical site infection. Endoscopic component separation can also be used to mobilize flaps with minimal ischemia to overlying subcutaneous and skin tissue, theoretically decreasing infection rates. Mobilization of midline fascia is reduced with endoscopic methods. Mesh can also be utilized to reinforce the repair. Overall, component separation without mesh compares to standard mesh repair with respect to hernia recurrence, but precludes the risk of mesh implantation. When mesh is added to component separation, recurrence rates may be as low as 4% to 10% depending on follow up period.Mesh repair has become the standard for elective manage-ment of most incisional hernias. Position of mesh placement is controversial. Mesh can be placed above the midline fascia (overlay), bridged across fascial defects (interlay), underneath fascia (sublay), or within the abdominal cavity (underlay). A systematic review found that sublay placement of mesh may reduce hernia recurrence and prevent wound related compli-cations. The sublay technique is performed by developing the plane between the rectus muscle and the posterior sheath, and affixing mesh in this space. The anterior sheath can be approxi-mated if there is no tension.Material used for mesh manufacturing can be classified into two classes: synthetic and biologic. Synthetic meshes can be either permanent or degradable, while all biologic meshes are degradable. Permanent mesh is currently made of either poly-propylene, polyethylene terephthalate polyester, or expanded polytetrafluoroethylene. Permanent mesh is durable and of rel-atively low cost. Degradable synthetic mesh, including Vicryl mesh, is eventually eliminated and loses structural support, but it does offer the advantage of lower mesh infection rates. Degrad-able mesh is associated with high recurrence rates, but it can be used for temporary abdominal wall closure in contaminated or infected fields. Newer synthetic biomaterial meshes, includ-ing Gore BioA or Phasix, degrade over a longer period of time and may reduce recurrence rates, but long-term effectiveness is unknown. Biologic meshes are decellularized, collagen-rich porcine, bovine, or human tissue. These meshes are designed to allow host cellular ingrowth, promoting incorporation and eventual replacement of the mesh with host tissue. Biologic meshes are a high cost alternative to synthetic degradable mesh and can be used in infected fields. However, their efficacy in preventing recurrence is unclear. Composite products contain two components and are used during intraperitoneal repair. One side of composite mesh, which is placed on the abdominal wall side of implantation, is made of typical nondegradable synthetic material and promotes integration of host tissue. The other side is covered in a synthetic or biologic material, allowing contact with viscera and preventing adhesion formation. These materi-als include polyglactin, collagen, cellulose, titanium, omega-3, and hyaluronate. This allays concerns of direct mesh contact 3Figure 35-6. Computed tomography scan imaging of Spigelian hernia. Hernia contents traverse through the arcuate line but remain covered by the external oblique aponeurosis. (Reproduced with permission from Martin M, Paquette B, Badet N, et al: Spigelian hernia: CT findings and clinical relevance, Abdom Imaging. 2013 Apr;38(2):260-264.)Brunicardi_Ch35_p1549-p1566.indd 155512/02/19 9:58 AM 1556SPECIFIC CONSIDERATIONSPART IIwith viscera that may cause adhesions, erosion, and eventual fistula formation. Pore size and mesh weight are also important aspects of mesh design. Recently, large-pore, lightweight mesh has been developed. This was initially thought to delay incorpo-ration, but that has not been seen in practice. They do allow the theoretical advantage of increased incorporation of host tissue and potentially better elasticity and improved postoperative pain when compared to microporous heavier meshes. There is also initial data which suggests lower rates of mesh infection with the use of large pore mesh.Initially described by LeBlanc and Booth in 1993, laparo-scopic repair is now an accepted modality for treatment of inci-sional hernias. Several studies have found that laparoscopic repair has a lower incidence of surgical site and mesh infections compared to open repair. It also seems that lapa-roscopic repair allows faster recovery with less postoperative pain. A meta-analysis of 11 studies comparing laparoscopic and open ventral hernia repair found no difference in hernia recur-rence and lower rates of wound infection and wound drainage. There was however, a higher risk of bowel injury in the laparo-scopic group. Another meta-analysis of six randomized con-trolled trials had similar findings. Follow-up in these studies is relatively short, and more long-term data is needed at this time to compare these two modalities of repair.Laparoscopic hernia repair is performed by initially plac-ing lateral ports for midline defects and contralaterally placed ports for lateral defects. Adhesions between the abdominal wall and intestine are carefully taken down, and the hernia contents are completely reduced. The sac is normally left in situ. Once the fascial defect is defined, a mesh is properly shaped and fash-ioned over the hernia. Transfascial sutures are placed circum-ferentially to position the mesh with sufficient overlap (4–5 cm) with healthy abdominal wall. Spiral tacks may be placed accord-ing to surgeon preference. Even more recently, robotic surgery has been established as another surgical modality in the treat-ment of ventral hernias. The theoretical advantage of improved visualization and articulating instruments may improve out-comes, but the cost-effectiveness of robotic repair is unclear. Overall, more studies are needed to evaluate the role of robotics in ventral hernia surgery.Although still rare, given the increase in laparoscopic procedures, the incidence of laparoscopic port site hernias is becoming more common. Given the size of the hernias, there is a substantial risk of bowel strangulation and ischemia. These hernias commonly present as Richter’s hernia, or a hernia con-taining only a portion of bowel wall. A recent meta-analysis found that the incidence of port site hernia after laparoscopic procedure was less than 1%. Patients can present either early or several years after surgery. Risk factors are similar to other incisional hernias. The most common site of herniation is at an umbilical incision, but it may be found elsewhere. In adults, hernias usually occur in ports that are greater than 5 mm in size, but they can occur in any size ports in children. Depending on the timing of presentation, these are usually repaired via an open approach by increasing the size of the skin incision, reducing the hernia, and approximating all layers of fascia.Rectus Abdominis Diastasis. Rectus abdominis diastasis (diastasis recti) is an anatomic term referring to an abnormal separation of rectus muscles and a laxity at the linea alba. Although there is controversy regarding normal separation dis-tances between rectus muscles, a distance of two centimeters is usually considered abnormal in the midline abdomen above the umbilicus. This can either be a congenital or acquired abnor-mality. This is not a true hernia as the midline fascia is intact, and as such incarceration and strangulation do not occur. Risk factors for acquired rectus abdominis diastasis include condi-tions that elevate intraabdominal pressure, including obesity and pregnancy, as well as conditions which weaken the abdominal wall, including connective tissue disorders or prior abdominal surgery. Risk factors of developing a diastasis recti after preg-nancy include older age at the time of pregnancy, multiple preg-nancies, and recurrent ceasarean sections. Postpartum exercise reduces the risk of developing diasthesis recti. Most patients with diastasis recti can be diagnosed based on physical exam where a fusiform bulge is usually apparent. This bulge worsens with contraction of the rectus muscles or Valsalva maneuver. If imaging is needed, ultrasonography can be used to confirm dia-thesis and rule out hernia. CT scan can also be used to confirm diagnosis and measure distance between muscle pillars. Rectus diastasis does not require surgical repair and may be improved via weight loss and exercise. Indications for repair include dis-ability of abdominal wall muscular function or cosmesis. Sur-gical repair includes both open and laparoscopic plication of the rectus sheath. Mesh can also be used to bridge the muscle; however, complication rates increase with mesh usage. These procedures do, unfortunately, have a high risk of recurrence long term and introduce a new risk of incisional hernia.Rectus Sheath Hematoma. Disruption of one of the branches of the inferior epigastric artery as well as an inability to tampon-ade the hemorrhage results in a rectus sheath hematoma. This occurs commonly around the arcuate line where the artery and its branches are relatively fixed causing vulnerability to shearing forces. Several risk factors are associated with rectus hematoma formation via either proclivity to disruption of blood vessels or by inability to cease bleeding. Trauma to the abdominal wall, including iatrogenic trauma with laparoscopic trocar placement, can lead to disruption of blood vessels. Vigorous contraction of the rectus muscle, either with coughing, sneezing, or exercise, can also induce hemorrhage formation. Chronic pulmonary dis-ease can lead to hemorrhage because of coughing fits. Patients on anticoagulation also present with higher risk of hematoma formation. This condition presents with acute abdominal pain and a palpable abdominal wall mass. Rectus sheath hematoma may be mistaken with intraperitoneal pathology, including appendicitis if on the right side. However, in patients with rec-tus sheath hematomas, pain usually increases with contraction of the rectus muscles as opposed to intraperitoneal conditions. In addition, palpation of a mass that does not change during contraction of the rectus muscle, known as Fothergill’s sign, is also associated with rectus sheath pathology. The diagnosis should be confirmed via ultrasound or CT scan with intravenous contrast. Obtaining a type and screen, hemoglobin/hematocrit, and coagulation factors are critical in the management of these patients.Treatment of patients with rectus sheath hematoma depends on the hemodynamic stability of the patient as well as the size of the hematoma. Hemodynamically stable patients with small hematomas, stable serial hemoglobin/hematocrits, and normal coagulation factors may be observed without hospital-ization. Hemodynamically stable patients with larger or bilateral hematomas and decreases in hemoglobin should be monitored in the hospital setting, with serial hemoglobin levels, compres-sion of the hematoma, and bedrest. If anticoagulated, reversal is necessary and transfusions of packed red blood cells may 4Brunicardi_Ch35_p1549-p1566.indd 155612/02/19 9:58 AM 1557ABDOMINAL WALL, OMENTUM, MESENTERY, AND RETROPERITONEUMCHAPTER 35be required in some situations. Patients in hypovolemic shock should be aggressively resuscitated with the use of blood prod-ucts and treated via angiographic embolization. Angiographic intervention may also be required if the hematoma increases in size or if clinical deterioration occurs. Surgical therapy can be performed if angiographic intervention has failed. Surgical treatment includes operative evacuation of hematoma and liga-tion of bleeding vessels.Desmoid Tumors. Also known as aggressive fibromatosis, desmoid tumors are fibroblastic neoplasms with aggressive infiltrative behavior but no metastatic potential. These tumors can occur anywhere in the body but commonly occur in the abdomen or abdominal wall. Desmoid tumors are rare and usu-ally occur sporadically. They are, however, also associated with familial adenomatous polyposis (FAP), with an even greater risk in patients with Gardner’s syndrome. Of patients with FAP, 10% to 15% develop desmoid tumors. After prophylactic col-ectomy, desmoid tumors becomes the primary cause of death in patients with FAP. Risk factors for sporadic development of desmoid tumors include previous surgical incision, pregnancy, hormonal exposure, and trauma. Females have a higher pre-dilection for formation of desmoid tumors. Diagnosis can be performed via core-needle or incisional biopsy. Larger tumor size, young patient age, and extra-abdominal tumor location all predict poor recurrence free survival.The gold standard of treatment of abdominal wall desmoid tumors, historically, is margin-negative resection with immedi-ate mesh reconstruction. However, more recently there has been controversy as to whether complete microscopic resection is necessary. It is now commonly agreed that while complete microscopic resection is ideal, with the emergence of adjuvant therapy a positive margin may not require additional surgery, especially if re-resection would cause high morbidity. There is also some evidence to suggest a period of close watchful wait-ing, as some tumors appear to remain stable or even regress over time. In one cohort of 106 abdominal wall desmoids managed initially without surgery, 16% of patients went on to require surgery in a follow-up period of three years. Interestingly, 29 patients had spontaneous regression of their tumors over that time. The National Comprehensive Cancer Network (NCCN) now suggests initial close observation for patients with asymptomatic, non–life-threatening tumors. Surgery is indicated in patients with symptomatic disease, risk of invasion of surrounding structures, or enlarging tumors. There may be a role for adjuvant or neoadjuvant radiation therapy, although the data are unclear at this time. Primary radiation therapy may be an option for patients who are not surgical candidates. There may also be a role for systemic therapy, especially if tumors are unre-sectable. Options include hormonal therapy, nonsteroidal anti-inflammatory agents, cytotoxic chemotherapies (doxorubicin or carboplatin), or imatinib.Other Abdominal Wall Tumors. Various tumors may also be found within the abdominal wall including lipomas and neu-rofibromas (Fig. 35-7). Surgical resection is recommended for symptomatic or enlarging lesions. Abdominal wall malignancies are exceedingly rare and include several histologic subtypes of sarcomas, dermatofibrosarcoma protuberans, schwannomas, and melanomas. Workup of abdominal wall tumors should include core needle biopsy or excisional biopsy if the tumor is small enough. Magnetic resonance imaging (MRI) or CT scan with IV contrast should be utilized to define local extent of disease. MRI is preferred as this modality provides more detail on extent of disease. Chest CT should also be obtained to rule out pulmo-nary metastasis in high-grade tumors. Chest X-ray may be suf-ficient to stage tumors that are low grade, given the lower risk of distant disease. Surgical resection is the mainstay of treatment for nonmetastatic disease. For most soft tissue sarcomas, 1 cm margins are usually sufficient, but 2 cm margins may be needed for dermatofibrosarcoma protuberans. Tumors of the superficial abdominal wall should be resected with the underlying fascia, which may require use of mesh to prevent abdominal wall laxity or hernia.Given the rarity of these tumors, the efficacy of adjuvant or neoadjuvant chemoradiation is unclear. Adjuvant or neo-adjuvant therapy may be recommended in patients with large (>5 cm) or high-grade tumors. Some centers administer neoad-juvant radiation therapy to patients with high-risk tumors to monitor response. Chemotherapy may also be used in certain situations. If tumors involve underlying viscera, en bloc resec-tion may be required. Primary closure may be feasible, but pros-thetic mesh use (even in the setting of bowel resection) may be required. Options for abdominal wall closure after resection include absorbable or biologic mesh reinforcement, and myocu-taneous flap reconstruction.OMENTUMSurgical AnatomyThe omentum is a fibrous adipose apron providing support and protection of the intraabdominal viscera. Embryologically, the omentum originated from the dorsal mesogastrium. Anatomi-cally, the omentum is divided into the greater and lesser omen-tums. The greater omentum begins to form during the fourth week of gestation. Initially, the omentum forms as a double-layered structure, with the spleen developing between the two layers. As development proceeds, the layers of mesentery fuse, the spleen assumes its position in the peritoneum, and the gas-trosplenic ligament forms. The greater omentum, therefore, is a double-layered sheet of visceral fibroadipose tissue descending from the greater curvature of the stomach, covering the small intestines. The omentum folds back on itself and attaches onto the anterior peritoneum of the transverse colon (Fig. 35-8). 5Figure 35-7. Abdominal wall lipoma.Brunicardi_Ch35_p1549-p1566.indd 155712/02/19 9:59 AM 1558SPECIFIC CONSIDERATIONSPART IIIn an adult, the greater omentum lies between the abdominal wall and the hollow viscera, usually extending into the pelvis. The greater omental tissue connecting the stomach to transverse colon, as well as the stomach to the spleen, are known as the gastrocolic and gastrosplenic ligaments, respectively. The blood supply to the greater omentum is derived from the right and left gastroepiploic arteries. The venous system parallels the arterial supply and ultimately drains into the portal system. Lymphatic drainage of the greater omentum occurs via the subpyloric or splenic nodes depending on laterality ultimately culminating in the celiac nodes and subsequently the thoracic duct.Forming the anterior boundary of the lesser sac, the lesser omentum extends between the liver and lesser curvature of the stomach. Also known as the hepatoduodenal and hepatogastric ligaments, the portal triad (including the common bile duct, por-tal vein, and hepatic artery) is located within the inferolateral margin of the lesser omentum. This free edge of lesser omentum forms the foramen of Winslow, which is used to encircle the portal triad during a pringle maneuver (see Fig. 35-8).PhysiologyInitially described by the British surgeon Rutherford Morison as the “policeman of the abdomen,” the greater omentum is under-stood as a peritoneal defense organ. The omentum forms fibrin adhesions at sites of inflammation, effectively attempting to wall off peritoneal infections. The greater omentum is known to respond to a foreign stimulus by expanding stro-mal tissue that expresses chemotactic, inflammatory, and hemo-static factors, which promote tissue inflammation and subsequent repair. Forming a fibrin bridge between omental tis-sue and the injured site allows passage of inflammatory factors and immune cells. The Graham Patch repair of a perforated ulcer utilizes the complex inflammatory interactions of the omentum to improve leak rates after repair.The visceral fat of the greater omentum is also involved in metabolic functions of the body. Increased visceral fat, including the greater omentum, is an independent risk factor for insulin resistance and high triglyceride levels. This may be, in part, mediated by the increase in visceral inflammation seen in intra-abdominal obesity. Several adipokines, or cell-signaling molecules secreted by adipose tissue, are secreted by the greater omentum and act on peripheral tissues, affecting metabolic health throughout the body.Acquired DisordersOmental Infarction. Omental infarction is a rare cause of acute abdominal pain. Omental infarction may be primary or 6DiaphragmGastrohepaticligamentRight colic (hepatic)flexureAscending colonGreater omentum(gastrocolic ligament)Falciform ligamentRound ligamentof liverHepatoduodenalligament (containingportal triad)Arrow passingthrough omentalforamen intoomental bursaGastrophrenicligamentCoronaryligament (cut)StomachSpleenDescending colonPhrenicocolicligamentInferior recess ofomental bursa(between layers ofgreater omentum)GastrocolicligamentTransverse colon(sectioned)GastrosplenicligamentLeft colic (splenic)flexureTransversemesocolonLiver: Diaphragmatic surface Visceral surfaceAnterior view** Parts of greater omentum* Parts of lesser omentum********Figure 35-8. Greater and lesser omentum. The greater omentum begins along the greater curvature of the stomach, drapes over the transverse colon into the pelvis, and folds back on itself inserting along the posterior wall of the transverse colon. The greater omentum includes the gastrophrenic and gastro splenic ligament. The lesser omentum includes the gastrohepatic and hepatoduodenal ligaments, covering the lesser sac of the abdomen. The free lateral edge of the lesser omentum includes the portal triad, forming the foramen of Winslow below. (Reproduced with permission from Moore KL, Agur AM: Essential Clinical Anatomy, 5th edition. Philadelphia, PA: Lippincott Williams & Wilkins; 2014.)Brunicardi_Ch35_p1549-p1566.indd 155812/02/19 9:59 AM 1559ABDOMINAL WALL, OMENTUM, MESENTERY, AND RETROPERITONEUMCHAPTER 35secondary depending on the etiology. Primary infarction may be caused by torsion of the omentum from sudden or force-ful movements, thrombosis or vasculitis of omental vessels, or omental venous outflow obstruction. Secondary causes of torsion are most often due to hernias, tumors, or adhesions. Only about 250 cases of primary omental infarction have been reported in the literature. This occurs most often in male and obese patients. Omental infarction may mimic other intra-abdominal pathologies such as appendicitis, cholecystitis, or diverticulitis. Abdominal exam usually demonstrates perito-neal tenderness, with a possible palpable mass. Ultrasonogra-phy (US) and abdominal CT scan are used to assist diagnosis. US may demonstrate a hyperechoic, noncompressible intra-abdominal mass attached to the abdominal wall. CT scan demonstrates a streaking whirling pattern of fatty tissue in the anterior abdomen (Fig. 35-9). Regardless, only a small percent-age of patients are preoperatively diagnosed. Omental infarction can be treated conservatively, but this leads to several possible complications, including abscess or adhesion formation. Lapa-roscopic exploration and resection of infarcted tissue is the usual treatment of choice and leads to rapid resolution of symptoms.Omental Cysts. Cystic lesions of the omentum are rare dis-orders, related in pathogenesis to mesenteric cysts. Most are thought to form through degeneration or inclusion of lymphatic structures. Case reports described these lesions presenting as vague abdominal pain or nausea or vomiting. Cysts may also present as a lead point for omental torsion and infarction. Physi-cal exam may or may not reveal evidence of an intra-abdominal mass. Cysts may also be diagnosed incidentally on imaging exams performed for other reasons. CT scan and US are largely diagnostic and reveal a well-circumscribed cystic appearing lesion arising from the greater omentum. A very small percent-age may transform to malignancy. Most are resected, especially if symptomatic, via open or laparoscopic approaches. Cysts may relapse if treated conservatively via laparoscopic unroofing or percutaneous drainage.Omental Neoplasms. Most omental neoplasms are meta-static disease. Ovarian cancer is the most common cancer to have omental involvement. Other metastatic cancers include gastrointestinal tract tumors, melanoma, endometrial cancer, and kidney cancer.Primary tumors of the omentum are exceedingly rare. Benign masses may include lipomas, myxomas, and desmoid tumors. Extra gastrointestinal stromal tumors are a rare malig-nant tumor of the omentum that have been described in several case series. These tumors share many genetic and immuno-phenotypic similarities to classical GISTS, including c-kit and PDGFRA mutations. In one review of case reports, the median age of diagnosis was noted to be 65 years and had equal predi-lection for male and female patients.MESENTERYSurgical AnatomyThe mesentery is a contiguous structure suspending and fix-ing bowel to the abdominal wall providing housing for arterial, venous, nervous, and lymphatic structures connecting hollow viscera with the body. The mesentery is derived from the meso-dermal germ layer becoming the dorsal mesentery. Previous theories of development included sliding and regression models of mesenteric development. However, with a new contiguous model of development of the mesentery, several key simple steps are proposed to take place. Initially, the mesentery provides a point of suspension from vascular connections. As the intestine and mesentery elongate, they undergo a 270° counterclockwise rotation leaving the primordial abdominal cavity. Eventually, the duodenum and ascending/descending colon flatten against the posterior abdominal wall returning the bowel back into the abdomen and taking its normal shape. The resultant develop-ment of the white line of Toldt along the lateral border of the ascending and descending large bowel provides an avascular fascial plan between the colon, its mesentery, and the underlying retroperitoneal space. The small intestine mesentery, transverse colon mesentery, and sigmoid colon mesentery remain mobile.Defects in the proper rotation and fixation of the bowel results in the spectrum of congenital disorders known as intesti-nal malrotation. In this scenario, the intestine and mesentery are simply suspended from vascular connection, making intestinal volvulus common. Defects that form in anatomical positions may act as routes for intestinal herniation. Common sites of her-niation include the paraduodenal or mesocolic areas, leading to either acute or chronic intestinal obstruction in pediatric or adult populations. Areas where mesenteric attachment is incomplete may predispose patients to volvulus. Attachments of the cecum may degrade overtime leading to an area of laxity and possible twisting. The sigmoid mesentery can also increase in size over time also leading to possible sigmoid volvulus. Rarely, other areas of the colon can develop volvulus if differential mesen-teric lengths form.Sclerosing MesenteritisSclerosing mesenteritis is a rare disorder characterized by idio-pathic fibrosis of the mesentery, affecting hollow viscera as well as mesenteric vessels. The disease is part of a spectrum of inflammation and fibrosis, which when localized is known as mesenteric lipodystrophy and when diffuse is known as mes-enteric panniculitis. The cause of this disease is unknown, but it may be instigated by antecedent abdominal surgery, an auto-immune disease, a paraneoplastic syndrome, a previous infec-tion (including typhoid, tuberculosis, influenza, and rheumatic fever), or vascular insult. This disease most commonly effects Figure 35-9. Computed tomography scan findings indicative of omental infarction. The area demonstrated by the bold arrow appears congested with a streaking whirling pattern of fatty tissue in the anterior abdomen. (Reproduced with permission from Barai KP, Knight BC: Diagnosis and management of idiopathic omental infarc-tion: A case report, Int J Surg Case Rep. 2011;2(6):138-140.)Brunicardi_Ch35_p1549-p1566.indd 155912/02/19 9:59 AM 1560SPECIFIC CONSIDERATIONSPART IIwhite patients between 50 and 70 years of age, although it has been rarely described in children. Most studies report a predi-lection for male patients. Most patients with this disease pres-ent with abdominal pain. Other symptoms include nausea and vomiting, weight loss, anorexia, and altered bowel habits. This may appear as a chronic or acute disorder. On physical exam, patients may be found to have tenderness and distension. Up to 50% of patients are found to have an abdominal mass that often transmits aortic pulsations.Abdominal CT with IV contrast is used to assist in diag-nosis (Fig. 35-10). The most common finding is that of a soft tissue mass with a higher density than normal mesenteric tis-sue. Although it is sometimes difficult to distinguish mesen-teric fibrosis from a mesenteric tumor, two CT findings may add specificity. The “tumor pseudocapsule” refers to a hypodense zone around the associated fibrotic mass, and the “fat ring sign” refers to an area of preserved fat near mesenteric vessels cours-ing through areas of fibrosis. These lesions may also be calcified on CT scan.Pathologic confirmation is required to confirm the diagno-sis. This usually requires laparoscopic or open biopsy to provide adequate tissue for confirmation. Treatment of sclerosing mesenteritis is complex, with surgery having a mini-mal role. Patients who present with bowel ischemia may require bowel and mesenteric resection; however, the extent and loca-tion of mesenteric involvement may preclude complete resec-tion. If obstructive symptoms are dominant, intestinal bypass may be indicated. Aggressive surgical treatment is not indicated because in many cases symptoms may improve with medical treatment or even without intervention. Steroids, hormonal ther-apy, colchicine, thalidomide, and cyclophosphamide have all been reported to be beneficial.Mesenteric CystsMesenteric cysts are a rare benign disorder with an incidence ranging from 1 in 27,000 to 1 in 250,000 admissions. Cysts are thought to be caused by disruption of the lymphatics in the mes-entery either by traumatic disruption, mechanical obstruction, or congenital lymphatic malformations. Most cysts are unilocular, but they also may have multiple loculations. They are usually lined with a single layer of columnar epithelial cells. Presenta-tion of mesenteric cyst is varied, with some being found inciden-tally on imaging exams and others causing acute abdominal pain because of cyst rupture or bowel torsion. Chronic symptoms are usually nonspecific, including abdominal pain or discomfort, anorexia, distension, nausea, vomiting, or changes in bowel habits. Symptoms are due to local compression of abdominal structures. Up to 45% of cysts are found incidentally.Physical exam revels an abdominal mass in up to 60% of patients. The classic Tillaux’s sign is an abdominal mass lesion that is only mobile laterally, contrasting omental cysts which are usually freely mobile in all directions. CT scan and ultra-sound can be used to make an accurate diagnosis. Cystic lesions usually appear as a fluid filled mass without solid components (Fig. 35-11). It can sometimes be difficult to differentiate cystic masses from solid tumors based on imaging. Mesenteric cys-tic lymphangioma may present as numerous cysts on imaging. Up to 3% of mesenteric cysts contain malignancy, mostly as a sarcomatous lesion. In one recently published series, 19% of patients harbored malignancy. Solid components within the cystic structure are associated with higher rates of malignancy.Most mesenteric cysts are treated surgically. Marsupial-ization and simple aspiration have high rates of recurrence and 7Figure 35-11. Computed tomography scan demonstrating a mes-enteric cyst. White arrow points to a homogenous cystic structure located in the mesentery of the small bowel. (Reproduced with per-mission from Jain V, DeMuro JP, Geller M, et al. A case of laparo-scopic mesenteric cyst excision. Case Rep Surg. 2012;2012:594095.)ABFigure 35-10. Computed tomography scan findings of sclerosing mesenteritis in (A) coronal view and (B) cross-sectional view. The area demonstrated with arrows depicts an area of higher density and edema representing inflamed mesentery. (Reproduced with per-mission from Daumas A, Agostini S, Villeret J, et al. Spontaneous resolution of severe, symptomatic mesocolic panniculitis: a case report, BMC Gastroenterol. 2012 Jun 6;12:59.)Brunicardi_Ch35_p1549-p1566.indd 156012/02/19 9:59 AM 1561ABDOMINAL WALL, OMENTUM, MESENTERY, AND RETROPERITONEUMCHAPTER 35are generally discouraged. Benign lesions should be enuclu-ated, and malignant cysts should be resected with clear margins. Intestines or surrounding viscera may require resection if the associated vasculature is excised. Resection can be performed either via a laparoscopic or open procedure.Mesenteric TumorsPrimary mesenteric tumors are rare but represent several histo-logic patterns. Benign tumors include desmoid tumors, lipomas, and cystic lymphangiomas. The most common malignant neo-plasm of the mesentery is lymphoma. On imaging, lymphoma may appear as bulky adenopathy, usually surrounding and not obstructing nearby structures. Lymphomas should not be resected, but they may require operative biopsy for diagnosis. Other malignant tumors of the mesentery include gastrointesti-nal stromal tumors, carcinoids, liposarcoma, leiomyosarcoma, malignant fibrous histiocytomoas, lipoblastomas, or lymphan-giosarcoma. Treatment of malignant mesenteric masses usually involves wide resection; however, given the proximity to mes-enteric vessels, resection may not be feasible or require removal of large portions of bowel.RETROPERITONEUMSurgical AnatomyThe retroperitoneum is bound by the peritoneum anteriorly, the iliopsoas and lumbar muscles posteriorly, the diaphragm superiorly, and the levator ani muscles inferiorly. It is divided into the three spaces: the anterior pararenal space, the perirenal space, and the posterior pararenal space (Fig. 35-12). The ante-rior pararenal space refers to the area anterior to the renal fascia but posterior to the peritoneum. This area contains the ascend-ing and descending colon, the duodenum, and the pancreas. Posterior to this space is the perirenal space, which houses the inferior vena cava, the aorta, kidneys, and adrenal glands. The posterior pararenal space is in continuity with preperitoneal fat of the anterior abdomen. Given the compliance of the anterior boundary of the retroperitoneum and the rigidity of other mar-gins, tumors, hematomas, and abscesses tend to expand anteri-orly toward the peritoneal cavity.With the expansion of minimally invasive techniques in surgery, the retroperitoneoscopic approach has emerged as a potential modality for access to retroperitoneal organs. Patients are positioned in the prone or lateral decubitus positions. The retroperitoneoscopic approach allows access to the kidneys, adrenal glands, and retroperitoneal lymph nodes. One system-atic review found no difference when comparing laparoscopic to retroperitoneoscopic adrenalectomy in terms of operative outcomes, complications, or postoperative recovery. Retroperi-toneoscopic approach did, however, lead to shorter hospital stay likely because of reduced postoperative pain. The majority of the studies evaluating the retroperitoneoscopic approach are retrospective, and more randomized trials are needed to provide further guidance.Retroperitoneal InfectionsInfections of the retroperitoneum can be due to primary hema-togenous spread of microbes or due to secondary infection from retroperitoneal or nearby organs. Examples include abscesses due to a perforated retrocecal appendix, diverticulitis, a con-tained perforated duodenal ulcer, iatrogenic perforation of the gastrointestinal tract, or pancreatitis. Patients may develop back, Inferiorvena cavaDiaphragmEsophagusAbdominal aortaSplenorenal ligamentPancreasRoot of transversemesocolonDuodenojejunaljunctionLeft kidneyPsoas majorInferior mesenteric arterySite of descending mesocolonRoot of sigmoidmesocolonRectumSite of barearea of liverHepatic portalveinDuodenumSuperiormesenteric vein and arterySite of ascending colonRoot of mesenteryTesticular (or ovarian) vesselsUreterAnterior viewRight kidneyRightparacolic gutterFigure 35-12. Anatomy of the retroperitoneum. (Reproduced with permission from Moore KL, Agur AM: Essential Clinical Anatomy, 5th edition. Philadelphia, PA: Lippincott Williams & Wilkins; 2014.)Brunicardi_Ch35_p1549-p1566.indd 156112/02/19 9:59 AM 1562SPECIFIC CONSIDERATIONSPART IIflank, or groin pain and suffer from fevers or chills. Depend-ing on severity, patients may present with fulminant sepsis. Abscesses may become quite large given the substantial retro-peritoneal space. On physical exam, patients may present with erythema of the umbilicus or flank. Abscesses are usually found easily on CT scan of the abdomen with IV contrast, which can also show if the collection is loculated. Treatment of retroperi-toneal abscesses includes source control via treatment of the underlying condition, drainage of well-defined collections, and IV antibiotics. Image guided drainage is preferred, but it may be unsuccessful if the abscess is multiloculated or in an inacces-sible area. For these cases, operative drainage may be required. Given the insidious nature of this disease and a lack of abdomi-nal findings on physical exam, recognition of a retroperitoneal abscess may be delayed. Delays in diagnosis and insufficient drainage may lead to high morbidity and mortality. Depending on severity, mortality of retroperitoneal abscess can be as high as 25%. Rarely, patients may develop necrotizing fasciitis of the retroperitoneum, a condition with high mortality.Retroperitoneal FibrosisRetroperitoneal fibrosis is a rare disease characterized by inflammation and fibrosis of the tissue of the retroperitoneum. It exists as a spectrum of disease with chronic periaortitis, which affects the retroperitoneal tissue near large arteries of the retro-peritoneum. Fibrosis gradually expands, encasing the ureters, inferior vena cava, aorta, mesenteric vessels, or sympathetic nerves. Bilateral involvement is noted in up to 70% of cases. The condition may either be idiopathic or due to a secondary cause, including aortic aneurysms, pancreatitis, certain drugs (Ergot-derivatives, β-blockers, hydralazine, methyldopa, among others), malignancies (including lymphoma, carcinoids, sarco-mas, colorectal, breast, and others), infections such as tuber-culosis, radiation, retroperitoneal hematoma, surgery, asbestos, or tobacco use. Retroperitoneal fibrosis has been described in association with several autoimmune disorders including anky-losing spondylitis, systemic lupus erythematosus, Wegener’s granulomatosis, and polyarteritis nodosa.Idiopathic retroperitoneal fibrosis accounts for 70% of cases and is thought to be an immune-mediated disorder. Theo-ries regarding the pathogenesis of idiopathic fibrosis of the retro-peritoneum include exaggerated local reactions to aortic or iliac atherosclerosis or autoimmune deposition of fibroinflammatory cytokines. Retroperitoneal fibrosis is also a manifestation of IgG4-related disease, a multisystem disease characterized by lymphocytic infiltrate and variable degrees of fibrosis of sev-eral affected organs. One study has associated retroperitoneal fibrosis with the HLA-DRB1*03 allelle, which has been linked to autoimmune diseases such as systemic lupus erythematosus, type 1 diabetes mellitus, and myasthenia gravis.Idiopathic retroperitoneal fibrosis is rare, with an incidence of 1.3 per 100,000 people per year. It most commonly affects individuals in the fourth to sixth decades of life. Some studies suggest a 2:1 male-to-female predominance, but others have not found a gender predilection. Patients with this condition present with nonspecific findings. Most patients are diagnosed after ure-teral obstruction. Patients may complain of dull or acute back or flank pain. Systemic complaints include anorexia, weight loss, nausea, vomiting, fever, and malaise. Decreased urinary out-put may ensue if the ureters become fibrotic. Because of renal artery impingement, patients are commonly hypertensive on exam. Other physical exam findings include lower extremity edema and diminished lower extremity pulses if the vessels of the lower extremities are compressed. New hydrocele or varico-cele can also be associated with fibrosis of the retroperitoneum. Laboratory analysis is also nonspecific. If there is renal obstruc-tion, patients may have elevated serum blood urea nitrogen and creatinine. Erythrocyte sedimentation rate and C-reactive pro-tein is elevated in most patients with retroperitoneal fibrosis. Antinuclear antibodies may also be elevated, highlighting the autoimmune nature of this disease.Contrast-enhanced CT scan is the modality of choice to visualize the extent of disease. On CT scan, fibrotic ret-roperitoneum appears to have similar attenuation to muscle tissue (Fig. 35-13). The fibrotic mass can appear to encase the aorta and often compresses the inferior vena cava. If renal insufficiency precludes the use of IV contrast, MRI can be used to clarify the extent of fibrosis. Renal US can also be used to document ureteral compression and hydronephrosis. In some cases, a compressing mass lesion can also be found on abdominal US. Lower-extremity US may show deep venous thrombosis.Pathologic examination of tissue is necessary to confirm the diagnosis and to rule out malignancy. Differential of ret-roperitoneal masses include lymphomas or sarcomas, desmoid Figure 35-13. Computed tomography findings of retroperitoneal fibrosis. Arrows point to a soft tissue mass surrounding the aorta and common iliac arteries. Also present is hydronephrosis of the right kidney because of ureteral compression. (Reproduced with permission from Vagilo A. Salvarani C, Buzio C. Retroperitoneal Fibrosis, Lancet. 2006 Jan 21;367(9506):241-251.)Brunicardi_Ch35_p1549-p1566.indd 156212/02/19 9:59 AM 1563ABDOMINAL WALL, OMENTUM, MESENTERY, AND RETROPERITONEUMCHAPTER 35tumors, and infections such as tuberculosis. Biopsy can be obtained either via image-guided or surgical techniques, which may be performed laparoscopically or during an open procedure.Once the diagnosis of retroperitoneal fibrosis is estab-lished, treatment is initiated. Surgical treatment is aimed at relieving ureteral obstruction either by ureterolysis or stenting. Surgery is reserved for patients who develop renal insufficiency as any surgical intervention in these patients car-ries several associated risks. In patients with secondary fibro-sis, treatment is aimed at the underlying etiology or discontinuation of the causative medication. For patients with idiopathic retroperitoneal fibrosis, corticosteroids are the mainstay of treatment. Patients are usually started on one month of high-dose prednisone, followed by maintenance therapy and subsequent taper. Alternatively, tamoxifen can be used if patients have contraindications to steroids. Within days of instituting therapy, symptoms and inflammatory markers should improve. Over the course of a few weeks, renal func-tion should improve. Interval imaging studies are usually obtained after 1 month to evaluate for efficacy. If steroids fail to cause regression of disease, patients can be started on immunosuppressant medications including methotrexate, aza-thioprine, cyclophosphamide, or mycophenolate mofetil. Recurrence of retroperitoneal fibrosis varies between studies from 10% to 30%. In patients who respond to steroid therapy, 5-year survival is as high as 90%.BIBLIOGRAPHYEntries highlighted in bright blue are key references.Aguirre DA, Santosa AC, Casola G, Sirlin CB. Abdominal wall her-nias: imaging features, complications, and diagnostic pitfalls at multi-detector row CT. RadioGraphics. 2005;25:1501-1520.Ahmad G, Gent D, Henderson D, O’Flynn H, Phillips K, Watson A. Laparoscopic entry techniques. Cochrane Data-base Syst Rev. 2015;8:CD006583. doi: 10.1002/14651858.CD006583.pub4Awaiz A, Rahman F, Hossain MB, et al. Meta-analysis and system-atic review of laparoscopic versus open mesh repair for elec-tive incisional hernia. Hernia. 2015;19:449-463. doi: 10.1007/s10029-015-1351-zBagade S, Khanna G. Imaging of omphalomesenteric duct remnants and related pathologies in children. Curr Probl Diagn Radiol. 2015;44:246-255.Beer GM, Schuster A, Seifert B, et al. The normal width of the linea alba in nulliparous women. Clin Anat. 2009;22(6):706-711. doi: 10.1002/ca.20836Berrevoet F, Vanlander A, Sainz-Barriga M, et al. Infected large pore meshes may be salvaged by topical negative pressure ther-apy. Hernia. 2013;17:67-73. doi: 10.1007/s10029-012-0969-3Bhangu A, Fitzgerald JE, Singh P, Battersby N, Marriott P, Pinkney T. Systematic review and meta-analysis of prophylactic mesh placement for prevention of incisional hernia follow-ing midline laparotomy. Hernia. 2013;17(4):445-455. doi: 10.1007/s10029-013-1119-2Bickenbach KA, Karanicolas PJ, Ammori JB, et al. Development of the ventral body wall in the human embryo. Ann Surg. 2013;227:276-281. doi: 10.1053/j.sempedsurg.2014.09.009Bickenbach KA, Karanicolas PJ, Ammori JB, et al. Up and down or side to side? A systematic review and meta-analysis examining the impact of incision on outcomes after abdominal surgery. Am J Surg. 2013;206:400-409. doi: 10.1016/j.amjsurg.2012.11.008Bilsel Y, Abci I. The search for ideal hernia repair; mesh materi-als and types. Int J Surg. 2012;10:317-321. doi: 10.1016/j.ijsu.2012.05.002Brown SR, Tiernan J. Transverse verses midline incisions for abdom-inal surgery. Cochrane Database Syst Rev. 2005;(4):CD005199. doi: 10.1002/14651858.CD005199.pub2Caro-Tarrago A, Olona Casas C, Jimenez Salido A, et al. Prevention of incisional hernia in midline laparotomy with an onlay mesh: a randomized clinical trial. World J Surg. 2014;38:2223-2230. doi: 10.1007/s00268-014-2510-6Conze J, Kingsnorth AN, Flament JB, et al. Randomized clinical trial comparing lightweight composite mesh with polyester or polypropylene mesh for incisional hernia repair. Br J Surg. 2005;92:1488-1493. doi: 10.1002/bjs.5208de Vries Reilingh TS, van Goor H, Rosman C, et al. “Compo-nents separation technique” for the repair of large abdominal wall hernias. J Am Coll Surg. 2003;196:32-37. doi: 10.1016/S1072-7515(02)01478-3Deerenberg EB, Harlaar JJ, Steyerberg EW, et al. Small bites versus large bites for closure of abdominal midline incisions (STITCH): a double-blind, multicentre, randomised con-trolled trial. Lancet. 2015;386(10000):1254-1260. doi: http://dx.doi.org/10.1016/S0140-6736(15)60459-7DeMaria EJ, Moss JM, Sugerman HJ. Laparoscopic intraperito-neal polytetrafluoroethylene (PTFE) prosthetic patch repair of ventral hernia. Surg Endosc. 2000;14:326-329. doi: 10.1007/s004640020013den Hartog D, Dur AHM, Tuinebreijer WE, Kreis RW. Open surgi-cal procedures for incisional hernias. Cochrane Database Syst Rev. 2008; doi: 10.1002/14651858.CD006438.pub2Ellis H. Applied anatomy of abdominal incisions. Br J Hosp Med. 2010;71:M36-M37. doi: 10.12968/hmed.2010.71.Sup3.46991Franz MG. The biology of hernia formation. Surg Clin North Am. 2008;88:1-15.García CM, Ruiz SG, Franco CC. Anatomy of the abdominal wall. In: Suárez Grau JM, Bellido Luque JA, eds. Advances in Lap-aroscopy of the Abdominal Wall Hernia. London: Springer; 2014:7-22.Halm JA, Heisterkamp J, Veen HF, Weidema WF. Long-term follow-up after umbilical hernia repair: are there risk factors for recurrence after simple and mesh repair. Hernia. 2005;9: 334-337. doi: 10.1007/s10029-005-0010-1Hanson J. Netter’s Clinical Anatomy. 3rd ed. Philadelphia: Elsevier; 2014.Hasson HM. A modified instrument and method for laparoscopy. Am J Obset Gynecol. 1971;110:886-887. doi: 10.1016/0002-9378(71)90593-XHegazy AA. Anatomy and embryology of umbilicus in newborns: a review and clinical correlations. Frontiers Med. 2016;10: 271-277. doi: 10.1007/s11684-016-0457-8Henrich K, Huemmer HP, Reingruber B, Weber PG. Gastroschisis and omphalocele: treatments and long-term outcomes. Ped Surg Int. 2008;24:167-173. doi: 10.1007/s00383-007-2055-yHoward JH, Pollock R. Intra-abdominal and abdominal wall des-moid fibromatosis. Oncol Ther. 2016;4:57-72.Inaba T, Okinaga K, Fukushima R, et al. Prospective randomized study of two laparotomy incisions for gastrectomy: midline incision versus transverse incision. Gastric Cancer. 2004;7: 167-171. doi: 10.1007/s10120-004-0291-6Le Huu Nho R, Mege D, Ouaïssi M, et al. Incidence and prevention of ventral incisional hernia. J Visc Surg. 2012;149:e3-e14.Lowe JB, Garza JR, Bowman JL, Rohrich RJ, Strodel WE. Endoscopically assisted “components separation” for closure of abdominal wall defects. Plast Reconstr Surg. 2000; 105(2):720-729.Luijendijk RW, Hop WCJ, van den Tol MP, et al. A compari-son of suture repair with mesh repair for incisional her-nia. N Engl J Med. 2000;343:392-398. doi: 10.1056/NEJM200008103430603Maingot R, Zinner M, Ashley SW. Maingot’s Abdominal Opera-tions. New York: McGraw-Hill Medical; 2013.8Brunicardi_Ch35_p1549-p1566.indd 156312/02/19 9:59 AM 1564SPECIFIC CONSIDERATIONSPART IIMcBurney C. IV. The incision made in the abdominal wall in cases of appendicitis, with a description of a new method of operat-ing. Ann Surg. 1894;20:38-43.Mekonen HK, Hikspoors JPJM, Mommen G, et al. Develop-ment of the ventral body wall in the human embryo. J Anat. 2015;227:673-685. doi: 10.1111/joa.12380Millbourn D, Cengiz Y, Israelsson L. Effect of stitch length on wound complications after closure of mid-line incisions. Arch Surg. 2009;144(11):1056-1059.Murphy KP, O’Connor OJ, Maher MM. Adult abdominal her-nias. Am J Roentgenol. 2014;202:W506-W511. doi: 10.2214/AJR.13.12071Mwachaka PM, Saidi HS, Odula PO, et al. Locating the arcuate line of Douglas: is it of surgical relevance? Clin Anat. 2010;23: 84-86. doi: 10.1002/ca.20877Nachiappan S, Markar S, Karthikesaligam A, et al. Prophylactic mesh placement in high-risk patients undergoing elective lapa-rotomy: a systematic review. World J Surg. 2013;37:1861-1871. doi: 10.1007/s00268-013-2046-1Palmer R. Safety in laparoscopy. J Reprod Med. 1974;13:1-5.Ponten JEH, Somers KYA, Nienhuijs SW. Pathogenesis of the epigastric hernia. Hernia. 2012;16:627-633. doi: 10.1007/s10029-012-0964-8Ramirez O, Ruas E, Dellon A. “Components separation” method for closure for abdominal-wall defects: an anatomic and clinical study. Plast Reconstr Surg. 1990;86(3):519-526.Rastegarpour A, Cheung M, Vardhan M, et al. Surgical mesh for ventral incisional hernia repairs: understanding mesh design. Plast Surg. 2016;24(1):41-50.Reilingh TS de V, van Goor H, Charbon JA, et al. Repair of giant midline abdominal wall hernias: “components separation tech-nique” versus prosthetic repair. World J Surg. 2007;31:756-763. doi: 10.1007/s00268-006-0502-xRozen WM, Ashton MW, Taylor GI. Reviewing the vascular supply of the anterior abdominal wall: redefining anatomy for increas-ingly refined surgery. Clin Anat. 2008;21:89-98. doi: 10.1002/ca.20585Salameh JR. Primary and unusual abdominal wall hernias. Surg Clin North Am. 2008;88:45-60. doi: 10.1016/j.suc.2007.10.004Sanders DL, Kingsnorth AN. The modern management of inci-sional hernias. BMJ. 2012;344:e2843. doi: 10.1136/bmj.e2843Seiler CM, Deckert A, Diener MK, et al. Midline versus trans-verse incision in major abdominal surgery: a randomized, double-blind equivalence trial (POVATI: ISRCTN60734227). Ann Surg. 2009;249(6):913-920.Skandalakis P, Odyseas Z, Skandalakis J, Petros M. Spigelian her-nia: surgical anatomy, embryology, and technique of repair. Am Surg. 2006;72:42-48.Timmermans L, de Goede B, van Dijk SM, et al. Meta-analysis of sublay versus onlay mesh repair in incisional hernia surgery. Am J Surg. 2014;207:980-988. doi: 10.1016/j.amjsurg.2013.08.030Wilder F, D’Angelo S, Crago AM. Soft tissue tumors of the trunk: management of local disease in the breast and chest and abdom-inal walls. J Surg Oncol. 2015;111:546-552. doi: 10.1002/jso.23843Zhang Y, Zhou H, Chai Y, Cao C, Jin K, Hu Z. Laparoscopic versus open incisional and ventral hernia repair: a systematic review and meta-analysis. World J Surg. 2014;38(9):2233-2240. doi: 10.1007/s00268-014-2578-zOmentumAbdulAziz A, El Zalabany T, Al Sayed AR, Al Ansari A. Idiopathic omental infarction, diagnosed and managed laparoscopi-cally: a case report. Case Rep Surg. 2013;2013:193546. doi: 10.1155/2013/193546Anyfantakis D, Kastanakis M, Petrakis G, et al. Rectus sheath hematoma in a single secondary care institution: a retrospective study. Hernia. 2015;19(3):509-512.Collins D, Hogan AM, O’Shea D, Winter DC. The omentum: ana-tomical, metabolic, and surgical aspects. J Gastrointest Surg. 2009;13:1138-1146. doi: 10.1007/s11605-009-0855-1Dedemadi G, Georgoulis G, Kontopanos D, et al. Extragastroin-testinal stromal tumors of the omentum: review apropos of a case with a novel gain-of-function KIT mutation. J Gastrointest Cancer. 2009;40:73-78. doi: 10.1007/s12029-009-9089-4Giovanni C, Riccardo V, Grazia EM, et al. Laparoscopic treatment of an omental cyst: a case report and review of the literature. Surg Laparosc Endosc Percutan Tech. 2005;15(1):33-35.Katagiri H, Honjo K, Nasu M, et al. Omental infarction due to omental torsion. Case Rep Surg. 2013;2013:373810. doi: 10.1155/2013/373810Kranendonk MEG, van Herwaarden JA, Stupkova T, et al. Inflam-matory characteristics of distinct abdominal adipose tissue depots relate differently to metabolic risk factors for cardiovascular disease. Atherosclerosis. 2017;239:419-427. doi: 10.1016/j.atherosclerosis.2015.01.035Morison R. Remarks on some functions of the Omentum. Br Med J. 1906;1(2350):76-78.Motie MR, Asadi M. Large omental cyst: a case report and review of the literature. Acta Medica Iranica. 2011;49(10):690-693.Mouaqit O, Jahid A, Ifrine L, et al. Primary omental gastrointestinal stromal tumors. Clin Res Hepatol Gastroenterol. 2011;35: 590-593. doi: http://dx.doi.org/10.1016/j.clinre.2010.11.012Occhionorelli S, Zese M, Cappellari L, et al. Acute abdomen due to primary omental torsion and infarction. Case Rep Surg. 2014;2014:208382. doi: 10.1155/2014/208382Park TU, Oh JH, Chang IT, et al. Omental infarction: case series and review of the literature. J Emerg Med. 2017;42:149-154. doi: 10.1016/j.jemermed.2008.07.023Platell C, Cooper D, Papadimitriou JM, Hall JC. The omentum. World J Gastroenterol. 2000;6:169-176. doi: 10.3748/wjg.v6.i2.169Rangel-Moreno J, Moyron-Quiroz JE, Carragher DM, et al. Omental milky spots develop in the absence of lymphoid tissue-inducer cells and support B and T cell responses to peritoneal antigens. Immunity. 2017;30:731-743. doi: 10.1016/j.immuni.2009.03.014Rao TN, Parvathi T, Suvarchala A. Omental lymphangioma in adults—rare presentation report of a case. Case Rep Surg. 2012;2012:629482. doi: 10.1155/2012/629482Schwartz R, Reames M, McGrath P, et al. Primary solid neoplasms of the greater omentum. Surgery. 1991;109:543-539.Seow-En I, Seow-Choen F, Lim TKH, Leow WQ. Primary omen-tal gastrointestinal stromal tumour (GIST) presenting with a large abdominal mass and spontaneous haemoperitoneum. BMJ Case Rep. 2014;2014:bcr2014205528. doi: 10.1136/bcr-2014-205528Tarantino G, Lobello R, Scopacasa F, et al. The contribution of omen-tal adipose tissue to adipokine concentrations in patients with the metabolic syndrome. Clin Invest Med. 2007;30:E192–E199.Uramatsu M, Saida Y, Nagao J, et al. Omental cyst: report of a case. Surg Today. 2001;31:1104-1106. doi: 10.1007/s595-001-8068-0Yoo E, Kim JH, Kim M-J, et al. Greater and lesser omenta: nor-mal anatomy and pathologic processes. RadioGraphics. 2007;27:707-720. doi: 10.1148/rg.273065085MesenteryAdams SD, Stanton MP. Malrotation and intestinal atre-sias. Early Hum Dev. 2017;90:921-925. doi: 10.1016/j.earlhumdev.2014.09.017Akram S, Pardi DS, Schaffner JA, Smyrk TC. Sclerosing mesenteritis: clinical features, treatment, and outcome in ninety-two patients. Clin Gastroenterol Hepatol. 2017;5: 589-596. doi: 10.1016/j.cgh.2007.02.032Avincsal MO, Otani K, Kanzawa M, et al. Sclerosing mes-enteritis: a real manifestation or histological mimic of Brunicardi_Ch35_p1549-p1566.indd 156412/02/19 9:59 AM 1565ABDOMINAL WALL, OMENTUM, MESENTERY, AND RETROPERITONEUMCHAPTER 35IgG4-related disease? Pathol Int. 2016;66(3):158-163. doi: 10.1111/pin.12386Coffey JC, O’Leary DP. The mesentery: structure, function, and role in disease. Lancet Gastroenterol Hepatol. 2017;1(3): 238-247. doi: 10.1016/S2468-1253(16)30026-7Daskalogiannaki M, Voloudaki A, Prassopoulos P, et al. CT evalu-ation of mesenteric panniculitis. Am J Roentgenol. 2000;174: 427-431. doi: 10.2214/ajr.174.2.1740427Del Gobbo A, Bimbatti M, Ferrero S. A case report of mesenteric mucinous cystoadenoma with review of the literature. BMC Gastroenterol. 2010;10:105. doi: 10.1186/1471-230X-10-105Dequanter D, Lefebvre J, Belva P, Takieddine M, Vaneukem P. Mes-enteric cyst. A case treated by laparoscopy and a review of the literature. Surg Endosc. 2002;16(10):1493.Ezhapilli SR, Moreno CC, Small WC, et al. Mesenteric masses: approach to differential diagnosis at MRI with histopathologic correlation. J Magn Reson Imaging. 2014;40(4):753-769. doi: 10.1002/jmri.24690Halabi WJ, Jafari MD, Kang CY, et al. Colonic volvulus in the United States: trends, outcomes, and predictors of mortality. Ann Surg. 2014;259(2):293-301.Horton KM, Lawler LP, Fishman EK. CT findings in sclerosing mesenteritis (panniculitis): spectrum of disease. RadioGraph-ics. 2003;23:1561-1567. doi: 10.1148/rg.1103035010Hussein MRA, Abdelwahed SR. Mesenteric panniculitis: an update. Exp Rev Gastroenterol Hepatol. 2015;9:67-78. doi: 10.1586/17474124.2014.939632Kikiros CS, Edis AJ. Mesenteric panniculitis resulting in bowel obstruction: response to steroids. N Z J Surg. 1989;59(3): 287-290. doi: 10.1111/j.1445-2197.1989.tb01565.xKirby R, Rajasagaram N, Ghusn M. Primary mesenteric gastroin-testinal stromal tumour. J Surg Case Rep. 2014;2014:rju050. doi: 10.1093/jscr/rju050Park I-S, Kye B-H, Kim H-S, et al. Primary mesenteric carcinoid tumor. J Korean Surg Soc. 2013;84:114-117. doi: 10.4174/jkss.2013.84.2.114Parra-Davila E, McKenney M, Sleeman D, et al. Mesenteric panniculitis: case report and literature review. Am Surg. 1998;64:768-771.Peng L, Yang L, Wu N, Wu B. Primary primitive neuroectoder-mal tumor arising in the mesentery and ileocecum: a report of three cases and review of the literature. Exp Ther Med. 2015;9(4):1299-1303. doi: 10.3892/etm.2015.2242Rajendran S, Khan A, Murphy M, O’Hanlon D. The diagnosis and treatment of a symptomatic mesenteric cyst. BMJ Case Reports. 2014;2014:bcr2013202410. doi: 10.1136/bcr-2013-202410Salar O, El-Sharkawy AM, Singh R, Speake W. Internal her-nias: a brief review. Hernia. 2013;17:373-377. doi: 10.1007/s10029-012-1023-1Tan JJ-Y, Tan K-K, Chew S-P. Mesenteric cysts: an institution experience over 14 years and review of literature. World J Surg. 2009;33:1961-1965. doi: 10.1007/s00268-009-0133-0van Putte-Katier N, van Bommel EFH, Elgersma OE, Hendriksz TR. Mesenteric panniculitis: prevalence, clinicoradiological presentation and 5-year follow-up. Br J Radiol. 2014;87:20140451. doi: 10.1259/bjr.20140451RetroperitoneumConstantinides VA, Christakis I, Touska P, Palazzo FF. System-atic review and meta-analysis of retroperitoneoscopic versus laparoscopic adrenalectomy. Br J Surg. 2012;99:1639-1648. doi: 10.1002/bjs.8921Goenka AH, Shah SN, Remer EM. Imaging of the retroperitoneum. Radiol Clin North Am. 2017;50(2):333-355. doi: 10.1016/j.rcl.2012.02.004Huang S-H, Lo W-O, Lin C-M, et al. Retroperitoneal abscess: 7-year experience of 29 cases in a tertiary care center in Taiwan. Urol Sci. 2015;26:218-221. doi: http://dx.doi.org/10.1016/j.urols.2015.01.009Kermani TA, Crowson CS, Achenbach SJ, Luthra HS. Idio-pathic retroperitoneal fibrosis: a retrospective review of clini-cal presentation, treatment, and outcomes. Mayo Clin Proc. 2011;86(4):297-303. doi: 10.4065/mcp.2010.0663Knezevic S, Ignjatovic I, Lukic S, et al. Primary retroperitoneal mucinous cystadenoma: a case report. World J Gastroenterol. 2015;21(17):5427-5431. doi: 10.3748/wjg.v21.i17.5427Martorana D, Vaglio A, Greco P, et al. Chronic periaortitis and HLA–DRB1*03: another clue to an autoimmune origin. Arthri-tis Care Res. 2006;55:126-130. doi: 10.1002/art.21698Messiou C, Moskovic E, Vanel D, et al. Primary retroperitoneal soft tissue sarcoma: imaging appearances, pitfalls and diag-nostic algorithm. Eur J Surg Oncol. 2017;43(7):1191-1198. doi: 10.1016/j.ejso.2016.10.032Miralas P, Skandalakis J. Surgical Anatomy of the retroperitoneal spaces part II: the architecture of the retroperitoneal space. Am Surg. 2010;76(1):33-42.Osman S, Lehnert B, Eloseimy S, et al. A comprehensive review of the retroperitoneal anatomy, neoplasms, and pattern of disease spread. Curr Probl Diagn Radiol. 2013;42(5):191-208.Scali EP, Chandler TM, Heffernan EJ, Coyle J, Harris AC, Chang SD. Primary retroperitoneal masses: what is the differential diagnosis? Abdom Imaging. 2015;40:1887-1903. doi: 10.1007/s00261-014-0311-xScheel P, Feeley N. Retroperitoneal fibrosis: the clinical, labora-tory, and radiographic presentation. Medicine (Baltimore). 2009;88(4):202-207.Stone JR. Aortitis, periaortitis, and retroperitoneal fibrosis, as mani-festations of IgG4-related systemic disease. Curr Opin Rheu-matol. 2011;23(1):88-94.Vaglio A, Salvarani C, Buzio C. Retroperitoneal fibrosis. Lancet. 2017;367(9506):241-251. doi: 10.1016/S0140-6736(06)68035-5van Bommel EFH, Siemes C, Hak LE, et al. Long-term renal and patient outcome in idiopathic retroperitoneal fibrosis treated with prednisone. Am J Kidney Dis. 2017;49:615-625. doi: 10.1053/j.ajkd.2007.02.268Brunicardi_Ch35_p1549-p1566.indd 156512/02/19 9:59 AM
Brunicardi_Ch35_p1549-p1566.indd 156612/02/19 9:59 AMThis page intentionally left blankINTRODUCTIONSarcomas are a heterogeneous group of neoplasms that arise predominantly from cells of the embryonic mesoderm. While the majority of sarcomas are soft tissue sarcomas, other types of sarcoma include bone sarcomas (osteosarcoma, chondrosarcoma, and rare bone tumors like chordoma, angiosar-coma, and leiomyosarcoma of bone) and Ewing’s sarcoma/peripheral primitive neuroectodermal tumor, which can occur either in the bone or in the soft tissues. The primary focus of this chapter is soft tissue sarcomas. Most primary soft tissue sarco-mas originate in an extremity (50–60%); the next most common sites are the trunk (19%), retroperitoneum (15%), and head and neck (9%). The anatomic site of a primary sarcoma influ-ences treatment and outcome.1Soft tissue sarcomas include more than 70 histologic sub-types (Table 36-1). Historically, the most common subtypes in adults (excluding Kaposi’s sarcoma) were malignant fibrous histiocytoma (28%), liposarcoma (15%), leiomyosarcoma (12%), synovial sarcoma (10%), and malignant peripheral nerve sheath tumor (6%).2 Today, malignant fibrous histiocytoma is classified as either leiomyosarcoma, pleomorphic undifferenti-ated sarcoma, myxofibrosarcoma, or dedifferentiated liposar-coma based on cellular differentiation and genetics. Embryonal/alveolar rhabdomyosarcomas are the most common soft tissue sarcomas of childhood, whereas pleomorphic rhabdomyosar-coma occurs predominantly in adults, and although it shares part 12of the name, it has a different biology and should not be treated as a pediatric sarcoma.During the past 25 years, patients with extremity sarcomas have been treated with a multimodality approach, which has led to some improvements in survival, local control, and quality of life.3 However, patients with abdominal sarcomas con-tinue to have high rates of recurrence and poor overall survival.4 The overall 5-year survival rate for patients with all stages of soft tissue sarcoma is 50% to 60%. Of the patients who die of sarcoma, most succumb to lung metastasis, which 80% of the time occurs within 2 to 3 years after initial diagnosis.INCIDENCEIn the United States in 2012, approximately 11,280 new cases of soft tissue sarcoma were diagnosed, and 3900 deaths were attributable to this disease.5 The incidence of soft tissue sarcomas increased 1.3% per year from 1995 to 2009, and subsequently leveled off while mortality rates increased slightly (0.5% per year) from 2001 to 2014.5 The true incidence of sarcoma is thought to be higher than reported, and gastrointestinal stromal tumors (GISTs) likely account for an additional 5000 new sarcoma cases per year.1 Overall, sarcomas affect 5 to 6 individuals per 100,000 inhabitants per year,6 accounting for less than 1% of all malignancies in adults and 15% of malignancies in children.7345Soft Tissue SarcomasRicardo J. Gonzalez, Alessandro Gronchi, and Raphael E. Pollock 36chapterIntroduction1567Incidence1567Epidemiology1568Radiation Exposure / 1568Occupational Chemical Exposure / 1568Trauma / 1568Chronic Lymphedema / 1568Molecular Pathogenesis1569Translocation-Associated Sarcomas / 1569Amplification-Associated Sarcomas / 1569Oncogenic Mutations / 1569Complex Genomic Rearrangements / 1570Initial Assessment1570Clinical Presentation / 1570Diagnostic Imaging / 1570Biopsy Techniques / 1571Pathologic Assessment and Classification / 1572Staging and Prognostic Factors / 1573Treatment of Extremity and Trunk Wall Sarcoma1574Surgery / 1575Radiation Therapy / 1577Systemic Therapy / 1578Concurrent Chemoradiation Therapy / 1580Posttreatment Surveillance / 1580Management of Recurrent Sarcoma / 1581Special Clinical Situations1582Myxoid Liposarcoma / 1582Retroperitoneal Sarcoma / 1582Gastrointestinal Sarcoma / 1583Breast Sarcoma / 1584Uterine Sarcoma / 1584Gastrointestinal Stromal Tumors1585Radiologic Assessment / 1585Management of Localized Disease / 1585Management of Locally Advanced or Metastatic Disease / 1585Multidisciplinary Treatment / 1586Postoperative Imatinib / 1586Preoperative Imatinib / 1587Desmoids1588Dermatofibrosarcoma Protuberans1588Pediatric Sarcomas1589Rhabdomyosarcoma / 1589Nonrhabdomyosarcoma Soft Tissue Sarcomas / 1589Research Perspectives1590Conclusions1590Brunicardi_Ch36_p1567-p1598.indd 156701/03/19 6:38 PM 1568Table 36-1Relative frequency of histologic subtypes of soft tissue sarcomaHISTOLOGIC SUBTYPESNO.%Liposarcoma18815Leiomyosarcoma14812Unclassified sarcoma14011Synovial sarcoma12510Malignant peripheral nerve sheath tumor726Rhabdomyosarcoma605Fibrosarcoma383Ewing sarcoma252Angiosarcoma252Osteosarcoma141Epithelioid sarcoma141Chondrosarcoma131Clear cell sarcoma121Alveolar soft part sarcoma71Malignant hemangiopericytoma50.4Data from Coindre JM, Terrier P, Guillou L, et al. Predictive value of grade for metastasis development in the main histologic types of adult soft tissue sarcomas: a study of 1240 patients from the French Federation of Cancer Centers Sarcoma Group, Cancer. 2001 May 15;91(10):1914-1926.EPIDEMIOLOGYExcept for malignant peripheral nerve sheath tumors in patients with neurofibromatosis, sarcomas do not seem to result from progression or dedifferentiation of a benign soft tissue tumor. While most sarcomas are of unknown cause, a few sarcoma sub-types have been observed in settings suggesting etiology.Radiation ExposureExternal radiation therapy is a rare but well-established risk factor for soft tissue sarcoma that may be associated with radiation-induced mutations of the p53 gene.8 The incidence of sarcoma among patients who are often treated with radiation for cancer of the breast, cervix, ovary, testes, or lymphatic system is 8 to 50 times the general-population risk.9,10 In a review of 160 patients with postirradiation sarcomas, the most common histologic types were osteogenic sarcoma, pleomorphic undifferentiated sarcoma, angiosarcoma, and lymphangiosarcoma.9 The risk of developing a sarcoma increased with radiation dose, and the median time between radiation therapy and diagnosis of sarcoma was 10 years.9 A review of 44 patients with radiation-associated sarcomas identified between 1989 and 2009 noted that the average period from initial radiation treatment to diagnosis was 16 years and that radiation-associated sarcomas occurred most commonly in patients treated for breast cancer (36% of the patients in the series) and lymphoma (34% of the patients in the series).11 The 5-year overall survival rate for patients presenting without metastasis was 44%. A recent review of undifferentiated pleomorphic sarcoma characterizing outcomes between sporadic and radiation-associated presentation identified a higher incidence of local recurrence and worse overall and disease specific survival among patients who presented with radiation-associated undifferentiated pleomorphic sarcoma.12Occupational Chemical ExposureExposure to herbicides such as phenoxyacetic acids and to wood preservatives containing chlorophenols has been linked to an increased risk of soft tissue sarcoma.13 Several chemi-cal carcinogens, including thorium oxide (Thorotrast), vinyl chloride, and arsenic, have been associated with hepatic angiosarcomas.14TraumaAlthough patients with sarcoma often report a history of trauma, no causal relationship has been established. More often, a minor injury calls attention to a preexisting tumor.Chronic LymphedemaIn 1948, Stewart and Treves first described the association between chronic lymphedema after axillary dissection and sub-sequent lymphangiosarcoma (Fig. 36-1).15 Lymphangiosarcoma has been estimated to occur in 0.07% of patients who undergo axillary node dissection.16 It also has been reported to occur after filarial infections and in the lower extremities of patients with congenital lymphedema.17,18 Lymphangiosarcoma is gen-erally an aggressive tumor; average survival of patients with lymphangiosarcoma is 19 months.19Key Points1 Sarcomas are a heterogeneous group of tumors that can occur throughout the body and encompass more than 50 subtypes with distinct histologic lines of differentiation.2 Approximately two-thirds of soft tissue sarcomas arise in the extremities; the remaining one-third is distributed between the retroperitoneum, trunk, abdomen, head, and neck.3 Multimodality treatment, including surgical resection, radia-tion therapy, and, in selected cases, systemic chemotherapy, has been applied to patients with locally advanced, high-grade, extremity sarcomas.4 Overall 5-year survival rate for patients with all stages of soft tissue sarcoma is 50% to 60%.5 These rare tumors account for less than 1% of cancer in adults (estimated 10,000 cases per year in the United States) and represent 15% of cancers in children.6 The treatment algorithm for soft tissue sarcomas depends on tumor stage, site, and histology.7 Of the patients who die of sarcoma, most will succumb to metastatic disease in the lungs, which 80% of the time occurs within 2 to 3 years of the initial diagnosis.8 Progress in the understanding of soft tissue sarcoma biology is crucial for the development of new treatments.Brunicardi_Ch36_p1567-p1598.indd 156801/03/19 6:38 PM 1569SOFT TISSUE SARCOMASCHAPTER 36Figure 36-1. A 57-year-old with a chronic, progressive lymph-edema of the left upper extremity developed lymphangiosarcoma 10 years after breast cancer treatment.Table 36-2Fusion transcripts in soft tissue sarcomaDIAGNOSISCHROMOSOMAL ABNORMALITYGENES INVOLVEDAlveolar rhabdomyosarcomat(2;13)(q35;q14)t(1;13)(p36;q14)PAX3-FKHRPAX7-FKHRAlveolar soft part sarcomat(X;17)(p11.2;q25)TFE3-ASPLAngiomatoid fibrous histiocytomat(12;16)(q13;p11)FUS-ATF1Clear cell sarcomat(12;22)(q13;q12)EWS-ATF1Congenital fibrosarcoma/congenital mesoblastic nephromat(12;15)(p13;q25)ETV6-NTRK3Dermatofibrosarcoma protuberanst(17;22)(q22;q13)PDFGB-COL1A1Desmoplastic small round cell tumort(11;22)(p13;q12)EWS-WT1Endometrial stromal sarcomat(7;17)(p15;q21)JAZF1-JJAZ1Ewing’s sarcoma/peripheral primitive neuroectodermal tumort(11;22)(q24;q12)t(21;22)(q22;q12)t(7;22)(p22;q12)t(17;22)(q12;q12)t(2;22)(q33;q12)t(16;21)(p11;q22)EWS-FLI1EWS-ERGEWS-ETV1EWS-FEVEWS-E1AFFUS-ERGLow-grade fibromyxoid sarcomat(7;16)(q33;p11)FUS-CREB3I2Inflammatory myofibroblastic tumort(1;2)(q22;p23)t(2;19)(p23;p13)t(2;17)(p23;q23)TPM3-ALKTPM4-ALKCLTC-ALKMyxoid liposarcomat(12;16)(q13;p11)t(12;22)(q13;q12)TLS-CHOPEWS-CHOPMyxoid chondrosarcomat(9;22)(q22;q12)t(9;15)(q22;q21)t(9;17)(q22;q11)EWS-CHNTFC12-CHNTAF2N-CHNSynovial sarcomat(x;18)(p11;q11)SSX1-SYTSSX2-SYTSSX4-SYTMOLECULAR PATHOGENESISSarcomas can be broadly classified into three groups accord-ing to the genetic events underlying their development: specific translocations or gene amplification, defining oncogenic muta-tions, and complex genomic rearrangements.20 In general, sar-comas resulting from identifiable molecular events tend to occur in younger patients with histology suggesting a clear line of differentiation. The identifiable molecular events include point mutations, translocations causing overexpression of an autocrine grow factor, and oncogenic fusion transcription factor produc-ing a cellular environment prone to malignant transformation. In contrast, sarcomas without identifiable genetic changes or expression profile signatures tend to occur in older patients and exhibit pleomorphic cytology and p53 dysfunction.21 Improved understanding of the molecular pathogenesis of sarcomas has revealed several potential targets against which investigators are working to develop subtype-specific targeted therapy.Translocation-Associated SarcomasTo date, translocations have been identified in 14 subtypes of soft tissue sarcoma, accounting for 20% to 30% of all sarcomas22 (Table 36-2). Translocations result in in-frame gene fusion, which in turn results in fused products encoding oncoproteins that function as transcriptional activators or repressors.23,24 The best characterized gene fusions are in Ewing’s sarcoma (EWS-FLI1), clear cell sarcoma (EWS-ATF1), myxoid/round cell liposarcoma (TLS-CHOP), alveolar rhabdomyosarcoma (PAX3-FHKR), desmoplastic small round cell tumor (EWS-WT1), and synovial sarcoma (SS18-SSX). Fusion gene–related sarcomas have been estimated to account for 30% or more of all sarcomas.25Direct or indirect interactions between fusion transcripts and cell cycle regulators have been elucidated by several inves-tigators and identify these transcripts as potentially promising molecular therapeutic targets.26 However, fusion genes in sar-coma have been successfully targeted in only a few cases, in which fusion resulted in overexpression of a growth factor or growth factor receptor. Several growth factors and their recep-tors (e.g., epidermal growth factor receptor) previously reported to play an important role in autocrine or paracrine stimulation of carcinoma growth have been associated with high histologic grade and poor prognosis in soft tissue sarcomas.Amplification-Associated SarcomasOncogenes are genes that can induce malignant transformation and tend to drive cell proliferation. Several oncogenes have been associated with soft tissue sarcomas, including MDM2, N-myc, c-erbB2, and members of the ras family. These onco-genes produce specific oncoproteins that either play a role in nuclear function and cellular signal transduction or function as growth factors or growth factor receptors. This typically occurs in dedifferentiated liposarcoma, where the amplification of MDM2 drives the neoplastic process. Amplification of these genes has been shown to correlate with adverse outcome in sev-eral types of soft tissue sarcoma.23Oncogenic MutationsGISTs are the classic example of sarcomas in which tumorigen-esis is primarily driven by a single activating mutation, in the Brunicardi_Ch36_p1567-p1598.indd 156901/03/19 6:38 PM 1570SPECIFIC CONSIDERATIONSPART IIgene encoding KIT receptor tyrosine kinase or platelet-derived growth factor receptor-α (PDGFRA).20 The majority of GISTs have mutations in either exon 11 or exon 9 of KIT and respond dramatically to the tyrosine kinase inhibitor imatinib mesylate, although this treatment rarely produces cure.Complex Genomic RearrangementsThe largest group of sarcomas is the group with complex cytoge-netic alterations, which includes high-grade spindle cell sarco-mas and pleomorphic sarcomas.20 Many sarcomas in this group exhibit inactivation of tumor suppressor genes. The two genes most relevant to soft tissue sarcoma are retinoblastoma (Rb) and p53. Mutations or deletions in Rb can lead to retinoblastoma, the most common malignant ocular neoplasm of childhood. Survi-vors of retinoblastoma are at risk for developing soft tissue and bone sarcomas later in life. Patients with germline mutations in p53 (Li-Fraumeni syndrome) have a high incidence of soft tissue sarcomas Mutant p53 expression is thought to correlate with poor overall survival.23 Strategies to target p53 mutation are being investigated for treatment of some sarcomas.Neurofibromatosis type 1 (von Recklinghausen’s disease) occurs in approximately 1 of every 3000 people and is due to various mutations in the NF-1 tumor suppressor gene, located on chromosome 17. Patients with neurofibromatosis type 1 have an estimated 3% to 15% additional risk of malignant disease compared with the general population lifetime risk, including malignant peripheral nerve sheath tumors (MPNST) and GIST. In turn, 25% to 50% of patients with MPNST have a mutation in NF-1.27INITIAL ASSESSMENTThe clinical behavior of most soft tissue sarcomas is determined by anatomic location (depth in relation to the investing fascia), histologic subtype and grade of aggressiveness, and size. The dominant pattern of metastasis is hematogenous, primarily to the lungs. Lymph node metastasis is rare (affecting <5% of patients) except in a few histologic subtypes, including epi-thelioid sarcoma, pediatric rhabdomyosarcoma, clear cell sar-coma, angiosarcoma, and, more rarely, synovial sarcoma and myxofibrosarcoma.28Clinical PresentationSoft tissue sarcomas most commonly present as an asymptom-atic mass. Extremity sarcomas may present as a deep venous thrombosis, particularly in patients without significant risk factors for thrombosis.29 Tumors in the distal extremities are generally smaller, whereas tumors in the proximal extremities and retroperitoneum can grow quite large before becoming apparent. Tumors often grow centrifugally and can compress surrounding normal structures. Infrequently, tumor impinge-ment on bone or neurovascular bundles produces pain, edema, and swelling. Less frequently, tumors cause obstructive gastro-intestinal symptoms or neurologic symptoms related to com-pression of lumbar or pelvic nerves. Often an extremity mass is discovered after a traumatic event that draws attention to a preexisting lesion.The differential diagnosis of a soft tissue mass should include consideration of lipoma (which is 100 times more com-mon than sarcoma), lymphangioma, leiomyoma, neurinoma, primary or metastatic carcinoma, melanoma, and lymphoma. Superficial small lesions (<5 cm) that are new or that are not enlarging as indicated by clinical history can be observed. Figure 36-2. A 55-year-old man with a leiomyosarcoma involving the inferior vena cava. Note the displacement of the inferior vena cava to the right hemiabdomen adjacent to the liver (arrow).Enlarging masses and masses larger than 5 cm or deep to the fascia should be evaluated with a history, imaging, and biopsy.30Diagnostic ImagingDiagnostic imaging of the primary should be performed before any invasive procedure to avoid the possibility of soft tissue swelling or hemorrhage complicating the image interpretation. Pretreatment diagnostic imaging is helpful for defining the size and anatomic location of a tumor and its proximity to adjacent structures; staging disease with respect to regional or metastatic spread; guiding percutaneous biopsy; and establishing whether a tumor is benign or malignant and low grade or high grade.Radiographs are useful in the evaluation of primary bone tumors but not in the evaluation of soft tissue sarcomas of the extremities unless there is underlying bone involvement from an adjacent soft tissue tumor or mineralization patterns sugges-tive of histologic subtype. Magnetic resonance imaging (MRI) is the preferred imaging technique for soft tissue sarcomas of the extremities, whereas computed tomography (CT) is most use-ful for evaluating retroperitoneal, intra-abdominal, and truncal sarcomas.31 CT of the chest should be performed to assess for lung metastases in patients with high-grade tumors larger than 5 cm; while chest X-ray is sufficient for smaller or low-grade lesions. Abdominal/pelvic CT should be performed in patients with myxoid round cell liposarcomas, leiomyosarcomas, epi-thelioid sarcomas, or angiosarcomas because of their propensity to metastasize to the abdomen and/or pelvis.1 Total Spine MRI has been advocated for myxoid round cell liposarcoma.1 MRI of the brain should be considered for patients with alveolar soft part sarcomas and angiosarcomas because of their propensity to metastasize to the brain.Ultrasonography. Ultrasonography may have a diagnostic role in patients with soft tissue sarcoma who cannot undergo MRI. Ultrasonography can also be a useful adjunct to MRI when findings on MRI are indeterminate and for delineating adjacent vascular structures. Finally, ultrasonography can be used for postoperative surveillance and to guide biopsies.Computed Tomography. Chest CT should be performed to evaluate for lung metastasis at presentation and before any radi-cal treatment. CT is also the preferred imaging technique for evaluating retroperitoneal sarcomas (Fig. 36-2).31 Current CT Brunicardi_Ch36_p1567-p1598.indd 157001/03/19 6:38 PM 1571SOFT TISSUE SARCOMASCHAPTER 36techniques can provide a detailed image of the abdomen and pelvis and can delineate adjacent organs and vascular struc-tures. For extremity sarcomas, CT may be useful if MRI is not available or cannot be used. When histologic assessment of an extremity sarcoma reveals a myxoid liposarcoma, CT of the abdomen and pelvis should be done because this subtype is known to metastasize to the abdomen.32Magnetic Resonance Imaging. MRI is the most useful imag-ing modality for extremity sarcomas because of its superior soft tissue contrast resolution and multiplanar capabilities. MRI accurately delineates muscle groups and distinguishes among bone, vascular structures, and tumor. Sagittal and coronal views allow evaluation of anatomic compartments in three dimensions (Fig. 36-3). Soft tissue sarcomas of the extremities usually present on MRI as a heterogeneous mass. Their signal inten-sity tends to be equal to or slightly higher than that of adjacent skeletal muscle on T1-weighted images and heterogeneous and high on T2-weighted images. Hemorrhagic, cystic, or necrotic changes may also be observed in the tumor. If adjacent vas-cular structures must be delineated, special MRI techniques may be performed, including magnetic resonance angiography. MRI may also be an important adjunct to cytologic analysis in distinguishing benign lesions such as lipomas, hemangiomas, schwannomas, neurofibromas, and intramuscular myxomas from their malignant counterparts. In patients undergoing pre-operative chemotherapy, contrast-enhanced T1-weighted MRI can be useful in evaluating intratumoral necrosis.MRI is also valuable for assessing tumor recurrence after surgery. A baseline image is usually obtained 3 months after surgery. Some clinicians forego routine postoperative imaging of the primary extremity tumor site in asymptomatic patients, citing the difficulties in detecting early recurrence in scarred, irradiated tissue.31 Others advocate routine imaging every 3 to 4 months for the first 2 years, every 6 months in years 3 through 5, and then annually.Positron Emission Tomography. Positron emission tomogra-phy (PET) is a functional imaging modality that measures tumor uptake of the glucose analog [18F] fluorodeoxyglucose (FDG). Figure 36-3. A 62-year-old man presented with right thigh mass. Magnetic resonance imaging demonstrated an 18 × 15 cm2 dedifferentiated liposarcoma within the posterior compartment. Note the atypical fatty mass (left) with a large necrotic and peripherally enhancing nodule (left).PET imaging allows evaluation of the entire body. Although PET/CT may be useful in specific circumstances, FDG-PET is not currently recommended for the initial staging of patients with soft tissue sarcoma.Roberge and colleagues compared FDG-PET/CT versus chest CT alone in the initial staging of 75 patients with soft tissue sarcoma and found that only one patient had disease upstaged as a result of PET, whereas two had false-positive find-ings and three had indeterminate findings with no subsequent development of metastasis.33 Previous studies that reported a marginal benefit of PET/CT for detecting metastasis at the time of sarcoma staging included patients with more heterogeneous tumors, such as osseous tumors, soft tissue osteosarcomas, Ewing’s sarcoma, and rhabdomyosarcoma.34-36In patients with sarcoma, PET has primarily been used to assist with tumor grading and to assess response to chemotherapy.37-40 In 50 patients with resectable high-grade soft tissue tumors scheduled for preoperative chemotherapy and tumor resection, a 35% or greater reduction in tumor FDG uptake following an initial cycle of chemotherapy was associated with histopathologic tumor response defined as pathologic necrosis in 95% or more of the resected specimen.41 While this is helpful in determining response controversy exists as to whether this translates into a predictor of overall survival.Biopsy TechniquesFine-Needle Aspiration. At centers where cytopathologists have experience with evaluation of mesenchymal tumors, fine-needle aspiration is an acceptable method of diagnosing most soft tissue sarcomas, particularly when the results correlate closely with clinical and radiologic findings.42 Fine-needle aspiration of primary tumors has a lower diagnostic accuracy rate (60–90%) than core needle biopsy and is often not sufficient for establish-ing a specific histologic diagnosis and grade.43 However, fine-needle aspiration is the procedure of choice to confirm or rule out the presence of a metastatic focus or local recurrence.44Although fine-needle aspiration of superficial lesions can often be done in the clinic, fine-needle aspiration of deeper tumors may need to be done by an interventional radiologist Brunicardi_Ch36_p1567-p1598.indd 157101/03/19 6:38 PM 1572SPECIFIC CONSIDERATIONSPART IIunder sonographic or CT guidance. Generally, a 21to 23-gauge needle is introduced into the mass after appropriate cleansing of the skin and injection of local anesthetic. Negative pressure is applied, and the needle is moved back and forth several times in various directions. After the negative pressure is released, the needle is withdrawn, and the contents of the needle are used to prepare smears.45 A cytopathologist then examines the slides to determine whether sufficient diagnostic material is present.Core Needle Biopsy. Core needle biopsy is safe, accurate,46,47 and economical48 and has become the preferred technique for diagnosing soft tissue lesions. Dupuy and colleagues found that core needle biopsy had an accuracy of 93% in 221 patients with musculoskeletal neoplasms.46Image guidance (ultrasound or CT) can prevent sam-pling of nondiagnostic necrotic or cystic areas of the tumor and thus increase the positive yield rate. Image guidance also per-mits biopsy of tumors in otherwise inaccessible locations and tumors located near vital structures with less risk of injury or complication.The tissue sample obtained from core needle biopsy is usually sufficient for several diagnostic tests, such as electron microscopy, cytogenetic analysis, and flow cytometry. The risk for needle track seeding is negligible, and the reported compli-cation rate for core needle biopsy is less than 1%.46,47Incisional Biopsy. Historically, an open surgical biopsy was the gold standard for achieving adequate tissue for definitive and specific histologic diagnosis of bone or soft tissue sarcomas. Contemporary guidelines recommend incisional biopsy when core needle biopsy cannot produce adequate tissue for diagnosis or when findings on core needle biopsy are nondiagnostic.The disadvantages of incisional biopsy include the need to schedule the procedure, the need for general anesthesia, and high costs. In addition, an inappropriately placed incision can necessitate more extensive definitive resection to incorporate the biopsy incision. In a series of 107 patients with soft tissue sarcoma, planned surgical treatments had to be changed because of poorly oriented biopsies in 25% of cases.49 Complication rates up to 17% have been reported after incisional biopsies.45 Potential complications include hematoma, infection, wound dehiscence, and tumor fungation, any of which can delay defini-tive treatment.45Incisional biopsies should be performed only by surgeons experienced in the management of soft tissue sarcoma, ideally in a center specializing in the treatment of sarcoma and by the surgeon who will perform the definitive surgery. The biopsy incision should be oriented longitudinally along the extremity to allow a subsequent wide local excision that encompasses the biopsy site, scar, and tumor en bloc minimizing the risk for increasing the complexity of the subsequent curative procedure. A poorly oriented biopsy incision often necessitates an exces-sively large surgical defect for a wide local excision, which in turn can result in a larger postoperative radiation therapy field to encompass all tissues at risk. Adequate hemostasis must be achieved at the time of biopsy to prevent dissemination of tumor cells into adjacent tissue planes by hematoma.Excisional Biopsy. Excisional biopsy can be performed for easily accessible (superficial) extremity or truncal lesions smaller than 3 cm. However, excisional biopsy rarely provides benefits over other biopsy techniques. Excisional biopsies should not be performed for lesions involving the hands and feet because such biopsies may complicate definitive reexcision. For sarcomas with initial diagnosis confirmed with excisional biopsy, microscopic residual disease has been reported in up to 69% of reexcision specimens50,51; without reexcision, the reported rate of local recurrence is 30% to 40% when margins are positive or uncertain.Wide en bloc excision is seldom performed as a diagnostic procedure. When en bloc excision is done for diagnosis, the mar-gin status is often not adequately evaluated during pathologic assessment of the specimen. Unless detailed descriptions of the surgical procedure and the pathology specimen are provided, the margins should be classified as uncertain or unknown, a classifi-cation associated with the same prognosis as resection margins that are positive for tumor cells. In patients with uncertain or unknown margins, reexcision should be performed if possible to ensure negative margins. The biopsy site or tract (if applicable) should be included en bloc with the re-resected specimen.Pathologic Assessment and ClassificationSarcoma is generally diagnosed by morphologic assessment based on microscopic examination of histologic sections by an experienced sarcoma pathologist. However, even expert sar-coma pathologists disagree on the specific histologic diagnosis and the tumor grade in 25% to 40% of cases.52Morphologic assessment can be supported by ancillary techniques, including conventional cytogenetics; immunohis-tochemistry; and molecular genetic testing, which is useful for classifying soft tissue sarcoma subtypes with multiple genetic aberrations. Other molecular diagnostic techniques include cytogenetic analysis, fluorescence in situ hybridization, and polymerase chain reaction–based methods.53 However, molecu-lar genetic techniques are associated with significant technical limitations and should be interpreted in the context of the sar-coma’s morphologic features.Some experts have suggested that pathologic classification of soft tissue sarcomas has more prognostic significance than does tumor grade when other pretreatment variables are taken into account. Tumors with limited metastatic potential include des-moid, atypical lipomatous tumor (also called well-differentiated liposarcoma), dermatofibrosarcoma protuberans, and solitary fibrous tumor. Tumors with an intermediate risk of metastatic spread usually have a large myxoid component and include myx-oid liposarcoma, myxofibrosarcoma, and extraskeletal myxoid chondrosarcoma. Among the highly aggressive tumors with sub-stantial metastatic potential are angiosarcoma, clear cell sarcoma, pleomorphic and dedifferentiated liposarcoma, leiomyosarcoma, MPNST, rhabdomyosarcoma, and synovial sarcoma.It has recently been noted that malignant fibrous histio-cytoma is not associated with a distinct gene cluster, suggest-ing that malignant fibrous histiocytoma is not a separate tumor entity but rather a common morphologic appearance of various sarcoma subtypes.54,55 For example, most tumors initially diag-nosed as malignant fibrous histiocytoma in the retroperitoneum have been reclassified using genomic profiling as dedifferenti-ated liposarcomas,56 whereas those in the extremities have been reclassified as leiomyosarcoma, myxofibrosarcoma, or pleo-morphic undifferentiated sarcoma.Guidelines for the pathologic reporting of sarcoma have been established.1 Included in the report should be the primary diagnosis, anatomic site, depth, size, and histologic grade, pres-ence or absence of necrosis, status of excision margins and lymph nodes, TNM stage, and additional features of the tumor (i.e., mitotic rate and presence or absence of vascular invasion).Brunicardi_Ch36_p1567-p1598.indd 157201/03/19 6:38 PM 1573SOFT TISSUE SARCOMASCHAPTER 36Staging and Prognostic FactorsSoft tissue sarcoma is most commonly staged using either the American Joint Committee on Cancer (AJCC) system (generally used in the United States) or the World Health Organization sys-tem. A unique aspect of sarcoma staging is the inclusion of tumor grade, which is one of the most important prognostic factors.57The seventh edition of the AJCC staging system for soft tissue sarcomas is based on histologic grade of aggressive-ness, tumor size and depth, and the presence of nodal or distant metastases.58 This system does not apply to GIST, fibromatosis (desmoid tumor), Kaposi’s sarcoma, or infantile fibrosarcoma.Histologic Grade of Aggressiveness. Histologic grade is the most important prognostic factor for patients with soft tissue sarcoma. For accurate determination of grade, an adequate tis-sue sample must be appropriately fixed, stained, and reviewed by an experienced sarcoma pathologist. The features that define grade are cellularity, differentiation (good, moderate, or poor/anaplastic), pleomorphism, necrosis (absent, <50%, or ≥50%), and number of mitoses per high-power field (<10, 10–19, or ≥20). Tumor grade has been shown to predict metastasis and overall survival.59 Metastasis has been estimated to occur in 5% to 10% of low-grade lesions, 25% to 30% of intermediate-grade lesions, and 50% to 60% of high-grade lesions.The number of grades varies according to the classifica-tion system used. The most common classification systems, those of the National Cancer Institute and the French Federation of Cancer Centers, use three-tier tumor grades.60 The National Cancer Institute system is based primarily on histologic sub-type, location, and amount of necrosis. The French Federation of Cancer Centers system is based on tumor differentiation (good, moderate, or poor/anaplastic), number of mitoses per high-power field (<10, 10–19, or ≥20), and amount of tumor necrosis (absent, <50%, or ≥50%). A comparative analysis of the two systems suggested that the French Federation of Can-cer Centers system has better prognostic capability, predicting 5-year survival rates of 90%, 70%, and 40% for grade 1, 2, and 3 tumors, respectively.60Following the recommendation of the College of American Pathologists, the committee that developed the 2008 AJCC staging system changed the system from a four-grade to a three-grade system in which the grades are well differentiated (grade 1), moderately differentiated (grade 2), and poorly differentiated (grade 3).61 Grade 1 is considered low grade, and grades 2 and 3 are considered high grade.Tumor Size and Location. Tumor size is an important prog-nostic variable in soft tissue sarcomas. Sarcomas have classi-cally been stratified into two size groups; T1 lesions are 5 cm or smaller, and T2 lesions are larger than 5 cm. The staging of soft tissue sarcomas has changed considerably in the eighth edition of the AJCC Cancer Staging Handbook.62 Previously, all soft tissue sarcoma sites were staged as one. In the new edi-tion, subsites have been created, and they include head and neck; extremity and trunk; gastrointestinal tract; genitourinary tract; viscera and peritoneum; gynecological sites; breast lung, pleura and mediastinum; and other histologies. Size criteria for head and neck tumors have been reduced from the classic cri-teria because of a worse prognosis at smaller sizes. Trunk and extremity sarcoma has been reclassified relative to size criteria for tumor stage, changing the four categories: T1 tumors are smaller than 5 cm; T2 tumors are 5 to 10 cm; T3 tumors are 10 to 15 cm; and T4 tumors are larger than 15 cm.62Figure 36-4. A 74-year-old man with a history of an extraskeletal myxoid chondrosarcoma of the gluteal region developed multiple lung metastases.Anatomic tumor location was incorporated into the AJCC staging system in 1998. Soft tissue sarcomas above the superfi-cial investing fascia of the extremity or trunk are designated “a” lesions within the T category, whereas tumors invading or deep to the fascia and all retroperitoneal, mediastinal, and visceral tumors are designated “b” lesions. However, in this most recent AJCC staging system, the superficial versus deep distinction is less important and has been eliminated.62Nodal Metastasis. Overall, lymph node metastases arising from soft tissue sarcomas are rare,28 but the incidence of nodal involvement is higher for epithelioid sarcoma, pediatric rhab-domyosarcoma, clear cell sarcoma, synovial sarcoma, myxo-fibrosarcoma, and angiosarcoma. In the seventh edition of the AJCC staging system, sarcoma associated with nodal metas-tases was reclassified as stage III rather than stage IV because several studies reported better survival for patients with isolated regional lymph node metastases treated with radical lymphad-enectomy than for patients with distant metastases.28,63-65 How-ever, in the eighth edition of the AJCC, nodal disease has been revisited: N1 disease behaves similarly between stages III and IV and is now captured as stage IV.62 Patients with clinically or radiologically suspicious regional nodes should have metastases confirmed or ruled out by either fine-needle aspiration or core biopsy before radical lymphadenectomy.Distant Metastasis. Distant metastases occur most often in the lungs (Fig. 36-4). Selected patients with pulmonary metas-tases may survive for long periods after surgical resection and chemotherapy. Other potential sites of metastasis include bone (Fig. 36-5), brain (Fig. 36-6), and liver (Fig. 36-7). Visceral and retroperitoneal sarcomas have a higher incidence of liver and peritoneal metastases.Prognostic Factors. Prognostic variables in soft tissue sar-coma include primary tumor size, grade, and depth, all of which are incorporated into the staging system, as well as histology, Brunicardi_Ch36_p1567-p1598.indd 157301/03/19 6:38 PM 1574SPECIFIC CONSIDERATIONSPART IIFigure 36-5. A 36-year-old woman with history of multifocal sclerosing osteosarcoma of the humerus developed diffuse bony metastases 2 years after diagnosis.Figure 36-6. A 64-year-old man with a history of a T2 high-grade pleomorphic sarcoma of the thigh who developed brain metastases 14 months after diagnosis.Figure 36-7. A 33-year-old woman with osteosarcoma of the sternum who presented with a liver metastasis 3 years after diagnosis.tumor site, and presentation (local recurrence or initial diagno-sis). Patient factors such as older age and gender have also been associated with recurrence and mortality in several studies.66 A positive microscopic margin and early recurrence after resection of an extremity sarcoma have been shown to be associated with decreased survival.67Several groups have reported that Ki-67, a proliferation marker, is correlated with a poor clinical outcome in high-grade extremity sarcomas.68,69 E-cadherin and catenins, proteins essen-tial for intercellular junctions, have been associated with poor outcome in patients with soft tissue sarcoma.68 Similarly, higher CD100 expression has been shown to correlate with higher pro-liferative potential and poorer outcome.69Prognostic Nomograms. Prognostic nomograms for soft tis-sue sarcoma have been introduced for use in patient counsel-ing, selecting appropriate surveillance strategies, and selecting patients for clinical trials.70 One such nomogram, developed by Kattan and colleagues at Memorial Sloan-Kettering Cancer Center, considers age, histology, grade, location, depth, and size to determine the likelihood of 12-year sarcoma-specific survival.70 Two validation studies using the nomogram demon-strated good predictive value.71 More recently, the same group of investigators developed histology subtype-specific nomo-grams for patients with liposarcoma, synovial sarcoma, and GIST72 and demonstrated that they were accurate in predicting disease-specific survival. Other investigators have just devel-oped a site-specific nomogram for patients with retroperitoneal sarcoma, demonstrating an accurate prediction of survival and disease recurrence.73TREATMENT OF EXTREMITY AND TRUNK WALL SARCOMAThe goals of treatment of soft tissue sarcoma are to maxi-mize the likelihood of long-term recurrence-free survival while minimizing morbidity and maximizing function. In the past two decades, a multimodality treatment approach with optimal sequencing of treatments for individual patients has been shown to improve survival.74 Furthermore, patients with soft tissue sarcoma treated at high-volume centers have been shown to have improved survival and functional outcomes.75 Care at such centers is particularly important for patients with high-risk and advanced disease.The overall 5-year survival rate for patients with all stages of soft tissue sarcoma is 50% to 60%. For patients with extremity sarcomas, a multidisciplinary treatment approach has resulted in local control rates exceeding 90% and 5-year survival rates exceeding 70%. Most patients who die of soft tissue sarcoma die of metastatic disease, which becomes evident within 2 to 3 years of initial diagnosis in 80% of cases.Recommendations for evaluation and treatment of patients presenting with soft tissue masses are summarized in Table 36-3.Brunicardi_Ch36_p1567-p1598.indd 157401/03/19 6:38 PM 1575SOFT TISSUE SARCOMASCHAPTER 36Table 36-3Recommendations for the management of soft tissue masses1. Soft tissue tumors that are enlarging or greater than 3 cm should be evaluated with radiologic imaging (ultrasonography or computed tomography [CT]), and a tissue diagnosis should be made using core needle biopsy.2. Once a sarcoma diagnosis is established, obtain imaging (magnetic resonance imaging for extremity lesions and CT for other anatomic locations) and evaluate for metastatic disease with chest CT for intermediateor high-grade (grade 2 or 3) or large (T2) tumors.3. A wide local excision with 1to 2-cm margins is adequate therapy for low-grade lesions and T1 tumors.4. Radiation therapy plays a critical role in the management of large (T2), intermediateor high-grade tumors.5. Patients with locally advanced high-grade sarcomas or distant metastases should be evaluated for chemotherapy.6. An aggressive surgical approach should be taken in the treatment of patients with an isolated local recurrence or resectable distant metastases.SurgeryPrimary tumors with no evidence of distant metastasis are managed with surgery alone or, when wide pathologic margins cannot be achieved because of anatomic constraints and/or the grade is high, surgery plus radiation therapy. The type of surgical resection is determined by several factors, including tumor location, tumor size, depth of invasion, involvement of nearby structures, need for skin grafting or autogenous tissue reconstruction, and the patient’s performance status. In 1985, the National Institutes of Health developed a consensus statement recommending limb-sparing surgery for most patients with high-grade extremity sarcomas.76 However, for patients with primary or recurrent tumors that cannot be grossly resected with a limb-sparing procedure and preservation of function (<5% of patients), amputation remains the treatment of choice.Margin status after surgical resection has been shown to be an independent prognostic factor.77,78 The goal of surgical resec-tion is to achieve a complete resection because microscopically positive or grossly positive resection margins are associated with increased risk of local recurrence and death.79 If an unex-pected positive margin is found on pathologic examination of the resection specimen, reexcision should be performed if fea-sible. In patients with a positive margin, particularly in patients with macroscopic residual disease, local control is unlikely even with the addition of postoperative radiation therapy, emphasiz-ing the importance of a well-planned initial operation.80Wide Local Excision. The preferred treatment for extrem-ity sarcomas is wide local excision that includes resection of the biopsy site. The goal of wide local excision is to remove the tumor with approximately 1 to 2 cm of surrounding nor-mal soft tissue,77 but narrower margins may be necessary to preserve uninvolved critical neurovascular structures and may be adequate for patients undergoing radiation therapy.81 Dis-section should proceed through grossly normal tissue planes not abutting the tumor. Soft tissue sarcomas are generally sur-rounded by a zone of compressed reactive tissue that forms a pseudocapsule; this pseudocapsule should not be used to guide resection (enucleation) as microscopic disease exists within this reactive zone. If the tumor is adjacent to or displacing major neurovascular structures, these do not need to be resected, but the adventitia or perineurium should be removed.1 For some massive tumors of the extremities, wide local excision entails a radical or complete anatomic compartment resection. Surgical clips should be placed to delineate the extent of the resection bed for patients likely to require postoperative radiation therapy.Recent reports demonstrate encouraging results follow-ing radical en bloc resection with vascular reconstruction in the lower extremities.82,83 While en bloc resection with vascular reconstruction has been associated with increased rates of post-operative complications, reported local recurrence and 5-year survival rates are similar to those for patients not requiring ves-sel resection.84,85 Similarly, studies have shown acceptable func-tional outcomes with resection of the sciatic, tibial, and peroneal nerves with appropriate reconstruction and rehabilitation.86Bone invasion from extremity soft tissue sarcoma, which can generally be identified using high-quality cross-sectional imaging such as MRI, has been estimated to occur in about 5% of patients and is associated with reduced overall survival.87 In cases of bone invasion, bone resection is required to obtain an adequate surgical margin and to achieve local control. Although tumor resection and repair of skeletal defects are possible, the likelihood of postoperative complications may be increased, and functional outcomes may be less favorable. Lin and colleagues88 recently analyzed 55 patients with soft tissue sarcomas abutting bone and reported that in the absence of frank cortical bone pen-etration, periosteum was an adequate surgical margin in patients treated with wide local excision and radiation.Soft tissue sarcomas arising in the distal extremities, particularly the hands and feet, present unique technical chal-lenges. While distal-extremity tumors are often detected at a smaller size (<5 cm) than proximal-extremity tumors, resec-tion and reconstruction techniques are often more complex for distal-extremity tumors, and preoperative planning is criti-cal to obtain favorable functional outcomes. Identifying the proximity of the tumor to underlying critical structures (e.g., bone, tendon, or neurovascular structures) using MRI is essen-tial for surgical planning. In a reported series of patients with sarcomas of the hands or feet treated with limited surgery only, 32% of patients had local recurrences.89 Preservation of function and acceptable recurrence rates with limited surgery and adjuvant radiation therapy for soft tissue sarcomas of the distal extremities have been reported.90 For locally advanced tumors, repair of bone defects, vascular reconstruction, tendon transfers, and soft tissue reconstruction using regional or free flaps have resulted in good functional outcomes.91 Amputation remains a reasonable option for patients with soft tissue sar-comas of the distal extremities when acceptable oncologic or functional outcomes cannot be achieved using available limb salvage techniques.In an interesting study conducted in Ontario and Quebec, investigators found patients expecting a difficult recovery and patients with uncertain expectations had worse functional out-comes than patients anticipating an easy recovery, indicating that preoperative education including consultation with reha-bilitation services may optimize outcomes.92 Furthermore, all patients undergoing resection of extremity sarcomas should undergo physical therapy beginning immediately after surgery and continuing until maximum function is achieved.1Brunicardi_Ch36_p1567-p1598.indd 157501/03/19 6:38 PM 1576SPECIFIC CONSIDERATIONSPART IILocoregional Lymphadenectomy. Several studies have reported improved survival for patients with isolated regional lymph node metastases treated with radical lymphadenectomy.28,63-65 Patients with clinically or radiologically suspicious regional nodes should have metastases confirmed by biopsy before radi-cal lymphadenectomy. An ultrasound-guided fine-needle aspi-ration or core biopsy of lymph nodes in selected patients with suspicious clinical or radiologic findings. The utility of sentinel lymph node biopsy has remained controversial despite the rec-ognition that several histologic subtypes of high-grade sarcoma are known to have a propensity for lymph node metastasis. However, there have been no prospective studies of the sen-sitivity and specificity of sentinel lymph node biopsy for such tumors, and as such, sentinel node biopsy for sarcoma should be performed in either highly selected patients or in the setting of a clinical trial.Amputation. Amputation is the treatment of choice for the 5% of patients with primary or recurrent extremity tumors whose tumors cannot be grossly resected with limb-sparing proce-dures and preservation of function. Historically, local excision of large, high-grade soft tissue sarcomas resulted in local fail-ure rates of 50% to 70%, even when a margin of normal tissue around the tumor was excised; consequently, radical resection or amputation was recommended. Today, however, the addition of radiation therapy to less radical surgical resection has made limb salvage possible in most cases.A comparison of amputation versus limb-sparing sur-gery followed by adjuvant radiation therapy performed by the National Cancer Institute between 1975 and 1981 demonstrated no significant difference between the two groups in local recur-rence or overall survival rate.93 Potter and colleagues50 later reviewed the entire National Cancer Institute experience with 123 patients treated with conservative surgery plus radiation therapy and 83 treated with amputation. The local recurrence rate was significantly higher in the surgery and adjuvant radia-tion therapy group: 8% versus 0% in the amputation group. However, survival rates did not differ between the groups. Several large single-institution studies have since also reported favorable local control rates with conservative resection plus radiation therapy.94-96Isolated Regional Perfusion. Isolated regional perfusion is a limb-sparing technique in which a soft tissue sarcoma is perfused with high concentrations of tumor necrosis factor-alpha (TNF-α) and melphalan under hyperthermic conditions. The use of TNF-α is not approved by the U.S. Food and Drug Administration (FDA) and is used only in European countries. The technique is generally used for locally advanced, multifo-cal, or locally recurrent disease; it has also served as a pallia-tive treatment to achieve local control for patients with distant metastases.Limb perfusion requires isolating the main artery and vein of the perfused limb from the systemic circulation. The ana-tomic approach is determined by tumor site: external iliac ves-sels are used for thigh tumors, femoral or popliteal vessels for calf tumors, and axillary vessels for upper extremity tumors. The vessels are dissected, and all collateral vessels are ligated. The main artery and vein are then cannulated and connected to a pump oxygenator similar to that used in cardiopulmonary bypass. Either a tourniquet or an Esmarch band is applied to the limb to achieve complete vascular isolation. Chemotherapeutic agents are then added to the perfusion circuit and circulated for 90 minutes. Systemic leakage from the perfused limb is moni-tored continuously with 99Tc-radiolabeled human serum albumin injected into the perfusate, and radioactivity above the precor-dial area is recorded with a Geiger counter. During the entire procedure, hyperthermia of the perfused limb is maintained by external heating and by warming the perfusate to 40°C. At the end of the procedure, the limb is washed out, the cannulas are extracted, and the blood vessels are repaired.Despite the 40-year history of using isolated limb per-fusion to treat extremity sarcomas, many questions about this technique remain to be answered. The optimal chemotherapeu-tic agent in the perfusion circuit, the benefits of hyperthermia, and the effectiveness of hyperthermic perfusion as neoadjuvant or adjuvant treatment remain to be elucidated. Studies published to date have involved heterogeneous patient groups and various chemotherapeutic agents. Despite these limitations, response rates from 18% to 80% and overall 5-year survival rates from 50% to 70% have been reported.97-101 However, survival out-comes following isolated limb perfusion have not yet been directly compared with survival outcomes after more conven-tional treatment approaches.In the initial report of isolated regional perfusion for extremity sarcomas, published in 1974, McBride reported results in 79 patients with extremity sarcomas who had been treated with isolated limb perfusion during the previous 14 years.97 All patients received melphalan and dactinomycin. The overall 5-year survival rate was 57%, and only 13 patients had subsequent amputation for recurrent disease. Over the next 20 years, isolated perfusion for treatment of extremity sarcoma fell out of favor for several reasons. Most notably, improved survival and decreased local recurrence rates could be obtained with less radical therapy, including conservative surgical exci-sion combined with radiation to allow limb sparing in patients who were previously thought to require amputation.A 1992 report by Lienard and colleagues101 renewed interest in isolated limb perfusion for extremity tumors. Those investigators reported a 100% response rate among patients with extremity melanomas and sarcomas treated with high-dose recombinant TNF-α plus interferon-γ and melphalan in an iso-lated perfusion circuit. This report led to larger studies geared specifically to patients with sarcoma. The largest of these stud-ies, the European Multicenter Study, was reported by Egger-mont and colleagues in 1996.99 In that study of 186 patients, the overall tumor response rate was 82%, and the clinical and pathologic complete response rate was 29%. Although all of the study participants were reported to initially be candidates for amputation, the rate of limb salvage following isolated limb perfusion was 82%.99 Subsequent studies have shown high local response and limb salvage rates and acceptable local and sys-temic toxic effects.102However, results in the United States have been inferior to those reported in Europe. In a study by Fraker and colleagues, the complete response rate was 26%, and an additional 30% of patients had a partial response. Fourteen patients (32%) under-went amputation for progressive tumors, while the remaining 30 patients (68%) were able to undergo limb-sparing surgery after isolated limb perfusion.100 The inferior results in the U.S.-based studies are thought to be due to patient selection biases and the degree of treatment before limb perfusion.While isolated limb perfusion for extremity sarcoma has fallen out of favor, recent reports of isolated limb infusion from the H. Lee Moffitt Cancer Center have shown promising Brunicardi_Ch36_p1567-p1598.indd 157601/03/19 6:38 PM 1577SOFT TISSUE SARCOMASCHAPTER 36results.103 Patients with extremity sarcoma and who are con-sidered for amputation are offered the option of isolated limb infusion with high-dose melphalan and actinomycin-D on pro-tocol. Isolated limb infusion is a less invasive technique that can be repeated. Percutaneous cannulas are placed prior to infu-sion, the extremity is isolated similar to limb perfusion with an Esmarch band or tourniquet, and the perfusion is normothermic and acidotic. Results from a multicenter retrospective study have demonstrated an overall response rate of 58%, and after a median follow-up of 21 months, there was an overall limb sal-vage rate of 78%. The benefits over limb perfusion remain the ability to repeat the technique in patients with disease response and less operative morbidity and risk of vascular injury from open surgery and cannulation of the iliac vessels. Although to date the technique has been well established for patients with locally advanced extremity disease for melanoma, its applica-tion for advanced, locally recurrent extremity sarcoma deserves further study.Radiation TherapyRadiation therapy is part of the standard treatment for high-grade extremity and trunk wall soft tissue sarcomas either in the preor postoperative setting. Patients with low-grade tumors or small, superficial high-grade tumors that have been resected with adequate margins may safely avoid radiation therapy.The evidence supporting adjuvant radiation therapy for patients eligible for conservative surgical resection comes from two randomized trials104,105 and three large single-institution reports.106-108 In a randomized trial by the National Cancer Institute, 91 patients with high-grade extremity tumors were treated with limb-sparing surgery followed by chemotherapy alone or radiation therapy plus chemotherapy. The 10-year local control rate was 98% for patients receiving radiation therapy compared with 70% for those not receiving radiation therapy (P = .0001).104 Similarly, in a randomized trial from Memorial Sloan-Kettering Cancer Center, 164 patients underwent conservative surgery followed by observation or brachytherapy. For patients with high-grade tumors, the 5-year local control rate was 66% in the observation group and 89% in the brachytherapy group (P = .003).105 For patients with low-grade tumors, no significant difference was observed between treatment groups.109Until recently, the standard treatment guidelines required radiation therapy after surgery for all patients with intermediate or high-grade tumors of any size. However, small tumors (≤5 cm) have not generally been associated with local recurrence, and radiation therapy for such tumors may not be necessary.105 In a series of 174 patients reported by Geer and colleagues, post-operative radiation therapy did not improve 5-year local recur-rence or overall survival rates for patients with small soft tissue sarcomas.110 Karakousis and colleagues reported a 5-year local recurrence rate of 6% for 80 patients with extremity sarcomas treated with wide local excision and observation, a rate similar to that for the 64 patients who underwent resection with nar-rower surgical margins and postoperative radiation therapy.111The optimal mode of radiation therapy (external-beam radiation therapy, brachytherapy, or intensity-modulated radia-tion therapy [IMRT]) and timing of radiation therapy (preopera-tive, intraoperative, or postoperative) have yet to be defined. External-beam radiation therapy can be delivered using pho-tons or particle beams (electrons, protons, pions, or neutrons). Conventional fractionation is usually 1.8 to 2 Gy per day. CT is an integral part of radiation therapy, used to define the gross tumor volume and to estimate the margin of tissue at risk for microscopic tumor involvement. The optimal radiation margin is not well defined: a margin of 5 to 7 cm is standard, but some centers advocate wider margins for tumors larger than 15 cm. At most institutions, the typical preoperative dose is 50 Gy given in 25 fractions, and resection is performed 4 to 8 weeks after completion of radiation therapy to allow acute radiation changes to subside. Postoperative radiation therapy planning is based on tumor site, tumor grade, surgical margins, and institutional preferences. The entire surgical scar and drain sites should be included in the field so that a near-full dose can be administered to the superficial skin. Metallic clips placed in the tumor bed during surgery can help define the limits of the resection and aid in radiation therapy planning. Doses of 60 to 70 Gy are usually necessary for postoperative treatment.No consensus exists on the optimal sequence of radia-tion therapy and surgery. The available data come largely from single-institution, nonrandomized studies. Proponents of pre-operative radiation therapy note that multidisciplinary planning with radiation oncologists, medical oncologists, and surgeons is easier early in the course of therapy. In addition, for some radiosensitive histologic subtypes, such as myxoid liposarcoma, preoperative radiation therapy may shrink the tumor, facilitat-ing resection with negative margins. Furthermore, a tissue bed undisturbed by resection has better tissue oxygenation and can be successfully treated with lower doses of radiation. In addi-tion, Nielsen and colleagues112 demonstrated that preoperative radiation fields are smaller than postoperative radiation fields and that the average number of joints included in the field is lower with preoperative than postoperative radiation therapy, which may result in improved functional outcome. Critics of preoperative radiation therapy cite the difficulty of pathologic assessment of margins and the increased rate of postoperative wound complications.113 However, reconstructive surgical tech-niques with advanced tissue transfer procedures are being used more often in these high-risk wounds and reportedly result in better outcomes. The higher doses generally required for post-operative radiation therapy have also been shown to be associ-ated with greater long-term functional impairment.The only randomized comparison of preoperative and postoperative radiation therapy to date was performed by the National Cancer Institute of Canada Clinical Trials–Canadian Sarcoma Group.114 This trial was designed to examine compli-cations and functional outcome. The 190 patients enrolled from October 1994 to December 1997 were randomized to preopera-tive radiation therapy (50 Gy) or postoperative radiation therapy (66 Gy). With a median follow-up time of 3.3 years, the recur-rence and progression-free survival rates were similar in the two groups. The incidence of wound complications was higher in the preoperative group versus the postoperative group (35% vs. 17%), and the incidence of wound complications was signifi-cantly higher for tumors of the lower extremity (43%) than for those of the upper extremity (5%).114 Late radiation toxic effects (e.g., fibrosis, joint stiffness, and edema) were more common with postoperative than preoperative radiation therapy (48% vs. 32%) because of higher postoperative radiation doses and larger treatment field sizes.115Brachytherapy involves the placement of multiple radioactive seeds through catheters inserted in the tumor resection bed. The primary benefit of brachytherapy is the shorter overall treatment time of 4 to 6 days, compared to the 4 to 6 weeks generally required for preoperative or postoperative Brunicardi_Ch36_p1567-p1598.indd 157701/03/19 6:38 PM 1578SPECIFIC CONSIDERATIONSPART IIradiation therapy regimens. A cost-analysis comparison of adjuvant brachytherapy versus adjuvant external-beam irradiation for soft tissue sarcomas showed that costs were lower with brachytherapy.116 The implications of cost have been studied after radical resections and immediate adjuvant brachytherapy with either staged or immediate reconstruction noting a lower cost with staged reconstruction and tissue transfer techniques.117 Brachytherapy can also be used for recurrent disease previously treated with external-beam radiation. Guidelines established at Memorial Sloan-Kettering Cancer Center recommend spacing the afterloading catheters in 1-cm increments while leaving a 2-cm margin around the surgical bed.105 After adequate wound healing is confirmed, usually after the fifth postoperative day, the catheters are loaded with seeds containing iridium-192 that deliver 42 to 45 Gy of radiation to the tumor bed over 4 to 6 days. Subsequent studies at the H. Lee Moffitt Cancer Center that sought to determine outcomes between staged immediate and delayed reconstruction noted advantages in improved local control, wound healing, and less radiation-associated toxicity with staged reconstruction.118 The primary disadvantage of brachytherapy is that it requires significant expertise, extended inpatient hospital stays, and bed rest.IMRT delivers radiation more precisely to the tumor than external-beam irradiation while minimizing the volume of sur-rounding tissues exposed to high radiation doses. The proposed benefits of preoperative IMRT include reduced risk of postop-erative wound infections because of minimization of the dose to the skin119 and protection of underlying bone (e.g., femur) as a result of concave dose distributions.120 There have been no prospective randomized trials comparing the long-term out-comes following IMRT versus other types of radiation therapy. In a retrospective analysis of IMRT, patients with negative and positive/close (within 1 mm) margins were found to have 5-year local control rates of 94%.121 In addition, the rates of posttreat-ment edema and joint stiffness with IMRT were lower than the expected rates with conventional radiation therapy.Local toxic effects of radiation therapy vary according to radiation dose, field size, and timing (preoperative or postop-erative). With preoperative radiation therapy, the most frequent wound complications are wound dehiscence, wound necrosis, persistent drainage, infection, seroma formation, ulceration, and cellulitis.114 Postoperative irradiation of free flaps is often asso-ciated with wound complications, and patients should be advised that secondary surgical repair may be necessary; therefore, con-sideration for preoperative radiation rather than postoperative radiation for larger tumors requiring flap reconstruction is a logical and sound approach. Wound complication rates of 13% to 37% have been reported for preoperative radiation therapy, compared to 5% to 20% for postoperative radiation therapy.121 If catheters are loaded after the fifth postoperative day and/or if staged reconstruction is used, rates of wound complications after brachytherapy are improved if not similar to those after postoperative radiation therapy.118Long-term (chronic) effects of radiation therapy (those occurring >1 year after completion of therapy) are generally related to fibrosis/contractures, lymphedema, neurologic injury, osteitis, and fractures, all of which can cause substantial func-tional impairment.122 Variables associated with poorer func-tional outcome after radiation therapy include larger tumors, higher doses of radiation (>63 Gy), longer radiation fields (>35 cm), poor radiation technique, neural sacrifice, postop-erative fractures, and wound complications.115,123 Additionally, complications of any kind are less likely after treatment for upper extremity sarcoma than after treatment for lower extremity sarcoma.113,114Definitive radiation therapy that delivers maximal-tissue-tolerance doses of radiation may be appropriate for selected patients with unresectable soft tissue sarcomas. In a study of 112 patients with unresectable soft tissue sarcomas, tumor size and radiation dose were found to influence local control and survival.124 The local control rate was 51% for tumors smaller than 5 cm and 9% for tumors larger than 10 cm, and patients who received at least 64 Gy had better local control and survival.Systemic TherapyDespite improvements in local control rates, metastasis and death remain significant problems for patients with high-risk soft tissue sarcomas. Patients considered at high risk of death from sarcoma include those presenting with metastatic disease, localized sarcomas at nonextremity sites, or sarcomas of intermediateor high-grade histology larger than 5 cm.59,105Standard Chemotherapy. For most patients with sarcoma, results of conventional chemotherapy regimens have been poor. The chemosensitivity of soft tissue sarcoma varies by histologic subtype.30 Synovial sarcoma, myxoid/round cell liposarcoma, and uterine leiomyosarcoma are sensitive to chemotherapy,125 whereas pleomorphic liposarcoma, myxofibrosarcoma, epithe-lioid sarcoma, leiomyosarcoma, MPNSTs, angiosarcoma, and desmoplastic round cell tumors have intermediate sensitivity to chemotherapy. Relatively chemoresistant histologic subtypes include clear cell sarcoma, endometrial stromal sarcoma, alveo-lar soft part sarcoma, and extraskeletal myxoid chondrosarcoma. Considering the variability of responses by histologic subtype, it is not surprising that clinical trials of standard chemotherapy, which often include heterogeneous populations with respect to tumor grade and histology, have demonstrated no overall sur-vival benefit.Doxorubicin and ifosfamide are the two most active agents against soft tissue sarcoma, with consistently reported response rates of 20% or greater and positive dose-response curves.126,127 The European guidelines recommend doxorubicin 75 mg/m2 every 3 weeks as first-line treatment for advanced disease.30 Treatment duration is based on response, but a maximum of six cycles is generally recommended because of the risk of cumula-tive cardiotoxicity. Ifosfamide is the recommended second-line treatment and is recommended for first-line treatment in patients with cardiac morbidity. The standard dose of ifosfamide is 9 to 10 g/m2; however, single-institution series using higher-dose regimens (>10 g/m2) or standard-dose ifosfamide combined with doxorubicin have shown response rates of 20% to 60%.127 Synovial sarcomas have been shown to be particularly sensi-tive to ifosfamide. Ifosfamide-associated toxic effects include hemorrhagic cystitis, neurotoxicity, and renal tubular acidosis. Historically, combination therapy with doxorubicin plus ifos-famide, dacarbazine, or both has resulted in increased response rates but no improvement in overall survival.128 Dacarbazine as a single agent has also demonstrated activity in clinical trials.Over the past decade, several additional chemotherapeutic agents, including gemcitabine, taxanes, and trabectedin, have been noted to be active against soft tissue sarcomas. Gemcitabine as a single agent was reported to produce responses in 18% of patients with advanced sarcoma.129 Gemcitabine combined with docetaxel has been reported to produce response rates as high as 53% in patients with uterine leiomyosarcoma.129,130 Gemcitabine Brunicardi_Ch36_p1567-p1598.indd 157801/03/19 6:38 PM 1579SOFT TISSUE SARCOMASCHAPTER 36combined with vinorelbine has also been associated with clini-cal benefit in patients with advanced sarcomas.131 The taxanes (docetaxel and paclitaxel) have been found to be active against angiosarcomas, particularly of the face and scalp, likely because of their potent antiangiogenic effects.132,133Novel Chemotherapeutic Agents. Aldoxorubicin is a doxo-rubicin derivative that serves as a prodrug of doxorubicin that covalently binds to albumin in the blood until reaching the acidic tumor environment releasing doxorubicin into the tis-sue. A recent international, multicenter, phase 2b, open-label, randomized study enrolled 126 patients from 2012 to 2013. Single-agent aldoxorubicin therapy showed superior efficacy over doxorubicin by prolonging progression-free survival and improving rates of 6-month progression-free survival and tumor response, warranting further study.134Trabectedin, a marine-derived alkaloid that binds DNA, affecting transcription and inducing the formation of DNA double-strand breaks, has shown benefit in the treatment of advanced soft tissue sarcomas, particularly leiomyosarcoma, myxoid liposarcoma, and other translocation-related sarcomas.135 Trabectedin is generally well tolerated but can be associated with prolonged and severe neutropenia, thrombocytopenia, and hepatic toxic effects.Palifosfamide is a stabilized formulation of the active metabolite of ifosfamide that has been reported to be better tolerated than ifosfamide.136 Early trials have suggested anti-tumor activity comparable or superior to that of ifosfamide without nephrotoxicity; however, recent negative results of the PICASSO III Trial, a phase 3, placebo-controlled study of doxorubicin with or without palifosfamide in patients with metastatic soft tissue sarcoma, have neatly secured the fate of palifosfamide in the treatment of soft tissue sarcoma.137Targeted Therapies. Several targeted agents are being investigated for the treatment of soft tissue sarcomas. Among these are tyrosine kinase inhibitors (e.g., imatinib, suni-tinib, sorafenib, and dasatinib) that have been developed and approved for treatment of GIST. Clinical data accumulated in phase 2 trials also support the use of tyrosine kinase inhibitors (e.g., imatinib, sorafenib, and sunitinib) in the management of other advanced sarcomas.128 Anti–vascular endothelial growth factor antibodies such as bevacizumab have demonstrated activity in patients with metastatic or unresectable angiosar-coma, solitary fibrous tumor, and epithelioid hemangioendo-thelioma.138 Pazopanib is an oral angiogenesis inhibitor that targets vascular endothelial growth factor receptors, platelet-derived growth factor receptor (PDGFR), and c-kit. In a recent phase 3 study, pazopanib showed efficacy against placebo in second or further line of therapy in patients with advanced soft tissue sarcoma.139 Inhibitors of the mammalian target of rapamycin pathway, including temsirolimus, everolimus, and ridaforolimus, have also shown activity against some soft tis-sue sarcomas (i.e., PEComas).140Olaratumab is a human antiplatelet-derived growth factor receptor α monoclonal antibody that has antitumor activity in human sarcoma xenografts. Recently, a phase 1b and random-ized phase 2 study of olaratumab and doxorubicin versus doxo-rubicin alone has demonstrated improvements in both objective response rates (18.2% vs. 11.9%, P = 0.34) and median over-all survival (26.5 vs. 14.7 months [stratified hazard ratio 0.46, 0.30–0.71, P = 0.0003]). Additional studies are warranted for this promising combination of agents.141Benefits of Systemic Therapy. The use of adjuvant and neoad-juvant chemotherapy for soft tissue sarcomas remains controver-sial. More than a dozen individual randomized trials of adjuvant chemotherapy have failed to demonstrate improvement in disease-free or overall survival for patients with soft tissue sarcoma. How-ever, several limitations of these individual trials may explain the lack of observed improvement. First, the chemotherapy regimens used were suboptimal, consisting of single-agent therapy (most commonly with doxorubicin) and insufficiently intensive dosing schedules. Second, the patient groups were not large enough to reveal clinically significant differences in survival rates. Finally, most studies included patients at low risk of metastasis and death, namely those with small (<5 cm) and low-grade tumors.The Sarcoma Meta-Analysis Collaboration analyzed 1568 patients from 14 trials of doxorubicin-based adjuvant chemotherapy to evaluate the effect of adjuvant chemotherapy on localized, resectable soft tissue sarcomas.142 At a median follow-up time of 9.4 years, doxorubicin-based chemotherapy significantly improved the time to local and distant recurrence and recurrence-free survival rates. However, the absolute benefit in overall survival was only 4%, which was not significant (P = .12). In a subset analysis, patients with extremity tumors had a 7% benefit in terms of overall survival (P = .029).142After this meta-analysis, randomized controlled trials of more contemporary anthracycline/ifosfamide dosing combinations with relatively small numbers of patients have yielded conflicting results. In an Italian cooperative trial, adjuvant chemotherapy improved median disease-free and overall survival times in patients with high-risk extremity soft tissue sarcomas.143 In that study, 104 patients with high-grade tumors 5 cm or larger were randomized to definitive surgery or surgery plus adjuvant chemotherapy consisting of epirubicin (60 mg/m2 per day on days 1 and 2) and ifosfamide (1.8 g/m2 per day on days 1 through 5) for five cycles. With a median follow-up time of almost 5 years, disease-free survival times were 16 months in the surgery-alone group and 48 months in the combined-treatment group (P = .04), and median overall survival times were 46 months in the surgery-alone group and 75 months in the combined-treatment group (P = .03).143 However, several years later, the surgery-alone and combined-treatment groups had equivalent relapse rates and deaths, which resulted in statistically similar overall survival.144In an effort to further assess the role of chemotherapy in patients with stage III extremity sarcoma, a cohort analy-sis of the combined databases of The University of Texas MD Anderson Cancer Center and Memorial Sloan-Kettering Can-cer Center was performed. Data on 674 patients with stage III extremity sarcoma who received either preoperative or postop-erative doxorubicin-based chemotherapy were reviewed. The 5-year disease-specific survival rate was 61%.145 Cox regres-sion analysis showed a time-varying effect of chemotherapy with an associated benefit during the first year while receiving chemotherapy. However, the clinical benefits of chemotherapy in patients with stage III sarcomas were not sustained beyond 1 year. Grobmyer and colleagues compared the outcomes of patients treated at two institutions (1990–2001) with surgery only or surgery plus preoperative chemotherapy containing doxorubicin and ifosfamide. In this analysis, chemotherapy was associated with an improvement in the 3-year disease-specific survival rate that was most pronounced in patients with tumors larger than 10 cm (62% for surgery alone vs. 83% for neoadju-vant chemotherapy and surgery).146Brunicardi_Ch36_p1567-p1598.indd 157901/03/19 6:38 PM 1580SPECIFIC CONSIDERATIONSPART IIMore recently, the European Organization for Research and Treatment of Cancer (EORTC) completed a phase 3 ran-domized study (trial EORTC-62931; conducted from 1995 through 2003) comparing surgery alone versus surgery plus adjuvant ifosfamide (5 g/m2) plus doxorubicin (75 mg/m2) with growth factor support (lenograstim) every 21 days for five cycles in 351 patients with resected grade II or III soft tissue sarcoma at any site. The estimated relapse-free survival rate was 52% in both arms, and the overall survival rate was better in the control arm (69% vs. 64%).147 Although most individual studies are underpowered, data from all of these studies suggest that chemotherapy regimens that incorporate ifosfamide may provide some disease-free survival benefit but do not improve long-term overall survival for the majority of patients with soft tissue sarcoma.In 2008, two updates to the 1997 Sarcoma Meta-Anal-ysis Collaboration were published.148,149 O’Connor and col-leagues included all of the trials in the original meta-analysis and added data from four additional trials, for a total of 18 trials with 2170 patients.148 The results showed a benefit of chemotherapy in terms of disease-free survival at 5 years and recurrence-free survival at 10 years but again failed to demon-strate a benefit in terms of long-term overall survival. The sec-ond update, by Pervaiz and colleagues, which did not include the EORTC-62931 trial, showed that adjuvant chemotherapy was associated with a significant decrease in the risk of death (hazard ratio, 0.77; P = .01).149Because the evidence regarding adjuvant systemic therapy for stage III soft tissue sarcoma is inconclusive, considerable variation still exists in treatment recommendations even though patients with large, stage II or stage III soft tissue sarcomas are at high risk for recurrence and metastasis. Chemotherapy may be considered to downstage large tumors to enable limb-sparing procedures, particularly for tumors known to be chemosensi-tive. It is likely that subsets of high-risk patients with extremity soft tissue sarcoma defined on the basis of tumor size or histol-ogy derive significant benefit from systemic chemotherapy. For example, retrospective cohort analyses have noted a disease-specific survival benefit in patients with large, high-grade lipo-sarcomas and synovial sarcomas of the extremity treated with ifosfamide plus doxorubicin versus no chemotherapy.150Neoadjuvant (Preoperative) Chemotherapy. The use of neoadjuvant (preoperative) chemotherapy for soft tissue sarco-mas is based on the belief that only 30% to 50% of patients respond to standard adjuvant (postoperative) chemotherapy. The rationale for using neoadjuvant chemotherapy is that it enables oncologists to identify patients whose disease is sensi-tive to a particular chemotherapy regimen by assessing response while the primary tumor is in situ. Patients whose tumors do not respond to short courses of neoadjuvant chemotherapy can thus be spared the toxic effects of prolonged adjuvant chemotherapy. Another advantage of neoadjuvant chemotherapy is that it may shrink tumors, enabling less morbid operations. The theoreti-cal disadvantages of neoadjuvant chemotherapy are related to myelosuppression and potential postoperative wound healing complications.A recent randomized study comparing three preoperative cycles of full-dose anthracycline-ifosfamide–based chemother-apy with three preoperative plus two postoperative cycles of the same regimen in high-risk extremity and trunk wall soft tissue sarcomas showed equivalence between the two approaches, sug-gesting the possibility of limiting chemotherapy administration to the three preoperative courses, improving the ratio between toxicity and expected benefit.151A subanalysis on response showed how tumor attenuation on CT scan and MRI obtained by the administration of such preoperative treatment was associated with a higher percentage of pathologic necrosis152 and better outcome.153Eilber and colleagues examined treatment-induced patho-logic necrosis in patients who received neoadjuvant therapy for high-grade extremity sarcomas.154 The addition of ifosfamide to other agents (doxorubicin alone or doxorubicin and cisplatin) increased the rate of pathologic necrosis to 48% compared to 13% with other combinations. The 5and 10-year local recur-rence rates were significantly lower for patients with 95% or greater pathologic necrosis (6% and 11%, respectively) than for patients with less than 95% pathologic necrosis (17% and 23%, respectively).Concurrent Chemoradiation TherapyTreatment approaches that combine systemic chemotherapy with radiosensitizers and concurrent external-beam radiation therapy may improve disease-free survival by treating micro-scopic disease and enhancing the treatment of macroscopic disease. Concurrent chemoradiation therapy with doxorubicin-based regimens reportedly produces favorable local control rates for patients with sarcoma.150 Since those findings were published, several groups have evaluated routes of administra-tion, alternative chemotherapeutic agents, and the toxicity of combined therapies.Theoretical advantages notwithstanding, concurrent chemoradiation therapy decreases the total treatment time for patients with high-risk sarcoma. This decrease represents a sub-stantial advantage over current sequential combined-modality treatment approaches, for which the total duration of radiation therapy, chemotherapy, surgery, and rehabilitation frequently exceeds 6 to 9 months.Posttreatment SurveillanceCurrently, posttreatment surveillance is recommended for all patients with soft tissue sarcomas based on a few reports involving small numbers of patients, indicating that local recur-rence can be successfully treated with radical reexcision with or without radiation therapy.155,156 Similarly, several groups have reported that survival can be prolonged by resection of pulmo-nary metastases.157-159The National Comprehensive Cancer Network (NCCN) recommends a history and physical and chest CT or radiog-raphy every 3 to 6 months for 2 to 3 years after completion of treatment. Because most cases of distant metastasis occur within 2 to 3 years of initial diagnosis, the NCCN guidelines indicate that follow-up intervals can be lengthened to every 6 months, and imaging can be done annually during years 2 through 5.1 Consideration should also be given to imaging the primary tumor site; most experts recommend that the tumor site be evaluated every 6 months with MRI for extremity tumors or CT for intra-abdominal or retroperitoneal tumors. Guidelines have been established for using MRI to distinguish recurrences from typical postsurgical changes: a discrete nodule with low signal intensity on T1-weighted images and higher signal intensity on T2-weighted images that enhances after adminis-tration of intravenous contrast material is strongly suggestive of recurrence and should be biopsied. Ultrasonography may be an alternative to MRI or CT for assessing for recurrence in the extremities.Brunicardi_Ch36_p1567-p1598.indd 158001/03/19 6:38 PM 1581SOFT TISSUE SARCOMASCHAPTER 36Recurrence is common after surgery for abdominal soft tissue sarcomas. CT is useful for detecting recurrences at primary and distant anatomic sites in the abdomen and pelvis. After surgery, CT every 3 to 6 months during the first 2 years and every 6 months for 3 years thereafter has been recommended. However, today many experienced surgeons are advocating less aggressive imaging for asymptomatic patients, particularly after a second recurrence of retroperitoneal sarcoma, arguing that there is insufficient evidence to suggest that survival is improved by earlier detection.Whooley and colleagues reviewed the efficacy of the sur-veillance strategy used at Roswell Park Cancer Institute for 174 patients with soft tissue sarcomas of the extremities.160 Patients were evaluated every 3 months for the first 2 years, every 4 to 6 months during year 3, and every 6 months during years 4 and 5. Local recurrence occurred in 18% of patients at a median time after completion of treatment of 14 months, and all but one of the recurrences were detected with physical examination alone. Fifty-seven patients had distant recurrences (at a median of 18 months after treatment), of which 36 were asymptomatic and diagnosed by surveillance imaging. The investigators determined that the positive predictive value of chest radiography during follow-up was 92%.160 However, evaluation of the primary tumor site by CT or MRI was ineffective in detecting recurrences. The authors recommended that patient characteristics, location of the primary tumor, previous treatment, and physician familiarity with changes after surgery and radiation therapy should all be considered in determining the need for radiographic imaging.Management of Recurrent SarcomaUp to 20% of patients with extremity sarcoma develop locally recurrent disease, which is often accompanied by distant metastases; thus, all patients with recurrent extremity sarcoma should undergo a full staging assessment. Patients with microscopically positive surgical margins are at increased risk of local recurrence. In a series of 179 patients with locally recurrent extremity soft tissue sarcoma at Memorial Sloan-Kettering Cancer Center, the median interval to local recurrence was 16 months; 65% of patients developed a local recurrence by 2 years, and 90% by 4 years.155 The majority of patients (89%) were treated with additional limb-sparing surgery, and 73% received additional adjuvant therapy; the disease-specific survival after treatment of first local recurrence was 55% at 4 years. Independent prognostic factors for disease-specific survival after local recurrence included tumor grade, local recurrence size, and local recurrence-free interval. These data indicate that an isolated local recurrence should be treated aggressively with resection with negative margins.For patients with extremity sarcomas, achieving negative margins on resection of recurrent disease frequently requires amputation. However, in some patients with recurrent extrem-ity sarcoma, function-preserving resection combined with addi-tional radiation therapy, with or without chemotherapy, can produce acceptable rates of local control.161-163 Nori and col-leagues reported a local control rate of 69% among 40 patients with recurrent tumors treated with reexcision and brachytherapy to a median dose of 45 Gy.163 In a similar series, Midis and col-leagues reported that limb-sparing surgery was possible in 66% of patients, and the 5-year local recurrence-free survival rate was 72% in those patients.161The primary determinant of survival in patients with soft tissue sarcoma is the development of distant metastases. Patients with extremity sarcomas generally develop pulmonary metastases.160 Less common sites of metastasis for soft tissue sarcomas include bone (7%), liver (4%),49 and lymph nodes (5–7%).28 Myxoid liposarcoma of the extremity is known to metastasize to the abdomen and pelvis; therefore, staging CT of these regions must be performed before definitive local therapy is administered.32Management of Recurrent and Distant Metastatic Sarcoma.  In selected individuals with distant metastatic disease, surgical resection of a primary soft tissue sarcoma may be appropriate as a palliative procedure. The decision should be based on the patient’s symptoms, which often include pain; ability to achieve local tumor control; comorbidities; anticipated morbidity of the surgical procedure; and the extent of metastases.The most common initial site of distant metastasis of soft tissue sarcomas is the lung. Selected patients with a limited number of pulmonary nodules (less than four nodules), long disease-free intervals, and no endobronchial invasion may become long-term survivors after pulmonary resection (Fig. 36-8); 15% to 40% of patients with complete resection of metastatic disease confined to the lung are long-term survivors.159,160,164 In a retrospective multi-institutional study of 255 patients with lung metastases, the 5-year overall survival rate after metastasectomy was 38%.157 Favorable prognostic factors in that study included microscopically tumor-free margins, age younger than 40 years, and grade 1 or 2 tumor.157 For patients who are surgical candidates, pulmonary resection alone can be more cost-effective than watchful waiting, chemotherapy, or chemotherapy plus surgery.158Chemotherapy for Distant Metastatic Sarcoma.  Doxorubicin, either alone or combined with other agents, has been the primary treatment modality for patients with advanced or distant metastatic sarcomas for several decades.128 Although most patients with metastatic disease are not curable, some Figure 36-8. A 69-year-old patient with a history of a dedifferenti-ated liposarcoma of the retroperitoneum developed a solitary lung metastasis 6 years after surgical resection.Brunicardi_Ch36_p1567-p1598.indd 158101/03/19 6:38 PM 1582SPECIFIC CONSIDERATIONSPART IIpatients with limited disease experience stabilization of disease with multidisciplinary treatment, which often includes surgery and radiation therapy in addition to chemotherapy. Several factors predict better outcome for patients with recurrent metastatic sarcoma undergoing chemotherapy, including good performance status, previous response to chemotherapy, younger age, absence of hepatic metastases, low-grade tumor, and long disease-free interval.165 Isolated liver metastases, if stable over several months, may be amenable to resection,166 radiofrequency ablation,167 or chemoembolization.168As data accumulate regarding the sensitivity of sarcoma subtypes to particular chemotherapies, it is critical that histologydriven treatment approaches be used. New therapies are also being identified based on the unique molecular signatures of sarcomas.128Palliative Radiation Therapy. Definitive radiation therapy can be considered when no acceptable surgical option is avail-able (e.g., in patients with significant medical comorbidities). In this setting, radiation doses greater than 63 Gy yielded superior tumor control, but doses greater than 68 Gy resulted in increased rates of major complications.169SPECIAL CLINICAL SITUATIONSMyxoid LiposarcomaMyxoid liposarcomas belong to the group of soft tissue sarco-mas with lipomatous differentiation. However, myxoid liposar-comas differ from the other liposarcoma subtypes with respect to morphology (i.e., myxoid stroma and lipomatous differen-tiation) and clinical behavior. Myxoid liposarcomas frequently present as slow-growing, deep tumors in the lower extremity and can metastasize to other soft tissue locations, including the retroperitoneum and extremities.170,171 For this reason, CT of the chest, abdomen, and pelvis is recommended for adequate stag-ing and surveillance of myxoid liposarcoma.Retroperitoneal SarcomaMost retroperitoneal tumors are malignant, and about one-third are soft tissue sarcomas. Also to be considered in the differen-tial diagnosis of a retroperitoneal tumor are primary germ cell tumors, lymphoma, and metastatic testicular cancer. Approxi-mately 1000 new cases of retroperitoneal sarcoma are diagnosed annually in the United States, and these tumors account for 10% to 15% of all adult tissue sarcomas. Approximately two-thirds of retroperitoneal sarcomas are high grade (either grade 2 or 3), and liposarcoma and leiomyosarcoma are the most common histologies.Retroperitoneal sarcomas generally present as large masses: 70% are larger than 10 cm at diagnosis.172 They typi-cally do not produce symptoms until they grow large enough to compress or invade contiguous structures, although pain, early satiety, and obstructive gastrointestinal symptoms may occur early in the disease course in some patients. Evaluation of a patient with a retroperitoneal mass begins with an accurate his-tory that should exclude signs and symptoms associated with lymphoma (e.g., fever and night sweats). A complete physical examination, with particular attention to all nodal basins and with a testicular examination in men, is critically important. Laboratory assessment can be helpful; elevated lactate dehy-drogenase levels may suggest lymphoma, and elevated β-human chorionic gonadotropin levels or α-fetoprotein levels may indi-cate a germ cell tumor.Figure 36-9. A 50-year-old man with a large right dedifferentiated liposarcoma. Note the atypical fat surrounding the right kidney and displacing the viscera to the left hemiabdomen and the large dedifferentiated mineralized solid nodule lateral to the right kidney.Although the general principles of evaluation and man-agement for retroperitoneal sarcomas are similar to those for extremity sarcomas, there are some differences. Contrast-enhanced CT of the abdomen and pelvis is used to define the extent of the tumor and its relationship to surrounding struc-tures, particularly vascular structures, for surgical planning; contrast-enhanced CT can also often distinguish between well-differentiated and dedifferentiated liposarcoma. CT imaging is also done to evaluate the liver for the evidence of metastases, the peritoneal cavity for evidence of discontiguous disease, and the kidneys for assessment of function. Angiography or mag-netic resonance arteriography/venography can also be used to delineate vascular anatomy when involvement of critical vascu-lar structures is suspected. Thoracic CT should be performed to evaluate for potential lung metastases because 11% of patients with retroperitoneal sarcoma present with synchronous meta-static disease. CT-guided core needle biopsy is appropriate to provide a tissue diagnosis; however, well-differentiated liposar-coma may be diagnosed with CT imaging alone, and negative biopsy findings should not delay operative intervention.Complete surgical resection is the most effective treatment for primary or recurrent retroperitoneal sarcoma (Fig. 36-9). En bloc resection often necessitates sacrificing contiguous struc-tures such as the colon, kidney, spleen, pancreas, psoas muscle, small bowel, inferior vena cava, and aorta.173 In a review of 25 patients who underwent resection of retroperitoneal sarcoma with major blood vessel involvement in a 16-year time span, postoperative morbidity and mortality rates were 36% and 4%, respectively. Vessel patency rates were greater than 88% with a median follow-up time of 19.3 months.83,174 Local control and survival rates were favorable in patients with tumor-free resec-tion margins. The authors concluded that vascular resection is the treatment of choice in sarcomas that involve major blood vessels in the retroperitoneum.83 Similar considerations were made by other groups reporting specifically on inferior vena cava resection in the context of multivisceral resection for ret-roperitoneal sarcoma and on surgical morbidity after extended surgical resection of retroperitoneal sarcoma. Extended proce-dures, including also vessels, are feasible and safe if carried out in experienced centers. While the goal of sarcoma resection is Brunicardi_Ch36_p1567-p1598.indd 158201/03/19 6:38 PM 1583SOFT TISSUE SARCOMASCHAPTER 36wide excision, this is unlikely to be achievable in most patients with retroperitoneal sarcomas. Surgery is considered marginal in most cases, even when macroscopically complete, but every attempt should be made to minimize this marginality by liberally resecting surrounding organs when involved. The extension of surgery should then take into consideration a trade-off between expected morbidity and benefit and should be best carried out at high-volume centers, where technical skills and knowledge of the natural history of this very rare disease can be found.In an analysis of 500 patients with retroperitoneal soft tissue sarcoma treated at Memorial Sloan-Kettering Cancer Center, the median survival time was 103 months for those who underwent complete resection versus 18 months for those who underwent incomplete resection or observation without resection.172 In general, surgical resection should not be offered unless radiographic evidence indicates the potential for complete resection; however, palliative surgical resection may be considered to reduce symptoms of intestinal obstruction, pain, or bleeding.175 In particular, in patients with atypical lipomatous tumors, an aggressive surgical approach including incomplete resection or debulking is justified to palliate symptoms and may provide a potential survival benefit.176 Such an approach is not justified for dedifferentiated liposarcomas or other high-grade retroperitoneal sarcomas because these tumors have high rates of distant metastasis and local recurrence.Adjuvant Therapy. Most studies have failed to show a sur-vival benefit from adjuvant chemotherapy for retroperitoneal sarcoma.177-179 Because of the high rates of local recurrence, radiation therapy has been proposed for treating microscopic residual disease as an adjunct to surgical resection. However, the optimal technique and timing of radiation therapy have not been established, and the potential benefits of radiation therapy must be weighed against the increased risk of treatment-related toxic effects.Radiation treatment of retroperitoneal sarcomas is com-plex because tumors are usually large, which necessitates large treatment fields close to radiosensitive structures (e.g., bowel). Several techniques have been used, including preoperative and postoperative external-beam radiation therapy, intraoperative radiation therapy, and brachytherapy.180 Preoperative radiation therapy is feasible and well tolerated. Toxic effects may be less severe with preoperative radiation therapy given that the tumor borders are definable, the tumor displaces radiosensitive viscera away from the treatment field, and effective doses of radiation may be lower preoperatively.181Several studies have shown favorable local control rates for intermediateand high-grade retroperitoneal sarcoma treated with preoperative radiation therapy and complete resection.180 However, most studies have failed to show a survival benefit.182 This situation prompted the initiation of a multicenter, ran-domized trial sponsored by the American College of Surgeons Oncology Group (ACOSOG) comparing surgery to surgery with preoperative radiation (ACOSOG Z9031). Unfortunately, the study was closed prematurely in 2006 because of low patient accrual. A similar study is now ongoing in Europe, sponsored by the Soft Tissue and Bone Sarcoma Group (STBSG) of the EORTC.Current recommendations for radiation therapy for patients with retroperitoneal sarcoma at high volumes centers are based on disease characteristics at presentation.183 For high-risk patients, defined as those with large, high-grade tumors or recurrent low-grade tumors, preoperative radiation therapy to a total dose of 50 Gy followed by surgical resection is considered. Postoperative radiation is discouraged unless the resected tumor bed is clearly away from dose-limiting structures.Treatment of Recurrence. Retroperitoneal sarcomas recur more often than extremity and trunk wall ones. Retroperito-neal leiomyosarcomas, in addition to recurring locally in the tumor bed and metastasizing to the lungs, frequently spread to the liver. Retroperitoneal sarcomas can also recur diffusely throughout the peritoneal cavity (sarcomatosis). Resection of recurrent retroperitoneal sarcoma is similar to resection of recurrent extremity sarcoma. However, the likelihood that a recurrent retroperitoneal sarcoma will be resectable declines precipitously with each recurrence. In a large series of patients treated at Memorial Sloan-Kettering Cancer Center, the authors were able to resect recurrent tumors in 57% of patients with a first recurrence but only 20% of patients with a second recur-rence and 10% of patients with a third recurrence.68 In up to 25% of patients, well-differentiated retroperitoneal liposarcoma recurs in a poorly differentiated form or recurs with areas of dedifferentiation. Dedifferentiated retroperitoneal liposarcoma is more aggressive than its well-differentiated precursor and has a greater propensity for distant metastasis.Gastrointestinal SarcomaPatients with gastrointestinal sarcoma most often present with nonspecific gastrointestinal symptoms that are determined by the site of the primary tumor. In a series from Memorial Sloan-Kettering Cancer Center, early satiety and dyspepsia were noted in patients with tumors of the upper gastrointestinal tract, whereas tenesmus and changes in bowel habits were common in patients with tumors of the lower gastrointestinal tract.184 In a series of 80 patients with various smooth-muscle tumors of the gastrointestinal tract, Chou and colleagues185 identified the most common presenting symptoms and signs as gastrointes-tinal bleeding (44%), abdominal mass (38%), and abdominal pain (21%).Establishing the diagnosis of a gastrointestinal sarcoma preoperatively is often difficult. Radiologic assessment, includ-ing CT of the abdomen or pelvis, is sometimes useful to deter-mine the anatomic location, size, and extent of disease. Patients with localized disease frequently present with a large intra-abdominal mass. However, there is no radiographic evidence of regional lymph node metastases, which would be typical of an adenocarcinoma of similar size and anatomic location. In patients with advanced gastrointestinal sarcoma, CT may dem-onstrate disseminated intra-abdominal masses with or without concomitant ascites and invasion of tissue planes.Endoscopy (esophagoduodenoscopy or colonoscopy) has become the mainstay for evaluating symptoms related to the gastrointestinal tract. For tumors involving the stomach, upper endoscopy with endoscopic ultrasonography and biopsy are important diagnostic tests used to distinguish gastrointestinal sarcoma from adenocarcinoma of the stomach. Endoscopic biopsy of these tumors is preferred over CT-guided biopsy if feasible. This distinction is clinically significant because the extent of resection (local excision versus gastrectomy) and the role of regional lymphadenectomy differ for these two condi-tions. For gastrointestinal sarcomas, lymphatic spread is not the primary route of metastasis; consequently, lymphadenectomy is not routinely performed as part of resection. The general rec-ommendation for gastrointestinal sarcoma, based on published data and the primary pattern of distant (vs. local) failure, is to Brunicardi_Ch36_p1567-p1598.indd 158301/03/19 6:38 PM 1584SPECIFIC CONSIDERATIONSPART IIresect the tumor with a 2to 4-cm margin of normal tissue. However, some cases may be technically challenging because of the tumor’s anatomic location or size. For example, for gastric tumors located near the gastroesophageal junction, achieving adequate surgical margins may not be possible without a total or proximal subtotal gastrectomy. This recommendation is much different when considering resection of gastrointestinal stromal tumors (GIST) where a gross margin negative resection is rec-ommended are rarely is a total gastrectomy required. Similarly, large leiomyosarcomas arising from the stomach with invasion of adjacent organs should be resected together with the adjacent involved viscera en bloc.For sarcomas of the small or large intestine, segmental bowel resection is the standard treatment. For sarcomas of the jejunum, ileum, and colon, the tumor is excised en bloc with the involved segment of intestine and its mesentery; radical mesenteric lymphadenectomy is not attempted. For sarcomas originating in the rectum, the tumor resection technique is based on the anatomic location and size of the tumor. For small, low rectal lesions, clear margins may be achievable with a transanal excision. Large or locally invasive lesions may require more extensive operations for complete tumor extirpation.186,187Breast SarcomaSarcomas of the breast are rare tumors, accounting for less than 1% of all breast malignancies and less than 5% of all soft tissue sarcomas. A variety of histologic subtypes have been reported within the breast, including angiosarcoma, stromal sarcoma, fibrosarcoma, and malignant fibrous histiocytoma.Angiosarcoma of the breast accounts for about 50% of all sarcomas of the breast and has increasingly been associated with radiation therapy for treatment of primary breast cancer.10 The period between radiation therapy and diagnosis of radiation-associated breast sarcoma has been reported to range from 3 to 20 years, with an incidence of 0.3% at 10 years and 0.5% at 15 years.188 In a retrospective study of 55 patients with angiosarcoma of the breast, patients with radiation-associated angiosarcoma were on average 30 years older and were less likely to present with distant metastases than radiation-naive patients. Clinically, radiation-associated angiosarcoma of the breast may occur in the irradiated chest wall after mastectomy or in the irradiated breast following segmental resection. The findings at presentation of a patient with cutaneous angiosarcoma often include an expanding erythematous patch, red papular eruptions, bluish-black lesions, or bruise-like discoloration overlying an area of induration. Mammography is often nonspecific, and diagnosis requires punch or incisional biopsy.Cystosarcoma phyllodes are generally not considered to be sarcomas because these tumors are thought to originate from hormonally responsive stromal cells of the breast and are usu-ally benign. In patients with these tumors, infiltrating tumor margins, severe stromal overgrowth, atypia, and cellularity have all been identified as risk factors for metastases.189As with sarcomas at other anatomic sites, histopathologic grade and tumor size are important prognostic factors for sarco-mas of the breast. The likelihood of local recurrence increases as tumor size increases; tumors smaller than 5 cm are associated with better overall survival. Local and distant recurrences are more common in patients with high-grade lesions. Complete excision with negative margins is the primary therapy. Simple mastectomy confers no additional benefit if complete excision can be accomplished by segmental mastectomy. Because of low rates of regional lymphatic spread, axillary dissection is not rou-tinely indicated. Neoadjuvant chemotherapy or radiation ther-apy may be considered for patients with large, high-risk tumors.Uterine SarcomaSarcomas account for less than 5% of uterine malignancies. Uterine sarcomas have been classified into four histologic sub-groups: uterine leiomyosarcoma, endometrial stromal sarcoma, malignant mixed Müllerian tumor (carcinosarcoma), and undif-ferentiated endometrial sarcoma. Five-year overall survival rates for patients with uterine sarcoma are 30% to 50%.190 Total abdominal hysterectomy (TAH) is recommended for localized disease. Bilateral salpingo-oophorectomy is mandatory only in endometrial stromal sarcoma. Because uterine sarcomas are rare, the benefits of adjuvant therapy (e.g., chemotherapy, hor-monal therapy) have not been adequately evaluated. Pelvic post-operative irradiation has been studied instead in a randomized fashion. The results of such study have been reported, showing no benefit in survival in favor of radiation therapy.191Uterine leiomyosarcomas are smooth-muscle tumors and account for 35% to 40% of uterine sarcomas. Leiomyosarcoma can affect women in their twenties, although it is more com-monly diagnosed between 50 and 60 years of age. Standard treatment is TAH with or without ovarian preservation depend-ing on the patient’s wishes and menopausal status. Lymph node metastasis is present in less than 5% of patients at diagnosis, and lymphadenectomy is not recommended. Adjuvant pelvic radia-tion therapy can be considered for selected high-risk patients. Adjuvant chemotherapy is controversial. Gemcitabine plus docetaxel has been noted to be well tolerated and highly active, with a response rate of 53% in patients with unresectable uter-ine leiomyosarcoma.130 Doxorubicin and trabectedin have also demonstrated activity when used as firstor second-line therapy.Endometrial stromal sarcomas account for approximately 7% to 10% of uterine sarcomas. Mitotic count is used to clas-sify endometrial stromal sarcomas as low grade (<10 mito-ses per 10 high-power fields) or high-grade (>10 mitoses per 10 high-power fields). In general, low-grade tumors demon-strate an indolent clinical course, while high-grade tumors are more aggressive with a poorer prognosis. Unlike other uterine sarcomas subtypes, endometrial stromal sarcomas express pro-gesterone receptors and have been found to be responsive to hormonal manipulation as an adjuvant therapy or for treatment of recurrent disease.192,193 Surgical treatment for these tumors includes TAH and bilateral salpingo-oophorectomy in premeno-pausal women; postoperative hormone replacement therapy is contraindicated.194 Recurrent or advanced disease may respond to antiestrogen therapy. Tamoxifen is not recommended because it may be proestrogenic in this setting.Malignant mixed müllerian tumor accounts for 50% of uterine sarcomas and arises predominantly in postmenopausal women. This tumor is regarded as epithelial and is treated not with agents typically used to treat sarcoma but with agents used to treat ovarian and endometrial cancers.Undifferentiated endometrial sarcoma is an aggressive malignancy that does not express estrogen or progesterone receptors. It is associated with a poor prognosis even in patients presenting with localized disease. TAH with or without pres-ervation of the ovaries is recommended; postoperative pelvic radiation therapy may also be administered. Systemic agents for other soft tissue sarcomas are used for recurrent and/or meta-static disease.Brunicardi_Ch36_p1567-p1598.indd 158401/03/19 6:38 PM 1585SOFT TISSUE SARCOMASCHAPTER 36GASTROINTESTINAL STROMAL TUMORSGISTs, which account for the majority of gastrointestinal sar-comas, have distinctive molecular features that have been char-acterized over the last decade. These tumors share phenotypic similarities with the intestinal pacemaker cells known as the interstitial cells of Cajal195; interstitial cells of Cajal and GIST cells express the hematopoietic progenitor cell marker CD34 and the growth factor receptor c-Kit.196 Expression of the c-Kit gene protein product, CD117, has emerged as an important defining feature of GISTs. Using these diagnostic criteria, the incidence of GIST has been estimated to be 6 to 15 cases per million individuals per year.197-199 Until recently, systemic treat-ment for patients with unresectable or metastatic GIST was of little benefit because these tumors were resistant to conventional chemotherapy. Since the recognition that KIT activation occurs in most GISTs, KIT inhibition has emerged as an adjunct to sur-gery in select patients with resectable disease and as a primary treatment modality for patients with stage IV disease.Approximately 80% of GISTs have a mutation in the gene encoding the KIT receptor tyrosine kinase, and 5% to 10% have a mutation in the gene encoding the related PDGFRA recep-tor tyrosine kinase; such mutations result in the expression of mutant proteins with constitutive tyrosine kinase activity.1 The remaining GISTs do not have a detectable mutation, but lack of a mutation does not preclude a diagnosis of GIST if the tumor is morphologically typical of GIST. The presence and type of KIT (exon 11 or exon 9) or PDGFRA (exon 18) muta-tion has been found to predict tumor response to imatinib. In a phase 2 trial, patients with KIT exon 11 mutations had bet-ter response rates (83.5% vs. 47.8%) and survival than those with KIT exon 9 mutations or those without KIT or PDGFRA mutation.200 These findings have subsequently been confirmed in two additional phase 3 trials conducted by the EORTC– Italian Sarcoma Group–Australasian Gastrointestinal Trials Group (EORTC-62005).201,202The most common locations for GISTs are the stomach (60%) and small intestine (30%), but GISTs can arise anywhere along the gastrointestinal tract.203 Gastric GISTs have been shown to be associated with a more favorable prognosis than GISTs at other sites.204 GISTs are most commonly diagnosed by upper endoscopy and/or CT of the abdomen as an incidental finding in an asymptomatic patient or in a patient being evalu-ated for symptoms of early satiety, abdominal pain, or gastroin-testinal bleeding. GIST most frequently metastasizes to the liver and/or abdominal cavity.Radiologic AssessmentStandard imaging techniques apply for GIST as for other intraabdominal sarcomas. In general, oral and IV contrast enhanced spiral CT is the staging modality of choice for GIST. CT scan of the abdomen and pelvis allows for assessment of the primary lesion and the presence or absence of intraabdomi-nal disseminated disease or metastatic disease to the liver (the two most common locations for distant metastasis of GIST). FDG-PET has been reported to be useful for preoperative stag-ing of GISTs because it may reveal early metastases and estab-lish baseline metabolic activity and may be considered in select patients where equivocal findings are identified on CT or in the setting of following metabolic response to therapy. PET has been shown to be highly sensitive in detecting early response to imatinib treatment and in predicting long-term response in patients with metastatic GIST. If PET is to be used for moni-toring response to therapy, baseline PET should be performed before initiation of treatment. Useful and effective CT-based criteria by Choi et al for detection of GIST and for predicting prognosis of GIST have also been proposed and may be used readily without incurring the cost and radiation exposure of PET/CT.205Management of Localized DiseaseComplete surgical resection with negative margins is the rec-ommended treatment for localized GISTs. Extended anatomic resection, wide margins, and lymphadenectomy are not required; therefore, total gastrectomy for gastric primaries is rarely required even with the largest of lesions. Resection of even locally advanced tumors is associated with improved survival.206 The 5-year survival rate for all patients with GISTs ranges from 20% to 44%, and the 5-year survival rate for patients with com-pletely excised early-stage tumors is up to 75%.206 An analysis of 200 patients by DeMatteo and colleagues found a disease-specific survival rate of 54% for patients with grossly complete resection of primary GIST, and the median survival duration for patients with metastatic disease was only 20 months.58As for other soft tissue sarcomas, tumor size has con-sistently been identified as an important prognostic factor for GIST. Mitotic activity has also been identified as an important prognostic factor and is generally categorized as fewer than 5, 5 to 10, or more than 10 mitoses per high-power field. The National Institutes of Health207 and the Armed Forces Insti-tute of Pathology203 have proposed prognostic criteria for risk stratification of surgically treated, localized primary GIST. Both groups take into account tumor size and mitotic count; the Armed Forces Institute of Pathology also includes tumor site as a prognostic variable. Accurate risk stratification is essential for selecting patients most likely to benefit from adjuvant treatment.Management of Locally Advanced or Metastatic DiseaseTreatment with imatinib mesylate (Gleevec, ST1571), a selec-tive inhibitor of the KIT protein tyrosine kinase, has resulted in impressive clinical responses in a large percentage of patients with unresectable or metastatic GISTs. On the basis of the initial results in a single patient with metastatic GIST, the EORTC Soft Tissue and Bone Sarcoma Group initiated a phase 1 study to test the safety and efficacy of imatinib.208 In that study, 53% of patients with GISTs had confirmed partial responses; investiga-tors concluded that imatinib is safe and effective against this disease.208 A multicenter, international trial of imatinib for GIST was begun in July 2000 at four treatment centers: Dana-Farber Cancer Institute, Oregon Health Sciences University, Fox Chase Cancer Center, and University Hospital of Helsinki, Finland.209 A total of 147 patients with unresectable or metastatic GISTs were randomized to 400 or 600 mg of imatinib daily for up to 24 months. Objective response was demonstrated in 79 patients (54%); all had partial responses, and there was no significant difference in response rate between imatinib doses.210 Fourteen percent of patients experienced disease progression. The toxic-ity profile was acceptable; the predominant effects were gastro-intestinal effects (diarrhea, nausea), periorbital edema, muscle cramps, and fatigue. However, 21% of patients experienced serious (grade 3 or 4) adverse events, including gastrointestinal bleeding in 5% of patients, most likely related to the rapid tumor response of mural lesions.Brunicardi_Ch36_p1567-p1598.indd 158501/03/19 6:38 PM 1586SPECIFIC CONSIDERATIONSPART IIA phase 3 randomized Intergroup trial was simultaneously performed to assess the clinical activity of imatinib at two dose levels for patients with unresectable or metastatic GIST express-ing the c-Kit tyrosine kinase.211 From December 15, 2000, to September 1, 2001, 746 patients were accrued and randomized to low-dose (400 mg/d) or high-dose (800 mg/d) imatinib. The primary endpoint of the trial was survival. Preliminary toxicity data from 325 patients revealed a 23% incidence of grade 3 or 4 adverse events, including nausea and vomiting, gastrointestinal bleeding, abdominal pain, edema, fatigue, and rash.In February 2002, the FDA approved imatinib for treat-ment of GIST based on the results of these promising clinical trials. Both the Intergroup trial mentioned in the preceding paragraph and a separate phase 3 trial compared the efficacy of low-dose (400 mg/d) and high-dose (800 mg/d) imatinib in patients with metastatic or unresectable GISTs.212,213 Both stud-ies showed equivalent response rates and overall survival for the two doses but increased toxicity for the 800-mg/d dose. Current recommendations include consideration of dose escalation to 800 mg/d for patients who experience disease progression at a dose of 400 mg/d and for patients with advanced GIST and KIT exon 9 mutations.1,214The optimal duration of imatinib treatment, the duration of benefit from imatinib, and the long-term toxicity of imatinib have not been established. When feasible, imatinib should be continued in the absence of disease progression. A random-ized trial reported worse median progression-free survival in patients who stopped imatinib after 1 year than in patients who continued beyond 1 year (progression-free survival of 6 months vs. 18 months).215 Less than 4% of patients with GISTs have experienced serious adverse events with imatinib. Mild gastrointestinal toxicity is the most frequently reported adverse event, but gastrointestinal tract hemorrhage, presum-ably from rapid tumor necrosis, has also been reported. Thus, all patients with GISTs treated on clinical protocols should be evaluated and followed by a team of medical professionals that includes a surgeon.Many patients with GIST develop resistance to imatinib. Primary resistance is defined as clinical progression that devel-ops during the first 6 months of treatment and is most commonly seen in patients with KIT exon 9 mutation, PDGFRA exon 18 mutation, or no mutations.216 Secondary resistance is defined as progression that develops more than 6 months after the start of treatment in a patient with an initial response.217 Imatinib resis-tance should be managed by either dose escalation or transition to treatment with sunitinib.1In 2006, sunitinib malate (SU11248, Sutent, Pfizer) emerged as an alternative systemic treatment for patients unable to tolerate imatinib and patients with imatinib-refractory GIST. Sunitinib is a tyrosine kinase inhibitor that targets multiple kinases, including the vascular endothelial growth factor receptors, PDGFRA, KIT, and FLT3. Sunitinib has both antiangiogenic and antiproliferative activity. In a phase 3, randomized, placebo-controlled trial, sunitinib was associated with a significant improvement in median time to progression (27.3 weeks vs. 6.4 weeks with placebo) in patients with imatinib-resistant GIST.135 In addition, sunitinib therapy was well tolerated; diarrhea, fatigue, and nausea were the most common adverse effects. Sunitinib has also been associated with hand-foot skin reaction, hypertension, cardiotoxicity, and hypothyroidism.218-220 In 2006, sunitinib was approved by the FDA for treatment of patients with resistance or intolerance to imatinib.The third FDA-approved drug recently made available for treatment of patients with imatiniband sunitinib-resistant GIST is regorafenib. Regorafenib is a structurally unique inhibitor of multiple cancer-associated kinases, including KIT and PDGFR, with broad-spectrum anticancer activity in preclinical and early-phase trials. Because KIT and PDGFR-α remain drivers of GIST after resistance to imatinib and sunitinib, a multicenter, single-stage phase 2 trial examined regorafenib in patients with advanced GIST after failure of at least imatinib and sunitinib.221 Thirty-four patients were enrolled from February to December 2010 and given regorafenib orally, 160 mg daily, on days 1 to 21 of a 28-day cycle. Clinical benefit was noted in 79% of patients with a median progression-free survival of 10 months. This trial was then followed by a phase 3, international, placebo-controlled, randomized trial of regorafenib for metastatic GIST after failure of imatinib and sunitinib.222 Patients with progres-sion of disease on the placebo arm were crossed to the treatment arm of the study. Patients treated with regorafenib had a median progression-free survival of 4.8 months compared to 0.9 months on the placebo arm. Other tyrosine kinase inhibitors have dem-onstrated modest activity against GIST and target more than one family of protein kinases.223 Among these are sorafenib, dasatinib, and nilotinib for the treatment of imatinib-resistant GIST, and these are now generally reserved for therapy after progression with regorafenib.222Multidisciplinary TreatmentAlthough imatinib has improved survival of patients with advanced GIST, most patients with advanced GIST are not cured with imatinib. Some patients develop secondary resistance to imatinib with one or more sites of disease progression after 6 months of clinical response (Fig. 36-10A [before imatinib], Fig. 36-10B [after imatinib]). The mechanisms of imatinib resistance are currently being investigated. Surgery has been shown to be beneficial for selected patients with isolated disease progression during imatinib therapy.224-227 Surgical resection of residual metastatic disease responding to imatinib-sensitive GIST has also been shown to result in progression-free survival in 70% to 96% of patients with imatinibor sunitinib-sensitive GISTs.226-228 The optimal timing of surgery in relation to ima-tinib therapy for patients with metastatic disease remains to be determined. It is not possible to compare outcomes for patients treated with kinase inhibitors alone and patients treated with kinase inhibitors plus surgical resection outside the context of randomized trials given the heterogeneity of patients and biases associated with selection of patients for surgical resection.Postoperative ImatinibGiven the promising results of imatinib therapy for metastatic and locally advanced GIST, the next step was to study the efficacy of imatinib as adjuvant (postoperative) treatment in patients with surgically resectable disease, particularly those at high risk for recurrence because of large tumor size or high mitotic count. The ACOSOG first evaluated the efficacy of 1 year of postoperative imatinib in a single-arm phase 2 trial with 106 patients with high-risk GIST and compared the results with historical controls. Adjuvant treatment with imatinib for GIST patients was then examined in two key trials. In the ACOSOG randomized, double-blind, phase 3 Z9001 study,230 treatment with 12 months of imatinib was compared with placebo, fol-lowing complete resection of a primary GIST smaller than 3 cm. Primary and secondary endpoints were recurrence-free survival Brunicardi_Ch36_p1567-p1598.indd 158601/03/19 6:38 PM 1587SOFT TISSUE SARCOMASCHAPTER 36ABFigure 36-10. A 57-year-old man with a history of a pelvic gastrointestinal stromal tumor involving the small bowel mesen-tery treated preoperatively with 6 months of imatinib (Gleevec). A. Before imatinib. B. After imatinib.(RFS) and overall survival (OS), respectively. Results showed a significant benefit in RFS, but not OS, with 12 months of imatinib. Based on these results, imatinib for the adjuvant treat-ment of adult patients following resection of KIT-positive GIST was approved by the FDA in 2008 and by the European Medical Agency (EMA) in 2009.A more recent study conducted by the Scandinavian Sarcoma Group (SSG) and the Sarcoma Group of the Arbe-itsgemeinschaft Internistische Onkologie (AIO; SSGXVIII/AIO trial) compared 12 versus 36 months of adjuvant imatinib 400 mg/d in patients with GIST at high risk of recurrence (defined as a GIST tumor diameter >10 cm, or mitotic count >10 per 50 high-powered fields, or tumor diameter >5 cm and mitotic count >5 per 50 high-power fields, or tumor rupture).231 Results showed that both RFS and OS significantly improved with 36 months of imatinib: the 5-year RFS rates for patients receiving 36 versus 12 months of imatinib were 65.6% versus 47.9%, respectively, and the 5-year OS rates were 92% versus 81.7%, respectively.The NCCN and the European Society of Medical Oncol-ogy now recommend that imatinib be considered for patients at intermediate or high risk of recurrence after resection and that at least 36 months of adjuvant imatinib be considered for patients at high risk of recurrence.232 Further, both the FDA and EMA updated the label, extending the duration of adjuvant therapy to at least 36 months in patients at high risk of recurrence.Whether longer treatment durations may be of further benefit is still an open question that will be addressed by future studies. However, paralleling what is commonly done in the metastatic setting, many investigators believe that even adju-vant imatinib should become a chronic therapy. While moving toward more prolonged adjuvant treatment durations, it is all the more essential to identify the appropriate patients to treat to avoid the burden of adverse events or increased financial liabil-ity for patients who will not derive therapeutic benefit from imatinib. Risk stratification based on patients’ risk of recur-rence is a key component to optimizing adjuvant treatment. The most practical stratification scheme to use for making a decision for adjuvant therapy is the modified National Insti-tutes of Health consensus criteria.233 High-risk GIST patients, whose tumor harbors a sensitive genotype, should be treated by adjuvant imatinib because they have a poor prognosis. On the contrary, neither low-risk nor intermediate-risk GIST patients need adjuvant therapy, even if their tumor carries a sensitive genotype. In fact, evidence has been provided that the out-come of these patients with intermediateor low-risk GIST is good. When using other risk stratification schemes, such as the Armed Forces Institute of Pathology table, Memorial Sloan-Kettering Cancer Center nomogram, or the heat map,204,234,235 there is a consensus to treat all patients having 30% or higher risk of recurrence, if their tumor carries a sensitive genotype. There is also a consensus not to treat patients having 10% or less risk of recurrence, even if their tumor carries a sensitive genotype. All patients having a risk between 10% and 30% should be evaluated on a case-by-case basis, and advantages/disadvantages of treatment should be made clear and discussed with the patient. Whenever a decision for adjuvant therapy is made, treatment duration of at least 36 months should be con-sidered independently from the risk.Beside the risk of recurrence, the other important factor to consider is the tumor genotype. In other words, as found in both the metastatic and adjuvant settings, GIST tumors with KIT exon 11 and PDGFRA non-D842V mutations are sensitive to imatinib. Patients with these mutations are suitable for adjuvant imatinib if the risk determined by stratification tools is signifi-cant. Patients with KIT exon 9 mutations should also be treated; a higher dose (800 mg/d) may be more appropriate but remains to be studied clinically. Patients with PDGFRA D842V–mutated tumors should not be treated with adjuvant imatinib, nor should patients with KIT and PDGFRA wild-type tumors associated with neurofibromatosis type 1 or the pediatric GIST/Carney-Stratakis syndromes, whatever the risk. Patients with sporadic wild-type GIST could be treated on an individual basis.Preoperative ImatinibPatients with marginally resectable GIST or at significant risk for operative morbidity should be considered for preoperative imatinib with close monitoring. Since the optimal duration of preoperative therapy is unknown, imatinib should be continued until maximal response is achieved or until there is evidence of progression.236 Preoperative imatinib can be stopped imme-diately before surgery and resumed when oral medications are restarted.Brunicardi_Ch36_p1567-p1598.indd 158701/03/19 6:38 PM 1588SPECIFIC CONSIDERATIONSPART IIPreoperative imatinib in patients with primary GIST or resectable metastatic GIST has been evaluated in the context of two randomized phase 2 studies. The Radiation Treatment Oncology Group (RTOG 0132/ACRIN 6665) evaluated the efficacy of preoperative imatinib (600 mg/d) for 8 to 10 weeks before surgery and 24 months after surgery in patients with primary (n = 30) or potentially resectable recurrent or metastatic (n = 22) tumors.237 Primarily stable disease was noted during imatinib treatment, and the 2-year progression-free survival rates were 83% for primary GIST and 77% for recurrent or metastatic GIST. In another study, 19 patients undergoing surgical resection at a single institution were randomized to preoperative imatinib (600 mg/d) for 3, 5, or 7 days followed by surgical resection and postoperative imatinib for 24 months. The response rate assessed using FDG-PET was 69%, and the median disease-free survival time following treatment with surgery and imatinib was 46 months.238 Similar results were observed in a prospective series of patients treated at a major institution.239All of these studies show that neoadjuvant treatment is feasible, but to maximize the benefit of preoperative therapy, the following factors need to be considered. First, the patient should in principle have a favorable mutational status; other-wise, the treatment would be in vain, allowing the tumor to con-tinue growing. Fortunately, the majority of GISTs will respond, but it should not be forgotten that, especially in gastric loca-tion, the amount of insensitive mutations in the localized setting is less uncommon than what has been previously reported.240 However, we do not absolutely need to know the mutational status in advance, but we should be aware that mutation is an issue. Alternatively, if mutation status is not determined prior to treatment, we may also check response very early, either by CT, PET, or contrast-enhanced ultrasound. If a radiographic response is detected within a month, then the mutation status is likely favorable, and the treatment could be continued with-out necessarily pursuing mutation testing. If not, then mutation status should be investigated before continuing the treatment.Second, the resectability of the tumor and the extent of resection necessary should be considered. Other than presenta-tions of clearly inoperable tumors (which are usually treated with imatinib upfront) or symptomatic tumors requiring urgent intervention (hemorrhage, perforation, etc), there are few rea-sons today to perform extended procedures (i.e., multivisceral resections or formal organ resections) without first attempting preoperative therapy. For instance, patients with large GISTs who may require a long midline incision for resection may benefit from neoadjuvant imatinib to downstage the operation, potentially converting an open laparotomy approach to a laparo-scopic one. Another typical circumstance in which neoadjuvant therapy may be beneficial is in patients with GISTs arising in the esophagus, gastroesophageal junction, duodenum, or distal rectum. Preoperative treatment may shrink the tumor and allow a more conservative local excision. In general, such patients would normally undergo postoperative adjuvant treatment as well because of the expected recurrence risk. The chance of obtaining a response is high, and the benefit for tumor shrink-age obvious, so this approach should always be discussed with patients affected by bulky and/or poorly located disease (esoph-agus, gastroesophageal junction, duodenum, distal rectum) as well as for those who would be candidates for an adjuvant treat-ment anyway.Third, in the studies mentioned earlier, patients underwent surgery after a limited treatment duration (3 months at best). It is now well known that the preoperative treatment may result in sustained tumor shrinkage if given for a longer duration. Sur-gical resection may then be performed between 6 and 12 months or sooner if treatment effect plateaus. This allows for optimal tumor shrinkage, or at least shrinkage to the point where there is no further benefit to be gained by further neoadjuvant therapy without the risk of developing secondary resistance.DESMOIDSDesmoid tumors are not low-grade sarcomas but can be locally aggressive, although they do not metastasize. Approximately half of these tumors arise in the extremities; the remaining lesions are located on the trunk or in the retroperitoneum. Abdominal wall desmoids are associated with pregnancy and are thought to be the result of hormonal influence. Although usually sporadic, desmoids may occur in association with famil-ial adenomatous polyposis, a presentation that is referred to as Gardner’s syndrome and is linked to germline mutations in the APC gene. Sporadic cases of desmoid fibromatosis are com-monly linked to mutations in CTNNB1, the gene for β-catenin.The primary therapy for desmoid tumors has long been considered surgical resection with wide local excision to achieve negative margins. However, local recurrence occurs in up to one-third of patients independently of the quality of surgical margins.241-243 Up to two-thirds of the patients operated on with positive margins do not recur. This is why there is growing evidence that the primary approach could be more conservative. Function-sparing operations should be the goal, even if a positive margin is left on a critical structure. Moreover, some authors advocate the possibility to observe patients at presentation, limiting surgery to those who progress or fail medical therapies. It has in fact been reported that by this approach, up to 50% of patients skip surgical resection.244,245 Radiation therapy may be effective in patients with unresectable tumors or as adjuvant therapy following surgery for recurrent disease, although long-term side effects and the risk of radiation-induced sarcoma should always be considered. When used, a dose of 50 to 54 Gy is usually recommended. Systemic treatment is another option when surgery is not indicated. Hormonal therapies such as tamoxifen have been reported to be beneficial, as have nonsteroidal anti-inflammatory drugs, which are known to affect the β-catenin signaling pathways. Chemotherapy is also effective, although usually reserved for patients with tumor-associated symptoms who have not responded to other interventions. Combinations of methotrexate and vinblastine have been shown to have activity, as have single-agent pegylated liposomal doxorubicin246 and sorafenib.247 Imatinib has also been studied with unconvincing results.248-250DERMATOFIBROSARCOMA PROTUBERANSDermatofibrosarcoma protuberans is a rare low-grade sarcoma arising in the dermis that rarely metastasizes but is locally aggressive. The overall annual incidence has been estimated at 4.2 cases per million individuals,251 and the incidence is higher among blacks than whites (6.5 vs. 3.9 per million per year). Approximately 40% of cases arise on the trunk, and most of the remaining tumors are distributed between the head and neck and the extremities. Dermatofibrosarcoma protuberans presents as a nodular, cutaneous mass that grows slowly and persistently. Satellite lesions may be found in patients with larger tumors. Brunicardi_Ch36_p1567-p1598.indd 158801/03/19 6:38 PM 1589SOFT TISSUE SARCOMASCHAPTER 36Standard treatment is wide local excision, which generally results in local recurrence rates of less than 10%.252 Although local recurrence rates as high as 30% to 50% have been reported in population-based series, the associated 5-year survival rate is greater than 99%.251Dermatofibrosarcoma protuberans arises from a specific chromosomal translocation involving chromosomes 17 and 22, in which the collagen 1 α 1 gene is fused to the gene for PDGF β-chain (PDGFB).253 The resultant deregulated expression of PDGFB leads to continuous activation of the PDGFR protein tyrosine kinase, which promotes tumor cell growth. The identification of this chromosomal translocation in more than 90% of cases of dermatofibrosarcoma protuberans has led to the development of targeted therapy. Inhibiting PDGFR with imatinib has been shown to induce clinical and radiologic improvement in patients with unresectable dermatofibrosarcoma protuberans.21 These data have resulted in the approval by the FDA of imatinib for treatment of patients with locally advanced dermatofibrosarcoma protuberans.PEDIATRIC SARCOMASSoft tissue sarcomas in children are relatively rare, accounting for 7% to 8% of all pediatric cancers and totaling approximately 600 new cases per year.254 Pediatric sarcomas have traditionally been divided into two groups: rhabdomyosarcoma and nonrhab-domyosarcoma soft tissue sarcomas.RhabdomyosarcomaAssociated with skeletal muscle, rhabdomyosarcomas are the most common soft tissue tumors among children younger than 15 years and can occur at any site comprised of striated muscle. Patients with these tumors generally present with a painless enlarging mass; about 24% of tumors are located in the geni-tourinary system, 20% in the extremities, 20% in the head and neck, 16% in the parameningeal region, and 22% in other sites.255Rhabdomyosarcoma is a small round cell tumor that dem-onstrates muscle differentiation upon light microscopy and immunohistochemical analysis. Two primary histologic sub-types account for 90% of cases: embryonal (70%) and alveolar (20%). Alveolar rhabdomyosarcoma is associated with cytoge-netic translocation [t(2:13)(q35:q14)] in 85% to 90% of cases and [t(1:13)(p36:q14)] in 10% of cases.256 These translocations affect biologic activity at the levels of protein function and gene expression, thereby affecting the control of cell growth, apopto-sis, differentiation, and motility and ultimately contributing to tumorigenic behavior.256 Whereas alveolar rhabdomyosarcomas often have translocations, most embryonal rhabdomyosarcomas have an allelic loss at chromosome 11p15.5 that is thought to inactivate a tumor suppressor gene.256,257 Both of these dis-tinct molecular subtypes of rhabdomyosarcoma are thought to have similar alterations in downstream targets such as the p53 and Rb pathways.256 Further insight into these genetic altera-tions may lead to a better understanding of the pathogenesis of rhabdomyosarcoma and provide novel targets for therapeutic approaches.Extent of disease is the strongest predictor of long-term outcome. Several staging systems for rhabdomyosarcoma are available. The Intergroup Rhabdomyosarcoma Study Group system is based on surgical-pathologic groupings. Multidis-ciplinary evaluation including pediatric oncologists, surgical subspecialists, and radiation oncologists is critical to plan the best treatment approach to maximize local tumor control while minimizing long-term treatment effects.Complete surgical resection is the treatment of choice for rhabdomyosarcoma when function and cosmesis can be preserved. Patients who are able to undergo a complete tumor resection with negative (group I) or microscopic surgical mar-gins (group II) are able to undergo less intensive systemic ther-apy and still have overall survival rates approaching 90%.258 At some anatomic sites, in particular the head and neck and genito-urinary system, surgery is often avoided because the associated morbidity would be substantial. Recent findings suggest that chemotherapy alone can adequately control many such tumors. In the second International Society of Paediatric Oncology study of rhabdomyosarcoma (MMT84), the choice of local treatment was based on response to initial chemotherapy such that radical surgery and radiation therapy were avoided in 66% of patients. Among the patients who subsequently developed local relapse, the 5-year overall survival rate after salvage therapy was 46%.258Unlike other soft tissue sarcomas, rhabdomyosarcomas have a high propensity for lymph node metastasis, with rates up to 20% to 30% for sites such as the extremities, parates-ticular nodes, and prostate. Lymph node sampling and, more recently, sentinel lymph node mapping have been used to evalu-ate regional node status in children with rhabdomyosarcoma.About 15% to 20% of patients with rhabdomyosarcoma have distant metastasis at presentation, most commonly (40–50% of cases) to the lungs, followed by bone marrow and bone. However, all patients with rhabdomyosarcoma are assumed to have micrometastatic disease at presentation. Therefore, multia-gent chemotherapy is recommended for all patients with rhab-domyosarcoma. Combination regimens including vincristine, dactinomycin, and cyclophosphamide continue to be the basis of effective curative therapy.254 Although various combinations including doxorubicin, ifosfamide, cisplatin, and etoposide have been shown to be active against rhabdomyosarcoma, they have not improved outcomes.258,259 Radiation therapy is given to most patients with microscopic residual disease (group II) after resection.The prognosis for children with rhabdomyosarcomas is related to tumor site, surgical-pathologic grouping, and tumor histology. The 5-year disease-free survival rate for all patients has been reported to be 65%. Five-year disease-free survival rates for patients in groups I, II, III, and IV have been reported to be 84%, 74%, 62%, and 23%, respectively (see Table 36-3).260Nonrhabdomyosarcoma Soft Tissue SarcomasApproximately 60% of soft tissue sarcomas in children are nonrhabdomyosarcomas. These include numerous histologic subtypes, which are generally categorized into four groups: (a) fibrosarcoma, (b) Kaposi’s sarcoma, (c) other “specified” soft tissue sarcomas (e.g., synovial, angiosarcoma, hemangiopericy-toma, leiomyosarcoma, liposarcoma, and extraosseous Ewing’s sarcoma), and (d) “unspecified” soft tissue sarcoma.261 The most common subtypes are synovial sarcoma, MPNST, and fibro-sarcoma. No single histology accounts for more than 15% of all cases.As with adult tumors, the evaluation of the soft tissue mass begins with a history and physical examination followed by imaging, which usually includes MRI. A CT scan of the chest is important for evaluation of metastatic disease. A core needle biopsy is generally required to establish a diagnosis. Surgery remains the primary treatment of nonrhabdomyosarcoma, and Brunicardi_Ch36_p1567-p1598.indd 158901/03/19 6:38 PM 1590SPECIFIC CONSIDERATIONSPART IIlocal control of large, high-grade tumors is improved with radia-tion therapy. The prognostic factors for children with nonrhab-domyosarcoma are similar to those for adults, and the role of chemotherapy for high-risk tumors is unclear, as for adults.RESEARCH PERSPECTIVESAs the molecular alterations associated with various sar-coma subtypes are elucidated, many new potential targets for therapeutic intervention will be identified. A wide variety of DNA alterations have been observed in sarcomas that result in mutated genes encoding proteins ranging from transcription fac-tors to tyrosine kinases to cytokines. The challenge in identify-ing therapeutic targets in sarcoma is to identify those that are specifically important to cellular function. The ideal therapeutic target has been described as a single molecule that is critical for pathogenesis, is expressed and active, is involved in a single pathway amenable to blockade (i.e., no alternative bypass path-ways exist), and is critical for sarcoma cell survival.25CONCLUSIONSSoft tissue sarcomas are a heterogeneous family of rare tumors, accounting for approximately 1% of malignancies in adults. The etiology in the vast majority of patients is sporadic, and the man-agement of such diverse tumors is complex. Diagnosis by light microscopy is inexact, but molecular diagnosis, although still in its infancy, holds great promise. The natural history of soft tissue sarcomas is well established. Approximately two-thirds of cases arise in the extremities, and the remaining one-third are distrib-uted between the retroperitoneum, trunk, abdomen, and head and neck. The management algorithm for soft tissue sarcomas is complex and depends on tumor stage, site, and histology. The most common site of metastasis is the lungs, and metastasis generally occurs within 3 years of diagnosis.Soft tissue sarcomas have unique molecular profiles that contribute to varying responses to systemic therapy. Doxorubicinbased regimens have been the mainstay of treatment for the past two decades; however, it is now clear that specific histologic subtypes have increased sensitivity to specific agents. For exam-ple, angiosarcomas are more sensitive to paclitaxel, while leio-myosarcoma is sensitive to gemcitabine and docetaxel. Progress in understanding of soft tissue sarcoma biology is crucial for the development of additional therapeutic targets. Drug engineering will enable molecular-based therapies to become increasingly incorporated into clinical trials and, with success, into standard treatment strategies for soft tissue sarco-mas in the near future.REFERENCESEntries highlighted in bright blue are key references. 1. Demetri GD, Benjamin RS, Blanke CD, et al. NCCN Task Force report: management of patients with gastrointestinal stromal tumor (GIST)—update of the NCCN clinical practice guidelines. J Natl Compr Canc Netw. 2007;5(suppl 2):S1-S29; quiz S30. 2. Coindre JM, Terrier P, Guillou L, et al. Predictive value of grade for metastasis development in the main histologic types of adult soft tissue sarcomas: a study of 1240 patients from the French Federation of Cancer Centers Sarcoma Group. Cancer. 2001;91:1914-1926. 3. Gronchi A, Miceli R, Colombo C, et al. Primary extremity soft tissue sarcomas: outcome improvement over time at a single institution. Ann Oncol. 2011;22:1675-1681. 4. Gronchi A, Pollock R. Surgery in retroperitoneal soft tissue sarcoma: a call for a consensus between Europe and North America. Ann Surg Oncol. 2011;18:2107-2110. 5. American Cancer Society. Cancer Facts and Figures 2017. Available at: https://www.cancer.org/research/cancer-facts-statistics/all-cancer-facts-figures/cancer-facts-figures-2017 .html. Accessed August 3, 2018. 6. Gatta G, Van Der Zwan JM, Casali PG, et al. Rare cancers are not so rare: the rare cancer burden in Europe. Eur J Cancer. 2011;47:2493-2511. 7. Siegel R, Naishadham D, Jemal A. Cancer statistics, 2012. CA Cancer J Clin. 2012;62:10-29. 8. Gonin-Laurent N, Hadj-Hamou N, Vogt N, et al. RB1 and TP53 pathways in radiation-induced sarcomas. Oncogene. 2007;26:6106-6112. 9. Brady MS, Gaynor JJ, Brennan MF. Radiation-associated sarcoma of bone and soft tissue. Arch Surg. 1992;127: 1379-1385. 10. Vorburger SA, Xing Y, Hunt KK, et al. Angiosarcoma of the breast. Cancer. 2005;104:2682-2688. 11. Riad S, Biau D, Holt GE, et al. The clinical and functional outcome for patients with radiation-induced soft tissue sarcoma. Cancer. 2012;118:2682-2692. 12. Dineen SP, Roland CL, Feig R, et al. Radiation-associated undifferentiated pleomorphic sarcoma is associated with worse clinical outcomes than sporadic lesions. Ann Surg Oncol. 2015;22(12):3913-3920. 13. Smith AH, Pearce NE, Fisher DO, et al. Soft tissue sarcoma and exposure to phenoxyherbicides and chlorophenols in New Zealand. J Natl Cancer Inst. 1984;73:1111-1117. 14. Huang HY, Li CF, Huang WW, et al. A modification of NIH consensus criteria to better distinguish the highly lethal subset of primary localized gastrointestinal stromal tumors: a subdi-vision of the original high-risk group on the basis of outcome. Surgery. 2007;141:748-756. 15. Stewart FW. Lymphangiosarcoma in post-mastectomy lymphedema; a report of six cases in elephantiasis chirurgica. Cancer. 1948;1(1):64-81. 16. Stewart NJ, Pritchard DJ, Nascimento AG, et al. Lymphan-giosarcoma following mastectomy. Clin Orthop Relat Res. 1995;320:135-141. 17. Kelly-Hope LA, Thomas BC, Bockarie MJ, et al. Lymphatic filariasis in the Democratic Republic of Congo; micro-stratification overlap mapping (MOM) as a prerequisite for control and surveillance. Parasit Vectors. 2011;4:178. 18. Pardini M, Bonzano L, Roccatagliata L, et al. Functional mag-netic resonance evidence of cortical alterations in a case of reversible congenital lymphedema of the lower limb: a pilot study. Lymphology. 2007;40:19-25. 19. Schiffman S, Berger A. Stewart-Treves syndrome. J Am Coll Surg. 2007;204:328. 20. Demicco EG, Maki RG, Lev DC, et al. New therapeutic targets in soft tissue sarcoma. Adv Anat Pathol. 2012;19: 170-180. 21. Wunder JS, Nielsen TO, Maki RG, et al. Opportunities for improving the therapeutic ratio for patients with sarcoma. Lancet Oncol. 2007;8:513-524. 22. Guillou L, Benhattar J, Gengler C, et al. Translocation-positive low-grade fibromyxoid sarcoma: clinicopathologic and molec-ular analysis of a series expanding the morphologic spectrum and suggesting potential relationship to sclerosing epithelioid fibrosarcoma: a study from the French Sarcoma Group. Am J Surg Pathol. 2007;31:1387-1402. 23. Levine EA. Prognostic factors in soft tissue sarcoma. Semin Surg Oncol. 1999;17:23-32.678Brunicardi_Ch36_p1567-p1598.indd 159001/03/19 6:38 PM 1591SOFT TISSUE SARCOMASCHAPTER 36 24. Sorensen PH, Triche TJ. Gene fusions encoding chimaeric transcription factors in solid tumours. Semin Cancer Biol. 1996;7:3-14. 25. Borden EC, Baker LH, Bell RS, et al. Soft tissue sarcomas of adults: state of the translational science. Clin Cancer Res. 2003;9:1941-1956. 26. Oda Y, Tsuneyoshi M. Recent advances in the molecular pathology of soft tissue sarcoma: implications for diagnosis, patient prognosis, and molecular target therapy in the future. Cancer Sci. 2009;100:200-208. 27. Karnes PS. Neurofibromatosis: a common neurocutaneous disorder. Mayo Clin Proc. 1998;73:1071-1076. 28. Fong Y, Coit DG, Woodruff JM, et al. Lymph node metasta-sis from soft tissue sarcoma in adults. Analysis of data from a prospective database of 1772 sarcoma patients. Ann Surg. 1993;217:72-77. 29. Benns M, Dalsing M, Sawchuck A, et al. Soft tissue sarcomas may present with deep vein thrombosis. J Vasc Surg. 2006;43:788-793. 30. Grimer R, Judson I, Peake D, et al. Guidelines for the manage-ment of soft tissue sarcomas. Sarcoma. 2010;2010:506182. 31. Heslin MJ, Smith JK. Imaging of soft tissue sarcomas. Surg Oncol Clin N Am. 1999;8:91-107. 32. Pearlstone DB, Pisters PW, Bold RJ, et al. Patterns of recur-rence in extremity liposarcoma: implications for staging and follow-up. Cancer. 1999;85:85-92. 33. Roberge D, Hickeson M, Charest M, et al. Initial McGill expe-rience with fluorodeoxyglucose PET/CT staging of soft-tissue sarcoma. Curr Oncol. 2010;17:18-22. 34. Tateishi U, Yamaguchi U, Seki K, et al. Bone and soft-tissue sarcoma: preoperative staging with fluorine 18 fluorode-oxyglucose PET/CT and conventional imaging. Radiology. 2007;245:839-847. 35. Iagaru A, Quon A, McDougall IR, et al. F-18 FDG PET/CT evaluation of osseous and soft tissue sarcomas. Clin Nucl Med. 2006;31:754-760. 36. Piperkova E, Mikhaeil M, Mousavi A, et al. Impact of PET and CT in PET/CT studies for staging and evaluating treatment response in bone and soft tissue sarcomas. Clin Nucl Med. 2009;34:146-150. 37. Schuetze SM. Utility of positron emission tomography in sarcomas. Curr Opin Oncol. 2006;18:369-373. 38. Schuetze SM, Rubin BP, Vernon C, et al. Use of positron emission tomography in localized extremity soft tissue sar-coma treated with neoadjuvant chemotherapy. Cancer. 2004;103:339-348. 39. Folpe AL, Lyles RH, Sprouse JT, et al. (F-18) fluorodeoxy-glucose positron emission tomography as a predictor of patho-logic grade and other prognostic variables in bone and soft tissue sarcoma. Clin Cancer Res. 2000;6:1279-1287. 40. Eary JF, O’Sullivan F, Powitan Y, et al. Sarcoma tumor FDG uptake measured by PET and patient outcome: a retrospective analysis. Eur J Nucl Med Mol Imaging. 2002;29:1149-1154. 41. Benz MR, Czernin J, Allen-Auerbach MS, et al. FDG-PET/CT imaging predicts histopathologic treatment responses after the initial cycle of neoadjuvant chemotherapy in high-grade soft-tissue sarcomas. Clin Cancer Res. 2009;15:2856-2863. 42. Kilpatrick SE, Geisinger KR. Soft tissue sarcomas: the use-fulness and limitations of fine-needle aspiration biopsy. Am J Clin Pathol. 1998;110:50-68. 43. Yang YJ, Damron TA. Comparison of needle core biopsy and fine-needle aspiration for diagnostic accuracy in musculoskel-etal lesions. Arch Pathol Lab Med. 2004;128:759-764. 44. Clark MA, Fisher C, Judson I, et al. Soft-tissue sarcomas in adults. N Engl J Med. 2005;353:701-711. 45. Ayala AG, Ro JY, Fanning CV, et al. Core needle biopsy and fine-needle aspiration in the diagnosis of bone and soft-tissue lesions. Hematol Oncol Clin North Am. 1995;9:633-651. 46. Dupuy DE, Rosenberg AE, Punyaratabandhu T, et al. Accuracy of CT-guided needle biopsy of musculoskeletal neoplasms. AJR Am J Roentgenol. 1998;171:759-762. 47. Strauss DC, Qureshi YA, Hayes AJ, et al. The role of core nee-dle biopsy in the diagnosis of suspected soft tissue tumours. J Surg Oncol. 2010;102:523-529. 48. Skrzynski MC, Biermann JS, Montag A, et al. Diagnostic accuracy and charge-savings of outpatient core needle biopsy compared with open biopsy of musculoskeletal tumors. J Bone Joint Surg. 1996;78:644-649. 49. Huvos AG. The importance of the open surgical biopsy in the diagnosis and treatment of bone and soft-tissue tumors. Hematol Oncol Clin North Am. 1995;9:541-544. 50. Potter DA, Glenn J, Kinsella T, et al. Patterns of recurrence in patients with high-grade soft-tissue sarcomas. J Clin Oncol. 1985;3:353-366. 51. Noria S, Davis A, Kandel R, et al. Residual disease following unplanned excision of a soft-tissue sarcoma of an extremity. J Bone Joint Surg Am. 1996;78:650-655. 52. Presant CA, Russell WO, Alexander RW, et al. Soft-tissue and bone sarcoma histopathology peer review: the frequency of disagreement in diagnosis and the need for second pathology opinions. The Southeastern Cancer Study Group experience. J Clin Oncol. 1986;4:1658-1661. 53. Pfeifer J, Hill D, O’Sullivan M, et al. Diagnostic gold standard for soft tissue tumours: morphology or molecular genetics? Histopathology. 2002;37:485-500. 54. Fletcher CD, Gustafson P, Rydholm A, et al. Clinicopatho-logic re-evaluation of 100 malignant fibrous histiocytomas: prognostic relevance of subclassification. J Clin Oncol. 2001;19:3045-3050. 55. Tschoep K, Kohlmann A, Schlemmer M, et al. Gene expression profiling in sarcomas. Crit Rev Oncol Hematol. 2007;63:111-124. 56. Coindre JM, Hostein I, Maire G, et al. Inflammatory malig-nant fibrous histiocytomas and dedifferentiated liposarcomas: histological review, genomic profile, and MDM2 and CDK4 status favour a single entity. J Pathol. 2004;203:822-830. 57. Coindre JM. Grading of soft tissue sarcomas: review and update. Arch Pathol Lab Med. 2006;130:1448-1453. 58. DeMatteo RP, Lewis JJ, Leung D, et al. Two hundred gastro-intestinal stromal tumors: recurrence patterns and prognostic factors for survival. Ann Surg. 2000;231:51-58. 59. Coindre JM, Terrier P, Bui NB, et al. Prognostic factors in adult patients with locally controlled soft tissue sarcoma. A study of 546 patients from the French Federation of Cancer Centers Sarcoma Group. J Clin Oncol. 1996;14:869-877. 60. Guillou L, Coindre JM, Bonichon F, et al. Comparative study of the National Cancer Institute and French Federation of Cancer Centers Sarcoma Group grading systems in a population of 410 adult patients with soft tissue sarcoma. J Clin Oncol. 1997;15:350-362. 61. Rubin BP, Fletcher CD, Inwards C, et al. Protocol for the examination of specimens from patients with soft tissue tumors of intermediate malignant potential, malignant soft tissue tumors, and benign/locally aggressive and malignant bone tumors. Arch Pathol Lab Med. 2006;130:1616-1629. 62. Amin MB, Edge SB, Greene FL, et al. AJCC Staging Manual. 8th ed. New York: Springer; 2017. 63. Lahat G, Tuvin D, Wei C, et al. New perspectives for staging and prognosis in soft tissue sarcoma. Ann Surg Oncol. 2008;15:2739-2748. 64. Atalay C, Altinok M, Seref B. The impact of lymph node metastases on survival in extremity soft tissue sarcomas. World J Surg. 2007;31:1433-1437. 65. Riad S, Griffin AM, Liberman B, et al. Lymph node metastasis in soft tissue sarcoma in an extremity. Clin Orthop Relat Res. 2004;426:129-134.Brunicardi_Ch36_p1567-p1598.indd 159101/03/19 6:38 PM 1592SPECIFIC CONSIDERATIONSPART II 66. Behranwala KA, A’Hern R, Omar AM, et al. Prognosis of lymph node metastasis in soft tissue sarcoma. Ann Surg Oncol. 2004;11:714-719. 67. Grobmyer SR, Brennan MF. Predictive variables detailing the recurrence rate of soft tissue sarcomas. Curr Opin Oncol. 2003;15:319-326. 68. Gronchi A, Lo Vullo S, Colombo C, et al. Extremity soft tissue sarcoma in a series of patients treated at a single institution: local control directly impacts survival. Ann Surg. 2010;251:506. 69. Heslin MJ, Cordon-Cardo C, Lewis JJ, et al. Ki-67 detected by MIB-1 predicts distant metastasis and tumor mortality in primary, high grade extremity soft tissue sarcoma. Cancer. 1998;83:490-497. 70. Ch’ng E, Tomita Y, Zhang B, et al. Prognostic signifi-cance of CD100 expression in soft tissue sarcoma. Cancer. 2007;110:164-172. 71. Kattan MW, Leung DH, Brennan MF. Postoperative nomo-gram for 12-year sarcoma-specific death. J Clin Oncol. 2002;20:791-796. 72. Eilber FC, Kattan MW. Sarcoma nomogram: validation and a model to evaluate impact of therapy. J Am Coll Surg. 2007;205:S90-S95. 73. Dalal KM, Kattan MW, Antonescu CR, et al. Subtype spe-cific prognostic nomogram for patients with primary liposar-coma of the retroperitoneum, extremity, or trunk. Ann Surg. 2006;244:381-391. 74. Gronchi A, Miceli R, Shurell E, et al. Outcome prediction in primary resected retroperitoneal soft tissue sarcoma: histology-specific overall survival and disease-free survival nomograms built on major sarcoma center datasets. J Clin Oncol. 2013;31:1649-1655. 75. Clasby R, Tilling K, Smith M, et al. Variable management of soft tissue sarcoma: regional audit with implications for spe-cialist care. Br J Surg. 1997;84:1692-1696. 76. Gutierrez JC, Perez EA, Moffat FL, et al. Should soft tissue sarcomas be treated at high-volume centers? An analysis of 4205 patients. Ann Surg. 2007;245:952-958. 77. National Institutes of Health. National Institutes of Health consensus development panel on limb-sparing treatment of adult soft tissue sarcoma and osteosarcomas, Vol. 3, Cancer Treatment Symposium, 1985. Available at: http://consensus.nih.gov/1984/1984SarcomasOsteosarcomas046html. 78. McKee MD, Liu DF, Brooks JJ, et al. The prognostic significance of margin width for extremity and trunk sarcoma. J Surg Oncol. 2004;85:68-76. 79. Herbert SH, Corn BW, Solin LJ, et al. Limb-preserving treat-ment for soft tissue sarcomas of the extremities. The signifi-cance of surgical margins. Cancer. 1993;72:1230-1238. 80. Pisters P, Leung D, Woodruff J, et al. Analysis of prognostic factors in 1,041 patients with localized soft tissue sarcomas of the extremities. J Clin Oncol. 1996;14:1679-1689. 81. Alektiar K, Velasco J, Zelefsky M, et al. Adjuvant radiotherapy for margin-positive high-grade soft tissue sarcoma of the extremity. Int J Radiat Oncol Biol Phys. 2000;48:1051-1058. 82. Kim BK, Chen YLE, Kirsch DG, et al. An effective preoperative three-dimensional radiotherapy target volume for extremity soft tissue sarcoma and the effect of margin width on local control. Int J Radiat Oncol Biol Phys. 2010;77:843-850. 83. McKay A, Motamedi M, Temple W, et al. Vascular recon-struction with the superficial femoral vein following major oncologic resection. J Surg Oncol. 2007;96:151-159. 84. Schwarzbach MH, Hormann Y, Hinz U, et al. Results of limb-sparing surgery with vascular replacement for soft tissue sarcoma in the lower extremity. J Vasc Surg. 2005;42:88-97. 85. Karakousis CP, Karmpaliotis C, Driscoll DL. Major vessel resec-tion during limb-preserving surgery for soft tissue sarcomas. World J Surg. 1996;20:345-349; discussion 350. 86. Ghert MA, Davis AM, Griffin AM, et al. The surgical and functional outcome of limb-salvage surgery with vascular reconstruction for soft tissue sarcoma of the extremity. Ann Surg Oncol. 2005;12:1102-1110. 87. Brooks A, Gold J, Graham D, et al. Resection of the sciatic, peroneal, or tibial nerves: assessment of functional status. Ann Surg Oncol. 2002;9:41-47. 88. Ferguson PC, Griffin AM, O’Sullivan B, et al. Bone invasion in extremity soft-tissue sarcoma: impact on disease outcomes. Cancer. 2006;106:2692-2700. 89. Lin PP, Pino ED, Normand AN, et al. Periosteal margin in soft-tissue sarcoma. Cancer. 2007;109:598-602. 90. Owens JC, Shiu MH, Smith R, et al. Soft tissue sarcomas of the hand and foot. Cancer. 2006;55:2010-2018. 91. Schoenfeld GS, Morris CG, Scarborough MT, et al. Adjuvant radiotherapy in the management of soft tissue sarcoma involving the distal extremities. Am J Clin Oncol. 2006;29: 62-65. 92. Ferguson PC. Surgical considerations for management of distal extremity soft tissue sarcomas. Curr Opin Oncol. 2005;17:366-369. 93. Davidge K, Bell R, Ferguson P, et al. Patient expectations for surgical outcome in extremity soft tissue sarcoma. J Surg Oncol. 2009;100:375-381. 94. Rosenberg SA, Tepper J, Glatstein E, et al. The treatment of soft-tissue sarcomas of the extremities: prospective randomized evaluations of (1) limb-sparing surgery plus radiation therapy compared with amputation and (2) the role of adjuvant chemotherapy. Ann Surg. 1982;196(3):305-315. 95. Lindberg RD, Martin RG, Romsdahl MM, et al. Conservative surgery and postoperative radiotherapy in 300 adults with soft-tissue sarcomas. Cancer. 1981;47:2391-2397. 96. Suit HD, Proppe KH, Mankin HJ, et al. Preoperative radiation therapy for sarcoma of soft tissue. Cancer. 1981;47:2269-2274. 97. Leibel SA, Tranbaugh RF, Wara WM, et al. Soft tissue sarco-mas of the extremities: survival and patterns of failure with conservative surgery and postoperative irradiation compared to surgery alone. Cancer. 1982;50:1076-1083. 98. McBride CM. Sarcomas of the limbs. Results of adjuvant chemotherapy using isolation perfusion. Arch Surg. 1974;109:304-308. 99. Hoekstra HJ, Schraffordt Koops H, Molenaar WM, et al. Results of isolated regional perfusion in the treatment of malignant soft tissue tumors of the extremities. Cancer. 1987;60:1703-1707. 100. Eggermont AM, Schraffordt Koops H, Klausner JM, et al. Isolated limb perfusion with tumor necrosis factor and melphalan for limb salvage in 186 patients with locally advanced soft tissue extremity sarcomas. The cumulative multicenter European experience. Ann Surg. 1996;224:756-764; discussion 764-765. 101. Fraker D, Alexander HR, Ross M. A phase II trial of isolated perfusion with high dose tumor necrosis factor and melphalan for unresectable extremity sarcomas. Soc Surg Oncol Proc. Abstract 53, 1999. 102. Mullinax JE, Kroon HM, Thompson JF, et al. Isolated limb infusion as a limb salvage strategy for locally advanced extremity sarcoma. J Am Coll Surg. 2017;224(4):635-642. 103. Lienard D, Ewalenko P, Delmotte JJ, et al. High-dose recombinant tumor necrosis factor alpha in combination with interferon gamma and melphalan in isolation perfusion of the limbs for melanoma and sarcoma. J Clin Oncol. 1992;10: 52-60. 104. Grunhagen DJ, de Wilt JH, Graveland WJ, et al. Outcome and prognostic factor analysis of 217 consecutive isolated limb perfusions with tumor necrosis factor-alpha and melphalan for limb-threatening soft tissue sarcoma. Cancer. 2006;106: 1776-1784.Brunicardi_Ch36_p1567-p1598.indd 159201/03/19 6:38 PM 1593SOFT TISSUE SARCOMASCHAPTER 36 105. Yang JC, Chang AE, Baker AR, et al. Randomized pro-spective study of the benefit of adjuvant radiation therapy in the treatment of soft tissue sarcomas of the extremity. J Clin Oncol. 1998;16(1):197-203. 106. Pisters PW, Harrison LB, Leung DH, et al. Long-term results of a prospective randomized trial of adjuvant brachytherapy in soft tissue sarcoma. J Clin Oncol. 1996;14:859-868. 107. Suit HD, Spiro I. Role of radiation in the management of adult patients with sarcoma of soft tissue. Semin Surg Oncol. 1994;10:347-356. 108. Barkley HT Jr, Martin RG, Romsdahl MM, et al. Treatment of soft tissue sarcomas by preoperative irradiation and conservative surgical resection. Int J Radiat Oncol Biol Phys. 1988;14:693-699. 109. Wilson AN, Davis A, Bell RS, et al. Local control of soft tissue sarcoma of the extremity: the experience of a multidisciplinary sarcoma group with definitive surgery and radiotherapy. Eur J Cancer. 1994;30A:746-751. 110. Pisters PW, Harrison LB, Woodruff JM, et al. A prospective randomized trial of adjuvant brachytherapy in the management of low-grade soft tissue sarcomas of the extremity and superficial trunk. J Clin Oncol. 1994;12:1150-1155. 111. Geer RJ, Woodruff J, Casper ES, et al. Management of small soft-tissue sarcoma of the extremity in adults. Arch Surg. 1992;127:1285-1289. 112. Karakousis CP, Emrich LJ, Rao U, et al. Limb salvage in soft tissue sarcomas with selective combination of modalities. Eur J Surg Oncol. 1991;17:71-80. 113. Nielsen OS, Cummings B, O’Sullivan B, et al. Preoperative and postoperative irradiation of soft tissue sarcomas: effect of radiation field size. Int J Radiat Oncol Biol Phys. 1991;21:1595-1599. 114. Tseng JF, Ballo MT, Langstein HN, et al. The effect of preoperative radiotherapy and reconstructive surgery on wound complications after resection of extremity soft-tissue sarcomas. Ann Surg Oncol. 2006;13:1209-1215. 115. O’Sullivan B, Davis AM, Turcotte R, et al. Preoperative versus postoperative radiotherapy in soft-tissue sarcoma of the limbs: a randomised trial. Lancet. 2002;359(9325):2235-2241. 116. Davis AM, O’Sullivan B, Turcotte R, et al. Late radiation morbidity following randomization to preoperative versus postoperative radiotherapy in extremity soft tissue sarcoma. Radiother Oncol. 2005;75:48-53. 117. Janjan NA, Yasko AW, Reece GP, et al. Comparison of charges related to radiotherapy for soft-tissue sarcomas treated by preoperative external-beam irradiation versus interstitial implantation. Ann Surg Oncol. 1994;1:415-422. 118. Naghavi AO, Gonzalez RJ, Scott JG, et al. Staged reconstruction brachytherapy has lower overall cost in recurrent soft-tissue sarcoma. J Contemp Brachytherapy. 2017;9(1):20-29. 119. Naghavi AO, Gonzalez RJ, Scott JG, et al. Implications of staged reconstruction and adjuvant brachytherapy in the treatment of recurrent soft tissue sarcoma. Brachytherapy. 2016;15(4):495-503. 120. Griffin AM, Euler CI, Sharpe MB, et al. Radiation planning comparison for superficial tissue avoidance in radiotherapy for soft tissue sarcoma of the lower extremity. Int J Radiat Oncol Biol Phys. 2007;67:847-856. 121. Hong L, Alektiar KM, Hunt M, et al. Intensity-modulated radiotherapy for soft tissue sarcoma of the thigh. Int J Radiat Oncol Biol Phys. 2004;59:752-759. 122. Alektiar KM, Brennan MF, Singer S. Influence of site on the therapeutic ratio of adjuvant radiotherapy in soft-tissue sarcoma of the extremity. Int J Radiat Oncol Biol Phys. 2005;63:202-208. 123. Cannon CP, Ballo MT, Zagars GK, et al. Complications of combined modality treatment of primary lower extremity soft-tissue sarcomas. Cancer. 2006;107:2455-2461. 124. Stinson SF, DeLaney TF, Greenberg J, et al. Acute and long-term effects on limb function of combined modality limb sparing therapy for extremity soft tissue sarcoma. Int J Radiat Oncol Biol Phys. 1991;21:1493-1499. 125. Kepka L, DeLaney TF, Suit HD, Goldberg SI. Results of radia-tion therapy for unresected soft-tissue sarcomas. Int J Radiat Oncol Biol Phys. 2005;63(3):852-859. 126. Ferrari A, Gronchi A, Casanova M, et al. Synovial sarcoma: a retrospective analysis of 271 patients of all ages treated at a single institution. Cancer. 2004;101:627-634. 127. O’Bryan RM, Baker LH, Gottlieb JE, et al. Dose response evaluation of adriamycin in human neoplasia. Cancer. 1977;39:1940-1948. 128. Patel SR, Vadhan-Raj S, Papadopolous N, et al. High-dose ifosfamide in bone and soft tissue sarcomas: results of phase II and pilot studies—dose-response and schedule dependence. J Clin Oncol. 1997;15:2378-2384. 129. Movva S, Verschraegen C. Systemic management strategies for metastatic soft tissue sarcoma. Drugs. 2011;71:2115-2129. 130. Patel SR, Gandhi V, Jenkins J, et al. Phase II clinical investi-gation of gemcitabine in advanced soft tissue sarcomas and window evaluation of dose rate on gemcitabine triphosphate accumulation. J Clin Oncol. 2001;19:3483-3489. 131. Hensley ML, Maki R, Venkatraman E, et al. Gemcitabine and docetaxel in patients with unresectable leiomyosarcoma: results of a phase II trial. J Clin Oncol. 2002;20:2824-2831. 132. Dileo P, Morgan JA, Zahrieh D, et al. Gemcitabine and vinorelbine combination chemotherapy for patients with advanced soft tissue sarcomas: results of a phase II trial. Cancer. 2007;109:1863-1869. 133. Fata F, O’Reilly E, Ilson D, et al. Paclitaxel in the treatment of patients with angiosarcoma of the scalp or face. Cancer. 1999;86:2034-2037. 134. Skubitz KM, Haddad PA. Paclitaxel and pegylated-liposo-mal doxorubicin are both active in angiosarcoma. Cancer. 2005;104:361-366. 135. Chawla SP, Papai Z, Mukhametshina G, Sankhala K, et al. first-line aldoxorubicin vs doxorubicin in metastatic or locally advanced unresectable soft-tissue sarcoma: a phase 2b ran-domized clinical trial. JAMA Oncol. 2015;1(9):1272-1280. 136. Demetri GD, van Oosterom AT, Garrett CR, et al. Efficacy and safety of sunitinib in patients with advanced gastrointestinal stromal tumour after failure of imatinib: a randomised controlled trial. Lancet. 2006;368:1329-1338. 137. Jung S, Kasper B. Palifosfamide, a bifunctional alkylator for the treatment of sarcomas. Invest Drugs J. 2010;13(1):38-48. 138. Ryan CW, Merimsky O, Agulnik M, Blay JY, et al. PICASSO III: a phase III, placebo-controlled study of doxorubicin with or without palifosfamide in patients with metastatic soft tissue sarcoma. J Clin Oncol. 2016;34(32):3898-3905. 139. Agulnik M, Okuno S, Von Mehren M, et al. An open-label multicenter phase II study of bevacizumab for the treatment of angiosarcoma. J Clin Oncol. 2009;27:10522. 140. Sleijfer S, Ray-Coquard I, Papai Z, et al. Pazopanib, a multikinase angiogenesis inhibitor, in patients with relapsed or refractory advanced soft tissue sarcoma: a phase II study from the European Organisation for Research and Treatment of Cancer-Soft Tissue and Bone Sarcoma Group (EORTC study 62043). J Clin Oncol. 2009;27:3126-3132. 141. Ganjoo KN. New developments in targeted therapy for soft tissue sarcoma. Curr Oncol Rep. 2010;12:261-265. 142. Tap WD, Jones RL, Van Tine BA, et al. Olaratumab and doxorubicin versus doxorubicin alone for treatment of soft-tissue sarcoma: an open-label phase 1b and randomised phase 2 trial. Lancet. 2016;388(10043):488-497. 143. Adjuvant chemotherapy for localised resectable soft-tissue sarcoma of adults: meta-analysis of individual data. Sarcoma Meta-Analysis Collaboration. Lancet. 1997;350(9092):1647-1654.Brunicardi_Ch36_p1567-p1598.indd 159301/03/19 6:38 PM 1594SPECIFIC CONSIDERATIONSPART II 144. Frustaci S, Gherlinzoni F, De Paoli A, et al. Adjuvant chemotherapy for adult soft tissue sarcomas of the extremities and girdles: results of the Italian randomized cooperative trial. J Clin Oncol. 2001;19:1238-1247. 145. Frustaci S, De Paoli A, Bidoli E, et al. Ifosfamide in the adjuvant therapy of soft tissue sarcomas. Oncology. 2003; 65(suppl 2):80-84. 146. Cormier JN, Huang X, Xing Y, et al. Cohort analysis of patients with localized, high-risk, extremity soft tissue sarcoma treated at two cancer centers: chemotherapy-associated outcomes. J Clin Oncol. 2004;22:4567-4574. 147. Grobmyer SR, Maki RG, Demetri GD, et al. Neo-adjuvant chemotherapy for primary high-grade extremity soft tissue sarcoma. Ann Oncol. 2004;15:1667-1672. 148. Woll P, Van Glabbeke M, Hohenberger P, et al. Adjuvant chemotherapy (CT) with doxorubicin and ifosfamide in resected soft tissue sarcoma (STS): interim analysis of a randomised phase III trial. J Clin Oncol. 2007;25:10008. 149. O’Connor J, Chacón M, Petracci F, et al. Adjuvant chemother-apy in soft tissue sarcoma (STS): a meta-analysis of published data. ASCO Meeting Abstracts, 2008, Abstract 10526. 150. Pervaiz N, Colterjohn N, Farrokhyar F, et al. A systematic meta-analysis of randomized controlled trials of adjuvant chemotherapy for localized resectable soft-tissue sarcoma. Cancer. 2008;113:573-581. 151. Eilber FC, Tap WD, Nelson SD, et al. Advances in chemo-therapy for patients with extremity soft tissue sarcoma. Orthop Clin North Am. 2006;37:15-22. 152. Gronchi A, Frustaci S, Mercuri M, et al. Short, full-dose adju-vant chemotherapy in high-risk adult soft tissue sarcomas: a randomized clinical trial from the Italian Sarcoma Group and the Spanish Sarcoma Group. J Clin Oncol. 2012;30:850-856. 153. Stacchiotti S, Collini P, Messina A, et al. High-grade soft-tissue sarcomas: tumor response assessment—pilot study to assess the correlation between radiologic and pathologic response by using RECIST and Choi Criteria. Radiology. 2009;251:447-456. 154. Stacchiotti S, Verderio P, Messina A, et al. Tumor response assessment by modified Choi criteria in localized high-risk soft tissue sarcoma treated with chemotherapy. Cancer. 2012;118:5857. 155. Eilber FC, Rosen G, Eckardt J, et al. Treatment-induced patho-logic necrosis: a predictor of local recurrence and survival in patients receiving neoadjuvant therapy for high-grade extremity soft tissue sarcomas. J Clin Oncol. 2001;19:3203-3209. 156. Eilber FC, Brennan MF, Riedel E, et al. Prognostic factors for survival in patients with locally recurrent extremity soft tissue sarcomas. Ann Surg Oncol. 2005;12:228-236. 157. Singer S, Antman K, Corson JM, et al. Long-term salvage-ability for patients with locally recurrent soft-tissue sarcomas. Arch Surg. 1992;127:548-553; discussion 553-554. 158. van Geel AN, Pastorino U, Jauch KW, et al. Surgical treatment of lung metastases: the European Organization for Research and Treatment of Cancer-Soft Tissue and Bone Sarcoma Group study of 255 patients. Cancer. 1996;77:675-682. 159. Porter GA, Cantor SB, Walsh GL, et al. Cost-effectiveness of pulmonary resection and systemic chemotherapy in the management of metastatic soft tissue sarcoma: a combined analysis from the University of Texas M. D. Anderson and Memorial Sloan-Kettering Cancer Centers. J Thorac Cardiovasc Surg. 2004;127:1366-1372. 160. Dossett LA, Toloza EM, Fontaine J, et al. Outcomes and clinical predictors of improved survival in a patients undergoing pulmonary metastasectomy for sarcoma. J Surg Oncol. 2015;112(1):103-106. 161. Whooley BP, Mooney MM, Gibbs JF, et al. Effective follow-up strategies in soft tissue sarcoma. Semin Surg Oncol. 1999;17:83-87. 162. Midis GP, Pollock RE, Chen NP, et al. Locally recurrent soft tissue sarcoma of the extremities. Surgery. 1998;123:666-671. 163. Karakousis CP, Proimakis C, Rao U, et al. Local recurrence and survival in soft-tissue sarcomas. Ann Surg Oncol. 1996; 3:255-260. 164. Nori D, Schupak K, Shiu MH, et al. Role of brachytherapy in recurrent extremity sarcoma in patients treated with prior surgery and irradiation. Int J Radiat Oncol Biol Phys. 1991;20:1229-1233. 165. Suri RM, Deschamps C, Cassivi SD, et al. Pulmonary resection for metastatic malignant fibrous histiocytoma: an analysis of prognostic factors. Ann Thorac Surg. 2005;80:1847-1852. 166. Van Glabbeke M, van Oosterom AT, Oosterhuis JW, et al. Prognostic factors for the outcome of chemotherapy in advanced soft tissue sarcoma: an analysis of 2,185 patients treated with anthracycline-containing first-line regimens—a European Organization for Research and Treatment of Cancer Soft Tissue and Bone Sarcoma Group Study. J Clin Oncol. 1999;17:150-157. 167. Zacherl M, Bernhardt GA, Zacherl J, et al. Surgery for liver metastases originating from sarcoma-case series. Langenbecks Arch Surg. 2011;396:1083-1091. 168. Jones RL, McCall J, Adam A, et al. Radiofrequency ablation is a feasible therapeutic option in the multi modality management of sarcoma. Eur J Surg Oncol. 2010;36:477-482. 169. Maluccio MA, Covey AM, Schubert J, et al. Treatment of metastatic sarcoma to the liver with bland embolization. Cancer. 2006;107:1617-1623. 170. Kepka L, Suit HD, Goldberg SI, et al. Results of radiation ther-apy performed after unplanned surgery (without re-excision) for soft tissue sarcomas. J Surg Oncol. 2005;92:39-45. 171. Spillane AJ, Fisher C, Thomas JM. Myxoid liposarcoma—the frequency and the natural history of nonpulmonary soft tissue metastases. Ann Surg Oncol. 1999;6:389-394. 172. Estourgie SH, Nielsen GP, Ott MJ. Metastatic patterns of extremity myxoid liposarcoma and their outcome. J Surg Oncol. 2002;80:89-93. 173. Lewis JJ, Leung D, Woodruff JM, et al. Retroperitoneal soft-tissue sarcoma: analysis of 500 patients treated and followed at a single institution. Ann Surg. 1998;228:355-365. 174. Bonvalot S, Raut CP, Pollock RE, et al. Technical consid-erations in surgery for retroperitoneal sarcomas: position paper from E-Surge, a Master Class in Sarcoma Surgery, and EORTC–STBSG. Ann Surg Oncol. 2012;19(9):2981-2991. 175. Bonvalot S, Miceli R, Berselli M, et al. Aggressive surgery in retroperitoneal soft tissue sarcoma carried out at high-volume centers is safe and is associated with improved local control. Ann Surg Oncol. 2010;17:1507-1514. 176. Yeh JJ, Singer S, Brennan MF, et al. Effectiveness of palliative procedures for intra-abdominal sarcomas. Ann Surg Oncol. 2005;12:1084-1089. 177. Windham TC, Pisters PW. Retroperitoneal sarcomas. Cancer Control. 2005;12:36-43. 178. Tierney JF, Mosseri V, Stewart LA, et al. Adjuvant chemo-therapy for soft-tissue sarcoma: review and meta-analysis of the published results of randomised clinical trials. Br J Cancer. 1995;72:469-475. 179. Glenn J, Sindelar WF, Kinsella T, et al. Results of multimodality therapy of resectable soft-tissue sarcomas of the retroperito-neum. Surgery. 1985;97:316-325. 180. Singer S, Corson JM, Demetri GD, et al. Prognostic factors predictive of survival for truncal and retroperitoneal soft-tissue sarcoma. Ann Surg. 1995;221:185-195. 181. Pawlik TM, Ahuja N, Herman JM. The role of radiation in retroperitoneal sarcomas: a surgical perspective. Curr Opin Oncol. 2007;19:359-366. 182. Pawlik TM, Pisters PW, Mikula L, et al. Long-term results of two prospective trials of preoperative external beam radiotherapy for localized intermediateor high-grade retroperitoneal soft tissue sarcoma. Ann Surg Oncol. 2006;13:508-517.Brunicardi_Ch36_p1567-p1598.indd 159401/03/19 6:38 PM 1595SOFT TISSUE SARCOMASCHAPTER 36 183. Tzeng CW, Fiveash JB, Heslin MJ. Radiation therapy for retroperitoneal sarcoma. Expert Rev Anticancer Ther. 2006;6:1251-1260. 184. Ballo MT, Zagars GK, Pollock RE, et al. Retroperitoneal soft tissue sarcoma: an analysis of radiation and surgical treatment. Int J Radiat Oncol Biol Phys. 2007;67:158-163. 185. Conlon KC, Casper ES, Brennan MF. Primary gastrointestinal sarcomas: analysis of prognostic variables. Ann Surg Oncol. 1995;2:26-31. 186. Chou FF, Eng HL, Sheen-Chen SM. Smooth muscle tumors of the gastrointestinal tract: analysis of prognostic factors. Surgery. 1996;119:171-177. 187. Horowitz J, Spellman JE Jr, Driscoll DL, et al. An institutional review of sarcomas of the large and small intestine. J Am Coll Surg. 1995;180:465-471. 188. Meijer S, Peretz T, Gaynor JJ, et al. Primary colorectal sarcoma. A retrospective review and prognostic factor study of 50 consecutive patients. Arch Surg. 1990;125:1163-1168. 189. Kirova YM, Vilcoq JR, Asselain B, et al. Radiation-induced sarcomas after radiotherapy for breast carcinoma: a large-scale single-institution review. Cancer. 2005;104:856-863. 190. Chen WH, Cheng SP, Tzen CY, et al. Surgical treatment of phyllodes tumors of the breast: retrospective review of 172 cases. J Surg Oncol. 2005;91:185-194. 191. Denschlag D, Masoud I, Stanimir G, et al. Prognostic factors and outcome in women with uterine sarcoma. Eur J Surg Oncol. 2007;33:91-95. 192. Reed N, Mangioni C, Malmström H, et al. Phase III randomised study to evaluate the role of adjuvant pelvic radiotherapy in the treatment of uterine sarcomas stages I and II: a European Organisation for Research and Treatment of Cancer Gynaecological Cancer Group Study (protocol 55874). Eur J Cancer. 2008;44:808-818. 193. Leunen M, Breugelmans M, De Sutter P, et al. Low-grade endometrial stromal sarcoma treated with the aromatase inhibitor letrozole. Gynecol Oncol. 2004;95:769-771. 194. Scribner DR Jr, Walker JL. Low-grade endometrial stromal sarcoma preoperative treatment with Depo-Lupron and Megace. Gynecol Oncol. 1998;71:458-460. 195. Grimer R, Judson I, Peake D, et al. Guidelines for the manage-ment of soft tissue sarcomas. Sarcoma. 2010;2010:506182. 196. Kindblom LG, Remotti HE, Aldenborg F, et al. Gastrointesti-nal pacemaker cell tumor (GIPACT): gastrointestinal stromal tumors show phenotypic characteristics of the interstitial cells of Cajal. Am J Pathol. 1998;152:1259-1269. 197. Hirota S, Isozaki K, Moriyama Y, et al. Gain-of-function mutations of c-kit in human gastrointestinal stromal tumors. Science. 1998;279:577-580. 198. Nilsson B, Bumming P, Meis-Kindblom JM, et al. Gastro-intestinal stromal tumors: the incidence, prevalence, clinical course, and prognostication in the preimatinib mesylate era—a population-based study in western Sweden. Cancer. 2005;103:821-829. 199. Rubio J, Marcos-Gragera R, Ortiz MR, et al. Population-based incidence and survival of gastrointestinal stromal tumours (GIST) in Girona, Spain. Eur J Cancer. 2007;43:144-148. 198. Tran T, Davila JA, El-Serag HB. The epidemiology of malig-nant gastrointestinal stromal tumors: an analysis of 1,458 cases from 1992 to 2000. Am J Gastroenterol. 2005;100:162-168. 200. Heinrich MC, Corless CL, Demetri GD, et al. Kinase muta-tions and imatinib response in patients with metastatic gastro-intestinal stromal tumor. J Clin Oncol. 2003;21:4342-4349. 201. Debiec-Rychter M, Dumez H, Judson I, et al. Use of c-KIT/PDGFRAmutational analysis to predict the clinical response to imatinib in patients with advanced gastrointestinal stro-mal tumours entered on phase I and II studies of the EORTC Soft Tissue and Bone Sarcoma Group. Eur J Cancer. 2004;40:689-695. 202. Heinrich MC, Owzar K, Corless CL, et al. Correlation of kinase genotype and clinical outcome in the North American Intergroup phase III trial of imatinib mesylate for treatment of advanced gastrointestinal stromal tumor: CALGB 150105 Study by Cancer and Leukemia Group B and Southwest Oncology Group. J Clin Oncol. 2008;26: 5360-5367. 203. Miettinen M, Lasota J. Gastrointestinal stromal tumors: review on morphology, molecular pathology, prognosis, and differen-tial diagnosis. Arch Pathol Lab Med. 2006;130:1466-1478. 204. Miettinen M, Lasota J. Gastrointestinal stromal tumors: pathology and prognosis at different sites. Semin Diagn Pathol. 2006;2:70-83. 205. Choi H, Charnsangavej C, Faria SC, et al. Correlation of computed tomography and positron emission tomography in patients with metastatic gastrointestinal stromal tumor treated at a single institution with imatinib mesylate: proposal of new computed tomography response criteria. J Clin Oncol. 2007;25:1753-1759. 206. Ng EH, Pollock RE, Munsell MF, et al. Prognostic factors influencing survival in gastrointestinal leiomyosarcomas. Implications for surgical management and staging. Ann Surg. 1992;215:68-77. 207. Fletcher CD, Berman JJ, Corless C, et al. Diagnosis of gastro-intestinal stromal tumors: a consensus approach. Hum Pathol. 2002;33:459-465. 208. van Oosterom AT, Judson I, Verweij J, et al. Safety and effi-cacy of imatinib (STI571) in metastatic gastrointestinal stromal tumours: a phase I study. Lancet. 2001;358:1421-1423. 209. Blanke CD, von Mehren M, Joensuu H, et al. Evaluation of the safety and efficacy of an oral molecularly targeted therapy, ST1571, in patients with unresectable metastatic gastrointestinal stromal tumors (GISTs) expressing C-KIT (CD117). Proc Am Soc Clin Oncol. 2001;20:1. 210. von Mehren M, Blanke C, Joensuu H, et al. High incidence of durable responses induced by imatinib mesylate (Gleevec) in patients with unresectable and metastatic gastrointestinal stromal tumors. Proc Am Soc Clin Oncol. 2002; 21:1608. 211. Demetri G, Rankin C, Fletcher C, et al. Phase III doserandomized study of imatinib mesylate (Gleevec, ST1571) for GIST; intergroup S0033 early results. Proc Am Soc Clin Oncol. 2002;21:1651. 212. Verweij J, Casali PG, Zalcberg J, et al. Progression-free survival in gastrointestinal stromal tumours with high-dose imatinib: randomised trial. Lancet. 2004;364:1127-1134. 213. Blanke CD, Rankin C, Demetri GD, et al. Phase III randomized, intergroup trial assessing imatinib mesylate at two dose levels in patients with unresectable or metastatic gastrointestinal stromal tumors expressing the kit receptor tyrosine kinase: S0033. J Clin Oncol. 2008;26:626-632. 214. Zalcberg JR, Verweij J, Casali PG, et al. Outcome of patients with advanced gastro-intestinal stromal tumours crossing over to a daily imatinib dose of 800 mg after progression on 400 mg. Eur J Cancer. 2005;41:1751-1757. 215. Blay JY, Le Cesne A, Ray-Coquard I, et al. Prospective multicentric randomized phase III study of imatinib in patients with advanced gastrointestinal stromal tumors comparing interruption versus continuation of treatment beyond 1 year: the French Sarcoma Group. J Clin Oncol. 2007;25: 1107-1113. 216. Benjamin RS, Debiec-Rychter M, Le Cesne A, et al. Gastrointestinal stromal tumors II: medical oncology and tumor response assessment. Semin Oncol. 2009;4:302-311. 217. Maleddu A, Pantaleo MA, Nannini M, et al. Mechanisms of secondary resistance to tyrosine kinase inhibitors in gastrointestinal stromal tumours (review). Oncol Rep. 2009;21:1359-1366.Brunicardi_Ch36_p1567-p1598.indd 159501/03/19 6:38 PM 1596SPECIFIC CONSIDERATIONSPART II 218. Chu D, Lacouture ME, Weiner E, et al. Risk of hand-foot skin reaction with the multitargeted kinase inhibitor sunitinib in patients with renal cell and non–renal cell carcinoma: a meta-analysis. Clin Genitourin Cancer. 2009;7:11-19. 219. Zhu X, Stergiopoulos K, Wu S. Risk of hypertension and renal dysfunction with an angiogenesis inhibitor sunitinib: systematic review and meta-analysis. Acta Oncol. 2009;48:9-17. 220. Chu TF, Rupnick MA, Kerkela R, et al. Cardiotoxicity asso-ciated with the tyrosine kinase inhibitor sunitinib. Lancet. 2007;370(9604):2011-2009. 221. George S, Wang Q, Heinrich MC, et al. Efficacy and safety of regorafenib in patients with metastatic and/or unresectable GI stromal tumor after failure of imatinib and sunitinib: a multicenter phase II trial. J Clin Oncol. 2012;30(19):2401-2407. 222. Demetri GD, Reichardt P, Kang YK, et al. Efficacy and safety of regorafenib for advanced gastrointestinal stromal tumours after failure of imatinib and sunitinib (GRID): an international, multicentre, randomised, placebo-controlled, phase 3 trial. Lancet. 2013;381(9863):295-302. 223. Boyar MS, Taub RN. New strategies for treating GIST when imatinib fails. Cancer Invest. 2007;25:328-335. 224. Cassier PA, Dufresne A, Fayette J, et al. Emerging drugs for the treatment of soft tissue sarcomas. Expert Opin Emerg Drugs. 2007;12:139-153. 225. Andtbacka RH, Ng CS, Scaife CL, et al. Surgical resection of gastrointestinal stromal tumors after treatment with imatinib. Ann Surg Oncol. 2007;14:14-24. 226. Desai J, Shankar S, Heinrich MC, et al. Clonal evolution of resistance to imatinib in patients with metastatic gastrointesti-nal stromal tumors. Clin Cancer Res. 2007;13:5398-5405. 227. DeMatteo RP, Maki RG, Singer S, et al. Results of tyrosine kinase inhibitor therapy followed by surgical resection for metastatic gastrointestinal stromal tumor. Ann Surg. 2007;245:347-352. 228. Raut CP, Posner M, Desai J, et al. Surgical management of advanced gastrointestinal stromal tumors after treatment with targeted systemic therapy using kinase inhibitors. J Clin Oncol. 2006;24:2325-2331. 229. Gronchi A, Fiore M, Miselli F, et al. Surgery of residual disease following molecular-targeted therapy with imatinib mesylate in advanced/metastatic GIST. Ann Surg. 2007;245:341-346. 230. DeMatteo RP, Ballman KV, Antonescu CR, et al. Placebocontrolled randomized trial of adjuvant imatinib mesylate following the resection of localized, primary gastrointestinal stromal tumor (GIST). Lancet. 2009;373(9669):1097-1104. 231. Joensuu H, Eriksson M, Sundby Hall K, et al. One vs three years of adjuvant imatinib for operable gastrointestinal stromal tumor: a randomized trial. JAMA. 2012;307(12):1265-1272. 232. The ESMO/European Sarcoma Network Working Group. Gastrointestinal stromal tumors: ESMO clinical recommen-dations for diagnosis, treatment and follow-up. Ann Oncol. 2012;23:49-55. 233. Gold JS, Gönen M, Gutiérrez A, et al. Development and validation of a prognostic nomogram for recurrence-free sur-vival after complete surgical resection of localised primary gastrointestinal stromal tumour: a retrospective analysis. Lancet Oncol. 2009;10:1045-1052. 232. Joensuu H, Vehtari A, Riihimäki J, et al. Risk of recur-rence of gastrointestinal stromal tumour after surgery: an analysis of pooled population-based cohorts. Lancet Oncol. 2012;13(3):265-274. 234. Demetri GD, Antonia S, Benjamin RS, et al. Soft tissue sarcoma. J Natl Compr Canc Netw. 2010;8:630-674. 235. van der Zwan SM, DeMatteo RP. Gastrointestinal stromal tumor: 5 years later. Cancer. 2005;104:1781-1788. 236. Eisenberg BL, Harris J, Blanke CD, et al. Phase II trial of neoadjuvant/adjuvant imatinib mesylate (IM) for advanced primary and metastatic/recurrent operable gastrointestinal stromal tumor (GIST): early results of RTOG 0132/ACRIN 6665. J Surg Oncol. 2008;99:42-47. 237. McAuliffe JC, Hunt KK, Lazar AJF, et al. A randomized, phase II study of preoperative plus postoperative imatinib in GIST: evidence of rapid radiographic response and tem-poral induction of tumor cell apoptosis. Ann Surg Oncol. 2009;16:910-919. 238. Fiore M, Palassini E, Fumagalli E, et al. Preoperative ima-tinib mesylate for unresectable or locally advanced primary gastrointestinal stromal tumors (GIST). Eur J Surg Oncol. 2009;35:739-745. 239. Emile J, Brahimi S, Coindre J, et al. Frequencies of KIT and PDGFRA mutations in the MolecGIST prospective population-based study differ from those of advanced GISTs. Med Oncol. 2012;29:1765-1772. 240. Gronchi A, Casali P, Mariani L, et al. Quality of surgery and outcome in extra-abdominal aggressive fibromatosis: a series of patients surgically treated at a single institution. J Clin Oncol. 2003;21:1390-1397. 241. Lev D, Kotilingam D, Wei C, et al. Optimizing treatment of desmoid tumors. J Clin Oncol. 2007;25:1785-1791. 242. Salas S, Dufresne A, Bui B, et al. Prognostic factors influencing progression-free survival determined from a series of sporadic desmoid tumors: a wait-and-see policy according to tumor presentation. J Clin Oncol. 2011;29: 3553-3558. 243. Bonvalot S, Eldweny H, Haddad V, et al. Extra-abdominal primary fibromatosis: aggressive management could be avoided in a subgroup of patients. Eur J Surg Oncol. 2008;34: 462-468. 244. Fiore M, Rimareix F, Mariani L, et al. Desmoid-type fibromatosis: a front-line conservative approach to select patients for surgical treatment. Ann Surg Oncol. 2009;16: 2587-2593. 245. Constantinidou A, Scurr M, Jones R, et al. Treatment of aggressive fibromatosis with pegylated liposomal doxorubi-cin: The Royal Marsden Hospital experience. J Clin Oncol. (Meeting Abstracts), Abstract 10519, 2009. 246. Gounder MM, Lefkowitz RA, Keohan ML, et al. Activity of sorafenib against desmoid tumor/deep fibromatosis. Clin Cancer Res. 2011;17:4082-4090. 247. Dufresne A, Penel N, Salas S, et al. Updated outcome with long term follow-up of imatinib for the treatment of progres-sive or recurrent aggressive fibromatosis (desmoid tumor): a FNCLCC/French Sarcoma Group phase II trial. Age. 2009;40:59. 248. Chugh R, Wathen JK, Patel SR, et al. Efficacy of imatinib in aggressive fibromatosis: results of a phase II multicenter Sarcoma Alliance for Research through Collaboration (SARC) trial. Clin Cancer Res. 2010;16:4884-4891. 249. Penel N, Le Cesne A, Bui B, et al. Imatinib for progressive and recurrent aggressive fibromatosis (desmoid tumors): an FNCLCC/French Sarcoma Group phase II trial with a long-term follow-up. Ann Oncol. 2011;22:452-457. 250. Criscione VD, Weinstock MA. Descriptive epidemiology of dermatofibrosarcoma protuberans in the United States, 1973 to 2002. J Am Acad Dermatol. 2007;56:968-973. 251. Fiore M, Miceli R, Mussi C, et al. Dermatofibrosarcoma protuberans treated at a single institution: a surgical disease with a high cure rate. J Clin Oncol. 2005;23:7669-7675. 252. McArthur GA. Molecular targeting of dermatofibrosarcoma protuberans: a new approach to a surgical disease. J Natl Compr Canc Netw. 2007;5:557-562.Brunicardi_Ch36_p1567-p1598.indd 159601/03/19 6:38 PM 1597SOFT TISSUE SARCOMASCHAPTER 36 253. Grovas A, Fremgen A, Rauck A, et al. The National Cancer Data Base report on patterns of childhood cancers in the United States. Cancer. 1997;80:2321-2332. 254. Meyer WH, Spunt SL. Soft tissue sarcomas of childhood. Cancer Treat Rev. 2004;30:269-280. 255. Barr FG, Chatten J, D’Cruz CM, et al. Molecular assays for chromosomal translocations in the diagnosis of pediatric soft tissue sarcomas. JAMA. 1995;273:553-557. 256. Xia SJ, Pressey JG, Barr FG. Molecular pathogenesis of rhabdomyosarcoma. Cancer Biol Ther. 2002;1:97-104. 257. Scrable H, Witte D, Shimada H, et al. Molecular differential pathology of rhabdomyosarcoma. Genes Chromosomes Cancer. 1989;1:23-35. 258. Flamant F, Rodary C, Rey A, et al. Treatment of non-metastatic rhabdomyosarcomas in childhood and adolescence. Results of the second study of the International Society of Paediatric Oncology: MMT84. Eur J Cancer. 1998;34:1050-1062. 259. Crist WM, Anderson JR, Meza JL, et al. Intergroup rhabdomyosarcoma study-IV: results for patients with nonmetastatic disease. J Clin Oncol. 2001;19:3091-3102. 260. Crist WM, Garnsey L, Beltangady MS, et al. Prognosis in children with rhabdomyosarcoma: a report of the intergroup rhabdomyosarcoma studies I and II. Intergroup Rhabdomyo-sarcoma Committee. J Clin Oncol. 1990;8:443-452. 261. Loeb DM, Thornton K, Shokek O. Pediatric soft tissue sarcomas. Surg Clin North Am. 2008;88:615-627, vii.Brunicardi_Ch36_p1567-p1598.indd 159701/03/19 6:38 PM
Brunicardi_Ch36_p1567-p1598.indd 159801/03/19 6:38 PMThis page intentionally left blankInguinal HerniasChandan Das, Tahir Jamil, Stephen Stanek, Ziya Baghmanli, James R. Macho, Joseph Sferra, and F. Charles Brunicardi 37chapterINTRODUCTIONInguinal herniorrhaphy is one of the most commonly performed operations in the United States.1 Based on estimates made by the National Center for Health Statistics, in 2010 nearly 515,000 inguinal hernia operations were performed in hospitals, and an additional 450,000 were performed in ambulatory surgery centers.1Approximately 75% of abdominal wall hernias occur in the groin. Of inguinal hernia repairs, 90% are performed in men, and 10% are performed in women. This is thought to be because the lifetime risk of inguinal hernia is 27% in men and 3% in women.2 The incidence of inguinal hernia in men has a bimodal distribution, with peaks before the first year of age and after age 40. Abramson demonstrated the age-dependence of inguinal hernias in 1978. Those age 25 to 34 years had a life-time prevalence rate of 15%, whereas those age 75 years and over had a rate of 47% (Table 37-1).3 Approximately 70% of femoral hernia repairs are performed in women; however, the most common subtype of groin hernia in men and women is still the indirect inguinal hernia. Inguinal hernias are five times more common than femoral hernias.4Globally, the inguinal hernia repair has become one of the most important procedures in improving quality of life and preventing disability. In one study, an international coopera-tive organization performed over 1033 hernia repairs on 926 patients, and their impact was measured in disability adjusted life years (DALYs). They were able to avoid 5014 DALYs or 5.41 DALYs per patient.5HistorySurgical repair of hernias has been documented as far back as in ancient Egyptian and Greek civilizations.4 In the past, early management of inguinal hernias often involved a conservative approach with operative management reserved only for compli-cations. Surgery often involved routine excision of the testicle, and wounds were closed with cauterization or allowed to close by secondary intention. These procedures were 1performed without aseptic technique, and infection and recur-rence rates were high.From the late 1700s to the early 1800s, physicians including Hesselbach, Cooper, Camper, Scarpa, Richter, and Gimbernat identified vital components of the inguinal region from cadaveric dissection. This improved understanding of the anatomy and pathophysiology of inguinal hernias. These findings, coupled with the development of aseptic technique, led surgeons such as Marcy, Kocher, and Lucas-Championnière to perform sac dissection, high ligation, and closure of the internal ring. This led to improved outcomes, but recurrence rates remained unacceptably high.At around this time, Bassini (1844–1924) pioneered a new method that transformed inguinal hernia repair into a success-ful venture with minimal morbidity. The success of the Bassini repair over its predecessors ushered in an era of tissue-based repairs. The Bassini repair was then modified into the McVay and Shouldice repairs. All three of these techniques, as well as modern variations such as the Desarda operation, are currently practiced.6The next major advancement in inguinal hernia repair was in the 1980s. At this time, Lichtenstein applied a piece of mesh to the floor of the inguinal canal, allowing for a truly tension-free repair. This technique demonstrated superior outcomes compared to previous tissue-based repairs. There were several other advantages of this process. In addition to being truly tension-free, the mesh could restore the strength of the transversalis fascia, and importantly, the technique had a very short learning curve. The superior outcomes have been widely reproduced regardless of hernia size and type, and they were achievable among both expert and nonexpert hernia surgeons.7With the advent of minimally invasive surgery, inguinal hernia repair underwent its most recent transformation. Laparo-scopic inguinal hernia repair offers an alternative approach, minimizes postoperative pain,8 and improves recovery. Since the initial description by Ger, the laparoscopic method has become more sophisticated. Refinements in approach and technique have Introduction1599History / 1599Anatomy / 1600Pathophysiology / 1604Diagnosis1606History / 1606Physical Examination / 1607Imaging / 1607Treatment1608Prophylactic Antibiotics / 1609Open Approach / 1609Laparoscopic Approach / 1613Robot-Assisted Inguinal Hernia Repair / 1616Prosthesis Considerations / 1616Complications1618Hernia Recurrence / 1618Pain / 1619Cord and Testes Injury / 1620Laparoscopic Complications / 1620Hematomas and Seromas / 1621Outcomes1621Brunicardi_Ch37_p1599-p1624.indd 159929/01/19 2:02 PM 1600Key Points1 Conservative management of asymptomatic inguinal hernias is recommended.2 A thorough understanding of groin anatomy is essential to successful surgical treatment of inguinal hernias.3 Elective repair of inguinal hernias can be undertaken using a laparoscopic, robotic, or open approach.4 Robotic-assisted hernia surgery is quickly becoming adopted by general surgeons because of its better ergonomics and visualization.5 The use of prosthetic mesh as a reinforcement significantly improves recurrence rates, whether the repair is open or laparoscopic.6 Recurrence, pain, and quality of life are the metrics by which hernia repair outcomes are measured.7 Laparoscopic inguinal hernia repair results in less pain; how-ever, mastery of this technique has a longer learning curve.led to the development of the intraperitoneal onlay mesh,9,10 the transabdominal preperitoneal (TAPP) repair,11 and the totally extraperitoneal (TEP) repair.12 Irrespective of the approach, suc-cessful surgical treatment of inguinal hernias depends on a sound grasp of inguinal anatomy.AnatomyThe inguinal canal is an approximately 4to 6-cm long cone-shaped region situated in the anterior portion of the pelvic basin (Fig. 37-1). The canal begins on the posterior abdominal wall, where the spermatic cord passes through a hiatus in the transver-salis fascia also known as the deep (internal) inguinal ring. The canal concludes medially at the superficial (external) inguinal ring, the point at which the spermatic cord crosses a defect in the external oblique aponeurosis. The boundaries of the ingui-nal canal are the external oblique aponeurosis anteriorly, the internal oblique muscle laterally, the transversalis fascia and transversus abdominis muscle posteriorly, the internal oblique and transversus abdominis muscle superiorly, and the inguinal (Poupart’s) ligament inferiorly. The spermatic cord traverses the inguinal canal, and it contains three arteries, three veins, two nerves, the pampiniform venous plexus, and the vas deferens. It is enveloped in three layers of spermatic fascia.Additional important structures surrounding the inguinal canal include the iliopubic tract, the lacunar ligament, Cooper’s ligament, and the conjoined tendon (Fig. 37-2). The iliopubic tract is an aponeurotic band that begins at the anterior superior iliac spine and inserts into Cooper’s ligament from above. It forms on the deep inferior margin of the transversus abdominis and transversalis fascia. The shelving edge of the inguinal ligament is a structure that connects the iliopubic tract to the inguinal ligament. The iliopubic tract helps form the inferior margin of the internal inguinal ring as it courses medially, where it continues as the anteromedial border of the femoral canal. The lacunar ligament, or ligament of Gimbernat, is the triangular fanning of the inguinal ligament as it joins the pubic 2tubercle. Cooper’s (pectineal) ligament is the lateral portion of the lacunar ligament that is fused to the periosteum of the pubic tubercle. The conjoined tendon is commonly described as the fusion of the inferior fibers of the internal oblique and transversus abdominis aponeurosis at the point where they insert on the pubic tubercle.Inguinal hernias are generally classified as direct, indirect, or femoral based upon the site of herniation relative to surround-ing structures. Indirect hernias protrude lateral to the inferior epigastric vessels, through the deep inguinal ring. Direct hernias protrude medial to the inferior epigastric vessels, within Hesselbach’s triangle. The borders of the triangle are the ingui-nal ligament inferiorly, the lateral edge of rectus sheath medi-ally, and the inferior epigastric vessels superolaterally. Femoral hernias protrude through the small and inflexible femoral ring. They traverse the empty space between the femoral vein and the lymphatic channels. The borders of the femoral ring include the iliopubic tract and inguinal ligament anteriorly, Cooper’s liga-ment posteriorly, the lacunar ligament medially, and the femoral vein laterally. The Nyhus classification categorizes hernia defects by location, size, and type (Table 37-2).Laparoscopic inguinal hernia repair requires a thorough knowledge of inguinal anatomy from a posterior perspective (Fig. 37-3). Intraperitoneal points of reference are the five peritoneal folds, bladder, inferior epigastric vessels, and psoas muscle (Fig. 37-4). Two potential spaces exist within the pre-peritoneum. Between the peritoneum and the posterior lamina of the transversalis fascia is Bogros’s (preperitoneal) space. This area contains preperitoneal fat and areolar tissue. The most medial aspect of the preperitoneal space, that which lies superior to the bladder, is known as the space of Retzius. The posterior perspective also allows visualization of the myopectineal orifice of Fruchaud, a relatively weak portion of the abdominal wall that is divided by the inguinal ligament (Fig. 37-5).The vascular space is situated between the posterior and anterior laminae of the transversalis fascia, and it houses the Table 37-1Inguinal hernia prevalence by ageAGE (Y)25–3435–4445–5455–6465–7475+Current prevalence (%)121520262934Lifetime prevalence (%)151928344047Current = repaired hernias excluded; lifetime = repaired hernias included.Brunicardi_Ch37_p1599-p1624.indd 160029/01/19 2:02 PM 1601INGUINAL HERNIASCHAPTER 37Abdominal ringLateral leafPubic tubercleSpermatic cordInterrupted sutures taken to suture the medial leaf to the inguinal ligament Interrupted sutures between the upper border of the strip and conjoined muscle and internal oblique muscleInternal oblique muscle seen through the splitting incision made in the medial leafReflected medial leaf after a strip has been separatedFigure 37-2. Ligaments that contribute to the inguinal canal include the inguinal ligament, Cooper’s ligament, and the lacunar ligament. The iliopubic tract originates and inserts in a similar fashion to the inguinal ligament, but in a deeper position. m. = muscle.Abdominal ringLateral leafMedial leafPubic tubercleSpermatic cordInterrupted sutures taken to suture the medial leaf to the inguinal ligament Figure 37-1. Location and orientation of the inguinal canal within the pelvic basin. Boundaries of the canal include: transversus abdominus and transversalis fascia posterior; internal oblique muscle superior; external oblique aponeurosis anterior; inguinal ligament inferior. m. = muscle.inferior epigastric vessels. The inferior epigastric artery supplies the rectus abdominis. It is derived from the external iliac artery, and it anastomoses with the superior epigastric, a continuation of the internal thoracic artery. The epigastric veins course paral-lel to the arteries within the rectus sheath, posterior to the rectus muscles. Inspection of the internal inguinal ring will reveal the deep location of the inferior epigastric vessels.Nerves of interest in the inguinal region are the ilioin-guinal, iliohypogastric, genitofemoral, and lateral femoral cutaneous nerves (Figs. 37-6 and 37-7). The ilioinguinal and iliohypogastric nerves arise together from the first lumbar nerve (L1). The ilioinguinal nerve emerges from the lateral border of the psoas major and passes obliquely across the quadratus lumborum. At a point just medial to the anterior Brunicardi_Ch37_p1599-p1624.indd 160129/01/19 2:02 PM 1602SPECIFIC CONSIDERATIONSPART IIInferior epigastric vesselsCooper’s ligamentPubic tubercleArcuate lineUmbilicusLinea albaRectus muscleDeepinguinalringIliopubictractExternal iliacvesselsIndirecthernia siteDirecthernia siteObturatorvesselsTransversusabdominismusclearchSuperioranteriorcrusSpermatic cordSpermatic vesselsFemoral canalFigure 37-3. Anatomy of the groin region from the posterior perspective.AA UmbilicusB Median umbilical ligament (urachus)C Medial umbilical ligament (obliterated umbilical vein)D Lateral umbilical ligament (inferior epigastric vessels)E Lateral fossa (indirect hernia)F Medial fossa (direct hernia)G Supravesical fossaBEFBladderGCDFigure 37-4. Posterior view of intraperitoneal folds and associated fossa: A. Umbilicus. B. Median umbilical ligament. C. Medial umbilical ligament (obliterated umbilical vein). D. Lateral umbilical ligament (inferior epigastric vessels). E. Lateral fossa (indirect hernia). F. Medial fossa (direct hernia). G. Supravesical fossa. (Modified with permission from Rowe JS, Skandalakis JE, Gray SW: Multiple bilateral inguinal hernias, Am Surg. 1973 May;39(5):269-270.)Table 37-2Nyhus classification systemType IIndirect hernia; internal abdominal ring normal; typically in infants, children, small adultsType IIIndirect hernia; internal ring enlarged without impingement on the floor of the inguinal canal; does not extend to the scrotumType IIIADirect hernia; size is not taken into accountType IIIBIndirect hernia that has enlarged enough to encroach upon the posterior inguinal wall; indirect sliding or scrotal hernias are usually placed in this category because they are commonly associated with extension to the direct space; also includes pantaloon herniasType IIICFemoral herniaType IVRecurrent hernia; modifiers A–D are sometimes added, which correspond to indirect, direct, femoral, and mixed, respectivelysuperior iliac spine, it pierces the transversus and internal oblique muscles to enter the inguinal canal and exits through the superficial inguinal ring. It supplies somatic sensation to the skin of the upper and medial thigh. In males, it also inner-vates the base of the penis and upper scrotum. In females, it innervates the mons pubis and labium majus. The iliohypo-gastric nerve arises from T12–L1. After it pierces the deep abdominal wall, it courses between the internal oblique and transversus abdominis, supplying both. It then divides into lat-eral and anterior cutaneous branches. A common variant is for the iliohypogastric and ilioinguinal nerves to exit around the superficial inguinal ring as a single entity. The genitofemoral nerve arises from L1 to L2, courses along the retroperitoneum, and emerges on the anterior aspect of the psoas. It then divides into genital and femoral branches. The genital branch enters the inguinal canal lateral to the inferior epigastric vessels, and it courses ventral to the iliac vessels and iliopubic tract. In males, it travels through the superficial inguinal ring and sup-plies the ipsilateral scrotum and cremaster muscle. In females, it supplies the ipsilateral mons pubis and labium majus. The Brunicardi_Ch37_p1599-p1624.indd 160229/01/19 2:02 PM 1603INGUINAL HERNIASCHAPTER 37Epigastric vesselsInternal spermaticvesselsIliopsoas muscleIliopubictractMyopectinealorificeExternal iliac a. and v.Vas deferensObturator n.Obturator vesselsLacunar ligamentCooper's ligamentFigure 37-5. Posterior view of the myopectineal orifice of Fruchaud. a. = artery; n. = nerve; v. = vein.Ilioinguinal n.Iliohypogastric n.Iliac m.Lateral femoralcutaneous n.Femoral n.Inguinal ligamentGenitofemoral n.(femoral branch)(genital branch)Iliopectinal archPectineal ligamentIliopubic tractLacunar ligamentFigure 37-6. Retroperitoneal view of major inguinal nerves and their courses. m. = muscle; n. = nerve.femoral branch courses along the femoral sheath, supply-ing the skin of the upper anterior thigh. The lateral femoral cutaneous nerve arises from L2 to L3, emerges lateral to the psoas muscle at the level of L4, and crosses the iliacus mus-cle obliquely toward the anterior superior iliac spine. It then passes inferiorly to the inguinal ligament where it divides to supply the lateral thigh (Fig. 37-8).The preperitoneal anatomy seen in laparoscopic hernia repair led to characterization of important anatomic areas of interest, known as the triangle of doom, the triangle of pain, and the circle of death (Fig. 37-9).7 The triangle of doom is bordered medially by the vas deferens and laterally by the vessels of the spermatic cord. The contents of the space include the external iliac vessels, deep circumflex iliac vein, femoral nerve, and gen-ital branch of the genitofemoral nerve. The triangle of pain is a region bordered by the iliopubic tract and gonadal vessels, and it encompasses the lateral femoral cutaneous, femoral branch of the genitofemoral and femoral nerves. The circle of death is a vascular continuation formed by the common iliac, internal iliac, obturator, inferior epigastric, and external iliac vessels.Brunicardi_Ch37_p1599-p1624.indd 160329/01/19 2:03 PM 1604SPECIFIC CONSIDERATIONSPART IIFigure 37-7. Anterior view of the five major nerves of the inguinal region.Femoral branch ofgenitofemoral n.Ilioinguinal n.Lateral femoralcutaneous n.Medial and intermediatefemoral cutaneous nn.Saphenous n.Iliohypogastric n.Genital branch ofgenitofemoral n.Figure 37-8. Sensory dermatomes of the major nerves in the groin area. n. = nerve.PathophysiologyInguinal hernias may be congenital or acquired. Most adult inguinal hernias are considered acquired defects in the abdomi-nal wall. There is however, a known hereditary association that is not well understood.13 The most likely risk factor for inguinal hernia is weakness in the abdominal wall musculature; how-ever, there are several other risk-factors that have been studied (Table 37-3). Congenital hernias, which make up the majority of pediatric hernias, can be considered a developmental defect rather than an acquired weakness. During the normal course of development, the testes descend from the intra-abdominal space into the scrotum in the third trimester. Their descent is guided by the gubernaculum through an evagination of the peritoneum, which protrudes through the inguinal canal and becomes the processus vaginalis. Between 36 and 40 weeks’ gestation, the processus vaginalis closes and eliminates the peritoneal open-ing at the internal inguinal ring.14 Failure of the peritoneum to close results in a patent processus vaginalis (PPV). In preterm babies, indirect inguinal hernias as a result of PPV is very high (Fig. 37-10). However, overall, the risk of developing a symp-tomatic hernia during childhood in the presence of a known PPV is relatively low.15Overall, there is limited data regarding the etiology of inguinal hernia development. Several studies have documented strenuous physical activity as a risk factor for acquired inguinal hernia.16 A case-controlled study of over 1400 male patients with inguinal hernia revealed that a positive family history was associated with an eightfold lifetime incidence of Brunicardi_Ch37_p1599-p1624.indd 160429/01/19 2:03 PM 1605INGUINAL HERNIASCHAPTER 37Inferolateral border:iliopubic tractDeep circumflexiliac a. & v.Lateral border:reflected peritoneumLat. femoral cutaneous n.Ant. femoral cutaneous n. or other variable branchesFemoral br. of genitofemoral n.Femoral n.Superomedial border:gonadal vesselsLateral border:gonadal vesselsGenital branch ofgenitofemoral nerveIliac veinIliac arteryMedial border:ductus deferensPosterior border:peritoneal edgeDeep ringABFigure 37-9. Borders and contents of the (A) triangle of doom and (B) triangle of pain. a. = artery; Ant. = anterior; br. = branch; Lat. = lateral; n. = nerve; v. = vein. (Modified with permission from Colborn GL, Skandalakis JE: Laparoscopic cadaveric anatomy of the inguinal area, Probl Gen Surg. 1995;12(1):13-20.)inguinal hernia.17 Chronic obstructive pulmonary disease also significantly increases the risk of direct inguinal hernias, thought to be due to repeated instances of intra-abdominal pressure during coughing.18 Several studies have suggested a protective effect of obesity. In a large, population-based prospective study of American individuals (First National Health and Nutrition Examination Survey), the risk of inguinal hernia development in obese men was only 50% that of normal-weight men, while the risk in overweight men was 80% that of nonobese men. A possible explanation is the increased difficulty in detecting inguinal hernias in obese individuals.18Epidemiologic studies have identified risk factors that may predispose to a hernia. Microscopic examination of skin of inguinal hernia patients demonstrated significantly decreased ratios of type I to type III collagen. Type III collagen does not contribute to wound tensile strength as significantly as type I collagen. Additional analyses of similar skin revealed disaggregated collagen tracts with decreased collagen fiber density.19 Collagen disorders such as Ehlers-Danlos syndrome are also associated with an increased incidence of hernia formation (Table 37-4). Recent studies have found an association between concentrations of extracellular matrix Brunicardi_Ch37_p1599-p1624.indd 160529/01/19 2:03 PM 1606SPECIFIC CONSIDERATIONSPART IITable 37-3Presumed causes of groin herniationCoughingChronic obstructive pulmonary diseaseObesityStraining Constipation ProstatismPregnancyBirthweight <1500 gFamily history of a herniaValsalva’s maneuverAscitesUpright positionCongenital connective tissue disordersDefective collagen synthesisPrevious right lower quadrant incisionArterial aneurysmsCigarette smokingHeavy liftingPhysical exertionFigure 37-10. Varying degrees of closure of the processus vagi-nalis (PV). A. Closed PV. B. Minimally patent PV. C. Moderately patent PV. D. Scrotal hernia.Table 37-4Connective tissue disorders associated with groin herniationOsteogenesis imperfectaCutis laxa (congenital elastolysis)Ehlers-Danlos syndromeHurler-Hunter syndromeMarfan’s syndromeCongenital hip dislocation in childrenPolycystic kidney diseaseα1-Antitrypsin deficiencyWilliams syndromeAndrogen insensitivity syndromeRobinow’s syndromeSerpentine fibula syndromeAlport’s syndromeTel Hashomer camptodactyly syndromeLeriche’s syndromeTesticular feminization syndromeRokitansky-Mayer-Küster syndromeGoldenhar’s syndromeMorris syndromeGerhardt’s syndromeMenkes’ syndromeKawasaki diseasePfannenstiel syndromeBeckwith-Wiedemann syndromeRubinstein-Taybi syndromeAlopecia-photophobia syndromeDIAGNOSISHistoryWorkup for inguinal hernia begins with a detailed history. The most common symptom of inguinal hernia is a groin mass that protrudes while standing, coughing, or straining. It is sometimes described as reducible while lying down. Symptoms that are extrainguinal such as a change in bowel habits or urinary symptoms are far less common but should be recognized as having the potential to be ominous. The pain is thought to be due to compression of the nerves by the sac, causing generalized pressure, localized sharp pain, or referred pain. Referred pain may involve the scrotum, tes-ticle, or inner thigh.Important considerations of the patient’s history include the duration and timing of symptoms. Sudden onset symp-toms are more concerning. Questions should also be directed to characterize whether the hernia is reducible. Patients will often reduce the hernia by pushing the contents back into the abdomen, thereby providing temporary relief. As the defect size increases and more intra-abdominal contents fill the hernia sac, the hernia may become harder to reduce and incarcerate, prompting urgent surgical intervention.Certain elements of the review of systems such as chronic constipation, cough, or urinary retention should prompt the sur-geon to perform a thorough workup to rule out any underlying malignancy.elements and hernia formation.20 Although a significant amount of work remains to elucidate the biologic nature of hernias, current evidence suggests they have a multifactorial etiology with both environmental and hereditary influences.Brunicardi_Ch37_p1599-p1624.indd 160629/01/19 2:03 PM 1607INGUINAL HERNIASCHAPTER 37Figure 37-11. Digital examination of the inguinal canal.Table 37-5Differential diagnosis of groin herniaMalignancy Lymphoma Retroperitoneal sarcoma Metastasis Testicular tumorPrimary testicular Varicocele Epididymitis Testicular torsion Hydrocele Ectopic testicle Undescended testicleFemoral artery aneurysm or pseudoaneurysmLymph nodeSebaceous cystHidradenitisCyst of the canal of Nuck (female)Saphenous varixPsoas abscessHematomaAscitesPhysical ExaminationPhysical examination is essential to the diagnosis of inguinal hernia. The patient should be examined in a standing position to increase intra-abdominal pressure, with the groin and scro-tum fully exposed. Inspection is performed first, with the goal of identifying an abnormal bulge along the groin or within the scrotum. If an obvious bulge is not detected, palpation is per-formed to confirm the presence of the hernia.Palpation is performed by advancing the index fin-ger through the scrotum towards the external inguinal ring (Fig. 37-11). This allows the inguinal canal to be explored. The patient is then asked to perform a Valsalva maneuver to increase intraabdominal pressure. These maneuvers will reveal an abnor-mal bulge and allow the clinician to determine whether the her-nia is reducible or not. Examination of the contralateral side affords the clinician the opportunity to compare the presence and extent of herniation between sides. This is especially useful in the case of a small hernia. In addition to inguinal hernia, a number of other diagnoses may be considered in the differential of a groin bulge (Table 37-5).While very difficult to ascertain, there are certain physi-cal examination maneuvers that can be performed to help distinguish direct vs. indirect inguinal hernias. The inguinal occlusion test entails the examiner blocking the internal ingui-nal ring with a finger as the patient is instructed to cough. A controlled impulse suggests an indirect hernia, while persistent herniation suggests a direct hernia. Transmission of the cough impulse to the tip of the finger implies an indirect hernia, while an impulse palpated on the dorsum of the finger implies a direct hernia. When results of physical examination are com-pared against operative findings, there is a probability some-what higher than chance (i.e., 50%) of correctly diagnosing the type of hernia.21,22External groin anatomy is difficult to assess in obese patients, making the physical diagnosis of inguinal hernia chal-lenging. A further challenge to the physical examination is the identification of a femoral hernia. Femoral hernias should be palpable below the inguinal ligament, lateral to the pubic tubercle. In obese patients, a femoral hernia may be missed or misdiagnosed as a hernia of the inguinal canal. In contrast, a prominent inguinal fat pad in a thin patient, otherwise known as a femoral pseudohernia, may prompt an erroneous diagnosis of femoral hernia.ImagingIn the case of an ambiguous diagnosis, radiologic investigations may be used as an adjunct to history and physical examination. Imaging in obvious cases is unnecessary. The most common radiologic modalities include ultrasonography (US), computed tomography (CT), and magnetic resonance imaging (MRI). Each technique has certain advantages over physical examination alone; however, each modality is associated with potential limitations.US is the least invasive technique and does not impart any radiation to the patient. Anatomic structures can be more easily identified by the presence of bony landmarks; however, because there are few bones in the inguinal canal, other structures such as the inferior epigastric vessels are used to define groin anatomy. Positive intra-abdominal pressure is used to elicit the herniation of abdominal contents. Movement of these contents through the canal is essential to making the diagnosis with US, Brunicardi_Ch37_p1599-p1624.indd 160729/01/19 2:03 PM 1608SPECIFIC CONSIDERATIONSPART IIFigure 37-12. Computed tomography scan depicting a large right inguinal hernia (arrow). A smaller left inguinal hernia is also visualized.and lack of this movement may lead to a false negative. A recent meta-analysis demonstrated that ultrasound detects inguinal hernia with a sensitivity of 86%, specificity of 77%.23 In thin patients, normal movement of the spermatic cord and posterior abdominal wall against the anterior abdominal wall may lead to false-positive diagnoses of hernia.24CT and MRI provide static images that are able to delin-eate groin anatomy, to detect groin hernias, and to exclude potentially confounding diagnoses (Fig. 37-12). Meta-analysis determined standard CT detects inguinal hernia with a sensitiv-ity of 80%, specificity of 65%. Although direct herniography has a higher sensitivity and specificity than CT, its invasiveness and limited availability restrict its routine use.23 As CT imaging increases in resolution, its sensitivity in detecting inguinal her-nia is expected to expand; however, this has yet to be clinically confirmed by surgical correlation.25MRI is most commonly utilized in cases where physical examination detects a groin bulge, but where ultrasonography is inconclusive. In a 1999 study of 41 patients with clinical find-ings of inguinal hernia, laparoscopy revealed that MRI was an effective diagnostic test with a sensitivity of 95%, specificity of 96%.26 The expense of MRI precludes its routine use to diag-nose inguinal hernias.TREATMENTSurgical repair of hernias can be performed open, laparoscopic, or with robotic assistance. Surgical repair is the definitive treat-ment of inguinal hernias. The most common reason for elective repair is pain. Incarceration and strangulation are the primary indications for urgent repair. Symptomatic hernias should be operated on electively, and minimally symptomatic or asymptomatic hernias should undergo watchful waiting.27 Repair of minimally symptomatic inguinal hernia in patients with significant medical comorbidities surgery should be deferred and the patient medically optimized. If despite optimal management of comorbidities, the patient remains high-risk, open repair under local anesthesia can be safely performed.28 Although the natural history of untreated inguinal hernias is 3poorly defined, the rates of incarceration and strangulation are low in the asymptomatic population. As a result, nonoperative management is an appropriate consideration in minimally symp-tomatic patients. Prospective studies and meta-analyses have demonstrated no difference in intention-to-treat outcomes, qual-ity of life, or cost-effectiveness between watchful waiting and elective repair among healthy inguinal hernia patients.27,29 A 2012 systematic review found that 72% of asymptomatic ingui-nal hernia patients developed symptoms and had surgical repair within 7.5 years of diagnosis.30 Nevertheless, the complication rates of immediate and delayed elective repair are equivalent.29,31 A nonoperative strategy is safe for minimally symptomatic inguinal hernia patients.32Nonoperative inguinal hernia treatment targets pain, pres-sure, and protrusion of abdominal contents in the symptomatic patient population. The recumbent position aids in hernia reduc-tion via the effects of gravity and a relaxed abdominal wall. Trusses externally confine hernias to a reduced state and inter-mittently relieve symptoms in up to 65% of patients; however, they do not prevent complications, and they may be associated with an increased rate of incarceration.33 The risks of incarcera-tion and strangulation appear to decrease over the first year, likely because gradual enlargement of the abdominal wall defect facilitates spontaneous reduction of hernia contents. The sheer volume of protruding tissue in an inguinal hernia does not nec-essarily signify severe morbidity.Femoral and symptomatic inguinal hernias carry higher complication risks, and so surgical repair is performed earlier for these patients. Irrespective of symptoms, one study found the 3-month and 2-year cumulative incidences of strangulation were 2.8% and 4.5%, respectively, for inguinal hernias and 22% and 45%, respectively, for femoral hernias.34 Data from the Swedish Hernia Registry demonstrates that emergent operation is associ-ated with a sevenfold increase in all-cause mortality over that of elective surgery among 107,838 groin hernia repairs.35 For this reason, it is recommended that femoral hernias and symptomatic inguinal hernias be electively repaired, when possible.Incarceration occurs when hernia contents fail to reduce; however, a minimally symptomatic, chronically incarcerated hernia may also be treated nonoperatively. Taxis should be attempted for incarcerated hernias without sequelae of strangulation, and the option of surgical repair should be discussed prior to the maneuver. To perform taxis, analgesics and light sedatives are administered, and the patient is placed in the Trendelenburg position. The hernia sac is elongated with both hands, and while slight countertraction is maintained, reduction of the contents is attempted circumferentially in a small stepwise fashion to ease their reduction into the abdomen.The indication for emergent inguinal hernia repair is impending compromise of intestinal contents. As such, strangu-lation of hernia contents is a surgical emergency. Clinical signs that indicate strangulation include tenderness, fever, leukocy-tosis, and hemodynamic instability. The hernia bulge is usu-ally warm, tender, and the overlying skin is often erythematous or discolored. Symptoms of bowel obstruction in patients with sliding or incarcerated inguinal hernias may also indicate stran-gulation. Taxis should not be performed when strangulation is suspected, as reduction of potentially gangrenous tissue into the abdomen may result in an intra-abdominal catastrophe. Preop-eratively, the patient should receive fluid resuscitation, naso-gastric decompression, and prophylactic intravenous antibiotics.Brunicardi_Ch37_p1599-p1624.indd 160829/01/19 2:03 PM 1609INGUINAL HERNIASCHAPTER 37Prophylactic AntibioticsThe debate as to whether or not to administer preoperative prophylactic antibiotics in elective inguinal hernia repair still remains controversial as elective hernia repair is considered a clean procedure and as such are exempt from SCIP surgical prophylaxis guidelines. A Cochrane review of 17 randomized controlled trials in 2012 revealed an overall decrease in infec-tion rates (3.1% vs. 4.5%, odds ratio [OR] 0.64, 95% confi-dence interval [CI] 0.50–0.82) when prophylactic antibiotics are administered in patients. In subgroup analyses, the differ-ence was smaller in patients without mesh placement (3.5% vs. 4.9%, OR 0.71, 95% CI 0.51–1.00) than in those with mesh placement (2.4% vs. 4.2%, OR 0.56, 95% CI 0.38–0.81). However, with inguinal hernia repair, overall wound infection rates were higher than those expected for clean operations, as a result, they were unable to definitively recommend for or against antimicrobial prophylaxis.36,37 Although there is no uni-versal guideline regarding the administration of prophylactic antibiotics for open elective hernia repair, the routine indexing of cases for quality improvement databases have resulted in the routine administration of prophylactic perioperative antibiotics in inguinal hernia repairs.Open ApproachThe most commonly performed type of hernia operation still remains the open inguinal hernia repair. These repairs can be performed tension-free with mesh or by reconstruction of the floor with tissue. Tissue repairs are less common and are pri-marily indicated in infected fields.Exposure of the anterior inguinal region is common to the open approaches. An oblique or horizontal incision is performed over the groin (Fig. 37-13). The incision begins two fingerbreadths inferior and medial to the anterior superior iliac spine. It is then extended medially for approximately 6 to 8 cm. The subcutaneous tissue is dissected using electrocautery. Scarpa’s fascia is divided to expose the external oblique aponeurosis. A small incision is made in the external oblique aponeurosis parallel to the direction of the muscle fibers. Standard groin incisionEx. obliqueSpermatic cordCamper’sfasciaScarpa’sfasciaHemostatExternal ringInguinalfloorSQ fatARepaireddefect intransversalisfasciaDirect herniasacIndirect herniasacIllioinguinal nerveBFigure 37-13. A. Layers of the abdominal wall in the anterior open approach to hernia repair. B. Identification of indirect and direct hernia sacs with retraction of the spermatic cord and ilioinguinal nerve. Ex. = external; SQ = subcutaneous.Brunicardi_Ch37_p1599-p1624.indd 160929/01/19 2:03 PM 1610SPECIFIC CONSIDERATIONSPART IIFigure 37-14. Anterior open exposure of the inguinal canal. m. = muscle; n. = nerve; v. = vein.Metzenbaum scissors are introduced and spread beneath the fibers to sweep away the underlying ilioinguinal nerve. The scissors are then used to incise the aponeurosis superior to the inguinal ligament, splitting the external inguinal ring.The flaps of the external oblique aponeurosis are elevated with Hemostat clamps. The internal oblique fibers are dissected bluntly from the overlying external oblique flaps. Dissection of the inferior flap reveals the shelving edge of the inguinal ligament. The iliohypogastric and ilioinguinal nerves are iden-tified and preserved. Effort should be made to avoid remov-ing nerves from their natural bed and disrupting the protective investing fascia. The pubic tubercle is identified, and the cord structures are dissected off of the pubis, encircled, and elevated with a Penrose drain. The cord is elevated 2 cm over the pubic symphysis in an avascular plane, and cremasteric fibers are pre-served to avoid injuring cord structures (Fig. 37-14).An indirect hernia sac will generally be found on the antero-medial surface of the spermatic cord after division of the crem-asteric muscle in the direction of its fibers. The genital nerve is visualized along the inferolateral surface of the cord adjacent to the external spermatic vein. The floor of the inguinal canal is fully assessed for direct hernias. If a hernia is not visualized upon entry into the inguinal canal, the preperitoneal space should be explored for a femoral hernia. In addition to sac identification, the vas deferens and vessels of the spermatic cord must be identi-fied to allow dissection of the sac from the cord. Blunt dissection facilitates dissection of the sac from the cord. The dissection is carried proximally toward the deep inguinal ring.In cases where the viability of sac contents is in question, the sac should be incised, and hernia contents should be evalu-ated for signs of ischemia. The defect should be enlarged to augment blood flow to the sac contents. Viable contents may be reduced into the peritoneal cavity, while nonviable contents resected. In elective cases, the sac may be amputated at the internal inguinal ring or inverted into the preperitoneum. Both methods are effective; however, patients undergoing sac exci-sion had significantly increased postoperative pain in a prospec-tive trial.38 Dissection of a densely adherent sac may result in injury to cord structures and should be avoided; however, sac ligation at the internal inguinal ring is necessary in these cases. A hernia sac that extends into the scrotum may require division within the inguinal canal as extensive dissection and reduction risks injury to the testicular blood supply, resulting in testicular swelling, orchitis, and atrophy.At this point, the inguinal canal is reconstructed, either with native tissue or with prostheses. The following sections describe the most commonly performed types of tissue-based and prosthetic-based reconstructions.Tissue Repairs. Tissue-based herniorrhaphy is a suitable alter-native when prosthetic materials cannot be used safely. Indica-tions for tissue repairs include operative field contamination, emergency surgery, and when the viability of hernia contents is uncertain.Bassini Repair The Bassini repair was a historic advancement in operative technique. Its current use is limited as modern tech-niques reduce recurrence. The original repair includes dissection of the spermatic cord, dissection of the hernia sac with high liga-tion, and extensive reconstruction of the floor of the inguinal canal (Fig. 37-15). After exposing the inguinal floor, the transversalis fascia is incised from the pubic tubercle to the internal inguinal ring. Preperitoneal fat is bluntly dissected from the upper margin of the posterior side of the transversalis fascia to permit adequate tissue mobilization. A triple-layer repair is then performed. The internal oblique, transversus abdominis, and transversalis fascia are fixed to the shelving edge of the inguinal ligament and pubic periosteum with interrupted sutures. The lateral aspect of the repair reinforces the medial border of the internal inguinal ring.Shouldice Repair The Shouldice repair recapitulates principles of the Bassini repair, and its distribution of tension over several tissue layers results in lower recurrence rates (Fig. 37-16). Dur-ing dissection of the cord, the genital branch of the genitofemoral nerve is routinely divided, resulting in ipsilateral loss of sensation to the scrotum in men or the mons pubis and labium majus in women. With the posterior inguinal floor exposed, an incision in the transversalis fascia is made between the pubic tubercle and internal ring. Care is taken to avoid injury to preperitoneal struc-tures, which are bluntly dissected to mobilize the upper and lower fascial flaps. At the pubic tubercle, the iliopubic tract is sutured to the lateral edge of the rectus sheath using a synthetic, nonab-sorbable, monofilament suture. This continuous suture progresses laterally, approximating the edge of the inferior transversalis flap to the posterior aspect of the superior flap. At the internal inguinal ring, the suture continues back in the medial direction, approxi-mating the edge of the superior transversalis fascia flap to the shelving edge of the inguinal ligament. At the pubic tubercle, this suture is tied to the tail of the original stitch. The next suture begins at the internal inguinal ring, and it continues medially, apposing the aponeuroses of the internal oblique and transversus abdominis to the external oblique aponeurotic fibers. At the pubic tubercle, the suture doubles back through the same structures lat-erally towards the tightened internal ring.McVay Repair The McVay repair addresses both inguinal and femoral ring defects. This technique is indicated for femoral hernias and in cases where the use of prosthetic material is contraindicated (Fig. 37-17). Once the spermatic cord has been isolated, an incision in the transversalis fascia permits entry into the preperitoneal space. The upper flap is mobilized by gentle blunt dissection of underlying tissue. Cooper’s ligament is bluntly dissected to expose its surface. A 2 to 4 cm relaxing incision is made in the anterior rectus sheath vertically from the Brunicardi_Ch37_p1599-p1624.indd 161029/01/19 2:03 PM 1611INGUINAL HERNIASCHAPTER 37SpermaticcordPoupart'sligament Internal abdominaloblique muscleExternal abdominaloblique aponeurosisPreperitoneal fatTransversalis fasciaABEOTATFILIOFigure 37-15. Bassini repair. A. The transversalis fascia is opened. B. Reconstruction of the posterior wall by suturing the transver-salis fascia (TF), the transversus abdominis muscle (TA), and the internal oblique muscle (IO) medially to the inguinal ligament (IL) laterally. EO = external oblique aponeurosis.ABFigure 37-16. Shouldice repair. A. The iliopubic tract is sutured to the medial flap of the transversalis fascia and the internal oblique and transverse abdominis muscles. B. The second of the four suture lines, reversing toward the pubic tubercle approximating the inter-nal oblique and transversus muscles to the inguinal ligament. Two more suture lines affix the internal oblique and transversus muscles medially.Cooper’s ligamentFigure 37-17. McVay Cooper’s ligament repair.pubic tubercle. This incision is essential to reduce tension on the repair; however, it may result in increased postoperative pain and higher risk of ventral abdominal herniation. Using either interrupted or continuous suture, the superior transversalis flap is then fastened to Cooper’s ligament, and the repair is contin-ued laterally along Cooper’s ligament to occlude the femoral ring. Lateral to the femoral ring, a transition stitch is placed, affixing the transversalis fascia to the inguinal ligament. The transversalis is then sutured to the inguinal ligament laterally to the internal ring.Desarda Repair The Desarda hernia repair was recently described in 2001, and it consists of a mesh-free repair utilizing a strip of external oblique aponeurosis.An oblique skin incision is made, and dissection is carried down to the external oblique fascia. The integrity of the fascia is preserved as much as possible. The cremasteric muscle is then incised, and the spermatic cord along with the cremasteric muscle is separated from the inguinal floor. Excision of the sac is done in all cases except in small direct hernias, where it is inverted.The medial leaf of the external oblique aponeurosis is sutured to the inguinal ligament from the pubic tubercle to the abdominal ring using 1–0 Ethilon or Prolene interrupted sutures. The first two sutures are taken at the junction of the anterior rec-tus sheath and EOA. The last suture is taken so as to sufficiently Brunicardi_Ch37_p1599-p1624.indd 161129/01/19 2:03 PM 1612SPECIFIC CONSIDERATIONSPART IInarrow the abdominal ring without constricting the spermatic cord (Fig. 37-18). Each suture is passed first through the ingui-nal ligament, then the transversalis fascia, and then the EOA. The index finger of the left hand is used to protect the femo-ral vessels and retract the cord structures laterally while taking lateral sutures. A splitting incision is then taken in the EOA, partially separating a strip. This splitting incision is extended medially up to the pubic symphysis and laterally 1 to 2 cm beyond the reconstructed abdominal ring.The free border of the strip of the EOA is now sutured to the internal oblique or conjoined tendon lying close to it with 1–0 Ethilon or Prolene interrupted sutures. This is followed by closure of the superficial fascia and the skin as usual.39-41Prosthetic Repairs. The popularization of tension-free pros-thetic mesh repairs signified a paradigm shift in the surgical concept of inguinal hernia pathophysiology. Mesh-based her-nioplasty is the most commonly performed general surgical procedure, owing to the technique’s efficacy and improved out-comes. The techniques of the most commonly performed pros-thetic repairs are presented in this section.Lichtenstein Tension-Free Repair The Lichtenstein technique allows for a tension-free repair of the inguinal floor by buttressing the floor with a prosthetic mesh (Fig. 37-18). Initial exposure and mobilization of cord structures is identical to other open approaches. The inguinal canal is dissected to expose the shelving edge of the inguinal ligament, the pubic tubercle, and sufficient area for mesh. The most commonly used mesh is “flat iron” shaped with a keyhole for cord egress, it is available in several sizes. It should be noted that when selecting the size, it must be large enough to extend 2 to 3 cm superior to Figure 37-18. The Desarda repair. A. The medial leaf of the external oblique aponeurosis is sutured to the inguinal ligament. 1 Medial leaf, 2 interrupted sutures taken to suture the medial leaf to the inguinal ligament, 3 pubic tubercle, 4 abdominal ring, 5 spermatic cord, 6 lateral leaf B. Undetached strip of the external oblique aponeurosis forming the posterior wall. 1 Reflected medial leaf after a strip has been separated, 2 internal oblique muscle seen through the splitting incision made in the medial leaf, 3 interrupted sutures between the upper border of the strip and conjoined muscle and internal oblique muscle, 4 interrupted sutures between the lower border of the strip and the inguinal ligament, 5 pubic tubercle, 6 abdominal ring, 7 spermatic cord, 8 lateral leaf.64123568751234Hesselbach’s Triangle. The medial edge of the mesh is affixed to the anterior rectus sheath such that it overlaps the pubic tubercle by 1.5 to 2 cm. This refinement to the original Lichtenstein technique minimizes medial recurrence.42For fixation of the inferior margin of the mesh, a per-manent, synthetic, monofilament suture is used taking care to avoid placing sutures directly into the periosteum of the pubic tubercle. Fixation is continued along the shelving edge of the inguinal ligament from medial to lateral, ending at the internal ring. The upper tail of the mesh is then fixed to the internal oblique aponeurosis and the medial edge to the rectus sheath using a synthetic, absorbable suture.In the case of a femoral hernia, a triangular extension of the inferior aspect of the mesh is sutured to Cooper’s ligament medially and to the inguinal ligament laterally. The lateral tails of the mesh are tailored to fit snugly around the cord at the internal ring, but not too tight to strangulate it. The tails are then sutured to the inguinal ligament with an interrupted stitch and placed beneath the external oblique aponeurosis.Plug and Patch Technique. A modification of the Lichtenstein repair, the Plug and Patch technique was developed by Gilbert and later popularized by Rutkow and Robbins.43 Prior to placing the prosthetic mesh patch over the inguinal floor, a three-dimensional prosthetic plug is placed in the space previously occupied by the hernia sac (Fig. 37-19). In the case of an indirect hernia, the plug is placed alongside the spermatic cord through the internal ring. Prosthetic plugs of various sizes are available, and one of appropriate size is fixed to the margins of the internal ring with interrupted sutures.44 For direct hernias, the sac is reduced, and the plug is sutured to Cooper’s ligament, the inguinal ligament, and Brunicardi_Ch37_p1599-p1624.indd 161229/01/19 2:03 PM 1613INGUINAL HERNIASCHAPTER 37Figure 37-19. Lichtenstein tension-free hernioplasty. m. = muscle; n. = nerve; v. = vein.the internal oblique aponeurosis. While the technique has good overall outcomes, there have been some isolated case report series of complications involving the presence of the plug, including bowel obstruction and chronic pain.Wound Closure Once the reconstruction of the inguinal canal is complete, the cord contents are returned to their anatomic posi-tion. The external oblique aponeurosis is then reapproximated continuously from medial to lateral using an absorbable suture. The external ring should be reconstructed in close apposition to the spermatic cord to avoid the appearance of recurrence on future examination. Scarpa’s fascia and skin are appropriately closed.Laparoscopic ApproachLaparoscopic inguinal hernia repairs have become increas-ingly popular given the noninferiority studies, improved aes-thetics, and increased surgeon experience with the procedure. Principal endoscopic methods include the transabdominal preperitoneal (TAPP) repair, the totally extraperitoneal (TEP) repair, and the less-commonly performed intraperitoneal onlay mesh (IPOM) repair.Of note, awake patients do not tolerate abdominal insuffla-tion well; therefore, laparoscopic repair necessitates the admin-istration of general anesthesia and its inherent risks. Any patient with a contraindication to the use of general anesthesia should not undergo laparoscopic hernia repair. Occasionally, induction of general anesthesia may result in reduction of an incarcer-ated or strangulated inguinal hernia. If the surgeon suspects this might have occurred, the abdomen should be explored for non-viable tissue either via laparoscopy or upon conversion to an open laparotomy.The indications for laparoscopic inguinal hernia repair are similar to those for open repair. Most surgeons would agree that the endoscopic approach to bilateral or recurrent inguinal hernias is superior to the open approach.45 Concurrent inguinal hernia repair can be considered if a hernia patient is scheduled to undergo another laparoscopic procedure without gross contamination, such as prostatectomy.46,47 International Endohernia Society (IEHS) guidelines offer a grade A recommendation that TEP and TAPP are preferred alternatives to Lichtenstein repair for recurrent hernias after open anterior repair.48,49 The possibility of bilateral repair should be discussed with all patients undergoing endoscopic inguinal hernia surgery.The operating room configuration is identical for TAPP, TEP, and IPOM procedures. The patient is placed in the Trendelenburg position, and video screens are placed at the foot of the bed. The surgeon stands contralateral to the hernia, and the assistant stands opposite the surgeon. The patient’s arms are tucked to the sides. Figure 37-20 demonstrates a typical operating room setup for endoscopic inguinal hernia repair. The following sections outline the most commonly performed endoscopic inguinal hernia repair techniques.Transabdominal Preperitoneal Procedure. The transab-dominal approach confers the advantage of an intraperitoneal perspective, which is useful for bilateral hernias, large hernia defects, and scarring from previous lower abdominal surgery. The abdominal cavity is accessed using a dissecting trocar or open Hasson technique. Pneumoperitoneum to a level of 15 mmHg is achieved. Two 5-mm trocars are placed lateral and slightly inferior to the umbilical trocar, avoiding injury to the inferior epigastric vessels (Fig. 37-21). The patient is then placed in the Trendelenburg position, and the pelvis is inspected.The bladder, median and medial umbilical ligaments, external iliac, and inferior epigastric vessels are visualized. An incision is made in the peritoneum at the medial umbilical liga-ment, 3 to 4 cm superior to the hernia defect, and it is carried lat-erally to the anterior superior iliac spine. For bilateral inguinal hernia repair, bilateral peritoneal incisions are advisable, leav-ing a midline bridge of tissue to avoid injuring a potential patent urachus. The inferior edge of incised peritoneum is retracted, and the preperitoneum is dissected to expose the spermatic cord. If a direct hernia is encountered, the sac is inverted and fixed to Cooper’s ligament to prevent development of hematoma or seroma. An indirect hernia sac will usually protrude anterior to the spermatic cord. In this case, the sac is grasped and elevated superiorly from the cord and the space below is developed bluntly to allow for mesh placement. The sac is dissected from its adhesions, and the cord is skeletonized.The mesh usually measures 10 × 15 cm to completely cover the myopectineal orifice (Fig. 37-22). It is rolled length-wise and placed through the 12-mm trocar. It is unrolled in the preperitoneal space and secured medially to Cooper’s ligament using an endoscopic tacker. During this fixation, the surgeon palpates the end of the tacker from the abdominal surface to ensure its proper angle and to stabilize the pelvis. The mesh is then pulled taut and fixed laterally to the anterior superior iliac spine. Tacks are placed above the iliopubic tract to avoid injury to the lateral cutaneous nerve of the thigh and the femoral branch of the genitofemoral nerve. The peritoneal edges are reapproxi-mated using tacks or intracorporeal sutures as the mesh is sta-bilized. The peritoneum should be closed completely to avoid contact between the mesh and the intestine. The abdomen is desufflated, and the trocars are removed. The fascial defect of the 12-mm port and the skin incisions are appropriately closed.Totally Extraperitoneal Procedure. The advantage of the TEP repair is the access to the preperitoneal space without intra-peritoneal infiltration. Consequently, this approach minimizes the risk of injury to intra-abdominal organs and port site hernia-tion through an iatrogenic defect in the abdominal wall. As with TAPP, TEP is indicated for repair of bilateral inguinal hernias or Brunicardi_Ch37_p1599-p1624.indd 161329/01/19 2:03 PM 1614SPECIFIC CONSIDERATIONSPART IIFigure 37-20. Operating room setup for laparoscopic inguinal hernia repair.for unilateral hernias when scarring makes the anterior approach challenging.A small horizontal incision is made inferior to the umbi-licus. Subcutaneous tissue is dissected to the level of the ante-rior rectus sheath, which is then incised lateral to the linea alba. The rectus muscle is retracted superolaterally, and a dissecting balloon is advanced through the incision toward the pubic sym-physis. Under direct visualization with a 30° laparoscope, the balloon is inflated slowly to bluntly dissect the preperitoneal space (Fig. 37-23). The dissecting balloon is replaced with a 12-mm balloon trocar, and pneumopreperitoneum is achieved by insufflation to 15 mmHg. A 5-mm trocar is placed suprapubically in the midline, and another is placed inferior to the insufflation port (see Fig. 37-21). The patient is placed in the Trendelenburg position, and the operation proceeds in an identical fashion to TAPP. No modifications are necessary to repair bilateral ingui-nal hernias with the TEP approach. Any peritoneal rents should be repaired prior to desufflation to prevent mesh from contact-ing intraperitoneal structures. Following mesh placement, the preperitoneal space is desufflated slowly under direct vision to ensure proper mesh positioning. Trocars are removed, and the anterior rectus sheath is closed with an interrupted suture. If there Brunicardi_Ch37_p1599-p1624.indd 161429/01/19 2:03 PM 1615INGUINAL HERNIASCHAPTER 37BA Figure 37-21. Trocar placement for (A) transabdominal preperitoneal repair and (B) totally extraperitoneal repair.Figure 37-22. View of mesh placement in posterior repairs. A large mesh overlaps the myopectineal orifice.Figure 37-23. Balloon dissection of the preperitoneal space in a totally extraperitoneal inguinal hernia repair.Brunicardi_Ch37_p1599-p1624.indd 161529/01/19 2:04 PM 1616SPECIFIC CONSIDERATIONSPART IIis violation of the peritoneum during insufflation of the dissec-tion balloon and subsequent pneumoperitoneum, visualization can be compromised. To address this, a Veress needle or angio-catheter can be placed in the LUQ, which will allow desufflation of the peritoneum and restore visualization.Intraperitoneal Onlay Mesh Procedure. In contrast to TAPP and TEP, the IPOM procedure permits the posterior approach without preperitoneal dissection. It is an attractive procedure in cases where the anterior approach is unfeasible, in recurrent her-nias that are refractory to other approaches, or where extensive preperitoneal scarring would make TEP or TAPP challenging. Port placement and inguinal hernia identification are identical to TAPP. Hernia sac contents are reduced; however, the sac itself is not inverted from the preperitoneal space. Instead, mesh is placed directly over the defect and fixed in place with sutures or spiral tacks. Because these anchors are placed through the peritoneum without preperitoneal inspection, the lateral cutane-ous nerve of the thigh and the genitofemoral nerve are especially prone to injury. Furthermore, intraperitoneal mesh migration is a documented phenomenon that can lead to postoperative mor-bidity, recurrence, and reoperation.Robot-Assisted Inguinal Hernia RepairApplication of a robotic platform to hernia repair has been adapted by general surgeons across the country. The endowrist capabilities provides greatly improved manual dexterity and a relatively short learning curve. Though both total extraperito-neal repair and transabdominal preperitoneal repair can be adapted to a robotic platform, the latter has gained more traction among surgeons.Many papers have explored the efficacy and cost-effectiveness of robot-assisted herniorraphy. Retrospective data have had mixed results when comparing robot-assisted surgery vs. laparoscopy. One recent study has shown longer operative time,50 another analysis has shown increased cost.51 It should be noted, however, that there is a decrease in cost with robotic surgery as the volume of procedures increases at each center, though it is still unlikely that the costs will ever converge to that of laparoscopic surgery. A retrospective, single-institution study has shown greatly reduced complication rates with robotic assisted surgery in obese patients; however, this was compared against open inguinal hernia repair (10.8% vs. 3.2%, P = 0.047), the two groups were covariate matched for preoperative risk.52 Studies have also shown excellent long-term (36-month) quality of life indicators in robot-assisted TAPP, though this was a single surgeon survey.53 Further randomized trials will shed more light into cost issues as surgeons gain more experience with robotic application that would lead to shorter operative time and minimize additional instrument use.Similar to laparoscopy, robot-assisted repair is ideal for recurrent inguinal hernia patients who had previous anterior repair and bilateral hernias. Contraindications to robotic her-nia repair are the same as for laparoscopic repair and include coagulopathy and/or severe cardiopulmonary disease precluding induction of general anesthesia and pneumoperitoneum. Previ-ous preperitoneal repair is a relative contraindication along with the presence of a large incarcerated inguinal hernia.Patient evaluation should proceed similarly to workup for laparoscopic inguinal herniorraphy.Technique. Patients are instructed to void in preoperative area to avoid Foley catheter placement, though some surgeons advocate 4routine Foley catheter placement. Ideally, the operating table should have capability of synchronization with robotic arms to prevent injury to the patient during repositioning during the pro-cedure. The patient is placed in supine position with arms tucked at both sides. Appropriate padding of extremities is important to avoid neuropraxia and trauma from robotic arm movements. Three trocars are typically used for TAPP repair. Open Hasson technique is employed for initial trocar placement at umbilicus; this can be an 8-mm trocar or alternatively a 12-mm with a tele-scoped 8-mm trochar. Additionally, two 8-mm trocars are placed in each side of the mid-abdomen, slightly above the level of umbi-licus. After trocar placement, the robot is docked and targeted, and the patient is placed in Trendelenburg position. Typically, the surgeon will use robotic shears attached to electrocautery, Cadiere forceps, and a needle holder as the primary instruments. This combination provides optimal cost-effectiveness because the majority of the cost associated with robotic application is due to disposable instruments. Exposure starts with incising the parietal peritoneum from the medial umbilical ligament to the anterior superior iliac spine. A peritoneal flap is developed by blunt and sharp dissection with robotic shears in the prepreitoneal space. Special care is taken to leave the preperitoneal fat pad contain-ing nerves and vessels with the anterior abdominal wall. Small vessels can be coagulated with application of electrocautery with scissors. With the aid of pneumoperitoneum, the preference is first to perform a lateral dissection in the space of Bogros. Dissection continues in this plane laterally towards the anterior superior iliac spine. The generous development of a peritoneal flap will ensure successful mesh placement at the end. Then the space of Retzius is entered medially exposing the pubic symphysis. In the absence of haptic feedback, visual recognition of the pubic symphysis is crucial as this serves as an important landmark for further dis-section. Inferior epigastric vessels are readily identified. Next, an inferior peritoneal flap is developed to avoid rolling of mesh during closure. Direct, indirect, and femoral spaces are carefully examined. Cadiere forceps are then used to grasp the hernia sac to provide traction. Any cord lipoma is carefully dissected free from the cord structures, and the testicular vessels, pampiniform plexus, and ductus deferens are separated from hernia sac. These structures can usually be identified at the neck of sac. Reduction is successful when the sac stays reduced after traction is released. The next step is placement of the mesh. Lightweight barbed mesh and anatomically preshaped mesh are routinely used. Mesh should be an appropriate size to cover the myopectineal orifice entirely, and the peritoneal dissection will need to be large enough to accommodate this size mesh. It is rolled and placed through one of the ports by the bedside assistant. Then it is unrolled and placed in the pelvis overlapping the pubic symphysis by several centimeters medially; this is essential as the majority of recur-rences occur in this area. Utilization of tacking devices are not necessary, which helps to reduce procedural cost; however, this is surgeon preference. Finally, the peritoneal flap is placed back over the mesh layer and sutured back into place with a running locking suture that is facilitated by the increased intracorporeal dexterity of the robotic instruments. Then the fascia of the umbili-cal trochar site is closed with 0-absorbable suture (Fig 37-24), and the skin is closed with absorbable monofilament suture.Prosthesis ConsiderationsThe success of prosthetic repairs has generated considerable debate about the desirable physical attributes of mesh and their fixation. An ideal mesh should be easy to handle, flexible, Brunicardi_Ch37_p1599-p1624.indd 161629/01/19 2:04 PM 1617INGUINAL HERNIASCHAPTER 37Figure 37-24. Steps in robotic TAPP repair. A. Image of a direct inguinal hernia. B. There is no visible hernia on the contralateral side. C. Hernia contents and sac are dissected and cleared for mesh placement. D. Unrolling and placement of mesh E. Satisfactory placement of mesh. F. Closure of peritoneum. G. Completed repair of hernia with comparison to contralateral side.ABCDEFGBrunicardi_Ch37_p1599-p1624.indd 161729/01/19 2:04 PM 1618SPECIFIC CONSIDERATIONSPART IIstrong, immunologically inert, contraction-resistant, infection-resistant, and inexpensive to manufacture.54 The following section reviews the most common types of mesh and fixatives currently available.Synthetic Mesh Material. Polypropylene and polyester are the most common synthetic prosthetic materials used in her-nia repair. These materials are permanent and hydrophobic, and they promote a local inflammatory response that results in cellular infiltration and scarring with slight contraction in size. Other synthetic mesh materials are under investigation with the goals of minimizing postoperative pain and preventing infection or recurrence. In selecting mesh material, considerations include mesh absorbability, thickness, weight, porosity, and strength.Variations in the fiber diameter and fiber count of mesh materials categorize them as heavyweight or lightweight in den-sity, though there does not seem to be a universally agreed upon set of criteria for either. Commonly used lightweight mesh materi-als include β-d-glucan, titanium-coated polypropylene, and poly-propylene–poliglecaprone. These materials have greater elasticity and less theoretical surface area contact with surrounding tissues than their heavyweight counterparts.55 They are hypothesized to reduce scarring and chronic pain without compromising the strength of the repair. The use of lightweight mesh use in TEP and TAPP repairs is associated with fewer 3-month cumulative mesh-related complications.54 A 2012 meta-analysis of 2310 patients undergoing open or laparoscopic hernia repairs found a lower incidence of chronic pain (relative risk [RR] 0.61, CI 0.50–0.74) following use of lightweight mesh versus heavyweight mesh and no significant difference in rates of recurrence.55When available, lightweight mesh should be considered for all prosthetic repairs to minimize postoperative chronic pain. A disadvantage of currently available commercial pros-theses is their high cost. In settings where resources are limited, prosthetic repairs are performed using alternative materials. Polypropylene and polyethylene mosquito nets are inexpensive and ubiquitous in sub-Saharan Africa and India, and they have similar mechanical properties to commercially available hernio-plasty meshes. Meta-analysis of 577 hernioplasties performed using sterilized mosquito nets demonstrated similar rates of short-term mesh-related complications (6.1%) and recurrence (0.17%) to those using commercial meshes.56 Furthermore, the disability-adjusted life years (DALYs) prevented by inguinal hernia repair signify a comparable impact to that of vaccination in sub-Saharan Africa.57,58 Expensive prostheses are not neces-sarily needed for hernia surgery, whether in resource-limited or in resource-abundant settings, and the anticipated benefits should be evaluated with consideration of increased costs.Biologic Mesh. Although indications for the use of biologic prostheses have not been absolutely defined, they are commonly reserved for contaminated cases or when domain expansion is necessary in the face of high infection risk. This is partially on account of their high cost and high recurrence rates. There are numerous biologic materials available with differing properties, but in general, they have a lower tensile strength and subse-quently higher rates of rupture than synthetic prostheses.59 They also have varying degrees of tensile strength and tissue biocom-patibility between them. In ventral hernia repairs, xenograft material was associated with a lower rate of recurrence than allograft material.60 A review of biologic materials concludes cross-linked graft materials are more durable and less prone to failure than non–cross-linked grafts.61 Nevertheless, their 5diminished ability to remodel adversely affects rates of infec-tion and incorporation. While new prosthetic materials continue to be developed, no single biologic warrants routine use. These materials will continue to evolve, and they remain an important tool for challenging cases when used judiciously.Fixation Technique. Independent of prosthesis material, the method of its fixation remains disputed. Suturing, stapling, and tacking prostheses entail tissue perforation, which may cause inflammation, neurovascular injury, and chronic pain devel-opment. Conversely, improper prosthesis fixation may result in mesh migration, repair failure, meshoma pain, and hernia recurrence. Mesh may be fixed with fibrin-derived glue, and self-gripping mesh has been developed to minimize trauma to surrounding tissues and to reduce the risk for entrapment neuropathy. For hernias repaired via a strictly preperitoneal approach, prosthesis fixation may not be necessary at all.Fibrin glue fixation is a successful alternative to tack fixation in hernia repair with a synthetic prosthesis. Recent studies comparing fibrin glue fixation and suture fixation in open hernia repair show superior rates of chronic pain with both Lichtenstein and Plug and Patch techniques.62,63 Meta-analyses of endoscopic hernia repair determined the incidence of chronic postoperative pain after tacker fixation was significantly higher than after fibrin glue fixation, with one showing a relative risk of 4.64 (CI 1.9–11.7). Rates of other postoperative complications and recurrence were similar between both fixation methods.62,63 Glue fixation is a promising technical refinement, and several studies have shown long-term benefit; however, its questionable efficacy in larger hernias and cost remain considerations.In TEP repairs, fixation of mesh may not be compulsory. A prospective randomized trial comparing fixation and no fixation in TEP repairs found a significant increase in new pain and equiv-alent recurrence rates in the fixation group several months after repair.64 A 2012 meta-analysis comparing laparoscopic tacker mesh fixation to no mesh fixation found no statistically signifi-cant differences in operative duration, pain, mesh-related compli-cations, recurrence, or length of stay between the two methods.65 Studies of three-dimensional, ergonomically contoured mesh without fixation, as well as self-gripping meshes, have yielded similar results.66 In the preperitoneal approach, the reapproxi-mation of surrounding tissues and physiologic intra-abdominal pressure hypothetically prevent mesh migration. Due to higher theoretical risk of mesh migration, repair without fixation is not recommended for anterior or transperitoneal approaches.COMPLICATIONSAs with other clean operations, the most common complications of inguinal hernia repair include bleeding, infection, seroma, urinary retention, ileus, and injury to adjacent structures (Table 37-6). Complications specific to herniorrhaphy include hernia recurrence, chronic inguinal and pubic pain, and injury to the spermatic cord or testis. The incidence, prevention, and treatment of these complications are discussed in the ensuing section.Hernia RecurrenceWhen a patient develops pain, bulging, or a mass at the site of an inguinal hernia repair, clinical entities such as seroma, persistent cord lipoma, and hernia recurrence should be considered. Com-mon medical issues associated with recurrence include malnu-trition, immunosuppression, diabetes, steroid use, and smoking. Technical causes of recurrence include improper mesh size, tissue Brunicardi_Ch37_p1599-p1624.indd 161829/01/19 2:04 PM 1619INGUINAL HERNIASCHAPTER 37Table 37-6Complications of groin hernia repairsRecurrenceChronic groin pain Nociceptive  Somatic  Visceral Neuropathic  Iliohypogastric  Ilioinguinal  Genitofemoral  Lateral cutaneous  FemoralCord and testicular Hematoma Ischemic orchitis Testicular atrophy Dysejaculation Division of vas deferens Hydrocele Testicular descentBladder injuryWound infectionSeromaHematoma Wound Scrotal RetroperitonealOsteitis pubisProsthetic complications Contraction Erosion Infection Rejection FractureLaparoscopic Vascular injury  Intra-abdominal  Retroperitoneal  Abdominal wall  Gas embolism Visceral injury  Bowel perforation  Bladder perforation Trocar site complications  Hematoma  Hernia  Wound infection  Keloid Bowel obstruction  Trocar or peritoneal closure site hernia  Adhesions Miscellaneous  Diaphragmatic dysfunction  HypercapniaGeneral Urinary Paralytic ileus Nausea and vomiting Aspiration pneumonia Cardiovascular and respiratory insufficiencyischemia, infection, and tension in the reconstruction. A focused physical examination should be performed. As with primary her-nias, US, CT, or MRI can elucidate ambiguous physical findings. When a recurrent hernia is discovered and warrants reoperation, an approach through a virgin plane facilitates its dissection and exposure. Extensive dissection of the scarred field and mesh may result in injury to cord structures, viscera, large blood ves-sels, and nerves. After an initial anterior approach, the posterior endoscopic approach will usually be easier and more effective than another anterior dissection. Conversely, failed preperitoneal repairs should be approached using an open anterior repair.PainPain after inguinal hernia repair is classified into acute or chronic manifestations of three mechanisms: nociceptive (somatic), neuropathic, and visceral pain. Nociceptive pain is the most common of the three. Because it is usually a result of ligamentous or muscular trauma and inflammation, nociceptive pain is reproduced with abdominal muscle contraction. Treat-ment consists of rest, nonsteroidal anti-inflammatory drugs (NSAIDs), and reassurance as it resolves spontaneously in most cases. Neuropathic pain occurs as a result of direct nerve dam-age or entrapment. It may present early or late, and it mani-fests as a localized, sharp, burning, or tearing sensation. It may respond to pharmacologic therapy and to local steroid or anes-thetic injections when indicated. Visceral pain refers to pain conveyed through afferent autonomic pain fibers. It is usually poorly localized and may occur during ejaculation as a result of sympathetic plexus injury.Chronic postoperative pain remains an important measure of clinical outcome that has been reported in as many as 63% of inguinal hernia repair cases.67-69 Despite the significant anatomic variation in the three inguinal nerves, literature reviews suggest identification of all three nerves is possible in 70% to 90% of cases.70 Meticulous nerve identification may prevent injury that results in debilitating chronic postoperative pain syndromes. Notwithstanding, moderate-to-severe pain adversely affects physical activity, social interactions, health care utilization, employment, and productivity in 6% to 8% of patients.67,68,71-74 Pain in this subset of patients comprises a tremendous individ-ual and societal burden.Postherniorrhaphy inguinodynia is a debilitating chronic complication. Its incidence is independent of the method of her-nia repair.73 Selective ilioinguinal, iliohypogastric, and genito-femoral neurolysis/neurectomy, removal of mesh and fixation material, and revision of the repair are the three most common options for treatment. Nevertheless, anatomic variation and cross-innervation of the inguinal nerves in the retroperitoneum and inguinal canal make selective neurectomy less reliable.75-78 When inguinodynia is refractory to pharmacologic and interven-tional measures, triple neurectomy with removal of meshoma is routinely performed with acceptable outcomes in the majority of patients.74,76,77,79-84 Refractory inguinodynia with concurrent orchialgia also requires resection of the paravasal nerves.84A relatively newly described technique that has cited good outcomes is the laparoscopic triple neurectomy. This involves laparoscopic approach to and division of the main trunks of the ilioinguinal and iliohypogastric nerves and additional division of the genitofemoral nerve in the lumbar plexus.84,85 Several studies with moderate numbers of patients treated showed dura-ble reduction in pain scores.Other chronic pain syndromes include local nerve entrapment, meralgia paresthesia, and osteitis pubis. At greatest Brunicardi_Ch37_p1599-p1624.indd 161929/01/19 2:04 PM 1620SPECIFIC CONSIDERATIONSPART IIrisk of entrapment are the ilioinguinal and iliohypogastric nerves in anterior repairs and the genitofemoral and lateral femoral cutaneous nerves in endoscopic repairs. Clinical manifestations of nerve entrapment mimic acute neuropathic pain, and they occur with a dermatomal distribution. Injury to the lateral femoral cutaneous nerve results in meralgia paresthesia, a condition characterized by persistent paresthesia of the lateral thigh. Initial treatment of nerve entrapment consists of rest, ice, NSAIDs, physical therapy, and possible local corticosteroid and anesthetic injection. This can be followed by a trial of gabapentin86 or its analogues. Osteitis pubis is characterized by inflammation of the pubic symphysis and usually presents as medial groin or symphyseal pain that is reproduced by thigh adduction. Avoiding the pubic periosteum when placing sutures and tacks reduces the risk of developing osteitis pubis. CT scan or MRI excludes hernia recurrence, and bone scan is confirmatory for the diagnosis. Initial treatment is identical to that of nerve entrapment; however, if pain remains intractable, orthopedic surgery consultation should be sought for possible bone resection and curettage. Irrespective of treatment, the condition often takes six months to resolve.87Cord and Testes InjuryInjury to spermatic cord structures may result in ischemic orchitis or testicular atrophy. Ischemic orchitis is most com-monly caused by injury to the pampiniform plexus and not to the testicular artery. It usually manifests within 1 week of ingui-nal hernia repair as an enlarged, indurated, and painful testis, and it is almost certainly self-limited. It occurs in <1% of pri-mary hernia repairs; however, this figure is larger for recurrent inguinal hernia repairs.88 US will demonstrate testicular blood flow to differentiate between ischemia and necrosis. Emergent orchiectomy is only necessary in the case of necrosis. Injury to the testicular artery itself may lead to testicular atrophy, which is manifest over a protracted period but does not always lead to testicular necrosis. This is because despite compromise of the artery, there is collateral flow from the inferior epigastric, vesi-cal, prostatic, and scrotal arteries that supply the testes, and in the case of insufficiency, there is atrophy. Treatment for isch-emic orchitis most frequently consists of reassurance, NSAIDs, and comfort measures. Intraoperatively, proximal ligation of large hernia sacs to avoid cord manipulation minimizes the risk of injury.Injury to the vas deferens within the cord may lead to infertility. In open inguinal hernia repairs, isolating the vas deferens along with the cord structures using digital manipulation may cause injury or disruption. In endoscopic approach, grasping the vas may result in a crush injury. Transections of the vas deferens should be addressed with a urologic consult and early anastomosis, if possible. Historically, surgeons and their patients speculated that synthetic material would increase the risks of mesh rejection, carcinogenesis, and inflammation; however, as mesh became used more frequently, these concerns did not manifest. Nevertheless, one study found prosthetic mesh may exert long-term deleterious effects upon the vas deferens, causing azoospermia.89 Similar studies report varied results, though. A recent prospective study from the Swedish Hernia Registry discovered no difference in rates of patient-reported infertility between the general population and patients who underwent either mesh or tissue-based inguinal hernia repair.90 Chronic scarring may lead to vas deferens obstruction, resulting in decreased fertility rates and a dysejaculation syndrome. Pain and burning during ejaculation are usually self-limited, and more common causes, such as sexually transmitted diseases, should be excluded.In females, the round ligament is the analog to the sper-matic cord, and it maintains uterine anteversion. Injury to the artery of the round ligament does not result in clinically signifi-cant morbidity.Laparoscopic ComplicationsIn general, the risks of the TEP technique mirror those of open anterior repairs, as the peritoneal space is not violated. Com-plications of transabdominal laparoscopy include urinary reten-tion, paralytic ileus, visceral injuries, vascular injuries, and less commonly, bowel obstruction, hypercapnia, gas embolism, and pneumothorax. The most common complications of endoscopic inguinal hernia repair are presented in this section.Urinary Retention. The most common cause of urinary reten-tion after hernia repair is general anesthesia, which is routine in endoscopic hernia repairs. Among 880 patients undergoing inguinal hernia repair with local anesthesia only, 0.2% devel-oped urinary retention, while the rate of urinary retention was 13% among 200 patients undergoing repair with general or spinal anesthesia.91 Overall, the risk of development of postop-erative urinary retention is 2% to 3%.92-95 Other risk factors for postoperative urinary retention include pain, narcotic analgesia, and perioperative bladder distention. Initial treatment of urinary retention requires decompression of the bladder with short-term catheterization. Patients will generally require an overnight admission and trial of normal voiding before discharge. Failure to void normally requires reinsertion of the catheter for up to a week. Chronic requirement of a urinary catheter is rare, though older patients may require prolonged catheterization. Risk of urinary retention can be minimized by ensuring voiding prior to surgery and minimization of perioperative fluid administration.96Ileus and Bowel Obstruction. The laparoscopic transab-dominal approach is associated with a higher incidence of ileus than other modes of repair. This complication is self-limited; however, it necessitates sustained inpatient observation, intra-venous fluid maintenance, and possibly nasogastric decom-pression. Abdominal imaging may be helpful to confirm the diagnosis and to exclude bowel obstruction. Prolonged absence of bowel function, in conjunction with a suspicious abdominal series, should raise concern for obstruction. In this case, CT of the abdomen is helpful to distinguish anatomic sites of obstruc-tion, inflammation, and ischemia. In TAPP repairs, obstruction occurs most commonly secondary to herniation of bowel loops through peritoneal defects or large trocar insertion sites; how-ever, the use of smaller trocars and the preponderance of TEP repairs have reduced the frequency of this complication. True obstruction warrants reoperation.Visceral Injury. Small bowel, colon, and bladder are at risk for injury in laparoscopic hernia repair. The presence of intra-abdominal adhesions from previous surgeries may predispose to visceral injuries. Direct bowel injuries may also result from tro-car placement. In reoperative abdominal surgery, open Hasson technique and direct visualization of trocars are recommended to reduce the likelihood of visceral injury. Bowel injury may also occur secondary to electrocautery and instrument trauma outside of the camera field. Missed bowel injuries are associated with increased mortality. If injury to the bowel is suspected, its entire length should be examined, and conversion to open repair may be necessary.Brunicardi_Ch37_p1599-p1624.indd 162029/01/19 2:04 PM 1621INGUINAL HERNIASCHAPTER 37Bladder injuries are less common than visceral injuries, and they are usually associated with perioperative bladder dis-tention or extensive dissection of perivesical adhesions. As with bladder injuries encountered in open surgery, cystotomies must be repaired in several layers with 1 to 2 weeks of Foley catheter decompression. A confirmatory cystogram may be performed before catheter removal to confirm healing of the injury.Vascular Injury. The most severe vascular injuries usually occur in iliac or femoral vessels, either by misplaced sutures in anterior repairs, endoscopic tacker use, or by trocar injury or direct dissection in laparoscopic repairs. In these cases, exsan-guination may be swift. Conversion to an open approach may be necessary, and bleeding should be temporarily controlled with mechanical compression until vascular control is obtained.The most commonly injured vessels in laparoscopic hernia repair include the inferior epigastrics and external iliac arter-ies. Although apparent upon initial approach, these vessels may be obscured during mesh positioning, and tacks or staples may injure them. Oftentimes, due to tamponade effect, injury to the inferior epigastric vessels is not apparent until the adjacent tro-car is removed. If injured, the inferior epigastrics may be ligated with a percutaneous suture passer or endoscopic vessel clips.If the tissue pressure exerted by pneumoperitoneum is greater than an injured vessel’s hydrostatic intraluminal pres-sure, bleeding will not manifest until pneumoperitoneum is released. The presentation of an inferior epigastric vein injury is often delayed because of this effect, and it may result in a significant rectus sheath hematoma. Accordingly, the surgeon should be aware of this intraoperative consideration.Hematomas and SeromasHematomas may present as localized collections or as dif-fuse bruising over the operative site. Injury to spermatic cord vessels may result in a scrotal hematoma. Although they are self-limited, characteristic dark blue discoloration of the entire scrotum may alarm patients. Intermittent warm and cold com-pression aids in resolution. Hematomas may also develop in the incision, retroperitoneum, rectus sheath, and peritoneal cavity. The latter three sites are more frequently associated with lapa-roscopic repair. Bleeding within the peritoneum or preperitoneal space may not be readily apparent on physical examination. For this reason, close monitoring of subjective complaints, vital signs, urine output, and physical parameters is necessary.Seromas are fluid collections that most commonly develop within one week of synthetic mesh repairs. Large hernia sac remnants may fill with physiologic fluid and mimic seromas. Patients often mistake seromas for early recurrence. Treatment consists of reassurance and warm compression to accelerate resolution. To avoid secondary infection, seromas should not be aspirated unless they cause discomfort or they restrict activ-ity for a prolonged time.OUTCOMESThe incidence of recurrence is the most-cited measure of post-operative outcome following inguinal hernia repair. In evaluat-ing the various available techniques, other salient signifiers of outcome include complication rates, operative duration, hospital stay, and quality of life. The following section summarizes the evidence-based outcomes of the various approaches to inguinal hernia repair.Among tissue repairs, the Shouldice operation is the most commonly performed technique, and it is most frequently executed at specialized centers. A 2012 meta-analysis from the Cochrane database demonstrated significantly lower rates of hernia recurrence (OR 0.62, CI 0.45–0.85) in patients undergoing Shouldice operations when compared with other open tissue-based methods.97 In experienced hands, the overall recurrence rate for the Shouldice repair is about 1%.98 Although it is an elegant procedure, its meticulous nature requires significant technical expertise to achieve favorable outcomes, and it is associated with longer operative duration and longer hospital stay. One study found the recurrence rate for Shouldice repairs decreased from 9.4% to 2.5% after surgeons performed the repair six times.99 Compared with mesh repairs, the Shouldice technique resulted in significantly higher rates of recurrence (OR 3.65, CI 1.79–7.47); however, it is the most effective tissue-based repair when mesh is unavailable or contraindicated.97Hernia recurrence is drastically reduced as a result of the Lichtenstein tension-free repair.100 Compared with open elective tissue-based repairs, mesh repair is associated with fewer recur-rences (OR 0.37, CI 0.26–0.51) and with shorter hospital stay and faster return to usual activities.101,102 In a multi-institutional series, 3019 inguinal hernias were repaired using the Lichten-stein technique, with an overall recurrence rate of 0.2%.103 Among other tension-free repairs, the Lichtenstein technique remains the most commonly performed procedure worldwide. Meta-analysis demonstrates no significant differences in out-comes between the Lichtenstein and the Plug and Patch tech-niques; however, intra-abdominal plug migration and erosion into contiguous structures occurs in approximately 6% of cases.101,104,105 The Stoppa technique results in longer operative duration than the Lichtenstein technique. Nevertheless, postop-erative acute pain, chronic pain, and recurrence rates are similar between the two methods.106 Perhaps the most compelling advan-tage of the Lichtenstein technique is that nonexpert surgeons rapidly achieve similar outcomes to their expert counterparts. Guidelines issued by the European Hernia Society recommend the Lichtenstein repair for adults with either unilateral or bilat-eral inguinal hernias as the preferred open technique.102 Com-pared to open approaches, endoscopic primary inguinal hernia repair produces equivalent recurrence rates and improved recov-ery time, pain prevention, and return to normal activities.107 In a study of 168 patients randomized to either TEP or Lichtenstein repair, the 5-year recurrence rates were extremely low in both groups.108,109 Similarly, a study of 200 male patients randomized to either ambulatory TEP or Lichtenstein repair demonstrated no recurrences in either group after one year.110 Because endoscopic surgery requires specialized instruments and longer operative times, its cost is higher than conventional open repair; however, the potential financial benefit of shorter recovery and decreased pain may offset these costs in the long-term.Perhaps the most salient difference between open and endo-scopic techniques is the number of cases needed to develop techni-cal proficiency. In a randomized controlled trial performed by the VA Cooperative Study, two-year recurrence rates were 10.1% in patients undergoing endoscopic repair and 4.9% in those undergo-ing open repair, and the outcomes of endoscopic repairs improved after each surgeon performed at least 250 cases.111 More recently, Lal and colleagues found that surgeons sustained a decrease from 9% to 2.9% in postoperative recurrences after performing 100 TEP operations.112 Other studies also suggest surgeons develop proficiency in these endoscopic techniques after performing 30 67Brunicardi_Ch37_p1599-p1624.indd 162129/01/19 2:04 PM 1622SPECIFIC CONSIDERATIONSPART IIto 100 cases; however, this estimate has decreased precipitously since laparoscopic technique was first introduced.111,113,114Although controversy persists regarding the utility of TEP versus TAPP, reviews to date find no significant differences in operative duration, length of stay, time to recovery, or short-term recurrence rate between the two approaches. In TAPP repair, the risk of intra-abdominal injury is higher than in TEP repair. This finding prompted the IEHS to recommend TAPP should only be attempted by surgeons with sufficient experience.49 A Cochrane systematic review found rates of port-site hernias and visceral injuries were higher for the TAPP technique, while TEP may be associated with a higher rate of conversion to an alternative approach; however, neither finding was sufficiently compelling to recommend one technique over the other.114The frequency with which the aforementioned ingui-nal hernia repair techniques are performed reinforces the importance of broad experience. The authors recommend that surgeons become proficient in several techniques to address dif-ferent manifestations of inguinal hernias. Surgeons should tailor this experience to optimize outcomes for each patient.REFERENCESEntries highlighted in bright blue are key references. 1. National Center for Health Statistics. National Hospital Discharge Survey and National Survey of Ambulatory Surgery, 2010 . Available at: https://www.cdc.gov/nchs/index .htm. Accessed August 4, 2018. 2. Abramson JH, Gofin J, Hopp C, et al. The epidemiology of inguinal hernia. A survey in western Jerusalem. J Epidemiol Community Health. 1978;32(1):59-67. 3. Rutkow IM. Epidemiologic, economic, and sociologic aspects of hernia surgery in the United States in the 1990s. Surg Clin North Am 1998;78(6):941-951, v-vi. 4. Johnson J, Roth JS, Hazey JW, et al. The history of open inguinal hernia repair. Curr Surg. 2004;61(1):49-52. 5. Gil J, Rodriguez JM, Hernandez Aguera Q, et al. The usefulness of international cooperation in the repair of inguinal hernias in Sub-Saharan Africa. World J Surg. 2015;39(11):2622-2629. 6. Shulman AG, Amid PK, Lichtenstein IL. A survey of non-expert surgeons using the open tension-free mesh patch repair for primary inguinal hernias. Int Surg. 1995;80(1):35-36. 7. Spaw AT, Ennis BW, Spaw LP. Laparoscopic hernia repair: the anatomic basis. J Laparoendosc Surg. 1991;1(5):269-277. 8. Scheuermann U, Niebisch S, Lyros O, Jansen-Winkeln B, Gockel I. Transabdominal preperitoneal (TAPP) versus Lichtenstein operation for primary inguinal hernia repair—a systematic review and meta-analysis of randomized controlled trials. BMC Surg. 2017;17(1):55. 9. Fitzgibbons RJ, Jr, Salerno GM, Filipi CJ, Hunter WJ, Watson P. A laparoscopic intraperitoneal onlay mesh technique for the repair of an indirect inguinal hernia. Ann Surg. 1994;219(2):144-156. 10. Toy FK, Moskowitz M, Smoot RT, Jr, et al. Results of a prospective multicenter trial evaluating the ePTFE peritoneal onlay laparoscopic inguinal hernioplasty. J Laparoendosc Surg. 1996;6(6):375-386. 11. Arregui ME, Davis CJ, Yucel O, Nagan RF. Laparoscopic mesh repair of inguinal hernia using a preperitoneal approach: a preliminary report. Surg Laparosc Endosc. 1992;2(1):53-58. 12. Dulucq JL. Treatment of inguinal hernia by insertion of a subperitoneal patch under pre-peritoneoscopy (in French). Chirurgie. 1992;118(1-2):83-85. 13. Burcharth J, Pommergaard HC, Rosenberg J. The inheritance of groin hernia: a systematic review. Hernia. 2013;17(2):183-189. 14. Van Wessem KJ, Simons MP, Plaisier PW, Lange JF. The etiology of indirect inguinal hernias: congenital and/or acquired? Hernia. 2003;7(2):76-79. 15. Weaver KL, Poola AS, Gould JL, Sharp SW, St Peter SD, Holcomb GW 3rd. The risk of developing a symptomatic inguinal hernia in children with an asymptomatic patent processus vaginalis. J Pediatr Surg. 2017;52(1):60-64. 16. Flich J, Alfonso JL, Delgado F, Prado MJ, Cortina P. Inguinal hernia and certain risk factors. Eur J Epidemiol. 1992;8(2):277-282. 17. Lau H, Fang C, Yuen WK, Patil NG. Risk factors for inguinal hernia in adult males: a case-control study. Surgery. 2007;141(2):262-266. 18. Ruhl CE, Everhart JE. Risk factors for inguinal hernia among adults in the US population. Am J Epidemiol. 2007;165(10):1154-1161. 19. Klinge U, Binnebösel M, Mertens PR. Are collagens the culprits in the development of incisional and inguinal hernia disease? Hernia. 2006;10(6):472-477. 20. Franz MG. The biology of hernias and the abdominal wall. Hernia. 2006;10(6):462-471. 21. Ralphs DN, Brain AJ, Grundy DJ, Hobsley M. How accurately can direct and indirect inguinal hernias be distinguished? Br Med J. 1980;280(6220):1039-1040. 22. Cameron AE. Accuracy of clinical diagnosis of direct and indirect inguinal hernia. Br J Surg. 1994;81(2):250. 23. Robinson A, Light D, Kasim A, Nice C. A systematic review and meta-analysis of the role of radiology in the diagnosis of occult inguinal hernia. Surg Endosc. 2013;27(1):11-18. 24. Jamadar DA, Jacobson JA, Morag Y, et al. Sonography of inguinal region hernias. AJR Am J Roentgenol. 2006;187(1): 185-190. 25. Burkhardt JH, Arshanskiy Y, Munson JL, Scholz FJ. Diagnosis of inguinal region hernias with axial CT: the lateral crescent sign and other key findings. Radiographics. 2011;31(2):E1-E12. 26. van den Berg JC, de Valois JC, Go PM, Rosenbusch G. Detection of groin hernia with physical examination, ultrasound, and MRI compared with laparoscopic findings. Invest Radiol. 1999;34(12):739-743. 27. Fitzgibbons RJ, Jr, Giobbie-Hurder A, Gibbs JO, et al. Watch-ful waiting vs repair of inguinal hernia in minimally symp-tomatic men: a randomized clinical trial. JAMA. 2006;295(3): 285-292. 28. Chen T, Zhang Y, Wang H, et al. Emergency inguinal hernia repair under local anesthesia: a 5-year experience in a teaching hospital. BMC Anesthesiol. 2015;16:17. 29. van den Heuvel B, Dwars BJ, Klassen DR, Bonjer HJ. Is surgical repair of an asymptomatic groin hernia appropriate? A review. Hernia. 2011;15(3):251-259. 30. Mizrahi H, Parker MC. Management of asymptomatic inguinal hernia: a systematic review of the evidence. Arch Surg. 2012;147(3):277-281. 31. Thompson JS, Gibbs JO, Reda DJ, et al. Does delaying repair of an asymptomatic hernia have a penalty? Am J Surg. 2008;195(1):89-93. 32. Miserez M, Peeters E, Aufenacker T, et al. Update with level 1 studies of the European Hernia Society guidelines on the treatment of inguinal hernia in adult patients. Hernia. 2014;18(2):151-163. 33. Law NW, Trapnell JE. Does a truss benefit a patient with inguinal hernia? BMJ. 1992;304(6834):1092. 34. Gallegos NC, Dawson J, Jarvis M, Hobsley M. Risk of strangulation in groin hernias. Br J Surg. 1991;78(10): 1171-1173. 35. Nilsson H, Stylianidis G, Haapamäki M, Nilsson E, Nordin P. Mortality after groin hernia surgery. Ann Surg. 2007;245(4):656-660.Brunicardi_Ch37_p1599-p1624.indd 162229/01/19 2:04 PM 1623INGUINAL HERNIASCHAPTER 37 36. Sanchez-Manuel FJ, Lozano-García J, Seco-Gil JL. Antibi-otic prophylaxis for hernia repair. Cochrane Database Syst Rev. 2012;(2):CD003769. 37. Yin Y, Song T, Liao B, Luo Q, Zhou Z. Antibiotic prophylaxis in patients undergoing open mesh repair of inguinal hernia: a meta-analysis. Am Surg. 2012;78(3):359-365. 38. Delikoukos S, Lavant L, Hlias G, Palogos K, Gikas D. The role of hernia sac ligation in postoperative pain in patients with elective tension-free indirect inguinal hernia repair: a prospective randomized study. Hernia. 2007;11(5):425-428. 39. Desarda MP. Inguinal herniorrhaphy with an undetached strip of external oblique aponeurosis: a new approach used in 400 patients. Eur J Surg. 2001;167(6):443-448. 40. Desarda MP. New method of inguinal hernia repair: a new solution. ANZ J Surg. 2001;71(4):241-244. 41. Desarda MP. Physiological repair of inguinal hernia: a new technique (study of 860 patients). Hernia. 2006;10(2):143-146. 42. Amid PK, Shulman AG, Lichtenstein IL. Critical scrutiny of the open “tension-free” hernioplasty. Am J Surg. 1993;165(3):369-371. 43. Gilbert AI. Sutureless repair of inguinal hernia. Am J Surg. 1992;163(3):331-335. 44. Millikan KW, Cummings B, Doolas A. The Millikan modified mesh-plug hernioplasty. Arch Surg. 2003;138(5):525-529; discussion 529-530. 45. Voyles CR, Hamilton BJ, Johnson WD, Kano N. Meta-analysis of laparoscopic inguinal hernia trials favors open hernia repair with preperitoneal mesh prosthesis. Am J Surg. 2002;184(1):6-10. 46. Antunes AA, Dall’oglio M, Crippa A, Srougi M. Inguinal hernia repair with polypropylene mesh during radical retropubic prostatectomy: an easy and practical approach. BJU Int. 2005;96(3):330-333. 47. Lee BC, Rodin DM, Shah KK, Dahl DM. Laparoscopic inguinal hernia repair during laparoscopic radical prostatectomy. BJU Int. 2007;99(3):637-639. 48. Bittner R, Arregui ME, Bisgaard T, et al. Guidelines for laparoscopic (TAPP) and endoscopic (TEP) treatment of inguinal hernia (International Endohernia Society [IEHS]). Surg Endosc. 2011;25(9):2773-2843. 49. Bittner R, Montgomery MA, Arregui E, et al. Update of guidelines on laparoscopic (TAPP) and endoscopic (TEP) treatment of inguinal hernia (International Endohernia Society). Surg Endosc. 2015;29(2):289-321. 50. Waite KE, Herman MA, Doyle PJ. Comparison of robotic versus laparoscopic transabdominal preperitoneal (TAPP) inguinal hernia repair. J Robot Surg. 2016;10(3):239-244. 51. Higgins RM, Frelich MJ, Bosler ME, Gould JC. Cost analysis of robotic versus laparoscopic general surgery procedures. Surg Endosc. 2017;31(1):185-192. 52. Kolachalam R, Dickens E, D’Amico L, et al. Early outcomes of robotic-assisted inguinal hernia repair in obese patients: a multi-institutional, retrospective study. Surg Endosc. 2018;32(1):229-235. 53. Iraniha A, Peloquin J. Long-term quality of life and outcomes following robotic assisted TAPP inguinal hernia repair. J Robot Surg. 2018;12(2):261-269. 54. Pickett LC. Prosthetic choice in open inguinal hernia repair. In: Jacob BP, Ramshaw B, eds. The SAGES Manual of Hernia Repair. New York: Springer; 2013:19-26. 55. Sajid MS, Leaver C, Baig MK, Sains P. Systematic review and meta-analysis of the use of lightweight versus heavy-weight mesh in open inguinal hernia repair. Br J Surg. 2012;99(1):29-37. 56. Sorensen CG, Rosenberg J. The use of sterilized mosquito nets for hernioplasty: a systematic review. Hernia. 2012;16(6): 621-625. 57. Luboga S, Macfarlane SB, von Schreeb J, et al. Increasing access to surgical services in sub-saharan Africa: priorities for national and international agencies recommended by the Bellagio Essential Surgery Group. PLoS Med. 2009;6(12):e1000200. 58. Jacobs DO. Improving surgical services in developing nations: getting to go. World J Surg. 2010;34(11):2509-2510. 59. Earle DB, Mark LA. Prosthetic material in inguinal hernia repair: how do I choose? Surg Clin North Am. 2008;88(1):179-201. 60. Beale EW, Hoxworth RE, Livingston EH, Trussler AP. The role of biologic mesh in abdominal wall reconstruction: a systematic review of the current literature. Am J Surg. 2012;204(4):510-517. 61. Smart NJ, Bloor S. Durability of biologic implants for use in hernia repair: a review. Surg Innov. 2012;19(3):221-229. 62. Campanelli G, Sfeclan C, Cavalli M, Biondi A. Reducing postoperative pain: the use of Tisseel for mesh fixation in inguinal hernia repair. Surg Technol Int. 2012;22:134-139. 63. Fortelny RH, Petter-Puchner AH, Glaser KS, Redl H. Use of fibrin sealant (Tisseel/Tissucol) in hernia repair: a systematic review. Surg Endosc. 2012;26(7):1803-1812. 64. Taylor C, Layani L, Liew V, Ghusn M, Crampton N, White S. Laparoscopic inguinal hernia repair without mesh fixation, early results of a large randomised clinical trial. Surg Endosc. 2008;22(3):757-762. 65. Sajid MS, Ladwa N, Kalra L, McFall M, Baig MK, Sains P. A meta-analysis examining the use of tacker mesh fixation versus glue mesh fixation in laparoscopic inguinal hernia repair. Am J Surg. 2013;206(1):103-111. 66. Morrison JE, Jr, Jacobs VR. Laparoscopic preperitoneal inguinal hernia repair using preformed polyester mesh without fixation: prospective study with 1-year follow-up results in a rural setting. Surg Laparosc Endosc Percutan Tech. 2008;18(1):33-39. 67. Aasvang E, Kehlet H. Surgical management of chronic pain after inguinal hernia repair. Br J Surg. 2005;92(7):795-801. 68. Kehlet H. Chronic pain after groin hernia repair. Br J Surg. 2008;95(2):135-136. 69. Reinpold WM, Nehls J, Eggert A. Nerve management and chronic pain after open inguinal hernia repair: a prospective two phase study. Ann Surg. 2011;254(1):163-168. 70. Alfieri S, Amid PK, Campanelli G, et al. International guide-lines for prevention and management of post-operative chronic pain following inguinal hernia surgery. Hernia. 2011; 15(3):239-249. 71. Callesen T, Beck K, Kehlet H. Prospective study of chronic pain after groin hernia repair. Br J Surg. 1999;86(12):1528-1531. 72. Bay-Nielsen M, Perkins FM, Kehlet H; Danish Hernia Database. Pain and functional impairment 1 year after inguinal herniorrhaphy: a nationwide questionnaire study. Ann Surg. 2001;233(1):1-7. 73. Aasvang EK, Bay-Nielsen M, Kehlet H. Pain and functional impairment 6 years after inguinal herniorrhaphy. Hernia. 2006;10(4):316-321. 74. Aasvang EK, Kehlet H. The effect of mesh removal and selective neurectomy on persistent postherniotomy pain. Ann Surg. 2009;249(2):327-334. 75. Rab M, Ebmer J, Dellon AL. Anatomic variability of the ilioinguinal and genitofemoral nerve: implications for the treatment of groin pain. Plast Reconstr Surg. 2001; 108(6):1618-1623. 76. Loos MJ, Scheltinga MR, Roumen RM. Tailored neurectomy for treatment of postherniorrhaphy inguinal neuralgia. Surgery. 2010;147(2):275-281. 77. Zacest AC, Magill ST, Anderson VC, Burchiel KJ. Long-term outcome following ilioinguinal neurectomy for chronic pain. J Neurosurg. 2010;112(4):784-789. 78. Klaassen Z, Marshall E, Tubbs RS, Louis RG, Jr, Wartmann CT, Loukas M. Anatomy of the ilioinguinal and iliohypogastric Brunicardi_Ch37_p1599-p1624.indd 162329/01/19 2:04 PM 1624SPECIFIC CONSIDERATIONSPART IInerves with observations of their spinal nerve contributions. Clin Anat. 2011;24(4):454-461. 79. Starling JR, Harms BA, Schroeder ME, Eichman PL. Diagnosis and treatment of genitofemoral and ilioinguinal entrapment neuralgia. Surgery. 1987;102(4):581-586. 80. Starling JR, Harms BA. Ilioinguinal, iliohypogastric, and genitofemoral neuralgia. In: Bendavid R, ed. Prostheses and Abdominal Wall Hernia. Austin, TX: RG Landes Co; 1994: 351-356. 81. Amid PK. A 1-stage surgical treatment for postherniorrhaphy neuropathic pain: triple neurectomy and proximal end implantation without mobilization of the cord. Arch Surg. 2002;137(1):100-104. 82. Kim DH, Murovic JA, Tiel RL, Kline DG. Surgical management of 33 ilioinguinal and iliohypogastric neuralgias at Louisiana State University Health Sciences Center. Neurosurgery. 2005;56(5):1013-1020; discussion 1013-1020. 83. Madura JA, Madura JA 2nd, Copper CM, Worth RM. Inguinal neurectomy for inguinal nerve entrapment: an experience with 100 patients. Am J Surg. 2005;189(3):283-287. 84. Amid PK, Chen DC. Surgical treatment of chronic groin and testicular pain after laparoscopic and open preperitoneal inguinal hernia repair. J Am Coll Surg. 2011;213(4):531-536. 85. Chen DC, Hiatt JR, Amid PK. Operative management of refractory neuropathic inguinodynia by a laparoscopic ret-roperitoneal approach. JAMA Surg. 2013;148(10):962-967. 86. Benito-Leon J, Picardo A, Garrido A, Cuberes R. Gabapentin therapy for genitofemoral and ilioinguinal neuralgia. J Neurol. 2001;248(10):907-908. 87. LeBlanc KE, LeBlanc KA. Groin pain in athletes. Hernia. 2003;7(2):68-71. 88. Fong Y, Wantz GE. Prevention of ischemic orchitis during inguinal hernioplasty. Surg Gynecol Obstet. 1992;174(5):399-402. 89. Shin D, Lipshultz LI, Goldstein M, et al. Herniorrhaphy with polypropylene mesh causing inguinal vasal obstruction: a preventable cause of obstructive azoospermia. Ann Surg. 2005;241(4):553-558. 90. Hallén M, Sandblom G, Nordin P, et al. Male infertility after mesh hernia repair: a prospective study. Surgery. 2011; 149(2):179-184. 91. Finley RK, Jr, Miller SF, Jones LM. Elimination of urinary retention following inguinal herniorrhaphy. Am Surg. 1991;57(8):486-488; discussion 488-489. 92. Aeberhard P, Klaiber C, Meyenberg A, Osterwalder A, Tschudi J. Prospective audit of laparoscopic totally extraperitoneal inguinal hernia repair: a multicenter study of the Swiss Association for Laparoscopic and Thoracoscopic Surgery (SALTC). Surg Endosc. 1999;13(11):1115-1120. 93. Dulucq JL, Wintringer P, Mahajna A. Laparoscopic totally extraperitoneal inguinal hernia repair: lessons learned from 3,100 hernia repairs over 15 years. Surg Endosc. 2009;23(3):482-486. 94. Kapiris S, Mavromatis T, Andrikopoulos S, Georgiades C, Floros D, Diamantopoulos G. Laparoscopic transabdominal preperitoneal hernia repair (TAPP): stapling the mesh is not mandatory. J Laparoendosc Adv Surg Tech A. 2009;19(3):419-422. 95. Swadia ND. Laparoscopic totally extra-peritoneal inguinal hernia repair: 9 year’s experience. Hernia. 2011;15(3):273-279. 96. Petros JG, Rimm EB, Robillard RJ, Argy O. Factors influencing postoperative urinary retention in patients undergoing elective inguinal herniorrhaphy. Am J Surg. 1991;161(4):431-433; discussion 434. 97. Amato B, Moja L, Panico S, et al. Shouldice technique versus other open techniques for inguinal hernia repair. Cochrane Database Syst Rev. 2012;(4):CD001543. 98. Glassow F. The Shouldice Hospital technique. Int Surg. 1986;71(3):148-153. 99. Kingsnorth AN, Britton BJ, Morris PJ. Recurrent inguinal hernia after local anaesthetic repair. Br J Surg. 1991;68(4):273-275. 100. Lichtenstein IL, Shulman AG, Amid PK. Use of mesh to prevent recurrence of hernias. Postgrad Med. 1990;87(1):155-158, 160. 101. Scott NW, McCormack K, Graham P, Go PM, Ross SJ, Grant AM. Open mesh versus non-mesh for repair of femoral and inguinal hernia. Cochrane Database Syst Rev. 2002;(4):CD002197. 102. Simons MP, Aufenacker T, Bay-Nielsen M, et al. European Hernia Society guidelines on the treatment of inguinal her-nia in adult patients. Hernia. 2009;13(4):343-403. 103. Shulman AG, Amid PK, Lichtenstein IL. The safety of mesh repair for primary inguinal hernias: results of 3,019 operations from five diverse surgical sources. Am Surg. 1992;58(4):255-257. 104. Kingsnorth AN, Porter CS, Bennett DH, Walker AJ, Hyland ME, Sodergren S. Lichtenstein patch or Perfix plug-and-patch in inguinal hernia: a prospective double-blind randomized controlled trial of short-term outcome. Surgery. 2000;127(3):276-283. 105. Li J, Ji Z, Li Y. Comparison of mesh-plug and Lichtenstein for inguinal hernia repair: a meta-analysis of randomized controlled trials. Hernia. 2012;16(5):541-548. 106. Willaert W, De Bacquer D, Rogiers X, Troisi R, Berrevoet F. Open preperitoneal techniques versus lichtenstein repair for elective inguinal hernias. Cochrane Database Syst Rev. 2012;(7):CD008034. 107. McCormack K, Scott NW, Go PM, Ross S, Grant AM; EU Hernia Trialists Collaboration. Laparoscopic tech-niques versus open techniques for inguinal hernia repair. Cochrane Database Syst Rev. 2003;(1):CD001785. 108. Andersson B, Hallén M, Leveau P, Bergenfelz A, Westerdahl J. Laparoscopic extraperitoneal inguinal hernia repair versus open mesh repair: a prospective randomized controlled trial. Surgery. 2003;133(5):464-472. 109. Hallén M, Bergenfelz A, Westerdahl J. Laparoscopic extraperitoneal inguinal hernia repair versus open mesh repair: long-term follow-up of a randomized controlled trial. Surgery. 2008;143(3):313-317. 110. Lau H, Patil NG, Yuen WK. Day-case endoscopic totally extraperitoneal inguinal hernioplasty versus open Lichtenstein hernioplasty for unilateral primary inguinal hernia in males: a randomized trial. Surg Endosc. 2006;20(1):76-81. 111. Neumayer L, Giobbie-Hurder A, Jonasson O, et al. Open mesh versus laparoscopic mesh repair of inguinal hernia. N Engl J Med. 2004;350(18):1819-1827. 112. Lal P, Kajla RK, Chander J, Ramteke VK. Laparoscopic total extraperitoneal (TEP) inguinal hernia repair: overcoming the learning curve. Surg Endosc. 2004;18(4):642-645. 113. Katkhouda N, Campos GM, Mavor E, Trussler A, Khalil M, Stoppa R. Laparoscopic extraperitoneal inguinal hernia repair. A safe approach based on the understanding of rectus sheath anatomy. Surg Endosc. 1999;13(12):1243-1246. 114. Wake BL, McCormack K, Fraser C, Vale L, Perez J, Grant AM. Transabdominal pre-peritoneal (TAPP) vs totally extraperitoneal (TEP) laparoscopic techniques for ingui-nal hernia repair. Cochrane Database Syst Rev. 2005;(1): CD004703.Brunicardi_Ch37_p1599-p1624.indd 162429/01/19 2:04 PM
Thyroid, Parathyroid, and AdrenalGeeta Lal and Orlo H. Clark 38chapterTHYROIDHistorical BackgroundGoiters (from the Latin guttur, throat), defined as an enlarge-ment of the thyroid, have been recognized since 2700 b.c. even though the thyroid gland was not documented as such until the Renaissance period. In 1619, Hieronymus Fabricius ab Aqua-pendente recognized that goiters arose from the thyroid gland. The term thyroid gland (Greek thyreoeides, shield-shaped) is, however, attributed to Thomas Wharton in his Adenographia (1656). In 1776, the thyroid was classified as a ductless gland by Albrecht von Haller and was thought to have numerous func-tions ranging from lubrication of the larynx to acting as a res-ervoir for blood to provide continuous flow to the brain, and to beautifying women’s necks. Burnt seaweed was considered to be the most effective treatment for goiters.The first accounts of thyroid surgery for the treatment of goiters were given by Roger Frugardi in 1170. In response to failure of medical treatment, two setons were inserted at right angles into the goiter and tightened twice daily until the goiter separated. The open wound was treated with caustic powder and left to heal. However, thyroid surgery continued to be hazardous with prohibitive mortality rates (>40%) until the latter half of the 19th century, when advances in general anesthesia, antisep-sis, and hemostasis enabled surgeons to perform thyroid sur-gery with significantly reduced mortality and morbidity rates. The most notable thyroid surgeons were Emil Theodor Kocher (1841–1917) and C.A. Theodor Billroth (1829–1894), who per-formed thousands of operations with increasingly successful results. However, as more patients survived thyroid operations, new problems and issues became apparent. After total thyroid-ectomy, patients (particularly children) became myxedematous with cretinous features. Myxedema was first effectively treated in 1891 by George Murray using a subcutaneous injection of an extract of sheep’s thyroid, and later, Edward Fox demonstrated that oral therapy was equally effective. In 1909, Kocher was awarded the Nobel Prize for medicine in recognition “for his works on the physiology, pathology, and surgery of the thyroid gland.”EmbryologyThe thyroid gland arises as an outpouching of the primitive foregut around the third week of gestation. It originates at the base of the tongue at the foramen cecum. Endoderm cells in the floor of the pharyngeal anlage thicken to form the medial thyroid anlage (Fig. 38-1) that descends in the neck anterior to structures that form the hyoid bone and larynx. During its descent, the anlage remains connected to the foramen cecum via an epithelial-lined tube known as the thyroglossal duct. The epithelial cells making up the anlage give rise to the thyroid fol-licular cells. The paired lateral anlages originate from the fourth branchial pouch and fuse with the median anlage at approxi-mately the fifth week of gestation. The lateral anlages are neu-roectodermal in origin (ultimobranchial bodies) and provide the calcitonin producing parafollicular or C cells, which thus come to lie in the superoposterior region of the gland. Thyroid fol-licles are initially apparent by 8 weeks, and colloid formation begins by the 11th week of gestation.Developmental AbnormalitiesThyroglossal Duct Cyst and Sinus. Thyroglossal duct cysts are the most commonly encountered congenital cervical anoma-lies. During the fifth week of gestation, the thyroglossal duct lumen starts to obliterate, and the duct disappears by the eighth week of gestation. Rarely, the thyroglossal duct may persist in whole or in part. Thyroglossal duct cysts may occur anywhere along the migratory path of the thyroid, although 80% are found in juxtaposition to the hyoid bone. They are usually asymptom-atic but occasionally become infected by oral bacteria, prompt-ing the patient to seek medical advice. Thyroglossal duct sinuses Thyroid 1625Historical Background / 1625Embryology / 1625Developmental Abnormalities / 1625Thyroid Anatomy / 1627Thyroid Histology / 1629Thyroid Physiology / 1629Evaluation of Patients With Thyroid Disease / 1633Benign Thyroid Disorders / 1634Solitary Thyroid Nodule / 1641Malignant Thyroid Disease / 1645Parathyroid 1663Historical Background / 1663Embryology / 1663Anatomy and Histology / 1664Parathyroid Physiology and Calcium Homeostasis / 1664Hyperparathyroidism / 1665Hypoparathyroidism / 1681Adrenal 1681Historical Background / 1681Embryology / 1681Anatomy / 1682Adrenal Physiology / 1682Disorders of the Adrenal Cortex / 1685Disorders of the Adrenal Medulla / 1693The Adrenal Incidentaloma / 1695Adrenal Insufficiency / 1697Adrenal Surgery / 1698Brunicardi_Ch38_p1625-p1704.indd 162501/03/19 11:20 AM 1626result from infection of the cyst secondary to spontaneous or surgical drainage of the cyst and are accompanied by minor inflammation of the surrounding skin. Histologically, thyroglos-sal duct cysts are lined by pseudostratified ciliated columnar epithelium and squamous epithelium, with heterotopic thyroid tissue present in 20% of cases.The diagnosis usually is established by observing a 1to 2-cm, smooth, well-defined midline neck mass that moves upward with protrusion of the tongue. Routine thyroid imaging is not necessary, although thyroid scintigraphy and ultrasound have been performed to document the presence of normal thy-roid tissue in the neck. Treatment involves the “Sistrunk opera-tion,” which consists of en bloc cystectomy and excision of the central hyoid bone to minimize recurrence. Approximately 1% of thyroglossal duct cysts are found to contain cancer, which is usually papillary (85%). The role of total thyroidectomy in this setting is debated, but it is advised in patients with large tumors, particularly if there are additional thyroid nodules and evidence of cyst wall invasion or lymph node metastases.1 Squamous, Hürthle cell, and anaplastic cancers also have been reported but are rare. Medullary thyroid cancers (MTCs) are, however, not found in thyroglossal duct cysts.Lingual Thyroid. A lingual thyroid represents a failure of the median thyroid anlage to descend normally and may be the only thyroid tissue present. Intervention becomes necessary for obstructive symptoms such as choking, dysphagia, airway obstruction, or hemorrhage. Many of these patients develop hypothyroidism. Medical treatment options include administra-tion of exogenous thyroid hormone to suppress thyroid-stim-ulating hormone (TSH) and radioactive iodine (RAI) ablation followed by hormone replacement. Surgical excision is rarely needed but, if required, should be preceded by an evaluation of normal thyroid tissue in the neck to avoid inadvertently render-ing the patient hypothyroid.Ectopic Thyroid. Normal thyroid tissue may be found any-where in the central neck compartment, including the esopha-gus, trachea, and anterior mediastinum. Thyroid tissue has been observed adjacent to the aortic arch, in the aortopulmonary win-dow, within the upper pericardium, or in the interventricular septum. Often, “tongues” of thyroid tissue are seen to extend off the inferior poles of the gland and are particularly appar-ent in large goiters. Thyroid tissue situated lateral to the carotid sheath and jugular vein, previously termed lateral aberrant thyroid, almost always represents metastatic thyroid cancer in lymph nodes, and not remnants of the lateral anlage that had Buccalcavity1234EndodermMedian thyroiddiverticulumTracheo-esophageal tube1stpharyngealpouch2nd pouch 3rd pouch 4th pouch Figure 38-1. Thyroid embryology—early development of the median thyroid anlage as a pharyngeal pouch. (Reproduced with permission from Cady B, Rossi R: Surgery of the Thyroid and Para-thyroid Glands. Philadelphia, PA: WB Saunders; 1991.)Key Points1 There has been a paradigm shift in the surgical manage-ment of Graves’ disease with increased use of total or near-total thyroidectomy, rather than subtotal thyroidectomy.2 Familial nonmedullary thyroid cancer is increasingly being recognized as a separate entity. Surgeons must be aware of the potential for false-negative fine-needle aspi-ration biopsy in this setting.3 Fine-needle aspiration biopsies are now classified into six groups based on the risk of malignancy associated with each group (Bethesda criteria).4 Encapsulated follicular variants of papillary thyroid can-cers are now designated noninvasive follicular thyroid neoplasm with papillary-like nuclear features (NIFTP).5 Lobectomy or total/near-total thyroidectomy are consid-ered appropriate treatments for low-risk thyroid cancers. Some small papillary thyroid cancers (<1 cm) can be fol-lowed with active surveillance.6 Focused mini-incision parathyroidectomy, after appropri-ate localization, has become the procedure of choice for the treatment of sporadic primary hyperparathyroidism.7 Parathyroidectomy has been shown to improve the clas-sic and the so-called nonspecific symptoms and metabolic complications of primary hyperparathyroidism.8 Normocalcemic hyperparathyroidism is being increasingly recognized; however, there are no definitive guidelines for management.9 Very high calcium and parathyroid hormone levels in a patient with primary hyperparathyroidism should alert the surgeon to the presence of a possible parathyroid carcinoma.10 Subclinical Cushing’s syndrome is characterized by subtle abnormalities in corticosteroid synthesis, and many of its manifestations appear to be treated by adrenalectomy.11 Fine-needle aspiration biopsy has a very limited role in the evaluation of adrenal incidentalomas unless the patient has previously had a cancer and should only be performed after appropriate biochemical studies have been performed to rule out pheochromocytoma.12 Laparoscopic adrenalectomy has become the procedure of choice for excision of most adrenal lesions, except known or suspected cancers.Brunicardi_Ch38_p1625-p1704.indd 162601/03/19 11:20 AM 1627THYROID, PARATHYROID, AND ADRENALCHAPTER 38failed to fuse with the main thyroid, as previously suggested by Crile. Even if not readily apparent on physical examination or ultrasound imaging, the ipsilateral thyroid lobe contains a focus of papillary thyroid cancer (PTC), which may be microscopic.Pyramidal Lobe. Normally the thyroglossal duct atrophies, although it may remain as a fibrous band. In about 50% of indi-viduals, the distal end that connects to the thyroid persists as a pyramidal lobe projecting up from the isthmus, lying just to the left or right of the midline. In the normal individual, the pyra-midal lobe is not palpable, but in disorders resulting in thyroid hypertrophy (e.g., Graves’ disease, diffuse nodular goiter, or lymphocytic thyroiditis), the pyramidal lobe usually is enlarged and palpable.Thyroid AnatomyThe anatomic relations of the thyroid gland and surrounding structures are depicted in Fig. 38-2. The adult thyroid gland is brown in color and firm in consistency and is located posterior to the strap muscles. The normal thyroid gland weighs approx-imately 20 g, but gland weight varies with body weight and iodine intake. The thyroid lobes are located adjacent to the thy-roid cartilage and connected in the midline by an isthmus that is located just inferior to the cricoid cartilage. A pyramidal lobe is present in about 50% of patients. The thyroid lobes extend to the midthyroid cartilage superiorly and lie adjacent to the carotid sheaths and sternocleidomastoid muscles laterally. The strap muscles (sternohyoid, sternothyroid, and superior belly of the omohyoid) are located anteriorly and are innervated by the ansa cervicalis (ansa hypoglossi). The thyroid gland is enveloped by a loosely connecting fascia that is formed from the parti-tion of the deep cervical fascia into anterior and posterior divi-sions. The true capsule of the thyroid is a thin, densely adherent fibrous layer that sends out septa that invaginate into the gland, forming pseudolobules. The thyroid capsule is condensed into the posterior suspensory or Berry’s ligament near the cricoid cartilage and upper tracheal rings.Sup. thyroid a. and v.PyramidallobeCommon carotid a.Common carotid a.Thyroid cartilageInt. jugular v.Int. jugular v.Recurrent laryngeal n.Recurrentlaryngeal n.Vagus n.Vagus n.Vagus n.Arch of aortaThyrocervical trunkInf. thyroid v.Middle thyroid v.Ext. carotid a.Thyroidea ima a.(variable)TracheaSternocleido-mastoid m.Inf. thyroid a.Vertebralv. and a. Thyroid glandStrap musclesABFigure 38-2. Anatomy of the thyroid gland and surrounding structures, viewed anteriorly (A) and in cross-section (B). a. = artery; m. = muscle; n. = nerve; v. = vein.Brunicardi_Ch38_p1625-p1704.indd 162701/03/19 11:20 AM 1628SPECIFIC CONSIDERATIONSPART IIBlood Supply. The superior thyroid arteries arise from the ipsilateral external carotid arteries and divide into anterior and posterior branches at the apices of the thyroid lobes. The infe-rior thyroid arteries arise from the thyrocervical trunk shortly after their origin from the subclavian arteries. The inferior thy-roid arteries travel upward in the neck posterior to the carotid sheath to enter the thyroid lobes at their midpoint. A thyroidea ima artery arises directly from the aorta or innominate in 1% to 4% of individuals to enter the isthmus or replace a missing inferior thyroid artery. The inferior thyroid artery crosses the recurrent laryngeal nerve (RLN), necessitating identification of the RLN before the arterial branches can be ligated. The venous drainage of the thyroid gland occurs via multiple small surface veins, which coalesce to form three sets of veins—the supe-rior, middle, and inferior thyroid veins. The superior thyroid veins run with the superior thyroid arteries bilaterally. The middle vein or veins are the least consistent. The superior and middle veins drain directly into the internal jugular veins. The inferior veins often form a plexus, which drains into the bra-chiocephalic veins.Nerves. The left RLN arises from the vagus nerve where it crosses the aortic arch, loops around the ligamentum arteriosum, and ascends medially in the neck within the tracheoesophageal groove. The right RLN arises from the vagus at its crossing with the right subclavian artery. The nerve usually passes posterior to the artery before ascending in the neck, its course being more oblique than the left RLN. Along their course in the neck, the RLNs may branch, and pass anterior, posterior, or interdigitate with branches of the inferior thyroid artery (Fig. 38-3). The right RLN may be nonrecurrent in 0.5% to 1% of individuals and often is associated with a vascular anomaly. Nonrecurrent left RLNs are rare but have been reported in patients with situs inversus and a right-sided aortic arch. The RLN may branch in its course in the neck, and identification of a small nerve should alert the surgeon to this possibility. Identification of the nerves or their branches often necessitates mobilization of the most lateral and posterior extent of the thyroid gland, the tubercle of Zucker-kandl, at the level of the cricoid cartilage. The last segments of the nerves often course below the tubercle and are closely approximated to the ligament of Berry. Branches of the nerve may traverse the ligament in 25% of individuals and are particu-larly vulnerable to injury at this junction. The RLNs terminate by entering the larynx posterior to the cricothyroid muscle.The RLNs innervate all the intrinsic muscles of the larynx, except the cricothyroid muscles, which are innervated by the external laryngeal nerves. Injury to one RLN leads to paralysis of the ipsilateral vocal cord, which comes to lie in the parame-dian or the abducted position. The paramedian position results in a normal but weak voice, whereas the abducted position leads to a hoarse voice and an ineffective cough. Bilateral RLN injury may lead to airway obstruction, necessitating emergency trache-ostomy, or loss of voice. If both cords come to lie in an abducted position, air movement can occur, but the patient has an ineffec-tive cough and is at increased risk of repeated respiratory tract infections from aspiration.The superior laryngeal nerves also arise from the vagus nerves. After their origin at the base of the skull, these nerves 1) Nerve in tracheoesophageal groove R: 64% L: 77% 4) Nerve between branches of inferior thyroid artery R: 7% L: 67% 2) Nerve lateral to trachea R: 28% L: 17% R: 8% L: 6%5) Nerve posterior to artery R: 53% L: 69% R: 37% L: 24%3) Nerve far anterior6) Nerve anterior to artery7) Artery absent R: 3% L: 1%Figure 38-3. Relationship of recurrent laryngeal nerve to the inferior thyroid artery—the superior parathyroid is characteristically dorsal to the plane of the nerve, whereas the inferior gland is ventral to the nerve.Brunicardi_Ch38_p1625-p1704.indd 162801/03/19 11:20 AM 1629THYROID, PARATHYROID, AND ADRENALCHAPTER 38travel along the internal carotid artery and divide into two branches at the level of the hyoid bone. The internal branch of the superior laryngeal nerve is sensory to the supraglottic larynx. Injury to this nerve is rare in thyroid surgery, but its occurrence may result in aspiration. The external branch of the superior laryngeal nerve lies on the inferior pharyngeal constric-tor muscle and descends alongside the superior thyroid vessels before innervating the cricothyroid muscle. Cernea and col-leagues2 proposed a classification system to describe the rela-tionship of this nerve to the superior thyroid vessels (Fig. 38-4). The type 2a variant, in which the nerve crosses below the tip of the thyroid superior pole, occurs in up to 20% of individuals and places the nerve at a greater risk of injury. Therefore, the superior pole vessels should not be ligated en masse, but should be individually divided, low on the thyroid gland and dissected lateral to the cricothyroid muscle. Injury to this nerve leads to inability to tense the ipsilateral vocal cord and hence difficulty “hitting high notes,” difficulty projecting the voice, and voice fatigue during prolonged speech.Sympathetic innervation of the thyroid gland is provided by fibers from the superior and middle cervical sympathetic ganglia. The fibers enter the gland with the blood vessels and are vasomotor in action. Parasympathetic fibers are derived from the vagus nerve and reach the gland via branches of the laryngeal nerves.Parathyroid Glands. The embryology and anatomy of the parathyroid glands are discussed in detail in the “Parathyroid Gland” section of this chapter. About 85% of individuals have four parathyroid glands that can be found within 1 cm of the junction of the inferior thyroid artery and the RLN. The supe-rior glands are usually located dorsal to the RLN, whereas the inferior glands are usually found ventral to the RLN (Fig. 38-5).Lymphatic System. The thyroid gland is endowed with an extensive network of lymphatics. Intraglandular lymphatic ves-sels connect both thyroid lobes through the isthmus and also drain to perithyroidal structures and lymph nodes. Regional lymph nodes include pretracheal, paratracheal, perithyroidal, RLN, superior mediastinal, retropharyngeal, esophageal, and upper, middle, and lower jugular chain nodes. These lymph nodes can be classified into seven levels as depicted in Fig. 38-6. The central compartment includes nodes located in the area between the two carotid sheaths, whereas nodes lateral to the vessels are present in the lateral compartment. Thyroid can-cers may metastasize to any of these regions, although metas-tases to submaxillary nodes (level I) are rare (<1%). There also can be “skip” metastases to nodes in the lateral ipsilateral neck without central neck nodes.Thyroid HistologyMicroscopically, the thyroid is divided into lobules that contain 20 to 40 follicles (Fig. 38-7). There are about 3 × 106 follicles in the adult male thyroid gland. The follicles are spherical and average 30 μm in diameter. Each follicle is lined by cuboidal epithelial cells and contains a central store of colloid secreted from the epithelial cells under the influence of the pituitary hor-mone TSH. The second group of thyroid secretory cells is the C cells or parafollicular cells, which contain and secrete the hor-mone calcitonin. They are found as individual cells or clumped in small groups in the interfollicular stroma and located in the upper poles of the thyroid lobes.Thyroid PhysiologyIodine Metabolism. The average daily iodine requirement is 0.1 mg, which can be derived from foods such as fish, milk, and eggs or as additives in bread or salt. In the stomach and jeju-num, iodine is rapidly converted to iodide and absorbed into the bloodstream, and from there it is distributed uniformly through-out the extracellular space. Iodide is actively transported into the thyroid follicular cells by an adenosine triphosphate (ATP)–dependent process. The thyroid is the storage site of >90% of the body’s iodine content and accounts for one-third of the plasma iodine loss. The remaining plasma iodine is cleared via renal excretion.Thyroid Hormone Synthesis, Secretion, and Transport.  The synthesis of thyroid hormone consists of several steps 1cmType 1Type 2aType 2bFigure 38-4. Relationship of the external branch of the superior laryngeal nerve and superior thyroid artery originally described by Cernea and colleagues.2 In type 1 anatomy, the nerve crosses the artery ≥1 cm above the superior aspect of the thyroid lobe. In type 2 anatomy, the nerve crosses the artery <1 cm above the thyroid pole (2a) or below (2b) it. (Reproduced with permission from Bliss RD, Gauger PG, Delbridge LW:Surgeon’s approach to the thyroid gland: surgical anatomy and the importance of technique, World J Surg. 2000 Aug;24(8):891-897.)Brunicardi_Ch38_p1625-p1704.indd 162901/03/19 11:20 AM 1630SPECIFIC CONSIDERATIONSPART II(Fig. 38-8). The first, iodide trapping, involves active (ATP-dependent) transport of iodide across the basement mem-brane of the thyrocyte via an intrinsic membrane protein, the sodium/iodine (Na+/I–) symporter. Thyroglobulin (Tg) is a large (660 kDa) glycoprotein, which is present in thyroid follicles and has four tyrosyl residues. The second step in thyroid hormone synthesis involves oxidation of iodide to iodine and iodination of tyrosine residues on Tg, to form monoiodotyrosines (MIT) and diiodotyrosines (DIT). Both processes are catalyzed by thyroid peroxidase (TPO). A recently identified protein, pen-drin, is thought to mediate iodine efflux at the apical membrane. The third step leads to coupling of two DIT molecules to form tetra-iodothyronine or thyroxine (T4), and one DIT molecule with one MIT molecule to form 3,5,3′-triiodothyronine (T3) or 3,3′,5′-triiodothyronine reverse (rT3). When stimulated by TSH, thyrocytes form pseudopodia, which encircle portions of cell membrane containing Tg, which in turn, fuse with enzymecontaining lysosomes. In the fourth step, Tg is hydrolyzed to release free iodothyronines (T3 and T4) and monoand diiodo-tyrosines. The latter are deiodinated in the fifth step to yield iodide, which is reused in the thyrocyte. In the euthyroid state, T4 is produced and released entirely by the thyroid gland, whereas only 20% of the total T3 is produced by the thyroid. Most of the T3 is produced by peripheral deiodination (removal of 5′-iodine from the outer ring) of T4 in the liver, muscles, kidney, and anterior pituitary, a reaction that is catalyzed by 5′-mono-deiodinase. Some T4 is converted to rT3, the metaboli-cally inactive compound, by deiodination of the inner ring of T4. In conditions such as Graves’ disease, toxic multinodular goi-ter, or a stimulated thyroid gland, the proportion of T3 released from the thyroid may be dramatically elevated. Thyroid hor-mones are transported in serum bound to carrier proteins such as T4-binding globulin, T4-binding prealbumin, and albumin. Only a small fraction (0.02%) of thyroid hormone (T3 and T4) is free (unbound) and is the physiologically active component. T3 is the more potent of the two thyroid hormones, although its circulating plasma level is much lower than that of T4. T3 is less tightly bound to protein in the plasma than T4, and so it enters tissues more readily. T3 is three to four times more active than T4 per unit weight, with a half-life of about 1 day, compared to approximately 7 days for T4.The secretion of thyroid hormone is controlled by the hypothalamic-pituitary-thyroid axis (Fig. 38-9). The hypo-thalamus produces a peptide, the thyrotropin-releasing hor-mone (TRH), which stimulates the pituitary to release TSH or thyrotropin. TRH reaches the pituitary via the portovenous circulation. TSH, a 28-kDa glycopeptide, mediates iodide trap-ping, secretion, and release of thyroid hormones, in addition to increasing the cellularity and vascularity of the thyroid gland. The TSH receptor (TSH-R) belongs to a family of G-protein–coupled receptors that have seven transmembrane-spanning domains and use cyclic adenosine monophosphate in the signal-transduction pathway. TSH secretion by the anterior pituitary is also regulated via a negative feedback loop by T4 and T3. Because the pituitary has the ability to convert T4 to T3, the latter is thought to be more important in this feedback control. T3 also inhibits the release of TRH.The thyroid gland also is capable of autoregulation, which allows it to modify its function independent of TSH. As an adap-tation to low iodide intake, the gland preferentially synthesizes Lower parathyroidUpper parathyroidInt. jugular v.Recurrent laryngeal n.ThyroidInferior thyroid a.Common carotid a. Figure 38-5. Relationship of the parathyroids to the recurrent laryngeal nerve. a. = artery; v. = vein.Brunicardi_Ch38_p1625-p1704.indd 163001/03/19 11:20 AM 1631THYROID, PARATHYROID, AND ADRENALCHAPTER 38T3 rather than T4, thereby increasing the efficiency of secreted hormone. In situations of iodine excess, iodide transport, per-oxide generation, and synthesis and secretion of thyroid hor-mones are inhibited. Excessively large doses of iodide may lead to initial increased organification, followed by suppression, a phenomenon called the Wolff-Chaikoff effect. Epinephrine and human chorionic gonadotropin hormones stimulate thyroid hormone production. Thus, elevated thyroid hormone levels are found in pregnancy and gynecologic malignancies such as hydatidiform mole. In contrast, glucocorticoids inhibit thyroid hormone production. In severely ill patients, peripheral thyroid hormones may be reduced, without a compensatory increase in TSH levels, giving rise to the euthyroid sick syndrome.Thyroid Hormone Function. Free thyroid hormone enters the cell membrane by diffusion or by specific carriers and is car-ried to the nuclear membrane by binding to specific proteins. T4 is deiodinated to T3 and enters the nucleus via active trans-port, where it binds to the thyroid hormone receptor. The T3 receptor is similar to the nuclear receptors for glucocorticoids, mineralocorticoids, estrogens, vitamin D, and retinoic acid. In humans, two types of T3 receptor genes (α and β) are located on chromosomes 3 and 17. Thyroid receptor expression depends on peripheral concentrations of thyroid hormones and is tissue specific—the α form is abundant in the central nervous sys-tem, whereas the β form predominates in the liver. Each gene product has a ligand-independent, amino-terminal domain; IIVVIIIIIIIVVITrapezius m.Sternocleidomastoid m.Central neck nodesUpper jugular nodesSubmaxillary nodesParotidMiddle jugular nodesAnterior mediastinalnodesPosteriortriangleLower jugular nodesExternaljugularnodeSternocleido-mastoid m.Spinal accessory n.Jugulodigastric nodeDeep lateral nodesIntercalatednodeTransversecervical chainof nodesDigastric m.Mandibular &submandibularnodesSubmental nodeHyoidInternal jugularchain of nodesStrap muscleSuperior thyroid nodesAnterior superficialcervical nodesSupra-clavicular nodes ABFigure 38-6. A and B. Lymph nodes in the neck can be divided into six regions. Upper mediastinal nodes constitute level VII. m. = muscle; n. = nerve.Brunicardi_Ch38_p1625-p1704.indd 163101/03/19 11:20 AM 1632SPECIFIC CONSIDERATIONSPART IIa ligand-binding, carboxy-terminal domain; and centrally located DNA-binding regions. Binding of thyroid hormone leads to the transcription and translation of specific hormone-responsive genes.Thyroid hormones affect almost every system in the body. They are important for fetal brain development and skeletal mat-uration. T3 increases oxygen consumption, basal metabolic rate, and heat production by stimulation of Na+/K+ ATPase in various tissues. It also has positive inotropic and chronotropic effects on the heart by increasing transcription of the Ca2+ ATPase in the sarcoplasmic reticulum and increasing levels of β-adrenergic receptors and concentration of G proteins. Myocardial α recep-tors are decreased, and actions of catecholamines are amplified. Thyroid hormones are responsible for maintaining the normal hypoxic and hypercapnic drive in the respiratory center of the brain. They also increase gastrointestinal (GI) motility, leading to diarrhea in hyperthyroidism and constipation in hypothyroid-ism. Thyroid hormones also increase bone and protein turnover H2O2 GenerationIodinationDifferentiationGrowthHormone synthesisCREBCREMPAX-8TTF-1TTF-2XXXXXIP3PKCDAGPKAPIP2ATPcAMPPLCGqGSGIACTSHRTSHIGF-1 RIGF-1 NISIodide uptakeMITDITT3T4T3T4HydrolysisNADP+NADPHH2O2H2O22O2TPOTgTgTPOI or HOICouplingOrganificationMITDITMITDITT3T4DehalogenaseI–I–Figure 38-8. Thyroid follicular cell showing the major signaling pathways involved in thyroid cell growth and function and key steps in thy-roid hormone synthesis. The basal membrane of the cell in contact with the circulation and its apical surface contact the thyroid follicle. Thy-roid hormone synthesis is initiated by the binding of thyroid-stimulating hormone (TSH) to the TSH receptor (TSHR), a G-protein–coupled transmembrane receptor, on the basal membrane. Activation leads to an increase in cyclic adenosine monophosphate (cAMP), phosphorylation of protein kinase A (PKA), and activation of target cytosolic and nuclear proteins. The protein kinase C (PKC) pathway is stimulated at higher doses of TSH. Iodide is actively transported into the cell via the Na/I symporter (NIS) and flows down an electrical gradient to the apical membrane. There, thyroid peroxidase (TPO) oxidizes iodide and iodinated tyrosyl residues on thyroglobulin (Tg) in the presence of peroxide (H2O2). Monoand diiodotyrosyl (MIT, DIT) residues are also coupled to form T4 and T3 by TPO. Thyroglobulin carrying T4 and T3 is then internalized by pinocytosis and digested in lysosomes. Thyroid hormone is released into the circulation, while MIT and DIT are deiodinated and recycled. ATP = adenosine triphosphate; CREB = cAMP response element binding protein; CREM = cAMP response element modulator; DAG = diacylglycerol; IGF-1 = insulin-like growth factor 1; IP3 = inositol-3-phosphate; NADP+ = nicotinamide adenine dinucleotide phosphate, oxidized form; NADPH = nicotinamide adenine dinucleotide phosphate; PIP2 = phosphatidylinositol; PLC = phospholipase C; T3 = 3,5′,3-triiodothyronine; T4 = thyroxine. (Reproduced with permission from Kopp P: Pendred’s syndrome and genetic defects in thyroid hormone synthesis, Rev Endocr Metab Disord. 2000 Jan;1(1-2):109-121.)Figure 38-7. Normal thyroid histology—follicular cells surround colloid.Brunicardi_Ch38_p1625-p1704.indd 163201/03/19 11:20 AM 1633THYROID, PARATHYROID, AND ADRENALCHAPTER 38and the speed of muscle contraction and relaxation. They also increase glycogenolysis, hepatic gluconeogenesis, intestinal glucose absorption, and cholesterol synthesis and degradation.Evaluation of Patients With Thyroid DiseaseTests of Thyroid Function. A multitude of different tests are available to evaluate thyroid function. No single test is sufficient to assess thyroid function in all situations, and the results must be interpreted in the context of the patient’s clinical condition. TSH is the only test necessary in most patients with thyroid nodules that clinically appear to be euthyroid.Serum Thyroid-Stimulating Hormone (Normal 0.5–5 μU/mL)  The tests for serum TSH are based on the following principle: monoclonal TSH antibodies are bound to a solid matrix and bind serum TSH. A second monoclonal antibody binds to a separate epitope on TSH and is labeled with radioisotope, enzyme, or fluorescent tag. Therefore, the amount of serum TSH is propor-tional to the amount of bound secondary antibody (immunomet-ric assay). Serum TSH levels reflect the ability of the anterior pituitary to detect free T4 levels. There is an inverse relation-ship between the free T4 level and the logarithm of the TSH concentration—small changes in free T4 lead to a large shift in TSH levels. The ultrasensitive TSH assay has become the most sensitive and specific test for the diagnosis of hyperand hypo-thyroidism and for optimizing T4 therapy.Total T4 (Reference Range 55–150 nmol/L) and T3 (Reference Range 1.5–3.5 nmol/L) Total T4 and T3 levels are measured by radioimmunoassay and measure both the free and bound components of the hormones. Total T4 levels reflect the output from the thyroid gland, whereas T3 levels in the nonstimulated thyroid gland are more indicative of peripheral thyroid hor-mone metabolism, and are, therefore, not generally suitable as a general screening test. Total T4 levels are increased not only in hyperthyroid patients, but also in those with elevated Tg levels secondary to pregnancy, estrogen/progesterone use, or congeni-tal diseases. Similarly, total T4 levels decrease in hypothyroidism and in patients with decreased Tg levels due to anabolic steroid use and protein-losing disorders like nephrotic syndrome. Indi-viduals with these latter disorders may be euthyroid if their free T4 levels are normal. Measurement of total T3 levels is impor-tant in clinically hyperthyroid patients with normal T4 levels, who may have T3 thyrotoxicosis. As discussed previously in “Thyroid Hormone Synthesis, Secretion, and Transport,” total T3 levels often are increased in early hypothyroidism.Free T4 (Reference Range 12–28 pmol/L) and Free T3 (3–9 pmol/L) These radioimmunoassay-based tests are a sensitive and accurate measurement of biologically active thy-roid hormone. Free T4 estimates are not performed as a routine screening tool in thyroid disease. Use of this test is confined to cases of early hyperthyroidism in which total T4 levels may be normal but free T4 levels are raised. In patients with end-organ resistance to T4 (Refetoff’s syndrome), T4 levels are increased, but TSH levels usually are normal. Free T3 is most useful in con-firming the diagnosis of early hyperthyroidism, in which levels of free T4 and free T3 rise before total T4 and T3. Free T4 levels may also be measured indirectly using the T3-resin uptake test. If free T4 levels are increased, fewer hormone binding sites are available for binding radiolabeled T3 that has been added to the patient’s serum. Therefore, more T3 binds with an ion-exchange resin, and the T3-resin uptake is increased.Thyrotropin-Releasing Hormone This test is useful to evalu-ate pituitary TSH secretory function and is performed by admin-istering 500 μg of TRH intravenously and measuring TSH levels after 30 and 60 minutes. In a normal individual, TSH levels should increase at least 6 μIU/mL from the baseline. This test also was previously used to assess patients with borderline hyperthyroidism but has largely been replaced by sensitive TSH assays for this purpose.Thyroid Antibodies Thyroid antibodies include anti-Tg, anti-microsomal, or anti-TPO and thyroid-stimulating immuno-globulin (TSI). Anti-Tg and anti-TPO antibody levels do not determine thyroid function, but rather indicate the underlying disorder, usually an autoimmune thyroiditis. About 80% of patients with Hashimoto’s thyroiditis have elevated thyroid anti-body levels; however, levels may also be increased in patients with Graves’ disease, multinodular goiter, and occasionally, thyroid neoplasms.Serum Thyroglobulin Tg is only made by normal or abnormal thyroid tissue. It normally is not released into the circulation in large amounts but increases dramatically in destructive pro-cesses of the thyroid gland, such as thyroiditis, or overactive states such as Graves’ disease and toxic multinodular goiter. The most important use for serum Tg levels is in monitoring patients with differentiated thyroid cancer for recurrence, partic-ularly after total thyroidectomy and RAI ablation. Elevated anti-Tg antibodies can interfere with the accuracy of serum Tg levels and should always be measured when interpreting Tg levels.ThyroidPortalsystemHypothalamusTRHTissueTSH++T4T4T4T3T3T3––II“Free”Figure 38-9. Hypothalamic-pituitary-thyroid hormone axis. In both the hypothalamus and pituitary, 3,5′,3-triiodothyronine (T3) is primarily responsible for inhibition of thyrotropin-releasing hor-mone (TRH) and thyroid-stimulating hormone (TSH) secretion. T4 = thyroxine. (Reproduced with permission from Greenspan FS, Gardner D: Basic and Clinical Endocrinology, 6th ed. New York, NY: McGraw-Hill Education; 2001.)Brunicardi_Ch38_p1625-p1704.indd 163301/03/19 11:20 AM 1634SPECIFIC CONSIDERATIONSPART IISerum Calcitonin (0–4 pg/mL Basal) This 32-amino-acid polypeptide is secreted by the C cells and functions to lower serum calcium levels, although in humans, it has only minimal physiologic effects. It is also a sensitive marker of MTC.Thyroid Imaging Radionuclide Imaging Both iodine-123 (123I) and iodine-131 (131I) are used to image the thyroid gland. The former emits low-dose radiation, has a half-life of 12 to 14 hours, and is used to image lingual thyroids or goiters. In contrast, 131I has a half-life of 8 to 10 days and leads to higher-dose radiation expo-sure. Therefore, this isotope is used to screen and treat patients with differentiated thyroid cancers for metastatic disease. The images obtained by these studies provide information not only about the size and shape of the gland, but also the distribution of functional activity. Areas that trap less radioactivity than the surrounding gland are termed cold (Fig. 38-10), whereas areas that demonstrate increased activity are termed hot. The risk of malignancy is higher in “cold” lesions (20%) compared to “hot” or “warm” lesions (<5%). Technetium Tc 99m pertech-netate (99mTc) is taken up by the thyroid gland and is increas-ingly being used for thyroid evaluation. This isotope is taken up by the mitochondria, but is not organified. It also has the advantage of having a shorter half-life and minimizes radiation exposure. It is particularly sensitive for nodal metastases. More recently, 18F-fluorodeoxyglucose (FDG) positron emission tomography (PET) combined with computed tomography (CT) is being increasingly used to screen for metastases in patients with thyroid cancer in whom other imaging studies are nega-tive. PET scans are not routinely used in the evaluation of thy-roid nodules; however, they may show clinically occult thyroid lesions. There are several recent reports of rates of malignancy in these lesions ranging from 14% to 63%. These incidentally Figure 38-10. Radioactive iodine scan of the thyroid, with the arrow showing an area of decreased uptake, a cold nodule.discovered nodules should be worked up by ultrasound and fine-needle aspiration biopsy (FNAB).Ultrasound Ultrasound is an excellent noninvasive and por-table imaging study of the thyroid gland with the added advan-tage of no radiation exposure. It is helpful in the evaluation of thyroid nodules, distinguishing solid from cystic ones, and pro-viding information about size and multicentricity. In addition, characteristics such as echotexture, shape, borders and presence of calcifications, and vascularity can provide useful information regarding risk of malignancy. Ultrasound is also especially help-ful for assessing cervical lymphadenopathy (Fig. 38-11) and to guide FNAB. An experienced ultrasonographer is necessary for the best results.Computed Tomography/Magnetic Resonance Imaging Scan CT and magnetic resonance imaging (MRI) studies provide excellent imaging of the thyroid gland and adjacent nodes and are particularly useful in evaluating the extent of large, fixed, or substernal goiters (which cannot be evaluated by ultrasound) and their relationship to the airway and vascular structures. Noncontrast CT scans should be obtained for patients who are likely to require subsequent RAI therapy. If contrast is necessary, therapy needs to be delayed by several months. Combined PET-CT scans are increasingly being used for Tg-positive, RAI-negative tumors.Benign Thyroid DisordersHyperthyroidism. The clinical manifestations of hyperthy-roidism result from an excess of circulating thyroid hormone. Hyperthyroidism may arise from a number of conditions that are listed in Table 38-1. It is important to distinguish disorders such as Graves’ disease and toxic nodular goiters that result from increased production of thyroid hormone from those dis-orders that lead to a release of stored hormone from injury to the thyroid gland (thyroiditis) or from other nonthyroid gland–related conditions. The former disorders lead to an increase in RAI uptake (RAIU), whereas the latter group is characterized by low RAIU. Of these disorders, Graves’ disease, toxic mul-tinodular goiter, and solitary toxic nodule are most relevant to the surgeon.Diffuse Toxic Goiter (Graves’ Disease) Although originally described by the Welsh physician Caleb Parry in a posthumous article in 1825, this disorder is known as Graves’ disease after Robert Graves, an Irish physician who described three patients in 1835. Graves’ disease is by far the most common cause of hyperthyroidism in North America, accounting for 60% to 80% of cases. It is an autoimmune disease with a strong famil-ial predisposition, female preponderance (5:1), and peak inci-dence between the ages of 40 and 60 years. Graves’ disease is characterized by thyrotoxicosis, diffuse goiter, and extrathy-roidal conditions including ophthalmopathy, dermopathy (pre-tibial myxedema), thyroid acropachy, gynecomastia, and other manifestations.Etiology, Pathogenesis, and Pathology. The exact etiology of the initiation of the autoimmune process in Graves’ disease is not known. However, conditions such as the postpartum state, iodine excess, lithium therapy, and bacterial and viral infections have been suggested as possible triggers. Genetic factors also play a role, as haplotyping studies indicate that Graves’ disease is associated with certain human leukocyte antigen (HLA) hap-lotypes, including HLA-B8, HLA-DR3, and HLADQA1*0501 in Caucasian patients, whereas HLA-DRB1*0701 is protective Brunicardi_Ch38_p1625-p1704.indd 163401/03/19 11:20 AM 1635THYROID, PARATHYROID, AND ADRENALCHAPTER 38against it. Polymorphisms of the cytotoxic T-lymphocyte anti-gen 4 (CTLA-4) gene also have been associated with Graves’ disease development. CD40 has also been recognized as a Graves’ susceptibility gene. It has an important role in B-cell function and its upregulation leads to a lower threshold for B-cell activation. It can also lead to enhanced IL-6 secretion and activation of T-cells in thyrocytes leading to a local inflam-matory response. Other susceptibility genes include PTPN22 (encodes the lymphoid tyrosine phosphatase) and CD25, which encodes for the interleukin-2 receptor α-chain (IL-2Rα).3 Once initiated, the inflammatory process causes sensitized T-helper lymphocytes to stimulate B lymphocytes, which produce anti-bodies directed against the thyroid hormone receptor. TSIs or antibodies that stimulate the TSH-R, as well as TSH-binding inhibiting immunoglobulins or antibodies, have been described. The thyroid-stimulating antibodies stimulate the thyrocytes to grow and synthesize excess thyroid hormone, which is a hall-mark of Graves’ disease. Graves’ disease also is associated with other autoimmune conditions such as type 1 diabetes mellitus, Addison’s disease, pernicious anemia, and myasthenia gravis.Macroscopically, the thyroid gland in patients with Graves’ disease is diffusely and smoothly enlarged, with a concomitant increase in vascularity. Microscopically, the gland is hyperplastic, and the epithelium is columnar with minimal colloid present. The nuclei exhibit mitosis, and papillary pro-jections of hyperplastic epithelium are common. There may be aggregates of lymphoid tissue, and vascularity is markedly increased.Clinical Features. The clinical manifestations of Graves’ disease can be divided into those related to hyperthyroidism and those specific to Graves’ disease. Hyperthyroid symp-toms include heat intolerance, increased sweating and thirst, and weight loss despite adequate caloric intake. Symptoms of increased adrenergic stimulation include palpitations, nervous-ness, fatigue, emotional lability, hyperkinesis, and tremors. The most common GI symptoms include increased frequency of bowel movements and diarrhea. Female patients often develop amenorrhea, decreased fertility, and an increased incidence of miscarriages. Children experience rapid growth with early bone maturation, whereas older patients may present with cardiovas-cular complications such as atrial fibrillation and congestive heart failure.On physical examination, weight loss and facial flush-ing may be evident. The skin is warm and moist, and African American patients often note darkening of their skin. Tachycar-dia or atrial fibrillation is present, with cutaneous vasodilation leading to a widening of the pulse pressure and a rapid falloff in the transmitted pulse wave (collapsing pulse). A fine tremor, muscle wasting, and proximal muscle group weakness with hyperactive tendon reflexes often are present.Approximately 50% of patients with Graves’ disease also develop clinically evident ophthalmopathy, and dermopathy occurs in 1% to 2% of patients. It is characterized by deposi-tion of glycosaminoglycans, leading to thickened skin in the pretibial region and dorsum of the foot (Fig. 38-12). Eye symp-toms include lid lag (von Graefe’s sign), spasm of the upper eyelid revealing the sclera above the corneoscleral limbus (Dal-rymple’s sign), and a prominent stare, due to catecholamine excess. True infiltrative eye disease results in periorbital edema, conjunctival swelling and congestion (chemosis), proptosis, limitation of upward and lateral gaze (from involvement of the inferior and medial rectus muscles, respectively), keratitis, and even blindness due to optic nerve involvement. The etiology of Graves’ ophthalmopathy is not completely known; however, Figure 38-11. Thyroid ultrasound showing a lymph node (arrow) along the carotid artery.Table 38-1Differential diagnosis of hyperthyroidismINCREASED HORMONE SYNTHESIS (INCREASED RAIU)RELEASE OF PREFORMED HORMONE (DECREASED RAIU)Graves’ disease (diffuse toxic goiter)Toxic multinodular goiterToxic adenomaDrug induced—amiodarone, iodineThyroid cancerStruma ovariiHydatidiform moleTSH-secreting pituitary adenomaThyroiditis—acute phase of Hashimoto’s thyroiditis, subacute thyroiditisFactitious (iatrogenic) thyrotoxicosis“Hamburger thyrotoxicosis”RAIU = radioactive iodine uptake; TSH = thyroid-stimulating hormone.Brunicardi_Ch38_p1625-p1704.indd 163501/03/19 11:20 AM 1636SPECIFIC CONSIDERATIONSPART IIorbital fibroblasts and muscles are thought to share a common antigen, the TSH-R. Ophthalmopathy is thought to result from inflammation caused by cytokines released from sensitized killer T lymphocytes and cytotoxic antibodies. Gynecomas-tia is common in young men. Rare bony involvement leads to subperiosteal bone formation and swelling in the metacarpals (thyroid acropachy). Onycholysis, or separation of fingernails from their beds, is a commonly observed finding. On physical examination, the thyroid usually is diffusely and symmetrically enlarged, as evidenced by an enlarged pyramidal lobe. There may be an overlying bruit or thrill over the thyroid gland and a loud venous hum in the supraclavicular space.Diagnostic Tests. The diagnosis of hyperthyroidism is made by a suppressed TSH with or without an elevated free T4 or T3 level. If eye signs are present, other tests are generally not needed. However, in the absence of eye findings, an 123I uptake and scan should be performed. An elevated uptake, with a dif-fusely enlarged gland, confirms the diagnosis of Graves’ disease and helps to differentiate it from other causes of hyperthyroid-ism. Technetium scintigraphy (using pertechnetate, which is trapped by the thyroid, but not organified) can also be used to determine etiology. While technetium scans result in low range of normal uptake and high background activity, total-body radi-ation exposure is less than that of 123I scans. If free T4 levels are normal, free T3 levels should be determined, as they often are elevated in early Graves’ disease or toxic nodules (T3 toxi-cosis). Anti-Tg and anti-TPO antibodies are elevated in up to 75% of patients but are not specific. Elevated TSH-R or thyroidstimulating antibodies (TSAb) are diagnostic of Graves’ disease and are increased in about 90% of patients. CT or MRI scans of the orbits are useful in evaluating Graves’ ophthalmopathy.Treatment. Graves’ disease may be treated by any of three treatment modalities: antithyroid drugs, thyroid ablation with radioactive 131I, and thyroidectomy. The choice of treatment depends on several factors, as discussed in the following sections.Antithyroid Drugs Antithyroid medications generally are administered in preparation for RAI ablation or surgery. The drugs commonly used are propylthiouracil (PTU, 100 to 300 mg three times daily) and methimazole (10 to 30 mg three times daily, then once daily). Methimazole has a longer half-life and can be dosed once daily. Both drugs reduce thyroid hormone production by inhibiting the organic binding of iodine and the coupling of iodotyrosines (mediated by TPO). In addition, PTU also inhibits the peripheral conversion of T4 to T3, making it useful for the treatment of thyroid storm. Both drugs can cross the placenta, inhibiting fetal thyroid function, and are excreted in breast milk, although PTU has a lower risk of transplacental transfer. Methimazole also has been associated with congeni-tal aplasia; therefore, PTU is preferred in pregnant and breast-feeding women. Side effects of treatment include reversible granulocytopenia, skin rashes, fever, peripheral neuritis, poly-arteritis, vasculitis, hepatitis, and, rarely, agranulocytosis and aplastic anemia. Patients should be monitored for these pos-sible complications and should always be warned to stop PTU or methimazole immediately and seek medical advice should they develop a sore throat or fever. Treatment of agranulocy-tosis involves admission to the hospital, discontinuation of the drug, and broad-spectrum antibiotic therapy. Surgery should be postponed until the granulocyte count reaches 1000 cells/mm3.The dose of antithyroid medication is titrated as needed in accordance with TSH and T4 levels. Most patients have improved symptoms in 2 weeks and become euthyroid in about 6 weeks. Some physicians use the block-replace regimen, by adding T4 (0.05 to 0.10 mg) to prevent hypothyroidism and suppress TSH secretion, because some, but not all, studies sug-gest that this reduces recurrence rates. The length of therapy is debated. Treatment with antithyroid medications is associated ABFigure 38-12. A. Graves’ ophthalmopathy and (B) pretibial myx-edema. This patient demonstrates exophthalmos, proptosis, perior-bital swelling, congestion, and edema of the conjunctiva.Brunicardi_Ch38_p1625-p1704.indd 163601/03/19 11:20 AM 1637THYROID, PARATHYROID, AND ADRENALCHAPTER 38with a high relapse rate when these drugs are discontinued, with 40% to 80% of patients developing recurrent disease after a 1to 2-year course. Patients with small glands are less likely to recur, so that treatment for curative intent is reserved for patients with (a) small, nontoxic goiters less than 40 g; (b) mildly elevated thyroid hormone levels; (c) negative or low or titers of thyroid hormone receptor antibodies; and (d) rapid decrease in gland size with antithyroid medications. The catecholamine response of thyrotoxicosis can be alleviated by administering β-blocking agents. β-Blockade should be considered in all patients with symptomatic thyrotoxicosis and is recommended for elderly patients, those with coexistent cardiac disease, and patients with resting heart rates >90 bpm. These drugs have the added effect of decreasing the peripheral conversion of T4 to T3. Pro-pranolol is the most commonly prescribed medication in doses of about 20 to 40 mg four times daily. Higher doses are some-times required due to increased clearance of the medication. Caution should be exercised in patients with asthma. Calcium channel blockers are useful for rate control in patients in whom β-blockers are contraindicated.Radioactive Iodine Therapy (131I) RAI forms the mainstay of Graves’ disease treatment in North America. The major advan-tages of this treatment are the avoidance of a surgical procedure and its concomitant risks, reduced overall treatment costs, and ease of treatment. Antithyroid drugs are given until the patient is euthyroid and then discontinued to maximize drug uptake. The 131I dose is calculated after a preliminary scan and usu-ally consists of 8 to 12 mCi administered orally. After standard treatment with RAI, most patients become euthyroid within 2 months. However, only about 50% of patients treated with RAI are euthyroid 6 months after treatment, and the remain-ing are still hyperthyroid or already hypothyroid.4 After 1 year, about 2.5% of patients develop hypothyroidism each year. RAI also has been documented to lead to progression of Graves’ oph-thalmopathy (33% after RAI compared to 16% after surgery), and ophthalmopathy is more common in smokers. Although there is no evidence of long-term problems with infertility, and overall cancer incidence rates are unchanged, there is a small increased risk of nodular goiter, thyroid cancer,5 and hyperpara-thyroidism (HPT)6 in patients who have been treated with RAI. Patients treated with RAI have an unexplained increase in their overall and cardiovascular mortality rates when compared to the general population.RAI therapy is therefore most often used in older patients with small or moderate-sized goiters, those who have relapsed after medical or surgical therapy, and those in whom antithyroid drugs or surgery are contraindicated. Absolute contraindications to RAI include women who are pregnant (or planning pregnancy within 6 months of treatment) or breastfeeding. Relative contra-indications include young patients (i.e., especially children and adolescents), those with thyroid nodules, and those with oph-thalmopathy. Lack of access to a high-volume thyroid surgeon is also a consideration. The higher the initial dose of 131I, the earlier the onset and the higher the incidence of hypothyroidism.Surgical Treatment In North America, surgery is recom-mended when RAI is contraindicated as in patients who (a) have confirmed cancer or suspicious thyroid nodules, (b) are young, (c) desire to conceive soon (<6 months) after treatment, (d) have had severe reactions to antithyroid medications, (e) have large goiters (>80 g) causing compressive symptoms, and (f) are reluctant to undergo RAI therapy. Relative indications for thyroidectomy include patients, particularly smokers, with mod-erate to severe Graves’ ophthalmopathy, those desiring rapid control of hyperthyroidism with a chance of being euthyroid, and those demonstrating poor compliance to antithyroid medica-tions. Pregnancy is also a relative contraindication, and surgery should be used only when rapid control is needed and antithy-roid medications cannot be used. Surgery is best performed in the second trimester. The goal of thyroidectomy for Graves’ disease should be the complete and permanent control of the disease with minimal morbidity. Patients should be rendered euthyroid before operation with antithyroid drugs that should be continued up to the day of surgery. Lugol’s iodide solution or saturated potassium iodide generally is administered beginning 7 to 10 days preoperatively (three drops twice daily) to reduce vascularity of the gland and decrease the risk of precipitating thyroid storm. The major action of iodine in this situation is to inhibit release of thyroid hormone. If it is not possible to render the patient euthyroid prior to surgery (if the surgery is urgent or the patient is allergic to antithyroid medications), the patient can be prepared with β-blockade and potassium iodide alone. Steroids can be a useful adjunct in this situation.The extent of thyroidectomy to be performed used to be determined by the desired outcome (risk of recurrence vs. euthy-roidism) and surgeon experience. In patients with coexistent thyroid cancer and those who refused RAI therapy or had severe ophthalmopathy or life-threatening reactions to antithyroid medications (vasculitis, agranulocytosis, or liver failure), total or near-total thyroidectomy was recommended. Ophthalmopa-thy has been demonstrated to stabilize or improve in most patients after total thyroidectomy, presumably from removal of the antigenic stimulus. A subtotal thyroidectomy, leaving a 4to 7-g remnant, was recommended for all remaining patients. Dur-ing subtotal thyroidectomy, remnant tissue may be left on each side (bilateral subtotal thyroidectomy), or a total lobectomy can be performed on one side with a subtotal thyroidectomy on the other side (Hartley-Dunhill procedure). Results were similar with either procedure, but the latter procedure was theoretically associated with fewer complications and requires reentering only one side of the neck should recurrence require reoperation. Most studies, however, show no difference in the rates of com-plications with either approach, although patients undergoing a total resection had higher rates of temporary hypoparathyroid-ism. However, patients treated with subtotal thyroidectomy are prone to recurrence, the rates of which are dependent on rem-nant size. Based on the current evidence, recently revised guide-lines from the American Thyroid Association (ATA) recommend total or near-total thyroidectomy as the procedure of choice for the surgical management of Graves’ disease.7 Recurrent thyrotoxicosis usually is managed by radioiodine treatment.Toxic Multinodular Goiter Toxic multinodular goiters usu-ally occur in older individuals, who often have a prior history of a nontoxic multinodular goiter. Over several years, enough thyroid nodules become autonomous to cause hyperthyroidism. The presentation often is insidious in that hyperthyroidism may only become apparent when patients are placed on low doses of thyroid hormone suppression for the goiter. Some patients have T3 toxicosis, whereas others may present only with atrial fibrillation or congestive heart failure. Hyperthyroidism also can be precipitated by iodide-containing drugs such as contrast media and the antiarrhythmic agent amiodarone (Jod-Basedow 1Brunicardi_Ch38_p1625-p1704.indd 163701/03/19 11:20 AM 1638SPECIFIC CONSIDERATIONSPART IIhyperthyroidism). Symptoms and signs of hyperthyroidism are similar to Graves’ disease, but extrathyroidal manifestations are absent.Diagnostic Studies. Blood tests are similar to Graves’ disease with a suppressed TSH level and elevated free T4 or T3 levels. RAI uptake also is increased, showing multiple nodules with increased uptake and suppression of the remaining gland.Treatment. Hyperthyroidism must be adequately controlled. Both RAI and surgical resection may be used for treatment. When surgery is performed, near-total or total thyroidectomy is recommended to avoid recurrence and the consequent increased complication rates with repeat surgery. Care must be taken in identifying the RLN, which may be found laterally on the thy-roid (rather than posterior) or stretched anteriorly over a nodule. RAI therapy is reserved for elderly patients who represent very poor operative risks, provided there is no airway compression from the goiter and thyroid cancer is not a concern. However, because uptake is less than in Graves’ disease, larger doses of RAI often are needed to treat the hyperthyroidism. Furthermore, RAI-induced thyroiditis has the potential to cause swelling and acute airway compromise and leaves the goiter intact, with the possibility of recurrent hyperthyroidism.Toxic Adenoma Hyperthyroidism from a single hyperfunction-ing nodule typically occurs in younger patients who note recent growth of a long-standing nodule along with the symptoms of hyperthyroidism. Toxic adenomas are characterized by somatic mutations in the TSH-R gene, although G-protein–stimulating gene (gsp) mutations may occur also.8 Most hyperfunctioning or autonomous thyroid nodules have attained a size of at least 3 cm before hyperthyroidism occurs. Physical examination usu-ally reveals a solitary thyroid nodule without palpable thyroid tissue on the contralateral side. RAI scanning shows a “hot” nodule with suppression of the rest of the thyroid gland. These nodules are rarely malignant. Smaller nodules may be man-aged with antithyroid medications and RAI. Larger nodules can require higher doses, which can lead to hypothyroidism. Sur-gery (lobectomy and isthmusectomy) is preferred to treat young patients and those with larger nodules. Percutaneous ethanol injection (PEI) has been reported to have reasonable success rates but has not been directly compared with surgery.Thyroid Storm Thyroid storm is a condition of hyperthyroid-ism accompanied by fever, central nervous system agitation or depression, and cardiovascular and GI dysfunction, including hepatic failure. The condition may be precipitated by abrupt cessation of antithyroid medications, infection, thyroid or non-thyroid surgery, and trauma in patients with untreated thyrotoxi-cosis. Occasionally, thyroid storm may result from amiodarone administration or exposure to iodinated contrast agents or fol-lowing RAI therapy. This condition was previously associated with high mortality rates but can be appropriately managed in an intensive care unit setting. β-Blockers are given to reduce peripheral T4 to T3 conversion and decrease the hyperthyroid symptoms. Oxygen supplementation and hemodynamic support should be instituted. Nonaspirin compounds can be used to treat pyrexia, and Lugol’s iodine or sodium ipodate (intravenously) should be administered to decrease iodine uptake and thyroid hormone secretion. PTU therapy blocks the formation of new thyroid hormone and reduces peripheral conversion of T4 to T3. Corticosteroids often are helpful to prevent adrenal exhaustion and block hepatic thyroid hormone conversion.Hypothyroidism. Deficiency in circulating levels of thyroid hormone leads to hypothyroidism and, in neonates, to cretin-ism, which is characterized by neurologic impairment and men-tal retardation. Hypothyroidism also may occur in Pendred’s syndrome (associated with deafness) and Turner’s syndrome. Conditions that cause hypothyroidism are listed in Table 38-2.Clinical Features Failure of thyroid gland development or function in utero leads to cretinism and characteristic facies similar to those of children with Down syndrome and dwarfism. Failure to thrive and severe mental retardation often are present. Immediate testing and treatment with thyroid hormone at birth can lessen the neurologic and intellectual deficits. Hypothyroid-ism developing in childhood or adolescence results in delayed development and may also lead to abdominal distention, umbili-cal hernia, and rectal prolapse. In adults, symptoms in general are nonspecific, including tiredness, weight gain, cold intoler-ance, constipation, and menorrhagia. Patients with severe hypo-thyroidism or myxedema develop characteristic facial features due to the deposition of glycosaminoglycans in the subcutane-ous tissues, leading to facial and periorbital puffiness. The skin becomes rough and dry and often develops a yellowish hue from reduced conversion of carotene to vitamin A. Hair becomes dry and brittle, and severe hair loss may occur. There is also a characteristic loss of the outer two thirds of the eyebrows. An enlarged tongue may impair speech, which is already slowed, in keeping with the impairment of mental processes. Patients may also have nonspecific abdominal pain accompanied by disten-tion and constipation. Libido and fertility are impaired in both sexes. Cardiovascular changes in hypothyroidism include bra-dycardia, cardiomegaly, pericardial effusion, reduced cardiac output, and pulmonary effusions. When hypothyroidism occurs as a result of pituitary failure, other features of hypopituitarism, such as pale, waxy skin; loss of body hair; and atrophic genita-lia, may be present.Table 38-2Causes of hypothyroidismPRIMARY (INCREASED TSH LEVELS)SECONDARY (DECREASED TSH LEVELS)TERTIARYHashimoto’s thyroiditisPituitary tumorHypothalamic insufficiencyRAI therapy for Graves’ diseasePituitary resection or ablationResistance to thyroid hormonePostthyroidectomy  Excessive iodine intake  Subacute thyroiditis  Medications: antithyroid drugs, lithium  Rare: iodine deficiency, dyshormogenesis  RAI = radioactive iodine; TSH = thyroid-stimulating hormone.Brunicardi_Ch38_p1625-p1704.indd 163801/03/19 11:20 AM 1639THYROID, PARATHYROID, AND ADRENALCHAPTER 38Laboratory Findings Hypothyroidism is characterized by low circulating levels of T4 and T3. Raised TSH levels are found in primary thyroid failure, whereas secondary hypothyroidism is characterized by low TSH levels that do not increase following TRH stimulation. Thyroid autoantibodies are highest in patients with autoimmune disease (Hashimoto’s thyroiditis, Graves’ dis-ease) and may also be elevated in patients with nodular goiter and thyroid neoplasms. An electrocardiogram demonstrates decreased voltage with flattening or inversion of T waves.Treatment T4 is the treatment of choice and is administered in dosages varying from 50 to 200 μg per day, depending on the patient’s size and condition. Starting doses of 100 μg of T4 daily are well tolerated; however, elderly patients and those with coexisting heart disease and profound hypothyroidism should be started on a considerably lower dose such as 25 to 50 μg daily because of associated hypercholesterolemia and atherosclerosis. The dose can be slowly increased over weeks to months to attain a euthyroid state. A baseline electrocardiogram should always be obtained in patients with severe hypothyroidism before treat-ment. T4 dosage is titrated against clinical response and TSH levels, which should return to normal. The management of patients with subclinical hypothyroidism (normal T4, slightly raised TSH) is controversial. Some evidence suggests that patients with subclinical hypothyroidism and increased antithy-roid antibody levels should be treated because they will sub-sequently develop hypothyroidism. Patients who present with myxedema coma may require initial emergency treatment with large doses of IV T4 (300 to 400 μg), with careful monitoring in an intensive care unit setting.9Thyroiditis. Thyroiditis usually is classified into acute, sub-acute, and chronic forms, each associated with a distinct clinical presentation and histology.Acute (Suppurative) Thyroiditis The thyroid gland is inherently resistant to infection due to its extensive blood and lymphatic supply, high iodide content, and fibrous capsule. However, infectious agents can seed it (a) via the hematoge-nous or lymphatic route, (b) via direct spread from persistent pyriform sinus fistulae or thyroglossal duct cysts, (c) as a result of penetrating trauma to the thyroid gland, or (d) due to immu-nosuppression. Streptococcus and anaerobes account for about 70% of cases; however, other species also have been cultured.10 Acute suppurative thyroiditis is more common in children and often is preceded by an upper respiratory tract infection or otitis media. It is characterized by severe neck pain radiating to the jaws or ear, fever, chills, odynophagia, and dysphonia. Compli-cations such as systemic sepsis, tracheal or esophageal rupture, jugular vein thrombosis, laryngeal chondritis, and perichondritis or sympathetic trunk paralysis may also occur.The diagnosis is established by leukocytosis on blood tests and FNAB for Gram’s stain, culture, and cytology. CT scans may help to delineate the extent of infection and identify abscesses. A persistent pyriform sinus fistula should always be suspected in children with recurrent acute thyroiditis. The sensitivity of identification of fistulae in the acute setting is lowest for barium esophagography (50%) and best for direct endoscopy (100%), with CT scans being intermediate (80%). Both barium esopha-gogram and CT scans have improved sensitivity once the acute inflammation has resolved (100% and 83%, respectively), with CT being better at defining the accurate anatomic pathway and its relationship to the thyroid gland.11 Treatment consists of parenteral antibiotics and drainage of abscesses. Thyroidec-tomy may be needed for persistent abscesses or failure of open drainage. Patients with pyriform sinus fistulae require complete resection of the sinus tract, including the area of the thyroid where the tract terminates, to prevent recurrence. Transnasal flexible fiberoptic laryngoscopy is being increasingly used to identify the internal opening of the pyriform sinus tract and may also allow electrocauterization of the tract, and success rates similar to open surgery have been reported.Subacute Thyroiditis Subacute thyroiditis can occur in the painful or painless forms. Although the exact etiology is not known, painful thyroiditis is thought to be viral in origin or result from a postviral inflammatory response. Genetic pre-disposition may also play a role, as manifested by its strong association with the HLA-B35 haplotype. One model of patho-genesis suggests that viral or thyroid antigens, when presented by macrophages in the context of HLA-B35, stimulate cytotoxic T lymphocytes and damage thyroid follicular cells.Painful thyroiditis most commonly occurs in 30to 40-year-old women and is characterized by the sudden or grad-ual onset of neck pain, which may radiate toward the mandible or ear. History of a preceding upper respiratory tract infection often can be elicited. The gland is enlarged, exquisitely ten-der, and firm. The disorder classically progresses through four stages. An initial hyperthyroid phase, due to release of thyroid hormone, is followed by a second, euthyroid phase. The third phase, hypothyroidism, occurs in about 20% to 30% of patients and is followed by resolution and return to the euthyroid state in >90% of patients. A few patients develop recurrent disease.In the early stages of the disease, TSH is decreased, and Tg, T4, and T3 levels are elevated due to the release of pre-formed thyroid hormone from destroyed follicles. The erythro-cyte sedimentation rate is typically >100 mm/h. RAIU also is decreased (<2% at 24 hours), even in euthyroid patients, due to the release of thyroid hormones from destruction of the thyroid parenchyma. Painful thyroiditis is self-limited, and therefore, treatment is primarily symptomatic. Aspirin and other nonste-roidal anti-inflammatory drugs are used for pain relief, but ste-roids may be indicated in more severe cases. Short-term thyroid replacement may be needed and may shorten the duration of symptoms. Thyroidectomy is reserved for the rare patient who has a prolonged course not responsive to medical measures or for recurrent disease.Painless thyroiditis is considered to be autoimmune in ori-gin and may occur sporadically or in the postpartum period; the latter typically occurs at about 6 weeks after delivery in women with high TPO antibody titers in early pregnancy. This timing is thought to coincide with a decrease in the normal immune tolerance of pregnancy and consequent rebound elevation of antibody titers.Painless thyroiditis also is more common in women and usually occurs between 30 and 60 years of age. Physical exami-nation demonstrates a normal sized or minimally enlarged, slightly firm, nontender gland. Laboratory tests and RAIU are similar to those in painful thyroiditis, except for a normal erythrocyte sedimentation rate. The clinical course also paral-lels painful thyroiditis. Patients with symptoms may require β-blockers and thyroid hormone replacement. Thyroidectomy or RAI ablation is only indicated for the rare patient with recur-rent, disabling episodes of thyroiditis.Brunicardi_Ch38_p1625-p1704.indd 163901/03/19 11:20 AM 1640SPECIFIC CONSIDERATIONSPART IIChronic Thyroiditis Lymphocytic (Hashimoto’s) Thyroiditis. Lymphocytic thy-roiditis was first described by Hashimoto in 1912 as struma lymphomatosa—a transformation of thyroid tissue to lymphoid tissue. It is the most common inflammatory disorder of the thy-roid and the leading cause of hypothyroidism today.Etiology, Pathogenesis, and Pathology Hashimoto’s thyroid-itis is an autoimmune process that is thought to be initiated by the activation of CD4+ T (helper) lymphocytes with specificity for thyroid antigens. Once activated, T cells can recruit cyto-toxic CD8+ T cells to the thyroid. Hypothyroidism results not only from the destruction of thyrocytes by cytotoxic T cells but also by autoantibodies, which lead to complement fixation and killing by natural killer cells or block the TSH-R. Antibod-ies are directed against three main antigens—Tg (60%), TPO (95%), and TSH-R (60%)—and, less commonly, the sodium/iodine symporter (25%). Apoptosis (programmed cell death) also has been implicated in the pathogenesis of Hashimoto’s thyroiditis. Chronic thyroiditis also has been associated with increased intake of iodine and administration of medications such as interferon-α, lithium, and amiodarone. Support for an inherited predisposition includes an increased incidence of thyroid autoantibodies in first-degree relatives of patients with Hashimoto’s thyroiditis compared to controls and the occur-rence of the autoantibodies and hypothyroidism in patients with specific chromosomal abnormalities such as Turner’s syn-drome and Down syndrome. Associations with HLA-B8, DR3, and DR5 haplotypes of the major histocompatibility complex also have been described. Alterations in CTLA4 have also been shown to increase the risk of developing Hashimoto’s thyroid-itis. Other associated genes include various cytokine genes, GITR (glucocorticoid-induced tumor necrosis factor-receptor) and STAT 3; however, these need further confirmatory studies.11On gross examination, the thyroid gland is usually mildly enlarged throughout and has a pale, gray-tan cut surface that is granular, nodular, and firm. On microscopic examination, the gland is diffusely infiltrated by small lymphocytes and plasma cells and occasionally shows well-developed germinal centers. Thyroid follicles are smaller than normal with reduced amounts of colloid and increased interstitial connective tissue. The fol-licles are lined by Hürthle or Askanazy cells, which are charac-terized by abundant eosinophilic, granular cytoplasm.Clinical Presentation Hashimoto’s thyroiditis is also more common in women (male-to-female ratio is 1:10 to 20) between the ages of 30 and 50 years old. The most common presenta-tion is that of a minimally or moderately enlarged firm granular gland discovered on routine physical examination or the aware-ness of a painless anterior neck mass, although 20% of patients present with hypothyroidism, and 5% present with hyperthy-roidism (Hashitoxicosis). In classic goitrous Hashimoto’s thy-roiditis, physical examination reveals a diffusely enlarged, firm gland, which also is lobulated. An enlarged pyramidal lobe often is palpable.Diagnostic Studies When Hashimoto’s thyroiditis is suspected clinically, an elevated TSH and the presence of thyroid autoan-tibodies usually confirm the diagnosis. FNAB with ultrasound guidance is indicated in patients who present with a solitary suspicious nodule or a rapidly enlarging goiter. Thyroid lym-phoma is a rare but well-recognized, ominous complication of chronic autoimmune thyroiditis and has a prevalence 80 times higher than expected frequency in this population than in a control population without thyroiditis. Studies of clonal simi-larity indicate that lymphoma may, in fact, evolve from Hashi-moto’s thyroiditis.12Treatment Thyroid hormone replacement therapy is indicated in overtly hypothyroid patients, with a goal of maintaining nor-mal TSH levels. The management of patients with subclinical hypothyroidism (normal T4 and elevated TSH) is controversial. A systematic review of cohort studies showed that in ageand sex-adjusted analyses, subclinical hypothyroidism is associated with a hazard ratio (HR) for coronary heart disease events of 1.89 (95% confidence interval [CI], 1.28 to 2.80; P <.001) and coronary heart disease mortality of 1.58 (95% CI, 1.10 to 2.27; P = .005) for a TSH level of 10 to 19.9 mIU/L.13 The data for TSH levels of 5 to 10 mIU/L were less convincing. An evalu-ation of the 12 randomized controlled trials in this area only showed a trend toward improvement of some lipid parameters, and none of the included trials evaluated overall mortality or car-diac morbidity. For this reason, levothyroxine is recommended for all patients with TSH levels >10 μIU/mL and patients with levels of 5 to 10 μIU/mL in the presence of a goiter or anti-TPO antibodies. Treatment is also advised especially for middle-aged patients with cardiovascular risk factors such as hyperlipidemia or hypertension and in pregnant patients. Surgery may occa-sionally be indicated for suspicion of malignancy or for goiters causing compressive symptoms or cosmetic deformity.Riedel’s Thyroiditis Riedel’s thyroiditis is a rare variant of thyroiditis also known as Riedel’s struma or invasive fibrous thyroiditis that is characterized by the replacement of all or part of the thyroid parenchyma by fibrous tissue, which also invades into adjacent tissues. The etiology of this disorder is contro-versial, and it has been reported to occur in patients with other autoimmune diseases. This association, coupled with the pres-ence of lymphoid infiltration and response to steroid therapy, suggests a primary autoimmune etiology. Riedel’s thyroiditis also is associated with other focal sclerosing syndromes includ-ing mediastinal, retroperitoneal, periorbital, and retro-orbital fibrosis and sclerosing cholangitis, suggesting that it may, in fact, be a primary fibrotic disorder. It is now considered a manifestation of IgG4-related systemic disease characterized by elevated serum IgG4 levels and a lymphoplasmacytic infiltrate with an abundance of IgG4 bearing plasma cells.14 The disease occurs predominantly in women between the ages of 30 and 60 years old. It typically presents as a painless, hard anterior neck mass, which progresses over weeks to years to produce symptoms of compression, including dysphagia, dyspnea, chok-ing, and hoarseness. Patients may present with symptoms of hypothyroidism and hypoparathyroidism as the gland is replaced by fibrous tissue. Physical examination reveals a hard, “woody” thyroid gland with fixation to surrounding tissues. The diagnosis needs to be confirmed by open thyroid biopsy because the firm and fibrous nature of the gland renders FNAB inadequate.Surgery is the mainstay of the treatment. The chief goal of operation is to decompress the trachea by wedge excision of the thyroid isthmus and to make a tissue diagnosis. More extensive resections are not advised due to the infiltrative nature of the fibrotic process that obscures usual landmarks and struc-tures. Hypothyroid patients are treated with thyroid hormone replacement. Some patients who remain symptomatic have been reported to experience dramatic improvement after treatment with corticosteroids and tamoxifen. Mycophenolate mofetil and more recently rituximab has also been used to attenuate the Brunicardi_Ch38_p1625-p1704.indd 164001/03/19 11:20 AM 1641THYROID, PARATHYROID, AND ADRENALCHAPTER 38inflammatory process and led to dramatic symptom improve-ments in some patients.15Goiter. Any enlargement of the thyroid gland is referred to as a goiter. The causes of nontoxic goiters are listed in Table 38-3. Goiters may be diffuse, uninodular, or multinodular. Most non-toxic goiters are thought to result from TSH stimulation second-ary to inadequate thyroid hormone synthesis and other paracrine growth factors.16 Elevated TSH levels induce diffuse thyroid hyperplasia, followed by focal hyperplasia, resulting in nod-ules that may or may not concentrate iodine, colloid nodules, or microfollicular nodules. The TSH-dependent nodules progress to become autonomous. Familial goiters resulting from inher-ited deficiencies in enzymes necessary for thyroid hormone synthesis may be complete or partial. The term endemic goiter refers to the occurrence of a goiter in a significant proportion of individuals in a particular geographic region. In the past, dietary iodine deficiency was the most common cause of endemic goi-ter. This condition has largely disappeared in North America due to routine use of iodized salt and iodination of fertilizers, animal feeds, and preservatives. However, in areas of iodine deficiency, such as Central Asia, South America, and Indonesia, up to 90% of the population have goiters. Other dietary goitro-gens that may participate in endemic goiter formation include kelp, cassava, and cabbage. In many sporadic goiters, no obvi-ous cause can be identified.Clinical Features Most patients with nontoxic goiters are asymptomatic, although patients often complain of a pres-sure sensation in the neck. As the goiters become very large, compressive symptoms such as dyspnea and dysphagia ensue. Patients also describe having to clear their throats frequently (catarrh). Dysphonia from RLN injury is rare, except when malignancy is present. Obstruction of venous return at the tho-racic inlet from a substernal goiter results in a positive Pember-ton’s sign—facial flushing and dilatation of cervical veins upon raising the arms above the head (Fig. 38-13A). Sudden enlarge-ment of nodules or cysts due to hemorrhage may cause acute pain. Physical examination may reveal a soft, diffusely enlarged gland (simple goiter) or nodules of various size and consistency in case of a multinodular goiter. Deviation or compression of the trachea may be apparent.Diagnostic Tests Patients usually are euthyroid with normal TSH and low-normal or normal free T4 levels. If some nod-ules develop autonomy, patients have suppressed TSH levels or become hyperthyroid. RAI uptake often shows patchy uptake with areas of hot and cold nodules. FNAB is recommended in patients who have a dominant nodule or one that is painful or enlarging, as carcinomas have been reported in 5% to 10% of multinodular goiters. CT scans are helpful to evaluate the extent of retrosternal extension and airway compression (Fig. 38-13B).Treatment Most euthyroid patients with small, diffuse goi-ters do not require treatment. Some physicians give patients with large goiters exogenous thyroid hormone to reduce the TSH stimulation of gland growth; this treatment may result in decrease and/or stabilization of goiter size and is most effective for small diffuse goiters. Endemic goiters are treated by iodine administration. Surgical resection is reserved for goiters that (a) continue to increase despite T4 suppression, (b) cause obstruc-tive symptoms, (c) have substernal extension (considered a rela-tive indication by some groups), (d) have malignancy suspected or proven by FNAB, and (e) are cosmetically unacceptable. Near-total or total thyroidectomy is the treatment of choice, and patients require lifelong T4 therapy.Solitary Thyroid NoduleSolitary thyroid nodules are present in approximately 4% of individuals in the United States, whereas thyroid cancer has a much lower incidence of 40 new cases per 1 million. Therefore, it is of utmost importance to determine which patients with soli-tary thyroid nodule would benefit from surgery.History. Details regarding the nodule, such as time of onset, change in size, and associated symptoms such as pain, dyspha-gia, dyspnea, or choking, should be elicited. Pain is an unusual symptom and, when present, should raise suspicion for intra-thyroidal hemorrhage in a benign nodule, thyroiditis, or malig-nancy. Patients with MTC may complain of a dull, aching sensation. A history of hoarseness is worrisome, as it may be secondary to malignant involvement of the RLNs. Most impor-tantly, patients should be questioned regarding risk factors for malignancy, such as exposure to ionizing radiation and family history of thyroid and other malignancies associated with thy-roid cancer.External-Beam Radiation Low-dose therapeutic radiation has been used to treat conditions such as tinea capitis (6.5 cGy), thymic enlargement (100 to 400 cGy), enlarged tonsils and adenoids (750 cGy), acne vulgaris (200 to 1500 cGy), and other conditions such as hemangioma and scrofula. Radiation (approximately 4000 cGy) is also an integral part of the manage-ment of patients with Hodgkin’s disease. It is now known that a history of exposure to low-dose ionizing radiation to the thyroid gland places the patient at increased risk for developing thyroid cancer. The risk increases linearly from 6.5 to 2000 cGy, beyond which the incidence declines as the radiation causes destruc-tion of the thyroid tissue. The risk is maximum 20 to 30 years after exposure, but these patients require lifelong monitoring. During the nuclear fallout from Chernobyl in 1986, 131I release was accompanied by a marked increase in the incidence of both benign and malignant thyroid lesions noted within 4 years of exposure, particularly in children.17 Most thyroid carcinomas following radiation exposure are papillary, and some of these cancers with a solid type of histology and presence of RET/PTC translocations appear to be more aggressive. In general, there is a 40% chance that patients presenting with a thyroid nodule and a history of radiation have thyroid cancer. Of those patients who have thyroid cancer, the cancer is located in the dominant nodule in 60% of patients, but in the remaining 40% of patients, the cancer is in another nodule in the thyroid gland.Table 38-3Etiology of nontoxic goiterCLASSIFICATIONSPECIFIC ETIOLOGYEndemicIodine deficiency, dietary goitrogens (cassava, cabbage)MedicationsIodide, amiodarone, lithiumThyroiditisSubacute, chronic (Hashimoto’s)FamilialImpaired hormone synthesis from enzyme defectsNeoplasmAdenoma, carcinomaResistance to thyroid hormone—Brunicardi_Ch38_p1625-p1704.indd 164101/03/19 11:20 AM 1642SPECIFIC CONSIDERATIONSPART IIABFigure 38-13. A. Retrosternal extension of a large goiter may result in impeded flow in the superior vena cava, leading to dilated veins over the chest wall. This may become more prominent when patients raise their arms above the head—Pemberton’s sign. B. Computed tomography scan demonstrating retrosternal extension and consequent tracheal deviation and compression from a large goiter.Brunicardi_Ch38_p1625-p1704.indd 164201/03/19 11:20 AM 1643THYROID, PARATHYROID, AND ADRENALCHAPTER 38Family History A family history of thyroid cancer is a risk factor for the development of both medullary and nonmedullary thyroid cancer. Familial MTCs occur in isolation or in associa-tion with other tumors as part of multiple endocrine neoplasia type 2 (MEN2) syndromes. Nonmedullary thyroid cancers can occur in association with other known familial cancer syn-dromes such as Cowden’s syndrome, Werner’s syndrome (adult progeroid syndrome), familial adenomatous polyposis, and DICER 1 (Table 38-4). Nonmedullary thyroid cancers can also occur independently of these syndromes as the predominant tumors in the families, and in fact nonsyndromic FNMTC accounts for 95% of cases. The definition of familial nonmedul-lary thyroid cancer (FNMTC) is variable across the literature; however, in most studies, it is defined by the presence of two or more first-degree relatives with follicular cell–derived cancers. FNMTC is now recognized as a distinct clinical entity associated with a high incidence of multifocal tumors and benign thyroid nodules. Some studies report that these patients have higher locoregional recurrence rates and consequently shorter disease-free survival. Several candidate chromosomal loci that predispose to these tumors have been identified, includ-ing MNG1 (14q32), thyroid carcinoma with oxphilia (TCO, on 19p13.2), fPTC/papillary renal neoplasia (PRN, on 1q21), NMTC1 (2q21), and FTEN (8p23.1-p22). Susceptibility genes include SRGAP1 (12q14), TITF-1/NKX2.1 (14q13), FOXE1 (9q22), and the telomere-telomerase complex.18Physical Examination. The thyroid gland is best palpated from behind the patient and with the neck in mild extension. The cricoid cartilage is an important landmark, as the isthmus is situated just below it. Nodules that are hard, gritty, or fixed to surrounding structures such as the trachea or strap muscles are more likely to be malignant. The cervical chain of lymph nodes should be assessed as well as the nodes in the posterior triangle.Diagnostic Investigations. An algorithm for the workup of a solitary thyroid nodule is shown in Fig. 38-14.Fine-Needle Aspiration Biopsy FNAB has become the single most important test in the evaluation of thyroid masses and can be performed with or without ultrasound guidance. Ultrasound guidance is recommended for nodules that are difficult to pal-pate, for cystic or solid-cystic nodules that recur after the initial aspiration, and for multinodular goiters. A 23-gauge needle is inserted into the thyroid mass, and several passes are made while aspirating the syringe. After releasing the suction on the syringe, the needle is withdrawn and the cells are immediately placed on prelabeled dry glass slides; some are immersed in a 70% alcohol solution while others are air dried. A sample of the aspirate is also placed in a 90% alcohol solution for cytospin or cell pellet. The slides are stained by Papanicolaou’s or Wright’s stains and examined under the microscope. If a bloody aspirate is obtained, the patient should be repositioned in a more upright position and the biopsy repeated with a finer (25to 30-gauge) needle.After FNAB, the majority of nodules can be classified into several categories that determine further management. To address the issue of variability in the terminology of fine-needle aspiration (FNA), the National Cancer Institute (NCI) hosted the “NCI Thyroid Fine Needle Aspiration State of the Science Conference,” which then defined the Bethesda criteria for thyroid FNA.19 Accordingly, optimum cytology specimens should have at least six follicles each containing at least 10 to 15 cells from at least two aspirates.The FNA is classified as “nondiagnostic or unsatisfac-tory” in 2% to 20% of cases and typically results from a virtu-ally acellular specimen, cyst fluid, or the presence of blood or clotting artifact. The risk of malignancy in this setting ranges from 1% to 4%, and reaspiration under ultrasound guidance is recommended. A “benign” result is obtained in 60% to 70% of thyroid FNAs. The most common lesion in this setting is a follicular nodule (includes adenomatoid nodule, colloid nodule, and follicular adenoma). Other diagnoses include lymphocytic (Hashimoto’s) thyroiditis and granulomatous thyroiditis. False-negative results are reported in up to 3% of cases, and follow-up is recommended. A result of “atypia of unknown significance (AUS) or follicular lesion of unknown significance (FLUS)” is obtained in 3% to 6% of biopsies. The risk of malignancy in this scenario is difficult to determine; however, it is thought to be in the range of 5% to 15%. Clinical correlation and a repeat FNA are recommended for AUS lesions (which often results in 23Table 38-4Familial cancer syndromes involving nonmedullary thyroid cancerSYNDROMEGENEMANIFESTATIONTHYROID TUMORCowden’s syndromePTENIntestinal hamartomas, benign and malignant breast tumorsFTC, rarely PTC and Hürthle cell tumorsFAPAPCColon polyps and cancer, duodenal neoplasms, desmoidsPTC cribriform growth patternWerner’s syndromeWRNAdult progeroid syndromePTC, FTC, anaplastic cancerCarney complex type 1PRKAR1αCutaneous and cardiac myxomas, breast and adrenal tumorsPTC, FTCMcCune-Albright syndromeGNAS1Polyostotic fibrous dysplasia, endocrine abnormalities, café-au-lait spotsPTC clear cellDICER 1 syndrome Pleuropulmonary blastoma, cystic nephroma, ovarian sex cord-stromal tumorsMultinodular goiter, thyroid cancerFAP = familial adenomatous polyposis; FTC = follicular thyroid cancer; PTC = papillary thyroid cancer.Brunicardi_Ch38_p1625-p1704.indd 164301/03/19 11:20 AM 1644SPECIFIC CONSIDERATIONSPART IIa more definitive interpretation), although clinical observation or surgery may be appropriate because of worrisome clinical or ultrasound findings. The category of “follicular neoplasm” is intended to identify nodules that might be follicular carcinomas. The term suspicious for a follicular neoplasm is preferred by some laboratories for this category because up to 35% of cases turn out not to be neoplasms but hyperplastic proliferations of follicular cells, most commonly those of multinodular goiter. Lobectomy is the preferred treatment for this result, and approx-imately 15% to 35% of lesions placed in this category prove to be malignant. Hürthle cell neoplasms are also included in this category. Most papillary and other carcinomas can be diagnosed by FNA, but the features are subtle at times, such as in follicular variant of papillary carcinomas. If the diagnosis is uncertain, the lesions are classified as “suspicious for malignancy.” Lobec-tomy or near-total thyroidectomy is recommended because 60% to 75% turn out to be malignant. This category also includes lesions suspicious for medullary carcinoma and lymphoma, and ancillary testing such as immunohistochemical analysis and flow cytometry may be helpful. The risk of malignancy in lesions classified as “malignant” by FNA is 97% to 99%, and near-total/total thyroidectomy is recommended.Laboratory Studies Most patients with thyroid nodules are euthyroid. Determining the blood TSH level is helpful. If a patient with a nodule is found to be hyperthyroid, the risk of malignancy is approximately 1%. Serum Tg levels cannot dif-ferentiate benign from malignant thyroid nodules unless the lev-els are extremely high, in which case metastatic thyroid cancer should be suspected. Tg levels are, however, useful in following patients who have undergone total thyroidectomy for thyroid cancer and also for serial evaluation of patients undergoing nonoperative management of thyroid nodules. Serum calcitonin levels should be obtained in patients with MTC or a family his-tory of MTC or MEN2. There is insufficient evidence to recom-mend routine calcitonin testing for all nodules. All patients with MTC should be tested for RET oncogene mutations and have a 24-hour urine collection with measurement of levels of vanil-lylmandelic acid (VMA), metanephrine, and catecholamine levels to rule out a coexisting pheochromocytoma. About 10% of patients with familial MTC and MEN2A have de novo RET mutations, so that their children are at risk for thyroid cancer.Imaging Ultrasound is helpful for detecting nonpalpable thy-roid nodules, differentiating solid from cystic nodules, and identifying adjacent lymphadenopathy. Ultrasound evaluation can identify features of a nodule that increase the a priori risk of malignancy, such as fine stippled calcification and enlarged regional nodes; however, a tissue diagnosis is strongly recom-mended before thyroidectomy.20 Ultrasound also provides a noninvasive and inexpensive method of following the size of suspected benign nodules diagnosed by FNAB and for identi-fying enlarged lymph nodes. Ultrasound elastography is used to evaluate tissue stiffness noninvasively. This technique takes advantage of the fact that malignant nodules tend to be harder than benign nodules and thus deform less compared with the surrounding normal thyroid parenchyma. Larger studies are warranted before elastography and newer techniques such as contrast-enhanced ultrasound can be routinely included in the evaluation of thyroid nodules.21 CT and MRI are unnecessary in the routine evaluation of thyroid tumors except for large, fixed, or substernal lesions. Scanning the thyroid with 123I or 99mTc is rarely necessary, and thyroid scanning currently is recom-mended in the assessment of thyroid nodules only in patients Solitary thyroid noduleFNABBenignMalignantNondiagnosticRepeatFNAB withu/sguidanceCystColloidnoduleAspirateReaccumulates x 3ThyroidectomyObserveContinuedgrowth,compressivesymptoms+/–FNABAUS/FLUSFN orSuspiciousfor FNSuspiciousformalignancyNear-total/ totalThyroidectomyRepeatFNABLobectomyLobectomy ornear-total/totalthyroidectomyFigure 38-14. Management of a solitary thyroid nodule based on Bethesda criteria. a = except in patients with a history of external radia-tion exposure or a family history of thyroid cancer; FNAB = fine-needle aspiration biopsy; AUS = atypia of unknown significance; FLUS = follicular lesion of unknown significance; FN = follicular neoplasm.Brunicardi_Ch38_p1625-p1704.indd 164401/03/19 11:20 AM 1645THYROID, PARATHYROID, AND ADRENALCHAPTER 38who have follicular thyroid nodules on FNAB and a suppressed TSH. PET scanning does not play a major role in the primary evaluation of thyroid nodules.Management. Malignant tumors are treated by thyroidectomy, as discussed earlier and later in this chapter in “Surgical Treat-ment under Malignant Thyroid Disease.” Simple thyroid cysts resolve with aspiration in about 75% of cases, although some require a second or third aspiration. If the cyst persists after three attempts at aspiration, unilateral thyroid lobectomy is rec-ommended. Lobectomy also is recommended for cysts >4 cm in diameter or complex cysts with solid and cystic components, as the latter have a higher incidence of malignancy (15%). When FNAB is used in complex nodules, the solid portion should be sampled. If a colloid nodule is diagnosed by FNAB, patients should still be observed with serial ultrasound and Tg measure-ments. If the nodule enlarges, repeat FNAB often is indicated. Although controversial, levothyroxine in doses sufficient to maintain a serum TSH level between 0.1 and 1.0 μU/mL may also be administered. In areas with a high prevalence of iodine deficiency, this can decrease nodule size and potentially prevent the growth of new nodules. In iodine-sufficient populations, the data are less impressive. Randomized controlled trial analyses have shown that less than 25% of benign nodules shrink more than 50% with TSH suppression in iodine-replete populations. Thyroidectomy should be performed if a nodule enlarges on TSH suppression, causes compressive symptoms, or for cos-metic reasons. An exception to this general rule is the patient who has had previous irradiation of the thyroid gland or has a family history of thyroid cancer. In these patients, total or near-total thyroidectomy is recommended because of the high incidence of thyroid cancer and decreased reliability of FNAB in this setting.Malignant Thyroid DiseaseIn the United States, thyroid cancer accounts for <1% of all malignancies (2% of women and 0.5% of men) and is the most rapidly increasing cancer in women. Thyroid cancer is respon-sible for six deaths per million persons annually. Most patients present with a palpable swelling in the neck, which initiates assessment through a combination of history, physical exami-nation, and FNAB.Molecular Genetics of Thyroid Tumorigenesis. Several oncogenes and tumor suppressor genes are involved in thy-roid tumorigenesis,22 as depicted in Table 38-5. The RET proto-oncogene (Fig. 38-15) plays a significant role in the pathogenesis of thyroid cancers. It is located on chromosome 10 and encodes a receptor tyrosine kinase, which binds sev-eral growth factors such as glial-derived neurotrophic factor and neurturin. The RET protein is expressed in tissues derived from the embryonic nervous and excretory systems. Therefore, Table 38-5Oncogenes, tumor suppressor genes, and other genetic alterations implicated in thyroid tumorigenesisGENEFUNCTIONTUMOROncogenes  RETMembrane receptor with tyrosine kinase activitySporadic and familial MTC, PTC (RET/PTC rearrangements)METSameOverexpressed in PTCTRK1SameActivated in some PTCTSH-RLinked to heterotrimeric G proteinHyperfunctioning adenomaGsα (gsp)Signal transduction molecule (GTP binding)Hyperfunctioning adenoma, follicular adenomaRasSignal transduction proteinFollicular adenoma and carcinoma, PTCPAX8/PPARγ1OncoproteinFollicular adenoma, follicular carcinomaB-Raf (BRAF)Signal transductionPTC, tall cell and poorly differentiated, anaplasticCTNNB1 (β-catenin)Signal transductionUpregulated in poorly differentiated and anaplastic cancersTERT promoterChromosome integrityMutated in thyroid cancers including PTC, FTC and anaplastic cancersTumor suppressors  p53Cell cycle regulator, arrests cells in G1, induces apoptosisDedifferentiated PTC, FTC, anaplastic cancersp16Cell cycle regulator, inhibits cyclin-dependent kinaseThyroid cancer cell linesPTENProtein tyrosine phosphataseFollicular adenoma and carcinomaOther genetic alterations  microRNASmall, noncoding RNASpecific types upregulated in papillary and some follicular carcinomasFTC = follicular thyroid cancer; GTP = guanosine triphosphate; MTC = medullary thyroid cancer; PTC = papillary thyroid cancer.Brunicardi_Ch38_p1625-p1704.indd 164501/03/19 11:20 AM 1646SPECIFIC CONSIDERATIONSPART IIReceptorGDNFTyrosinekinaseIntracellularExtracellularSubstrateATP620618811609634830804768= MEN2A & FMTC mutation= MEN2B mutation= FMTC mutation= Hirschsprung's disease mutation918Figure 38-15. Structure of the RET tyrosine kinase receptor. Multiple endocrine neoplasia type 2A (MEN2A) and type 2B (MEN2B), famil-ial medullary thyroid cancer (FMTC), and Hirschsprung’s disease result from germline mutations in the RET proto-oncogene. The extracel-lular domain binds the ligand glial-derived neurotrophic factor (GDNF) and contains 28 cysteine residues. Mutations in cysteine residues at codons 609, 611, 618, 620, and 634, which are in the juxtamembrane region of the receptor, are associated with MEN2A and FMTC. The ATP-binding site is located intracellularly near the site, which binds the substrate for the tyrosine kinase catalytic domain. Mutations at codon 918 (Met to Thr) alter the substrate binding pocket located in the intracellular region and cause MEN2B. FMTC is associated with mutations at codons 768 and 804. ATP = adenosine triphosphate. (Reproduced with permission from Wells S, Franz C. Medullary carcinoma of the thyroid gland, World J Surg. 2000 Aug;24(8):952-956.)RET disruption can lead to developmental abnormalities in organs derived from these systems, such as the enteric nervous system (Hirschsprung’s disease) and kidney. Germline muta-tions in the RET proto-oncogene are known to predispose to MEN2A, MEN2B, and familial MTCs, and somatic mutations have been demonstrated in tumors derived from the neural crest, such as MTCs (30%) and pheochromocytomas. The tyrosine kinase domain of RET can fuse with other genes by rearrange-ment. These fusion products also function as oncogenes and have been implicated in the pathogenesis of PTCs. At least 15 RET/PTC rearrangements have been described and appear to be early events in tumorigenesis. Young age and radiation expo-sure seem to be independent risk factors for the development of RET/PTC rearrangements. Up to 70% of papillary cancers in children exposed to the radiation fallout from the 1986 Cher-nobyl disaster carry RET/PTC rearrangements, the most com-mon being RET/PTC1 and RET/PTC3. These rearrangements confer constitutive activation of the receptor tyrosine kinases. RET/PTC3 is associated with a solid type of PTC that appears to present at a higher stage and to be more aggressive. It has now been established that RET/PTC signaling involves the mitogen-activated protein kinase (MAPK) pathway via other signaling molecules such as Ras, Raf, and MEK. In normal cells, physi-ologic activation of Raf kinases occurs via direct interaction with guanosine triphosphate (GTP)–bound Ras, a membrane-bound small G protein. Activated Raf, a serine-threonine kinase, in turn phosphorylates MEK, another serine-threonine kinase. This leads to phosphorylation of ERK/MAPK, which phosphor-ylates regulatory molecules in the nucleus, thereby altering gene expression. Aberrant activation of the MAPK pathway leads to tumorigenesis. Aside from RET/PTC alterations, mutations in the Ras genes can also activate the MAPK pathway. Mutated RAS oncogenes have been identified in up to 20% to 40% of thyroid follicular adenomas and carcinomas, multinodular goi-ters, and papillary and anaplastic carcinomas. There are three Raf kinases, A-Raf, B-Raf (BRAF), and C-Raf. Mutations in BRAF also have been implicated in aberrant MAPK pathway activation and tumorigenesis. Of the various identified BRAF mutations, T1799A (V600E amino acid substitution) is the most common and occurs frequently in thyroid cancers. Interestingly, BRAF mutations occur in papillary and anaplastic tumors (aver-age prevalence of 44% and 22%, respectively),23 but not in fol-licular thyroid cancers, suggesting a role in the pathogenesis of these malignancies. Studies also show that BRAF mutations are associated with more aggressive clinicopathologic features, including larger tumor size, invasion, and lymphadenopathy, and may have a role as prognostic markers.The p53 gene is a tumor suppressor gene encoding a transcriptional regulator, which causes cell cycle arrest allow-ing repair of damaged DNA, thus helping to maintain genomic integrity. Mutations of p53 are rare in PTCs but common in undifferentiated thyroid cancers and thyroid cancer cell lines. Other cell cycle regulators and tumor suppressors such as p15 and p16 are mutated more commonly in thyroid cancer cell lines than in primary tumors. An oncogene resulting from the fusion of the DNA binding domain of the thyroid-transcription fac-tor PAX8 gene to the peroxisome proliferator-activated receptor gamma 1 (PPARγ1) has been noted to play an important role Brunicardi_Ch38_p1625-p1704.indd 164601/03/19 11:21 AM 1647THYROID, PARATHYROID, AND ADRENALCHAPTER 38in the development of follicular neoplasms, including follicular cancers. Mutations in the telomerase reverse transcriptase cata-lytic subunit (TERT) promoter unit have also been recently been identified in well-differentiated thyroid cancers and appear to be related to poor prognosis. Thyroid cancer stem cells have also been identified; however, their role in thyroid carcinogenesis remains to be determined.24 Mutations in the kinases PIK3CA and AKT1 are rare in thyroid cancers and tend to occur as late events in tumorigenesis.Specific Tumor Types Papillary Carcinoma Papillary carcinoma accounts for 80% of all thyroid malignancies in iodine-sufficient areas and is the predominant thyroid cancer in children and individuals exposed to external radiation. Papillary carcinoma occurs more often in women, with a 2:1 female-to-male ratio, and the mean age at presentation is 30 to 40 years. Most patients are euthyroid and present with a slow-growing painless mass in the neck. Dys-phagia, dyspnea, and dysphonia usually are associated with locally advanced invasive disease. Lymph node metastases are common, especially in children and young adults, and may be the presenting complaint. “Lateral aberrant thyroid” almost always denotes a cervical lymph node that has been invaded by metastatic cancer. Suspicion of thyroid cancer often originates through physical examination of patients and a review of their history. Diagnosis is established by FNAB of the thyroid mass or lymph node. Once thyroid cancer is diagnosed on FNAB, a complete neck ultrasound is strongly recommended to evalu-ate the contralateral lobe and for lymph node metastases in the central and lateral neck compartments. Distant metastases are uncommon at initial presentation, but may ultimately develop in up to 20% of patients. The most common sites are lungs, fol-lowed by bone, liver, and brain.Pathology. On gross examination, PTCs generally are hard and whitish and remain flat on sectioning with a blade, in contrast to normal tissue or benign nodular lesions that tend to bulge. Mac-roscopic calcification, necrosis, or cystic change may be appar-ent. Histologically, papillary carcinomas may exhibit papillary projections (Fig. 38-16A), a mixed pattern of papillary and fol-licular structures, or a pure follicular pattern (follicular variant). The diagnosis is established by characteristic nuclear cellular features. Cells are cuboidal with pale, abundant cytoplasm, crowded nuclei that may demonstrate “grooving,” and intranu-clear cytoplasmic inclusions (leading to the designation of Orphan Annie nuclei [Fig. 38-16B]), which allow diagnosis by FNAB. Psammoma bodies, which are microscopic, calcified deposits representing clumps of sloughed cells, also may be present. Mixed papillary-follicular tumors and follicular variant of papillary thyroid carcinoma (FVPTC) are classified as papil-lary carcinomas because they behave biologically as papillary carcinomas. Two main subtypes of FVPTC are recognized: encapsulated and nonencapsulated (infiltrative). The for-mer is challenging to diagnose. Since the tumors have no invasion, the diagnosis relies on the finding of characteristic nuclei, which can be subjective. In addition, several studies have shown that the encapsulated tumors have an indolent behavior and are genetically distinct from their infiltrative counterparts. As such, these tumors are now designated noninvasive follicular thyroid neoplasm with papillary-like nuclear features (NIFTP).25 Multifocality is common in papillary carcinoma and may be present in up to 85% of cases on microscopic examination. Mul-tifocality is associated with an increased risk of cervical nodal metastases, and these tumors may rarely invade adjacent struc-tures such as the trachea, esophagus, and RLNs. Other variants of papillary carcinoma include tall cell, insular, columnar, dif-fuse sclerosing, clear cell, trabecular, and poorly differentiated types. These variants account for about 1% of all papillary car-cinomas and are generally associated with a worse prognosis.Minimal or occult/microcarcinoma refers to tumors of 1 cm or less in size with no evidence of local invasiveness through the thyroid capsule or angioinvasion, and that are not associated with lymph node metastases. They are nonpalpable and usually are incidental findings at operative, histologic, or autopsy examination. Studies have demonstrated occult PTC to be present in 2% to 36% of thyroid glands removed at autopsy. These tumors are also being identified more frequently due to the widespread use of ultrasound. These occult tumors are generally associated with a better prognosis than larger tumors, but they may be more aggressive than previously appreciated. About 25% of patients with these tumors have associated occult lymph node metastases.Prognostic Indicators. In general, patients with PTC have an excellent prognosis with a >95% 10-year survival rate. Sev-eral prognostic indicators have been incorporated into various 4Figure 38-16. A. Histomicrograph of a papillary thyroid cancer (hematoxylin-eosin stain). B. Fine-needle aspiration biopsy specimen from a papillary thyroid cancer showing typical intranuclear cytoplasmic inclusions in the center of the slide.Brunicardi_Ch38_p1625-p1704.indd 164701/03/19 11:21 AM 1648SPECIFIC CONSIDERATIONSPART IIstaging systems, which enable patients to be stratified into low-risk and high-risk groups. Unfortunately, all of these classifica-tion systems rely on data that are not available preoperatively.In 1987, Hay and colleagues26 at the Mayo Clinic proposed the AGES scoring system, which incorporates Age, histologic Grade, Extrathyroidal invasion, and metastases and tumor Size to predict the risk of dying from papillary cancer. Low-risk patients are young, with well-differentiated tumors, no metas-tases, and small primary lesions, whereas high-risk patients are older, with poorly differentiated tumors, local invasion, dis-tant metastases, and large primary lesions. The MACIS scale is a postoperative system modified from the AGES scale. This scale incorporates distant Metastases, Age at presentation (<40 or >40 years old), Completeness of original surgical resection, extrathyroidal Invasion, and Size of original lesion (in centime-ters) and classifies patients into four risk groups based on their scores. Cady proposed the AMES system27 to classify differen-tiated thyroid tumors into lowand high-risk groups using Age (men <40 years old, women <50 years old), Metastases, Extra-thyroidal spread, and Size of tumors (< or >5 cm). A simplified system by DeGroot and associates28 uses four groups—class I (intrathyroidal), class II (cervical nodal metastases), class III (extrathyroidal invasion), and class IV (distant metastases)—to determine prognosis. Another classification system is the TNM system (Tumor, Nodal status, Metastases; Table 38-6), which used by most medical centers in North America and has been recently updated.29 In this new version, minimal extrathyroidal extension is no longer considered T3a disease. Thyroglobulin doubling time (using levels obtained when TSH is <0.1 mIU/L) has also been demonstrated to be an independent prognostic marker for metastatic disease and recurrence.30Several molecular and genetic markers such as tumor DNA aneuploidy, decreased cyclic adenosine monophosphate response to TSH, increased epidermal growth factor binding, presence of N-ras and gsp mutations, overexpression of c-myc, and presence of p53 mutations also have been associated with a worse prognosis. The presence of BRAF V600E mutation, as previously mentioned, is associated with aggressive tumor characteristics, including extrathyroidal extension, older age at presentation, and lymph node and distant metastases. This muta-tion also appears to be an independent predictor of both tumor recurrence (even for early-stage disease) and tumor-related mortality. Some studies propose that BRAF mutation status on FNAB can be used to tailor initial management including more extensive initial surgical excision, high-dose postoperative RAI therapy, increased TSH suppression, and closer follow-up.31 The correlation of RET/PTC rearrangements and Ras mutations with prognosis is less clear. TERT promoter mutations have been associated with poor disease-specific and disease-free survival.Surgical Treatment. Most authors agree that patients with high-risk tumors (judged by any of the classification systems discussed earlier in “Prognostic Indicators”) or bilateral tumors should undergo total or near-total thyroidectomy. The optimal surgical strategy in the majority of patients with low-risk (small, unilateral) cancers was controversial for many years, with the focus of the debate centering around outcome data and risks associated with extent of thyroidectomy in this group of patients. Proponents of total thyroidectomy indicate that it enables the use of RAI to effectively detect and treat residual thyroid tissue or metastatic disease and makes serum Tg level a more sensitive marker of recurrent or persistent disease. It is also known that a significant proportion (33% to 50%) of patients who develop a recurrence die from their disease,32 and even though the data are retrospective, long-term, follow-up studies suggest that recur-rence rates are lowered and that survival is improved in patients undergoing near-total or total thyroidectomy28,32-36 (Fig. 38-17). In addition, diminished survival is noted in patients with low-risk disease (mortality rates of 5% at 10 to 20 years), and it is not possible to accurately risk stratify patients preoperatively. In the last 10 years, a large study of >50,000 patients with papillary cancer demonstrated that, in multivariate analyses, total thyroid-ectomy led to a significantly improved recurrence and survival for tumors >1 cm. Furthermore, the authors also showed that patients with tumors 1 to 2 cm in diameter who were treated with lobectomy had a 24% higher risk of recurrence and a 49% higher risk of thyroid cancer mortality.37 Based on this informa-tion, the American Thyroid Association 2009 guidelines for the evidence-based management of thyroid cancers recommended a near-total or total thyroidectomy for primary cancers >1 cm unless there are contraindications to the surgery.38 However, additional studies since then have demonstrated no survival dif-ferences based on initial surgical procedure when adjusting for complexity/risk and comorbid diseases.39 This finding, coupled with a trend for increased use of ultrasound and Tg measure-ments to assess for recurrences and the declining use of RAI ablation, led to revised guidelines in 2015. Accordingly, either near-total/total thyroidectomy or lobectomy constitute appropriate initial treatment for tumors >1 cm and <4 cm without extrathyroidal extension or lymph node involvement (cN0). Of note, the guidelines do state that the treatment team may elect near-total/total thyroidectomy to facilitate RAI ther-apy, enhance follow-up based on disease features, or if the patient expresses a preference for complete thyroid excision.40There has also been in change in the management of pap-illary microcarcinomas (<1 cm) since at least two trials from Japan have shown that active surveillance (defined as observa-tion without immediate surgery) can be a viable and safe first line of treatment for these very-low-risk tumors without extra-thyroidal extension or lymph node metastases.41 Tumors that progress during monitoring are treated by surgery. If surgery is chosen as initial treatment for these patients, a thyroid lobec-tomy is considered sufficient.When PTC is diagnosed by FNAB, the definitive operation can be done without confirming the diagnosis by frozen section during the operation. Patients with a nodule that is suspicious for papillary cancer should be treated by thyroid lobectomy, isthmu-sectomy, and removal of any pyramidal lobe or adjacent lymph nodes. If intraoperative frozen-section examination of a lymph node or primary tumor confirms carcinoma, completion total or near-total thyroidectomy is performed. If a definitive diagnosis cannot be made or the surgeon is concerned about the viability of the parathyroid glands or the status of the RLN, the opera-tion is terminated. When final histology confirms carcinoma, completion thyroidectomy is performed if deemed necessary based on risk-stratification. During thyroidectomy, enlarged or obviously involved central neck nodes should be removed (ther-apeutic central-compartment, level VI), along with nodes with known lateral neck metastases. Some investigators recommend routine bilateral central neck dissection due to the high inci-dence of microscopic metastases and data showing improved rates of recurrence and survival (compared to historic controls). 5Brunicardi_Ch38_p1625-p1704.indd 164801/03/19 11:21 AM 1649THYROID, PARATHYROID, AND ADRENALCHAPTER 38Table 38-6TNM classification of thyroid tumors PAPILLAEY or FOLLICULAR TUMORSDIAGNOSIS AGETUMORNODEMETASTASISSTAGE<55 yearsAny TAny NM0I<55 yearsAny TAny NM1II≥55 yearsT1N0/NXM0I≥55 yearsT1N1M0II≥55 yearsT2N0/NXM0I≥55 yearsT2N1M0II≥55 yearsT3a/T3bAny NM0II≥55 yearsT4aAny NM0III≥55 yearsT4bAny NM0IVA≥55 yearsAny TAny NM1IVBMEDULLARY THYROID CANCERTUMORNODEMETASTASISSTAGET1N0M0IT2N0M0IIT3N0M0IIT1–3N1aM0IIIT4aAny NM0IVAT1–3N1bM0IVAT4bAny NM0IVBAny TAny NM1IVCANAPLASTIC CANCERTUMORNODEMETASTASISSTAGET1–T3aN0/NXM0IVAT1–T3aN1M0IVBT3bAny NM0IVBT4Any NM0IVBAny TAny NM1IVCDEFINITIONSPrimary tumor (T)TX = Primary tumor cannot be assessedT0 = No evidence of primary tumorT1 = Tumor ≤2 cm in greatest dimension limited to the thyroid T1a = Tumor ≤1 cm in greatest dimension limited to the thyroid T1b = Tumor >1 cm but ≤2 cm in greatest dimension limited to the thyroidT2 = Tumor >2 cm but ≤4 cm in greatest dimension limited to the thyroidT3 = Tumor >4 cm limited to the thyroid, or gross extrathyroidal extension invading only strap muscles T3a = Tumor >4 cm limited to the thyroid T3b = Gross extrathyroidal extension invading only strap muscles (sternohyoid, sternothyroid, thyrohyoid, or omohyoid muscles) from a tumor of any sizeT4 = Includes gross extrathyroidal extension beyond the strap muscles T4a = Gross extrathyroidal extension invading subcutaneous soft tissues, larynx, trachea, esophagus, or recurrent laryngeal nerve from a tumor of any size T4b = Gross extrathyroidal extension invading prevertebral fascia or encasing the carotid artery or mediastinal vessels from a tumor of any sizeRegional lymph nodes (N)NX = Regional lymph nodes cannot be assessedN0 = No evidence of locoregional lymph node metastasis N0a = One or more cytologically or histologically confirmed benign lymph nodes N0b = No radiologic or clinical evidence of locoregional lymph node metastasisN1 = Metastasis to regional nodes N1a = Metastasis to level VI or VII (pretracheal, paratracheal, or prelaryngeal/Delphian, or upper mediastinal) lymph nodes. This can be unilateral or bilateral disease. N1b = Metastasis to unilateral, bilateral, or contralateral lateral neck lymph nodes (levels I, II, III, IV, or V) or retropharyngeal lymph nodesDistant Metastasis (M)M0 = No distant metastasisM1 = Distant metastasisUsed with the permission of the American College of Surgeons. Amin MB, Edge SB, Greene FL, et al. (Eds.) AJCC Cancer Staging Manual, 8th Ed. Springer New York, 2017.Brunicardi_Ch38_p1625-p1704.indd 164901/03/19 11:21 AM 1650SPECIFIC CONSIDERATIONSPART IIHowever, these risks need to be balanced with the increased risk of hypoparathyroidism with routine central neck dissection and the fact that some studies do not show any difference in recur-rence rates or rates of low or undetectable Tg levels. The updated 2015 ATA guidelines for thyroid cancer management suggest that prophylactic (ipsilateral or bilateral) dissection may be per-formed in patients with advanced (T3 or T4) papillary thyroid carcinoma, or if the lateral neck nodes are involved with tumor (N1b), or if the information will help in treatment planning.40 The American Head and Neck Society urges the involvement of multidisciplinary teams in the decision-making process for pro-phylactic CND and indicates that it can be considered in patients with high risk of recurrence (to include older or young age, mul-tifocal disease and extrathyroidal extension in addition to the aforementioned factors).42 Further prospective studies are needed before definitive recommendations can be made in this regard.Biopsy-proven lymph node metastases detected clini-cally or by imaging in the lateral neck in patients with papil-lary carcinoma are managed with modified radical or functional neck dissection,40 as described later in this chapter in “Thyroid Surgery.” Dissection of the posterior triangle and suprahyoid dissection usually are not necessary unless there is extensive metastatic disease in levels 2, 3, and 4, but should be performed when appropriate. Prophylactic lateral neck node dissection is not necessary in patients with PTC because these cancers do not appear to metastasize systemically from lymph nodes, and micrometastases often can be ablated with RAI therapy.Follicular Carcinoma Follicular carcinomas account for 10% of thyroid cancers and occur more commonly in iodinedeficient areas. The overall incidence of this tumor is declining in the United States, probably due to iodine supplementation and improved histologic classification. Women have a higher incidence of follicular cancer, with a female-to-male ratio of 3:1, and a mean age at presentation of 50 years old. Follicular cancers usually present as solitary thyroid nodules, occasion-ally with a history of rapid size increase, and long-standing goi-ter. Pain is uncommon, unless hemorrhage into the nodule has occurred. Unlike papillary cancers, cervical lymphadenopathy is uncommon at initial presentation (about 5%), although distant metastases may be present. In <1% of cases, follicular cancers may be hyperfunctioning, leading patients to present with signs and symptoms of thyrotoxicosis. FNAB is unable to distinguish benign follicular lesions from follicular carcinomas. Therefore, preoperative clinical diagnosis of cancer is difficult unless dis-tant metastases are present. Large follicular tumors (>4 cm) in older men are more likely to be malignant.Due to the limitations inherent in the FNAB diagnosis, a number of studies have focused on identifying molecular mark-ers to distinguish benign from malignant follicular lesions. Many of these genetic changes can be identified using tissue obtained during FNAB. While no single marker has met the ideal charac-teristics of being simple to use, reproducible, and cost-effective, several combinations of markers appear to be useful in differen-tiating benign from malignant lesions. A commonly used panel of seven genes used to “rule in” malignancy detects mutations in BRAF, Ras, RET/PTC, and PAX/PPARg and has been associated with a sensitivity of 57% to 75%, specificity of 97% to 100%, PPV of 87% to 100%, and NPV of 79% to 86% in the case of nodules consistent with Follicular/Hürthle cell neoplasm or sus-picious of the same.43 In contrast, the Afirma Gene Expression Classifier (GEC) uses a “rule out” strategy to identify benign nodules. This method uses material from additional FNA passes (in an RNA-preserving solution) to analyze a 167 gene panel, and the results obtained are reported as benign or suspicious.44 It is reported to have a lower PPV of 37% but a better NPV of 94% for Follicular/Hürthle cell neoplasms. Next generation sequenc-ing techniques have been used to enhance malignancy detection Less than near-totalthyroidectomyP = 0.02Less thannear-totalthyroidectomy00510152025303524681012Cumulative death (%)Near-total or totalthyroidectomyNear-totalor totalthyroidectomyYears after initial therapy04361135262907227218111200640290698555464416365131432092100032Figure 38-17. Improved survival in patients with papillary or follicular thyroid cancer following total or near-total thyroidectomy compared to those who underwent less than near-total thyroidectomy. (Reproduced with permission from Mazzaferri E, Jhiang S: Long-term impact of initial surgical and medical therapy on papillary and follicular thyroid cancer, Am J Med. 1994 Nov;97(5):418-428.)Brunicardi_Ch38_p1625-p1704.indd 165001/03/19 11:21 AM 1651THYROID, PARATHYROID, AND ADRENALCHAPTER 38by including additional mutations and gene arrangements. The advanced version of this assay (ThyroSeqV2) had a sensitivity of 90%, specificity of 93%, PPV of 83%, and NPV of 96% in a study of Follicular/Hüurthle cell neoplasm/suspicious of the same nodules, making it useful as both a “rule in” and “rule out” test.45 Of note, these assays have also been evaluated in “AUS/FLUS” and “suspicious for malignancy” nodules with varying results, i.e., the performance characteristics of these tests have been noted to change depending upon the prevalence of malig-nancy in the tested population (pretest probability). At this time, the ATA guidelines do not advise molecular testing in the work-up of “suspicious for malignancy” nodules. Molecular testing may be used to supplement cytology results for malignancy risk assessment in “AUS/FLUS” or “follicular/Hürthle cell neo-plasm/suspicious of the same” nodules depending on feasibility and informed patient preference.40 Expression arrays also have been used to investigate the role of microRNAs, which are a new class of small, noncoding RNAs that have been implicated in carcinogenesis. The specific microRNAs miR-197 and miR-346 are upregulated in follicular thyroid cancers46 and have the potential to be used as diagnostic markers. Additional studies have also demonstrated the feasibility of studying a panel of microRNAs in a small number of FNA samples. ThyGenX/ThyraMIR uses a mutation panel supplemented with 10 miRNA markers,47 whereas Rosetta GX Reveal is exclusively based on miRNA markers; however, both require further validation.48Pathology. Follicular carcinomas usually are solitary lesions, and the majority are surrounded by a capsule. Histologically, follicles are present, but the lumen may be devoid of colloid. Architectural patterns depend on the degree of differentiation demonstrated by the tumor. Malignancy is defined by the pres-ence of capsular and vascular invasion (Fig. 38-18). In general, minimally invasive tumors appear grossly encapsulated and have microscopic invasion through the tumor capsule without extension into the parenchyma and/or invasion into smallto medium-sized vessels (venous caliber) in or immediately out-side the capsule, but not within the tumor. On the other hand, widely invasive tumors demonstrate evidence of large vessel invasion and/or broad areas of tumor invasion through the cap-sule. They may, in fact, be unencapsulated. It is important to note that there is a wide variation of opinion among clinicians and pathologists with respect to the above definitions. Tumor infiltration and invasion, as well as tumor thrombus within the middle thyroid or jugular veins, may be apparent at operation.Surgical Treatment and Prognosis. Patients diagnosed by FNAB as having a follicular lesion should undergo thyroid lobectomy because at least 70% to 80% of these patients will have benign adenomas. Total thyroidectomy is recommended by some surgeons in older patients with follicular lesions >4 cm because of the higher risk of cancer in this setting (50%) and certainly should be performed in patients with atypia on FNA, a family history of thyroid cancer, or a history of radiation exposure. Intraoperative frozen-section examination usually is not helpful, but it should be performed when there is evidence of capsular or vascular invasion or when adjacent lymphadenopa-thy is present. Total thyroidectomy should be performed when thyroid cancer is diagnosed. There is debate among experts about whether patients with minimally invasive follicular can-cers should undergo completion thyroidectomy because the prognosis is so good in these patients. A diagnosis of frankly invasive carcinoma or follicular carcinoma with angioinvasion, with or without capsular invasion, necessitates completion of total thyroidectomy primarily so that 131I can be used to detect and ablate metastatic disease. Prophylactic nodal dissection is not needed because nodal involvement is infrequent, but in the unusual patient with nodal metastases, therapeutic neck dissec-tion is recommended. Prophylactic central neck dissection may be considered in patients with large tumors. The cumulative mortality from follicular thyroid cancer is approximately 15% at 10 years and 30% at 20 years. Poor long-term prognosis is predicted by age over 50 years old at presentation, tumor size >4 cm, higher tumor grade, marked vascular invasion, extrathy-roidal invasion, and distant metastases at the time of diagnosis.Hürthle Cell Carcinoma Hürthle cell carcinomas account for approximately 3% of all thyroid malignancies and, under the World Health Organization classification, are considered to be a subtype of follicular thyroid cancer. Hürthle cell cancers also are characterized by vascular or capsular invasion and, there-fore, cannot be diagnosed by FNAB. Tumors contain sheets of eosinophilic cells packed with mitochondria, which are derived from the oxyphilic cells of the thyroid gland. Hürthle cell tumors differ from follicular carcinomas in that they are more often multifocal and bilateral (about 30%), usually do not take up RAI (about 5%), are more likely to metastasize to local nodes (25%) and distant sites, and are associated with a higher mortal-ity rate (about 20% at 10 years). Hence, they are considered to be a separate class of tumors by some groups.Management is similar to that of follicular neoplasms, with lobectomy and isthmusectomy being sufficient surgical treatment for unilateral Hürthle cell adenomas. When Hürthle cell neoplasms are found to be invasive on definitive paraffin-section histology, then total thyroidectomy should be performed. These patients should also undergo routine central neck node removal, similar to patients with MTC, and modified radical neck dissection when lateral neck nodes are palpable or identi-fied by ultrasonography. Although RAI scanning and ablation usually are ineffective, they probably should be considered to ablate any residual normal thyroid tissue and occasionally ablate tumors because there is no other good therapy.Postoperative Management of Differentiated Thyroid Cancer Radioiodine Therapy The issue of whether RAI therapy offers any benefit to patients with differentiated thyroid cancer Figure 38-18. Hematoxylin-eosin–stained section from follicular thyroid carcinoma showing capsular invasion.Brunicardi_Ch38_p1625-p1704.indd 165101/03/19 11:21 AM 1652SPECIFIC CONSIDERATIONSPART IIremains controversial in the absence of prospective, random-ized controlled trials. Long-term cohort studies by Mazzaferri and associates and DeGroot and colleagues demonstrate that postoperative RAI therapy reduces recurrence (Fig. 38-19) and provides a small improvement in survival, even in low-risk patients.28,34 Screening with RAI is more sensitive than chest X-ray or CT scanning for detecting metastases; however, it is less sensitive than Tg measurements for detecting metastatic disease in most differentiated thyroid cancers except Hürthle cell tumors. Screening and treatment are facilitated by the removal of all normal thyroid tissue, which effectively competes for iodine uptake. Metastatic differentiated thyroid carcinoma can be detected and treated by 131I in about 75% of patients. Multiple studies show that RAI effectively treats >70% of lung micrometastases that are detected by RAI scan in the presence of a normal chest X-ray, whereas the success rates drop to <10% with pulmonary macrometastases. Early detection therefore is very important to improve prognosis.Several features place patients at increased risk for local recurrences or metastases. The 2015 ATA guidelines use various features to risk-stratify tumors.40 Low-risk papillary thyroid cancer includes those without local tumor invasion, all macroscopic tumor resected, absence of aggressive histol-ogy (e.g., tall cell, columnar cell carcinoma), no known dis-tant metastases (clinical or on RAI scan if done), no vascular invasion, clinical N0 or ≤5 pathologic N1 micrometastases (<0.2 cm in largest dimension), intrathyroidal, encapsulated fol-licular variant of papillary thyroid cancer, intrathyroidal, well differentiated follicular thyroid cancer with capsular invasion and no or minimal (<4 foci) vascular invasion and intrathyroi-dal papillary microcarcinoma (unifocal or multifocal, including BRAFV600E mutated). Intermediate-risk tumors include those showing microscopic invasion of tumor into the perithyroidal soft tissues or RAI-avid metastatic foci in the neck on the first posttreatment whole-body RAI scan. This group also includes tumors with aggressive histology (e.g., tall cell, columnar cell carcinoma), papillary thyroid cancer with vascular invasion, clinical N1 or >5 pathologic N1 with all involved lymph nodes <3 cm in largest dimension and multifocal papillary microcar-cinoma with extra-thyroidal extension (ETE) and BRAFV600E mutated (if known). High-risk tumors include those demon-strating macroscopic invasion of tumor into the perithyroidal soft tissues (gross ETE), incomplete tumor resection, and pres-ence of distant metastases (or postoperative serum thyroglobu-lin suggestive of distant metastase) or pathologic N1 with any metastatic lymph node ≥3 cm in largest dimension. Follicular thyroid cancers with extensive vascular invasion (>4 foci of vascular invasion) also fall into this category. It is important to note that this risk assessment represents a continuum with recurrence rates from 1% to 2% for low-risk cancers to >50% for high-risk cancers.The current ATA guidelines recommend RAI therapy after surgical treatment for all patients with high-risk disease, i.e., those with gross ETE and M1 disease. RAI therapy is not rec-ommended for patients with papillary microcarcinomas, either uni -or multifocal. RAI remnant ablation is not routinely recom-mended after thyroidectomy for ATA low-risk DTC patients. However, it may be considered in patients with aggressive histology or vascular invasion. Consideration of RAI is recom-mended for patients with intermediate-risk disease and “gen-erally favored” for patients with microscopic ETE due to the risk of recurrent disease, large (>2–3 cm) or clinically evident lymph nodes (central, mediastinal, and lateral neck) or presence of extranodal extension. Advancing age may also favor RAI use. However, RAI is not needed for patients with a few (<5) microscopic nodal metastases in the central compartment in the absence of other adverse features as there is insufficient evi-dence for its utility in this setting. It is generally favored for patients with lateral neck disease. There is currently no estab-lished role for molecular testing in determining RAI therapy.Remnant ablation can be performed with either thyroid hormone withdrawal or recombinant TSH (rTSH) stimula-tion. This is based on randomized studies showing that both techniques are equally effective in preparing patients for abla-tion, with the latter being associated with an improved quality of life.49,50 In patients with ATA high-risk disease (including distant metastases), there is insufficient data to recommend thy-rogen-mediated ablation, and hormone withdrawal is preferred. Furthermore, if patients have comorbidities that can be exac-erbated by severe hypothyroidism (cardiac or psychiatric con-ditions), consideration should be given to thyrogen-mediated RAI. If hormone withdrawal is used, T4 therapy should be dis-continued for approximately 6 weeks before scanning with 131I. Patients should receive T3 during this time period to decrease the period of hypothyroidism. T3 has a shorter half-life than T4 (1 day vs. 1 week) and needs to be discontinued for 2 weeks to allow TSH levels to rise before treatment. Levels >30 mU/L are considered optimal, based on noncontrolled studies. A low-iodine diet also is recommended during this 2-week period. The usual protocol involved administering a screening dose of 1 to 3 mCi and measuring uptake 24 hours later. After a total thy-roidectomy, this value should be <1%. A “hot” spot in the neck after initial screening usually represents residual normal tissue in the thyroid bed. Some investigators recommend omitting the scanning dose altogether to minimize thyrocyte “stunning” and subsequent requirement for higher treatment doses. Others recommend scanning only if the size of the remnant cannot be determined by the operative report or ultrasound, or if the results would alter the decision to treat or the dose to be administered. Current guidelines recommend using either 123I or low-activity 131I (1to 3-mCi dose) and delivering a therapeutic dose within 72 hours.The recommended dose of RAI is 30 mCi if remnant abla-tion is performed after total thyroidectomy for ATA low-risk thyroid or intermediate-risk cancer with lower risk features (i.e., low-volume central neck nodal metastases with no other known gross residual disease or any other adverse features). If RAI is given for adjuvant treatment to treat suspected microscopic dis-ease (in the absence of metastatic disease), doses ranging from 30 to 150 mCi are recommended, and there is no solid evidence to show that higher doses reduce the recurrence rates for T3 and N1 disease in this setting.If patients have an elevated Tg level, but negative RAI scan on follow-up, some physicians recommend treating once with 100 mCi of 131I and repeating the imaging 1 to 2 weeks later. Approximately one-third of these patients demonstrate uptake on posttreatment imaging, and Tg levels usually decrease in these patients, documenting therapeutic benefit. The maxi-mum dose of radioiodine that can be administered at one time without performing dosimetry is approximately 200 mCi with a cumulative dose of 1000 to 1500 mCi. Up to 500 mCi can be given with proper pretreatment dosimetry. Recent studies also Brunicardi_Ch38_p1625-p1704.indd 165201/03/19 11:21 AM 1653THYROID, PARATHYROID, AND ADRENALCHAPTER 38Initial medical therapyall recurrencesNoneT4 aloneP< .05403530252015105P< .0001Years after initial therapyPercent cancer recurrences605040302010004035302520151050NoneT4 + RAI T4 alone T4 + RAI remnant ablation34/16315/230101/78922/1120/13551/6035/823/10217/4621/661/847/3782/541/6710/3264/390/386/2290/250/2610/1350/130/181/51Initial medical therapydistant recurrencesNoneT4 aloneP<.0002P<.02Years after initial therapyPercent distant recurrence35302520151050None 8/163 9/112 3/82 0/66 1/54 4/39 0/25 0/13T4 alone 19/789 15/603 7/462 0/378 2/326 4/229 8/135 1/51T4 + RAI 2/230 0/135 1/102 0/84 1/67 0/38 0/26 0/11T4 + RAI remnant ablationABFigure 38-19. Tumor recurrence at a median of 16.7 years after thyroid surgery. The numerator is the number of patients with recurrence, and the denominator is the number of patients in each time interval. The P values are derived from log-rank statistical analysis of 40-year life-table data. Figure shows that all recurrences (A) and distant metastases (B) were reduced in patients who received radioactive iodine (RAI) in addition to thyroxine (T4) therapy. (Reproduced with permission from Mazzaferri E, Kloos R: Current approaches to primary therapy for papillary and follicular thyroid cancer, Clin Endocrinol Metab. 2001 Apr;86(4):1447-1363.)Brunicardi_Ch38_p1625-p1704.indd 165301/03/19 11:21 AM 1654SPECIFIC CONSIDERATIONSPART IIshow an increase in the number of second cancers in patients treated with RAI.51 The early and delayed complications of RAI therapy are listed in Table 38-7.Thyroid Hormone T4 is necessary as replacement therapy in patients after total or near-total thyroidectomy, and also has the additional effect of suppressing TSH and reducing the growth stimulus for any possible residual thyroid cancer cells. TSH suppression reduces tumor recurrence rates. Current guidelines advise maintaining initial TSH levels <0.1 mU/mL in patients with high-risk thyroid cancer and in the range of 0.1 to 0.5 mU/mL in patients with intermediate-risk disease. For low-risk patients (with or without remnant ablation) with undetectable serum Tg levels, TSH levels can be maintained at the lower end of the reference range (0.5–2 mU/L). If these patients have low measureable Tg levels, it is recommended that TSH be maintained at or slightly below lower limit of normal (0.1 to 0.5 mU/L) while continuing surveillance for recurrence. In low-risk patients treated with lobectomy alone, it is advised to keep TSH in the mid to lower reference range (0.5–2 mU/L), and hor-mone therapy may be needed to maintain these levels. Further TSH suppression levels are determined by response to therapy. The risk of tumor recurrence must be balanced with the side effects associated with prolonged TSH suppression, including osteopenia and cardiac problems, particularly in older patients.Follow-Up of Patients With Differentiated Thyroid Cancer Thyroglobulin Measurement Tg and anti-Tg antibody levels should be measured initially at 6 to 12 month intervals and more frequently in patients with high-risk tumors. Further measure-ments are guided by response to therapy. Patients are considered to have an excellent response to treatment if suppressed Tg is <0.2 ng/mL and stimulated Tg is <1 ng/mL with negative imag-ing. In these patients, Tg levels can be followed every 12 to 24 months while on thyroid hormone as their risk of recurrence is low (1–4%). Patients with structurally or biochemically incomplete (negative imaging but suppressed Tg ≥1 ng/mL or stimulated Tg ≥10 ng/mL or rising anti-Tg levels) or indeter-minate responses (nonspecific imaging findings, suppressed Tg detectable but <1 ng/mL, and stimulated Tg detectable but <10 ng/mL or stable or declining anti-Tg levels) require addi-tional investigations.40 Tg measurements in FNAB aspirates have also been shown to be useful in the detection of nodal metastatic disease.52Imaging After the first posttreatment scan, lowand some intermediate-risk patients with negative TSH-stimulated Tg and cervical ultrasound do not require routine diagnostic whole-body radioiodine scans. However, diagnostic whole-body scans 6 to 12 months after remnant ablation may be of value in the follow-up of patients with highor intermediate-risk patients with higher risk features. Other scenarios for follow-up scans include patients with abnormal uptake outside the thyroid bed on posttherapy scan, those with poorly informative postablation scans (e.g., due to high thyroid bed uptake), and patients with Tg antibodies.Cervical ultrasound be performed to evaluate the thyroid bed and central and lateral cervical nodal compartments at 6 and 12 months after thyroidectomy and then annually for at least 3 to 5 years, depending on the patient’s risk for recurrent disease and Tg status. Sonographically suspicious nodes ≥8 to 10 mm on the smallest diameter measurement should be biopsied for cytology as well as Tg measurement in the aspirate washout. Smaller nodes can be followed and biopsied if there is contin-ued growth. FDG-PET and PET-CT scans have been shown to be useful to localize recurrent or persistent thyroid cancer in patients who have Tg-positive, RAI scan–negative disease. FDG-PET can also be useful for the initial staging of patients with poorly differentiated thyroid carcinomas or Hürthle cell tumors, particularly in patients with other evidence of disease on imaging or Tg levels. In addition, they may be used as a prog-nostic tool in patients with metastatic disease and to evaluate the response to treatment in patients with metastatic or locally advanced disease.Additional Treatment Modalities Radiotherapy, Thermal Ablation, and Chemotherapy  External-beam radiotherapy is occasionally required to control unresectable, locally invasive, or recurrent disease and to treat metastases in support bones to decrease the risk of fractures. It also is of value for the treatment and control of pain from bony metastases when there is minimal or no RAIU. Stereotac-tic brain radiotherapy and intensity-modulated radiation therapy have both been used successfully for metastatic lesions. Percuta-neous thermal ablation by increasing (radiofrequency ablation) or decreasing temperature (cryoablation) in the lesion to induce irreversible cellular damage has shown promise for lung, bone, and liver lesions.53,54 Single-drug and multidrug chemotherapy has been used with little success in disseminated thyroid can-cer, and there is no role for routine chemotherapy. Doxorubicin (Adriamycin) and paclitaxel (Taxol) were previously the most frequently used agents. The former acts as a radiation sensitizer and should be considered in patients undergoing external-beam radiation.Novel Therapies These therapies are directed at the molecular pathways known to be involved in thyroid cancers. Sorafenib Table 38-7Complications of radioactive iodine therapy (131I) and doses at which they are observedACUTELONG-TERMNeck pain, swelling, and tendernessThyroiditis (if remnant present)Sialadenitis (50–450 mCi), taste dysfunctionHemorrhage (brain metastases)Cerebral edema (brain metastases, 200 mCi)Vocal cord paralysisNausea and vomiting (50–450 mCi)Bone marrow suppression (200 mCi)HematologicBone marrow suppression (>500 mCi)Leukemia (>1000 mCi)FertilityOvarian/testicular damage, infertilityIncreased spontaneous abortion ratePulmonary fibrosisChronic sialadenitis, nodules, taste dysfunctionIncreased risk of cancerAnaplastic thyroid cancerGastric cancerHepatocellular cancerLung cancerBreast cancer (>1000 mCi)Bladder cancerHypoparathyroidismBrunicardi_Ch38_p1625-p1704.indd 165401/03/19 11:21 AM 1655THYROID, PARATHYROID, AND ADRENALCHAPTER 38and lenvatinib are U.S. Food and Drug Administration (FDA) and European Medical Agency (EMA)-approved for use in patients with advanced differentiated thyroid cancer that is non-responsive to RAI after evaluation in phase 3 placebo-controlled double blinded trials (the DECISION study and the SELECT study, respectively).55,56 Both drugs are multikinase inhibitors and target RET kinase and the vascular endothelial growth factor (VEGF)-receptor; however, lenvatinib also inhib-its the fibroblast growth factor and the platelet-derived growth factor receptor. Sorafenib demonstrated progression-free sur-vival (PFS) improvement by 5 months with about 12% partial response rates, whereas lenvatinib prolonged median PFS by 15.7 months compared with placebo with response rates of 65%, including some complete responses. Vandetanib is mainly a RET-kinase inhibitor, but it also affects the VEGF-receptor and epidermal growth factor receptor. It has been evaluated in a phase 2 trial and also demonstrated an improved PFS.57 However, none of the agents show improvements in overall survival. Moreover, they are associated with significant side effects (diarrhea, fatigue hypertension, hepatotoxicity, bleed-ing, and thrombosis) that affect patient quality of life. As such, they are considered only in patients with metastatic, rapidly progressive, symptomatic disease that is unable to respond to other local treatment approaches and generally in the context of clinical trials. Oncogenic kinase inhibitors that selectively inhibit the mutant V600E BRAF kinase (dabrafenib) has also shown promise in treating a subset of patients with advanced differentiated thyroid cancer.58Medullary Carcinoma MTC accounts for about 5% of thyroid malignancies and arises from the parafollicular or C cells of the thyroid, which, in turn, are derived from the ultimobranchial bod-ies. These cells are concentrated superolaterally in the thyroid lobes, and this is where MTC usually develops. C cells secrete calcitonin, a 32-amino-acid polypeptide that functions to lower serum calcium levels, although its effects in humans are mini-mal. Most MTCs occur sporadically. However, approximately 25% occur within the spectrum of several inherited syndromes such as familial MTC, MEN2A, and MEN2B. All these variants are known to result secondary to germline mutations in the RET proto-oncogene. The syndromes also are characterized by geno-type-phenotype correlations, with specific mutations leading to particular clinical manifestations. The salient clinical and genetic features of these syndromes are outlined in Table 38-8. Some clinical features of MEN2B patients are shown in Fig. 38-20.Table 38-8Clinical and genetic features of medullary thyroid cancer syndromesSYNDROMEMANIFESTATIONSRET MUTATIONSMEN2A MTC, pheochromocytoma, primary hyperparathyroidism, lichen planus amyloidosis Exon 10—codons 609, 611, 618, 620Exon 11—codon 634 (more commonly associated with pheochromocytoma and primary hyperparathyroidism)MEN2BMTC, pheochromocytoma, Marfanoid habitus, mucocutaneous ganglioneuromatosisExon 16—codon 918Familial MTCMTCCodons 609, 611, 618, 620, and 634  Codons 768, 790, 791, or 804 (rare)MEN2A and Hirschsprung’s diseaseMTC, pheochromocytoma, primary hyperparathyroidism, Hirschsprung’s diseaseCodons 609, 618, 620MEN2 = multiple endocrine neoplasia type 2; MTC = medullary thyroid cancer.BAFigure 38-20. Features of MEN2B: thickened lips (A) and mucosal neuromas (A and B).Brunicardi_Ch38_p1625-p1704.indd 165501/03/19 11:21 AM 1656SPECIFIC CONSIDERATIONSPART IIPatients with MTC often present with a neck mass that may be associated with palpable cervical lymphadenopathy (15% to 20%). Pain or aching is more common in patients with these tumors, and local invasion may produce symptoms of dys-phagia, dyspnea, or dysphonia. Distant blood-borne metastases to the liver, bone (frequently osteoblastic), and lung occur later in the disease. The female-to-male ratio is 1.5:1. Most patients present between 50 and 60 years old, although patients with familial disease present at a younger age. Medullary thyroid tumors secrete not only calcitonin and carcinoembryonic anti-gen (CEA), but also other peptides such as calcitonin gene–related peptide, histaminadases, prostaglandins E2 and F2α, and serotonin. Patients with extensive metastatic disease frequently develop diarrhea, which may result from increased intestinal motility and impaired intestinal water and electrolyte flux. About 2% to 4% of patients develop Cushing’s syndrome as a result of ectopic production of adrenocorticotropic hormone (ACTH).Pathology. MTCs typically are unilateral (80%) in patients with sporadic disease and multicentric in familial cases, with bilateral tumors occurring in up to 90% of familial patients. Familial cases also are associated with C-cell hyperplasia, which is considered a premalignant lesion. Microscopically, tumors are composed of sheets of infiltrating neoplastic cells separated by collagen and amyloid. Marked heterogeneity is present; cells may be polygonal or spindle shaped. The presence of amyloid is a diagnostic finding, but immunohistochemistry for calcitonin is more commonly used as a diagnostic tumor marker. These tumors also stain positively for CEA and calcito-nin gene–related peptide.Diagnosis. The diagnosis of MTC is established by history, physical examination, raised serum calcitonin, or CEA levels, and FNAB cytology of the thyroid mass. Attention to family history is important because about 25% of patients with MTC have familial disease. Because it is not possible to distinguish sporadic from familial disease at initial presentation, all new patients with MTC should be screened for RET point mutations, pheochromocytoma, and HPT. Screening of patients with famil-ial MTC for RET point mutations has largely replaced using provocative testing with pentagastrin or calcium-stimulated calcitonin levels to make the diagnosis. Calcitonin and CEA are used to identify patients with persistent or recurrent MTC. Calcitonin is a more sensitive tumor marker, but CEA is a better predictor of prognosis.Treatment. The ATA published revised guidelines for the man-agement of medullary cancers in 2015.59 A neck ultrasound is recommended to evaluate the central and lateral neck compart-ments and the superior mediastinum. Serum calcitonin, CEA, calcium levels should also be measured, and RET proto-onco-gene mutation testing should be performed. Pheochromocy-tomas need to be excluded. If patients are found to have a pheochromocytoma, this must be operated on first. Primary hyperparathyroidism, if present, is treated at the time of thyroidectomy. These tumors are generally (>50%) bilateral. Total thyroidectomy is the treatment of choice for patients with MTC because of the high incidence of multicentricity, the more aggressive course, and the fact that 131I therapy usually is not effective.Central compartment nodes frequently are involved early in the disease process, so that a bilateral prophylactic central neck node dissection should be routinely performed. In patients with palpable or imaging-detected cervical nodes, symptoms and signs of distant disease or calcitonin levels >500 pg/mL, additional imaging to include a neck and chest CT and a triple-phase liver CT or contrast-enhanced MRI and an axial MRI/bone scan is recommended to assess for metastatic disease. In patients with no distant disease but nodal involvement, an ipsilateral or bilateral lateral neck dissection (levels IIA, III, IV, and V) is performed. Less aggressive neck surgery should be consid-ered to preserve speech and swallowing while maintaining locoregional control in patients with limited metastatic disease. The role of prophylactic lateral neck dissection is controversial and may be considered based on calcitonin levels. Some groups favor this procedure if central neck lymph nodes are involved or if the primary tumor is ≥1.5 cm.In the case of locally recurrent or widely metastatic dis-ease, tumor debulking is advised not only to ameliorate symp-toms of pain, flushing, and diarrhea, but also to decrease risk of death from recurrent central neck or mediastinal disease. External-beam radiotherapy is controversial but can be consid-ered for patients with resected T4 disease and for patients with unresectable residual or recurrent tumor and symptomatic bony metastases. Liver metastases tend to be multiple and are typi-cally not amenable to resection, percutaneous ethanol ablation, or radiofrequency ablation. However, chemoembolization may be helpful in this setting. There is no effective chemotherapy regimen.Various targeted therapies directed against the RET kinase have been investigated for the treatment of MTC.43 Many of these also inhibit VEGF receptor due to their close structural similarities. Sorafenib, sunitinib, lenvatinib, and cabozantinib are some such multikinase inhibitors, whereas axitinib and pazopanib act only on VEGFR. Vandetanib inhibits both targets and is also an EGF receptor inhibitor, and cabozantinib targets c-MET in addition to RET and VEGF receptor. Both drugs are currently approved by the FDA and EMA for the treatment of advanced and progressive MTC based on data that they prolong progression-free survival, in addition to reducing secretion of calcitonin and CEA.60,61 They are recommended as first-line sys-temic therapy in symptomatic patients with advanced MTC. An anti-CEA monoclonal antibody (labetuzumab) also has shown antitumor response in a small group of patients. Patients with recurrent/metastatic disease should be enrolled in well-designed clinical trials.In patients who have hypercalcemia and an increased PTH at the time of thyroidectomy, only obviously enlarged parathy-roid glands should be removed. The other parathyroid glands should be preserved and marked in patients with normocalce-mia, as only about 20% of patients with MEN2A develop HPT. When a normal parathyroid cannot be maintained on a vascu-lar pedicle, it should be removed, biopsied to confirm that it is a parathyroid, and then autotransplanted to the forearm of the nondominant arm, particularly in patients with MEN2A. Reim-plantation into the sternocleidomastoid muscle is also accept-able for patients with known MEN2B and familial MTC.Prophylactic total thyroidectomy is indicated in RET mutation carriers once the mutation is confirmed. The ATA guidelines stratify mutation into various risk levels to offer recommendations regarding age at which a prophylactic Brunicardi_Ch38_p1625-p1704.indd 165601/03/19 11:21 AM 1657THYROID, PARATHYROID, AND ADRENALCHAPTER 38Figure 38-21. Magnetic resonance imaging scan of a patient with anaplastic thyroid cancer. Note heterogeneity consistent with necrosis.thyroidectomy should be performed and to predict phenotypes, including pheochromocytomas.59 In general, in patients with less aggressive mutations (designated ATA moderate-risk), thy-roidectomy may be delayed >5 years, especially if there is a nor-mal annual serum calcitonin, neck ultrasound, less aggressive family history, or family preference. Children with MEN2A and mutations at codon 634 (designated high-risk) are advised to undergo thyroidectomy at <5 years of age, and those with MEN2B-related mutations (designated highest-risk) should undergo the procedure before age 1. Central neck dissection can be avoided in children who are RET-positive and calcitonin-negative with a normal ultrasound examination. When the cal-citonin is increased or the ultrasound suggests a thyroid cancer, a prophylactic central neck dissection is indicated.Postoperative Follow-Up and Prognosis. Patients are fol-lowed by annual measurements of calcitonin and CEA levels, in addition to history and physical examination. Other modalities used to localize recurrent disease include ultrasound, CT, MRI, and more recently, FDG-PET/CT scans. Prognosis is related to disease stage. The 10-year survival rate is approximately 80% but decreases to 45% in patients with lymph node involvement. Survival also is significantly influenced by disease type. It is best in patients with non-MEN familial MTC, followed by those with MEN2A, and then those with sporadic disease. Progno-sis is the worst (survival of 35% at 10 years) in patients with MEN2B. Performing prophylactic surgery in RET oncogene mutation carriers not only improves survival rates but also ren-ders most patients calcitonin free.Anaplastic Carcinoma Anaplastic carcinoma accounts for approximately 1% of all thyroid malignancies in the United States. Women are more commonly affected, and the majority of tumors present in the seventh and eighth decade of life. The typical patient has a long-standing neck mass, which rapidly enlarges and may be painful. Associated symptoms such as dys-phonia, dysphagia, and dyspnea are common. The tumor is large and may be fixed to surrounding structures or may be ulcerated with areas of necrosis (Fig. 38-21). Lymph nodes usually are palpable at presentation. Evidence of metastatic spread also may be present. Diagnosis is confirmed by FNAB revealing char-acteristic giant and multinucleated cells. Differential diagnoses on FNA can include lymphomas, medullary carcinomas, direct extension from a laryngeal carcinoma, or other metastatic car-cinomas or melanoma. When spindle cell elements are present, primary and metastatic sarcomas need to be considered as well. Immunohistochemical markers can aid with excluding other diagnoses. Core or incisional biopsy occasionally is needed to confirm the diagnosis, especially when there is necrotic material on the FNA.Pathology. On gross inspection, anaplastic tumors are firm and whitish in appearance. Microscopically, sheets of cells with marked heterogeneity are seen. The three main histologic growth patterns are spindle cell, squamoid, and pleomorphic giant cell. Tumors may show a predominance of one pattern or a mixture of various patterns. Foci of more differentiated thy-roid tumors, either follicular or papillary, may be seen, suggest-ing that anaplastic tumors arise from more well-differentiated tumors.Treatment and Prognosis. This tumor is one of the most aggressive thyroid malignancies, with few patients surviving 6 months beyond diagnosis. All forms of treatment have been disappointing. The ATA has published guidelines for the man-agement of patients with anaplastic cancer.62 Imaging (ultra-sound, CT, MRI, or PET-CT) should be obtained to assess resectability. All patients should have preoperative laryngos-copy to assess the status of the vocal cords. A total or near-total thyroidectomy with therapeutic lymph node dissection is rec-ommended for patients with an intrathyroidal mass (although lobectomy may also be appropriate, particularly if there is concern for vocal cord paralysis). If extrathyroidal extension is present, an en bloc resection should be considered if all gross disease can be removed (R1). Tracheostomy should be avoided as long as possible unless there is impending airway loss. Adjuvant radiation which should be offered to patients with a good performance status and no metastatic disease who desire aggressive management. Cytotoxic chemotherapy (with some combination of a taxane, anthracycline, and platinum) is typi-cally given concurrently and has been associated with prolonged survival, although these agents are also being used in a neoadju-vant fashion, particularly in patients with unresectable disease.Lymphoma Lymphomas account for <1% of thyroid malignan-cies, and most are of the non-Hodgkin’s B-cell type. Although the disease can arise as part of a generalized lymphomatous con-dition, most thyroid lymphomas develop in patients with chronic lymphocytic thyroiditis. Chronic antigenic lymphocyte stimu-lation has been suggested to result in lymphocyte transforma-tion. Patients usually present with symptoms similar to those of patients with anaplastic carcinoma, although the rapidly enlarg-ing neck mass often is painless. Patients may present with acute respiratory distress. Ultrasound can be useful for early diagno-sis, and lymphoma appears as a well-defined hypoechoic mass. The diagnosis usually is suggested by FNAB, but FNAB can be nondiagnostic, particularly in the setting of low-grade lym-phomas. Therefore, needle core or open biopsy may be neces-sary for definitive diagnosis. Staging studies should be obtained expeditiously to assess the extent of extrathyroidal spread.Brunicardi_Ch38_p1625-p1704.indd 165701/03/19 11:21 AM 1658SPECIFIC CONSIDERATIONSPART IITreatment and Prognosis. Patients with thyroid lymphoma respond rapidly to chemotherapy (CHOP—cyclophosphamide, doxorubicin, vincristine, and prednisone), which also has been associated with improved survival. Combined treatment with radiotherapy and chemotherapy often is recommended. Thy-roidectomy and nodal resection are used to alleviate symptoms of airway obstruction in patients who do not respond quickly to the above regimens or who have completed the regimen before diagnosis. Prognosis depends on the histologic grade of the tumor and whether the lymphoma is confined to the thy-roid gland or is disseminated. The overall 5-year survival rate is about 50%; patients with extrathyroidal disease have markedly lower survival rates.Metastatic Carcinoma The thyroid gland is a rare site of metastases from other cancers, including kidney, breast, lung, and melanoma. Clinical examination and a review of the patient’s history often suggest the source of the metastatic dis-ease, and FNAB usually provides definitive diagnosis. Resec-tion of the thyroid, usually lobectomy, may be helpful in many patients, depending on the status of their primary tumor.Thyroid Surgery Conduct of Thyroidectomy Patients with any recent or remote history of altered phonation or prior neck or upper chest surgery that places the recurrent laryngeal or vagus nerves at risk should undergo vocal cord assessment by direct or indirect laryngos-copy before thyroidectomy. Laryngeal examination is also advised in patients with known posterior extension of thyroid cancer and extensive central nodal metastases.40 The patient is positioned supine, with a sandbag between the scapulae. The head is placed on a donut cushion, and the neck is extended to provide maximal exposure. A Kocher transverse collar incision, typically 3 to 5 cm in length, is placed in or parallel to a natu-ral skin crease 1 cm below the cricoid cartilage (Fig. 38-22A), although longer incisions may be needed. The subcutaneous tis-sues and platysma are incised sharply, and subplatysmal flaps are raised superiorly to the level of the thyroid cartilage and inferiorly to the suprasternal notch (Fig. 38-22B). The strap muscles are divided in the midline along the entire length of the mobilized flaps, and the thyroid gland is exposed. On the side to be approached first, the sternohyoid muscles are sepa-rated from the underlying sternothyroid muscle by blunt dissec-tion until the internal jugular vein and ansa cervicalis nerve are identified. The strap muscles rarely need to be divided to gain exposure to the thyroid gland. If this maneuver is necessary, the muscles should be divided high to preserve their innervation by branches of the ansa cervicalis. If there is evidence of direct tumor invasion into the strap muscles, the portion of involved muscle should be resected en bloc with the thyroid gland. The sternothyroid muscle is then dissected off the underlying thyroid by a combination of sharp and blunt dissection, thus exposing the middle thyroid veins. The thyroid lobe is retracted medially and anteriorly, and the lateral tissues are swept posterolaterally using a peanut sponge. The middle thyroid veins are ligated and divided (Fig. 38-22C). Attention is then turned to the midline where Delphian nodes and the pyramidal lobe are identified. The fascia just cephalad and caudad to the isthmus is divided. The superior thyroid pole is identified by retracting the thyroid first inferiorly and medially, and then the upper pole of the thy-roid is mobilized caudally and laterally. The dissection plane is kept as close to the thyroid as possible, and the superior pole vessels are individually identified, skeletonized, ligated, and divided low on the thyroid gland to avoid injury to the exter-nal branch of the superior laryngeal nerve (Fig. 38-22D). Once these vessels are divided, the tissues posterior and lateral to the superior pole can be swept from the gland in a posteromedial direction, to reduce the risk of damaging vessels supplying the upper parathyroid.The RLNs should then be identified, and the ATA 2015 guidelines strongly recommend visual identification in all cases.40 The course of the right RLN is more oblique than the left RLN. The nerves can be most consistently identified at the level of the cricoid cartilage. The parathyroids usually can be identified within 1 cm of the crossing of the inferior thyroid artery and the RLN, although they also may be ectopic in loca-tion. The lower pole of the thyroid gland should be mobilized by gently sweeping all tissues dorsally. The inferior thyroid vessels are dissected, skeletonized, ligated, and divided as close to the surface of the thyroid gland as possible to minimize devascular-ization of the parathyroids (extracapsular dissection) or injury to the RLN. The RLN is most vulnerable to injury in the vicinity of the ligament of Berry. The nerve often passes through this structure along with small crossing arterial and venous branches (Fig. 38-22E). Any bleeding in this area should be controlled with gentle pressure before carefully identifying the vessel and ligating it. Use of the electrocautery should be avoided in prox-imity to the RLN. Once the ligament is divided, the thyroid can be separated from the underlying trachea by sharp dissection. The pyramidal lobe, if present, must be dissected in a cephalad direction to above the level of the notch in the thyroid cartilage or higher in continuity with the thyroid gland. If a lobectomy is to be performed, the isthmus is divided flush with the trachea on the contralateral side and suture ligated. The procedure is repeated on the opposite side for a total thyroidectomy.Parathyroid glands located anteriorly on the surface of the thyroid that cannot be dissected from the thyroid with a good blood supply or that have been inadvertently removed during the thyroidectomy should be resected, confirmed as parathy-roid tissue by frozen section, divided into 1-mm fragments, and reimplanted into individual pockets in the sternocleido-mastoid muscle. The sites should be marked with silk sutures and a clip. Various novel techniques using indocyanine fluo-rescence angiography and near-infrared autofluorescence have shown utility in the identification and viability assessment of parathyroid glands; however, they are not routinely used at the present time.63,64 If a subtotal thyroidectomy is to be performed, once the superior pole vessels are divided and the thyroid lobe mobilized anteriorly, the thyroid lobe is cross-clamped with a Mayo clamp, leaving approximately 4 g of the posterior por-tion of the thyroid. The thyroid remnant is suture ligated, taking care to avoid injury to the RLN. Routine drain placement rarely is necessary. After adequate hemostasis is obtained, the strap muscles are reapproximated in the midline. The platysma is approximated in a similar fashion. The skin can be closed with subcuticular sutures or clips.Nerve Monitoring Intraoperative RLN and external laryngeal nerve monitoring techniques are being increasingly used during thyroid and parathyroid surgery. Both continuous monitoring using endotracheal tube electrodes and intermittent monitor-ing by periodic stimulation and laryngeal palpation are used. Many published studies have established the feasibility of nerve monitoring; however, none were able to show that the technique equivocally reduces nerve injury (particularly by experienced Brunicardi_Ch38_p1625-p1704.indd 165801/03/19 11:21 AM 1659THYROID, PARATHYROID, AND ADRENALCHAPTER 38Figure 38-22. Conduct of thyroidectomy. A. Correct placement of thyroidectomy incision. B. Raising subplatysmal flaps. C. Dissection of middle thyroid vein. D. Dissection of the superior pole vessels, which should be individually ligated. E. Dissection at the ligament of Berry. Note small artery and vein within the ligament and the recurrent laryngeal nerve coursing laterally. F. Endoscopic thyroidectomy via axillary incisions. m. = muscle; n. = nerve; v. = vein.IncorrectCricoid cartilageCorrectAPlatysmaCauteryFive straight clamps on dermisBMiddle thyroid v.CCricothyroid m.External branch ofsuperior laryngeal n.Superior thyroid vesselsDBrunicardi_Ch38_p1625-p1704.indd 165901/03/19 11:21 AM 1660SPECIFIC CONSIDERATIONSPART IISmall artery & veinin ligament of BerryRecurrent laryngeal n.ThyroidEFFigure 38-22. (Continued)surgeons and especially when the RLN is routinely visually identified) until recently. In 2009, Barczynski and colleagues65 were the first to demonstrate in their prospective randomized trial with 2000 nerves at risk that neuromonitoring was asso-ciated with a statistically significant improvement in transient RLN injury rates when compared to the practice of visualiza-tion of the nerve alone and particularly in patients at higher risk of nerve injury. Of note, there was no difference in permanent RLN injury rates, and a later meta-analysis of all the published studies also failed to show a protective effect of neuromonitor-ing. Despite conflicting data, the technology has become widely adopted. The current ATA guidelines recommend that intraop-erative neural stimulation may be used to facilitate nerve iden-tification of the RLN and confirm its function, especially prior to proceeding with contralateral thyroidectomy.Minimally Invasive Approaches Several approaches to minimally invasive thyroidectomy have been described. Miniincision procedures use a small, 3-cm incision with no flap creation and minimal dissection to deliver the thyroid into the wound and then perform the pretracheal and paratracheal dissec-tion. Video assistance can be used to improve the visualization Brunicardi_Ch38_p1625-p1704.indd 166001/03/19 11:21 AM 1661THYROID, PARATHYROID, AND ADRENALCHAPTER 38via the small incision. Totally endoscopic approaches also have been described, via the supraclavicular, anterior chest, axillary, and breast approach. The axillary, anterior chest, and breast approaches eliminate the skin incision in the neck but are more invasive. The endoscopic approaches can also be performed with the assistance of robotic techniques. More recently, there have been studies of transoral robotic-assisted thyroidectomy in which the thyroid is approached through the oral cavity.66 These methods are feasible, but clear benefits over the “tradi-tional” open approach via small neck incisions have not been established.4Typically, endoscopic thyroidectomies are performed under general anesthesia. For the axillary approach, a 30-mm skin incision is made in the axilla, and 12-mm and 5-mm trocars are inserted through this incision (Fig. 38-22F). An additional 5-mm trocar is inserted adjacent to the incision. For the anterior chest approach, a 12-mm skin incision is made in the skin of the anterior chest approximately 3 to 5 cm below the border of the ipsilateral clavicle. Two additional 5-mm trocars are inserted by endoscopic guidance below the ipsilateral clavicle, and carbon dioxide (CO2) is then insufflated up to a pressure of 4 mmHg to facilitate creation of a working space. The anterior border of the sternocleidomastoid muscle is then separated from the ster-nohyoid muscle to expose the sternothyroid muscle. The thy-roid gland is exposed by splitting the sternothyroid muscle. The lower pole is retracted upward and dissected from the adipose tissue to identify the RLN. As the RLN is exposed, Berry’s liga-ment is exposed and incised with a 5-mm clip or laparoscopic coagulating shears. The upper pole of the thyroid gland is sepa-rated from the cricothyroid muscle, and the external branch of the superior laryngeal nerve can be identified during this maneu-ver. The upper pole of the thyroid gland then is dissected free.Surgical Removal of Intrathoracic Goiter A goiter is consid-ered mediastinal if at least 50% of the thyroid tissue is located intrathoracically. Mediastinal goiters can be primary or second-ary. Primary mediastinal goiters constitute approximately 1% of all mediastinal goiters and arise from accessory (ectopic) thy-roid tissue located in the chest. These goiters are supplied by intrathoracic blood vessels and do not have any connection to thyroid tissue in the neck. The vast majority of mediastinal goi-ters are, however, secondary mediastinal goiters that arise from downward extension of cervical thyroid tissue along the fascial planes of the neck and derive their blood supply from the supe-rior and inferior thyroid arteries. Virtually all intrathoracic goi-ters can be removed via a cervical incision. Patients who have (a) invasive thyroid cancers, (b) had previous thyroid operations and may have developed parasitic mediastinal vessels, or (c) pri-mary mediastinal goiters with no thyroid tissue in the neck may require a median sternotomy for removal.49 The chest, however, should be prepared in most cases in the event it is necessary to perform a median sternotomy to control mediastinal bleeding or completely remove an unsuspected invasive cancer. The goiter is approached via a neck incision. The superior pole vessels and the middle thyroid veins are identified and ligated first. Early division of the isthmus helps with subsequent mobilization of the substernal goiter from beneath the sternum. Placement of large 1-0 or 2-0 sutures deep into the goiter, when necessary, helps deliver it. For patients in whom thyroid cancer is suspected or demonstrated in an intrathoracic gland, attempts should be made to avoid rupture of the thyroid capsule. When sternotomy is indicated, the sternum usually should be divided to the level of the third intercostal space and then laterally on one side at the space between the third and fourth ribs (Fig. 38-23).Central and Lateral Neck Dissection for Nodal Metastases  Central compartment (medial to the carotid sheath) lymph nodes frequently are involved in patients with papillary, medullary, and Hürthle cell carcinomas and should be removed at the time of thyroidectomy, preserving the RLNs and parathyroid glands. Central neck dissection is particularly important in patients with medullary and Hürthle cell carcinoma because of the high fre-quency of microscopic tumor spread and because these tumors cannot be ablated with 131I. An ipsilateral modified radical neck dissection is indicated in the presence of palpable cervical lymph nodes or prophylactically in some patients with medul-lary carcinoma.A modified radical (functional) neck dissection can be per-formed via the cervical incision used for thyroidectomy, which can be extended laterally (Fig. 38-24A) to the anterior margin of the trapezius muscle. The procedure involves removal of all fibro-fatty tissue along the internal jugular vein (levels II, III, and IV) and the posterior triangle (level V). In contrast to a radical neck dissection, the internal jugular vein, the spinal accessory nerve, the cervical sensory nerves, and the sternoclei-domastoid muscle are preserved unless they are adherent to or invaded by tumor. The procedure begins by opening the plane between the strap muscles medially and the sternocleidomas-toid muscle laterally. The anterior belly of the omohyoid muscle is retracted laterally, and the dissection is carried posteriorly until the carotid sheath is reached. The internal jugular vein is retracted medially with a vein retractor and the fibro-fatty tissue and lymph nodes are dissected away from it by a combination of sharp and blunt dissection. The lateral dissection is carried along the posterior border of the sternocleidomastoid muscle, remov-ing the tissue from the posterior triangle. The deep dissection plane is the anterior scalenus muscle, the phrenic nerve, the bra-chial plexus, and the medial scalenus muscle. The phrenic nerve is preserved on the scalenus anterior muscle, as are the cervical sensory nerves in most patients (Fig. 38-24B). Dissection along the spinal accessory nerve superiorly is most important because this is a frequent site of metastatic disease.123Figure 38-23. Conduct of thyroidectomy. Incisions for a partial sternotomy.Brunicardi_Ch38_p1625-p1704.indd 166101/03/19 11:21 AM 1662SPECIFIC CONSIDERATIONSPART IIComplications of Thyroid Surgery Nerves, parathyroids, and surrounding structures are all at risk of injury during thyroidec-tomy. Injury to the RLN may occur by severance, ligation, or traction, but should occur in <1% of patients undergoing thy-roidectomy by experienced surgeons. The RLN is most vulner-able to injury during the last 2 to 3 cm of its course, but also can be damaged if the surgeon is not alert to the possibility of nerve branches and the presence of a nonrecurrent nerve, par-ticularly on the right side. If the injury is recognized intraopera-tively, most surgeons advocate primary reapproximation of the perineurium using nonabsorbable sutures. Approximately 20% of patients are at risk of injury to the external branches of the 123McFee incisionABSpinal accessory n.Phrenic n.Vagus n.Scalenusanticus m.LymphnodesCarotid a. Internaljugular v.Figure 38-24. Conduct of neck dissection. A. Incisions for modified radical neck dissection. B. Anatomic relations of structures identified during a modified radical neck dissection. a. = artery; m. = muscle; n. = nerve.Brunicardi_Ch38_p1625-p1704.indd 166201/03/19 11:21 AM 1663THYROID, PARATHYROID, AND ADRENALCHAPTER 38superior laryngeal nerve, especially if superior pole vessels are ligated en masse. The cervical sympathetic trunk is at risk of injury in invasive thyroid cancers and retroesophageal goiters and may result in Horner’s syndrome. Transient hypocalcemia (from surgical injury or inadvertent removal of parathyroid tis-sue) has been reported in up to 50% of cases, but permanent hypoparathyroidism occurs <2% of the time. Postoperative hypocalcemia is more likely in patients who undergo concomi-tant thyroidectomy and central and lateral neck dissection and in patients with Graves’ disease. Postoperative hematomas or bleeding may also complicate thyroidectomies and rarely neces-sitate emergency reoperation to evacuate the hematoma. Bilat-eral vocal cord dysfunction with airway compromises requires immediate reintubation and tracheostomy. Seromas may need aspiration to relieve patient discomfort. Wound cellulitis and infection and injury to surrounding structures, such as the carotid artery, jugular vein, and esophagus, are infrequent.PARATHYROIDHistorical BackgroundIn 1849, the curator of the London Zoological Gardens, Sir Richard Owen, provided the first accurate description of the normal parathyroid gland after autopsy examination of an Indian rhinoceros. However, human parathyroids were not grossly and microscopically described until 1879 by Ivar Sandström, a med-ical student in Uppsala, Sweden. He suggested that these glands be named the glandulae parathyroideae, although their function was not known.The association of HPT and the bone disease osteitis fibrosa cystica (described by von Recklinghausen) was recog-nized in 1903. Calcium measurement became possible in 1909, and the association between serum calcium levels and the para-thyroid glands was established. The first successful parathyroid-ectomy was performed in 1925 by Felix Mandl on a 38-year-old man who had severe bone pain secondary to advanced osteitis fibrosa cystica. The patient’s condition dramatically improved after the operation, and he lived for another 7 years before dying of recurrent HPT or renal failure. In 1926, the first parathyroid operation was performed at Massachusetts General Hospital. Edward Churchill, assisted by an intern named Oliver Cope, operated on the famous sea captain Charles Martell for severe primary HPT (PHPT). It was not until his seventh operation, which included total thyroidectomy, that an ectopic adenoma was found substernally. Unfortunately, Captain Martell died 6 weeks later, likely due to laryngeal spasm and complications of renal stones and ureteral obstruction. The first successful para-thyroidectomy for HPT in the United States was performed on a 56-year-old woman in 1928 by Isaac Y. Olch at the Barnes Hospital in St. Louis, Missouri. At operation, a parathyroid ade-noma was found attached to the left lower lobe of the thyroid gland. Postoperatively, the patient developed tetany, requiring lifelong supplemental calcium.EmbryologyIn humans, the superior parathyroid glands are derived from the fourth branchial pouch, which also gives rise to the thyroid gland. The third branchial pouches give rise to the inferior para-thyroid glands and the thymus (Fig. 38-25). The parathyroids remain closely associated with their respective branchial pouch derivatives. The position of normal superior parathyroid glands is more consistent, with 80% of these glands being found near the posterior aspect of the upper and middle thyroid lobes, at the level of the cricoid cartilage. Approximately 1% of normal upper glands may be found in the paraesophageal or retro-esophageal space. Enlarged superior glands may descend in the tracheoesophageal groove and come to lie caudal to the inferior glands. Truly ectopic superior parathyroid glands are rare, but they may be found in the middle or posterior mediastinum or in the aortopulmonary window.51 As the embryo matures, the thy-mus and inferior parathyroids migrate together caudally in the neck. The most common location for inferior glands is within a distance of 1 cm from a point centered where the inferior thyroid artery and RLN cross. Approximately 15% of inferior glands Parathyroid IIIForamen caecumThyroglossal ductMedian thyroidThymusTracheaEsophagusFifth branchialpouchFourthbranchialpouchThirdbranchialpouchParathyroid IVUltimobranchialbodyMedian thyroidLateralthyroid or ultimobranchial bodyEsophagusParathyroid IVParathyroid IIIThymusABFigure 38-25. Parathyroid embryology. Figure demonstrates a schematic view of the pharynx of an 8to 10-mm embryo (A) and locations of the thyroid, parathyroid, and thymic tissues in a 13to 14-mm embryo (B). The lower parathyroids are derived from the third branchial pouch and migrate with the thymus, whereas the upper parathyroids are derived from the fourth branchial pouch and lie in close proximity to the ultimobranchial bodies. (Reproduced with permission from Randolph G: Surgery of the Thyroid and Parathyroid Glands. Philadelphia, PA: Elsevier/Saunders; 2003.)Brunicardi_Ch38_p1625-p1704.indd 166301/03/19 11:21 AM 1664SPECIFIC CONSIDERATIONSPART IIare found in the thymus. The position of the inferior glands, however, tends to be more variable due to their longer migratory path. Undescended inferior glands may be found near the skull base, angle of the mandible, or superior to the upper parathyroid glands along with an undescended thymus. The frequency of intrathyroidal glands is about 2%.Anatomy and HistologyMost patients have four parathyroid glands. The superior glands usually are dorsal to the RLN at the level of the cricoid cartilage, whereas the inferior parathyroid glands are located ventral to the nerve. Normal parathyroid glands are gray and semitransparent in newborns but appear golden yellow to light brown in adults. Parathyroid color depends on cellularity, fat content, and vas-cularity. Moreover, they often are embedded in and sometimes difficult to discern from surrounding fat. Normal parathyroid glands are located in loose tissue or fat and are ovoid. They measure up to 7 mm in size and weigh approximately 40 to 50 mg each. Parathyroid glands usually derive their blood supply from branches of the inferior thyroid artery, although branches from the superior thyroid artery supply at least 20% of upper glands. Branches from the thyroidea ima, and vessels to the trachea, esophagus, larynx, and mediastinum may also be found. The parathyroid glands drain ipsilaterally by the superior, middle, and inferior thyroid veins.Akerström and colleagues,67 in an autopsy series of 503 cadavers, found four parathyroid glands in 84% of cases. Super-numerary glands were present in 13% of patients, most com-monly in the thymus. Only 3% of patients had less than four glands. Similar results were obtained in other dissection studies of 428 human subjects by Gilmour who reported a 6.7% inci-dence of supernumerary glands.68Histologically, parathyroid glands are composed of chief cells and oxyphil cells arranged in trabeculae, within a stroma composed primarily of adipose cells (Fig. 38-26). The parathy-roid glands of infants and children are composed mainly of chief cells, which produce parathyroid hormone (PTH). Acidophilic, mitochondria-rich oxyphil cells are derived from chief cells, can be seen around puberty, and increase in numbers in adult-hood. A third group of cells, known as water-clear cells, also are derived from chief cells, are present in small numbers, and are rich in glycogen. Although most oxyphil and water-clear Figure 38-26. Normal parathyroid histology showing chief cells interspersed with adipose cells.cells retain the ability to secrete PTH, their functional signifi-cance is not known.Parathyroid Physiology and Calcium HomeostasisCalcium is the most abundant cation in human beings and has several crucial functions. Extracellular calcium levels are 10,000-fold higher than intracellular levels, and both are tightly controlled. Extracellular calcium is important for excitationcontraction coupling in muscle tissues, synaptic transmission in the nervous system, coagulation, and secretion of other hormones. Intracellular calcium is an important second messenger regulat-ing cell division, motility, membrane trafficking, and secretion. Calcium is absorbed from the small intestine in its inorganic form. Calcium fluxes in the steady state are depicted in Fig. 38-27.Extracellular calcium (900 mg) accounts for only 1% of the body’s calcium stores, the majority of which is sequestered in the skeletal system. Approximately 50% of the serum cal-cium is in the ionized form, which is the active component. The remainder is bound to albumin (40%) and organic anions such as phosphate and citrate (10%). The total serum calcium levels range from 8.5 to 10.5 mg/dL (2.1 to 2.6 mmol/L), and ionized calcium levels range from 4.4 to 5.2 mg/dL (1.1 to 1.3 mmol/L). Both concentrations are tightly regulated. The total serum calcium level must always be considered in its rela-tionship to plasma protein levels, especially serum albumin. For each gram per deciliter of alteration of serum albumin above or below 4.0 mg/dL, there is a 0.8 mg/dL increase or decrease in protein-bound calcium and, thus, in total serum calcium levels. Total and, particularly, ionized calcium levels are influenced by various hormone systems.Parathyroid Hormone. The parathyroid cells rely on a G-protein–coupled membrane receptor, designated the calcium-sensing receptor (CASR), to regulate PTH secretion by sensing extracellular calcium levels69 (Fig. 38-28). PTH secretion also is stimulated by low levels of 1,25-dihydroxy vitamin D, cat-echolamines, and hypomagnesemia. The PTH gene is located on chromosome 11. PTH is synthesized in the parathyroid gland as a precursor hormone preproPTH, which is cleaved first to pro-PTH and then to the final 84-amino-acid PTH. Secreted PTH has a half-life of 2 to 4 minutes. In the liver, PTH is metabolized into the active N-terminal component and the relatively inactive C-terminal fraction. The C-terminal component is excreted by the kidneys and accumulates in chronic renal failure.PTH functions to regulate calcium levels via its actions on three target organs, the bone, kidney, and gut. PTH increases the resorption of bone by stimulating osteoclasts and promotes the release of calcium and phosphate into the circulation. At the kidney, calcium is primarily absorbed in concert with sodium in the proximal convoluted tubule, but fine adjustments occur more distally. PTH acts to limit calcium excretion at the dis-tal convoluted tubule via an active transport mechanism. PTH also inhibits phosphate reabsorption (at the proximal convoluted tubule) and bicarbonate reabsorption. It also inhibits the Na+/H+ antiporter, which results in a mild metabolic acidosis in hyper-parathyroid states. PTH and hypophosphatemia also enhance 1-hydroxylation of 25-hydroxyvitamin D, which is responsible for its indirect effect of increasing intestinal calcium absorption.Calcitonin. Calcitonin is produced by thyroid C cells and func-tions as an antihypercalcemic hormone by inhibiting osteoclast-mediated bone resorption. Calcitonin production is stimulated Brunicardi_Ch38_p1625-p1704.indd 166401/03/19 11:21 AM 1665THYROID, PARATHYROID, AND ADRENALCHAPTER 38Figure 38-27. Calcium balance and fluxes in a normal human. Solid arrows depict a direct effect, whereas dashed arrows depict an indirect effect. The thickness of the arrows is representative of the magnitude of the flux. ECF = extracellular fluid; PTH = parathyroid hormone; VIT. = vitamin. (Reproduced with permission from Felig P, Frohman L: Endocrinology and Metabolism. New York, NY: McGraw-Hill Education; 2001.)PTHPTHVIT. DECFCALCIUM900 mgKidneyUrine0.15 0.3 g900 1400 gBone0.25 0.5 g0.25 0.5 g0.25 0.5 g0.1 0.2 g0.4 1.5 g0.35 1.0 gVIT. DPTHby calcium and pentagastrin and also by catecholamines, chole-cystokinin, and glucagon. When administered intravenously to experimental animals, it produces hypocalcemia. At the kidney, calcitonin increases phosphate excretion by inhibiting its reab-sorption. Calcitonin plays a minimal, if any, role in the regula-tion of calcium levels in humans. However, it is very useful as a marker of MTC and in treating acute hypercalcemic crisis.Vitamin D. Vitamin D refers to vitamin D2 and vitamin D3, both of which are produced by photolysis of naturally occurring ste-rol precursors. Vitamin D2 is available commercially in pharma-ceutical preparations, whereas vitamin D3 is the most important physiologic compound and is produced from 7-dehydrocholes-terol, which is found in the skin. Vitamin D is metabolized in the liver to its primary circulating form, 25-hydroxyvitamin D. Further hydroxylation in the kidney results in 1,25-dihydroxy vitamin D, which is the most metabolically active form of vitamin D. Vitamin D stimulates the absorption of calcium and phosphate from the gut and the resorption of calcium from the bone.HyperparathyroidismHyperfunction of the parathyroid glands may be classified as primary, secondary, or tertiary. PHPT arises from increased PTH production from abnormal parathyroid glands and results from a disturbance of normal feedback control exerted by serum calcium. Elevated PTH levels may also occur as a compensa-tory response to hypocalcemic states resulting from chronic renal failure or GI malabsorption of calcium. This secondary HPT can be reversed by correction of the underlying problem (e.g., kidney transplantation for chronic renal failure). However, chronically stimulated glands may occasionally become autono-mous, resulting in persistence or recurrence of hypercalcemia after successful renal transplantation, resulting in tertiary HPT.Primary Hyperparathyroidism. PHPT is a common dis-order, affecting 100,000 individuals annually in the United States. PHPT occurs in 0.1% to 0.3% of the general population and is more common in women (1:500) than in men (1:2000). Increased PTH production leads to hypercalcemia via increased GI absorption of calcium, increased production of vitamin D3, and reduced renal calcium clearance. PHPT is characterized by increased parathyroid cell proliferation and PTH secretion that is independent of calcium levels.Etiology The exact cause of PHPT is unknown, although exposure to low-dose therapeutic ionizing radiation and familial predisposition account for some cases. Various diets and inter-mittent exposure to sunshine may also be related. Other causes include renal leak of calcium and declining renal function with age as well as alteration in the sensitivity of parathyroid glands to suppression by calcium. The latency period for development of PHPT after radiation exposure is longer than that for the development of thyroid tumors, with most cases occurring 30 to 40 years after exposure. Patients who have been exposed to radiation have similar clinical presentations and calcium levels when compared to patients without a history of radiation expo-sure. However, the former tends to have higher PTH levels and a higher incidence of concomitant thyroid neoplasms. Lithium therapy has been known to shift the set point for PTH secre-tion in parathyroid cells, thereby resulting in elevated PTH lev-els and mild hypercalcemia. Lithium stimulates the growth of abnormal parathyroid glands in vitro and also in susceptible patients in vivo. PHPT results from the enlargement of a single gland or parathyroid adenoma in approximately 80% of cases, multiple adenomas or hyperplasia in 15% to 20% of patients, and parathyroid carcinoma in 1% of patients. Existence of two enlarged glands or double adenomas is supported by bio-chemical (calcium and PTH), intraoperative PTH (IOPTH), molecular, and histologic data. This entity is less common in younger patients but accounts for up to 10% of older patients with PHPT. It should be emphasized that when more than one abnormal parathyroid gland is identified preoperatively or intra-operatively, the patient has hyperplasia (all glands abnormal) until proven otherwise.Genetics Most cases of PHPT are sporadic. However, PHPT also occurs within the spectrum of a number of inherited Brunicardi_Ch38_p1625-p1704.indd 166501/03/19 11:21 AM 1666SPECIFIC CONSIDERATIONSPART IIdisorders such as MEN1, MEN2A, isolated familial HPT, and familial HPT with jaw-tumor syndrome. All of these syndromes are inherited in an autosomal dominant fashion. PHPT is the earliest and most common manifestation of MEN1 and develops in 80% to 100% of patients by age 40 years old. These patients also are prone to pancreatic neuroendocrine tumors and pitu-itary adenomas and, less commonly, to adrenocortical tumors, lipomas, skin angiomas, and carcinoid tumors of the bronchus, thymus, or stomach. About 50% of patients develop gastrino-mas, which often are multiple and metastatic at diagnosis. Insu-linomas develop in 10% to 15% of cases, whereas many patients have nonfunctional pancreatic endocrine tumors. Prolactinomas occur in 10% to 50% of MEN1 patients and constitute the most common pituitary lesion. MEN1 has been shown to result from germline mutations in the MEN1 gene, a tumor suppressor gene located on chromosome 11q12-13 that encodes menin, a protein that is postulated to interact with the transcription factors JunD and nuclear factor-κB in the nucleus, in addition to replication protein A and other proteins.70 Most MEN1 mutations result in a nonfunctional protein and are scattered throughout the translated nine exons of the gene. This makes presymptomatic screening for mutation carriers difficult. MEN1 mutations also have been found in kindreds initially suspected to represent isolated famil-ial HPT. HPT develops in about 20% of patients with MEN2A and generally is less severe. MEN2A is caused by germline mutations of the RET proto-oncogene located on chromosome 10. In contrast to MEN1, genotype-phenotype correlations have been noted in this syndrome in that individuals with mutations at codon 634 are more likely to develop HPT. Patients with the familial HPT with jaw-tumor syndrome have an increased predisposition to parathyroid carcinoma. This syndrome maps to a tumor suppressor locus HRPT2 (CDC73 or parafibromin) on chromosome 1. Patients belonging to isolated HPT kindreds also appear to demonstrate linkage to HRPT2. More recently, a subset of patients with MEN-1 phenotype in the absence of MENIN mutations were found to harbor inactivating mutation NH2Ca2+Ca2+Ca2+[Ca2+]iCASRPKCCOOHG proteins PLCIns (1,4,5) P3Regulation of PTHParathyroid cellSystemic effectsKidney25(OH)D3LiverVitamin D1,25(OH)2D3BoneSmall intestineERCa2+Ca2+Ca2+Ca2+Ca2+Ca2+Figure 38-28. Regulation of calcium homeostasis. The calcium-sensing receptor (CASR) is expressed on the surface of the parathyroid cell and senses fluctuations in the concentration of extracellular calcium. Activation of the receptor is thought to increase intracellular cal-cium levels, which, in turn, inhibit parathyroid hormone (PTH) secretion via posttranslational mechanisms. Increased PTH secretion leads to an increase in serum calcium levels by increasing bone resorption and enhancing renal calcium reabsorption. PTH also stimulates renal 1-α-hydroxylase activity, leading to an increase in 1,25-dihydroxy vitamin D, which also exerts a negative feedback on PTH secretion. PKC = protein kinase C; PLC = phospholipase C. (Reproduced with permission from Carling T: Molecular pathology of parathyroid tumors, Trends Endocrinol Metab. 2001 Mar;12(2):53-58.)Brunicardi_Ch38_p1625-p1704.indd 166601/03/19 11:21 AM 1667THYROID, PARATHYROID, AND ADRENALCHAPTER 38in the tumor suppressor gene CDKN1B on chromosome 12p13 and given the diagnosis of MEN4.71,72 CDKN1B encodes p27kip1, which is involved in cyclin D1 signaling.Approximately 25% to 40% of sporadic parathyroid ade-nomas and some hyperplastic parathyroid glands have loss of heterozygosity (LOH) at 11q13, the site of the MEN1 gene. The parathyroid adenoma 1 oncogene (PRAD1 or CCND1), which encodes cyclin D1, a cell cycle control protein, is overexpressed in about 18% of parathyroid adenomas. This was demonstrated to result from a rearrangement on chromosome 11 that places the PRAD1 gene under the control of the PTH promoter. Sporadic parathyroid tumors also appear to carry alterations in cyclin dependent kinase inhibitor encoding genes, in particular somatic inactivating mutations of CDKN1B. Other chromosomal regions deleted in parathyroid adenomas and possibly reflecting loss of tumor suppressor genes include 1p, 6q, and 15q, whereas ampli-fied regions suggesting oncogenes have been identified at 16p and 19p. RET mutations are rare in sporadic parathyroid tumors. Sporadic parathyroid cancers are characterized by uniform loss of the tumor suppressor gene RB, which is involved in cell cycle regulation, and 60% have HRPT2 (CDC73) mutations. These alterations are rare in benign parathyroid tumors and may have implications for diagnosis. The p53 tumor suppressor gene is also inactivated in a subset (30%) of parathyroid carcinomas.73Clinical Manifestations Patients with PHPT formerly pre-sented with the “classic” pentad of symptoms (i.e., kidney stones, painful bones, abdominal groans, psychic moans, and fatigue overtones). With the advent and widespread use of auto-mated blood analyzers in the early 1970s, there has been an alteration in the “typical” patient with PHPT. They are more likely to be minimally symptomatic or asymptomatic. Currently, most patients present with weakness, fatigue, polydipsia, poly-uria, nocturia, bone and joint pain, constipation, decreased appe-tite, nausea, heartburn, pruritus, depression, and memory loss. Patients with PHPT also tend to score lower than healthy controls when assessed by general multidimensional health assessment tools such as the Medical Outcomes Study Short-Form Health Survey (SF-36) and other specific questionnaires. Furthermore, these symptoms and signs improve in most, but certainly not all, patients after parathyroidectomy. Truly “asymptomatic” PHPT appears to be rare, occurring in <5% of patients, as determined by prospectively administered questionnaires. Complications of PHPT are described in the following section.Renal Disease. Approximately 80% of patients with PHPT have some degree of renal dysfunction or symptoms. Kidney stones were previously reported in up to 80% of patients but now occur in about 20% to 25%. The calculi are typically com-posed of calcium phosphate or oxalate. In contrast, PHPT is found to be the underlying disorder in only 3% of patients pre-senting with nephrolithiasis. Nephrocalcinosis, which refers to renal parenchymal calcification, is found in <5% of patients and is more likely to lead to renal dysfunction. Chronic hypercalce-mia also can impair concentrating ability, thereby resulting in polyuria, polydipsia, and nocturia. The incidence of hyperten-sion is variable but has been reported to occur in up to 50% of patients with PHPT. Hypertension appears to be more common in older patients and correlates with the magnitude of renal dys-function and, in contrast to other symptoms, is least likely to improve after parathyroidectomy.Bone Disease. Bone disease, including osteopenia, osteoporo-sis, and osteitis fibrosa cystica, is found in about 15% of patients with PHPT. Increased bone turnover, as found in patients with osteitis fibrosa cystica, can be determined by documenting an elevated blood alkaline phosphatase level. Advanced PHPT with osteitis fibrosa cystica now occurs in <5% of patients. It has pathognomonic radiologic findings, which are best seen on X-rays of the hands and are characterized by subperiosteal resorption (most apparent on the radial aspect of the middle pha-lanx of the second and third fingers), bone cysts, and tufting of the distal phalanges (Fig. 38-29). The skull also may be affected and appears mottled with a loss of definition of the inner and outer cortices. Brown or osteoclastic tumors and bone cysts also may be present. Severe bone disease, resulting in bone pain and tenderness and/or pathologic fractures, is rarely observed nowa-days. However, reductions of bone mineral density (BMD) with osteopenia and osteoporosis are more common. Patients with normal serum alkaline phosphatase levels almost never have clinically apparent osteitis fibrosa cystica. HPT typically results in a loss of bone mass at sites of cortical bone such as the radius and relative preservation of cancellous bone such as that located at the vertebral bodies. Patients with PHPT, however, also may Figure 38-29. X-ray of the hand showing subperiosteal bone resorption most apparent along the radial aspect of the middle pha-lanx, characteristic of osteitis fibrosa cystica.Brunicardi_Ch38_p1625-p1704.indd 166701/03/19 11:21 AM 1668SPECIFIC CONSIDERATIONSPART IIhave osteoporosis of the lumbar spine that improves dramati-cally following parathyroidectomy. Fractures also occur more frequently in patients with PHPT, and the incidence of fractures also decreases after parathyroidectomy. Bone disease correlates with serum PTH and vitamin D levels.Gastrointestinal Complications. PHPT has been associated with peptic ulcer disease. In experimental animals, hypergastrin-emia has been shown to result from PTH infusion into blood ves-sels supplying the stomach, independent of its effects on serum calcium. An increased incidence of pancreatitis also has been reported in patients with PHPT, although this appears to occur only in patients with profound hypercalcemia (Ca2+ ≥12.5 mg/dL). Patients with PHPT also have an increased incidence of choleli-thiasis, presumably due to an increase in biliary calcium, which leads to the formation of calcium bilirubinate stones.Neuropsychiatric Complications. Severe hypercalcemia may lead to various neuropsychiatric manifestations such as florid psy-chosis, obtundation, or coma. Other findings such as depression, anxiety, and fatigue are more commonly observed in patients with only mild hypercalcemia. The etiology of these symptoms is not known. Studies demonstrate that levels of certain neu-rotransmitters (monoamine metabolites 5-hydroxyindoleacetic acid and homovanillic acid) are reduced in the cerebrospi-nal fluid of patients with PHPT when compared to controls. Electroencephalogram abnormalities also occur in patients with primary and secondary HPT and normalize following parathyroidectomy.Other Features. PHPT also can lead to fatigue and muscle weakness, which is prominent in the proximal muscle groups. Although the exact etiology of this finding is not known, muscle biopsy studies show that weakness results from a neuropathy, rather than a primary myopathic abnormality. Patients with HPT also have an increased incidence of chondrocalcinosis, gout, and pseudogout, with deposition of uric acid and calcium pyro-phosphate crystals in the joints. Calcification at ectopic sites such as blood vessels, cardiac valves, and skin also has been reported, as has hypertrophy of the left ventricle independent of the presence of hypertension. There is also evidence for subtle cardiovascular manifestations in mild disease, such as changes in endothelial function, increased vascular stiffness, and perhaps subtle diastolic dysfunction. Several large studies from Europe also suggest that PHPT is associated with increased death rates from cardiovascular disease and cancer even in patients with mild HPT, although this finding was not substantiated in North American studies.Physical Findings Parathyroid tumors are seldom palpable, except in patients with profound hypercalcemia or parathyroid cancer. A palpable neck mass in a patient with PHPT is more likely to be thyroid in origin or a parathyroid cancer. Patients also may demonstrate evidence of band keratopathy, a depo-sition of calcium in Bowman’s membrane just inside the iris of the eye. This nonspecific condition generally is caused by chronic eye diseases such as uveitis, glaucoma, and trauma but also may occur in the presence of conditions associated with high calcium or phosphate levels. Fibro-osseous jaw tumors, and/or the presence of familial disease in patients with PHPT and jaw tumors, if present, should alert the physician to the pos-sibility of parathyroid carcinoma.Differential Diagnosis Hypercalcemia may be caused by a multitude of conditions, as listed in Table 38-9. PHPT and malignancy account for >90% of all cases of hypercalcemia. PHPT is more common in the outpatient setting, whereas malig-nancy is the leading cause of hypercalcemia in hospitalized patients. PHPT can virtually always be distinguished from other diseases causing hypercalcemia by a combination of history, physical examination, and appropriate laboratory investigations.Hypercalcemia associated with malignancy includes three distinct syndromes. Although bone metastases may cause hypercalcemia, patients with solid tumors of the lung, breast, kidney, head and neck, and ovary often have humoral hyper-calcemia of malignancy, without any associated bony metas-tases. In addition, hypercalcemia also may be associated with hematologic malignancies such as multiple myeloma. Humoral hypercalcemia of malignancy is known to be mediated primar-ily by PTH-related peptide (PTHrP), which also plays a role in the hypercalcemia associated with bone metastases and multiple myeloma.Thiazide diuretics cause hypercalcemia by decreasing renal clearance of calcium. This corrects in normal patients within days to weeks after discontinuing the diuretic, but patients with PHPT continue to be hypercalcemic. Thiazide diuretics can, therefore, exacerbate underlying PHPT and can be used to unmask PHPT in patients with borderline hyper-calcemia. Familial hypocalciuric hypercalcemia 1 (FHH1) is a rare autosomal dominant condition with nearly 100% pen-etrance and results from inherited heterozygous mutations in the CASR gene located on chromosome 3.54 Homozygous germline mutations at this locus result in neonatal severe pri-mary hyperparathyroidism and calcemia, a condition that can rapidly prove fatal. Patients with FHH1 generally have lifelong hypercalcemia, which is not corrected by parathyroidectomy. A milder form of the disease known as familial hypercalciu-ric hypercalcemia results from germline inactivating mutations in the intracytoplasmic tail domain of the CaSR gene. These patients have an appropriate hypercalciuric response to elevated calcium and PTH in addition to hypermagnesemia and hyper-phosphaturia. Some cases benefit from parathyroidectomy. Recently two new types of FHH (2 and 3) have been described. These are associated with germline inactivating mutations of GNA11(19p13.3) and AP2S1(19q12.2) genes. Both mutations cause hypocalciuric hypercalcemia through aberrant inactiva-tion of CaSR signaling. Although clinical presentation in FHH2 is similar to FHH1, those with FHH3 tend to have higher PTH levels and osteomalacia.71Table 38-9Differential diagnosis of hypercalcemiaHyperparathyroidismMalignancy—hematologic (multiple myeloma), solid tumors (due to PTHrP)Endocrine diseases—hyperthyroidism, Addisonian crisis, VIPomaGranulomatous diseases—sarcoidosis, tuberculosis, berylliosis, histoplasmosisMilk-alkali syndromeDrugs—thiazide diuretics, lithium, vitamin A or D intoxicationFamilial hypocalciuric hypercalcemiaPaget’s diseaseImmobilizationPTHrP = parathyroid hormone-related protein; VIP = vasoactive intestinal peptide.Brunicardi_Ch38_p1625-p1704.indd 166801/03/19 11:21 AM 1669THYROID, PARATHYROID, AND ADRENALCHAPTER 38Coexisting primaryhyperparathyroidismand malignancyIntact PTHNormalrangeHypo-parathyroidismPrimaryhyper-parathyroidismLimit ofdetectionHypercalcemiaassociatedwith malignancy968634Intact PTH (pg/mL of hPTH [1-84])Normal50020015010050Figure 38-30. Intact parathyroid hormone (PTH) measurement allows differentiation between the various causes of hypercalcemia. (Reproduced with permission from Endres DB, Villanueva R, Sharp CF, et al. Measurement of parathyroid hormone, Endocrinol Metab Clin North Am. 1989 Sep;18(3):611-629.)Hypercalcemia also is found in approximately 10% of patients with sarcoidosis secondary to increased 25-hydroxy vitamin D 1-hydroxylase activity in lymphoid tissue and pul-monary macrophages, which is not subject to inhibitory feed-back control by serum calcium. Thyroid hormone also has bone-resorption properties, thus causing hypercalcemia in thy-rotoxic states, especially in immobilized patients. Hemoconcen-tration appears to be an important factor in the hypercalcemia associated with adrenal insufficiency and pheochromocytoma, although the latter patients may have associated parathyroid tumors (MEN2A), and some pheochromocytomas are known to secrete PTHrP. Other endocrine lesions such as vasoactive intestinal peptide–secreting tumors may be associated with hypercalcemia due to increased secretion of PTHrP. Milk-alkali syndrome requires the ingestion of large quantities of calcium with an absorbable alkali such as that used in the treatment of peptic ulcer disease with antacids. Ingestions of large quantities of vitamins D and A are infrequent causes of hypercalcemia, as is immobilization.Diagnostic Investigations Biochemical Studies. The presence of an elevated serum cal-cium and intact PTH or two-site PTH levels, without hypocal-ciuria, establishes the diagnosis of PHPT with virtual certainty. These sensitive PTH assays use immunoradiometric or immu-nochemiluminescent techniques and can reliably distinguish PHPT from other causes of hypercalcemia. Furthermore, they do not cross-react with PTHrP (Fig. 38-30). In patients with Table 38-10Biochemical features of primary hyperparathyroidismSERUM TESTSALTERATIONCalciumIncreased, except in normocalcemic primary hyperparathyroidismIntact PTHIncreased or inappropriately highChlorideIncreased or high normalPhosphateDecreased or low normalChloride-to-phosphate ratioIncreased (usually >33)MagnesiumUnchanged or decreased (in patients with osteitis fibrosa cystica)Uric acidNormal or increasedAlkaline phosphataseNormal or increased (in the presence of high turnover bone disease)Acid-base statusMild hyperchloremic metabolic acidosisCalcium-to-creatinine clearance ratioGenerally >0.02 (vs. <0.01 in FHH) but there are exceptions1,25-dihydroxy vitamin DNormal or increasedUrine tests 24-h urinary calciumNormal or increasedBFHH = benign familial hypocalciuric hypercalcemia; PTH = parathyroid hormone.metastatic cancer and hypercalcemia, intact PTH levels help to determine whether the patient also has concurrent PHPT. Although extremely rare, a patient with hypercalcemia may have a tumor that secretes PTH. FNAB of such a tumor for PTH levels or selective venous catheterization of the veins draining such tumors can help clarify the diagnosis.Patients with PHPT also typically have decreased serum phosphate (∼50%) and elevated 24-hour urinary calcium con-centrations (∼60%). A mild hyperchloremic metabolic acidosis also is present (80%), thereby leading to an elevated chloride-to-phosphate ratio (>33). Urinary calcium levels need not be measured routinely, except in patients who have not had previ-ously documented normocalcemia or have a family history of hypercalcemia to rule out FHH. In patients with FHH, 24-hour urinary calcium excretion is characteristically low (<100 mg/d). Furthermore, the serum calcium-to-creatinine clearance ratio (24-hour urine calcium/plasma total calcium/24-hour urine creatinine/plasma creatinine) usually is <0.01 in patients with FHH, whereas it is typically >0.02 in patients with PHPT, although there are exceptions to this. Other biochemical features of PHPT are listed in Table 38-10. Elevated levels of alkaline phosphatase may be found in approximately 10% of patients with PHPT and are indicative of high-turnover bone disease. These patients are prone to developing postoperative hypocal-cemia due to bone hunger. Serum and urine protein electropho-resis may be necessary to exclude multiple myeloma.Brunicardi_Ch38_p1625-p1704.indd 166901/03/19 11:21 AM 1670SPECIFIC CONSIDERATIONSPART IIOccasionally, patients present with normocalcemic PHPT due to vitamin D deficiency, a low serum albumin, excessive hydration, a high-phosphate diet, or a low normal blood calcium set point. These patients have increased total PTH levels with or without increased blood ionized calcium levels and must be distinguished from patients with renal leak hypercalciuria who also have increased PTH levels due to excessive calcium loss in the urine. This can be accomplished by administering thiazide diuretics. In patients with idiopathic hypercalciuria, the urinary calcium level falls, and the secondary increase in the blood PTH level also decreases to normal, whereas patients with normocal-cemic HPT continue to have elevated urine calcium and blood PTH levels and may, in fact, become hypercalcemic.Radiologic Tests. In patients with profound hypercalcemia or PHPT associated with vitamin D deficiency, hand and skull X-rays may demonstrate osteitis fibrosa cystica, but this is rare in current clinical practice. BMD studies using dual-energy absorptiometry are being increasingly used to assess the effects of PHPT on bone. PHPT primarily leads to one loss at cortical sites such as the distal radius while bone density is preserved at sites such as the lumbar spine. Current evaluation of patients with PHPT includes vertebral imaging by X-ray or vertebral fracture assessment (VFA) or CT scan in addition to BMD stud-ies. Measurement of trabecular bone score (TBS) is optional. In addition, renal imaging by ultrasound, X-ray, or CT scan is also recommended. Parathyroid localization studies are not used to confirm the diagnosis of PHPT, but rather to aid in identify-ing the location of the offending gland(s), as discussed later in “Preoperative Localization Tests.”Treatment Indications for Parathyroidectomy and Role of Medical Management. Most authorities agree that patients who have developed complications and have “classic” symptoms of PHPT should undergo parathyroidectomy. However, the treatment of patients with asymptomatic PHPT has been the subject of con-troversy, due, in part, to the fact that there is little agreement on what constitutes an asymptomatic patient.At the National Institutes of Health consensus conference in 1990, “asymptomatic” PHPT was defined as “the absence of common symptoms and signs of PHPT, including no bone, renal, gastrointestinal, or neuromuscular disorders.” To deter-mine the best course of action for these patients, it is important to consider the natural history of untreated PHPT and the out-comes of treatment options, both medical and surgical.With respect to the natural history, the panel advocated nonoperative management of these patients with mild PHPT based on observational studies, which suggested relative stabil-ity of biochemical parameters over time. However, the consen-sus panel considered certain patients to be candidates for surgery based on testing or other information indicating end-organ effects or a higher likelihood of disease progression, and this led to the establishment of initial guidelines for parathyroidectomy.74 Subsequently, another observational study on the natural history of treated versus untreated HPT was published by Silverberg and colleagues.75 In their cohort of 52 patients with asymptomatic HPT followed without surgery, levels of serum and urinary calcium, PTH, alkaline phosphatase, and vitamin D metabolites remained relatively stable over a 10-year period in most patients. Average bone mass also remained relatively stable. However, the study also reported development of a new indication for surgery in 14 (27%) of 52 of their asymptom-atic patients and, because approximately 50% of their patients were initially treated surgically, overall, about 75% of patients were underwent parathyroidectomy. Age <50 years was predic-tive of progression, and patients undergoing parathyroidectomy showed not only normalization of calcium and PTH levels but also improved BMD at the spine and hip. Based on these and other studies, the guidelines were reassessed at a second work-shop on asymptomatic PHPT held at the National Institutes of Health in 2002.76Since that time, additional studies have provided further insights into the natural history of treated and untreated HPT. Three of these were randomized, controlled, prospective studies ranging in duration from 1 to 3.5 years. One was an observa-tional study (a continuation of the Columbia University PHPT Project) but was notable for its long duration of follow-up of 15 years.77 These studies confirmed the relative stability of vari-ous biochemical indices, thus validating the need for guidelines. However, the long-term study suggested that the stability was not indefinite as calcium levels tended to rise in years 13 to 15. In addition, the study also demonstrated that bone density mea-surements remained stable for 8 to 10 years, but cortical bone density worsened after year 10. More concerning was the fact that 60% of patients lost >10% of their BMD over the 15-year observation period. Furthermore, whether patients met the 2002 guidelines for surgery did not appear to predict the risk of pro-gressive disease, with 40% of patients undergoing follow-up eventually needing surgery. Although there are no randomized trials, registry data also suggest that fracture risk is increased for PHPT up to 10 years prior to diagnosis and treatment.Medical options for treating PHPT and its complications include antiresorptive treatments such as bisphosphonates, hor-mone replacement therapy (HRT), and selective estrogen recep-tor modulators such as raloxifene.78 Bisphosphonates and HRT are reasonable options in patients for whom skeletal protection is needed, as evidence from randomized, placebo-controlled trials indicates that these medications are very effective at decreasing bone turnover and increasing BMD in PHPT, with the effects being comparable to patients undergoing parathyroidectomy. Caution needs to be exercised due to the nonskeletal effects of HRT, and hence, bisphosphonates are preferred. There are no clinical studies regarding the effects of raloxifene on BMD in HPT, and none of these agents affects calcium or PTH levels. More recently, calcimimetics (modifiers of the sensitivity of the CASR) have been used in randomized, multicenter controlled trials and have been shown to decrease both serum calcium and PTH levels in both symptomatic and asymptomatic PHPT patients. Unfortunately, bone density failed to improve in medi-cally treated patients. Although this therapy shows promise, long-term outcome data are lacking, and their routine use is not advocated at this time, except in patients who are very poor operative risks or refuse surgery.Successful parathyroidectomy results in resolution of oste-itis fibrosa cystica and decreased formation of renal stones in symptomatic (classic) patients. In addition, it results in improved BMD (6% to 8% in the first year and up to 12% to 15% at 15 years) and fracture risk (by 50% at hip and upper arm and 30% overall) after adjustment for age, sex, and previous frac-tures over a 20-year observation period.75 There are also data to show that it improves a number of the nonspecific manifesta-tions of PHPT such as fatigue, polydipsia, polyuria and nocturia, Brunicardi_Ch38_p1625-p1704.indd 167001/03/19 11:21 AM 1671THYROID, PARATHYROID, AND ADRENALCHAPTER 38Table 38-11Indications for parathyroidectomy in patients with asymptomatic primary HPT (2014 NIH consensus conference guidelines)• Serum calcium >1 mg/dL above the upper limits of normal• GFR <60 mL/min; 24-h urine for calcium >400 mg/d (>10 mmol/d) and increased stone risk by biochemical stone risk analysis; presence of nephrolithiasis or nephrocalcinosis by X-ray, ultrasound, or CT• Substantially decreased bone mineral density at the lumbar spine, total hip, femoral neck, or distal radius (>2.5 SD below peak bone mass, T score <−2.5; vertebral fracture by X-ray, CT, MRI, or VFA)• Age <50 y• Long-term medical surveillance not desired or possibleGFR = glomerular filtration rate; HPT = hyperparathyroidism; NIH = National Institutes of Health; SD = standard deviation; VFA = vertebral fracture assessmentbone and joint pain, constipation, nausea, and depression in many patients. This also has been demonstrated using symptom questionnaires and various standardized general quality-of-life assessments such as the SF-36 and a specific parathyroidectomy assessment of symptoms scale.79 The increased death rate in patients with PHPT appears to be revers-ible by successful parathyroidectomy, at least in some studies. Lastly, parathyroidectomy can be accomplished with >95% suc-cess rates with minimal morbidity, even in elderly patients and is the only curative treatment option for PHPT. Previous inves-tigations have also documented that parathyroidectomy is more cost-effective than medical management or follow-up.80Given these findings, it is recommended that parathyroid-ectomy should be offered to virtually all patients except those in whom the operative risks are prohibitive. This is also acknowl-edged by the panel of the latest workshop, which stated that “even though patients may not meet the guidelines for surgi-cal intervention, it is always a reasonable option in those who do not have medical contraindications.” This was first stated in the 2008 guidelines and reiterated in the most recent revi-sion in 2014, which advised parathyroidectomy for patients with smaller elevations in serum calcium levels (>1 mg/dL above the upper limit of normal) and if BMD measured at any of three sites (radius, spine, or hip) is greater than 2.5 standard deviations below those of genderand race-matched, not age-matched, controls (i.e., peak bone density or T score [rather than Z score] <2.5). In addition, patients <50 years of age were advised to undergo parathyroidectomy. Parathyroidectomy is also indicated for creatinine clearance <60 cc/minute and urine calcium >400 mg/day in the presence of increased stone risk by biochemical stone risk analysis. The significant changes from the previous guidelines pertain to the fact that (a) patients with nephrolithiasis or nephrocalcinosis by X-ray, ultrasound, or CT scan and (b) those with vertebral fracture by X-ray, CT, MRI, or VFA are also candidates for parathyroidectomy.81,82 The current guidelines are summarized in Table 38-11.It is important to point out that the neurocognitive and neuropsychological aspects of PHPT remain a topic of con-troversy with respect to the guidelines for parathyroidectomy. Although there were more studies since the previous iteration 6of the guidelines, there were concerns that while some lacked adequate controls and were plagued by problems related to the instruments used to quantify these nonspecific symptoms, others showed variability in improvement of neurocognitive symptoms following parathyroidectomy. Similarly, uncertainty is also present concerning the cardiovascular consequences of mild HPT. Therefore, the workshop panel emphasizes that these criteria alone should not be used as guidelines for surgical intervention.Since there are no definitive criteria to indicate which patients with mild PHPT will develop progressive disease, more clinical studies are required. Patients who do not undergo sur-gery should undergo routine follow-up as outlined in the recent workshop summary statement, consisting of annual calcium and serum creatinine measurements, and measurements of BMD at three sites every 1 to 2 years.82Preoperative Localization Tests. Localization studies may be classified into noninvasive or invasive modalities. These stud-ies have variable performance characteristics, which, in turn, vary with operator and institutional experience, as outlined in Table 38-12. Localization studies have permitted surgeons to perform more limited operations, some of them under local anesthesia. These “minimally invasive” procedures include uni-lateral and focused neck exploration, radio-guided parathyroid-ectomy, and several endoscopic or video-assisted approaches. The use of localization studies has been shown in some studies to be associated with lower morbidity rates (hypoparathyroidism and RLN injury) and decreased operative times, reduced dura-tion of hospital stay, and improved cosmetic outcomes, while maintaining success rates similar to those obtained with tradi-tional bilateral neck explorations. Some studies also show that use of localization studies may be more cost-effective. Overall, it has become routine to localize hyperfunctioning parathyroid glands before parathyroidectomy. It is important to point out that imaging is not a diagnostic approach, and the decision for exploration should be made before any imaging is performed.99mTc-labeled sestamibi (Fig. 38-31A) is the most widely used and accurate modality with a sensitivity >80% for detec-tion of parathyroid adenomas. Sestamibi (Cardiolite) initially was introduced for cardiac imaging and is concentrated in mitochondria-rich tissue. It was subsequently noted to be useful for parathyroid localization due to the delayed washout of the radionuclide from hypercellular parathyroid tissue compared to thyroid tissue. Sestamibi scans generally are complemented by neck ultrasound (Fig. 38-31B), which can identify adenomas with >75% sensitivity in experienced centers and is most useful in identifying intrathyroidal parathyroids. Single-photon emis-sion CT, particularly when used with CT, has been shown to be superior to other nuclear medicine–based imaging. Specifically, single-photon emission CT can indicate whether an adenoma is located in the anterior or posterior mediastinum (aortopulmo-nary window), thus enabling the surgeon to modify the opera-tive approach accordingly. CT and MRI scans are less sensitive than sestamibi scans, but they are helpful in localizing large paraesophageal and mediastinal glands. More recently, four-dimensional CT (4D-CT) has shown utility in parathyroid local-ization. This technique incorporates the perfusion of contrast in hyperfunctioning parathyroid tissue over time, thus providing functional information in addition to the anatomic information provided by conventional three-dimensional CT imaging. In one study, 4D-CT showed improved sensitivity of 88% compared to Brunicardi_Ch38_p1625-p1704.indd 167101/03/19 11:21 AM 1672SPECIFIC CONSIDERATIONSPART IIthat of sestamibi (65%) and ultrasound (57%) for lateralization of the enlarged gland and also showed superiority when local-ization to the correct quadrant was examined.83 A combination of 4D-CT and ultrasound has been reported to have a positive predictive value of 92% for single-gland disease and 75% for multiple-gland disease.IOPTH was initially introduced in 1993 and is used to determine the adequacy of parathyroid resection (Fig. 38-32).84 According to one commonly used criterion, when the PTH falls by 50% or greater 10 minutes after removal of a parathyroid tumor, as compared to the highest preremoval value, the test is considered positive, and the operation is terminated. IOPTH measurements, like localization studies, are less reliable in mul-tiglandular disease. Bilateral internal jugular vein sampling has also been used to lateralize tumors intraoperatively but is less accurate.Operative Approaches Unilateral parathyroid exploration was first carried out using intraoperative staining of a biopsy from the normal parathyroid gland with Sudan black dye to rule out a double adenoma. Initially, the choice of side to be explored was random, but the introduction of preoperative localization studies has enabled a more directed approach. In contrast, the focused approach identifies only the enlarged parathyroid gland, and no attempts are made to locate other parathyroid glands. Unilateral neck explorations have several advantages over bilateral neck exploration, including reduced operative times and complications, such as injury to the RLN and hypoparathyroidism. However, Table 38-12Commonly used parathyroid localization studiesSTUDYADVANTAGESDISADVANTAGESPreoperative, noninvasive Sestamibi-technetium-99m scanAllows planar and SPECT imagingFalse-positive tests due to thyroid neoplasms, lymphadenopathyUltrasoundIdentification of juxtaand intrathyroidal tumorsFalse-positive results due to thyroid nodules, cysts, lymph nodes, esophageal lesions Relatively inexpensiveFalse-negatives result from substernal, ectopic, and undescended tumorsCT scanLocalization of ectopic (mediastinal) glandsNot useful for juxtaor intrathyroidal glands  False-positive results from lymph nodes  Relatively high cost  Radiation exposure  Requires IV contrast  Interference from shoulders and metallic clipsMRI scanLocalization of ectopic tumorsExpensive No radiation exposureFalse-positive results from lymph nodes and thyroid nodules No IV contrastCannot be used in claustrophobic patientsFour-dimensional CT scanStructural and functional informationSimilar to CT scanPreoperative, invasiveFNABCan distinguish parathyroid tumor from lymphadenopathy using PTH assayExperienced cytologist neededAngiogramProvides a road map for selective venous samplingExpensive Treatment of mediastinal tumors by embolizationExperienced radiologist needed  Neurologic complicationsVenous samplingUseful to lateralize tumor in equivocal cases or negative localization studiesExpensive, experienced radiologist neededIntraoperativePTH assayImmediate confirmation of tumor removalExpensive  Increased operative time, decreased accuracy in multiple-gland diseaseCT = computed tomography; FNAB = fine-needle aspiration biopsy; IV = intravenous; MRI = magnetic resonance imaging; PTH = parathyroid hormone; SPECT = single-photon emission computed tomography.Brunicardi_Ch38_p1625-p1704.indd 167201/03/19 11:21 AM 1673THYROID, PARATHYROID, AND ADRENALCHAPTER 38ABFigure 38-31. A. Sestamibi scan in a patient with primary hyperparathyroidism showing persistent uptake suggesting a left lower hypercel-lular parathyroid gland. B. Neck ultrasound in a patient with primary hyperparathyroidism showing a left lower parathyroid adenoma.most existing studies comparing the two approaches are retro-spective and do not analyze the results on an intent-to-treat basis. Another argument against a unilateral exploration is the risk of missing another adenoma on the opposite side of the neck. The incidence of double adenomas has been reported to range from 0% to 10%, with an increased incidence in elderly patients. The risk of missing a second adenoma is higher in populations with a higher incidence of multiple adenomas, such as those with famil-ial HPT, MEN syndromes, and the elderly. Another difficulty inherent with unilateral exploration is the inability to discern whether the combination of an abnormal gland and a normal gland on the initial side constitutes a single adenoma or asym-metric hyperplasia. A recently published update on the 5-year results of a randomized trial comparing unilateral versus bilateral neck exploration did not note any difference in the rates of recur-rent or persistent disease in the two groups of patients.85 These issues will only be resolved by a large, prospective, multicenter study or improved molecular analytic techniques.Brunicardi_Ch38_p1625-p1704.indd 167301/03/19 11:21 AM 1674SPECIFIC CONSIDERATIONSPART IIRadio-guided parathyroidectomy takes advantage of the ability of parathyroid tumors to retain 99mTc-sestamibi. Before sur-gery, 1 to 2 mCi of the isotope is injected, and a hand-held gamma probe is used to guide the identification of the enlarged gland, taking care to ensure the equilibration of radioactivity counts in all quadrants. Reported advantages include easier localization, par-ticularly in reoperative cases, and the ability to perform the pro-cedure under local anesthetic or sedation using smaller incisions. Many studies demonstrated the feasibility of this technique; how-ever, it is rarely used now, largely because it offers little advantage over preoperative sestamibi scans and is associated with increased operative times. Like preoperative scanning, it also has reduced accuracy in the presence of multiglandular disease.Endoscopic approaches include both video-assisted and total endoscopic techniques. Total endoscopic parathyroidec-tomy was first described by Gagner in 1996,86 and several other investigators have since reported on this technique. Although port placements are variable, as is the case with endoscopic thy-roidectomy, they all involve creation of a working space in the neck using CO2 insufflation, with the reported advantages being superior cosmesis and excellent visualization. Although feasi-ble, these techniques also have been associated with increased operating times, more personnel, and greater expense, and have, in general, not been useful for patients with multiglandu-lar disease, a large thyroid mass, or previous neck surgery and irradiation. Their greatest use has been in patients with tumors at ectopic sites such as the mediastinum where thoracoscopic parathyroidectomy is an excellent alternative to sternotomy. Robotic approaches using a gasless, transaxillary technique are also being used for parathyroidectomy. Reported advantages include improved three-dimensional magnified visualization, refined ergonomic control, more freedom of motion with multi-articulated instruments, and improved cosmetic result as a result of incision placement in the axilla.Studies have shown that if both sestamibi scan and neck ultrasound studies independently identify the same, enlarged parathyroid gland, and no other gland, it is indeed the abnormal gland in approximately 95% of cases. These patients with spo-radic PHPT are candidates for a focused neck exploration, an approach that is most commonly referred to as minimally inva-sive parathyroidectomy. A standard bilateral neck exploration is planned if parathyroid localization studies or IOPTH are not available; if the localizing studies fail to identify any abnormal parathyroid gland or identify multiple abnormal glands in patients with a family history of PHPT, MEN1, or MEN2A; or if a concomitant thyroid disorder requires bilateral exploration. In addition, finding a minimally abnormal parathy-roid gland on the side indicated by localization studies during focal exploration should prompt a bilateral exploration or at least the identification of a normal parathyroid gland on the same side. In patients with MEN1, HPT should be corrected before treatment of gastrinomas because gastrin levels decline after parathyroidectomy.Conduct of Parathyroidectomy (Standard Bilateral Explo-ration) An experienced parathyroid surgeon with a thor-ough knowledge of parathyroid anatomy and embryology and meticulous technique is crucial for the best surgical results. The procedure usually is performed under general anesthesia. The patient is positioned supine on the operating table with the neck extended. For a bilateral exploration, the neck is explored via a 3to 4-cm incision just caudal to the cricoid cartilage. The initial dissection and exposure is similar to that used for thy-roidectomy. After the strap muscles are separated in the midline, one side of the neck is chosen for exploration. In contrast to a thyroidectomy, the dissection during a parathyroidectomy is maintained lateral to the thyroid, making it easier to identify the parathyroid glands and not disturb their blood supply.Identification of Parathyroids. A bloodless field is important to allow identification of parathyroid glands. The middle thyroid veins are ligated and divided, thus enabling medial and anterior retraction of the thyroid lobe, with the aid of a peanut sponge or placement of 2-0 silk sutures into the thyroid. The space between the carotid sheath and thyroid is then opened by gentle sharp and blunt dissection, from the cricoid cartilage superiorly to the thy-mus inferiorly and the RLN is identified. Approximately 85% of the parathyroid glands are found within 1 cm of the junction of the inferior thyroid artery and RLNs. The upper parathyroid glands usually are superior to this junction and dorsal (posterior) to the nerve, whereas the lower glands are located inferior to the junction and ventral (anterior) to the recurrent nerve. Because parathyroid glands are partly surrounded by fat, any fat lobule at typical parathyroid locations should be explored because the normal or abnormal parathyroid gland may be concealed in the fatty tissue. The thin fascia overlying a “suspicious” fat lobule should be incised using a sharp curved hemostat and scalpel. This maneuver often causes the parathyroid gland to “pop” out. Alternatively, gentle, blunt peanut sponge dissection between the carotid sheath and the thyroid gland often reveals a “float” sign, suggesting the site of the abnormal parathyroid gland. Normal parathyroids are light beige and only slightly darker or brown compared to adjacent fat.Parathyroid tissue needs to be distinguished from normal or brown fat tissue, thyroid nodules, lymph nodes, and ectopic thymus. Lymph nodes generally are light beige to whitish gray in color, glassy, and multiple in number, whereas thyroid nod-ules generally are more vascular, firm, dark or reddish brown in color, and have a more variegated appearance. Intraoperatively, 7Standard 24 hr irma pg/ml2000160012008004000correlation r = 0.9161r2 = 0.8393p value <0.00010400800120016002000Figure 38-32. Correlation of the 10-minute incubation time quick parathyroid hormone assay with the 24-hour immunoradiometric (irma) parathyroid hormone assay from 138 paired intraoperative samples from 38 patients undergoing parathyroidectomy. (Repro-duced with permission from Irvin G, Dembrow VD, Prudhomme DL: Clinical usefulness of an intraoperative “quick parathyroid hormone” assay, Surgery. 1993 Dec;114(6):1019-1022.)Brunicardi_Ch38_p1625-p1704.indd 167401/03/19 11:21 AM 1675THYROID, PARATHYROID, AND ADRENALCHAPTER 38a suspicious nodule may be aspirated using a fine needle attached to a syringe containing 1 cc of saline. Very high PTH levels in the aspirate have been shown to be diagnostic in the intraopera-tive identification of parathyroid glands. Several characteristics such as size (>7 mm), weight, and color are used to distinguish normal from hypercellular parathyroid glands. Hypercellular glands generally are darker, more firm, and more vascular than normocellular glands. No single method is 100% reliable, and therefore, the parathyroid surgeon must rely on experience and, at times, advice from a pathologist to help distinguish normal from hypercellular glands. Although several molecular studies have shown use in distinguishing parathyroid adenomas from hyperplasia, this determination also must be made by the sur-geon intraoperatively by documenting the presence of a normal parathyroid gland.Location of Parathyroid Glands. The majority of lower para-thyroid glands are found in proximity to the lower thyroid pole (Fig. 38-33A). If not found at this location, the thyrothymic liga-ment and thymus should be mobilized. The upper end of the cervical thymus is gently grasped with a right-angle clamp, and the distal portion is bluntly dissected from perithymic fat with a peanut sponge. One can then “walk down” the thymus with suc-cessive right-angle clamps (Fig. 38-33B). Applying light tension along with a “twisting” motion helps to free the upper thymus. The carotid sheath also should be opened from the bifurcation to the base of the neck if the parathyroid tumor cannot be found. If these maneuvers are unsuccessful, an intrathyroidal gland should be sought by using intraoperative ultrasound, incising the thyroid capsule on its posterolateral surface, or by perform-ing an ipsilateral thyroid lobectomy and “bread-loafing” the thy-roid lobe. Preoperative or intraoperative ultrasonography can be useful for identifying intrathyroidal parathyroid glands. Rarely, the third branchial pouch may maldescend and be found high in the neck (undescended parathymus), anterior to the carotid bulb, along with the missing parathyroid gland. Upper para-thyroid glands are more consistent in position and usually are found near the junction of the upper and middle thirds of the gland, at the level of the cricoid cartilage (Fig. 38-33C). Ectopic upper glands may be found in carotid sheath, tracheoesopha-geal groove, retroesophageal, or in the posterior mediastinum. The locations of ectopic upper and lower parathyroid glands are shown in Fig. 38-34. Every attempt must be made to identify all four glands. Treatment depends on the number of abnormal glands.1. A single adenoma is presumed to be the cause of a patient’s PHPT if only one parathyroid tumor is identified and the other parathyroid glands are normal, a situation present in about 80% of patients with PHPT. Adenomas typically have an atrophic rim of normal parathyroid tissue, but this char-acteristic may be absent. The adenoma is dissected free of surrounding tissue, taking care to stay immediately adjacent to the tumor, without fracturing it. The vascular pedicle is clamped, divided, and ligated. Care should be taken to not rupture the parathyroid gland to decrease the risk of parathy-romatosis. If there is any question about the presumed nor-mal glands, one of them should be biopsied and examined by frozen section.2. If two abnormal and two normal glands are identified, the patient has double adenomas. Triple adenomas are pres-ent if three glands are abnormal and one is normal. Mul-tiple adenomas are more common in older patients with an incidence of up to 10% in patients >60 years old. The abnormal glands should be excised, provided the re-maining glands are confirmed as such, thus excluding asymmetric hyperplasia after biopsy and frozen section.3. If all parathyroid glands are enlarged or hypercellular, pa-tients have parathyroid hyperplasia that has been shown to occur in about 15% of patients in various series. These glands are often lobulated, usually lack the rim of normal Upper parathyroid glandRecurrentlaryngeal n.Inf. thyroid a. ThymusLowerparathyroidglandThyroidABCFigure 38-33. Conduct of parathyroidectomy. A. Exposure of the lower parathyroid gland near the inferior pole of the thyroid gland and anterior to the recurrent laryngeal nerve. B. A thymectomy may be necessary if the lower parathyroid cannot be found in its usual location, or if the patient has familial primary hyperparathyroid-ism or secondary hyperparathyroidism. C. Exposure of the upper parathyroid gland near the insertion of the recurrent laryngeal nerve at the level of the cricothyroid muscle. a. = artery; Inf. = inferior; n. = nerve.Brunicardi_Ch38_p1625-p1704.indd 167501/03/19 11:21 AM 1676SPECIFIC CONSIDERATIONSPART IIparathyroid gland seen in adenomas, and may be variable in size. It often is difficult to distinguish multiple adenomas from hyperplasia with variable gland size. Hyperplasia may be of the chief cell (more common), mixed, or clear cell type. Patients with hyperplasia may be treated by subtotal para-thyroidectomy or by total parathyroidectomy and autotrans-plantation, with the choice of procedure being determined by rates of recurrence, postoperative hypocalcemia, and failure rates of autotransplanted tissue. Initial studies demonstrated equivalent cure rates and postoperative hypocalcemia for the two techniques, with the latter having the added advantage of avoiding recurrence in the neck. However, autotrans-planted tissue may fail to function in about 5% of cases.All four parathyroid glands are identified and carefully mobilized. For patients with hyperplasia, a titanium clip is placed across the most normal gland, leaving a 50-mg rem-nant and taking care to avoid disturbing the vascular pedicle and that the gland is resected with a sharp scalpel. If possible, it is preferable to subtotally resect an inferior gland, which is more easily accessible in case of recurrence due to its anterior location with respect to the RLN. The resected parathyroid tis-sue is confirmed by frozen section or PTH assay. If the rem-nant appears to be viable, the remaining glands are resected. If there is any question as to the viability of the initially subtotally resected gland, another gland is chosen for subtotal resection, and the initial remnant is removed. Whenever multiple para-thyroids are resected, it is preferable to cryopreserve tissue, so that it may be autotransplanted should the patient become hypo-parathyroid. Parathyroid tissue usually is transplanted into the nondominant forearm. A horizontal skin incision is made over-lying the brachioradialis muscle a few centimeters below the antecubital fossa. Pockets are made in the belly of the muscle, and one to two pieces of parathyroid tissue measuring 1 mm each are placed into each pocket. A total of 12 to 14 pieces are transplanted. Autotransplanted tissue also has been reported to function when transplanted into fat.Indications for Sternotomy A sternotomy is usually not rec-ommended at the initial operation, unless the calcium level is >13 mg/dL. Rather, it is preferred to biopsy the normal glands and subsequently close the patient’s neck and obtain localiz-ing studies, if they were not obtained previously. Intraoperative PTH assay during the operation from large veins may be helpful. Using highly selective venous catheterization postoperatively also may be needed when noninvasive localization studies are negative, equivocal, or conflicting. Lower parathyroid glands tend to migrate into the anterior mediastinum in the thymus or perithymic fat and usually can be approached via a cervical inci-sion. A sternotomy is needed to deliver these tumors in approxi-mately 5% of cases. Generally, the gland can be approached by a partial sternotomy to the third intercostal space. The midline sternotomy can be extended to the left or right side as required. Upper glands tend to migrate to the posterior mediastinum in the tracheoesophageal groove. Mediastinal glands also may be found in the aortopulmonary window or pericardium, or attached to the ascending aorta, aortic arch, or its branches.Special Situations Normocalcemic Hyperparathyroidism. This disorder is becoming increasingly recognized in clinical practice (preva-lence from 0.5% to 16%) and is defined by the presence of an elevated PTH level with repeatedly normal calcium (including ionized calcium) levels. In addition, other secondary causes of elevated PTH should be ruled out, namely, vitamin D deficiency, osteomalacia, hypercalciuria (renal leak), and renal insufficiency. Data regarding the natural history of this disorder are limited. In a series of 37 patients, Lowe and colleagues87 showed that 19% of patients became frankly hyper-calcemic within 3 years. In addition, 57% developed osteoporo-sis, 11% developed fragility fractures, and 14% developed nephrolithiasis. Although the study had some limitations, it led the authors to suggest that normocalcemic HPT may represent a variant of “symptomatic” PHPT and may not be an early form of “asymptomatic” disease. Limited studies show that 800.811217440.222128040.20.8626Figure 38-34. Location of ectopic upper and lower parathyroid glands. (Reproduced with permission from Akerström G, Malmaeus J, Bergström R: Surgical anatomy of human parathyroid glands, Surgery. 1984 Jan;95(1):14-21.)Brunicardi_Ch38_p1625-p1704.indd 167601/03/19 11:22 AM 1677THYROID, PARATHYROID, AND ADRENALCHAPTER 38parathyroidectomy is more likely to be unsuccessful in these patients. In the absence of strong data, no guidelines are avail-able for this entity.88 As such, most clinicians follow a conserva-tive course unless patients progress to the classic hypercalcemic form or develop nephrolithiasis, reduced bone mineral density, or fragility fractures.Parathyroid Carcinoma. Parathyroid cancer accounts for approximately 1% of PHPT cases. It may be suspected preop-eratively by the presence of severe symptoms, serum calcium levels >14 mg/dL, significantly elevated PTH levels (five times normal), and a palpable parathyroid gland. Local invasion is quite common; approximately 15% of patients have lymph node metastases, and 33% have distant metastases at pre-sentation. Intraoperatively, parathyroid cancer is suggested by the presence of a large, gray-white to gray-brown parathyroid tumor that is adherent to or invasive into surrounding tissues like muscle, thyroid, RLN, trachea, or esophagus. Enlarged lymph nodes also may be present. Frozen sections are generally unreliable. Accurate diagnosis necessitates histologic examina-tion. The major diagnostic criteria include vascular or capsular invasion, trabecular or fibrous stroma, and frequent mitoses. It is, however, important to emphasize that these classic findings are not as frequently noted as previously reported, and some may be found in benign adenomas as well.Treatment of parathyroid cancer consists of neck explora-tion, with en bloc excision of the tumor and the ipsilateral thy-roid lobe, in addition to the removal of contiguous lymph nodes (tracheoesophageal, paratracheal, and upper mediastinal). The recurrent nerve is not sacrificed unless it is directly involved with tumor. Adherent soft tissue structures (strap muscles or other soft tissues) should also be resected.89 Modified radical neck dissection is recommended in the presence of lateral lymph node metastases. Prophylactic neck dissection is not advised. If the diagnosis is made postoperatively, a decision must be made regarding the adequacy of initial surgery based on a review of operative notes, pathology reports, localization studies, and cal-cium and PTH levels. If any question exists, histologic review by another experienced pathologist can be helpful. Additional procedures can include ipsilateral thyroid lobectomy with resec-tion of contiguous structures and lymph nodes if the features are typical or the patient remains hypercalcemic. Patients with equivocal pathologic findings and normocalcemia may be monitored closely. Reoperation is indicated for locally recur-rent or metastatic disease to control hypercalcemia. Adjuvant radiation therapy should be considered in patients at high risk of local recurrence such as those with close or positive margins, invasion of surrounding structures, or tumor rupture. Radiation may also be used as primary therapy in unresectable disease or for palliation of bone metastases. Chemotherapy is not very effective. Bisphosphonates have shown some effectiveness in treating hypercalcemia associated with parathyroid carcinoma. Cinacalcet hydrochloride, a calcimimetic, can reduce PTH lev-els by directly binding to the CASR cells on the parathyroid gland and has been shown to be useful in controlling hyper-calcemia in patients with refractory parathyroid carcinoma.90 Other promising approaches include antiparathyroid hormone immunotherapy, octreotide, and the telomerase inhibitor azido-thymidine, but additional investigations are needed in this area.Familial Hyperparathyroidism. PHPT may occur as a com-ponent of various inherited syndromes such as MEN1 and MEN2A. Inherited PHPT also can occur as isolated familial HPT (non-MEN) or familial HPT with jaw tumors. The diag-nosis of familial HPT is known or suspected in approximately 85% of patients preoperatively. Furthermore, patients with hereditary HPT generally have a higher incidence of multiglan-dular disease, supernumerary glands, and recurrent or persistent disease. Therefore, these patients warrant a more aggressive approach and are not candidates for various focused surgical approaches.91 Although not absolutely necessary, preoperative sestamibi scan and ultrasound can be obtained in patients with inherited HPT to identify potential ectopic glands. A standard bilateral neck exploration is performed, along with a bilateral cervical thymectomy, regardless of the results of localization studies. Both subtotal parathyroidectomy and total parathyroid-ectomy with autotransplantation are appropriate, and parathy-roid tissue also should be cryopreserved. If an adenoma is found in patients with familial HPT, the adenoma and the ipsilateral normal parathyroid glands are resected. The normal-appearing glands on the contralateral side are biopsied and marked, so that only one side of the neck will need to be explored in the event of recurrence. Patients with MEN2A require total thyroidectomy and central neck dissection for prevention/treatment of MTC, a procedure that places the parathyroids at risk. Moreover, HPT is less aggressive in these patients. Hence, only abnormal para-thyroid glands need to be resected at neck exploration. The other normal parathyroid glands should be marked with a clip.Neonatal Hyperparathyroidism. Infants with neonatal HPT present with severe hypercalcemia, lethargy, hypotonia, and mental retardation. This disorder is associated with homozygous mutations in the CASR gene. As indicated earlier, urgent total parathyroidectomy (with autotransplantation and cryopreserva-tion) and thymectomy are indicated. Subtotal resection is associ-ated with high recurrence rates.Parathyromatosis. Parathyromatosis is a rare condition char-acterized by the finding of multiple nodules of hyperfunctioning parathyroid tissue throughout the neck and mediastinum, usu-ally following a previous parathyroidectomy. The true etiology of parathyromatosis is not known. It is postulated to arise either from overgrowth of congenital parathyroid rests (ontogenous parathyromatosis) or seeding at surgery from rupture of parathy-roid tumors or subtotal resection of hyperplastic glands. Para-thyromatosis represents a rare cause of persistent or recurrent HPT92 and can be identified intraoperatively. Aggressive local resection of these deposits can result in normocalcemia but is rarely curative. Some studies suggest that these patients have low-grade carcinoma because of invasion into muscle and other structures distant from the resected parathyroid tumor.Postoperative Care and Follow-Up Patients who have under-gone parathyroidectomy are advised to undergo calcium level checks 2 weeks postoperatively, at 6 months, and then annu-ally. Recurrences are rare (<1%), except in patients with famil-ial HPT. Recurrence rates of 15% at 2 years and 67% at 8 years have been reported for MEN1 patients.Persistent and Recurrent Hyperparathyroidism. Per-sistence is defined as hypercalcemia that fails to resolve after parathyroidectomy and is more common than recurrence, which refers to HPT occurring after an intervening period of at least 6 months of biochemically documented normocalcemia.93 Recurrent disease is far less common than persistent HPT; however, both occur more frequently in the setting of familial HPT and MEN1, in particular. The most common causes for both these states include ectopic parathyroids, unrecognized 9Brunicardi_Ch38_p1625-p1704.indd 167701/03/19 11:22 AM 1678SPECIFIC CONSIDERATIONSPART IIhyperplasia, or supernumerary glands. More rare causes include parathyroid carcinoma, missed adenoma in a normal position, incomplete resection of an abnormal gland, parathyromatosis, or an inexperienced surgeon. The most common sites of ecto-pic parathyroid glands in patients with persistent or recurrent HPT are paraesophageal (28%), mediastinal (26%), intrathymic (24%), intrathyroidal (11%), carotid sheath (9%), and high cer-vical or undescended (2%) (Fig. 38-35).Once the diagnosis of persistent or recurrent HPT is sus-pected, it should be confirmed by the necessary biochemical tests. Other causes of an elevated serum PTH such as renal insufficiency, renal calcium leak, and GI tract abnormalities should be considered. A detailed family history should be per-formed to screen for familial disease, as this will influence the operative approach. In particular, a 24-hour urine collec-tion should be performed to rule out FHH. In redo-parathyroid surgery, the glands are more likely to be in ectopic locations, and postoperative scarring tends to make the procedure more technically demanding. Cure rates are generally lower (80–90% compared with 95–99% for initial operation), and risk of injury to RLNs and permanent hypocalcemia are higher. Therefore, an evaluation of severity of HPT and the patient’s anesthetic risk (using the American Society of Anesthesiology classifica-tion of physical status or the Goldman cardiac index) is impor-tant. There are no published guidelines directly applicable to this group of patients. In general, patients with significant and ongoing problems such as recurrent kidney stones, a markedly elevated calcium level, or ongoing bone loss will need reex-ploration. Patients in whom the diagnosis remains in question or those with equivocal or minimal symptoms may be considered for conservative management. Preoperative localization studies are routinely performed. Noninvasive studies such as a sesta-mibi scan and ultrasound are obtained, supplemented by 4D-CT scans. If these studies are negative, discordant, or equivocal, obtaining an ultrasound-guided aspirate of a suspicious cervi-cal lesion or a highly selective venous catheterization for PTH levels (by an experienced angiographer) is recommended. Previ-ous operative notes and pathology reports should be carefully reviewed and reconciled with the information obtained from localization studies before any neck reexploration. An algorithm for the treatment of patients with recurrent and persistent HPT is shown in Fig. 38-36.Generally, these patients are approached with a focused exploration. The lateral approach is frequently used and can be achieved via the previous incision. The plane between the ster-nocleidomastoid and strap muscle is opened and allows for early identification of the RLN. Parathyroid tissue is cryopreserved routinely. Use of adjuncts, such as measuring intraoperative PTH levels, is critical to ensure adequate resection and avoid potentially harmful additional explorations. In case of difficult reexplorations, additional techniques such as bilateral internal jugular vein sampling for PTH, thyroid lobectomy on the side of the missing gland, cervical thymectomy, and ligation of the ipsi-lateral inferior thyroid artery (after lobectomy, to cause infarc-tion of the missing gland) may be needed. Blind mediastinal exploration is not recommended. In patients who are denied, refuse, or fail exploration, medical options such as cinacalcet may be considered.Figure 38-35. Anatomic location of ectopic parathyroid glands. Numbers represent number of glands found in each location, with a total of 54. (Reproduced with permission from Shen W, Düren M, Morita E, et al: Reoperation for persistent or recurrent primary hyperparathyroidism, Arch Surg. 1996 Aug;131(8):861-867.)High cervicalpositionCarotidsheathIntrathymicIntrathyroidalAnteriormediastinum(nonthymic)AortopulmonarywindowPosteriormediastinumParaesophageal5169213315C3C4C5C6C7T1T2T3T4Brunicardi_Ch38_p1625-p1704.indd 167801/03/19 11:22 AM 1679THYROID, PARATHYROID, AND ADRENALCHAPTER 38Recurrent or persistent HPT1) Confirm diagnosis2) Rule out FHH3) Review operative notes and pathologyParathyroidectomyPositiveNegativeNoninvasivelocalization studiesNegativePositiveSelective venous catheterization for PTHIs tumorlocalized?Follow-upif mildhypercalcemia ParathyroidectomyMedical therapyNoYesFigure 38-36. Management of recurrent and persistent hyperpara-thyroidism (HPT). FHH = familial hypocalciuric hypercalcemia; PTH = parathyroid hormone.Hypercalcemic Crisis. Patients with PHPT may occasionally present acutely with nausea, vomiting, fatigue, muscle weak-ness, confusion, and a decreased level of consciousness—a complex referred to as hypercalcemic crisis. These symptoms result from severe hypercalcemia from uncontrolled PTH secre-tion, worsened by polyuria, dehydration, and reduced kidney function and may occur with other conditions causing hyper-calcemia. Calcium levels are markedly elevated and may be as high as 16 to 20 mg/dL. Parathyroid tumors tend to be large or multiple and may be palpable. Patients with parathyroid cancer or familial HPT are more likely to present with hypercalcemic crisis.Treatment consists of therapies to lower serum calcium levels followed by surgery to correct HPT. The mainstay of therapy involves rehydration with a 0.9% saline solution to keep urine output >100 cc/h. Once urine output is established, diure-sis with furosemide (which increases renal calcium clearance) is begun. If these methods are unsuccessful, other drugs may be used to lower serum calcium levels as outlined in Table 38-13. Occasionally, in life-threatening cases, hemodialysis may be of benefit.Secondary Hyperparathyroidism. Secondary HPT com-monly occurs in patients with chronic renal failure but also may occur in those with hypocalcemia secondary to inadequate cal-cium or vitamin D intake or malabsorption. The pathophysiol-ogy of HPT in chronic renal failure is complex and appears to be related to hyperphosphatemia (and resultant hypocalcemia), deficiency of 1,25-dihydroxy vitamin D due to loss of renal tissue, low calcium intake, decreased calcium absorption, and abnormal parathyroid cell response to extracellular calcium or vitamin D in vitro and in vivo. Patients generally are hypocalce-mic or normocalcemic. Aluminum hydroxide, which often was used as a phosphate binder, has been shown to contribute to the osteomalacia observed in this disease. These patients gen-erally are treated medically with a low-phosphate diet, phos-phate binders, adequate intake of calcium and 1, 25-dihydroxy vitamin D, and a high-calcium, low-aluminum dialysis bath. Calcimimetics have been shown to control parathyroid hyper-plasia and osteitis fibrosa cystica associated with secondary HPT in animal studies and to decrease plasma PTH and total and ionized calcium levels in humans.As the indications for parathyroidectomy were not well established, surgical treatment was traditionally recommended for patients with bone pain, pruritus, and (a) a calciumphosphate product ≥70, (b) calcium >11 mg/dL with markedly elevated PTH, (c) calciphylaxis, (d) progressive renal osteodys-trophy, and (e) soft tissue calcification and tumoral calcinosis, despite maximal medical therapy. Following the introduction of calcimimetics, there appears to have been a reduction in para-thyroidectomy rates. Parathyroidectomy has been reported to maintain biochemical targets for up to 5 years and improve bone density, fracture risk, calcinosis, hemoglobin levels, and even long-term survival. Studies also report that in a large series of patients on hemodialysis, calcimimetics increased the likelihood of achieving goal PTH (≤300 pg/mL), calcium, phosphate, and Ca × PO4 product, in addition to reducing the risk of fractures and cardiovascular complications.In the absence of randomized trials comparing medical ther-apy with parathyroidectomy, current recommendations from the National Kidney Foundation’s Kidney Disease Quality Outcomes Initiative (KDOQI) advise parathyroidectomy for patients on maximal medical therapy with (a) severe HPT (defined as PTH >800 pg/mL, (b) hypercalcemia, (c) osteoporosis or pathologic bone fracture, (d) Symptoms and signs such as pruritis, bone pain, severe vascular calcifications, myopathy, and (e) calci-phylaxis.94 Calciphylaxis is a rare, limband life-threatening complication of secondary HPT characterized by painful (some-times throbbing), violaceous, and mottled lesions usually on the extremities, which often become necrotic and progress to non-healing ulcers, gangrene, sepsis, and death. Skin biopsy can be helpful to make the diagnosis. These are critically ill, high-risk patients, but successful parathyroidectomy sometimes relieves symptoms. Not all patients with calciphylaxis will have high PTH levels, and parathyroidectomy should not be undertaken in the absence of documented hyperparathyroidism. Assessment of parathyroid mass is thought to be an important factor for pre-dicting the response to medical management. Therefore, some groups recommend parathyroidectomy if the glands are >1 cm (or >500 mm3) on ultrasound. These glands are more likely to have developed nodular hyperplasia and hence might be refrac-tory to medical management.Patients should undergo routine dialysis the day before surgery to correct electrolyte abnormalities. Localization stud-ies are not necessary but can identify ectopic parathyroid glands. A bilateral neck exploration is indicated. The parathyroid glands in secondary HPT are characterized by asymmetric enlargement and nodular hyperplasia. These patients may be treated by sub-total resection, leaving about 50 mg of the most normal parathy-roid gland or total parathyroidectomy and autotransplantation Brunicardi_Ch38_p1625-p1704.indd 167901/03/19 11:22 AM 1680SPECIFIC CONSIDERATIONSPART IIof parathyroid tissue into the brachioradialis muscle of the non-dominant forearm, with parathyroid cryopreservation. Upper thymectomy usually is performed because 15% to 20% of patients have one or more parathyroid glands situated in the thy-mus or perithymic fat. Some groups recommend total parathy-roidectomy without autotransplantation because it is associated with a lower rate of recurrence.95 While it may be preferable in patients with calciphylaxis, this procedure is contraindicated in patients eligible for renal transplant. Since the evidence needed to determine the superiority of one approach over another is lacking, the choice of procedure is influenced by surgeon pref-erence and experience and various patient factors, as indicated earlier.Tertiary Hyperparathyroidism. Generally, renal transplan-tation is an excellent method of treating secondary HPT, but some patients develop autonomous parathyroid gland function and tertiary HPT. Tertiary HPT can cause problems similar to PHPT, such as pathologic fractures, bone pain and worsened bone disease, renal stones, peptic ulcer disease, pancreatitis, and mental status changes. The transplanted kidney is also at risk from tubulointerstitial calcification and volume depletion. Similar to patients with secondary HPT, many patients with ter-tiary HPT are being treated with cinacalcet. Although the drug is effective and well-tolerated in these patients, the long-term effects on kidney allograft function are not known, and many of these patients have persistence of their hypercalcemic symp-toms. On the other hand, parathyroidectomy has been shown to lead to a more immediate and dramatic reduction in hypercal-cemic symptoms. As such, operative intervention is indicated if autonomous PTH secretion persists for >1 year after a successful transplant in patients with hypophosphatemia, low BMD/severe osteopenia, symptoms, and signs such as fatigue, pruritis, bone pain, peptic ulcer disease or nephrocalcinosis, provided they are deemed operative candidates.96 All parathyroid glands should be identified. The traditional surgical management of these patients consisted of subtotal or total parathyroid-ectomy with autotransplantation and an upper thymectomy. Some authors suggest that these patients derive similar benefit from excision of only obviously enlarged glands, while avoid-ing the higher risks of hypocalcemia associated with the for-mer approach. Others recommend that all parathyroid glands be identified and subtotal parathyroidectomy be performed as long-term follow-up studies show that limited excisions in these patients are associated with an up to fivefold increased risk of recurrent or persistent disease. Further studies are needed to define the best operative approach for these patients.Complications of Parathyroid Surgery. Parathyroidectomy can be accomplished successfully in >95% of patients with minimal mortality and morbidity, provided the procedure is performed by a surgeon experienced in parathyroid surgery. Table 38-13Medications commonly used to treat hypercalcemiaMEDICATIONDOSAGE AND ADMINISTRATIONMECHANISM, ONSET OF ACTION, AND DURATIONSIDE EFFECTSBisphosphonates (pamidronate, zolendronic acid preferred in patients with malignancy due to rapid action)60–90 mg IV over 4–24 hInhibits osteoclastic bone resorption; rapid onset, 2–3 dMay cause local pain and swelling, low-grade fever, lymphopenia, electrolyte abnormalities, osteonecrosis of the jaw in some patients (iv use)Calcitonin4 IU/kg SC/IMInhibits osteoclast function, augments renal calcium excretion; onset of action in hours; but short lived, therefore not useful as sole therapyTransient nausea and vomiting, abdominal cramps, flushing, and local skin reactionMithramycin (plicamycin)25 μg/kg/d IV for 3–4 dInhibits osteoclasts RNA secretion; rapid onset of action (12 h); peaks at 48–72 h and lasts days to several weeksMay cause renal, hepatic, and hematologic complications, nausea and vomitingGallium nitrate200 mg/m2 BSA/d IV for 5 dReduces urinary calcium excretion; onset of action delayed (5–7 d)Nephrotoxicity, nausea, vomiting, hypotension, anemia, hypophosphatemiaGlucocorticoidsHydrocortisone 100 mg IV q8hDelayed onset of action (7–10 d); useful for hematologic malignancies, sarcoidosis, vitamin D intoxication, hyperthyroidismHypertension, hyperglycemiaCalcimimetics (cinacalcet)Up to 90 mg 3 o 4 times per dayUseful in patients with parathyroid carcinoma and patients with chronic renal failureGastrointestinal complaints, hypotension, hypocalcemiaBSA = body surface area; IM = intramuscular; IV = intravenous; SC = subcutaneous.Brunicardi_Ch38_p1625-p1704.indd 168001/03/19 11:22 AM 1681THYROID, PARATHYROID, AND ADRENALCHAPTER 38Table 38-14Conditions causing hypocalcemiaHypoparathyroidism • Surgical • Neonatal • Familial • Heavy metal deposition • Magnesium depletionResistance to the action of parathyroid hormone • Pseudohypoparathyroidism • Renal failure • Medications—calcitonin, bisphosphonates, mithramycinFailure of normal 1,25-dihydroxy vitamin D productionResistance to the action of 1,25-dihydroxy vitamin DAcute complex formation or deposition of calcium • Acute hyperphosphatemia • Acute pancreatitis • Massive blood transfusion (citrate overload) • “Hungry bones”Specific complications include transient and permanent vocal cord palsy and hypoparathyroidism. The latter is more likely to occur in patients who undergo four-gland exploration with biopsies, subtotal resection with an inadequate remnant, or total parathyroidectomy with a failure of autotransplanted tissue. Furthermore, hypocalcemia is more likely to occur in patients with high-turnover bone disease as evidenced by elevated pre-operative alkaline phosphatase levels. Vocal cord paralysis and hypoparathyroidism are considered permanent if they persist for >6 months. Fortunately, these complications are rare, occurring in approximately 1% of patients undergoing surgery by experi-enced parathyroid surgeons.Patients with symptomatic hypocalcemia or those with calcium levels <8 mg/dL are treated with oral calcium supple-mentation (up to 1–2 g every 4 hours). 1,25-Dihydroxy vitamin D (calcitriol [Rocaltrol] 0.25–0.5 μg twice a day) may also be required, particularly in patients with severe hypercalcemia and elevated serum alkaline phosphatase levels, preoperatively and with osteitis fibrosa cystica. Intravenous calcium supplementa-tion rarely is needed, except in cases of severe, symptomatic hypocalcemia.HypoparathyroidismHypocalcemia can be the result of a multitude of conditions, which are listed in Table 38-14. The parathyroid glands may be congenitally absent in DiGeorge syndrome, which also is characterized by lack of thymic development and, therefore, a thymus-dependent lymphoid system. By far, the most common cause of hypoparathyroidism is thyroid surgery, particularly total thyroidectomy with a concomitant central neck dissection. Patients often develop transient hypocalcemia due to ischemia of the parathyroid glands; permanent hypoparathyroidism is rare. Hypoparathyroidism also may occur after parathyroid surgery, which is more likely if patients undergo a subtotal resection or total parathyroidectomy with parathyroid autotransplantation.Acute hypocalcemia results in decreased ionized calcium and increased neuromuscular excitability. Patients initially develop circumoral and fingertip numbness and tingling. Mental symptoms include anxiety, confusion, and depression. Physical examination reveals positive Chvostek’s sign (contraction of facial muscles elicited by tapping on the facial nerve anterior to the ear) and Trousseau’s sign (carpopedal spasm that is elic-ited by occluding blood flow to the forearm with a blood pres-sure cuff for 2–3 minutes). Tetany, which is characterized by tonic-clonic seizures, carpopedal spasm, and laryngeal stridor, may prove fatal and should be avoided. Most patients with post-operative hypocalcemia can be treated with oral calcium and vitamin D supplements; IV calcium infusion is rarely required except in patients with preoperative osteitis fibrosa cystica.ADRENALHistorical BackgroundEustachius provided the first accurate anatomic account of the adrenals in 1563. The anatomic division of the adrenals into the cortex and medulla was described much later, by Cuvier in 1805. Subsequently, Thomas Addison in 1855 described the features of adrenal insufficiency, which still bear his name. DeCreccio provided the first description of congenital adrenal hyperplasia (CAH) occurring in a female pseudohermaphrodite in 1865. Pheochromocytomas were first identified by Frankel in 1885, but were not named as such until 1912 by Pick, who noted the characteristic chromaffin reaction of the tumor cells. Adren-aline was identified as an agent from the adrenal medulla that elevated blood pressure in dogs and was subsequently named epinephrine in 1897. The first successful adrenalectomies for pheochromocytoma were performed by Roux in Switzerland and Charles Mayo in the United States.In 1932, Harvey Cushing described 11 patients who had moon facies, truncal obesity, hypertension, and other features of the syndrome that now bears his name. Although several individuals prepared adrenocortical extracts to treat adrenalec-tomized animals, cortisone was first synthesized by Kendall. Aldosterone was identified in 1952, and the syndrome result-ing from excessive secretion of this mineralocorticoid was first described in 1955 by Conn.EmbryologyThe adrenal or suprarenal glands are two endocrine organs in one; an outer cortex and an inner medulla, each with distinct embryologic, anatomic, histologic, and secretory features. The cortex originates around the fifth week of gestation from mesodermal tissue near the gonads on the adrenogenital ridge (Fig. 38-37). Therefore, ectopic adrenocortical tissue may be found in the ovaries, spermatic cord, and testes. The cortex dif-ferentiates further into a thin, definitive cortex and a thicker, inner fetal cortex. The latter is functional and produces fetal adrenal steroids by the eighth week of gestation, but undergoes involution after birth, resulting in a decrease in adrenal weight during the first three postpartum months. The definitive cor-tex persists after birth to form the adult cortex over the first 3 years of life. In contrast, the adrenal medulla is ectodermal in origin and arises from the neural crest. At around the same time as cortical development, neural crest cells migrate to the para-aortic and paravertebral areas and toward the medial aspect of the developing cortex to form the medulla. Most extra-adrenal neural tissue regresses but may persist at several sites. The larg-est of these is located to the left of the aortic bifurcation near the inferior mesenteric artery origin and is designated as the organ of Zuckerkandl. Adrenal medullary tissue also may be found in neck, urinary bladder, and para-aortic regions. Several Brunicardi_Ch38_p1625-p1704.indd 168101/03/19 11:22 AM 1682SPECIFIC CONSIDERATIONSPART IIfactors are involved in adrenal development and include insulin-like growth factor 2; gastric inhibitory peptide; and the dosagesensitive, sex-reversal adrenal hypoplasia (DAX1) gene.AnatomyThe adrenal glands are paired, retroperitoneal organs located superior and medial to the kidneys at the level of the elev-enth ribs. The normal adrenal gland measures 5 × 3 × 1 cm and weighs 4 to 5 g. The right gland is pyramidal shaped and lies in close proximity to the right hemidiaphragm, liver, and inferior vena cava (IVC). The left adrenal is closely associated with the aorta, spleen, and tail of the pancreas. Each gland is supplied by three groups of vessels—the superior adrenal arter-ies derived from the inferior phrenic artery, the middle adrenal arteries derived from the aorta, and the inferior adrenal arteries derived from the renal artery. Other vessels originating from the intercostal and gonadal vessels may also supply the adrenals. These arteries branch into about 50 arterioles to form a rich plexus beneath the glandular capsule and require careful dissec-tion, ligation, and division during adrenalectomy. In contrast to the arterial supply, each adrenal usually is drained by a single, major adrenal vein. The right adrenal vein is usually short and drains into the IVC, whereas the left adrenal vein is longer and empties into the left renal vein after joining the inferior phrenic vein. Accessory veins occur in 5% to 10% of patients—on the right, these vessels may drain into the right hepatic vein or the right renal vein; on the left, accessory veins may drain directly into the left renal vein. The anatomic relationships of the adre-nals and surrounding structures are depicted in Fig. 38-38.The adrenal cortex appears yellow due to its high lipid content and accounts for about 80% to 90% of the gland’s vol-ume. Histologically, the cortex is divided into three zones—the zona glomerulosa, zona fasciculata, and zona reticularis. The outer area of the zona glomerulosa consists of small cells and is the site of production of the mineralocorticoid hormone, aldo-sterone. The zona fasciculata is made up of larger cells, which often appear foamy due to multiple lipid inclusions, whereas the zona reticularis cells are smaller. These latter zones are the site of production of glucocorticoids and adrenal androgens. The adrenal medulla constitutes up to 10% to 20% of the gland’s volume and is reddish-brown in color. It produces the catechol-amine hormones epinephrine and norepinephrine. The cells of the adrenal medulla are arranged in cords and are polyhedral in shape. They often are referred to as chromaffin cells because they stain specifically with chromium salts.Adrenal PhysiologyCholesterol, derived from the plasma or synthesized in the adre-nal, is the common precursor of all steroid hormones derived from the adrenal cortex. Cholesterol initially is cleaved within mitochondria to 5-δ-pregnolone, which in turn is transported to the smooth endoplasmic reticulum where it forms the substrate for various biosynthetic pathways leading to steroidogenesis (Fig. 38-39).Mineralocorticoids. The major adrenal mineralocorticoid hormones are aldosterone, 11-deoxycorticosterone (DOC), and cortisol. Cortisol has minimal effects on the kidney due to hor-mone degradation. Aldosterone secretion is regulated primarily by the renin-angiotensin system. Decreased renal blood flow, decreased plasma sodium, and increased sympathetic tone all stimulate the release of renin from juxtaglomerular cells. Renin, in turn, leads to the production of angiotensin I from its pre-cursor angiotensinogen. Angiotensin I is cleaved by pulmo-nary angiotensin-converting enzyme (ACE) to angiotensin II; the latter is not only a potent vasoconstrictor, but it also leads to increased aldosterone synthesis and release. Hyperkalemia is another potent stimulator of aldosterone synthesis, whereas ACTH, pituitary pro-opiomelanocortin, and antidiuretic hor-mone are weak stimulators.Aldosterone is secreted at a rate of 50 to 250 μg/d (depend-ing on sodium intake) and circulates in plasma chiefly as a complex with albumin. Small amounts of the hormone bind to corticosteroid-binding globulin, and approximately 30% to 50% of secreted aldosterone circulates in a free form. The hormone has a half-life of only 15 to 20 minutes and is rapidly cleared via the liver and kidney. A small quantity of free aldosterone also is excreted in the urine. Mineralocorticoids cross the cell membrane and bind to cytosolic receptors. The receptor-ligand complex subsequently is transported into the nucleus where it induces the transcription and translation of specific genes. Aldo-sterone functions mainly to increase sodium reabsorption and potassium and hydrogen ion excretion at the level of the renal distal convoluted tubule. Less commonly, aldosterone increases sodium absorption in salivary glands and GI mucosal surfaces.9123678CA45BFigure 38-37. Cross-section of the embryo depicting adrenal development: (1) neural tube, (2) chorda, (3) aorta, (4) base of the mesentery, (5) digestive tube, (6) adrenal cortex, (7) undifferenti-ated gonad, (8) mesonephros, and (9) neural crest. Cells migrate from the neural crest to form the ganglia of the sympathetic trunk (A), sympathetic plexi (B), and the adrenal medulla and paraganglia (C). (Reproduced with permission from Avisse C, Marcus C, Patey M, et al: Surgical anatomy and embryology of the adrenal glands, Surg Clin North Am. 2000 Feb;80(1):403-415.)Brunicardi_Ch38_p1625-p1704.indd 168201/03/19 11:22 AM 1683THYROID, PARATHYROID, AND ADRENALCHAPTER 38AbdominalaortaInferiorvena cavaLeft inferiorphrenica. and v.Right phrenic a.Celiac trunkSuperiormesenteric a.Left adrenal gland Right adrenal gland Left superior adrenal aa.Right superior adrenal aa.Inferior adrenal a.Renal a. and v.Left adrenal v.Inferior adrenal a.Rightadrenalv.Middleadrenala.Figure 38-38. Anatomy of the adrenals and surrounding structures. a. = artery; v. = vein.Pregnenolone17˜-hydroxypregnenoloneAndrostenedioneDHEADHEASCortisolAldosteroneCholesterol12217˜-hydroxyprogesterone311-deoxycortisol42Progesterone311-deoxy-corticosterone4.5Corticosterone518-hydroxy-corticosterone567678Figure 38-39. Synthesis of adrenal steroids. The enzymes involved are (1) p450scc (cholesterol side chain cleavage), (2) 3β-hydroxysteroid dehydrogenase, (3) p450c21 (21β-hydroxylase), (4) p450c11 (11β-hydroxylase), (5) p450c11AS (aldosterone synthase), (6) p450c17 (17α-hydroxylase activity), (7) p450c17 (17,20-lyase/desmolase activity), and (8) sulfokinase. DHEAS = dehydroepiandrosterone sulfate.Glucocorticoids. The secretion of cortisol, the major adrenal glucocorticoid, is regulated by ACTH secreted by the anterior pituitary, which, in turn, is under the control of corticotrophin-releasing hormone (CRH) secreted by the hypothalamus. ACTH is a 39-amino-acid protein, which is derived by cleavage from a larger precursor, pro-opiomelanocortin. ACTH is further cleaved into α-melanocyte-stimulating hormone and corticotrophin-like intermediate peptide. ACTH not only stimulates the secretion of glucocorticoids, mineralocorticoids, and adrenal androgens, but is also trophic for the adrenal glands. ACTH secretion may be Brunicardi_Ch38_p1625-p1704.indd 168301/03/19 11:22 AM 1684SPECIFIC CONSIDERATIONSPART IIstimulated by pain, stress, hypoxia, hypothermia, trauma, and hypoglycemia. ACTH secretion fluctuates, peaking in the morn-ing and reaching nadir levels in the late afternoon. Thus, there is a diurnal variation in the secretion of cortisol, with peak cortisol excretion also occurring in the early morning and declining dur-ing the day to its lowest levels in the evening (Fig. 38-40). Corti-sol controls the secretion of both CRH and ACTH via a negative feedback loop. A similar mechanism leads to the inhibition of CRH secretion by ACTH.Cortisol is transported in plasma bound primarily to corti-costeroid-binding globulin (75%) and albumin (15%). Approxi-mately 10% of circulating cortisol is free and is the biologically active component. The plasma half-life of cortisol is 60 to 90 minutes and is determined by the extent of binding and rate of inactivation. Cortisol is converted to diand tetrahydrocor-tisol and cortisone metabolites in the liver and the kidney. The majority (95%) of cortisol and cortisone metabolites are con-jugated with glucuronic acid in the liver, thus facilitating their renal excretion. A small amount of unmetabolized cortisol is excreted unchanged in the urine.Glucocorticoid hormones enter the cell and bind cytosolic steroid receptors. The activated receptor-ligand complex is then transported to the nucleus where it stimulates the transcription of specific target genes via a “zinc finger” DNA binding ele-ment. Cortisol also binds the mineralocorticoid receptor with an affinity similar to aldosterone. However, the specificity of mineralocorticoid action is maintained by the production of 11β-hydroxysteroid dehydrogenase, an enzyme that inactivates cortisol to cortisone in the kidney. Glucocorticoids have impor-tant functions in intermediary metabolism but also affect con-nective tissue, bone, immune, cardiovascular, renal, and central nervous systems, as outlined in Table 38-15.Sex Steroids. Adrenal androgens are produced in the zona fasciculata and reticularis from 17-hydroxypregnenolone in response to ACTH stimulation. They include dehydroepiandros-terone (DHEA) and its sulfated counterpart (DHEAS), andro-stenedione, and small amounts of testosterone and estrogen. Adrenal androgens are weakly bound to plasma albumin. They exert their major effects by peripheral conversion to the more potent testosterone and dihydrotestosterone but also have weak intrinsic androgen activity. Androgen metabolites are conju-gated as glucuronides or sulfates and excreted in the urine. Dur-ing fetal development, adrenal androgens promote the formation of male genitalia. In normal adult males, the contribution of adrenal androgens is minimal; however, they are responsible for the development of secondary sexual characteristics at puberty. Adrenal androgen excess leads to precocious puberty in boys and virilization, acne, and hirsutism in girls and women.Catecholamines. Catecholamine hormones (epinephrine, norepinephrine, and dopamine) are produced not only in the central and sympathetic nervous system but also the adrenal medulla. The substrate, tyrosine, is converted to catechol-amines via a series of steps shown in Fig. 38-41A. Phenyletha-nolamine N-methyltransferase, which converts norepinephrine to epinephrine, is only present in the adrenal medulla and the organ of Zuckerkandl. Therefore, the primary catecholamine produced may be used to distinguish adrenal medullary tumors from those situated at extra-adrenal sites. Catecholamines are stored in granules in combination with other neuropeptides, ATP, calcium, magnesium, and water-soluble proteins called chromogranins. Hormonal secretion is stimulated by various stress stimuli and mediated by the release of acetylcholine at the preganglionic nerve terminals. In the circulation, these pro-teins are bound to albumin and other proteins. Catecholamines are cleared by several mechanisms including reuptake by sym-pathetic nerve endings, peripheral inactivation by catechol O-methyltransferase and monoamine oxidase, and direct excre-tion by the kidneys. Metabolism of catecholamines takes place 2520151050Noon4 PM8 PMMidnight4 AM8 AMNoonLunchSnackSnackDinnerSleepB’fast200180160140120100806040200Plasma ACTH (pg/mL)Plasma 11-ohcs (µg/dL) Figure 38-40. Diurnal variation in cortisol levels as determined by half-hourly sampling in a 16-year-old girl. (Reproduced with permission from Krieger DT, Allen W, Rizzo F, et al: Characterization of the normal temporal pattern of plasma corticosteroid levels, J Clin Endocrinol Metab. 1971 Feb;32(2):266-284.)Brunicardi_Ch38_p1625-p1704.indd 168401/03/19 11:22 AM 1685THYROID, PARATHYROID, AND ADRENALCHAPTER 38Table 38-15Functions of glucocorticoid hormonesFUNCTION/SYSTEMEFFECTSGlucose metabolismIncreased hepatic glycogen deposition, gluconeogenesis, decreased muscle glucose uptake and metabolismProtein metabolismDecreased muscle protein synthesis, increased catabolismFat metabolismIncreased lipolysis in adipose tissueConnective tissueInhibition of fibroblasts, loss of collagen, thinning of skin, striae formationSkeletal systemInhibition of bone formation, increased osteoclast activity, potentiate the action of PTHImmune systemIncreases circulation of polymorphonuclear cells; decreases numbers of lymphocytes, monocytes, and eosinophils; reduces migration of inflammatory cells to sites of injuryCardiovascular systemIncreases cardiac output and peripheral vascular toneRenal systemSodium retention, hypokalemia, hypertension via mineralocorticoid effect, increased glomerular filtration via glucocorticoid effectsEndocrine systemInhibits TSH synthesis and release, decreased TBG levels, decreased conversion of T4 to T3PTH = parathyroid hormone; T3 = 3,5’,3-triiodothyronine; T4 = thyroxine; TBG = thyroxine-binding globulin; TSH = thyroid-stimulating hormone.primarily in the liver and kidneys and leads to the formation of metabolites such as metanephrines, normetanephrines, and VMA, which may undergo further glucuronidation or sulfation before being excreted in the urine (Fig. 38-41B).Adrenergic receptors are transmembrane-spanning mol-ecules that are coupled to G proteins. They may be subdivided into α and β subtypes, which are localized in different tissues, have varying affinity to various catecholamines, and mediate distinct biologic effects (Table 38-16). The receptor affinities for α receptors are—epinephrine > norepinephrine >> isopro-terenol; β1 receptors—isoproterenol > epinephrine = norepi-nephrine; and β2 receptors—isoproterenol > epinephrine >> norepinephrine.Disorders of the Adrenal CortexHyperaldosteronism. Hyperaldosteronism may be secondary to stimulation of the renin-angiotensin system from renal artery stenosis and to low-flow states such as congestive heart failure and cirrhosis. Hyperaldosteronism resulting from these condi-tions is reversible by treatment of the underlying cause. Primary hyperaldosteronism results from autonomous aldosterone secre-tion, which, in turn, leads to suppression of renin secretion. Pri-mary aldosteronism usually occurs in individuals between the ages of 30 to 50 years old and accounts for 1% of hypertension cases. It is associated with hypokalemia; however, more patients with Conn’s syndrome are being diagnosed with normal potas-sium levels. Most cases result from a solitary functioning adre-nal adenoma (∼70%) and idiopathic bilateral hyperplasia (30%). Adrenocortical carcinoma and glucocorticoid-suppressible hyperaldosteronism are rare, each accounting for <1% of cases. Glucocorticoid-suppressible hyperaldosteronism is an auto-somal dominant form of hypertension in which aldosterone secretion is abnormally regulated by ACTH. This condition is caused by recombinations between linked genes encoding closely related isozymes, 11b-hydroxylase (CYP11B1), and aldosterone synthase (CYP11B2) generating a dysregulated chimeric gene with aldosterone synthase activity. This entity is now designated familial hyperaldosteronism type I (FH-I). Initially, FH-III referred to patients with massive adrenal hyper-plasia refractory to glucocorticoid administration. However, the term is now more commonly used to describe patients with pri-mary hyperaldosteronism due to germline KCNJ5 mutations. This gene encodes an inward rectifier potassium channel, and the mutations affected amino acids in or close to the chan-nel’s selectivity filter. Somatic gain of function mutations are found in up to 40% of aldosterone-producing adenomas (APA). Familial hyperaldosteronism type II refers to families in which two first-degree relatives have been diagnosed with primary hyperaldosteronism (adenoma or hyperplasia) and in whom types I and III have been excluded. Other genes mutated in (APA) include CACNA1D (encodes a voltage-gated L-type calcium channel), ATP1A1 (encodes part of the Na+-K+-ATPase), ATP2B3 (encodes the plasma membrane Ca2+ ATPase), CACNA1H (encodes the α1 subunit of the T-type voltage calcium channel), and CTNNB1 (β-catenin).97Symptoms and Signs Patients typically present with hyperten-sion, which is long-standing, moderate to severe, and may be difficult to control despite multiple-drug therapy. Other symp-toms include muscle weakness, polydipsia, polyuria, nocturia, headaches, and fatigue. Weakness and fatigue are related to the presence of hypokalemia.Diagnostic Studies Laboratory Studies. Hypokalemia is a common finding, and hyperaldosteronism must be suspected in any hypertensive patient who presents with coexisting spontaneous hypokale-mia (K <3.2 mmol/L) or hypokalemia (<3 mmol/L) while on diuretic therapy, despite potassium replacements. However, it is important to note that up to 40% of patients with a confirmed aldosteronoma were normokalemic preoperatively. Once the diagnosis is suspected, further tests are necessary to confirm the diagnosis. Before testing, patients must receive adequate sodium and potassium. Antihypertensive medications should be held, if possible, and spironolactone, β-blockers, ACE inhibitors, and angiotensin II receptor blockers should be avoided. Patients with primary hyperaldosteronism have an ele-vated plasma aldosterone concentration level with a suppressed plasma renin activity; a plasma aldosterone concentrationto-plasma renin activity ratio of 1:25 to 30 is strongly sugges-tive of the diagnosis.98 False-positive results can occur, particularly in patients with chronic renal failure. Patients with primary hyperaldosteronism also fail to suppress aldosterone levels with sodium loading. This test can be performed by performing a 24-hour urine collection for cortisol, sodium, and aldosterone after 5 days of a high-sodium diet or alternatively giving the Brunicardi_Ch38_p1625-p1704.indd 168501/03/19 11:22 AM 1686SPECIFIC CONSIDERATIONSPART IIFigure 38-41. A. Synthesis of catecholamines. B. Metabolism of catecholamine hormones.Tyrosine hydroxylaseL-amino acid decarboxylase Dopamine-beta-hydroxylasePhenylethanolamine-N-methyltransferaseATyrosineDopa(L-dihydroxyphenylalanine)DopamineNorepinephrineEpinephrineMAOMAOMAOMAODihydroxymandelicacid3-methoxy-4-hydroxymandelic acidCOMTCOMTCOMTEpinephrineNorepinephrineMetanephrineNormetanephrineMAO Monoamine oxidase COMT Catechol O-methyltransferaseBBrunicardi_Ch38_p1625-p1704.indd 168601/03/19 11:22 AM 1687THYROID, PARATHYROID, AND ADRENALCHAPTER 38Table 38-16Catecholamine hormone receptors and effects they mediateRECEPTORTISSUEFUNCTIONα1Blood vesselsContraction GutDecreased motility, increased sphincter tone PancreasDecreased insulin and glucagon release LiverGlycogenolysis, gluconeogenesis EyesPupil dilation UterusContraction SkinSweatingα2Synapse (sympathetic)Inhibits norepinephrine release PlateletAggregationβ1HeartChronotropic, inotropic Adipose tissueLipolysis GutDecreased motility, increased sphincter tone PancreasIncreased insulin and glucagon releaseβ2Blood vesselsVasodilation BronchiolesDilation UterusRelaxationpatient 2 L of saline while in the supine position, 2 to 3 days after being on a low-sodium diet. Plasma aldosterone level <5 ng/dL or a 24-hour urine aldosterone <14 μg after saline loading essentially rules out primary hyperaldosteronism. Once the biochemical diagnosis is confirmed, further evaluation should be directed at determining which patients have a unilat-eral aldosteronoma vs. bilateral hyperplasia because surgery is almost always curative for the former, but usually not the latter. No biochemical studies can make this distinction with 100% sensitivity; thus, imaging studies are necessary.Radiologic Studies. CT scans with 0.5-cm cuts in the adrenal area can localize aldosteronomas with a sensitivity of 90%. A unilateral 0.5to 2-cm adrenal tumor with a normal-appearing contralateral gland confirms an aldosteronoma in the presence of appropriate biochemical parameters. MRI scans are less sen-sitive but more specific, particularly if opposed phase chemi-cal shift images are obtained. MRI scans also have increased use in pregnant patients or those unable to tolerate intravenous contrast. If adrenal hyperplasia is suspected, the algorithm depicted in Fig. 38-42 is useful. Selective venous catheteriza-tion and adrenal vein sampling (AVS) for aldosterone have been demonstrated to be 95% sensitive and 90% specific in localiz-ing the aldosteronoma. In this procedure, the adrenal veins are cannulated, and blood samples for aldosterone and cortisol are obtained from both adrenal veins and the vena cava after ACTH administration.99 Measurement of cortisol levels is necessary to confirm proper placement of the catheters in the adrenal veins. A greater than fourfold difference in the aldosterone-to-cortisol ratios between the adrenal veins indicates the presence of a uni-lateral tumor. Some investigators use this study routinely, but it is invasive, requires an experienced interventional radiolo-gist, and can lead to adrenal vein rupture in approximately 1% of cases. Therefore, most groups advocate use of this modal-ity selectively in ambiguous cases, when the tumor cannot be localized and in patients with bilateral adrenal enlargement to determine whether there is unilateral or bilateral increased secretion of aldosterone.100 Additional indications for forgoing AVS include patients who are suspected of having adrenocor-tical carcinoma, those with comorbid conditions precluding surgery and those with proven familial hyperaldosteronism type I or III. Scintigraphy with 131I-6β-iodomethyl noriodocho-lesterol (NP-59) also may be used for the same purpose. Like cholesterol, this compound is taken up by the adrenal cortex, but unlike cholesterol, it remains in the gland without undergo-ing further metabolism. Adrenal adenomas appear as “hot” nod-ules with suppressed contralateral uptake, whereas hyperplastic glands show bilaterally increased uptake. This test, however, is not widely available. Newer isotopes such as 11C-metomidate in conjunction with PET-CT have also shown promise in the localization of aldosteronomas.101AdrenalectomyBilateral hyperfunctionor failure to localizeMedical managementAdrenalectomyUnilateralincreased aldosteroneCT scan or MRIUnilateral adrenal tumorusually 0.5 2 cmin diameterBilaterallyabnormal or normaladrenals1) Selective venous catheterization for aldosterone and cortisol or2) NP-59 scanFigure 38-42. Management of an adrenal aldosteronoma. CT = computed tomography; MRI = magnetic resonance imaging.Brunicardi_Ch38_p1625-p1704.indd 168701/03/19 11:22 AM 1688SPECIFIC CONSIDERATIONSPART IIFigure 38-43. Some characteristic features of Cushing’s syndrome—moon facies, hirsutism, and acne.Table 38-17Etiology of Cushing’s syndromeACTH-dependent (70%) • Pituitary adenoma or Cushing’s disease (∼70%) • Ectopic ACTH productiona (∼10%) • Ectopic CRH production (<1%)ACTH-independent (20–30%) • Adrenal adenoma (10–15%) • Adrenal carcinoma (5–10%) • Adrenal hyperplasia—pigmented micronodular cortical hyperplasia or gastric inhibitory peptide-sensitive macronodular hyperplasia (5%)Other • Pseudo-Cushing’s syndrome • Iatrogenic—exogenous administration of steroidsaFrom small cell lung tumors, pancreatic islet cell tumors, medullary thyroid cancers, pheochromocytomas, and carcinoid tumors of the lung, thymus, gut, pancreas, and ovary.ACTH = adrenocorticotropic hormone; CRH = corticotrophin-releasing hormone.Treatment Preoperatively, control of hypertension and ade-quate potassium supplementation (to keep K >3.5 mmol/L) are important. Patients generally are treated with spironolactone (an aldosterone antagonist), amiloride (a potassium-sparing diuretic that blocks sodium channels in the distal nephron), nifedipine (a calcium channel blocker), or captopril (an ACE inhibitor). Unilateral tumors producing aldosterone are best managed by adrenalectomy, either by a laparoscopic approach (preferred) or via a posterior open approach. If a carcinoma is suspected because of the large size of the adrenal lesion or mixed hormone secretion, an anterior transabdominal approach is preferred to permit adequate determination of local invasion and distal metastases. Only 20% to 30% of patients with hyperaldosteron-ism secondary to bilateral adrenal hyperplasia benefit from sur-gery, and as described, selective venous catheterization is useful to predict which patients will respond. For the other patients, medical therapy with spironolactone, amiloride, or triamterene is the mainstay of management. Glucocorticoid-suppressible hyperaldosteronism is treated by administering exogenous dexa-methasone at doses of 0.5 to 1 mg daily. Treatment with spirono-lactone may help decrease glucocorticoid requirements in this condition and avoid symptoms of Cushing’s syndrome. Postop-eratively, some patients experience transient hypoaldosteronism requiring mineralocorticoids for up to 3 months. Recent studies suggest that postresection hyperkalemia may be more common and last longer than previously appreciated; therefore, it should be screened for in patients who are older and who have had a longer duration of hypertension, impaired kidney function, and higher preoperative aldosterone levels, making them a high-risk group.102 Rarely, acute Addison’s disease may occur 2 to 3 days after adrenalectomy. Adrenalectomy is >90% successful in improving hypokalemia and about 70% successful in cor-recting hypertension. Patients who respond to spironolactone therapy and those with a shorter duration of hypertension with minimal renal damage are more likely to achieve improvement in hypertension, whereas male patients, those >50 years old, and those with multiple adrenal nodules, are least likely to benefit from adrenalectomy.Cushing’s Syndrome. Cushing described patients with a pecu-liar fat deposition, amenorrhea, impotence (in men), hirsutism, purple striae, hypertension, diabetes, and other features that con-stitute the syndrome (Fig. 38-43). He also recognized that sev-eral of these patients had basophilic tumors of the pituitary gland and concluded that these tumors produced hormones that caused adrenocortical hyperplasia, thus resulting in the manifestations of the syndrome. Today, the term Cushing’s syndrome refers to a complex of symptoms and signs resulting from hypersecretion of cortisol regardless of etiology. In contrast, Cushing’s disease refers to a pituitary tumor, usually an adenoma, which leads to bilateral adrenal hyperplasia and hypercortisolism. Cushing’s syndrome (endogenous) is a rare disease, affecting 10 in 1 mil-lion individuals. It is more common in adults but may occur in children. Women are more commonly affected (male-to-female ratio is 1:8). Although most individuals have sporadic disease, Cushing’s syndrome may be found in MEN1 families and can result from ACTH-secreting pituitary tumors, primary adre-nal neoplasms, or an ectopic ACTH-secreting carcinoid tumor (more common in men) or bronchial adenoma (more common in women).Cushing’s syndrome may be classified as ACTH-dependent or ACTH-independent (Table 38-17). The most common cause of hypercortisolism is exogenous administration of steroids. However, approximately 70% of cases of endogenous Cush-ing’s syndrome are caused by an ACTH-producing pituitary tumor. Primary adrenal sources (adenoma, hyperplasia, and Brunicardi_Ch38_p1625-p1704.indd 168801/03/19 11:22 AM 1689THYROID, PARATHYROID, AND ADRENALCHAPTER 38Table 38-18Features of Cushing’s syndromeSYSTEMMANIFESTATIONGeneralWeight gain—central obesity, buffalo hump, supraclavicular fat padsIntegumentaryHirsutism, plethora, purple striae, acne, ecchymosisCardiovascularHypertensionMusculoskeletalGeneralized weakness, osteopeniaNeuropsychiatricEmotional lability, psychosis, depressionMetabolicDiabetes or glucose intolerance, hyperlipidemiaRenalPolyuria, renal stonesGonadalImpotence, decreased libido, menstrual irregularitiescarcinoma) account for about 20% of cases, and ectopic ACTH-secreting tumors account for <10% of cases. CRH also may be secreted ectopically in bronchial carcinoid tumors, pheochro-mocytomas, and other tumors. These patients are difficult to distinguish from those with ectopic ACTH production, but can be diagnosed by determining CRH levels. Patients with major depression, alcoholism, pregnancy, chronic renal failure, or stress also may have elevated cortisol levels and symptoms of hypercortisolism. However, these manifestations resolve with treatment of the underlying disorder, and these patients are deemed to have pseudo-Cushing’s syndrome.Primary adrenal hyperplasia may be micronodular, mac-ronodular, or massively macronodular. Adrenal hyperplasia resulting from ACTH stimulation usually is macronodular (3-cm nodules). Primary pigmented nodular adrenocortical disease is a rare cause of ACTH-independent Cushing’s syndrome, which is characterized by the presence of small (<5 mm), black adrenal nodules. Primary pigmented nodular adrenocortical disease may be associated with Carney complex (atrial myxomas, schwanno-mas, and pigmented nevi) and is thought to be immune related.Symptoms and Signs The classical features of Cushing’s syn-drome are listed in Table 38-18. Early diagnosis of this disease requires a thorough knowledge of these manifestations, coupled with a high clinical suspicion. In some patients, symptoms are less pronounced and may be more difficult to recognize, par-ticularly given their diversity and the absence of a single defin-ing symptom or sign. Progressive truncal obesity is the most common symptom, occurring in up to 95% of patients. This pattern results from the lipogenic action of excessive corti-costeroids centrally and catabolic effects peripherally, along with peripheral muscle wasting. Fat deposition also occurs in unusual sites, such as the supraclavicular space and posterior neck region, leading to the so-called buffalo hump. Purple striae are often visible on the protuberant abdomen. Rounding of the face leads to moon facies, and thinning of subcutaneous tis-sues leads to plethora. There is an increase in fine hair growth on the face, upper back, and arms, although true virilization is more commonly seen with adrenocortical cancers. Endocrine abnormalities include glucose intolerance, amenorrhea, and decreased libido or impotence. In children, Cushing’s syndrome is characterized by obesity and stunted growth. Patients with Cushing’s disease also may present with headaches, visual field defects, and panhypopituitarism. Hyperpigmentation of the skin, if present, suggests an ectopic ACTH-producing tumor with high levels of circulating ACTH.Diagnostic Tests The aims of diagnostic tests in the evalua-tion of patients suspected of having Cushing’s syndrome are twofold: to confirm the presence of Cushing’s syndrome and to determine its etiology (Fig. 38-44).Laboratory Studies. Cushing’s syndrome is characterized by elevated glucocorticoid levels that are not suppressible by exog-enous hormone administration and loss of diurnal variation. This phenomenon is used to screen patients using the overnight low-dose dexamethasone suppression test. In this test, 1 mg of a synthetic glucocorticoid (dexamethasone) is given at 11 p.m. and plasma cortisol levels are measured at 8 a.m. the following morning. Physiologically normal adults suppress cortisol levels to <3 μg/dL, whereas most patients with Cushing’s syndrome do not. False-negative results may be obtained in patients with mild disease; therefore, some authors consider the test positive only if cortisol levels are suppressed to <1.8 μg/dL. False-positive results can occur in up to 3% of patients with chronic renal fail-ure, depression, or those taking medications such as phenytoin, which enhance dexamethasone metabolism. In patients with a negative test but a high clinical suspicion, the classic low-dose dexamethasone (0.5 mg every 6 hours for eight doses, or 2 mg over 48 hours) suppression test or urinary cortisol measurement should be performed. Measurement of elevated 24-hour urinary cortisol levels is a very sensitive (95–100%) and specific (98%) modality of diagnosing Cushing’s syndrome and is particularly useful for identifying patients with pseudo-Cushing’s syn-drome. A urinary cortisol-free excretion of less than 100 μg/dL (in most laboratories) rules out hypercortisolism. Recently, salivary cortisol measurements using commercially available kits also have demonstrated superior sensitivity in diagnosing Cushing’s syndrome and are being increasingly used. Overall, 24-hour urinary tests for free cortisol and the overnight dexa-methasone suppression test at the 5 μg/dL cutoff have the high-est specificity for the diagnosis of Cushing’s syndrome.103Once a diagnosis of hypercortisolism is established, further testing is aimed at determining whether it is ACTH-dependent or ACTH-independent Cushing’s syndrome. This is best accom-plished by measurement of plasma ACTH levels (normal 10–100 pg/mL). Elevated ACTH levels are found in patients with adrenal hyperplasia due to Cushing’s disease (15–500 pg/mL) and those with CRH-secreting tumors, but the highest levels are found in patients with ectopic sources of ACTH (>1000 pg/mL). In con-trast, ACTH levels are characteristically suppressed (<5 pg/mL) in patients with primary cortisol-secreting adrenal tumors. The high-dose dexamethasone suppression test is used to distinguish between the causes of ACTH-dependent Cushing’s syndrome (pituitary vs. ectopic). The standard test (2 mg dexamethasone every 6 hours for 2 days) or the overnight test (8 mg) may be used, with 24-hour urine collections for cortisol and 17-hydroxy steroids performed over the second day. Failure to suppress urinary cortisol by 50% confirms the diagnosis of an ectopic ACTH-producing tumor. Patients suspected of having ectopic tumors should also undergo testing for MTC and pheochro-mocytoma. Bilateral petrosal vein sampling also is helpful for determining whether the patient has Cushing’s disease or ecto-pic Cushing’s syndrome.Brunicardi_Ch38_p1625-p1704.indd 168901/03/19 11:22 AM 1690SPECIFIC CONSIDERATIONSPART IIThe CRH test also is helpful in determining the etiology of Cushing’s syndrome. Ovine CRH (1 μg/kg) is administered intravenously, followed by serial measurements of ACTH and cortisol at 15-minute intervals for 1 hour. Patients with a primary adrenal hypercortisolism exhibit a blunted response (ACTH peak <10 pg/mL), whereas those with ACTH-dependent Cushing’s syndrome demonstrate a higher elevation of ACTH (>30 pg/mL). CRH stimulation also can enhance the useful-ness of petrosal vein sampling. Patients with pituitary tumors also have a higher peak ACTH than those with ectopic ACTHproducing tumors.Radiologic Studies. CT and MRI scans of the abdomen can identify adrenal tumors with 95% sensitivity. They also are helpful in distinguishing adrenal adenomas from carcinomas, as discussed in the subsequent section “Adrenocortical Cancer.” MRI scans have the added advantage of allowing assessment of vascular anatomy. Adrenal adenomas appear darker than the liver on T2-weighted imaging. Radioscintigraphic imag-ing of the adrenals using NP-59 also can be used to distinguish adenoma from hyperplasia. Reports suggest that “cold” adrenal nodules are more likely to be cancerous, although this distinc-tion is not absolute. NP-59 scanning is most useful in identi-fying patients with an adrenal source of hypercortisolism and primary pigmented micronodular hyperplasia.Thin-section head CT scans are 22% sensitive, and contrast-enhanced brain MRI scans are 33% to 67% sensitive at identifying pituitary tumors. Inferior petrosal sinus sampling for ACTH before and after CRH injection has been helpful in this regard and has a sensitivity approaching 100%. In this study, catheters are placed in both internal jugular veins and a periph-eral vein. A ratio of petrosal to peripheral vein ACTH level of >2 in the basal state and >3 after CRH stimulation is diagnostic 1) Overnight DST2) 24-hour urinary free cortisol3) 11:00 pm salivary cortisol1) Plasma ACTH2) High-dose DST and urinary cortisolConfirm the diagnosisACTH gradient?Determine source of hypercortisolismDecreased ACTHLack of suppressionCT scan adrenalsIncreased ACTHPositive Increased ACTHLack of suppressionEquivocalresultsFurther testingBilateral petrosalvein samplingAdrenalsourcePituitarysourceEctopic ACTHsourceSTEPS IN DIAGNOSISDIAGNOSTIC STUDIESYesNoFigure 38-44. Diagnosis of Cushing’s syndrome. ACTH = adrenocorticotropic hormone; CT = computed tomography; DST = dexamethasone suppression test.Brunicardi_Ch38_p1625-p1704.indd 169001/03/19 11:22 AM 1691THYROID, PARATHYROID, AND ADRENALCHAPTER 38of a pituitary tumor. In patients suspected of having ectopic ACTH production, CT or MRI scans of the chest and anterior mediastinum are performed first, followed by imaging of the neck, abdomen, and pelvis if the initial studies are negative.Treatment Laparoscopic adrenalectomy is the treatment of choice for patients with adrenal adenomas. Open adrenalectomy is reserved for large tumors (≥6 cm) or those suspected to be adrenocortical cancers. Bilateral adrenalectomy is curative for primary adrenal hyperplasia.The treatment of choice in Cushing’s disease is transsphe-noidal excision of the pituitary adenoma, which is successful in 80% of patients. Pituitary irradiation has been used for patients with persistent or recurrent disease after surgery. However, it is associated with a high rate of panhypopituitarism, and some patients develop visual deficits. This has led to increased use of stereotactic radiosurgery, which uses CT guidance to deliver high doses of radiotherapy to the tumor (photon or gamma knife) and also bilateral laparoscopic adrenalectomy. Patients who fail to respond to either treatment are candidates for pharmacologic therapy with adrenal inhibitors (medical adrenalectomy) such as ketoconazole, metyrapone, or aminoglutethimide.Patients with ectopic ACTH production are best managed by treating the primary tumor, including recurrences, if possible. Medical or bilateral laparoscopic adrenalectomy has been used to palliate patients with unresectable disease and those whose ectopic ACTH-secreting tumor cannot be localized.Patients undergoing surgery for a primary adrenal ade-noma secreting glucocorticoids require preoperative and post-operative steroids due to suppression of the contralateral adrenal gland. These patients are also at increased predisposition for infectious and thromboembolic complications, the latter due to a hypercoagulable state resulting from an increase in clotting factors including factor VIII and von Willebrand’s factor com-plex, and by impaired fibrinolysis. Duration of steroid therapy is determined by the ACTH stimulation test. Exogenous ste-roids may be needed for up to 2 years but are needed indefi-nitely in patients who have undergone bilateral adrenalectomy. This latter group of patients also may require mineralocorticoid replacement therapy. Typical replacement doses include hydro-cortisone (10–20 mg every morning and 5–10 mg every eve-ning) and fludrocortisone (0.05–0.1 mg/d every morning).Adrenocortical Cancer. Adrenal carcinomas are rare neo-plasms with a worldwide incidence of two per 1 million. These tumors have a bimodal age distribution, with an increased inci-dence in children and adults in the fourth and fifth decades of life. The majority are sporadic, but adrenocortical carcinomas also occur in association with germline mutations of p53 (Li-Fraumeni syndrome) and MENIN (multiple endocrine neoplasia type 1) genes. Loci on 11p (Beckwith-Wiedemann syndrome), 2p (Carney complex), and 9q also have been implicated. Somatic p53 mutations are present in up to 33% of tumors, and LOH at the p53 locus has been reported in >85% of adreno-cortical carcinomas. In addition, insulin-like growth factor II is overexpressed in 90% of tumors, and approximately 30% harbor somatic activating mutations in the b-catenin gene. Recently identified genes mutated in adrenal cancers include ZNRF3 (an E3 ubiquitin ligase) and others involved in chromatin modeling and several microRNAs. Patterns of mutations may also help better define prognosis in adrenocortical cancers.104Symptoms and Signs Approximately 50% of adrenocorti-cal cancers are nonfunctioning. The remaining secrete cortisol (30%), androgens (20%), estrogens (10%), aldosterone (2%), or multiple hormones (35%). Patients with functioning tumors often present with the rapid onset of Cushing’s syndrome accompanied by virilizing features. Nonfunctioning tumors more commonly present with an enlarging abdominal mass and abdominal or back pain. Rarely, weight loss, anorexia, and nau-sea may be present.Diagnostic Tests Diagnostic evaluation of these patients begins with measurement of serum electrolyte levels to rule out hypokalemia, urinary catecholamines to rule out pheochromo-cytomas, an overnight 1-mg dexamethasone suppression test, and a 24-hour urine collection for cortisol, and 17-ketosteroids to rule out Cushing’s syndrome.CT and MRI scans are useful to image these tumors (Fig. 38-45). The size of the adrenal mass on imaging studies is the single most important criterion to help diagnose malig-nancy. In the series reported by Copeland, 92% of adrenal can-cers were >6 cm in diameter.105 The sensitivity, specificity, and likelihood ratio of tumor size in predicting malignancy (based on Surveillance, Epidemiology, and End Results program data) were reported as 96%, 51%, and 2 for tumors ≥4 cm, and 90%, 78%, and 4.1 for tumors ≥6 cm.106 Other CT imaging charac-teristics suggesting malignancy include tumor heterogeneity, irregular margins, and the presence of hemorrhage and adjacent lymphadenopathy or liver metastases. Moderately bright signal intensity on T2-weighted images (adrenal mass–to–liver ratio 1.2:2.8), significant lesion enhancement, and slow washout after injection of gadolinium contrast also indicate malignancy, as does evidence of local invasion into adjacent structures such as the liver, blood vessels (IVC), and distant metastases. FDG-PET or PET-CT scans may have some utility in distinguishing benign from malignant lesions, as discussed in the section on incidentalomas. Once adrenal cancer is diagnosed, CT scans of the chest and pelvis or FDG-PET or PET-CT scans are per-formed for staging. The tumor-node-metastasis (TNM) staging system for adrenocortical carcinoma is depicted in Table 38-19. Up to 70% of patients present with stage III or IV disease.Pathology Most adrenocortical cancers are large, weigh-ing between 100 and 1000 g. On gross examination, areas of Figure 38-45. Computed tomography scan of the abdomen show-ing a left adrenocortical cancer with synchronous liver metastasis.Brunicardi_Ch38_p1625-p1704.indd 169101/03/19 11:22 AM 1692SPECIFIC CONSIDERATIONSPART IIhemorrhage and necrosis often are evident. Microscopically, cells are hyperchromatic and typically have large nuclei and prominent nucleoli. It is very difficult to distinguish benign adrenal adenomas from carcinomas by histologic examination alone. Capsular or vascular invasion is the most reliable sign of cancer. Weiss and associates studied a combination of nine criteria for their usefulness in distinguishing malignant from benign adrenal tumors: nuclear grade III or IV; mitotic rate greater than 5 per 50 high-power fields; atypical mitoses; clear cells comprising 25% or less of the tumor; a diffuse architecture; microscopic necrosis; and invasion of venous, sinusoidal, and capsular structure. Tumors with four or more of these criteria were likely to metastasize and/or recur.107 Rarely, the diagnosis of malignancy of a completely resected adrenal tumor is often only made in retrospect by the finding of metastatic disease many years later. Molecular markers such as Ki67 (indicating proliferative activity) can also be useful in this regard.Treatment The most important predictor of survival in patients with adrenal cancer is the adequacy of resection. Patients who undergo complete resection have 5-year actuarial survival rates ranging from 32% to 48%, whereas median survival is <1 year in those undergoing incomplete excision. Therefore, adrenocor-tical carcinomas are treated by excision of the tumor en bloc with any contiguously involved lymph nodes or organs such as the diaphragm, kidney, pancreas, liver, or IVC. This is best accomplished by open adrenalectomy via a generous subcostal incision or a thoracoabdominal incision (on the right side). The incisions should permit wide exposure, minimize chances of capsule rupture and tumor spillage, and allow vascular control of the aorta, IVC, and renal vessels, as needed.Mitotane or o,p-DDD or 1,1-dichloro-2-(o-chlorophenyl)-2-(p-chlorophenyl) ethane, which is a derivative of the insec-ticide DDT, has adrenolytic activity and has been used in the adjuvant setting and for the treatment of unresectable or metastatic disease. However, the therapeutic effectiveness is conflicting, and consistent improvement in survival rates is lacking. Moreover, the drug is associated with significant GI and neurologic side effects, particularly at the effective doses of 2 to 6 g/d. Terzolo and associates retrospectively evaluated the use of mitotane in the adjuvant setting and reported signifi-cantly increased recurrence-free survival in the treatment group, even in long-term follow-up.108,109 However, a study of several centers in the United States failed to show similar results.110 The routine use of this medication awaits evaluation in random-ized, controlled trials. Determination of blood mitotane levels is helpful to ascertain whether therapeutic and nontoxic levels are present. Adrenocortical tumors commonly metastasize to the liver, lung, and bone.Surgical debulking is recommended for isolated, recurrent disease and has been demonstrated to prolong survival. Sys-temic chemotherapeutic agents used in this tumor include etopo-side, cisplatin, doxorubicin, and, more recently, paclitaxel, but consistent responses are rare, possibly due to the expression of the multidrug resistance gene (MDR-1) in tumor cells. In vitro data indicate that mitotane may be able to reverse this resistance when combined with various chemotherapeutic agents. Results from the First International Randomized Trial in Advanced or Metastatic Adrenocortical Carcinoma Treatment (FIRM-ACT) showed that patients receiving etoposide, doxorubicin, cispla-tin, and mitotane had better response rates and progression-free survival rates than patients receiving streptozotocin and mitotane.111 There has been recent interest in the use of sura-min, a growth factor inhibitor, as therapy for adrenocortical carcinoma; however, this requires further study, particularly because this drug may be associated with significant neurotoxic-ity. Gossypol, a naturally occurring insecticide (from the cotton plant Gossypium species), also appears to inhibit the growth of adrenocortical cancer cell lines and tumors in vivo. However, poor response rates combined with high death rates in limited clinical studies have reduced enthusiasm for this agent. Adre-nocortical cancers also are relatively insensitive to conventional external-beam radiation therapy. However, this modality is used in the adjuvant setting in patients with incomplete resections and palliation of bony metastases. Ketoconazole, metyrapone, or aminoglutethimide may also be useful in controlling steroid hypersecretion. Targeted molecular therapies such as VEGF/EGF-receptor inhibitors, tyrosine-kinase inhibitors, and IGF-2 inhibitors have had disappointing results in patients with ACC.Sex Steroid Excess. Adrenal adenomas or carcinomas that secrete adrenal androgens lead to virilizing syndromes. Although women with virilizing tumors develop hirsutism, amenorrhea, infertility, and other signs of masculinization, such as increased muscle mass, deepened voice, and temporal bald-ing, men with these tumors are more difficult to diagnose and, hence, usually present with disease in advanced stages. Chil-dren with virilizing tumors have accelerated growth, premature development of facial and pubic hair, acne, genital enlargement, and deepening of their voice. Feminizing adrenal tumors are less common and occur in men in the third to fifth decades of life. These tumors lead to gynecomastia, impotence, and testicular atrophy. Women with these tumors develop irregular menses or dysfunctional uterine bleeding. Vaginal bleeding may occur in postmenopausal women. Girls with these tumors experience precocious puberty with breast enlargement and early menarche.Diagnostic Tests Virilizing tumors produce excessive amounts of the androgen precursor, DHEA, which can be measured Table 38-19TNM Staging for adrenocortical cancerTUMORNODEMETASTASISSTAGET1N0M0IT2N0M0IIT1N1M0IIIT2N1M0IIIT3Any NM0IIIT4Any NM0IIIAny TAny NM1IVPrimary tumor (T): T1, size ≤5 cm without local invasion; T2, size >5 cm without local invasion; T3, any size with local invasion but no involvement of adjacent organs; T4, any size with involvement of adjacent organs.Nodes (N): N0, no involvement of regional nodes; N1, positive regional lymph nodes.Metastasis (M): M0, no known distal metastases: M1, distant metastases present.Used with the permission of the American College of Surgeons. Amin MB, Edge SB, Greene FL, et al. (Eds.) AJCC Cancer Staging Manual, 8th Ed. Springer New York, 2017.Brunicardi_Ch38_p1625-p1704.indd 169201/03/19 11:22 AM 1693THYROID, PARATHYROID, AND ADRENALCHAPTER 38in plasma or urine as 17-ketosteroids. Patients with feminiz-ing tumors also have elevated urinary 17-ketosteroids in addi-tion to increased estrogen levels. Androgen-producing tumors often are associated with production of other hormones such as glucocorticoids.Treatment Virilizing and feminizing tumors are treated by adrenalectomy. Malignancy is difficult to diagnose histologi-cally but is suggested by the presence of local invasion, recur-rence, or distal metastases. Adrenolytic drugs such as mitotane, aminoglutethimide, and ketoconazole may be useful in control-ling symptoms in patients with metastatic disease.Congenital Adrenal Hyperplasia. CAH refers to a group of disorders that result from deficiencies or complete absence of enzymes involved in adrenal steroidogenesis. 21-Hydroxylase (CYP21A2) deficiency is the most common enzymatic defect, accounting for >90% of cases of CAH. This deficiency pre-vents the production of 11-deoxycortisol and 11-DOC from progesterone precursors. Deficiency of glucocorticoids and aldosterone leads to elevated ACTH levels and overproduction of adrenal androgens and corticosteroid precursors such as 17hydroxyprogesterone and Δ4-androstenedione. These com-pounds are converted to testosterone in the peripheral tis-sues, thereby leading to virilization. Complete deficiency of 21-hydroxylase presents at birth with virilization, diarrhea, hypovolemia, hyponatremia, hyperkalemia, and hyperpig-mentation. Partial enzyme deficiency may present at birth or later with virilizing features. These patients are less prone to the salt wasting that characterizes complete enzyme deficiency. 11β-Hydroxylase deficiency is the second most common form of CAH and leads to hypertension (from 11-DOC accumula-tion), virilization, and hyperpigmentation. Other enzyme defi-ciencies include 3β-hydroxydehydrogenase and 17-hydroxylase deficiency. Congenital adrenal lipoid hyperplasia is the most severe form of CAH, which is caused by cholesterol desmolase deficiency. It leads to the disruption of all steroid biosynthetic pathways, thus resulting in a fatal salt-wasting syndrome in phe-notypic female patients.Diagnostic Tests The particular enzyme deficiency can be diagnosed by karyotype analysis and measurement of plasma and urinary steroids. The most common enzyme defi-ciency, absence of 21-hydroxylase, leads to increased plasma 17-hydroxyprogesterone and progesterone levels because these compounds cannot be converted to 11-deoxycortisol and 11-DOC, respectively. 11β-Hydroxylase deficiency is the next most common disorder and results in elevated plasma 11-DOC and 11-deoxycortisol. Urinary 17-hydroxyprogesterone, andro-gens, and 17-ketosteroids also are elevated. The dexamethasone suppression test (2–4 mg divided four times a day for 7 days) can be used to distinguish adrenal hyperplasia from neoplasia. CT, MRI, and iodocholesterol scans generally are used to local-ize the tumors.Treatment Patients with CAH traditionally have been man-aged medically, with cortisol and mineralocorticoid replacement to suppress the hypothalamic-pituitary-adrenal axis. However, the doses of steroids required often are supraphysiologic and lead to iatrogenic hypercortisolism. More recently, bilateral laparoscopic adrenalectomy has been proposed as an alternative treatment for this disease and has been successfully performed in a limited number of patients for various forms of CAH.Disorders of the Adrenal MedullaPheochromocytomas. Pheochromocytomas are rare tumors with prevalence rates ranging from 0.3% to 0.95% in autopsy series and approximately 1.9% in series using biochemical screening. They can occur at any age, with a peak incidence in the fourth and fifth decades of life, and have no gender predilec-tion. Extra-adrenal tumors, also called functional paraganglio-mas, may be found at sites of sympathetic ganglia in the organ of Zuckerkandl, neck, mediastinum, abdomen, and pelvis. Pheo-chromocytomas often are called the 10 percent tumor because 10% are bilateral, 10% are malignant, 10% occur in pediatric patients, 10% are extra-adrenal, and 10% are familial.Pheochromocytomas occur in families with MEN2A and MEN2B in approximately 50% of patients. Both syndromes are inherited in an autosomal dominant fashion and are caused by germline mutations in the RET proto-oncogene. Another syndrome with an increased risk of pheochromocytomas is von Hippel-Lindau (VHL) disease, which also is inherited in an autosomal dominant manner. This syndrome also includes retinal angioma, hemangioblastomas of the central nervous system, renal cysts and carcinomas, pancreatic cysts, and epi-didymal cystadenomas. The incidence of pheochromocytomas in the syndrome is approximately 14%. The gene causing VHL has been mapped to chromosome 3p and is a tumor suppres-sor gene. Pheochromocytomas also are included within the tumor spectrum of neurofibromatosis type 1 (NF1 gene) and other neuroectodermal disorders (Sturge-Weber syndrome and tuberous sclerosis), Carney’s syndrome (gastric epithelioid leio-myosarcoma, pulmonary chondroma, and extra-adrenal para-ganglioma), MEN1 syndrome, and the familial paraganglioma and pheochromocytoma syndrome are caused by mutations in the succinyl dehydrogenase family of genes (SDHB, SDHC, and SDHD), which comprise portions of the mitochondrial complex II.112 More recently, mutations in SDHA and SDH5 have also been identified. Additional susceptibility loci include TMEM127 (involved in the mTORC1-signaling pathway) and MAX (myc-associated factor X).Symptoms and Signs Headache, palpitations, and diaphoresis constitute the “classic triad” of pheochromocytomas. Symp-toms such as anxiety, tremulousness, paresthesias, flushing, chest pain, shortness of breath, abdominal pain, nausea, vomit-ing, and others are nonspecific and may be episodic in nature. Cardiovascular complications such as myocardial infarction and cerebrovascular accidents may ensue. These symptoms can be incited by a range of stimuli including exercise, micturition, and defecation. The most common clinical sign is hyperten-sion. Pheochromocytomas are one of the few curable causes of hypertension and are found in 0.1% to 0.2% of hypertensive patients. Hypertension related to this tumor may be paroxys-mal with intervening normotension, sustained with paroxysms or sustained hypertension alone. Sudden death may occur in patients with undiagnosed tumors who undergo other surgeries or biopsy.Diagnostic Tests Biochemical Studies. Pheochromocytomas are diagnosed by testing 24-hour urine samples for catecholamines and their metab-olites as well as by determining plasma metanephrine levels. Urinary metanephrines are 98% sensitive and also about 98% specific for pheochromocytomas, whereas VMA measure-ments are slightly less sensitive and specific. False-positive VMA tests may result from ingestion of caffeine, raw fruits, Brunicardi_Ch38_p1625-p1704.indd 169301/03/19 11:22 AM 1694SPECIFIC CONSIDERATIONSPART IIBAFigure 38-46. A left-sided pheochromocytoma (arrows) imaged by a computed tomography scan of the abdomen (A) and a metaiodoben-zylguanidine scan viewed posteriorly (B).or medications (α-methyldopa). Fractionated urinary catechol-amines (norepinephrine, epinephrine, and dopamine) also are very sensitive but less specific for pheochromocytomas. Because extraadrenal sites lack phenylethanolamine N-methyltransferase, these tumors secrete norepinephrine, whereas epinephrine is the main hormone secreted from adrenal pheochromocytomas. Many physiologic and pathologic states can alter the levels of plasma catecholamines. Hence, they often are thought to be less accurate than urinary tests. Both epinephrine and norepi-nephrine should be measured, as tumors often secrete one or the other hormone. Sensitivities of 85% and specificities of 95% have been reported using cutoff values of 2000 pg/mL for norepinephrine and 200 pg/mL for epinephrine. Clonidine is an agent that suppresses neurogenically mediated catecholamine excess but not secretion from pheochromocytomas. A normal clonidine suppression test is defined by a decrease of basal cate-cholamine levels to <500 pg/mL within 2 to 3 hours after an oral dose of 0.3 mg of clonidine. Chromogranin A is a monomeric, acidic protein, which is stored in the adrenal medulla and other neuroendocrine tumors and released along with catecholamine hormones. It has been reported to have a sensitivity of 83% and a specificity of 96% and is useful in conjunction with catechol-amine measurement for diagnosing pheochromocytomas. Some studies have shown that plasma metanephrines should be the first-line test to identify pheochromocytomas, as the predictive value of a negative test is very high and normal levels exclude pheochromocytoma in patients with preclinical disease or dopa-mine secreting tumors. Although sensitivities of 96% to 100% have been reported, specificity is lower at 85% to 89% and may be much lower at 77% in elderly patients. Although attractive because of the simplicity of a blood test, measurement of plasma metanephrines is generally reserved for cases for which there is a high index of suspicion.Radiologic Studies. Radiologic studies are useful to localize tumors and to assess the extent of spread once the diagnosis has been made with biochemical tests. CT scans are 85% to 95% sensitive and 70% to 100% specific for pheochromocytomas (Fig. 38-46A). The scans should be performed without con-trast to minimize the risk of precipitating a hypertensive crisis, although some recent studies suggest that intravenous contrast may be used. Images should include the region from the dia-phragm to the aortic bifurcation so as to include the organ of Zuckerkandl. CT scans do not provide functional information and cannot definitively diagnose pheochromocytomas. MRI scans are 95% sensitive and almost 100% specific for pheo-chromocytomas because these tumors have a characteristic appearance on T2-weighted images or after gadolinium. MRI is also the study of choice in pregnant women as there is no risk of radiation exposure. Metaiodobenzylguanidine (MIBG) is taken up and concentrated by vesicles in the adrenal medullar cells because its structure is similar to norepinephrine. Normal adrenal medullary tissue does not take up appreciable MIBG. 131I-radiolabeled MIBG is, therefore, useful for localizing pheo-chromocytomas (Fig. 38-46B), especially those in ectopic posi-tions. This test has a reported sensitivity of 77% to 89% and a specificity ranging from 88% to 100%.Treatment The medical management of pheochromocytomas is aimed chiefly at blood pressure control and volume repletion. Irreversible, long-acting α-blockers such as phenoxybenzamine are started 1 to 3 weeks before surgery at doses of 10 mg twice daily, which may be increased to 300 to 400 mg/d with rehydra-tion. Patients should be warned about orthostatic hypotension. β-Blockers such as propranolol at doses of 10 to 40 mg every 6 to 8 hours often need to be added preoperatively in patients who have persistent tachycardia and arrhythmias. β-Blockers should only be instituted after adequate α-blockade and hydration to avoid the effects of unopposed α stimulation (i.e., hypertensive crisis and congestive heart failure) and are typically initiated 3 to 4 days preoperatively. Patients also should be volume repleted preoperatively to avoid postoperative hypotension, which ensues with the loss of vasoconstriction after tumor removal. Other α-blockers such as prazosin, terazosin, and doxazosin, which are selective α1-adrenergic blockers, have a better side effect profile and are preferable to phenoxybenzamine when long-term Brunicardi_Ch38_p1625-p1704.indd 169401/03/19 11:22 AM 1695THYROID, PARATHYROID, AND ADRENALCHAPTER 38pharmacologic therapy is needed, as in patients with metastatic pheochromocytoma. Nicardipine is the most commonly used calcium channel blocker and inhibits norepinephrine-mediated calcium transport into vascular smooth muscle. When used as the primary mode of treatment, it appears to be just as effec-tive as αand β-blockade preoperatively and for intraoperative hemodynamics.113 In some patients, catecholamine-synthesis inhibitors such as α-methyl-p-l-tyrosine (metyrosine) may need to be added if standard αand β-blockade is poorly tolerated or is ineffective in reaching target blood pressure and when moder-ate intraoperative tumor manipulation is anticipated.Adrenalectomy is the treatment of choice for patients with pheochromocytoma. The chief goal of surgery is to resect the tumor completely with minimal tumor manipulation or rupture of the tumor capsule. Surgery should be performed with both noninvasive and invasive monitors, including an arterial line and central venous lines. In patients with congestive heart failure or underlying coronary artery disease, Swan-Ganz catheters may be necessary. Stress must be avoided during anesthesia induc-tion, and use of inhaled agents like isoflurane and enflurane are preferred because they have minimal cardiac depressant effects. Fentanyl, ketamine, and morphine should be avoided as they can potentially stimulate catecholamine release from the tumor. The common medications used for intraoperative blood pres-sure control include nitroprusside, nitroglycerin, phentolamine, and nicardipine. Intraoperative arrhythmias are best managed by short-acting β-blockers such as esmolol. Adrenalectomy usu-ally was performed via an open anterior approach to facilitate detection of bilateral tumors, extra-adrenal lesions, or metastatic lesions. However, most pheochromocytomas <5 cm in diameter can be safely resected laparoscopically. Postoperatively, these patients are prone to hypotension due to loss of adrenergic stim-ulation and consequent vasodilatation and therefore need large volume resuscitation.Hereditary Pheochromocytomas. Inherited pheochromo-cytomas tend to be multiple and bilateral. Generally, unilat-eral adrenalectomy is recommended in the absence of obvious lesions in the contralateral adrenal gland because of Addison’s disease, requiring lifelong steroid replacement in patients under-going bilateral adrenalectomy. For patients with tumors in both adrenal glands, cortical-sparing subtotal adrenalectomy may preserve adrenocortical function and avoid the morbidity of bilateral total adrenalectomy. Laparoscopic subtotal adrenal-ectomy has been shown to provide short-term clinical results comparable to total adrenalectomy, with reduced surgical morbidity and may be done as a unilateral or bilateral subtotal procedure.114 However, these patients remain at risk for recur-rent pheochromocytoma, which has been reported in 20% of patients with VHL disease a median of 40 months after partial adrenalectomy, and in 33% of MEN2 patients followed for 54 to 88 months after surgery. Autotransplantation of adrenocortical tissue after total adrenalectomy may be another option for these patients. However, the transplanted cortical tissue rarely pro-vides full function, and steroid replacement usually is required.Malignant Pheochromocytomas. Approximately 12% to 29% of pheochromocytomas are malignant, and these tumors are associated with decreased survival. There are no definitive histologic criteria defining malignant pheochromocytomas. In fact, pleomorphism, nuclear atypia, and abundant mitotic fig-ures are seen in benign tumors. Capsular and vascular invasion may be seen in benign lesions as well. Malignancy usually is diagnosed when there is evidence of invasion into surrounding structures or distant metastases. The most common sites for met-astatic disease are bone, liver, regional lymph nodes, lung, and peritoneum, although the brain, pleura, skin, and muscles may also occasionally be involved. Some studies also suggest that older patient age and larger tumors are associated with a higher risk of malignancy. Although risk of malignancy increases with size for all pheochromocytomas, size does not seem to reliably predict malignancy in pheochromocytomas with local disease only.115 Given this difficulty of defining malignancy clinically (in the absence of metastatic disease), a number of other features such as DNA ploidy, tumor size, and necrosis, neuropeptide Y mRNA expression, and serum neuron-specific enolase expres-sion have been studied. Malignant pheochromocytomas are more likely to express p53 and bcl-2 and have activated telom-erase. Recent data suggest that flow cytometry and molecular markers such as expression of Ki-67, tissue inhibitor of metal-loproteinase, and COX-2 also have shown some use in deter-mining malignancy. When pheochromocytomas develop in the MEN syndromes, they rarely are malignant. In contrast, patients with germline SDHB mutations appear to have a higher propen-sity for extra-adrenal and malignant tumors. In general, soft tis-sue lesions are treated with resection if feasible. External-beam radiation can be used for unresectable lesions or symptomatic skeletal metastases. Therapeutic 131I-MIBG irradiation may be useful in patients with diffuse disease showing 123-I-MIBG uptake on a diagnostic scan. Chemotherapy regimens typically use cyclophosphamide, vincristine, and dacarbazine with vari-able response rates. However, molecular targeted therapies such as sunitinib have shown some promising results.The Adrenal IncidentalomaAdrenal lesions discovered during imaging performed for unre-lated reasons are referred to as incidentalomas. This definition excludes tumors discovered on imaging studies performed for evaluating symptoms of hormone hypersecretion or staging patients with known cancer. The incidence of these lesions iden-tified by CT scans ranges from 0.4% to 4.4%.Differential Diagnosis. The differential diagnosis of adre-nal incidentalomas is shown in Table 38-20. Nonfunctional cortical adenomas account for the majority (36–94%) of adre-nal incidentalomas in patients without a history of cancer. In a series of patients from the Mayo Clinic, no nonfunctional Table 38-20Differential diagnosis of adrenal incidentalomaFUNCTIONING LESIONSNONFUNCTIONING LESIONSBenignBenign Aldosteronoma Cortisol-producing  adenoma Sex steroid–producing  adenoma Pheochromocytoma Cortical adenoma Myelolipoma Cyst Ganglioneuroma HemorrhageMalignant Adrenocortical cancer Metastasis Malignant pheochromocytoma Adrenocortical cancerBrunicardi_Ch38_p1625-p1704.indd 169501/03/19 11:22 AM 1696SPECIFIC CONSIDERATIONSPART IIlesion progressed to cause clinical or biochemical abnormali-ties. However, other studies indicate that 5% to 20% of patients with apparently nonfunctioning cortical adenomas have under-lying, subtle abnormalities of glucocorticoid secretion, and a rare benign-appearing incidentaloma is a cancer.By definition, patients with incidentalomas do not have clinically overt Cushing’s syndrome, but subclinical Cushing’s syndrome is estimated to occur in approximately 8% of patients. This disorder is characterized by subtle fea-tures of cortisol excess, such as weight gain, skin atrophy, facial fullness, diabetes, and hypertension, accompanied by loss of normal diurnal variation in cortisol secretion, autonomous cor-tisol secretion, and resistance to suppression by dexamethasone. Total cortisol produced and 24-hour urinary cortisol levels may be normal. Examination of the natural history of subclinical Cushing’s syndrome indicates that, although most patients remain asymptomatic, some do progress to clinically evident Cushing’s syndrome. Furthermore, cases of postoperative adre-nal crisis from unrecognized suppression of the contralateral adrenal have been reported, making preoperative identification of this condition imperative, particularly in the era of early dis-charge following laparoscopic adrenalectomy.The adrenal is a common site of metastases of lung and breast tumors, melanoma, renal cell cancer, and lymphoma. In patients with a history of nonadrenal cancer and a unilat-eral adrenal mass, the incidence of metastatic disease has been reported to range from 32% to 73%. Myelolipomas are benign, biochemically nonfunctioning lesions composed of ele-ments of hematopoietic and mature adipose tissue, which are rare causes of adrenal incidentaloma. Other less commonly encountered lesions include adrenal cysts, ganglioneuromas, and hemorrhage.Diagnostic Investigations. The diagnostic workup of an adrenal incidentaloma is aimed at identifying patients who would benefit from adrenalectomy (i.e., patients with function-ing tumors and tumors at increased risk of being malignant). It is not necessary for asymptomatic patients whose imaging studies are consistent with obvious cysts, hemorrhage, myelolipomas, or diffuse metastatic disease to undergo additional investigations. All other patients should be tested for underlying hormonally active tumors using (a) a low-dose (1 mg) overnight dexametha-sone suppression test to rule out subclinical Cushing’s syndrome and 17-ketosteroids (if sex steroid excess is suspected); (b) a 24-hour urine collection for catecholamines, metanephrines, VMA, or plasma metanephrine to rule out pheochromocytoma; and (c) in hypertensive patients, serum electrolytes, plasma aldosterone, and plasma renin to rule out an aldosteronoma. In patients with a high index of suspicion for subclinical Cushing’s (those with hypertension, obesity, or diabetes), three tests (i.e., dexamethasone suppression test, salivary cortisol, and 24-hour urine free cortisol) may be used. Confirmatory tests can be per-formed based on the results of the initial screening studies.Determination of the malignant potential of an inciden-taloma is more difficult. The risk of malignancy in an adrenal lesion is related to its size. Lesions >6 cm in diameter have an approximate risk of malignancy of about 25%.82 However, this size cutoff is not absolute because adrenal carcinomas also have been reported in lesions <6 cm. Carcinomas account for 2% of lesions <4 cm and 6% of lesions 4.1 to 6 cm in size. This has led to increased use of the imaging characteristics of incidentalomas to predict malignancy. Benign adrenal adenomas tend to be homogeneous, well encapsulated, and have smooth and regular margins. They also tend to be hypoattenuating lesions (<10 Hounsfield units) on CT scanning. In contrast, adrenal cancers tend to be hyperattenuating (>18 Hounsfield units) and inhomo-geneous, have irregular borders, and may show evidence of local invasion or adjacent lymphadenopathy. On MRI T2-weighted imaging, adenomas demonstrate low signal inten-sity when compared to the liver (adrenal mass-to-liver ratio <1.4), whereas carcinomas and metastases have moderate inten-sity (mass-to-liver ratio 1.2:2.8). Pheochromocytomas are extremely bright, with mass-to-liver ratios >3. Unfortunately, the ranges overlap, and signal intensity is not 100% reliable for determining the nature of the lesion. Radionuclide imaging with NP-59 also has been used to distinguish between various adre-nal lesions, with some investigators suggesting that uptake of NP-59 was 100% predictive of a benign lesion (adenoma), whereas absence of imaging was 100% predictive of a nonade-nomatous lesion. However, the technique has not gained wide-spread acceptance because patients need to be given cold iodine 1 week before the study to prevent thyroid uptake, imaging needs to be delayed by 5 to 7 days after administration of the contrast, and false-positive and false-negative results occur. FDG-PET or PET-CT scans may have some utility in distin-guishing potentially malignant from benign lesions in cases of inconclusive CT densitometry. However, caution must be exer-cised for false-positive (some adenomas and pheochromocyto-mas) and false-negative results (small lesions or those with hemorrhage or necrosis).116 FNAB cannot be used to distinguish adrenal adenomas from carcinomas. This being said, FNAB is useful in the setting of a patient with a history of cancer and a solitary adrenal mass. The positive predictive value of FNAB in this situation has been shown to be almost 100%, although false-negative rates of up to 33% have been reported. Biopsies usually are performed under CT guidance, and appropriate testing to rule out pheochromocytomas should be undertaken before the procedure to avoid precipitating a hypertensive crisis.Management. An algorithm for the management of patients with incidentalomas is shown in Fig. 38-47. The AACE and American Association of Endocrine Surgeons (AAES) have published management guidelines for patients with adrenal incidentalomas.117 Patients with functional tumors or obviously malignant lesions should undergo adrenalectomy. The optimal management of patients with subclinical Cushing’s syndrome is controversial, especially due to the paucity of data from high-quality prospective trials. In general, operative intervention is advised in patients with subclinical Cushing’s syndrome with suppressed plasma ACTH levels and elevated urinary cortisol levels because these patients are at high risk for progression to overt Cushing’s syndrome. The adrenal incidentaloma guide-lines also recommend adrenalectomy in patients with worsening hypertension, abnormal glucose tolerance, or osteoporosis.For nonfunctional lesions, the risk of malignancy needs to be balanced with operative morbidity and mortality. The AACE/AAES guidelines recommend that lesions with suspicious fea-tures on imaging studies such as heterogeneity, irregular cap-sule, or adjacent nodes should be treated by adrenalectomy. Nonoperative therapy, with close periodic follow-up, is advised for lesions <4 cm in diameter with benign imaging characteris-tics, whereas adrenalectomy is recommended for lesions ≥4 cm in size due to the increased risk of cancer.1011Brunicardi_Ch38_p1625-p1704.indd 169601/03/19 11:22 AM 1697THYROID, PARATHYROID, AND ADRENALCHAPTER 38Questions1) Low dose DST2) Plasma metanephrines or 24 h urine catecholamines, VMA, metanephrines3) Plasma aldosterone, renin activity, electrolytesAdrenalectomyYesNoPast historyof cancer?YesSolitarymetastasisyesNoConsideradrenalectomySystemic therapySee question 3<4 cm,Benign imaging featuresNoRepeat imaging in 3–6 months, biochemicalevaluation annually˜4 cm, Indeterminate orsuspicious imagingfeaturesAdrenalectomy1Is the tumorfunctioning?2Is the tumormetastatic?3Is it at highrisk of beingmalignant?Figure 38-47. Management algorithm for an adrenal incidentaloma. CT = computed tomography; DST = dexamethasone suppression test; VMA = vanillylmandelic acid.However, several important points must be considered in the management of these patients. First, size criteria for malig-nancy are not definitive and are derived from a selected series of patients. Second, the actual size of adrenal tumors can be underestimated by at least 1 cm by modalities such as CT and MRI scans because tumors are larger in a cephalocaudal axis. Third, the natural history of incidentalomas is variable and depends on the underlying diagnosis, age of the study popula-tion, and the size of the mass. Older patients are more likely to have nonfunctioning adenomas. Existing data in terms of the long-term behavior of these nonfunctional lesions, although limited, indicate that malignant transformation is uncommon. Furthermore, tumors that increase in size by at least 1 cm over a 2-year follow-up period and those with subtle hormonal abnor-malities appear to be more likely to enlarge. Overt hormone overproduction is more likely in tumors >3 cm and those with increased NP-59 uptake. Surgeons are more likely to operate on a 40-year-old patient with a 4-cm lesion, while electing to follow an 80-year-old patient with a similar lesion but multiple concurrent comorbidities. Based on the above considerations, some surgeons use a size threshold for adrenalectomy with a nonfunctioning homogeneous tumor of 3 to 4 cm in young patients with no comorbidities and 5 cm in older patients with significant comorbidity.Lesions that grow during follow-up also are treated by adrenalectomy. Myelolipomas generally do not warrant adrenal-ectomy unless there is concern regarding malignancy, which is rare, or bleeding into the lesion, which is more likely in myelo-lipomas >4 cm in size. These tumors, even when large, can be removed laparoscopically. Resection of solitary adrenal metas-tases in patients with a history of nonadrenal cancer has been demonstrated to lead to prolonged patient survival. Suspected adrenal metastases also may be resected for diagnosis.There is no consensus regarding the follow-up of patients with adrenal incidentaloma. The AACE/AAES guidelines recommend repeating hormonal screening with a 1-mg dexa-methasone suppression test and urinary catecholamines and metabolites yearly for 5 years as the risk of hypersecretion appears to plateau after this time period. It also recommends repeat imaging at 3 to 6 months and then annually for 1 to 2 years. Less frequent imaging is reasonable or small (<2 cm), uniform, hypodense cortical nodules in patients without a his-tory of malignant disease. Adrenalectomy is recommended for lesions that grow ≥1 cm or if autonomous hormone secretion develops during follow-up.Adrenal InsufficiencyAdrenal insufficiency may be primary, resulting from adrenal dis-ease, or secondary, due to a deficiency of ACTH (Table 38-21). The most commonly encountered causes of primary adrenal insufficiency are autoimmune disease, infections, and meta-static deposits. Spontaneous adrenal hemorrhage can occur in patients with fulminant meningococcal septicemia (Water-house-Friderichsen syndrome). Bilateral adrenal hemorrhage also can occur secondary to trauma, severe stress, infection, and coagulopathies and, if unrecognized, is lethal. Exogenous glucocorticoid therapy with suppression of the adrenal glands is the most common cause of secondary adrenal insufficiency.Symptoms and Signs. Acute adrenal insufficiency should be suspected in stressed patients with any of the relevant risk factors. It may mimic sepsis, myocardial infarction, or pulmo-nary embolus and presents with fever, weakness, confusion, nausea, vomiting, lethargy, abdominal pain, or severe hypoten-sion. Chronic adrenal insufficiency, such as that occurring in patients with metastatic tumors, may be more subtle. Symptoms include fatigue, salt craving, weight loss, nausea, vomiting, and Brunicardi_Ch38_p1625-p1704.indd 169701/03/19 11:22 AM 1698SPECIFIC CONSIDERATIONSPART IIabdominal pain. These patients may appear hyperpigmented from increased secretion of CRH and ACTH, with increased α-melanocyte-stimulating hormone side-products.Diagnostic Studies. Characteristic laboratory findings include hyponatremia, hyperkalemia, eosinophilia, mild azote-mia, and fasting or reactive hypoglycemia. The peripheral blood smear may demonstrate eosinophilia in approximately 20% of patients. Adrenal insufficiency is diagnosed by the ACTH stimulation test. ACTH (250 μg) is infused intravenously, and cortisol levels are measured at 0, 30, and 60 minutes. Peak cor-tisol levels <20 μg/dL suggest adrenal insufficiency. ACTH levels also allow primary insufficiency to be distinguished from secondary causes. High ACTH levels with low plasma cortisol levels are diagnostic of primary adrenal insufficiency.Treatment. Treatment must be initiated based on clinical sus-picion alone, even before test results are obtained, or the patient is unlikely to survive. Management includes volume resuscita-tion with at least 2 to 3 L of a 0.9% saline solution or 5% dex-trose in saline solution. Blood should be obtained for electrolyte (decreased Na+ and increased K+), glucose (low), and cortisol (low) levels; ACTH (increased in primary and decreased in sec-ondary); and quantitative eosinophilic count. Dexamethasone (4 mg) should be administered intravenously. Hydrocortisone (100 mg intravenously every 8 hours) also may be used, but it interferes with testing of cortisol levels. Once the patient has been stabilized, underlying conditions such as infection should be sought, identified, and treated. The ACTH stimulation test should be performed to confirm the diagnosis. Glucocorticoids can then be tapered to maintenance doses (oral hydrocortisone 15–20 mg in the morning and 10 mg in the evening). Mineralo-corticoids (fludrocortisone 0.05–0.1 mg daily) may be required once the saline infusions are discontinued.Adrenal SurgeryChoice of Procedure. Adrenalectomy may be performed via a laparoscopic or open approach. In either approach, the gland may be approached anteriorly, laterally, or posteriorly via the retroperitoneum. The choice of approach depends on the size and nature of the lesion and expertise of the surgeon. Laparo-scopic adrenalectomy has rapidly become the standard proce-dure of choice for the excision of most benign-appearing adrenal lesions <6 cm in diameter. The role of laparoscopic adrenalec-tomy in the management of adrenocortical cancers is controver-sial. The data with respect to local tumor recurrence and intra-abdominal carcinomatosis from laparoscopic adrenalec-tomy for malignant adrenal tumors that were not appreciated as such, preoperatively or intraoperatively, are conflicting. Although laparoscopic adrenalectomy appears to be feasible and safe for solitary adrenal metastasis118 (provided there is no local invasion and the tumor can be resected intact), open adrenalec-tomy or laparoscopic-assisted open adrenalectomy is the safest option for suspected or known adrenocortical cancers and malig-nant pheochromocytomas. Technical considerations and surgeon experience, rather than absolute tumor size, usually determine the size threshold for laparoscopic resection. Hand-assisted lapa-roscopic adrenalectomy may provide a bridge between laparo-scopic adrenalectomy and conversion to an open procedure. There have been no randomized trials directly comparing open vs. laparoscopic adrenalectomy. However, studies have shown that laparoscopic adrenalectomy is associated with decreased blood loss, postoperative pain, and narcotic use; reduced length of hospital stay; and faster return to work.Laparoscopic Adrenalectomy. The procedure is performed under general anesthesia. Arterial lines are used routinely, and central lines are necessary for patients in whom massive fluid shifts are anticipated (e.g., those with large, active pheochro-mocytomas). A nasogastric tube and Foley catheter are rec-ommended. Routine preoperative antibiotics are not needed, except in patients with Cushing’s syndrome. The adrenals can be removed laparoscopically via a transabdominal (anterior or lateral) or retroperitoneal (lateral or posterior) approach. The lateral approach is preferred by most laparoscopic surgeons and uses gravity to aid retraction of surrounding organs. Patients, however, need to be repositioned for a bilateral procedure. The anterior transabdominal approach offers the advantage of a con-ventional view of the abdominal cavity and allows a bilateral adrenalectomy to be performed without the necessity of repo-sitioning the patient. The posterior retroperitoneal approach has also been gaining popularity in recent years, particularly in patients with previous anterior abdominal surgery and peri-toneal adhesions. In addition, several centers have successfully utilized robotic approaches for both lateral transabdominal and retroperitoneal laparoscopic adrenal surgery. Single incision laparoscopic adrenalectomy is another option. While these latter approaches are feasible,119 their widespread use awaits analysis of long-term outcomes data and cost analyses. The lateral trans-abdominal approach is widely used and described in detail in the following section.12Table 38-21Etiology of adrenal insufficiencyPRIMARYSECONDARYAutoimmune (autoimmune polyglandular disease types I and II)Exogenous glucocorticoid therapyInfectious—TB, fungi, CMV, HIVBilateral adrenalectomyHemorrhage—spontaneous (Waterhouse-Friderichsen syndrome) and secondary to stress, trauma, infections, coagulopathy, or anticoagulantsPituitary or hypothalamic tumorsMetastasesPituitary hemorrhage (postpartum Sheehan’s syndrome)Infiltrative disorders—amyloidosis, hemochromatosisTrans-sphenoidal resection of pituitary tumorAdrenoleukodystrophy Congenital adrenal hyperplasia Drugs—ketoconazole, metyrapone, aminoglutethimide, mitotane CMV = cytomegalovirus; HIV = human immunodeficiency virus; TB = tuberculosis.Brunicardi_Ch38_p1625-p1704.indd 169801/03/19 11:22 AM 1699THYROID, PARATHYROID, AND ADRENALCHAPTER 38Umbilicus1234Figure 38-48. Positioning of the patient and placement of trocars for a laparoscopic adrenalectomy. Four trocars are placed from the mid-clavicular to the anterior axillary line.Triangular ligamentInferiorvena cavaPancreasSpleenABLiverRight adrenalLeft adrenalFigure 38-49. Technique of laparoscopic adrenalectomy. Expo-sure of the right adrenal is facilitated by division of the triangular ligament (A) and dissection and reflection of the spleen and tail of the pancreas aids in identifying the left adrenal (B).Lateral Transabdominal Approach The patient is placed in the lateral decubitus position, and the operating table is flexed at the waist to open the space between the lower rib cage and the iliac crest (Fig. 38-48). The surgeon and assistant both stand on the same side, facing the front of the patient. Pneumoperi-toneum is created using a Veress needle or insufflation via a Hasson port. In general, four 10-mm trocars are placed between the midclavicular line medially and anterior axillary line later-ally, one to two fingerbreadths below the costal margin (see Fig. 38-48), although additional ports may be placed, if needed. A 30° laparoscope is inserted through the second or midcla-vicular port. Most of the dissection is carried out via the two most lateral ports. However, the instruments and ports may be changed to provide optimum exposure, as needed.For a right adrenalectomy, a fan retractor is inserted through the most medial port to retract the liver. An atrau-matic grasper and an L-hook cautery are inserted via the two lateral ports for the dissection. The right triangular ligament is divided, and the liver is rotated medially (Fig. 38-49A). Rarely, the hepatic flexure of the colon may need mobilization during a right adrenalectomy. The right kidney is identified visually and by palpation with an atraumatic grasper. The adrenal gland is identified on the superomedial aspect of the kidney. Gerota’s fascia is incised with the hook cautery. Dissection of the adrenal is started superomedially and then proceeds inferiorly, dissect-ing around the adrenal in a clockwise manner. The periadrenal tissues are grasped or moved with a blunt grasper to facilitate circumferential dissection. The right adrenal vein is identified at its junction with the IVC, ligated with clips, and divided using endoscopic scissors. Alternatively, a vascular stapler may be used to divide the vein endoscopically. There may be a second adrenal vein on the right. Generally, two clips are left on the vena cava side. Although early identification of the adrenal vein is helpful to facilitate mobilization and prevent injury, it can be dissected whenever it is safe to do so. Early ligation of the adrenal vein makes it easier to mobilize the gland but may make subsequent dissection more difficult due to venous congestion. The arterial branches to the adrenal gland can be electrocoagu-lated if small or clipped and divided.For a left adrenalectomy, the fan retractor is used to retract the spleen. The splenic flexure is mobilized early, and the lat-eral attachments to the spleen and the tail of the pancreas are divided using the electrocautery (Fig. 38-49B). Gravity allows the spleen and the pancreatic tail to fall medially. The remain-der of the dissection proceeds similarly to that described for the right adrenal. In addition to the adrenal vein, the inferior phrenic vein, which joins the left adrenal vein medially, also needs to be Brunicardi_Ch38_p1625-p1704.indd 169901/03/19 11:22 AM 1700SPECIFIC CONSIDERATIONSPART IIABAnterior approachCThoracoabdominal approachPosterior approachFigure 38-50. Incisions for open adrenalectomy. Anterior approach (A), posterior approach (B), and thoracoabdominal approach (C).Anterior Approach The adrenals may be removed via a mid-line incision or bilateral subcostal incision (Fig. 38-50). The for-mer allows adequate infraumbilical exposure for examination of extra-adrenal tumors, whereas the latter provides better superior and lateral exposure. For the right side, the hepatic flexure of the colon is mobilized inferiorly, and the triangular ligament is incised to retract the liver medially and superiorly. A generous Kocher maneuver is used to mobilize the duodenum anteriorly and expose the retroperitoneal fat and the IVC (Fig. 38-51A). Gerota’s fascia is incised, and the gland is freed of surround-ing fibro-fatty tissue and the kidney inferiorly. The lateral and superior surfaces usually are mobilized first. Then, the short, right adrenal vein is dissected, ligated, and divided, taking care not to injure the hepatic veins and IVC. On the left side, the adrenal is located cephalad to the pancreatic tail and just lateral to the aorta. For large tumors, the adrenal is best approached by medial visceral rotation to mobilize the spleen, colon, and pan-creas toward the midline (Fig. 38-51B). An alternative approach is to enter the lesser sac by division of the gastrocolic ligament. The pancreas is mobilized superiorly by incision of its inferior dissected, doubly clipped, and divided. As with the right adrenal vein, the left-sided veins also can be divided with a vascular stapler. Once the dissection is complete, the area of the adrenal bed can be irrigated and suctioned. A drain is rarely necessary. The gland is placed in a nylon specimen bag, which is brought out via one of the ports after morcellation, if necessary.Posterior Retroperitoneal Approach The retroperitoneal approach provides a more direct access to the adrenal gland and avoids abdominal adhesions in patients who have had previous abdominal surgery. Furthermore, bilateral adrenalectomy can be performed without repositioning the patient. Intraoperative ultrasound is helpful for identifying the adrenal, but the dis-section and exposure are more difficult because the working space is limited. This makes vascular control difficult and also renders it unsuitable for large (>5 cm) lesions. This tech-nique is being increasingly used for small adenomas causing hyperaldosteronism.The patient is placed in the prone-jackknife position, and the operating table is flexed at the waist to open the space between the posterior costal margin and the pelvis. Palpation is used to identify the position of the twelfth rib. Percutane-ous ultrasound is performed to determine the outline of the underlying kidney and adrenal. When done laparoscopically, the surgeon stands on the side of the adrenal to be removed, and the assistant stands on the opposite side. A 1.5-cm incision is placed 2 cm inferior and parallel to the twelfth rib, laterally at the level of the inferior pole of the kidney. Gerota’s space is entered under direct vision using a 12-mm direct viewing trocar with a 0° laparoscope through the muscle layers of the posterior abdominal wall. Alternatively, blunt dissection with the surgeon’s finger also can identify the space behind Gerota’s fascia. The trocar is then replaced by a dissecting balloon, which is manually inflated using a hand pump under direct vision through the laparoscope. A 12-mm trocar is then reinserted into this space, and CO2 is insufflated to 12 to 15 mmHg pressure. The 0° laparoscope is replaced by a 45° laparoscope. Two addi-tional 5or 10-mm trocars are placed, one each on either side of the first port. Laparoscopic ultrasound then is used to help locate the adrenal gland and vessels. The adrenal dissection is begun at the superior pole and then proceeds to the lateral and inferior aspect. The medial dissection usually is performed last, and the vessels are identified and divided as described in the earlier “Lateral Transabdominal Approach” section.Open Adrenalectomy. Open adrenalectomy may be per-formed via four approaches, each with specific advantages and disadvantages. The anterior approach allows examination of the abdominal cavity and resection of bilateral tumors via a single incision. The posterior approach avoids the morbidity of a lapa-rotomy incision, especially in patients with cardiopulmonary disease and those prone to wound complications (Cushing’s syndrome) and avoids abdominal adhesions in patients who have undergone previous abdominal surgery. Recovery time is also quicker and hospitalization shorter. However, the retroperi-toneal exposure is difficult, particularly in obese patients, and the small working space makes it unsuitable for tumors >6 cm in diameter. The lateral approach is best for obese patients and for large tumors because it provides a bigger working space. The thoracoabdominal approach is most useful for en bloc resection of large (>10 cm), malignant lesions. However, it is associated with significant morbidity and should be used selectively.Brunicardi_Ch38_p1625-p1704.indd 170001/03/19 11:22 AM 1701THYROID, PARATHYROID, AND ADRENALCHAPTER 38ABRightadrenalSpleenPancreasPancreasColonLeftadrenal v.LeftkidneyFigure 38-51. Technique of open adrenalectomy. Exposure of the right adrenal is facilitated by a Kocher maneuver to mobilize the duodenum and upward retraction of the liver (A). The left adrenal can be exposed by medial visceral rotation of the spleen and pan-creas (B). v. = vein.peritoneal attachments, thus exposing the left kidney and adre-nal. The gland is then mobilized as on the right side.Posterior Approach The patient is placed prone on the operat-ing table, similar to the laparoscopic approach. A hockey stick or curvilinear incision may be used, and extended through the latissimus dorsi and sacrospinous fascia. The twelfth rib gener-ally is excised at its base, and the eleventh rib is retracted supe-riorly to reveal the pleura and the lateral arcuate ligament of the liver on the right side. The pleura also is mobilized cephalad, and the adrenal and kidney are identified. The superior aspect of the gland is dissected first, and the superior vessels are identi-fied and ligated. This prevents superior retraction of the adrenal gland. The remainder of the gland is then dissected and the adre-nal gland and tumor removed. The resulting space generally is filled with perinephric fat and closed in layers. A chest X-ray is obtained postoperatively to rule out a pneumothorax.Lateral Approach The patient is placed in a lateral position with the table flexed, and an incision is made between the elev-enth and twelfth ribs or subcostally. The dissection then is per-formed as indicated previously in “Anterior Approach.”Complications of Adrenal Surgery. Patients with Cushing’s syndrome are more prone to infectious (incisional and intra-abdominal abscess) and thrombotic complications. Creation of pneumoperitoneum may result in injury to various organs from Veress needle and trocar insertion, subcutaneous emphysema, pneumothorax, and hemodynamic compromise. Excessive retraction and dissection may lead to bleeding from injury to the IVC and renal vessels, or from injury to surrounding organs such as the liver, pancreas, spleen, and stomach. Postopera-tive hemodynamic instability may be evident in patients with pheochromocytomas, and patients are at risk of adrenal insuffi-ciency after bilateral adrenalectomy and sometimes after unilat-eral adrenalectomy (unrecognized Cushing’s syndrome or, very rarely, Conn’s syndrome). Long-term morbidity results mainly from injury to nerve roots during trocar insertion, which can lead to chronic pain syndromes or muscle weakness, although this is more of an issue in case of open procedures.Approximately 30% of patients who undergo bilateral adrenalectomy for Cushing’s disease are at risk of developing Nelson’s syndrome from progressive growth of the preexisting pituitary tumor. This leads to increased ACTH levels, hyper-pigmentation, visual field defects, headaches, and extraocular muscle palsies. Transsphenoidal pituitary resection is the ini-tial mode of therapy, and external-beam radiotherapy is used in patients with residual tumor or extrasellar invasion.REFERENCESEntries highlighted in bright blue are key references. 1. Rayess HM, Monk I, Svider PF, Gupta A, Raza SN, Lin HS. Thyroglossal duct cyst carcinoma: a systematic review of clinical features and outcomes. Otolaryngol Head Neck Surg. 2017;156:794-802. 2. Cernea CR, Ferraz AR, Nishio S, Dutra A, Jr, Hojaij FC, dos Santos LR. Surgical anatomy of the external branch of the superior laryngeal nerve. Head Neck. 1992;14:380-383. 3. Pujol-Borrell R, Gimenez-Barcons M, Marin-Sanchez A, Colobran R. Genetics of Graves’ disease: special focus on the role of TSHR gene. Horm Metab Res. 2015;47:753-766. 4. Hagen F, Ouellette RP, Chapman EM. Comparison of high and low dosage levels of I-131 in the treatment of thyrotoxicosis. N Engl J Med. 1967;277(11):559-562. 5. Singer RB. Long-term comparative cancer mortality after use of radio-iodine in the treatment of hyperthyroidism, a fully reported multicenter study. J Insur Med. 2001;33:138-142. 6. Cundiff JG, Portugal L, Sarne DH. Parathyroid adenoma after radioactive iodine therapy for multinodular goiter. Am J Otolaryngol. 2001;22:374-375. 7. Ross DS, Burch HB, Cooper DS, et al. 2016 American Thy-roid Association guidelines for diagnosis and management of hyperthyroidism and other causes of thyrotoxicosis. Thyroid. 2016;26(10):1343-1421. 8. Krohn K, Paschke R. Somatic mutations in thyroid nodular disease. Mol Genet Metab. 2002;75:202-208.Brunicardi_Ch38_p1625-p1704.indd 170101/03/19 11:22 AM 1702SPECIFIC CONSIDERATIONSPART II 9. Jonklaas J, Bianco AC, Bauer AJ, et al. Guidelines for the treatment of hypothyroidism: prepared by the American Thy-roid Association task force on thyroid hormone replacement. Thyroid. 2014;24:1670-1751. 10. Brook I. Microbiology and management of acute suppura-tive thyroiditis in children. Int J Pediatr Otorhinolaryngol. 2003;67:447-451. 11. Sheng Q, Lv Z, Xiao X, et al. Diagnosis and management of pyriform sinus fistula: experience in 48 cases. J Ped Surg. 2014;49:455-459. 12. Moshynska O, Saxena A. Clonal relationship between Hashi-moto’s thyroiditis and thyroid lymphoma. J Clin Pathol. 2008;61(4):438-444. 13. Rodondi N, den Elzen WP, Bauer DC, et al. Subclinical hypo-thyroidism and the risk of coronary heart disease and mortality. JAMA. 2010;304:1365-1374. 14. Pusztaszeri M, Triponez F, Pache JC, Bongiovanni M. Rie-del’s thyroiditis with increased IgG4 plasma cells: evidence for an underlying IgG4-related sclerosing disease? Thyroid. 2012;22:964-968. 15. Soh SB, Pham A, O’Hehir RE, Cherk M, Topliss DJ. Novel use of rituximab in a case of Riedel’s thyroiditis refractory to glucocorticoids and tamoxifen. J Clin Endocrinol Metab. 2013;98:3543-3549. 16. Knudsen N, Laurberg P, Perrild H, Bulow I, Ovesen L, Jorgensen T. Risk factors for goiter and thyroid nodules. Thy-roid. 2002;12:879-888. 17. Ron E. Thyroid cancer incidence among people living in areas contaminated by radiation from the Chernobyl accident. Health Phys. 2007;93:502-511. 18. Peiling Yang S, Ngeow J. Familial non-medullary thyroid cancer: unraveling the genetic maze. Endocr Relat Cancer. 2016;23:R577-R595. 19. Cibas ES, Ali SZ; Conference NCITFSotS. The Bethesda System for reporting thyroid cytopathology. Am J Clin Pathol. 2009;132(5):658-665. 20. Nobrega LH, Paiva FJ, Nobrega ML, et al. Predicting malig-nant involvement in a thyroid nodule: role of ultrasonography. Endocr Pract. 2007;13:219-224. 21. Chen M, Zhang KQ, Xu YF, Zhang SM, Cao Y, Sun WQ. Shear wave elastography and contrast-enhanced ultrasonog-raphy in the diagnosis of thyroid malignant nodules. Mol Clin Oncol. 2016;5:724-730. 22. Penna GC, Vaisman F, Vaisman M, Sobrinho-Simoes M, Soares P. Molecular markers involved in tumorigenesis of thyroid carcinoma: focus on aggressive histotypes. Cytogenet Genome Res. 2016;150:194-207. 23. Caronia LM, Phay JE, Shah MH. Role of BRAF in thyroid oncogenesis. Clin Cancer Res. 2011;17:7511-7517. 24. Zane M, Scavo E, Catalano V, et al. Normal vs cancer thy-roid stem cells: the road to transformation. Oncogene. 2016;35:805-815. 25. Nikiforov YE, Seethala RR, Tallini G, et al. Nomenclature revision for encapsulated follicular variant of papillary thy-roid carcinoma: a paradigm shift to reduce overtreatment of indolent tumors. JAMA Oncol. 2016;2(8):1023-1029. 26. Hay ID, Grant CS, Taylor WF, McConahey WM. Ipsilateral lobectomy versus bilateral lobar resection in papillary thyroid carcinoma: a retrospective analysis of surgical outcome using a novel prognostic scoring system. Surgery. 1987;102:1088-1095. 27. Cady B, Rossi R. An expanded view of risk-group definition in differentiated thyroid carcinoma. Surgery. 1988;104:947-953. 28. DeGroot LJ, Kaplan EL, McCormick M, Straus FH. Natural history, treatment, and course of papillary thyroid carcinoma. J Clin Endocrinol Metab. 1990;71:414-424. 29. AJCC Cancer Staging Manual. 8th ed. New York: Springer-Verlag; 2017. 30. Miyauchi A, Kudo T, Miya A, et al. Prognostic impact of serum thyroglobulin doubling-time under thyrotropin suppres-sion in patients with papillary thyroid carcinoma who under-went total thyroidectomy. Thyroid. 2011;21:707-716. 31. Bhaijee F, Nikiforov YE. Molecular analysis of thyroid tumors. Endocr Pathol. 2011;22:126-133. 32. Cady B, Sedgwick CE, Meissner WA, Wool MS, Salzman FA, Werber J. Risk factor analysis in differentiated thyroid cancer. Cancer. 1979;43:810-820. 33. Lee JH, Lee ES, Kim YS. Clinicopathologic significance of BRAF V600E mutation in papillary carcinomas of the thyroid: a meta-analysis. Cancer. 2007;110:38-46. 34. Mazzaferri EL, Jhiang SM. Long-term impact of initial surgical and medical therapy on papillary and follicular thyroid cancer. Am J Med. 1994;97(5):418-428. 35. Hay ID, Grant CS, Bergstralh EJ, Thompson GB, van Heerden JA, Goellner JR. Unilateral total lobectomy: is it sufficient surgical treatment for patients with AMES low-risk papillary thyroid carcinoma? Surgery. 1998;124:958-964; discussion 64-66. 36. Mazzaferri EL, Massoll N. Management of papillary and follicular (differentiated) thyroid cancer: new paradigms using recombinant human thyrotropin. Endocr Relat Cancer. 2002;9:227-247. 37. Bilimoria KY, Bentrem DJ, Ko CY, et al. Extent of sur-gery affects survival for papillary thyroid cancer. Ann Surg. 2007;246:375-381; discussion 81-84. 38. Cooper DS, Doherty GM, Haugen BR, et al. Management guidelines for patients with thyroid nodules and differentiated thyroid cancer. Thyroid. 2006;16:109-142. 39. Adam MA, Pura J, Gu L, et al. Extent of surgery for papil-lary thyroid cancer is not associated with survival: an analysis of 61,775 patients. Ann Surg. 2014;260:601-605; discussion 605-607. 40. Haugen BR, Alexander EK, Bible KC, et al. 2015 Ameri-can Thyroid Association Management guidelines for adult patients with thyroid nodules and differentiated thyroid cancer: the American Thyroid Association guidelines task force on thyroid nodules and differentiated thyroid cancer. Thyroid. 2016;26(1):1-133. 41. Ito Y, Miyauchi A, Oda H. Low-risk papillary microcarci-noma of the thyroid: a review of active surveillance trials. Eur J Surg Oncol. 2018;44(3):307-315. 42. Agrawal N, Evasovich MR, Kandil E, et al. Indications and extent of central neck dissection for papillary thyroid cancer: an American Head and Neck Society consensus statement. Head Neck. 2017;39:1269-1279. 43. Nikiforov YE, Ohori NP, Hodak SP, et al. Impact of muta-tional testing on the diagnosis and management of patients with cytologically indeterminate thyroid nodules: a prospec-tive analysis of 1056 FNA samples. J Clin Endocrinol Metab. 2011;96:3390-3397. 44. Alexander EK, Kennedy GC, Baloch ZW, et al. Preoperative diagnosis of benign thyroid nodules with indeterminate cytol-ogy. N Engl J Med. 2012;367:705-715. 45. Nikiforov YE, Carty SE, Chiosea SI, et al. Highly accu-rate diagnosis of cancer in thyroid nodules with follicular neoplasm/suspicious for a follicular neoplasm cytology by ThyroSeq v2 next-generation sequencing assay. Cancer. 2014;120:3627-3634. 46. Weber F, Teresi RE, Broelsch CE, Frilling A, Eng C. A limited set of human MicroRNA is deregulated in follicular thyroid carcinoma. J Clin Endocrinol Metab. 2006;91:3584-3591. 47. Wylie D, Beaudenon-Huibregtse S, Haynes BC, Giordano TJ, Labourier E. Molecular classification of thyroid lesions by combined testing for miRNA gene expression and somatic gene alterations. J Pathol Clin Res. 2016;2:93-103.Brunicardi_Ch38_p1625-p1704.indd 170201/03/19 11:22 AM 1703THYROID, PARATHYROID, AND ADRENALCHAPTER 38 48. Benjamin H, Schnitzer-Perlman T, Shtabsky A, et al. Ana-lytical validity of a microRNA-based assay for diagnosing indeterminate thyroid FNA smears from routinely prepared cytology slides. Cancer Cytopathol. 2016;124:711-721. 49. Leboeuf R, Perron P, Carpentier AC, Verreault J, Langlois MF. L-T3 preparation for whole-body scintigraphy: a randomized-controlled trial. Clin Endocrinol (Oxf). 2007;67:839-844. 50. Lee J, Yun MJ, Nam KH, Chung WY, Soh EY, Park CS. Quality of life and effectiveness comparisons of thyroxine withdrawal, triiodothyronine withdrawal, and recombinant thyroid-stimulating hormone administration for low-dose radioiodine remnant ablation of differentiated thyroid carci-noma. Thyroid. 2010;20:173-179. 51. Iyer NG, Morris LG, Tuttle RM, Shaha AR, Ganly I. Rising incidence of second cancers in patients with low-risk (T1N0) thyroid cancer who receive radioactive iodine therapy. Cancer. 2011;117:4439-4446. 52. Snozek CL, Chambers EP, Reading CC, et al. Serum thyro-globulin, high-resolution ultrasound, and lymph node thyro-globulin in diagnosis of differentiated thyroid carcinoma nodal metastases. J Clin Endocrinol Metab. 2007;92:4278-4281. 53. Wertenbroek MW, Links TP, Prins TR, Plukker JT, van der Jagt EJ, de Jong KP. Radiofrequency ablation of hepatic metastases from thyroid carcinoma. Thyroid. 2008;18:1105-1110. 54. Cazzato RL, Bonichon F, Buy X, et al. Over ten years of sin-gle-institution experience in percutaneous image-guided treat-ment of bone metastases from differentiated thyroid cancer. Eur J Surg Oncol. 2015;41:1247-1255. 55. Brose MS, Nutting CM, Jarzab B, et al. Sorafenib in radioac-tive iodine-refractory, locally advanced or metastatic differ-entiated thyroid cancer: a randomised, double-blind, phase 3 trial. Lancet. 2014;384:319-328. 56. Schlumberger M, Tahara M, Wirth LJ, et al. Lenvatinib ver-sus placebo in radioiodine-refractory thyroid cancer. N Engl J Med. 2015;372:621-630. 57. Leboulleux S, Bastholt L, Krause T, et al. Vandetanib in locally advanced or metastatic differentiated thyroid cancer: a randomised, double-blind, phase 2 trial. Lancet Oncol. 2012;13:897-905. 58. Falchook GS, Millward M, Hong D, et al. BRAF inhibitor dabrafenib in patients with metastatic BRAF-mutant thyroid cancer. Thyroid. 2015;25:71-77. 59. Wells SA, Jr, Asa SL, Dralle H, et al. Revised American Thy-roid Association guidelines for the management of medullary thyroid carcinoma. Thyroid. 2015;25:567-610. 60. Thornton K, Kim G, Maher VE, et al. Vandetanib for the treat-ment of symptomatic or progressive medullary thyroid cancer in patients with unresectable locally advanced or metastatic disease: U.S. Food and Drug Administration drug approval summary. Clin Cancer Res. 2012;18:3722-3730. 61. Elisei R, Schlumberger MJ, Muller SP, et al. Cabozan-tinib in progressive medullary thyroid cancer. J Clin Oncol. 2013;31:3639-3646. 62. Smallridge RC, Ain KB, Asa SL, et al. American Thyroid Association guidelines for management of patients with anaplastic thyroid cancer. Thyroid. 2012;22(11):1104-1139. 63. Zaidi N, Bucak E, Yazici P, et al. The feasibility of indocyanine green fluorescence imaging for identifying and assessing the perfusion of parathyroid glands during total thyroidectomy. J Surg Oncol. 2016;113:775-778. 64. McWade MA, Paras C, White LM, et al. Label-free intraop-erative parathyroid localization with near-infrared autofluores-cence imaging. J Clin Endocrinol Metab. 2014;99:4574-4580. 65. Barczynski M, Konturek A, Cichon S. Randomized clini-cal trial of visualization versus neuromonitoring of recur-rent laryngeal nerves during thyroidectomy. Br J Surg. 2009;96:240-246. 66. Clark JH, Kim HY, Richmon JD. Transoral robotic thyroid surgery. Gland Surg. 2015;4:429-434. 67. Akerstrom G, Malmaeus J, Bergstrom R. Surgical anatomy of human parathyroid glands. Surgery. 1984;95:14-21. 68. Gilmour J. The gross anatomy of the parathyroid glands. J Pathol. 1938;46:133. 69. Ward BK, Magno AL, Walsh JP, Ratajczak T. The role of the calcium-sensing receptor in human disease. Clin Biochem. 2012;45:943-953. 70. Balogh K, Racz K, Patocs A, Hunyady L. Menin and its inter-acting proteins: elucidation of menin function. Trends Endo-crinol Metab. 2006;17:357-364. 71. Duan K, Gomez Hernandez K, Mete O. Clinicopatho-logical correlates of hyperparathyroidism. J Clin Pathol. 2015;68:771-787. 72. Pardi E, Mariotti S, Pellegata NS, et al. Functional character-ization of a CDKN1B mutation in a Sardinian kindred with multiple endocrine neoplasia type 4 (MEN4). Endocr Con-nect. 2015;4:1-8. 73. Segiet OA, Deska M, Michalski M, Gawrychowski J, Wojnicz R. Molecular profiling in primary hyperparathyroidism. Head Neck. 2015;37:299-307. 74. Proceedings of the NIH Consensus Development Confer-ence on diagnosis and management of asymptomatic primary hyperparathyroidism. Bethesda, Maryland, October 29-31, 1990. J Bone Miner Res. 1991;6(suppl 2):S1-S166. 75. Silverberg SJ, Shane E, Jacobs TP, Siris E, Bilezikian JP. A 10-year prospective study of primary hyperparathyroid-ism with or without parathyroid surgery. N Engl J Med. 1999;341:1249-1255. 76. Bilezikian JP, Khan AA, Potts JT, Jr. Third International Workshop on the Management of Asymptomatic Primary H. Guidelines for the management of asymptomatic pri-mary hyperparathyroidism: summary statement from the third international workshop. J Clin Endocrinol Metab. 2009;94:335-339. 77. Rubin MR, Bilezikian JP, McMahon DJ, et al. The natu-ral history of primary hyperparathyroidism with or without parathyroid surgery after 15 years. J Clin Endocrinol Metab. 2008;93:3462-3470. 78. Marcocci C, Bollerslev J, Khan AA, Shoback DM. Medical management of primary hyperparathyroidism: proceedings of the fourth International Workshop on the Management of Asymptomatic Primary Hyperparathyroidism. J Clin Endocri-nol Metab. 2014;99:3607-3618. 79. Pasieka JL, Parsons L, Jones J. The long-term benefit of parathyroidectomy in primary hyperparathyroidism: a 10-year prospective surgical outcome study. Surgery. 2009;146:1006-1013. 80. Zanocco K, Angelos P, Sturgeon C. Cost-effectiveness analy-sis of parathyroidectomy for asymptomatic primary hyper-parathyroidism. Surgery. 2006;140:874-881; discussion 81-82. 81. Udelsman R, Akerstrom G, Biagini C, et al. The surgical management of asymptomatic primary hyperparathyroidism: proceedings of the Fourth International Workshop. J Clin Endocrinol Metab. 2014;99:3595-3606. 82. Bilezikian JP, Brandi ML, Eastell R, et al. Guidelines for the management of asymptomatic primary hyperparathy-roidism: summary statement from the Fourth International Workshop. J Clin Endocrinol Metab. 2014;99(10):3561-3569. 83. Rodgers SE, Hunter GJ, Hamberg LM, et al. Improved pre-operative planning for directed parathyroidectomy with 4-dimensional computed tomography. Surgery. 2006;140:932-940; discussion 40-41. 84. Sharma J, Milas M, Berber E, Mazzaglia P, Siperstein A, Weber CJ. Value of intraoperative parathyroid hormone moni-toring. Ann Surg Oncol. 2008;15(2):493-498.Brunicardi_Ch38_p1625-p1704.indd 170301/03/19 11:22 AM 1704SPECIFIC CONSIDERATIONSPART II 85. Westerdahl J, Bergenfelz A. Unilateral versus bilateral neck exploration for primary hyperparathyroidism: five-year follow-up of a randomized controlled trial. Ann Surg. 2007;246:976-981. 86. Gagner M. Endoscopic subtotal parathyroidectomy in patients with primary hyperparathyroidism. Br J Surg. 1996;83:875. 87. Lowe H, McMahon DJ, Rubin MR, Bilezikian JP, Silver-berg SJ. Normocalcemic primary hyperparathyroidism: further characterization of a new clinical phenotype. J Clin Endocrinol Metab. 2007;92(8):3001-3005. 88. Eastell R, Brandi ML, Costa AG, D’Amour P, Shoback DM, Thakker RV. Diagnosis of asymptomatic primary hyperpara-thyroidism: proceedings of the Fourth International Workshop. J Clin Endocrinol Metab. 2014;99:3570-3579. 89. Cetani F, Pardi E, Marcocci C. Update on parathyroid carci-noma. J Endocrinol Invest. 2016;39:595-606. 90. Silverberg SJ, Rubin MR, Faiman C, et al. Cinacalcet hydro-chloride reduces the serum calcium concentration in inop-erable parathyroid carcinoma. J Clin Endocrinol Metab. 2007;92:3803-3808. 91. Iacobone M, Citton M, Viel G, Schiavone D, Torresan F. Surgi-cal approaches in hereditary endocrine tumors. Updates Surg. 2017;69:181-191. 92. Twigt BA, van Dalen T, Vroonhoven TJ, Consten EC. Recur-rent hyperparathyroidism caused by benign neoplastic seeding: two cases of parathyromatosis and a review of the literature. Acta Chir Belg. 2013;113:228-232. 93. Guerin C, Paladino NC, Lowery A, Castinetti F, Taieb D, Sebag F. Persistent and recurrent hyperparathyroidism. Updates Surg. 2017;69:161-169. 94. Madorin C, Owen RP, Fraser WD, et al. The surgical manage-ment of renal hyperparathyroidism. Eur Arch Otorhinolaryn-gol. 2012;269:1565-1576. 95. Qiu NC, Zha SL, Liu ME, et al. To assess the effects of para-thyroidectomy (TPTX versus TPTX+AT) for secondary hyper-parathyroidism in chronic renal failure: a meta-analysis. Int J Surg. 2017;44:353-362. 96. Dulfer RR, Franssen GJH, Hesselink DA, Hoorn EJ, van Eijck CHJ, van Ginhoven TM. Systematic review of surgical and medical treatment for tertiary hyperparathyroidism. Br J Surg. 2017;104:804-813. 97. Dutta RK, Soderkvist P, Gimm O. Genetics of primary hyper-aldosteronism. Endocr Relat Cancer. 2016;23:R437-R454. 98. Galati SJ. Primary aldosteronism: challenges in diagno-sis and management. Endocrinol Metab Clin North Am. 2015;44:355-369. 99. Rossi GP, Auchus RJ, Brown M, et al. An expert consensus statement on use of adrenal vein sampling for the subtyping of primary aldosteronism. Hypertension. 2014;63:151-160. 100. Funder JW, Carey RM, Mantero F, et al. The management of primary aldosteronism: case detection, diagnosis, and treatment: an Endocrine Society clinical practice guideline. J Clin Endocrinol Metab. 2016;101:1889-1916. 101. Powlson AS, Gurnell M, Brown MJ. Nuclear imaging in the diagnosis of primary aldosteronism. Curr Opin Endocrinol Diabetes Obes. 2015;22:150-156. 102. Tahir A, McLaughlin K, Kline G. Severe hyperkalemia fol-lowing adrenalectomy for aldosteronoma: prediction, patho-genesis and approach to clinical management—a case series. BMC Endocr Disord. 2016;16:43. 103. Pecori Giraldi F, Ambrogio AG, De Martin M, Fatti LM, Scacchi M, Cavagnini F. Specificity of first-line tests for the diagnosis of Cushing’s syndrome: assessment in a large series. J Clin Endocrinol Metab. 2007;92:4123-4129. 104. Faillot S, Assie G. Endocrine tumours: the genomics of adre-nocortical tumors. Eur J Endocrinol. 2016;174:R249-R265. 105. Copeland PM. The incidentally discovered adrenal mass. Ann Surg. 1984;199:116-122. 106. Sturgeon C, Shen WT, Clark OH, Duh QY, Kebebew E. Risk assessment in 457 adrenal cortical carcinomas: how much does tumor size predict the likelihood of malignancy? J Am Coll Surg. 2006;202:423-430. 107. Aubert S, Wacrenier A, Leroy X, et al. Weiss system revisited: a clinicopathologic and immunohistochemical study of 49 adrenocortical tumors. Am J Surg Pathol. 2002;26:1612-1619. 108. Terzolo M, Angeli A, Fassnacht M, et al. Adjuvant mito-tane treatment for adrenocortical carcinoma. N Engl J Med. 2007;356:2372-2380. 109. Berruti A, Grisanti S, Pulzer A, et al. Long-term outcomes of adjuvant mitotane therapy in patients with radically resected adrenocortical carcinoma. J Clin Endocrinol Metab. 2017;102:1358-1365. 110. Postlewait LM, Ethun CG, Tran TB, et al. Outcomes of adju-vant mitotane after resection of adrenocortical carcinoma: a 13-institution study by the US Adrenocortical Carcinoma Group. J Am Coll Surg. 2016;222:480-490. 111. Fassnacht M, Terzolo M, Allolio B, et al. Combination chemo-therapy in advanced adrenocortical carcinoma. N Engl J Med. 2012;366:2189-2197. 112. Rednam SP, Erez A, Druker H, et al. Von Hippel-Lindau and hereditary pheochromocytoma/paraganglioma syndromes: clinical features, genetics, and surveillance recommendations in childhood. Clin Cancer Res. 2017;23:e68-e75. 113. Brunaud L, Boutami M, Nguyen-Thi PL, et al. Both preopera-tive alpha and calcium channel blockade impact intraoperative hemodynamic stability similarly in the management of pheo-chromocytoma. Surgery. 2014;156:1410-1417; discussion7-8. 114. Scholten A, Valk GD, Ulfman D, Borel Rinkes IH, Vriens MR. Unilateral subtotal adrenalectomy for pheochromocytoma in multiple endocrine neoplasia type 2 patients: a feasible surgi-cal strategy. Ann Surg. 2011;254:1022-1027. 115. Shen WT, Sturgeon C, Clark OH, Duh QY, Kebebew E. Should pheochromocytoma size influence surgical approach? A com-parison of 90 malignant and 60 benign pheochromocytomas. Surgery. 2004;136:1129-1137. 116. McDermott S, O’Connor OJ, Cronin CG, Blake MA. Radio-logical evaluation of adrenal incidentalomas: current methods and future prospects. Best Pract Res Clin Endocrinol Metab. 2012;26:21-33. 117. Zeiger MA, Thompson GB, Duh QY, et al. The American Association of Clinical Endocrinologists and American Association of Endocrine Surgeons medical guidelines for the management of adrenal incidentalomas. Endocr Pract. 2009;15(suppl 1):1-20. 118. Glenn JA, Kiernan CM, Yen TW, et al. Management of sus-pected adrenal metastases at 2 academic medical centers. Am J Surg. 2016;211:664-670. 119. Economopoulos KP, Mylonas KS, Stamou AA, et al. Laparo-scopic versus robotic adrenalectomy: a comprehensive meta-analysis. Int J Surg. 2017;38:95-104.Brunicardi_Ch38_p1625-p1704.indd 170401/03/19 11:22 AM
INTRODUCTIONIn his 1953 classic textbook entitled The Surgery of Infancy and Childhood, Dr. Robert E. Gross summarized the essential challenge of pediatric surgery: “Those who daily operate upon adults, even with the greatest of skill, are sometimes appalled—or certainly are not at their best —when called upon to operate upon and care for a tiny patient. Something more than diminu-tive instruments or scaled-down operative manipulations are necessary to do the job in a suitable manner.” To this day, surgi-cal residents and other trainees often approach the pediatric sur-gical patient with the same mix of fear, trepidation, and anxiety. These same trainees often complete their pediatric surgical rotations with a profound respect for the resilience of young children to undergo complex operations and an appreciation for the precision required from their caregivers, both in the operat-ing room and during the perioperative period. Over the decades, the specialty of pediatric surgery has evolved considerably in its care for the smallest of surgical patients, such that in utero sur-gery is now an option in an increasing number of circumstances. Similarly, our understanding of the pathophysiology of the dis-eases that pediatric surgeons face has increased to the point that some pediatric surgical diseases are now understood at the level of molecular or cellular signaling pathways. Pediatric surgery provides the opportunity to intervene in a wide array of diseases and to exert a long-lasting impact on the lives of children and their grateful parents. The scope of diseases encountered in the standard practice of pediatric surgery is immense, with patients Pediatric SurgeryDavid J. Hackam, Jeffrey Upperman, Tracy Grikscheit, Kasper Wang, and Henri R. Ford 39chapterIntroduction1705Pediatric Surgical Themes: Pitfalls and Pearls1706General Considerations1707Fluid and Electrolyte Balance / 1707Acid-Base Equilibrium / 1707Blood Volume and Blood Replacement / 1707Parenteral Alimentation and Nutrition / 1708Venous Access / 1709Thermoregulation / 1709Pain Control / 1710Neck Masses1710Lymphadenopathy / 1710Thyroglossal Duct Remnants / 1710Branchial Cleft Anomalies / 1711Lymphatic Malformation / 1711Torticollis / 1712Respiratory System1712Congenital Diaphragmatic Hernia (Bochdalek) / 1712Congenital Lobar Emphysema / 1714Bronchopulmonary Foregut Malformations / 1715Bronchiectasis / 1716Foreign Bodies / 1716Esophagus1717Esophageal Atresia and Tracheoesophageal Fistula / 1717Corrosive Injury of the Esophagus / 1721Gastroesophageal Reflux / 1721Gastrointestinal Tract1722An Approach to the Vomiting Infant / 1722Hypertrophic Pyloric Stenosis / 1722Intestinal Obstruction in the Newborn / 1723Duodenal Obstruction / 1724Intestinal Atresia / 1724Malrotation and Midgut Volvulus / 1725Meconium Ileus / 1726Necrotizing Enterocolitis / 1727Short Bowel Syndrome / 1730Intussusception / 1731Appendicitis / 1731Intestinal Duplications / 1733Meckel’s Diverticulum / 1733Mesenteric Cysts / 1733Hirschsprung’s Disease / 1734Anorectal Malformations / 1735Jaundice1737The Approach to the Jaundiced Infant / 1737Biliary Atresia / 1737Choledochal Cyst / 1739Deformities of the Abdominal Wall1740Embryology of the Abdominal Wall / 1740Umbilical Hernia / 1740Patent Urachus / 1740Omphalocele / 1740Gastroschisis / 1741Prune-Belly Syndrome / 1743Inguinal Hernia / 1743Genitalia1744Undescended testis / 1744Vaginal Anomalies / 1745Ovarian Cysts and Tumors / 1745Ambiguous Genitalia / 1746Pediatric Malignancy1747Wilms’ Tumor / 1747Neuroblastoma / 1748Rhabdomyosarcoma / 1749Teratoma / 1750Liver Tumors / 1751Trauma in Children1751Mechanisms of Injury / 1751Initial Management / 1752Evaluation of Injury / 1752Injuries to the Central Nervous System / 1752Thoracic Injuries / 1752Abdominal Injuries / 1752Fetal Intervention1753Fetal Surgery for Lower Urinary Tract Obstruction / 1754Fetal Surgery for Myelomeningocele / 1754The EXIT Procedure / 1754Brunicardi_Ch39_p1705-p1758.indd 170512/02/19 11:26 AM 1706Key Points1 In infants with Bochdalek-type congenital diaphragmatic hernia, the severity of pulmonary hypoplasia and the resul-tant pulmonary hypertension are key determinants of sur-vival. Barotrauma and hypoxia should be avoided.2 During initial management of an infant with esophageal atresia and distal tracheoesophageal fistula, every effort should be made to avoid distending the gastrointestinal tract, especially when using mechanical ventilation. The patient should be evaluated for components of the VAC-TERRL (vertebral, anorectal, cardiac, tracheoesophageal, renal, radial limb) anomalies. Timing and extent of surgery are dictated by the stability of the patient.3 Although malrotation with midgut volvulus occurs most commonly within the first few weeks of life, it should always be considered in the differential diagnosis in a child with bilious emesis. Volvulus is a surgical emergency; therefore, in a critically ill child, prompt surgical interven-tion should not be delayed for any reason.4 When evaluating a newborn infant for vomiting, it is criti-cal to distinguish between proximal and distal causes of intestinal obstruction using both prenatal and postnatal history, physical examination, and abdominal radiographs.5 Risk factors for necrotizing enterocolitis (NEC) include prematurity, formula feeding, bacterial infection, and intestinal ischemia. Critical to the management of infants with advanced (Bell stage III) or perforated NEC is timely and adequate source control of peritoneal contamination. Early sequelae of NEC include perforation, sepsis, and death. Later sequelae include short bowel syndrome and stricture.6 In patients with intestinal obstruction secondary to Hirschsprung’s disease, a leveling ostomy or endorectal pull-through should be performed using ganglionated bowel, proximal to the transition zone between ganglionic and aganglionic intestine.7 Prognosis of infants with biliary atresia is directly related to age at diagnosis and timing of portoenterostomy. Infants with advanced age at the time of diagnosis or infants who fail to demonstrate evidence of bile drainage after porto-enterostomy usually require liver transplantation.8 Infants with omphaloceles have greater associated morbid-ity and mortality than infants with gastroschisis due to a higher incidence of congenital anomalies and pulmonary hypoplasia. Gastroschisis can be associated with intestinal atresia, but not with other congenital anomalies. An intact omphalocele can be repaired electively, whereas gastros-chisis requires urgent intervention to protect the exposed intestine.9 Prognosis for children with Wilms’ tumor is defined by the stage of disease at the time of diagnosis and the histo-logic type (favorable vs. unfavorable). Preoperative che-motherapy is indicated for bilateral involvement, a solitary kidney, or tumor in the inferior vena cava above the hepatic veins. Gross tumor rupture during surgery auto-matically changes the stage to 3 (at a minimum).10 Injury is the leading cause of death in children older than 1 year of age. Blunt mechanisms account for the majority of pediatric injuries. The central nervous system is the most commonly injured organ system and the leading cause of death in injured children.ranging in age from the fetus to 18 years old, and it includes pathologies in the head and neck, thoracic, gastrointestinal, and genitourinary regions. This chapter is not designed to cover the entire spectrum of diseases a pediatric surgeon is expected to master; rather, it presents a synopsis of the most commonly encountered pediatric surgical conditions that a practicing gen-eral surgeon is likely to treat over the course of her or his career.PEDIATRIC SURGICAL THEMES: PITFALLS AND PEARLSThis chapter focuses on the unique considerations regarding the diagnosis and management of surgical diseases in the pediatric population. Many surgical trainees approach the surgical care of children with some degree of fear and trepidation. As any pediatric caregiver will attest to, the surgical management of infants and children requires delicate, careful, and professional interactions with their parents. The stress that the parents of sick children experience in the hospital setting can, at times, be over-whelming. It is due, in part, to the uncertainty regarding a par-ticular prognosis, the feeling of helplessness that evolves when one is unable to care for one’s own child, and in certain cases, the guilt or remorse that one feels for not seeking medical care earlier, or for consenting to a particular procedure. Management of the sick child and his or her family requires not only a cer-tain set of skills but also a unique knowledge base. This section is included to summarize some important general principles in accomplishing this task.1. Children are not little adults, but they are little people. In practical terms, this often-heard refrain implies that children have unique fluid, electrolyte, and medication needs. Thus, the dosage of medications and the administration of IV fluids should at all times be based on their weight. The corollary of this point is that infants and young children are extremely sensitive to perturbations in their normal physiology and may be easily tipped into fluid overload or dehydration.2. Sick children whisper before they shout. Children with surgi-cal diseases can deteriorate very quickly. But before they dete-riorate, they often manifest subtle physical findings. These findings—referred to as “whispers”—may include signs such as tachycardia, bradycardia, hypothermia, fever, recurrent emesis, or feeding intolerance. Meticulous attention to these subtle findings may unmask the development of potentially serious, life-threatening physiological disturbances.3. Always listen to the mother and the father. Surgical diseases in children can be very difficult to diagnose because children are often minimally communicative, and information that they communicate may be confusing, conflicting, or both. In all cases, it is wise to listen to the child’s parents, who have closely observed their child and know him or her best. Most importantly, the child’s parents know with certainty Brunicardi_Ch39_p1705-p1758.indd 170612/02/19 11:26 AM 1707PEDIATRIC SURGERYCHAPTER 39whether or not the child is sick or not, despite not always knowing the precise diagnosis.4. Pediatric tissue must be handled delicately and with pro-found respect.5. Children suffer pain after surgery. Timely and adequate pain management must accompany surgical interventions.6. Pay particular attention to the postoperative pediatric patient whose pain cannot be soothed by the administration of stan-dard amounts of analgesic agents. Ask yourself whether a sig-nificant yet unrecognized postoperative complication exists.GENERAL CONSIDERATIONSFluid and Electrolyte BalanceIn managing the pediatric surgical patient, an understanding of fluid and electrolyte balance is critical as the margin between dehydration and fluid overload is small. This is particularly true in infants, who have little reserve at baseline and even less when ill. Failure to pay meticulous attention to their hydration status can result in significant fluid overload or dehydration. Several surgical diagnoses such as gastroschisis or short-gut syndrome are characterized by a predisposition to fluid loss. Others require judicious restoration of intravascular volume in order to pre-vent cardiac failure as is the case in patients with congenital diaphragmatic hernia and associated pulmonary hypertension.The infant’s physiologic day is approximately eight hours in duration. Accordingly, careful assessment of the individual patient’s fluid balance, including fluid intake and output for the previous eight hours, is essential to prevent dehydration or fluid overload. Clinical signs of dehydration include tachycardia, decreased urine output, reduced skin turgor, depressed fonta-nelle, absent tears, lethargy, and poor feeding. Fluid overload is often manifested by the onset of a new oxygen requirement, respiratory distress, tachypnea, and tachycardia. The physi-cal assessment of the fluid status of each child must include a complete head-to-toe evaluation, with emphasis on determining whether perturbations in normal physiology are present.At 12 weeks’ gestation, the total body water of a fetus is approximately 94 cc/kg. By the time the fetus reaches full term, the total body water has decreased to approximately 80 cc/kg. Total body water drops an additional 5% within the first week of life, and by 1 year of life, total body water approaches adult levels, around 60 to 65 cc/kg. Parallel to the drop in total body water is the reduction in extracellular fluid. These changes are accelerated in the preterm infant who may face additional fluid losses due to coexisting congenital anomalies or surgery. Nor-mal daily maintenance fluids for most children can be estimated using the following formula:100 mL/kg for the first 10 kg, plus 50 mL/kg for 11 to 20 kg, plus 25 mL/kg for each additional kilogram of body weight thereafter.Because IV (I.V.) fluid orders are written as milliliters per hour, this can be conveniently converted to:4 mL/kg/h up to 10 kg, add 2 mL/kg/h for 11 to 20 kg, and add 1 mL/kg/h for each additional kilogram body weight thereafter.For example, a 26-kg child has an estimated maintenance fluid requirement of (10 × 4) + (10 × 2) + (6 × 1) = 66 mL/h in the absence of massive fluid losses or shock. A newborn infant with gastroschisis will manifest significant evaporative losses from the exposed bowel such that fluid requirements can be on the order of 150 to 180 cc/kg/day.Precise management of a neonate’s fluid status requires an understanding of changes in the glomerular filtration rate (GFR) and tubular function of the kidney. The term newborn’s GFR is approximately 21 mL/min/1.73 m2 compared to 70 mL/min/1.73 m2 in an adult. Within the first 2 weeks of life GFR increases to approximately 60, and by 2 years of age it is essentially at adult levels. The capacity to concentrate urine is very limited in preterm and term infants. In comparison to an adult who can concentrate urine to 1200 mOsm/kg, infants can concentrate urine at best to 600 mOsm/kg. While infants are capable of secreting antidiuretic hormone, ADH, the aquaporin water channel–mediated osmotic water permeability of the infant’s collecting tubules is severely limited compared to that of adults, leading to an insensitivity to ADH.Sodium requirements range from 2 mEq/kg per day in term infants up to 5 mEq/kg per day in critically ill preterm infants as a consequence of salt wasting. Potassium require-ments are on the order of 1 to 2 mEq/kg per day. Calcium and magnesium supplementation of IV fluids is essential to prevent laryngospasm, dysrhythmias, and tetany.Acid-Base EquilibriumAcute metabolic acidosis usually implies inadequate tissue perfusion and is a serious disorder in children. Potentially life-threatening causes that are specific for the pediatric population must be sought; they include intestinal ischemia from necro-tizing enterocolitis (in the neonate), midgut volvulus, or incar-cerated hernia. Other causes include chronic bicarbonate loss from the gastrointestinal tract or acid accumulation as in chronic renal failure. Respiratory acidosis implies hypoventilation, the cause of which should be apparent. Treatment of acute meta-bolic acidosis should be aimed at restoring tissue perfusion by addressing the underlying abnormality first. For severe meta-bolic acidemia where the serum pH is less than 7.25, sodium bicarbonate should be administered using the following guide-line: base deficit × weight in kilograms × 0.5 (in newborns). The last factor in the equation should be 0.4 for smaller children and 0.3 for older children. The dose should be diluted to a concentra-tion of 0.5 mEq/mL because full-strength sodium bicarbonate is hyperosmolar. One-half the corrective dose is given, and the serum pH is measured again. During cardiopulmonary resusci-tation (CPR), one-half the corrective dose can be given as an intravenous bolus and the other half given slowly intravenously.Respiratory alkalosis is usually caused by hyperventila-tion, which is readily correctable. Metabolic alkalosis most commonly implies gastric acid loss, as in the child with pyloric stenosis, or aggressive diuretic therapy. In the child with gastric fluid loss, IV fluids of 5% dextrose, 0.5% normal saline, and 20 mEq KCl/L usually correct the alkalosis.Blood Volume and Blood ReplacementCriteria for blood transfusion in infants and children remain poorly defined. The decision to transfuse a critically ill pediatric patient may depend on a number of clinical features that include the patient’s age, primary diagnosis, the presence of ongoing bleeding, coagulopathy, hypoxia, hemodynamic compromise, lactic acidosis, cyanotic heart disease, and overall severity of illness. A recent survey of transfusion practices among pediatric intensivists showed that the baseline hemoglobin levels that would prompt them to recommend RBC transfusion ranged from 7 to 13 g/dL. Patients with cyanotic heart disease are often transfused to Brunicardi_Ch39_p1705-p1758.indd 170712/02/19 11:26 AM 1708SPECIFIC CONSIDERATIONSPART IIhigher hemoglobin values, although the threshold for transfusion in this population remains to be defined. In general terms, there is a trend towards an avoidance of the use of RBC products whenever possible as current studies suggest that lower hemoglobin concentrations are well tolerated by many groups of patients and that administration of RBCs may have unintended negative consequences, including perhaps an increase in predisposition to the development of necrotizing enterocolitis, although this finding is controversial. In addition, there is increasing evidence that PRBC transfusion may have adverse effects on the host immune in both children and adults. These effects are poorly understood but may include effects due to RBC storage and due to factors that are particular to the individual RBC donor. The TRIPICU randomized controlled trial by Lacroix et al in 2007, which was performed in stable critically ill children, determined that a restrictive Hb transfusion trigger (70 g/L) was as safe as a liberal Hb trigger (95 g/L) and was associated with reduced blood use. It remains uncertain whether this can be extrapolated to unstable patients. Expert opinion now generally favors an Hb transfusion trigger of 70 g/L in stable critically ill children, which is the same as the recommendation for adult patients (see Chapter 7). A higher threshold should be considered if the child has symptomatic anemia or impaired cardiorespiratory function.A useful guideline for estimating blood volume for the newborn infant is approximately 80 mL/kg of body weight. When packed red blood cells are required, the transfusion requirement is usually administered in 10 mL/kg increments, which is roughly equivalent to a 500-mL transfusion for a 70-kg adult. The following formula may be used to determine the vol-ume (ml) of PRBC to be transfused:(Target hematocrit—Current Hematocrit) × weight (kg) × 80/65 (65 represents the estimated hematocrit of a unit of PRBC)As a general rule, blood is recommended for replacement of volume loss if the child’s perfusion is inadequate despite administration of 2 to 3 boluses of 20 mL/kg of isotonic crystalloid. Consideration should be given for the administration of 10 mL/kg of packed red blood cells as soon as possible. Type O blood can be administered without a cross-match and is relatively safe; type-specific blood can be obtained quite quickly; however, unlike fully cross-matched blood, incompatibilities other than ABO and Rh may exist.In the child, coagulation deficiencies may rapidly assume clinical significance after extensive blood transfusion. It is advisable to have fresh frozen plasma and platelets available if more than 30 mL/kg have been transfused. Plasma is given in a dose of 10 to 20 mL/kg, and platelets are given in a dose of 1 unit/5 kg. Each unit of platelets consists of 40 to 60 mL of fluid (plasma plus platelets). Following transfusion of PRBCs to neonates with tenuous fluid balance, a single dose of a diuretic (such as furosemide 1 mg/kg) may help to facilitate excretion of the extra fluid load. Many clinicians prefer to administer fresh products to minimize the deleterious effects of red cell storage.In pediatric patients who have lost greater than 30 mL/kg with ongoing bleeding, consideration should be given to initia-tion of a massive transfusion protocol. Such a protocol involves transfusion, based on weight, of 1:1:1 transfusion of RBCs, plasma, and platelets.Parenteral Alimentation and NutritionThe nutritional requirements of the surgical neonate must be met in order for the child to grow and to heal surgical wounds. Table 39-1Nutritional requirements for the pediatric surgical patientAGECALORIESPROTEIN(kcal/kg/d)(gram/kg/d)0–6 months100–12026 months–1 year1001.51–3 years1001.24–6 years9017–10 years70111–14 years55115–18 years451If inadequate protein and carbohydrate calories are given, the child may not only fail to recover from surgery but may also exhibit growth failure and impaired development of the central nervous system. In general terms, the adequacy of growth must be assessed frequently by determining both total body weight as well as head circumference. Neonates that are particularly predisposed to protein-calorie malnutrition include those with gastroschisis, intestinal atresia, or intestinal insufficiency from other causes, such as necrotizing enterocolitis. The protein and caloric requirements for the surgical neonate are shown in Table 39-1.Nutrition can be provided via either the enteral or parenteral routes. Whenever possible, the enteral route is preferred because it not only promotes the growth and function of the gastrointestinal system, it also ensures that the infant learns how to feed. There are various enteral feeding preparations available; these are outlined in Table 39-2. The choice of formula is based upon the individual clinical state of the child. Pediatric surgeons are often faced with situations where oral feeding is not possible. This problem can be seen in the extremely premature infant who has not yet developed the feeding skills, or in the infant with concomitant craniofacial anomalies that impair sucking, for example. In these instances, enteral feeds can be administered either a nasojejunal or a gastrostomy tube.When the gastrointestinal tract cannot be used because of mechanical, ischemic, inflammatory, or functional disorders, parenteral alimentation must be given. Prolonged parenteral nutrition is delivered via a central venous catheter. Peripheral IV alimentation can be given, utilizing less concentrated but greater volumes of solutions. Long-term parenteral nutrition should include supplemental copper, zinc, and iron to prevent the development of trace metal deficiencies. A major complica-tion of long-term total parenteral nutrition (TPN) is the devel-opment of parenteral nutrition–associated cholestasis, which can eventually progress to liver failure. To prevent this major complication, concomitant enteral feedings should be instituted, and the gastrointestinal tract should be used as soon as pos-sible. When proximal stomas are in place, gastrointestinal con-tinuity should be restored as soon as possible. Where intestinal insufficiency is associated with dilation of the small intestine, tapering or intestinal lengthening procedures may be beneficial. Brunicardi_Ch39_p1705-p1758.indd 170812/02/19 11:26 AM 1709PEDIATRIC SURGERYCHAPTER 39Table 39-2Formulas for pediatric surgical neonatesFORMULAkcal/mLPROTEIN (g/mL)FAT (g/mL)CARBOHYDRATE (g/mL)Human milk0.670.0110.040.07Milk-based formula    Enfamil 200.670.0150.0380.069Similac 200.670.0150.0360.072Soy-based formula    Prosobee0.670.020.0360.07Isomil0.670.0180.0370.068Special formula    Pregestimil.67.019.028.091Alimentum.67.019.038.068Preterm    Enfamil Premature.80.024.041.089Other strategies to minimize the development of TPN-related liver disease include meticulous catheter care to avoid infec-tion, which increases cholestatic symptoms, aggressive treat-ment of any infection, and early cycling of parenteral nutrition in older children who can tolerate not receiving continuous dextrose solution for a limited period. Evidence suggests that cholestasis eventually resolves in most cases after parenteral nutrition is discontinued, as measured by levels of total bili-rubin. Preliminary evidence suggests that substituting omega-3 fish oil lipid emulsion in parenteral nutrition for the standard soybean-based emulsions may prevent the development of TPN-related cholestasis and reverse the effects of established liver disease. A phase 2 trial to determine whether parenteral nutrition–associated liver disease can be reversed or its progres-sion halted by using a parenteral fat emulsion prepared from fish oil as measured by normalization of serum levels of hepatic enzymes and bilirubin is ongoing (ClinicalTrials.gov, identifier NCT00826020).Venous AccessObtaining reliable vascular access in an infant or child is an important task that often becomes the responsibility of the pedi-atric surgeon. The goal should always be to place the catheter in the least invasive, least risky, and least painful manner, and in a location that is most accessible and allows for use of the catheter without complications for as long as it is needed. In infants, cen-tral venous access may be established using a cutdown approach, either in the antecubital fossa, external jugular vein, facial vein, or proximal saphenous vein. If the internal jugular vein is used, care is taken to prevent venous occlusion. In infants over 3 kg and in older children, percutaneous access of the subclavian, internal jugular, or femoral veins is possible in most cases, and central access is achieved using the Seldinger technique. The use of ultrasound (US) is considered standard of care for placement of central lines in this population for the internal jugular vein and femoral veins, and it significantly improves the safety of the insertion procedure. The catheters are tunneled to an exit site separate from the venotomy site. Where available, PICC lines (peripherally inserted central catheters) may be placed, typically via the antecubital fossa. Regardless of whether the catheter is placed by a cutdown approach or percutaneously, a chest X-ray to confirm central location of the catheter tip and to exclude the presence of a pneumothorax or hemothorax is mandatory. When discussing the placement of central venous catheters with par-ents, it is important to note that the complication rate for central venous lines in children can be high. The incidence of catheter-related sepsis or infection remains a problem, yet should be less than 1% with meticulous attention to catheter insertion care and exit site management. Superior or inferior vena caval occlusion is a significant risk after the placement of multiple lines, particu-larly in the smallest premature patients.ThermoregulationCareful regulation of the ambient environment of infants and children is crucial as these patients are extremely thermolabile. Premature infants are particularly susceptible to changes in envi-ronmental temperature. Because they are unable to shiver and lack stores of fat, their potential for thermogenesis is impaired. The innate inability to regulate temperature is compounded by the administration of anesthetic and paralyzing agents. Since these patients lack adaptive mechanisms to cope with the envi-ronment, the environment must be carefully regulated. Attention to heat conservation during transport of the infant to and from the operating room is essential. Transport systems incorporating heating units are necessary for premature infants. In the operat-ing room, the infant is kept warm by the use of overhead heat-ing lamps, a heating blanket, warming of inspired gases, and coverage of the extremities and head with occlusive materials. During abdominal surgery, extreme care is taken to avoid wet and cold drapes. All fluids used to irrigate the chest or abdomen must be warmed to body temperature. Laparoscopic approaches for abdominal operations may result in more stable thermoregu-lation due to decreased heat loss from the smaller wound size. Constant monitoring of the child’s temperature is critical in a lengthy procedure, and the surgeon should continuously com-municate with the anesthesiologist regarding the temperature of the patient. The development of hypothermia in infants and chil-dren can result in cardiac arrhythmias or coagulopathy. These potentially life-threatening complications can be avoided by careful attention to thermoregulation.Brunicardi_Ch39_p1705-p1758.indd 170912/02/19 11:26 AM 1710SPECIFIC CONSIDERATIONSPART IIPain ControlAll children including neonates experience pain; the careful recognition and management of pediatric pain represents an important component of the perioperative management of all pediatric surgical patients. There is a range of pain manage-ment options that can improve the child’s well-being, as well as the parents’ sense of comfort. Given that morphine and fentanyl have an acceptable safety margin, they should be administered to neonates and children when indicated, bear-ing in mind that withholding analgesia poses a significant risk, as does administration of excessive analgesic agents. A recent randomized trial of neonates on ventilators showed that the use of a morphine infusion decreased the incidence of intraventricular hemorrhage by 50%. Additional analge-sic modalities include the use of topical anesthetic ointment (EMLA cream) and the use of regional anesthesia, such as caudal blocks for hernias and epidural or incisional catheter infusions (On-Q) for large abdominal or thoracic incisions. In surgical neonates that have been administered large con-centrations of narcotics over a prolonged period, transient physical dependence should not only be expected but also anticipated. When narcotics are discontinued, symptoms of narcotic withdrawal may develop, including irritability, rest-lessness, and episodes of hypertension and tachycardia. Early recognition of these signs is essential, as is timely treatment using nalaxone and other agents. It is important to admin-ister pain control in concert with a well-qualified and col-laborative pediatric pain-management team, which typically includes anesthesiologists with expertise in pain management, as well as advance practice nurses who can respond rapidly when the pain control is inadequate or excessive. By ensuring that the pediatric surgical patient has adequate analgesia, the surgeon ensures that the patient receives the most humane and thorough treatment and provides important reassurance to all other members of the healthcare team and to the family that pain control is a very high priority.NECK MASSESThe management of neck masses in children is determined by their location and the length of time that they have been pres-ent. Neck lesions are found either in the midline or lateral com-partments. Midline masses include thyroglossal duct remnants, thyroid masses, thymic cysts, or dermoid cysts. Lateral lesions include branchial cleft remnants, cystic hygromas, vascular mal-formations, salivary gland tumors, torticollis, and lipoblastoma (a rare benign mesenchymal tumor of embryonal fat occurring in infants and young children). Enlarged lymph nodes and rare malignancies such as rhabdomyosarcoma can occur either in the midline or laterally.LymphadenopathyThe most common cause of a neck mass in a child is an enlarged lymph node, which typically can be found laterally or in the midline. The patient is usually referred to the pedi-atric surgeon for evaluation after the mass has been present for several weeks. A detailed history and physical examination often helps determine the likely etiology of the lymph node and the need for excisional biopsy. Enlarged tender lymph nodes are usually the result of a bacterial infection (Staphy-lococcus or Streptococcus). Treatment of the primary cause (e.g., otitis media or pharyngitis) with antibiotics often is all that is necessary. However, when the involved nodes become fluctuant, incision and drainage are indicated. In many North American institutions, there has been an increasing prevalence of methicillin-resistant Staphylococcus aureus infection of the skin and soft tissues, leading to increased staphylococcal lymphadenitis in children. More chronic forms of lymphadeni-tis, including infections with atypical mycobacteria, as well as cat-scratch fever, are diagnosed based on serologic findings or excisional biopsy. The lymphadenopathy associated with infectious mononucleosis can be diagnosed based on serology. When the neck nodes are firm, fixed, and others are also pres-ent in the axillae or groin, or the history suggests lymphoma, excisional biopsy is indicated. In these cases, it is essential to obtain a chest radiograph to look for the presence of a medias-tinal mass. Significant mediastinal load portends cardiorespira-tory collapse due to loss of venous return and compression of the tracheobronchial tree with general anesthesia.Thyroglossal Duct RemnantsPathology and Clinical Manifestations. The thyroid gland buds off the foregut diverticulum at the base of the tongue in the region of the future foramen cecum at 3 weeks of embryonic life. As the fetal neck develops, the thyroid tissue becomes more anterior and caudad until it rests in its normal position. The “descent” of the thyroid is intimately connected with the development of the hyoid bone. Residual thyroid tis-sue left behind during the migration may persist and subse-quently present in the midline of the neck as a thyroglossal duct cyst. The mass is most commonly appreciated in the 2to 4-year-old child when the baby fat disappears and irregulari-ties in the neck become more readily apparent. Usually the cyst is encountered in the midline at or below the level of the hyoid bone and moves up and down with swallowing or with protrusion of the tongue. Occasionally it presents as an intrathyroidal mass. Most thyroglossal duct cysts are asymp-tomatic. If the duct retains its connection with the pharynx, infection may occur, and the resulting abscess will necessitate incision and drainage, occasionally resulting in a salivary fis-tula. Submental lymphadenopathy and midline dermoid cysts can be confused with a thyroglossal duct cyst. Rarely, midline ectopic thyroid tissue masquerades as a thyroglossal duct cyst and may represent the patient’s only thyroid tissue. Therefore, if there is any question regarding the diagnosis or if the thyroid gland cannot be palpated in its normal anatomic position, it is advisable to obtain a nuclear scan to confirm the presence of a normal thyroid gland. Although rarely the case in children, in adults the thyroglossal duct may contain thyroid tissue that can undergo malignant degeneration. The presence of malignancy in a thyroglossal cyst should be suspected when the cyst grows rapidly or when US demonstrates a complex anechoic pattern or the presence of calcification.Treatment. If the thyroglossal duct cyst presents with an abscess, treatment should first consist of drainage and antibiot-ics. Following resolution of the inflammation, resection of the cyst in continuity with the central portion of the hyoid bone and the tract connecting to the pharynx in addition to ligation at the foramen cecum (the Sistrunk operation), is curative in over 90% of patients. Lesser operations result in unacceptably high recur-rence rates, and recurrence is more frequent following infection. According to a recent review, factors predictive of recurrence included more than two infections prior to surgery, age under 2 years, and inadequate initial operation.Brunicardi_Ch39_p1705-p1758.indd 171012/02/19 11:26 AM 1711PEDIATRIC SURGERYCHAPTER 39Branchial Cleft AnomaliesPaired branchial clefts and arches develop early in the fourth gestational week. The first cleft and the first, second, third, and fourth pouches give rise to adult organs. The embryologic com-munication between the pharynx and the external surface may persist as a fistula. A fistula is seen most commonly with the second branchial cleft, which normally disappears, and extends from the anterior border of the sternocleidomastoid muscle superiorly, inward through the bifurcation of the carotid artery, and enters the posterolateral pharynx just below the tonsillar fossa. In contrast, a third branchial cleft fistula passes posterior to the carotid bifurcation. The branchial cleft remnants may con-tain small pieces of cartilage and cysts, but internal fistulas are rare. A second branchial cleft sinus is suspected when clear fluid is noted draining from the external opening of the tract at the anterior border of the lower third of the sternomastoid muscle. Rarely, branchial cleft anomalies occur in association with bili-ary atresia and congenital cardiac anomalies, an association that is referred to as Goldenhar’s complex.Treatment. Complete excision of the cyst and sinus tract is necessary for cure. Dissection of the sinus tract is facilitated with passage of a fine lacrimal duct probe through the external opening into the tract and utilizing it as a guide for dissection. Injection of a small amount of methylene blue dye into the tract also may be useful. A series of two or sometimes three small transverse incisions in a “stepladder” fashion is preferred to a long oblique incision in the neck, which is cosmetically unde-sirable. Branchial cleft cysts can present as abscesses. In these cases, initial treatment includes incision and drainage with a course of antibiotics to cover Staphylococcus and Streptococ-cus species, followed by excision of the cyst after the infection resolves.Lymphatic MalformationEtiology and Pathology. Lymphatic malformation (cystic hygroma or lymphangioma) occurs as a result of sequestration or obstruction of developing lymph vessels in approximately 1 in 12,000 births. Although the lesion can occur anywhere, the most common sites are in the posterior triangle of the neck, axilla, groin, and mediastinum. The cysts are lined by endo-thelium and filled with lymph. Occasionally unilocular cysts occur, but more often there are multiple cysts “infiltrating” the surrounding structures and distorting the local anatomy. A particularly troublesome variant of lymphatic malformation is that which involves the tongue, floor of the mouth, and struc-tures deep in the neck. Adjacent connective tissue may show extensive lymphocytic infiltration. The mass may be apparent at birth or may appear and enlarge rapidly in the early weeks or months of life as lymph accumulates; most present by age 2 years (Fig. 39-1A). Extension of the lesion into the axilla or mediastinum occurs about 10% of the time and can be demon-strated preoperatively by chest X-ray, US, or computed tomo-graphic (CT) scan, although magnetic resonance imaging (MRI) is preferable. Occasionally lymphatic malformations contain nests of vascular tissue. These poorly supported vessels may bleed and produce rapid enlargement and discoloration of the lesion. Infection within the lymphatic malformations, usually caused by Streptococcus or Staphylococcus, may occur. In the neck, this can cause rapid enlargement, which may result in airway compromise. Rarely, it may be necessary to carry out percutaneous aspiration of a cyst to relieve respiratory distress.The diagnosis of lymphatic malformation by prenatal US, before 30 weeks’ gestation, has detected a “hidden mortality” as well as a high incidence of associated anomalies, including abnormal karyotypes and hydrops fetalis. Occasionally, very large lesions can cause obstruction of the fetal airway. Such obstruction can result in the development of polyhydramnios by impairing the ability of the fetus to swallow amniotic fluid. In these circumstances, the airway is usually markedly distorted, which can result in immediate airway obstruction unless the air-way is secured at the time of delivery. Orotracheal intubation or emergency tracheostomy while the infant remains attached to the placenta, the so-called EXIT procedure (ex utero intrapar-tum technique) may be necessary to secure the airway.Treatment. The modern management of most lymphatic malformations includes image-guided sclerotherapy as first-line therapy, which often involves multiple injections. Cyst excision may be used in cases where injection is inadequate. BAFigure 39-1. A. Left cervical cystic hygroma in a 2-day old baby. B. Intraoperative photograph showing a vessel loop around the spinal accessory nerve.Brunicardi_Ch39_p1705-p1758.indd 171112/02/19 11:26 AM 1712SPECIFIC CONSIDERATIONSPART IIFigure 39-2. Prenatal ultrasound of a fetus with a congenital dia-phragmatic hernia. Arrows point to the location of the diaphragm. Arrowhead points to the stomach, which is in the thoracic cavity.Total removal of all gross disease is often not possible because of the extent of the lymphatic malformation and its proximity to, and intimate relationship with, adjacent nerves, muscles, and blood vessels (Fig. 39-1B). Radical ablative surgery is not indicated for these lesions, which are always benign. Conservative excision and unroofing of remaining cysts is advised, with repeated partial excision of residual cysts and sclerotherapy if necessary, preserving all adjacent crucial structures. In cases in which surgical excision is performed, closed-suction drainage is recommended. Nevertheless, fluid may accumulate beneath the surgically created flaps in the area from which the lymphatic malformation was excised, requiring multiple needle aspirations. A combined sclerotherapy/resectional approach is particularly useful for masses that extend to the base of the tongue or the floor of the mouth.TorticollisThe presence of a lateral neck mass in infancy in association with rotation of the head towards the opposite side of the mass indicates the presence of congenital torticollis. This lesion results from fibrosis of the sternocleidomastoid muscle. The mass may be palpated in the affected muscle in approximately two-thirds of cases, or it may be diagnosed by US. Histologi-cally, the lesion is characterized by the deposition of collagen and fibroblasts around atrophied muscle cells. In the vast major-ity of cases, physical therapy based on passive stretching of the affected muscle is of benefit. Rarely, surgical transection of the sternocleidomastoid may be indicated.RESPIRATORY SYSTEMCongenital Diaphragmatic Hernia (Bochdalek)Pathology. The septum transversum extends to divide the pleural and coelomic cavities during fetal development. This precursor of the diaphragm normally completes separation of these two cavities at the posterolateral aspects of this mesen-chymally derived structure. The most common variant of a congenital diaphragmatic hernia is a posterolateral defect, also known as a Bochdalek hernia. Diaphragmatic defects allow abdominal viscera to fill the chest cavity. The abdominal cav-ity is small and underdeveloped and remains scaphoid after birth. Both lungs are hypoplastic, with decreased bronchial and pulmonary artery branching. Lung weight, lung volume, and DNA content are also decreased, and these findings are more striking on the ipsilateral side. This anomaly is encountered more commonly on the left (80–90%). Linkage analyses have recently implicated genetic mutations in syndromic variants of congenital diaphragmatic hernias. In many instances, there is a surfactant deficiency, which compounds the degree of respira-tory insufficiency. Amniocentesis with karyotype may identify chromosomal defects, especially trisomy 18 and 21. Associated anomalies, once thought to be uncommon, were identified in 65 of 166 patients in one study, predominately of the heart, fol-lowed by abdominal wall defects, chromosomal changes, and other defects.Prenatal ultrasonography is successful in making the diag-nosis of congenital diaphragmatic hernia (CDH) as early as 15 weeks’ gestation, and early antenatal diagnosis is associated with worse outcomes. US findings include herniated abdominal viscera in the chest that may also look like a mass or lung anom-aly, changes in liver position, and mediastinal shift away from the herniated viscera (Fig. 39-2). Accurate prenatal prediction of outcome for fetuses who have CDH remains a challenge. One index of severity for patients with left CDH is the lung-to-head ratio (LHR), which is the product of the length and the width of the right lung at the level of the cardiac atria divided by the head circumference (all measurements in millimeters). An LHR value of less than 1.0 is associated with a very poor prognosis, whereas an LHR greater than 1.4 predicts a more favorable outcome. The utility of the LHR in predicting outcome in patients with CDH has recently been questioned because of the tremendous interobserver variability in calculating this ratio for a par-ticular patient, as well as the lack of reliable measures to deter-mine postnatal disease severity. Because the LHR is not gestational age independent, Jani and colleagues proposed the introduction of a new measurement: the observed to expected (o/e) LHR, to correct for gestational age. The observed LHR may be expressed as a percentage of the expected mean for ges-tational age of the observed/expected lung-to-head ratio (o/e LHR), which is considered extreme if <15%, severe at 15% to 25%, moderate at 26% to 35%, and mild at 36% to 45%. The most reliable prenatal predictor of postnatal survival is absence of liver herniation, where in 710 fetuses, there was significantly higher survival rate in fetuses without herniation (74% without herniation vs. 45% with herniation).Following delivery, the diagnosis of CDH is made by CXR (Fig. 39-3). The differential diagnosis includes broncho-pulmonary foregut malformations, in which the intrathoracic loops of bowel may be confused for lung or foregut pathol-ogy. The vast majority of infants with CDH develop immedi-ate respiratory distress, which is due to the combined effects of three factors. First, the air-filled bowel in the chest compresses the mobile mediastinum, which shifts to the opposite side of the chest, compromising air exchange in the contralateral lung. Second, pulmonary hypertension develops. This phenomenon results in persistent fetal circulation with resultant decreased pulmonary perfusion and impaired gas exchange. Finally, the lung on the affected side is often hypoplastic, such that it is essentially nonfunctional. Varying degrees of pulmonary hypo-plasia on the opposite side may compound these effects. The second and third factors are thought to be the most important. Neonates with CDH are usually in respiratory distress requiring 1Brunicardi_Ch39_p1705-p1758.indd 171212/02/19 11:26 AM 1713PEDIATRIC SURGERYCHAPTER 39Figure 39-3. Chest X-ray showing a left congenital diaphragmatic hernia.ventilation and intensive care, and the overall mortality in most series is around 50%.Treatment. CDH care has been improved through effective use of improved methods of ventilation and timely cannula-tion for extracorporeal membrane oxygenation (ECMO). Many infants are symptomatic at birth due to hypoxia, hypercarbia, and metabolic acidosis. Prompt cardiorespiratory stabilization is mandatory. It is noteworthy that the first 24 to 48 hours after birth are often characterized by a period of relative stability with high levels of PaO2 and relatively good perfusion. This has been termed the “honeymoon period” and is often followed by progressive cardiorespiratory deterioration. In the past, cor-rection of the hernia was believed to be a surgical emergency, and patients underwent surgery shortly after birth. It is now accepted that the presence of persistent pulmonary hyperten-sion that results in right-to-left shunting across the open fora-men ovale or the ductus arteriosus, and the degree of pulmonary hypoplasia, are the leading causes of cardiorespiratory insuffi-ciency. Current management therefore is directed toward man-aging the pulmonary hypertension, and minimizing barotrauma while optimizing oxygen delivery. To achieve this goal, infants are placed on mechanical ventilation using relatively low or “gentle” settings that prevent overinflation of the noninvolved lung. Levels of PaCO2 in the range of 50 to 60 mmHg or higher are accepted as long as the pH remains ≥7.25. If these objec-tives cannot be achieved using conventional ventilation, high frequency oscillatory ventilation (HFOV) may be employed to avoid the injurious effects of conventional tidal volume venti-lation. Echocardiography will assess the degree of pulmonary hypertension and identify the presence of any coexisting cardiac anomaly. ICU goals include minimal sedation, meticulous atten-tion to endotracheal tube secretions, and gradual changes to ven-tilator settings to avoid inducing pulmonary hypertension via hypoxia. To minimize the degree of pulmonary hypertension, inhaled nitric oxide may be administered, and in some patients, this improves pulmonary perfusion. Nitric oxide is administered into the ventilation circuit and is used in concentrations up to 40 parts per million. Correction of acidosis using bicarbonate solution may minimize the degree of pulmonary hypertension. As the degree of pulmonary hypertension becomes hemody-namically significant, right-sided heart failure develops, and systemic perfusion is impaired. Administration of excess IV fluid will compound the degree of cardiac failure and lead to marked peripheral edema. Inotropic support using epinephrine, dopamine, and milrinone alone or in combination may be useful in optimizing cardiac contractility and maintaining mean arterial pressure.Infants with CDH who remain severely hypoxic despite maximal ventilatory care may be candidates for treatment of their respiratory failure ECMO, with access via venovenous (VV) or venoarterial (VA) routes. VV bypass is established with a single cannula through the right internal jugular vein, with blood removed from and infused into the right atrium by separate ports. VA bypass provides additional cardiac support, whereas VV bypass requires a well-functioning heart and relies on the lungs for some oxygenation as well. In VA ECMO, the right atrium is cannulated by means of the internal jugular vein and the aortic arch through the right common carotid artery. As much of the cardiac output is directed through the membrane oxygenator as is necessary to provide oxygenated blood to the infant and remove carbon dioxide. The infant is maintained on bypass until the pulmonary hypertension is resolved and lung function, as measured by compliance and the ability to oxy-genate and ventilate, is improved. This is usually seen within 7 to 10 days, but in some infants, it may take up several weeks to occur. Complications associated with ECMO increase after 14 days and include cannula malposition, bleeding in multiple locations, and infection. The use of ECMO is associated with significant risk. Because patients require systemic anticoagu-lation, bleeding complications are the most significant. They may occur intracranially or at the site of cannula insertion, and they can be life-threatening. Systemic sepsis is a significant problem and may necessitate decannulation. Criteria for plac-ing infants on ECMO include the presence of normal cardiac anatomy by echocardiography, the absence of fatal chromosome anomalies, and the expectation that the infant would die with-out ECMO. Traditionally, a threshold of weight greater than 2 kg and gestational age greater than 34 weeks has been applied, although success has been achieved at weights as low as 1.8 kg. Upon decannulation, some centers repair the carotid artery. In instances in which the child is cannulated for a brief period (5 days or less) this may be feasible. A recent study failed to show any benefit from repairing the carotid artery, although this finding remains to be studied further.A strategy that does not involve the use of ECMO but instead emphasizes the use of permissive hypercapnia and the avoidance of barotrauma may provide equal overall outcome in patients with CDH. This likely reflects the fact that mortality is related to the degree of pulmonary hypoplasia and the pres-ence of congenital anomalies, neither of which are correctable by ECMO.Brunicardi_Ch39_p1705-p1758.indd 171312/02/19 11:26 AM 1714SPECIFIC CONSIDERATIONSPART IIFigure 39-4. Congenital lobar emphysema of the left upper lobe in a 2-week-old boy. Mediastinal shift is present.The timing of diaphragmatic hernia repair still varies from center to center, particularly when the infant is on ECMO. In patients that are not on ECMO, repair should be performed once the hemodynamic status has been optimized. In neonates that are on ECMO, some surgeons perform early repair on bypass; oth-ers wait until the infant’s lungs are improved and the pulmonary hypertension has subsided and then repair the diaphragm and discontinue bypass within hours of surgery. Still others repair the diaphragm only after the infant is off bypass. Operative repair of the diaphragmatic hernia may be accomplished either by an abdominal or transthoracic approach and can be performed either via open or minimally invasive techniques. Through a subcostal incision the abdominal viscera are withdrawn from the chest, exposing the defect in the diaphragm. Care must be taken when reducing the spleen and liver, as bleeding from these structures can be fatal. The anterior margin is often apparent, while the posterior muscular rim is attenuated. If the infant is heparinized on bypass, minimal dissection of the muscular margins is per-formed. Electrocautery is used liberally to minimize postopera-tive bleeding. Most infants who require ECMO support prior to hernia repair have large defects, often lacking the medial and posterior margins. About three-fourths of infants repaired on bypass require prosthetic material to patch the defect, suturing it to the diaphragmatic remnant or around ribs or costal cartilages for the large defects. If there is adequate muscle for closure, a single layer of nonabsorbable horizontal mattress suture, pled-geted or not, closes the defect. Just before the repair is complete, a chest tube may be positioned in the thoracic cavity but is not mandatory. Patients repaired on ECMO are at risk for develop-ing a hemothorax, which can significantly impair ventilation. Anatomic closure of the abdominal wall may be impossible after reduction of the viscera. Occasionally, a prosthetic patch or acellular material may be sutured to the fascia to facilitate closure. The patch can be removed at a later time, and the ventral hernia can be closed at that time or subsequently. In patients who are deemed to be candidates for a minimally invasive approach (stable patients, >2 kg, no pulmonary hypertension), a thoraco-scopic repair may be safely performed although concerns have been raised about possible effects of the longer operative time for thoracoscopic repair and higher recurrence rates. If the dia-phragm has been repaired on ECMO, weaning and decannulation are accomplished as soon as possible. All infants are ventilated postoperatively to maintain preductal arterial oxygenation of 80 to 100 torr. Very slow weaning from the ventilator is necessary to avoid recurrent pulmonary hypertension.Fetal tracheal occlusion is an experimental prenatal ther-apy for the treatment of severe congenital diaphragmatic hernia that reverses lung hypoplasia. The rationale for this approach is that the occlusion of the fetal trachea leads to net accumula-tion of lung liquid under pressure, which results in the develop-ment of large fluid-filled lungs. The balloon may be placed into the trachea under laparoscopic guidance, then removed prior to delivery when maximal lung growth has been achieved. The use of fetal tracheal occlusion remains investigational, although early reports are promising.Congenital Lobar EmphysemaCongenital lobar emphysema (CLE) is a condition manifested during the first few months of life as a progressive hyperexpan-sion of one or more lobes of the lung. It can be life-threatening in the newborn period if extensive lung tissue is involved, but in the older infant and in cases in which the lesion is less severely distended it causes less respiratory distress. Air entering during inspiration is trapped in the lobe; on expiration, the lobe can-not deflate and progressively overexpands, causing atelectasis of the adjacent lobe or lobes. This hyperexpansion eventually shifts the mediastinum to the opposite side and compromises the other lung. CLE usually occurs in the upper lobes of the lung (left greater than right), followed next in frequency by the right middle lobe, but it also can occur in the lower lobes. It is caused by intrinsic bronchial obstruction from poor bronchial cartilage development or extrinsic compression. Approximately 14% of children with this condition have cardiac defects, with an enlarged left atrium or a major vessel causing compression of the ipsilateral bronchus.Symptoms range from mild respiratory distress to full-fledged respiratory failure with tachypnea, dyspnea, cough, and late cyanosis. These symptoms may be stationary or they may progress rapidly or result in recurrent pneumonia. Occasionally, infants with CLE present with failure to thrive, which likely reflects the increased work associated with the overexpanded lung. A hyperexpanded hemithorax on the ipsilateral side is pathogneumonic for CLE. Diagnosis is typically confirmed by chest X-ray that shows a hyperlucent affected lobe with adja-cent lobar compression and atelectasis. The mediastinum may be shifted as a consequence of mass effect to the contralateral side causing compression and atelectasis of the contralateral lung (Fig. 39-4). Although chest radiograph is usually sufficient, it is sometimes important to obtain at CT scan of the chest to clearly establish the diagnosis of CLE. This should be done only in the stable patient. Unless foreign body or mucous plugging is suspected as a cause of hyperinflation, bronchoscopy is not advisable because it can lead to more air trapping and cause life-threatening respiratory distress in a stable infant. Treatment is resection of the affected lobe, which can be safely performed using either an open or thoracoscopic approach. Unless symp-toms necessitate earlier surgery, resection can usually be per-formed after the infant is several months of age. The prognosis is excellent.Brunicardi_Ch39_p1705-p1758.indd 171412/02/19 11:26 AM 1715PEDIATRIC SURGERYCHAPTER 39Figure 39-5. Computed tomography scan of the chest showing a congenital cystic adenomatoid malformation of the left lower lobe.Figure 39-6. Intraoperative photograph showing left lower lobe congenital cystic adenomatoid malformation seen in Fig. 39-5.Bronchopulmonary Foregut MalformationsBronchopulmonary foregut malformations include foregut duplication cysts, congenital pulmonary airway malformations, and pulmonary sequestrations as discussed in the following sections.Congenital Pulmonary Airway Malformations. Previ-ously denoted as congenital cystic adenomatous malformation, (CCAM), congenital pulmonary airway malformations (CPAM) exhibits cystic proliferation of the terminal airway, producing cysts lined by mucus-producing respiratory epithelium, and elastic tissue in the cyst walls without cartilage formation. There may be a single cyst with a wall of connective tissue contain-ing smooth muscle. Cysts may be large and multiple (type I), smaller and more numerous (type II), or they may resemble fetal lung without macroscopic cysts (type III). CPAMs frequently occur in the left lower lobe. However, this lesion can occur in any location and may occur in more than one lobe on more than one side, although this is rare. Clinical symptoms range from none to severe respiratory failure at birth. Over time, these mal-formations can be subject to repeated infections and produce fever and cough in older infants and children. The diagnosis is usually confirmed by CT for surgical planning and charac-teristic features that might delineate other bronchopulmonary foregut malformations (Fig. 39-5). Prenatal US may suggest the diagnosis. Resection is curative and may need to be performed urgently in the infant with severe respiratory distress. Long term, there is a risk of malignant degeneration in unresected CPAMs, but this risk occurs over decades and has not been fully defined. As a result, resection of the affected lobe is usually per-formed (Fig. 39-6). Antenatal resection may be rarely indicated in those instances in which fetal development is complicated by hydrops as a result of the mechanical and vascular effects of the lung lesion.Pulmonary Sequestration. Pulmonary sequestration is uncommon and consists of a mass of lung tissue, usually in the left lower chest, occurring without the usual connections to the pulmonary artery or tracheobronchial tree, yet with a systemic blood supply from the aorta. There are two kinds of sequestra-tion. Extralobar sequestration is usually a small area of nonaer-ated lung separated from the main lung mass, with a systemic blood supply, located immediately above the left diaphragm. It is commonly found in cases of CDH. Intralobar sequestration more commonly occurs within the parenchyma of the left lower lobe but can occur on the right. There is no major connection to the tracheobronchial tree, but a secondary connection may be established, perhaps through infection or via adjacent intra-pulmonary shunts. The blood supply frequently originates from the aorta below the diaphragm; multiple vessels may be present (Fig. 39-7). Venous drainage of both types can be systemic or pulmonary. The cause of sequestration is unknown but most probably involves an abnormal budding of the developing lung that picks up a systemic blood supply and never becomes con-nected with the bronchus or pulmonary vessels. Sequestrations may, in some cases, exhibit mixed pathology with components consistent with CCAMs. Extralobar sequestration is asymptom-atic and is usually discovered incidentally on chest X-ray. If the diagnosis can be confirmed, e.g., by CT scan, resection is not necessary. Diagnosis of intralobar sequestration may be made prenatally and confirmed on postnatal CT scan. Alternatively, the diagnosis of intralobar sequestration may be established after repeated infections manifested by cough, fever, and con-solidation in the posterior basal segment of the left lower lobe. Increasingly the diagnosis is being made in the early months of life by US, and color Doppler often can be helpful in delin-eating the systemic arterial supply. Removal of the entire left lower lobe is usually necessary since the diagnosis often is made late after multiple infections. Occasionally segmental resection Figure 39-7. Arteriogram showing large systemic artery supply to intralobar sequestration of the left lower lobe.Brunicardi_Ch39_p1705-p1758.indd 171512/02/19 11:26 AM 1716SPECIFIC CONSIDERATIONSPART IIof the sequestered part of the lung can be performed using an open, or ideally, a thoracoscopic approach. If an open approach is used, it is important to open the chest through a low inter-costal space (sixth or seventh) to gain access to the vascular attachments to the aorta. These attachments may insert into the aorta below the diaphragm; in these cases, division of the ves-sels as they traverse the thoracic cavity is essential. Prognosis is generally excellent. However, failure to obtain adequate control of these vessels may result in their retraction into the abdomen and result in uncontrollable hemorrhage. It is also possible to perform a combined thoracoscopic and open approach, wherein the vessels are clipped and divided thoracoscopically and then the lesion safely removed through a limited thoracotomy.Bronchogenic Cyst. Bronchogenic cysts are duplication cysts originating from the airway, regardless of the identity of the lining epithelial identity. They can occur anywhere along the respiratory tract and can present at any age, although typically they present after accumulation of intraluminal contents and not within the newborn period. Histologically, they are hamartoma-tous and usually consist of a single cyst lined with an epithe-lium; the mesenchyme contains cartilage and smooth muscle. They are probably embryonic rests of foregut origin that have been pinched off from the main portion of the developing tra-cheobronchial tree and are closely associated in causation with other foregut duplication cysts such as those arising from the esophagus. Bronchogenic cysts may be seen on prenatal US but are discovered most often incidentally on postnatal chest X-ray. Although they may be completely asymptomatic, bronchogenic cysts may produce symptoms, usually compressive, depending on the anatomic location and size, which increases over time if there is no egress for building luminal contents. In the para-tracheal region of the neck they can produce airway compres-sion and respiratory distress. In the lung parenchyma, they may become infected and present with fever and cough. In addition, they may cause obstruction of the bronchial lumen with distal atelectasis and infection, or they may cause mediastinal com-pression. Rarely, rupture of the cyst can occur. Chest X-ray usu-ally shows a dense mass, and CT scan or MRI delineates the precise anatomic location of the lesion. Treatment consists of resection of the cyst, which may need to be undertaken in emer-gency circumstances for airway or cardiac compression. Resec-tion can be performed either as an open procedure, or more commonly using a thoracoscopic approach. If resection of a common wall will result in injury to the airway, resection of the inner epithelial cyst lining after marsupialization is acceptable.BronchiectasisBronchiectasis is an abnormal and irreversible dilatation of the bronchi and bronchioles associated with chronic suppura-tive disease of the airways. Usually patients have an underlying congenital pulmonary anomaly, cystic fibrosis, or immunologic deficiency. Bronchiectasis can also result from chronic infection secondary to a neglected bronchial foreign body. The symptoms include a chronic cough, often productive of purulent secretions, recurrent pulmonary infection, and hemoptysis. The diagnosis is suggested by a chest X-ray that shows increased bronchovas-cular markings in the affected lobe. Chest CT delineates bron-chiectasis with excellent resolution. The preferred treatment for bronchiectasis is medical, consisting of antibiotics, postural drainage, and bronchodilator therapy because many children with the disease show signs of airflow obstruction and bron-chial hyperresponsiveness. Lobectomy or segmental resection is indicated for localized disease that has not responded appro-priately to medical therapy. In severe cases, lung transplantation may be required to replace the terminally damaged, septic lung.Foreign BodiesThe inherent curiosity of children and their innate propensity to place new objects into their mouths to fully explore them place them at great risk for aspiration. Aspirated objects can be found either in the airway or in the esophagus; in both cases the results can be life-threatening.Airway Ingestion. Aspiration of foreign bodies most com-monly occurs in the toddler age group. Peanuts are the most common object that is aspirated, although other materials (pop-corn, for instance) may also be involved. A solid foreign body often will cause air trapping, with hyperlucency of the affected lobe or lung seen especially on expiration. Oil from the peanut is very irritating and may cause pneumonia. Delay in diagnosis can lead to atelectasis and infection. The most common ana-tomic location for a foreign body is the right main stem bronchus or the right lower lobe. The child usually will cough or choke while eating but may then become asymptomatic. Total respira-tory obstruction with tracheal foreign body may occur; however, respiratory distress is usually mild if present at all. A unilateral wheeze is often heard on auscultation. This wheeze often leads to an inappropriate diagnosis of “asthma” and may delay the correct diagnosis for some time. Chest X-ray will show a radi-opaque foreign body, but in the case of nuts, seeds, or plastic toy parts, the only clue may be hyperexpansion of the affected lobe on an expiratory film or fluoroscopy. Bronchoscopy confirms the diagnosis and allows removal of the foreign body. It can be a very simple procedure or it may be extremely difficult, espe-cially with a smooth foreign body that cannot be grasped easily or one that has been retained for some time. The rigid broncho-scope should be used in all cases, and utilization of the optical forceps facilitates grasping the inhaled object. Epinephrine may be injected into the mucosa when the object has been present for a long period of time, which minimizes bleeding. Bronchiectasis may be seen as an extremely late phenomenon after repeated infections of the poorly aerated lung and may require partial or total resection of the affected lobe. The differential diagnosis of a bronchial foreign body includes an intraluminal tumor (i.e., carcinoid, hemangioma, or neurofibroma).Foreign Bodies and Esophageal Injury. The most common foreign body in the esophagus is a coin, followed by small toy parts. Toddlers are most commonly affected. The coin is retained in the esophagus at one of three locations: the cricopharyngeus, the area of the aortic arch, or the gastroesophageal junction, all of which are areas of normal anatomic narrowing. Symptoms are variable depending on the anatomic position of the foreign body and the degree of obstruction. There is often a relatively asymptomatic period after ingestion. The initial symptoms are gastrointestinal, and include dysphagia, drooling, and dehydra-tion. The longer the foreign body remains in the esophagus with oral secretions unable to transit the esophagus, the greater the incidence of respiratory symptoms including cough, stridor, and wheezing. These findings may be interpreted as signs of upper respiratory infections. Objects that are present for a long period of time—particularly in children who have underlying neurological impairment—may manifest as chronic dysphagia. The chest X-ray is diagnostic in the case of a coin. A contrast swallow, or preferably an esophagoscopy, may be required for nonradiopaque foreign bodies. Coins lodged within the upper Brunicardi_Ch39_p1705-p1758.indd 171612/02/19 11:26 AM 1717PEDIATRIC SURGERYCHAPTER 39Figure 39-8. The five varieties of esophageal atresia and tracheoesophageal fistula. A. Isolated esophageal atresia. B. Esophageal atresia with tracheoesophageal fistula between proximal segment of esophagus and trachea. C. Esophageal atresia with tracheoesophageal fistula between distal esophagus and trachea. D. Esophageal atresia with fistula between both proximal and distal ends of esophagus and trachea. E. Tracheoesophageal fistula without esophageal atresia (H-type fistula).esophagus for less than 24 hours may be removed using Magill forceps during direct laryngoscopy. For all other situations, the treatment is by esophagoscopy, rigid or flexible, and removal of the foreign body. In the case of sharp foreign bodies such as open safety pins, extreme care is required on extraction to avoid injury to the esophagus. Rarely, esophagotomy is required for removal, particularly of sharp objects. Diligent follow-up is required after removal of foreign bodies, especially batteries, which can cause strictures, and sharp objects, which can injure the underlying esophagus. In the case of a retained battery, this case should be handled as a surgical emergency, as the negative pole of the battery directly damages the surrounding tissue, and tracheoesophageal fistula, aortic exsanguination, and mediasti-nitis have all been described after local tissue necrosis at the site where the battery has lodged.ESOPHAGUSEsophageal Atresia and Tracheoesophageal FistulaThe management of esophageal atresia (EA) and tracheoesopha-geal fistula (TEF) is one of the most gratifying pediatric sur-gical conditions to treat. In the not so distant past, nearly all infants born with EA and TEF died. In 1939 Ladd and Leven achieved the first success repair by ligating the fistula, placing a gastrostomy, and reconstructing the esophagus at a later time. Subsequently, Dr. Cameron Haight, in Ann Arbor, Michigan, performed the first successful primary anastomosis for esopha-geal atresia, which remains the current approach for treatment of this condition. Despite the fact that there are several com-mon varieties of this anomaly and the underlying cause remains obscure, a careful approach consisting of meticulous periopera-tive care and attention to the technical detail of the operation can result in an excellent prognosis in most cases.Anatomic Varieties. The five major varieties of EA and TEF are shown in Fig. 39-8. The most commonly seen variety is esophageal atresia with distal tracheoesophageal fistula (type C), which occurs in approximately 85% of the cases in most series. The next most frequent is pure esophageal atresia (type A), occurring in 8% to 10% of patients, followed by tracheoesophageal fistula without esophageal atresia (type E). This occurs in 8% of cases and is also referred to as an H-type fistula, based upon the anatomic similarity to that letter Figure 39-9. Barium esophagram showing H-type tracheoesophageal fistula (arrow).(Fig. 39-9). Esophageal atresia with fistula between both proximal and distal ends of the esophagus and trachea (type D) is seen in approximately 2% of cases, and type B, esophageal atresia with tracheoesophageal fistula between distal esophagus and trachea, is seen in approximately 1% of all cases.Etiology and Pathologic Presentation. The esophagus and trachea share a common embryologic origin. At approximately 4 weeks’ gestation, a diverticulum forms off the anterior aspect of the proximal foregut in the region of the primitive pharynx. This diverticulum extends caudally with progressive formation of the laryngo-tracheal groove, thus, creating a separate trachea and esophagus. Successful development of these structures is the consequence of extremely intricate interplay of growth and transcription factors necessary for rostral-caudal and anterior-posterior specification. The variations in clinically observed EA and TEF that must result in failure of successful formation of these structures are depicted in Fig. 39-8. While definitive genetic mutations have been difficult to identify in isolated EA-TEF, mutations in N-myc, Sox2, and CHD7 have been character-ized in syndromic EA-TEF with associated anomalies.Other congenital anomalies commonly occur in asso-ciation with EA-TEF. For instance, VACTERRL syndrome is associated with vertebral anomalies (absent vertebrae or hemi-vertebrae) and anorectal anomalies (imperforate anus), cardiac Brunicardi_Ch39_p1705-p1758.indd 171712/02/19 11:26 AM 1718SPECIFIC CONSIDERATIONSPART IIFigure 39-10. Type C esophageal atresia with tracheoesophageal fistula. Note the catheter that is coiled in the upper pouch and the presence of gas below the diaphragm, which confirms the presence of the tracheoesophageal fistula.defects, tracheoesophageal fistula, renal anomalies (renal agen-esis, renal anomalies), and radial limb hyperplasia. In nearly 20% of the infants born with esophageal atresia, some variant of congenital heart disease occurs.Clinical Presentation of Infants With Esophageal Atresia and Tracheoesophageal Fistula. The anatomic variant of infants with EA-TEF predicts the clinical presentation. When the esophagus ends either as a blind pouch or as a fistula into the trachea (as in types A, B, C, or D), infants present with exces-sive drooling, followed by choking or coughing immediately after feeding is initiated as a result of aspiration through the fistula tract. As the neonate coughs and cries, air is transmitted through the fistula into the stomach, resulting in abdominal dis-tention. As the abdomen distends, it becomes increasingly more difficult for the infant to breathe. This leads to further atelecta-sis, which compounds the pulmonary dysfunction. In patients with type C and D varieties, the regurgitated gastric juice passes through the fistula where it collects in the trachea and lungs and leads to a chemical pneumonitis, which further exacerbates the pulmonary status. In many instances, the diagnosis is actually made by the nursing staff who attempt to feed the baby and notice the accumulation of oral secretions.The diagnosis of esophageal atresia is confirmed by the inability to pass an orogastric tube into the stomach (Fig. 39-10). The dilated upper pouch may be occasionally seen on a plain chest radiograph. If a soft feeding tube is used, the tube will coil in the upper pouch, which provides further diagnostic cer-tainty. An important alternative diagnosis that must be consid-ered when an orogastric tube does not enter the stomach is that of an esophageal perforation. This problem can occur in infants after traumatic insertion of a nasogastric or orogastric tube. In this instance, the perforation classically occurs at the level of the piriform sinus, and a false passage is created, which prevents the tube from entering the stomach. Whenever there is any diag-nostic uncertainty, a contrast study will confirm the diagnosis of EA and occasionally document the TEF. The presence of a tracheoesophageal fistula can be demonstrated clinically by finding air in the gastrointestinal tract. This can be proven at the bedside by percussion of the abdomen and confirmed by obtain-ing a plain abdominal radiograph. Occasionally, a diagnosis of EA-TEF can be suspected prenatally on US evaluation. Typical features include failure to visualize the stomach and the pres-ence of polyhydramnios. These findings reflect the absence of efficient swallowing by the fetus.In a child with esophageal atresia, it is important to iden-tify whether coexisting anomalies are present. These include cardiac defects in 38%, skeletal defects in 19%, neurologi-cal defects in 15%, renal defects in 15%, anorectal defects in 8%, and other abnormalities in 13%. Examination of the heart and great vessels with echocardiography is important to exclude cardiac defects, as these are often the most important predictors of survival in these infants. The echocardiogram also demonstrates whether the aortic arch is left sided or right sided, which may influence the approach to surgical repair. Vertebral anomalies are assessed by plain radiography, and a spinal US is obtained if any are detected. A patent anus should be confirmed clinically. The kidneys in a newborn may be assessed clinically by palpation. A US of the abdomen will demonstrate the presence of renal anomalies, which should be suspected in the child who fails to make urine. The presence of extremity anomalies is suspected when there are missing digits and confirmed by plain radiographs of the hands, feet, forearms, and legs. Rib anomalies may also be present. These may include the presence of a 13th rib.Initial Management. The initial treatment of infants with EA-TEF includes attention to the respiratory status, decompression of the upper pouch, and appropriate timing of surgery. Because the major determinant of poor survival is the presence of other severe anomalies, a search for other defects including congeni-tal cardiac disease is undertaken in a timely fashion. The initial strategy after the diagnosis is confirmed is to place the neonate in an infant warmer with the head elevated at least 30°. A sump catheter is placed in the upper pouch on continuous suction. Both of these strategies are designed to minimize the degree of aspiration from the esophageal pouch. When saliva accumulates in the upper pouch and is aspirated into the lungs, coughing, bronchospasm, and desaturation episodes can occur, which may be minimized by ensuring the patency of the sump catheter. IV antibiotic therapy is initiated, and warmed electrolyte solu-tion is administered. Where possible, the right upper extremity is avoided as a site to start an IV line, as this location may interfere with positioning of the patient during the surgical repair. Some surgeons place a central line in all patients to facilitate the admin-istration of antibiotics and total parenteral nutrition as needed.The timing of repair is influenced by the stability of the patient. Definitive repair of the EA-TEF is rarely a surgical emergency. If the child is hemodynamically stable and is oxy-genating well, definitive repair may be performed within 1 to 2 days after birth. This allows for a careful determination of the presence of coexisting anomalies and for selection of an expe-rienced anesthetic team.Management of Esophageal Atresia and Tracheoesopha-geal Fistula in the Preterm Infant. The ventilated, prema-ture neonate with EA-TEF and associated hyaline membrane disease represents a patient who may develop severe, progres-sive, cardiopulmonary dysfunction. The tracheoesophageal fis-tula can worsen the fragile pulmonary status as a result of recurrent aspiration through the fistula, and as a result of increased abdominal distention, which impairs lung expansion. Moreover, the elevated airway pressure that is required to ven-tilate these patients can worsen the clinical course by forcing air through the fistula into the stomach, thereby exacerbating the Brunicardi_Ch39_p1705-p1758.indd 171812/02/19 11:26 AM 1719PEDIATRIC SURGERYCHAPTER 39ABCEDAzygos VeinEsophagusEsophagusAzygos VeinFigure 39-11. Primary repair of type C tracheosophageal fistula. A. Right thoracotomy incision. B. Azygous vein transected, proximal and distal esophagus demonstrated, and fistula identified. C. Tracheoesophageal fistula transected and defect in trachea closed. D. End-to-end anastomosis between proximal and distal esophagus (posterior row). E. Completed anastomosis.degree of abdominal distention and compromising lung expan-sion. In this situation, the first priority is to minimize the degree of positive pressure needed to adequately ventilate the child. This can be accomplished using high frequency oscil-latory ventilation (HFOV). If the gastric distention becomes severe, a gastrostomy tube should be placed. This procedure can be performed at the bedside under local anesthetic, if necessary. The dilated, air-filled stomach can easily be accessed through an incision in the left-upper quadrant of the abdomen. Once the gastrostomy tube is placed and the abdominal pressure is relieved, the pulmonary status can paradoxically worsen. This is because the ventilated gas may pass preferentially through the fistula, which is the path of least resistance, and bypass the lungs thereby worsening the hypoxemia. To correct this problem, the gastrostomy tube may be placed under water seal, elevated, or intermittently clamped. If these maneuvers are to no avail, liga-tion of the fistula may be required. This procedure can be per-formed in the neonatal intensive care unit if the infant is too unstable to be transported to the operating room. These inter-ventions allow for the infant’s underlying hyaline membrane disease to improve, for the pulmonary secretions to clear, and for the infant to reach a period of stability so that definitive repair can be performed.Primary Surgical Correction. In a stable infant, definitive repair is achieved through performance of a primary esopha-goesophagostomy. There are two approaches to this operation: 2open thoracotomy or thoracoscopy. In the open approach, the infant is brought to the operating room, intubated, and placed in the lateral decubitus position with the right side up in prepara-tion for right posterolateral thoracotomy. If a right-sided arch was determined previously by echocardiography, consideration is given to performing the repair through the left chest, although most surgeons believe that the repair can be performed safely from the right side as well. Bronchoscopy may be performed to exclude the presence of additional, upper-pouch fistulae in cases of esophageal atresia (i.e., differentiation of types B, C, and D variants) and identification of a laryngeotracheoesopha-geal cleft.The operative technique for primary repair is as follows (Fig. 39-11). A retropleural approach is generally used as this technique prevents widespread contamination of the thorax if a postoperative anastomotic leak occurs. The sequence of steps is as follows: (a) mobilization of the pleura to expose the struc-tures in the posterior mediastinum; (b) division of the fistula and closure of the tracheal opening; (c) mobilization of the upper esophagus sufficiently to permit an anastomosis without tension and to determine whether a fistula is present between the upper esophagus and the trachea (forward pressure by the anesthesia staff on the sump drain in the pouch can greatly facilitate dissection at this stage of the operation; care must be taken when dissecting posteriorly to avoid violation of either the lumen of trachea and esophagus); (d) mobilization of the dis-tal esophagus (this needs to be performed judiciously to avoid Brunicardi_Ch39_p1705-p1758.indd 171912/02/19 11:26 AM 1720SPECIFIC CONSIDERATIONSPART IIdevascularization since the blood supply to the distal esopha-gus is segmental from the aorta; most of the esophageal length is obtained from mobilizing the upper pouch since the blood supply travels via the submucosa from above); (e) performing a primary esophagoesophageal anastomosis (most surgeons perform this procedure in a single layer using 5-0 sutures; if there is excess tension, the muscle of the upper pouch can be circumferentially incised without compromising blood supply to increase its length; many surgeons place a transanastomotic feeding tube in order to institute feeds in the early postoperative period); and (f) placement of a retropleural drain and closure of the incision in layers.When a minimally invasive approach is selected, the patient is prepared for right-sided, transthoracic thoracoscopic repair. The same steps as described earlier for the open repair are undertaken, and the magnification and superb optics that are provided by the thoracoscopic approach provide for superb visualization. Identification of the fistula is performed as a first step; this can be readily ligated and divided between tho-racoscopically placed sutures. The anastomosis is performed in a single layer. The thoracoscopically performed TEF repair requires clear and ongoing communication between the oper-ating surgeons and the anesthesiologist; visualization can be significantly reduced with sudden changes in lung inflation, potentially leading to the need to convert to an open repair. Although clear guidelines for patient selection for a thoraco-scopic repair as opposed to an open repair remain lacking, rea-sonable selection criteria include patients over 2.5 kg who are hemodynamically stable and without comorbidities.Postoperative Course. The postoperative management strat-egy of patients with EA-TEF is influenced to a great degree by the preference of the individual surgeon and the institutional culture. Many surgeons prefer not to leave the infants intubated postoperatively to avoid the effects of positive pressure on the site of tracheal closure. However, early extubation may not be possible in babies with preoperative lung disease either from pre-maturity or pneumonia or when there is any vocal cord edema. When a transanastomotic tube is placed, feeds are begun slowly in the postoperative period. Some surgeons institute parenteral nutrition for several days, using a central line. The retropleural drain is assessed daily for the presence of saliva, indicating an anastomotic leak. Many surgeons obtain a contrast swallow 1 week after repair to assess the caliber of the anastomosis and to determine whether a leak is present. If there is no leak, feedings are started. The principal benefit of the thoracoscopic approach is that postoperative pain is significantly reduced, as is the requirement for postoperative narcotic analgesia.Complications of Surgery. Anastomotic leak occurs in 10% to 15% of patients and may be seen either in the immediate post-operative period or after several days. Early leakage (i.e., within the first 24 to 48 hours) is manifested by a new pleural effusion, pneumothorax, and sepsis and requires immediate exploration. In these circumstances, the anastomosis may be completely dis-rupted, possibly due to excessive tension. Revision of the anas-tomosis may be possible. If not, cervical esophagostomy and gastrostomy placement is required, with a subsequent procedure to reestablish esophageal continuity. Anastomotic leakage that is detected after several days usually heals without intervention, particularly if a retropleural approach is used. Under these cir-cumstances, broad spectrum antibiotics, pulmonary toilet, and optimization of nutrition are important. After approximately a week or so, a repeat esophagram should be performed, at which time the leakage may have resolved.Strictures at the anastomosis are not infrequent (10–20%), particularly if a leak has occurred. A stricture may become apparent at any time, from the early postoperative period to months or years later. It may present as choking, gagging, or failure to thrive, but it often becomes clinically apparent with the transition to eating solid food. A contrast swallow or esoph-agoscopy is confirmatory, and simple dilatation is usually cor-rective. Occasionally, repeated dilatations are required. These may be performed in a retrograde fashion, during which a silk suture is placed into the oropharynx and delivered from the esophagus through a gastrostomy tube. Tucker dilators are then tied to the suture and passed in a retrograde fashion from the gastrostomy tube and delivered out of the oropharynx. Increas-ing sizes are used, and the silk is replaced at the end of the pro-cedure where it is taped to the side of the face at one end, and to the gastrostomy tube at the other. Alternatively, image-guided balloon dilation over a guide wire may be performed, using intraoperative contrast radiography to determine the precise location of the stricture and to assess the immediate response to the dilation.“Recurrent” tracheoesophageal fistula may represent a missed upper pouch fistula or a true recurrence. This may occur after an anastomotic disruption, during which the recurrent fis-tula may heal spontaneously. Otherwise, reoperation may be required. Recently, the use of fibrin glue has been successful in treating recurrent fistulas, although long-term follow-up is lacking.Gastroesophageal reflux commonly occurs after repair of EA-TEF, potentially due to alterations in esophageal motility and the anatomy of the gastroesophageal junction. The clinical manifestations of such reflux are similar to those seen in other infants with primary gastroesophageal reflux disease (GERD). A loose antireflux procedure, such as a Nissen fundoplication, is used to prevent further reflux, but the child may have feed-ing problems after antireflux surgery as a result of the intrinsic dysmotility of the distal esophagus. The fundoplication may be safely performed laparoscopically in experienced hands, although care should be taken to ensure that the wrap is not excessively tight.Special Circumstances. Patients with type E tracheoesoph-ageal fistulas (also called H-type) most commonly present beyond the newborn period. Presenting symptoms include recurrent chest infections, bronchospasm, and failure to thrive. The diagnosis is suspected using barium esophagography and confirmed by endoscopic visualization of the fistula. Surgical correction is generally possible through a cervical approach with concurrent placement of a balloon catheter across the fis-tula and requires mobilization and division of the fistula. Out-come is usually excellent.Patients with duodenal atresia and EA-TEF may require urgent treatment due to the presence of a closed obstruction of the stomach and proximal duodenum. In stable patients, treat-ment consists of repair of the esophageal anomaly and correc-tion of the duodenal atresia if the infant is stable during surgery. If not, a staged approach should be utilized consisting of ligation of the fistula and placement of a gastrostomy tube. Definitive repair can then be performed at a later point in time.Primary esophageal atresia (type A) represents a chal-lenging problem, particularly if the upper and lower ends are too far apart for an anastomosis to be created. Under these Brunicardi_Ch39_p1705-p1758.indd 172012/02/19 11:26 AM 1721PEDIATRIC SURGERYCHAPTER 39circumstances, treatment strategies include placement of a gas-trostomy tube and performing serial bougienage to increase the length of the upper pouch. This occasionally allows for primary anastomosis to be performed. Occasionally, when the two ends cannot be brought safely together, esophageal replacement is required using either a gastric pull-up or colon interposition (see the following section).Outcome. Various classification systems have been utilized to predict survival in patients with EA-TEF and to stratify treat-ment. A system devised by Waterston in 1962 was used to strat-ify neonates based on birth weight, the presence of pneumonia, and the identification of other congenital anomalies. In response to advances in neonatal care, the surgeons from the Montreal Children’s Hospital proposed a new classification system in 1993. In the Montreal experience only two characteristics inde-pendently affected survival: preoperative ventilator dependence and associated major anomalies. Pulmonary disease as defined by ventilator dependence appeared to be more accurate than pneumonia. When the two systems were compared, the Montreal system more accurately identified children at highest risk. Spitz and colleagues analyzed risk factors in infants who died with EA-TEF. Two criteria were found to be important predictors of outcome: birth weight less than 1500 g and the presence of major congenital cardiac disease. A new classification for predicting outcome in esophageal atresia was therefore proposed: group I: birth weight ≥1500 g, without major cardiac disease, survival 97% (283 of 293); group II: birth weight <1500 g, or major car-diac disease, survival 59% (41 of 70); and group III: birth weight <1500 g, and major cardiac disease, survival 22% (2 of 9).In general, surgical correction of EA-TEF leads to a sat-isfactory outcome with nearly normal esophageal function in most patients. Overall survival rates of greater than 90% have been achieved in patients classified as stable, in all the various staging systems. Unstable infants have an increased mortality (40–60% survival) because of potentially fatal associated cardiac and chromosomal anomalies or prematurity. However, the use of a staged procedure also has increased survival in even these high-risk infants.Corrosive Injury of the EsophagusInjury to the esophagus after ingestion of corrosive substances most commonly occurs in the toddler age group. Both strong alkali and strong acids produce injury by liquefaction or coag-ulation necrosis, and since all corrosive agents are extremely hygroscopic, the caustic substance will cling to the esophageal epithelium. Subsequent strictures occur at the anatomic nar-rowed areas of the esophagus, cricopharyngeus, midesophagus, and gastroesophageal junction. A child who has swallowed an injurious substance may be symptom-free but usually will be drooling and unable to swallow saliva. The injury may be restricted to the oropharynx and esophagus, or it may extend to include the stomach. There is no effective immediate anti-dote. Diagnosis is by careful physical examination of the mouth and endoscopy with a flexible or a rigid esophagoscope. It is important to endoscope only to the first level of the burn in order to avoid perforation. Early barium swallow may delineate the extent of the mucosal injury. It is important to realize that the esophagus may be burned without evidence of injury to the mouth. Although previously used routinely, steroids have not been shown to alter stricture development or modify the extent of injury and are no longer part of the management of caustic injuries. Antibiotics are administered during the acute period.The extent of injury is graded endoscopically as either mild, moderate, or severe (grade I, II, or III). Circumferential esophageal injuries with necrosis have an extremely high like-lihood of stricture formation. These patients should undergo placement of a gastrostomy tube once clinically stable. A string should be inserted through the esophagus either immediately or during repeat esophagoscopy several weeks later. When estab-lished strictures are present (usually 3 to 4 weeks), dilatation is performed. Fluoroscopically guided balloon dilation of the stric-ture is effective, which should be performed in association with esophagoscopy, and allows for a precise evaluation of the nature and extent of the stenosis. The procedure should be performed under general anesthesia, and care must be taken to ensure there is no airway injury. Dislodgment of the endotracheal tube can occur during this procedure, and careful communication with the anesthesiologist is critical during the procedure.In certain circumstances, especially if a gastrostomy tube has been placed, retrograde dilatation may be performed, using graduated dilators brought through the gastrostomy and advanced into the esophagus via the transesophageal string. Management of esophageal perforation during dilation should include antibiotics, irrigation, and closed drainage of the tho-racic cavity to prevent systemic sepsis. When recognition is delayed or if the patient is systemically ill, esophageal diver-sion may be required with staged reconstruction at a later time.Although the native esophagus can be preserved in most cases, severe stricture formation that does not respond to dila-tion is best managed by esophageal replacement. The most com-monly used options for esophageal substitution are the colon (right colon or transverse/left colon) and the stomach (gastric tubes or gastric pull-up). Pedicled or free grafts of the jejunum are rarely used. The right colon is based on a pedicle of the middle colic artery, and the left colon is based on a pedicle of the middle colic or left colic artery. Gastric tubes are fashioned from the greater curvature of the stomach based on the pedi-cle of the left gastroepiploic artery. When the entire stomach is used, as in gastric pull-up, the blood supply is provided by the right gastric artery. The neoesophagus may traverse (a) sub-sternally; (b) through a transthoracic route; or (c) through the posterior mediastinum to reach the neck. A feeding jejunostomy is placed at the time of surgery and tube feedings are instituted once the postoperative ileus has resolved. Long-term follow-up has shown that all methods of esophageal substitution can sup-port normal growth and development, and the children enjoy reasonably normal eating habits. Because of the potential for late complications such as ulceration and stricture, follow-up into adulthood is mandatory, but complications appear to dimin-ish with time.Gastroesophageal RefluxGastroesophageal reflux (GER) occurs to some degree in all children and refers to the passage of gastric contents into the esophagus. By contrast, gastroesophageal reflux disease (GERD) describes the situation where reflux is symptomatic. Typical symptoms include failure to thrive, bleeding, stricture formation, reactive airway disease, aspiration pneumonia, or apnea. Failure to thrive and pulmonary problems are particularly common in infants with GERD, whereas strictures and esopha-gitis are more common in older children and adolescents. GERD is particularly problematic in neurologically impaired children.Clinical Manifestations. Because all infants experience occasional episodes of GER to some degree, care must be taken Brunicardi_Ch39_p1705-p1758.indd 172112/02/19 11:26 AM 1722SPECIFIC CONSIDERATIONSPART IIbefore a child is labeled as having pathologic reflux. A history of repeated episodes of vomiting that interferes with growth and development, or the presence of apparent life-threatening events, are required for the diagnosis of GERD. In older chil-dren, esophageal bleeding, stricture formation, severe heartburn, or the development of Barrett’s esophagus unequivocally con-note pathologic reflux or GERD. In neurologically impaired children, vomiting due to GER must be distinguished from chronic retching.The workup of patients suspected of having GERD includes documentation of the episodes of reflux and evalua-tion of the anatomy. A barium swallow should be performed as an initial test. This will determine whether there is obstruction of the stomach or duodenum (due to duodenal webs or pyloric stenosis) and will determine whether malrotation is present. The frequency and severity of reflux should be assessed using a 24-hour pH probe study. Although this test is poorly tolerated, it provides the most accurate determination that GERD is present. Esophageal endoscopy with biopsies may identify the presence of esophagitis, and it is useful to determine the length of intra-abdominal esophagus and the presence of Barrett’s esophagus. Some surgeons obtain a radioisotope “milk scan” to evaluate gastric emptying, although there is little evidence to show that this test changes management when a diagnosis of GERD has been confirmed using the aforementioned modalities.Treatment. Most patients with GERD are treated initially by conservative means. In the infant, propping and thickening the formula with rice cereal are generally recommended. Some authors prefer a prone, head-up position. In the infant unrespon-sive to position and formula changes and the older child with severe GERD, medical therapy is based on gastric acid reduc-tion with an H2-blocking agent and/or a proton pump inhibitor. Medical therapy is successful in most neurologically normal infants and younger children, many of whom will outgrow their need for medications. In certain patients, however, medical treatment does not provide symptomatic relief and surgery is therefore indicated. The least invasive surgical option includes the placement of a nasojejunal or gastrojejunal feeding tube. Because the stomach is bypassed, food contents do not enter the esophagus, and symptoms are often improved. However, as a long-term remedy, this therapy is associated with several problems. The tubes often become dislodged, acid reflux still occurs, and bolus feeding is generally not possible. Fundoplica-tion provides definitive treatment for gastroesophageal reflux and is highly effective in most circumstances. The fundus may be wrapped around the distal esophagus either 360o (i.e., Nissen) or to lesser degrees (i.e., Thal or Toupet). At present, the stan-dard approach in most children is to perform these procedures laparoscopically whenever possible. In children with feeding difficulties and in infants under 1 year of age, a gastrostomy tube should be placed at the time of surgery. Early postoperative complications include pneumonia and atelectasis, often due to inadequate pulmonary toilet and pain control with abdominal splinting. Late postoperative complications include wrap break-down with recurrent reflux, which may require repeat fundo-plication, and dysphagia due to a wrap performed too tightly, which generally responds to dilation. These complications are more common in children with neurologic impairment. The keys to successful surgical management of patients with GERD include careful patient selection and meticulous operative tech-nique. There are emerging concerns regarding the long-term use of acid reducing agents, which may increase the frequency with which antireflux procedures are performed in children, espe-cially those with neurological impairment.GASTROINTESTINAL TRACTAn Approach to the Vomiting InfantAll infants vomit. Because infant vomiting is so common, it is important to differentiate between normal and abnormal vomit-ing, which may be indicative of a potentially serious underlying disorder. In order to determine the seriousness of a particular infant’s bouts of emesis, one needs to characterize what the vomit looks like and how sick the baby is. Vomit that looks like feeds and comes up immediately after a feeding is almost always gastroesophageal reflux. This may or may not be of concern, as described earlier. Vomiting that occurs a short while after feed-ing, or vomiting that projects out of the baby’s mouth may be indicative of pyloric stenosis. By contrast, vomit that has any green color in it is always worrisome. This may be reflective of intestinal volvulus, an underlying infection, or some other cause of intestinal obstruction. A more detailed description of the management of these conditions is provided in the follow-ing sections.Hypertrophic Pyloric StenosisClinical Presentation. Infants with hypertrophic pyloric stenosis (HPS) typically present with nonbilious vomiting that becomes increasingly projectile, over the course of several days to weeks due to progressive thickening of the pylorus muscle. HPS occurs in approximately 1 in 300 live births and commonly in infants between 3 and 6 weeks of age. Male-to-female ratio is nearly 5:1.Eventually as the pyloric muscle thickening progresses, the infant develops a complete gastric outlet obstruction and is no longer able to tolerate any feeds. Over time, the infant becomes increasingly hungry, unsuccessfully feeds repeatedly, and becomes increasingly dehydrated. Wet diapers become less frequent, and there may even be a perception of less passage of flatus. HPS may be associated with jaundice due to an indi-rect hyperbilirubinemia, although the nature of this relation is unclear.The cause of HPS has not been determined. Studies have shown that HPS is found in several generations of the same family, suggesting a familial link. Recently, a genome-wide sig-nificant locus for pyloric stenosis at chromosome 11q23.3 was identified, and the single-nucleotide polymorphism (SNP) with the greatest significance was associated with part of the genome that regulates cholesterol. It is not clear how this links to the development of pyloric stenosis, but it does suggest a potential dietary link.Infants with HPS develop a hypochloremic, hypokale-mic metabolic alkalosis. The urine pH level is high initially, but eventually drops because hydrogen ions are preferentially exchanged for sodium ions in the distal tubule of the kidney as the hypochloremia becomes severe (paradoxical aciduria). While in the past the diagnosis of pyloric stenosis was most often made on physical examination by palpation of the typical “olive” in the right upper quadrant and the presence of visible gastric waves on the abdomen, current standard of care is to perform an US, which can diagnose the condition accurately in 95% of patients. Criteria for US diagnosis include a channel length of over 16 mm and pyloric thickness over 4 mm. It is important to note that younger babies may have lower values Brunicardi_Ch39_p1705-p1758.indd 172212/02/19 11:26 AM 1723PEDIATRIC SURGERYCHAPTER 39Pyloric “tumor”MucosaABCFigure 39-12. Fredet-Ramstedt pyloromyotomy. A. Pylorus deliv-ered into wound and seromuscular layer incised. B. Seromuscular layer separated down to submucosal base to permit herniation of mucosa through pyloric incision. C. Cross-section demonstrating hypertrophied pylorus, depth of incision, and spreading of muscle to permit mucosa to herniate through incision.for pyloric thickness and still be abnormal, and a close clinical correlation with the US result is mandatory. In cases in which the diagnosis remains unclear, upper gastrointestinal evaluation by contrast radiography will reveal delayed passage of contents from the stomach through the pyloric channel and a typical thickened appearance to the pylorus.Treatment. Given frequent fluid and electrolyte abnormali-ties at time of presentation, pyloric stenosis is never a surgical emergency. Fluid resuscitation with correction of electrolyte abnormalities and metabolic alkalosis is essential prior to induc-tion of general anesthesia for operation. For most infants, fluid containing 5% dextrose and 0.45% saline with added potassium of 2 to 4 mEq/kg over 24 hours at a rate of approximately 150 to 175 mL/kg for 24 hours will correct the underlying deficit. It is important to ensure that the child has an adequate urine output (>2 cc/kg per hour) as further evidence that rehydration has occurred.After resuscitation, a Fredet-Ramstedt pyloromyotomy is performed (Fig. 39-12). It may be performed using an open or laparoscopic approach. The open pyloromyotomy is per-formed through either an umbilical or a right upper quadrant transverse abdominal incision. The former route is cosmetically more appealing, although the transverse incision provides easier access to the antrum and pylorus. In recent years, the laparo-scopic approach has gained great popularity. Two randomized trials have demonstrated that both the open and laparoscopic approaches may be performed safely with equal incidence of postoperative complications, although the cosmetic result is clearly superior with the laparoscopic approach. Whether done through an open or laparoscopic approach, surgical treatment of pyloric stenosis involves splitting the pyloric muscle while leav-ing the underlying submucosa intact. The incision extends from just proximal to the pyloric vein of Mayo to the gastric antrum; it typically measures between 1 and 2 cm in length. Postop-eratively, IV fluids are continued for several hours, after which Pedialyte is offered, followed by formula or breast milk, which is gradually increased to 60 cc every 3 hours. Most infants can be discharged home within 24 to 48 hours following surgery. Recently, several authors have shown that ad lib feeds are safely tolerated by the neonate and result in a shorter hospital stay.The complications of pyloromyotomy include perforation of the mucosa (1–3%), bleeding, wound infection, and recur-rent symptoms due to inadequate myotomy. When perforation occurs, the mucosa is repaired with a stitch that is placed to tack the mucosa down and reapproximate the serosa in the region of the tear. A nasogastric tube is left in place for 24 hours. The outcome is generally very good.Intestinal Obstruction in the NewbornThe cardinal symptom of intestinal obstruction in the newborn is bilious emesis. Prompt recognition and treatment of neonatal intestinal obstruction can truly be lifesaving.The incidence of neonatal intestinal obstruction is 1 in 2000 live births. The approach to intestinal obstruction in the newborn infant is critical for timely and appropriate interven-tion. When a neonate develops bilious vomiting, one must con-sider a surgical etiology. Indeed, the majority of newborns with bilious emesis have a surgical condition. In evaluating a poten-tial intestinal obstruction, it is helpful to determine whether the intestinal obstruction is either proximal or distal to the ligament of Treitz. One must conduct a detailed prenatal and immediate postnatal history and a thorough physical examination. In all cases of intestinal obstruction, it is vital to obtain abdominal films in the supine and upright (or lateral decubitus) views to assess the presence of air-fluid levels or free air as well as how far downstream air has managed to travel. Importantly, one should recognize that it is difficult to determine whether a loop of bowel is part of either the small or large intestine, as neonatal bowel lacks clear features, such as haustra or plica circulares, normally present in older children or adults. As such, contrast imaging may be necessary for diagnosis in some instances.Proximal intestinal obstructions typically present with bil-ious emesis and minimal abdominal distention. The normal neo-nate should have a rounded, soft abdomen; in contrast, a neonate with a proximal intestinal obstruction typically exhibits a flat or scaphoid abdomen. On a series of upright and supine abdominal radiographs, one may see a paucity or absence of bowel gas, which normally should be present throughout the gastrointesti-nal tract within 24 hours. Of utmost importance is the exclusion of a malrotation with midgut volvulus from all other intestinal obstructions as this is a surgical emergency.Distal obstructions typically present with bilious emesis and abdominal distention. Passage of black-green meconium should have occurred within the first 24 to 38 hours. Of great 34Brunicardi_Ch39_p1705-p1758.indd 172312/02/19 11:26 AM 1724SPECIFIC CONSIDERATIONSPART IIFigure 39-13. Abdominal X-ray showing “double bubble” sign in a newborn infant with duodenal atresia. The two “bubbles” are numbered.importance, one should determine whether there is tenderness or discoloration of the abdomen, visible or palpable loops of intestine, presence or absence of a mass, and whether the anus is patent and in appropriate location. Abdominal radiographs may demonstrate calcifications may indicate complicated meconium ileus; pneumatosis and/or pneumoperitoneum may indicate necrotizing enterocolitis. A contrast enema may show whether there is a microcolon indicative of jejunoileal atresia or meconium ileus. If a microcolon is not present, then the diag-noses of Hirschsprung’s disease, small left colon syndrome, or meconium plug syndrome should be considered.Duodenal ObstructionWhenever the diagnosis of duodenal obstruction is entertained, malrotation and midgut volvulus must be excluded. This topic is covered in further detail later in this chapter. Other causes of duodenal obstruction include duodenal atresia, duodenal web, stenosis, annular pancreas, or duodenal duplication cyst. Duode-nal obstruction is easily diagnosed on prenatal US, which dem-onstrates the fluid-filled stomach and proximal duodenum as two discrete cystic structures in the upper abdomen. Associated polyhydramnios is common and presents in the third trimester. In 85% of infants with duodenal obstruction, the entry of the bile duct is proximal to the level of obstruction, such that vom-iting is bilious. Abdominal distention is typically not present because of the proximal level of obstruction. In those infants with obstruction proximal to the bile duct entry, the vomiting is nonbilious. The classic finding on abdominal radiography is the “double bubble” sign, which represents the dilated stomach and duodenum (Fig. 39-13). In association with the appropriate clin-ical picture, this finding is sufficient to confirm the diagnosis of duodenal obstruction. However, if there is any uncertainty, particularly when a partial obstruction is suspected, a contrast upper gastrointestinal series is diagnostic.Treatment. An orogastric tube is inserted to decompress the stomach and duodenum and the infant is given IV fluids to maintain adequate urine output. If the infant appears ill, or if abdominal tenderness is present, a diagnosis of malrotation and midgut volvulus should be considered, and surgery should not be delayed. Typically, the abdomen is soft, and the infant is very stable. Under these circumstances, the infant should be evaluated thoroughly for other associated anomalies. Approxi-mately one-third of newborns with duodenal atresia have asso-ciated Down syndrome (trisomy 21). These patients should be evaluated for associated cardiac anomalies. Once the workup is complete and the infant is stable, he or she is taken to the operat-ing room, and repair is performed either via an open approach or laparoscopically.Regardless of the surgical approach, the principles are the same. If open, the abdomen is entered through a transverse right upper quadrant supraumbilical incision under general endotra-cheal anesthesia. Associated anomalies should be searched for at the time of the operation. These include malrotation, ante-rior portal vein, a second distal web, and biliary atresia. The surgical treatment of choice for duodenal obstruction due to duodenal stenosis or atresia or annular pancreas is a duodeno-duodenostomy. This procedure can be most easily performed using a proximal transverse-to-distal longitudinal (diamond-shaped) anastomosis. In cases where the duodenum is extremely dilated, the lumen may be tapered using a linear stapler with a large Foley catheter (24F or greater) in the duodenal lumen. It is important to emphasize that an annular pancreas is never divided but rather is bypassed to avoid injury to the pancreatic ducts. Treatment of duodenal web includes vertical duodenot-omy, excision of the web, oversewing of the mucosa, and clos-ing the duodenotomy horizontally. Care must be taken to avoid injury to the bile duct, which opens up near the web in all cases. For this reason, some surgeons favor performing a duodeno-duodenostomy for children with duodenal web, although such an approach may lead to long-term complications associated with the creation of a blind section of duodenum between the web and the bypass, which can expand over time. Gastrostomy tube placement is not routinely performed. Recently reported survival rates exceed 90%. Late complications from repair of duodenal atresia occur in approximately 12% to 15% of patients and include megaduodenum, intestinal motility disorders, and gastroesophageal reflux.Specific consideration may be given to premature infants with duodenal obstruction. Whereas in the past pediatric sur-geons may have favored delayed repair until the child reached either term or a weight closer to 3 kg, there is no reason to wait, and once the child is stable from a pulmonary perspective, duo-denal repair can be performed in children as small as 1 kg quite safely, as long as there is meticulous attention to detail and a thorough knowledge of the anatomy.Intestinal AtresiaObstruction due to intestinal atresia can occur at any point along the intestinal tract. Intestinal atresias were previously thought to be the result of in utero mesenteric vascular accidents leading to segmental loss of the intestinal lumen, although more likely they are the result of developmental defects in normal intestinal organogenesis due to disruption of various signaling pathways such as fibroblast growth factor, bone morphogenic protein, and β-catenin pathways. The incidence of intestinal atresia has been estimated to be between 1 in 2000 to 1 in 5000 live births, with equal representation of the sexes. Infants with jejunal or ileal atresia present with bilious vomiting and progressive abdominal distention. The more distal the obstruction, the more distended the abdomen becomes, and the greater the number of obstructed loops on upright abdominal films (Fig. 39-14).In cases where the diagnosis of complete intestinal obstruction is ascertained by the clinical picture and the pres-ence of staggered air-fluid levels on plain abdominal films, the child can be brought to the operating room after appropriate resuscitation. In these circumstances, there is little extra infor-mation to be gained by performing a barium enema. By contrast, Brunicardi_Ch39_p1705-p1758.indd 172412/02/19 11:26 AM 1725PEDIATRIC SURGERYCHAPTER 39Figure 39-14. Intestinal obstruction in the newborn showing sev-eral loops of distended bowel with air fluid levels. This child has jejunal atresia.Figure 39-15. Operative photograph of newborn with “Christmas tree” type of ileal atresia.when there is diagnostic uncertainty, or when distal intestinal obstruction is apparent, a barium enema is useful to establish whether a microcolon is present and to diagnose the presence of meconium plugs, small left colon syndrome, Hirschsprung’s disease, or meconium ileus. Judicious use of barium enema is therefore required in order to safely manage neonatal intestinal obstruction, based on an understanding of the expected level of obstruction.Surgical correction of the small intestinal atresia should be performed relatively urgently, especially when there is a possibility of volvulus. At laparotomy, one of several types of atresia will be encountered. In type 1 there is a mucosal atre-sia with intact muscularis. In type 2, the atretric ends are con-nected by a fibrous band. In type 3A, the two ends of the atresia are separated by a V-shaped defect in the mesentery. Type 3B is an “apple-peel” deformity or “Christmas tree” deformity in which the bowel distal to the atresia receives its blood supply in a retrograde fashion from the ileocolic or right colic artery (Fig. 39-15). In type 4 atresia, there are multiple atresias with a “string of sausage” or “string of beads” appearance. Disparity in lumen size between the proximal distended bowel and the small diameter of collapsed bowel distal to the atresia has led to a num-ber of innovative techniques of anastomosis. However, under most circumstances, an anastomosis can be performed using the end-to-back technique in which the distal, compressed loop is “fish-mouthed” along its antimesenteric border. The proximal distended loop can be tapered as previously described. Because the distended proximal bowel rarely has normal motility, the extremely dilated portion should be resected prior to per-forming the anastomosis.Occasionally the infant with intestinal atresia will develop ischemia or necrosis of the proximal segment secondary to volvulus of the dilated, bulbous, blind-ending proximal bowel. Under these conditions, primary anastomosis may be performed as described earlier. Alternatively, an end ileostomy and mucus fistula should be created, and the anastomosis should be deferred to another time after the infant stabilizes.Malrotation and Midgut VolvulusEmbryology. During the sixth week of fetal development, the midgut grows too rapidly to be accommodated in the abdominal cavity and therefore herniates into the umbilical cord. Between the 10th and 12th week, the midgut returns to the abdominal cavity, undergoing a 270° counterclockwise rotation around the superior mesenteric artery. Because the duodenum also rotates caudal to the artery, it acquires a C-loop, which traces this path. The cecum rotates cephalad to the artery, which determines the location of the transverse and ascending colon. Subsequently, the duodenum becomes fixed retroperitoneally in its third por-tion and at the ligament of Treitz, while the cecum becomes fixed to the lateral abdominal wall by peritoneal bands. The takeoff of the branches of the superior mesenteric artery elon-gates and becomes fixed along a line extending from its emer-gence from the aorta to the cecum in the right lower quadrant. Genetic mutations likely disrupt the signaling critical for normal intestinal rotation. For instance, mutations in the gene BCL6 resulting in absence of left-sided expression of its transcript lead to reversed cardiac orientation, defective ocular development, and malrotation. The essential role of the dorsal gut mesentery in mediating normal intestinal rotation and the role of the fork-head box transcription factor FOXF1 in formation of the dorsal mesentery in mice are consistent with the noted association of intestinal malrotation with alveolar capillary dysplasia, caused by mutations in FOXF1. If rotation is incomplete, the cecum remains in the epigastrium, but the bands fixing the duode-num to the retroperitoneum and cecum continue to form. This results in (Ladd’s) bands extending from the cecum to the lat-eral abdominal wall and crossing the duodenum, which creates the potential for obstruction. The mesenteric takeoff remains confined to the epigastrium, resulting in a narrow pedicle sus-pending all the branches of the superior mesenteric artery and the entire midgut. A volvulus may therefore occur around the mesentery. This twist not only obstructs the proximal jejunum but also cuts off the blood supply to the midgut. Intestinal obstruction and complete infarction of the midgut occur unless the problem is promptly corrected surgically.Presentation and Management. Midgut volvulus can occur at any age, though it is seen most often in the first few weeks of life. Bilious vomiting is usually the first sign of volvulus and all infants with bilious vomiting must be evaluated rapidly to ensure that they do not have intestinal malrotation with volvu-lus. The child with irritability and bilious emesis should raise particular suspicions for this diagnosis. If left untreated, vascular Brunicardi_Ch39_p1705-p1758.indd 172512/02/19 11:26 AM 1726SPECIFIC CONSIDERATIONSPART IIFigure 39-16. Abdominal X-ray of a 10-day-old infant with bil-ious emesis. Note the dilated proximal bowel and the paucity of distal bowel gas, characteristic of a volvulus.compromise of the midgut initially causes bloody stools, but it eventually results in circulatory collapse. Additional clues to the presence of advanced ischemia of the intestine include ery-thema and edema of the abdominal wall, which progresses to shock and death. It must be reemphasized that the index of sus-picion for this condition must be high, since abdominal signs are minimal in the early stages. Abdominal films show a paucity of gas throughout the intestine with a few scattered air-fluid levels (Fig. 39-16). When these findings are present, the patient should undergo immediate fluid resuscitation to ensure adequate per-fusion and urine output followed by prompt exploratory lapa-rotomy. In cases where the child is stable, laparoscopy may be considered.Often the patient will not appear ill, and the plain films may suggest partial duodenal obstruction. Under these condi-tions, the patient may have malrotation without volvulus. This is best diagnosed by an upper gastrointestinal series that shows incomplete rotation with the duodenojejunal junction displaced to the right. The duodenum may show a corkscrew effect diag-nosing volvulus, or complete duodenal obstruction, with the small bowel loops entirely in the right side of the abdomen. Barium enema may show a displaced cecum, but this sign is unreliable, especially in the small infant in whom the cecum is normally in a somewhat higher position than in the older child.When volvulus is suspected, early surgical intervention is mandatory if the ischemic process is to be avoided or reversed. Volvulus occurs clockwise, and it is therefore untwisted coun-terclockwise. This can be remembered using the memory aid “turn back the hands of time.” Subsequently, a Ladd’s proce-dure is performed. This operation does not correct the malro-tation, but it does broaden the narrow mesenteric pedicle to prevent volvulus from recurring. This procedure is performed as follows (Fig. 39-17). The bands between the cecum and the abdominal wall and between the duodenum and terminal ileum are divided sharply to splay out the superior mesenteric artery and its branches. This maneuver brings the straightened duodenum into the right lower quadrant and the cecum into the left lower quadrant. The appendix is usually removed to avoid diagnostic errors in later life. No attempt is made to suture the cecum or duodenum in place. With advanced ischemia, reduc-tion of the volvulus without the Ladd’s procedure is accom-plished, and a “second look” 24 to 36 hours later often may show some vascular recovery. A plastic transparent silo may be placed to facilitate constant evaluation of the intestine and to plan for the timing of reexploration. Clearly necrotic bowel can then be resected conservatively. With early diagnosis and cor-rection, the prognosis is excellent. However, diagnostic delay can lead to mortality or to short-gut syndrome requiring intes-tinal transplantation.A subset of patients with malrotation will demonstrate chronic obstructive symptoms. These symptoms may result from Ladd’s bands across the duodenum, or occasionally, from intermittent volvulus. Symptoms include intermittent abdominal pain and intermittent vomiting that may occasionally be bilious. Infants with malrotation may demonstrate failure to thrive, and they may be diagnosed initially as having gastroesophageal reflux disease. Surgical correction using Ladd’s procedure as described earlier can prevent volvulus from occurring and improve symp-toms in many instances. In these cases, a laparoscopic approach may be taken, where diagnosis of Ladd’s bands and direct visu-alization of the relevant anatomy may be achieved.Meconium IleusPathogenesis and Clinical Presentation. Infants with cystic fibrosis have characteristic pancreatic enzyme deficiencies and abnormal chloride secretion in the intestine that result in the production of viscous, water-poor meconium. This phenotype is explained by the presence of mutations in the CFTR gene. Meconium ileus occurs when this thick, highly viscous meco-nium becomes impacted in the ileum and leads to high-grade intestinal obstruction. Recently, additional mutations were identified in genes encoding multiple apical plasma membrane proteins of infants with meconium ileus. Meconium ileus can be either uncomplicated, in which there is no intestinal perforation, or complicated, in which prenatal perforation of the intestine has occurred or vascular compromise of the distended ileum devel-ops. Antenatal US may reveal the presence of intra-abdominal or scrotal calcifications, or distended bowel loops. These infants present shortly after birth with progressive abdominal disten-tion and failure to pass meconium with intermittent bilious emesis. Abdominal radiographs show dilated loops of intestine. Because the enteric contents are so viscous, air-fluid levels do not form, even when obstruction is complete. Small bubbles of gas become entrapped in the inspissated meconium in the dis-tal ileum, where they produce a characteristic “ground glass” appearance.The diagnosis of meconium ileus is confirmed by a con-trast enema that typically demonstrates a microcolon. In patients with uncomplicated meconium ileus, the terminal ileum is filled with pellets of meconium. In patients with complicated meco-nium ileus, intraperitoneal calcifications form, producing an eggshell pattern on plain abdominal X-ray.Management. The treatment strategy depends on whether the patient has complicated or uncomplicated meconium ileus. Patients with uncomplicated meconium ileus can be Brunicardi_Ch39_p1705-p1758.indd 172612/02/19 11:26 AM 1727PEDIATRIC SURGERYCHAPTER 39Figure 39-17. Ladd procedure for malrotation. A. Lysis of cecal and duodenal bands. B. Broadening the mesentery. C. Appendectomy.treated nonoperatively. Either dilute water-soluble contrast or N-acetylcysteine (Mucomyst) is infused transanally via catheter under fluoroscopic control into the dilated portion of the ileum. Because these agents act by absorbing fluid from the bowel wall into the intestinal lumen, infants undergoing treatment are at risk of fluid and electrolyte abnormalities so that appropriate resuscitation of the infant during this maneuver is extremely important. The enema may be repeated at 12-hour intervals over several days until all the meconium is evacuated. Inability to reflux the contrast into the dilated portion of the ileum signi-fies the presence of an associated atresia or complicated meco-nium ilus, and thus warrants exploratory laparotomy. If surgical intervention is required because of failure of contrast enemas to relieve obstruction, operative irrigation with dilute contrast agent, N-acetylcysteine, or saline through a purse-string suture may be successful. Alternatively, resection of the distended ter-minal ileum is performed, and the meconium pellets are flushed from the distal small bowel. At this point, an end ileostomy may be created. The distal bowel may be brought up as a mucus fistula or sewn to the side of the ileum as a classic Bishop-Koop anastomosis. An end-to-end anastomosis may also be consid-ered in the appropriate setting (Fig. 39-18).Necrotizing EnterocolitisClinical Features. Necrotizing enterocolitis (NEC) is the most frequent and lethal gastrointestinal disorder affecting the intestine of the stressed, preterm neonate. The overall mortal-ity ranges between 10% and 50%. Advances in neonatal care such as surfactant therapy as well as improved methods of mechanical ventilation have resulted in increasing numbers of Brunicardi_Ch39_p1705-p1758.indd 172712/02/19 11:26 AM 1728SPECIFIC CONSIDERATIONSPART IIProximalDistalABCDProximalDistalProximalDistalProximalDistalDistalProximalTypical operative findingEnd to backThomas taperBishop-Koop with distal ventMikulicz enterostomyFigure 39-18. Techniques of intestinal anastomosis for infants with small bowel obstruction. A. End-to-back distal limb has been incised, creating “fishmouth” to enlarge the lumen. B. Bishop-Koop; proximal distended limb joined to side of distal small bowel, which is vented by “chimney” to the abdominal wall. C. Tapering; portion of antimesenteric wall of proximal bowel excised, with longitudinal closure to minimize disparity in the limbs. D. Mikulicz double-barreled enterostomy is constructed by suturing the two limbs together and then exte-riorizing the double stoma. The common wall can be crushed with a special clamp to create a large stoma. The stoma can be closed in an extraperitoneal manner.low-birth-weight infants surviving neonatal hyaline membrane disease. An increasing proportion of survivors of neonatal respi-ratory distress syndrome will therefore be at risk for developing NEC. Consequently, it is estimated that NEC may eventually surpass respiratory distress syndrome as the principal cause of death in the preterm infant. This is especially relevant, as NEC is a significant risk factor for more severe respiratory distress in premature infants.Multiple risk factors have been associated with the devel-opment of NEC. These include prematurity, initiation of enteral feeding, bacterial infection, intestinal ischemia resulting from birth asphyxia, umbilical artery cannulation, persistence of a patent ductus arteriosus, cyanotic heart disease, and maternal cocaine abuse. Nonetheless, the mechanisms by which these complex interacting etiologies lead to the development of the disease remain undefined. The only consistent epidemio-logic precursors for NEC are prematurity and enteral ali-mentation, representing the commonly encountered clinical situation of a stressed infant who is fed enterally. Of note, there is some debate regarding the type and strategy of enteral alimen-tation in the pathogenesis of NEC. A prospective randomized 5study showed no increase in the incidence of NEC despite an aggressive feeding strategy.The indigenous intestinal microbial flora has been shown to play a central role in the pathogenesis of NEC. The importance of bacteria in the pathogenesis of NEC is further supported by the finding that NEC occurs in episodic waves that can be abrogated by infection control measures, and the fact that NEC usually develops at least 10 days postnatally, when the GI tract is colonized by coliforms. More recently, outbreaks of NEC have been reported in infants fed formula contaminated with Enterobacter sakazakii. Common bacterial isolates from the blood, peritoneal fluid, and stool of infants with advanced NEC include Escherichia coli, Enterobacter, Klebsiella, and occasionally, coagulase-negative Staphylococ-cus species.NEC may involve single or multiple segments of the intes-tine, most commonly the terminal ileum, followed by the colon. The gross findings in NEC include bowel distention with patchy areas of thinning, pneumatosis, gangrene, or frank perforation. The microscopic features include the appearance of a “bland infarct” characterized by full thickness necrosis.Brunicardi_Ch39_p1705-p1758.indd 172812/02/19 11:26 AM 1729PEDIATRIC SURGERYCHAPTER 39Figure 39-19. Abdominal radiograph of infant with necrotizing enterocolitis. Arrows point to area of pneumatosis intestinalis.Clinical Manifestations. Infants with NEC present with a spectrum of disease. In general, the infants are premature and may have sustained one or more episodes of stress, such as birth asphyxia, or they may have congenital cardiac disease. The clin-ical picture of NEC has been characterized as progressing from a period of mild illness to that of severe, life-threatening sepsis by Bell and colleagues. Although not all infants progress through the various “Bell stages,” this classification scheme provides a useful format to describe the clinical picture associated with the development of NEC. In the earliest stage (Bell stage I), infants present with feeding intolerance. This is suggested by vomiting or by the presence of a large residual volume from a previous feeding in the stomach at the time of the next feed-ing. Following appropriate treatment, which consists of bowel rest and IV antibiotics, many of these infants will not progress to more advanced stages of NEC. These infants are colloqui-ally described as suffering from an “NEC scare” and represent a population of neonates who are at risk of developing more severe NEC if a more prolonged period of stress supervenes.Infants with Bell stage II have established NEC that is not immediately life-threatening. Clinical findings include abdomi-nal distention and tenderness, bilious nasogastric aspirate, and bloody stools. These findings indicate the development of intestinal ileus and mucosal ischemia, respectively. Abdominal examination may reveal a palpable mass indicating the pres-ence of an inflamed loop of bowel, diffuse abdominal tender-ness, cellulitis, and edema of the anterior abdominal wall. The infant may appear systemically ill, with decreased urine output, hypotension, tachycardia, and noncardiac pulmonary edema. Hematologic evaluation reveals either leukocytosis or leukope-nia, an increase in the number of bands, and thrombocytopenia. An increase in the blood urea nitrogen and plasma creatinine level may be found, which signify the development of renal dys-function. The diagnosis of NEC may be confirmed by abdomi-nal radiography. The pathognomonic radiographic finding in NEC is pneumatosis intestinalis, which represents invasion of the ischemic mucosa by gas producing microbes (Fig. 39-19). Other findings include the presence of ileus or portal venous gas. The latter is a transient finding that indicates the presence of severe NEC with intestinal necrosis. A fixed loop of bowel may be seen on serial abdominal radiographs, which suggests the possibility that a diseased loop of bowel, potentially with a localized perforation, is present. Although these infants are at risk of progressing to more severe disease, with timely and appropriate treatment, they often recover.Infants with Bell stage III have the most advanced form of NEC. Abdominal radiographs often demonstrate the presence of pneumoperitoneum, indicating that intestinal perforation has occurred. These patients may develop a fulminant course with progressive peritonitis, acidosis, sepsis, disseminated intravas-cular coagulopathy, and death.Pathogenesis of Necrotizing Enterocolitis. Several theories have been proposed to explain the development of NEC. In gen-eral terms, the development of diffuse pneumatosis intestinalis—which is associated with the development of stage II NEC—is thought to be due to the presence of gas within the wall of the intestine from enteric bacteria, suggesting the causative role of bacteria in the pathogenesis of NEC. Furthermore, the develop-ment of pneumoperitoneum indicates disease progression with severe disruption of the intestinal barrier (intestinal perforation). Finally, systemic sepsis with diffuse multisystem organ dysfunc-tion suggests the role for circulating proinflammatory cytokines in the pathogenesis of NEC. It has also been demonstrated that the premature intestine responds in an exaggerated fashion to bacterial products, rendering the host susceptible to barrier dys-function and the development of NEC. Various groups have shown that NEC pathogenesis requires activation of the bacterial receptor—Toll-like receptor 4 (TLR4)—in the intestinal epithe-lium. The expression of TLR4 is significantly elevated in the premature infant intestine as compared with the full-term infant intestine, a consequence of the role that TLR4 plays in normal intestinal development. When the infant is born prematurely and TLR4 expression levels are elevated, subsequent activation of TLR4 by colonizing bacteria in the neonatal intensive care unit leads to the induction of a severe proinflammatory response and the development of NEC. It is noteworthy that breast milk—long known to be protective against NEC—is able to suppress TLR4 signaling and that synthetic TLR4 antagonists are known to prevent NEC in preclinical models, suggesting the possibility of preventive approaches for this disease.Treatment. In all infants suspected of having NEC, feedings are discontinued, a nasogastric tube is placed, and broad-spec-trum parenteral antibiotics are given. The infant is resuscitated, and inotropes are administered to maintain perfusion as needed. Intubation and mechanical ventilation may be required to main-tain oxygenation. Total parenteral nutrition is started. Subse-quent treatment may be influenced by the particular stage of NEC that is present. Patients with Bell stage I are closely moni-tored and generally remain NPO and on IV antibiotics for 7 to 10 days, prior to reinitiating enteral nutrition. If the infant fully recovers, feedings may be reinitiated.Patients with Bell stage II disease merit close observa-tion. Serial physical examinations are performed looking for the development of diffuse peritonitis, a fixed mass, progres-sive abdominal wall cellulitis or systemic sepsis. If infants fail to improve after several days of treatment, consideration should be given to exploratory laparotomy. Paracentesis may be per-formed, and if the Gram stain demonstrates multiple organisms and leukocytes, perforation of the bowel should be suspected, and patients should undergo laparotomy.Brunicardi_Ch39_p1705-p1758.indd 172912/02/19 11:26 AM 1730SPECIFIC CONSIDERATIONSPART IIIn the most severe form of NEC (Bell stage III), patients have definite intestinal perforation or have not responded to nonoperative therapy. Two schools of thought direct fur-ther management. One group favors exploratory laparotomy. At laparotomy, frankly gangrenous or perforated bowel is resected, and the intestinal ends are brought out as stomas. When there is massive intestinal involvement, marginally viable bowel is retained and a “second-look” procedure is carried out after the infant stabilizes (24–48 hours). Patients with extensive necrosis at the second look may be managed by placing a proximal diverting stoma, resecting bowel that is definitely not viable, and leaving questionably viable bowel behind, distal to the diverted segment. When the intestine is viable except for a localized perforation without diffuse peri-tonitis and if the infant’s clinical condition permits, intestinal anastomosis may be performed. In cases where the diseased, perforated segment cannot be safely resected, drainage cath-eters may be left in the region of the diseased bowel, and the infant is allowed to stabilize.An alternative approach to the management of infants with perforated NEC involves drainage of the peritoneal cavity. This may be performed under local anesthesia at the bedside, and it can be an effective means of stabilizing the des-perately ill infant by relieving increased intra-abdominal pres-sure and allowing ventilation. When successful, this method also allows for drainage of perforated bowel by establishing a controlled fistula. Approximately one-third of infants treated with drainage alone survive without requiring additional oper-ations. Infants that do not respond to peritoneal drainage alone after 48 to 72 hours should undergo laparotomy. This proce-dure allows for the resection of frankly necrotic bowel diver-sion of the fecal stream and facilitates more effective drainage. It is noteworthy that a recent randomized controlled trial dem-onstrated that outcomes were similar in infants with NEC that were treated either with primary peritoneal drainage or lapa-rotomy, although this study was criticized for the large number of patients who were excluded from randomization. There was also concern that a number of patients who were thought to have NEC may actually have had spontaneous intestinal per-foration, given their lack of pneumatosis and relatively early onset of presentation; these patients would be anticipated to improve after peritoneal drainage due to the more local nature of their disease process.Necrotizing Enterocolitis in Older Infants. Although NEC is typically a disease that affects preterm infants, several inde-pendent groups have reported a tendency for early onset of NEC in term and near-term infants. In these patients, the pattern of disease was found to be different from that found in premature infants. Specifically, NEC in older infants typically is localized to the end of the small intestine and beginning of the colon, sug-gestive of an ischemic pathophysiology. There are four pertinent associations that are observed in term infants that develop NEC: congenital heart disease, in utero growth restriction, polycythe-mia, and perinatal hypoxic-ischemic events. As with NEC in preterm infants, NEC in older patients is also associated with formula consumption and is very rare in exclusively breastfed infants. Patients with NEC at full term typically present with bloody stools and may be characterized by rapid onset of symp-toms and a fulminant course. Thus, although it is true that NEC is typically a disease of premature babies, in the appropriate setting, NEC can develop at any age.Spontaneous Intestinal Perforation Versus Necrotizing Enterocolitis. In addition to NEC, preterm infants with intes-tinal pathology may develop spontaneous intestinal perforation (SIP). SIP is a distinct clinical entity from NEC, and it is essen-tially a perforation in the terminal ileum. The histopathology of SIP is different from NEC. Specifically, the mucosa is intact and not necrotic, there is no sign of ischemia, and the submucosa is thinned at the site of perforation. In contrast to NEC, pneuma-tosis intestinalis is absent in SIP. Moreover, the demographics of NEC and SIP are slightly different, in that patients with SIP tend to be slightly more premature, smaller, and more likely to have been on inotropic support. SIP occurs in two separate time points, both within a few days after birth and approximately 10 days later, and in all cases, free air will be present, but pneu-matosis will be absent. Because patients with SIP have isolated disease without necrosis or systemic inflammation, they tend to have a better outcome and are likely to respond better to peri-toneal drainage. In short, the diagnosis of SIP versus NEC has important prognostic significance. Treatment for SIP should pri-marily be surgical, with intestinal resection and stoma creation, followed by stoma reversal once the child is stable.In both SIP and NEC, the timing of stoma closure is a mat-ter of ongoing debate. Whereas in the past, pediatric surgeons typically waited until the child reached 5 kg or so, experience indicates that there is no benefit in waiting this long, and chil-dren tolerate stoma closure very well when they are at much lower weights. One approach is to close the stoma when the cal-culated gestational age is approximately 38 to 40 weeks, which will, on average, be at approximately 6 weeks after the initial surgery. This time point is selected based on the observation that proinflammatory gene expression has normalized by then, and NEC recurrence is very unlikely.Outcome. Survival in patients with NEC is dependent on the stage of disease, the extent of prematurity, and the presence of associated comorbidities. Survival by stage has recently been shown to be approximately 85%, 65%, and 35% for stages I, II, and III, respectively. Strictures develop in 20% of medically or surgically treated patients, and a contrast enema is mandatory before reestablishing intestinal continuity. If all other factors are favorable, the ileostomy is closed when the child is between 2 and 2.5 kg. At the time of stoma closure, the entire intestine should be examined to search for areas of NEC. Patients who develop massive intestinal necrosis are at risk of developing short bowel syndrome, particularly when the total length of the viable intes-tinal segment is less than 40 cm. These patients require TPN to provide adequate calories for growth and development, and may develop parenteral nutrition associated cholestasis and hepatic fibrosis. In a significant number of these patients, transplantation of the liver and small bowel may be required.Short Bowel SyndromeShort bowel syndrome (SBS) is an extremely morbid condition with an increasing incidence. Various congenital and perinatal acquired conditions such as gastroschisis, malrotation, atresia, and NEC may lead to SBS. Medical and surgical treatment options carry high dollar and human costs and morbidities including multiple infections and hospitalizations for vascular access, liver failure in conjunction with parenteral nutrition–associated cholestasis, and death. Medical centers that have developed multidisciplinary clinics focused on treating children with short bowel syndrome have achieved significant success in Brunicardi_Ch39_p1705-p1758.indd 173012/02/19 11:26 AM 1731PEDIATRIC SURGERYCHAPTER 39preventing line infections, reducing cholestasis, and improving nutrition and feeding independence overall.IntussusceptionIntussusception is the leading cause of intestinal obstruction in the young child. It refers to the condition whereby a segment of intestine becomes drawn into the lumen of the more proximal bowel. The process usually begins in the region of the termi-nal ileum, and extends distally into the ascending, transverse, or descending colon. Rarely, an intussusception may prolapse through the rectum.The cause of intussusception is not clear, although one hypothesis suggests that hypertrophy of the Peyer’s patches in the terminal ileum from an antecedent viral infection acts as a lead point. Peristaltic action of the intestine then causes the bowel distal to the lead point to invaginate into itself. Idio-pathic intussusception occurs in children between the ages of approximately 6 and 24 months of age. Beyond this age group, one should consider the possibility that a pathologic lead point maybe present. These include polyps, malignant tumors such as lymphoma, enteric duplication cysts or Meckel’s diverticu-lum. Such intussusceptions are rarely reduced by air or con-trast enema, and thus the lead point is identified when operative reduction of the intussusception is performed.Clinical Manifestations. Since intussusception is frequently preceded by a gastrointestinal viral illness, the onset may not be easily determined. Typically, the infant develops paroxysms of crampy abdominal pain and intermittent vomiting. Between attacks, the infant may act normally, but as symptoms progress, increasing lethargy develops. Bloody mucus (“currant-jelly” stool) may be passed per rectum. Ultimately, if reduction is not accomplished, gangrene of the intussusceptum occurs, and perforation may ensue. On physical examination, an elongated mass is detected in the right upper quadrant or epigastrium with an absence of bowel in the right lower quadrant (Dance’s sign). The mass may be seen on plain abdominal X-ray but is more easily demonstrated on air or contrast enema.Treatment. Patients with intussusception should be assessed for the presence of peritonitis and for the severity of systemic illness. Following resuscitation and administration of IV antibi-otics, the child is assessed for suitability to proceed with radio-graphic versus surgical reduction. In the absence of peritonitis, the child should undergo radiographic reduction. If peritonitis is present, or if the child appears systemically ill, urgent lapa-rotomy is indicated.In the stable patient, the air enema is both diagnostic and may be curative, and it is the preferred method of diagnosis and treatment of intussusception. Air is introduced with a manom-eter, and the pressure that is administered is carefully monitored. Under most instances, this should not exceed 120 mmHg. Suc-cessful reduction is marked by free reflux of air into multiple loops of small bowel and symptomatic improvement as the infant suddenly becomes pain free. Unless both of these signs are observed, it cannot be assumed that the intussusception is reduced. If reduction is unsuccessful, and the infant remains stable, the infant should be brought back to the radiology suite for a repeat attempt at reduction after a few hours. This strategy has improved the success rate of nonoperative reduction in many centers. In addition, hydrostatic reduction with barium may be useful if pneumatic reduction is unsuccessful. The overall suc-cess rate of radiographic reduction varies based on the experi-ence of the center, and it is typically between 60% and 90%.If nonoperative reduction is successful, the infant may be given oral fluids after a period of observation. Failure to reduce the intussusception mandates surgery. which can be approached through an open or laparoscopic technique. In an open procedure, exploration is carried out through a right lower quadrant incision, delivering the intussuscepted mass into the wound. Reduction usually can be accomplished by gentle distal pressure, where the intussusceptum is gently milked out of the intussuscipiens (Fig. 39-20). Care should be taken not to pull the bowel out, as this can cause damage to the bowel wall. The blood supply to the appendix is often compromised, and appen-dectomy is therefore often performed. If the bowel is frankly gangrenous, resection and primary anastomosis is performed. In experienced hands, laparoscopic reduction may be performed, even in very young infants. This is performed using a 5-mm lap-aroscope placed in the umbilicus, and two additional 5 mm ports in the left and right lower quadrants. The bowel is inspected, and if it appears to be viable, reduction is performed by milking the bowel or using gentle traction, although this approach is nor-mally discouraged during manual reduction. Atraumatic bowel graspers allow the bowel to be handled without injuring it.IV fluids are continued until the postoperative ileus sub-sides. Patients are started on clear liquids, and their diet is advanced as tolerated. Of note, recurrent intussusception occurs in 5% to 10% of patients, independent of whether the bowel is reduced radiographically or surgically. Patients present with recurrent symptoms in the immediate postoperative period. Treatment involves repeat air enema, which is successful in most cases. In patients who experience three or more episodes of intussusception, the presence of a pathologic lead point should be suspected and carefully evaluated using contrast stud-ies. After the third episode of intussusception, many pediatric surgeons will perform an exploratory laparotomy to reduce the bowel and to resect a pathologic lead point if identified.AppendicitisPresentation. Correct diagnosis of appendicitis in children can be one of the most humbling and challenging tasks facing the pediatric surgeon. The classical presentation is known to all students and practitioners of surgery: generalized abdomi-nal pain that localizes to the right lower quadrant followed by nausea, vomiting, fever, and localized peritoneal irritation in the region of McBurney’s point. When children present in this Figure 39-20. Open reduction of intussusception showing how the bowel is milked backwards to relieve the obstruction.Brunicardi_Ch39_p1705-p1758.indd 173112/02/19 11:26 AM 1732SPECIFIC CONSIDERATIONSPART IImanner, there should be little diagnostic delay. The child should be made NPO, administered IV fluids and broad-spectrum anti-biotics, and brought to the operating room for an appendec-tomy. However, children often do not present in this manner. The coexistence of nonspecific viral syndromes and the inability of young children to describe the location and quality of their pain often result in diagnostic delay. As a result, children with appendicitis often present with perforation, particularly those who are under 5 years of age. Perforation increases the length of hospital stay and makes the overall course of the illness sig-nificantly more complex.Diagnosis of Appendicitis in Children. There have been significant improvements in the role of radiographic studies in the diagnosis of acute appendicitis. While CT is quite reliable in making the diagnosis, US is very useful when performed in experienced centers and good visualization of the appendix is achieved. MRI may be performed where available with high specificity and sensitivity—and avoidance of radiation. US is very useful for excluding ovarian causes of abdominal pain. Despite these radiographic measures, the diagnosis of appendi-citis remains largely clinical, and each clinician should develop his or her own threshold to operate or to observe the patient. A reasonable practice guideline is as follows. When the diagno-sis is clinically apparent, appendectomy should obviously be performed with minimal delay. Localized right lower quadrant tenderness associated with low-grade fever and leukocytosis in boys should prompt surgical exploration. In girls, ovarian or uterine pathology must also be considered. When there is diag-nostic uncertainty, the child may be observed, rehydrated, and reassessed. In girls of menstruating age, an US may be obtained to exclude ovarian pathology (cysts, torsion, or tumor). If all studies are negative, yet the pain persists, and the abdominal findings remain equivocal, diagnostic laparoscopy may be employed to determine the etiology of the abdominal pain. The appendix should be removed even if it appears to be normal, unless another pathologic cause of the abdominal pain is defini-tively identified and the appendectomy would substantially increase morbidity.Surgical Treatment of Appendicitis. The definitive treat-ment for acute appendicitis is appendectomy. Prior to surgery, it is important that patients receive adequate IV fluids in order to correct dehydration that commonly develops as a result of fever and vomiting in patients with appendicitis. Patients should also be started on antibiotics (such as a second-generation cepha-losporin). Most surgeons will perform a laparoscopic appen-dectomy, which may have some advantage over removing the appendix through a single, larger incision. During the laparo-scopic appendectomy, a small incision is made at the umbilicus, and two additional incisions are made in the lower abdomen. The appendix is typically delivered through the umbilicus, and all incisions are then closed, with dissolvable sutures. If the appendix is not ruptured, the patient may start drinking liq-uids shortly after waking up from the operation, and may be advanced to a solid diet the next day. In general, the same steps are taken when appendectomy is performed through an open approach. The most common complication after appendectomy is a surgical site infection. Other risks—including bleeding or damage to other structures inside the abdomen—are extremely rare. Recovery from surgery is dependent upon the individual patient. Most children are back to school approximately 1 week from surgery and usually are allowed to return to full physical Figure 39-21. Computed tomography scan of the abdomen showing the presence of a ruptured appendix with pelvic fluid and a fecalith (arrow).activity after 2 to 3 weeks. During the recovery period, over-the-counter pain medication may be required. Older patients tend to require a longer time for full recovery.Management of the Child With Perforated Appendicitis.  The signs and symptoms of perforated appendicitis can closely mimic those of gastroenteritis and include abdominal pain, vom-iting, and diarrhea. Alternatively, the child may present with symptoms of intestinal obstruction. An abdominal mass may be present in the lower abdomen. When the symptoms have been present for more than 4 or 5 days, and an abscess is suspected, it is reasonable to obtain a computerized tomogram of the abdo-men and pelvis with IV, oral, and rectal contrast in order to visu-alize the appendix and the presence of an associated abscess, phlegmon, or fecalith (Fig. 39-21).An individualized approach is necessary for the child who presents with perforated appendicitis. When there is evidence of generalized peritonitis, intestinal obstruction or evidence of systemic toxicity, the child should undergo appendectomy. This should be delayed only for as long as is required to ensure ade-quate fluid resuscitation and administration of broad-spectrum antibiotics. The operation can be performed through an open or through a laparoscopic approach. One distinct advantage of the laparoscopic approach is that it provides excellent visualiza-tion of the pelvis and all four quadrants of the abdomen. At the time of surgery, adhesions are gently lysed, abscess cavities are drained and the appendix is removed. Drains are seldom used, and the skin incisions can be closed primarily. If a fecalith is identified outside the appendix on computerized tomography, every effort should be made to retrieve it and to remove it along with the appendix, if at all possible. Often, the child in whom symptoms have been present for more than 4 or 5 days will pres-ent with an abscess without evidence of generalized peritonitis. Under these circumstances, it is appropriate to perform image-guided percutaneous drainage of the abscess followed by broad-spectrum antibiotic therapy. The inflammation will generally subside within several days, and the appendix can be safely removed as an outpatient 6 to 8 weeks later. If the child’s symp-toms do not improve, or if the abscess is not amenable to per-cutaneous drainage, then laparoscopic or open appendectomy and abscess drainage is required. Patients who present with a phlegmon in the region of a perforated appendix may be man-aged in a similar manner. In general, children who are younger Brunicardi_Ch39_p1705-p1758.indd 173212/02/19 11:26 AM 1733PEDIATRIC SURGERYCHAPTER 39than 4 or 5 years of age do not respond as well to an initial nonoperative approach because their bodies do not localize or isolate the inflammatory process. Thus, these patients are more likely to require early surgical intervention. Patients who have had symptoms of appendicitis for no more than 4 days should probably undergo “early” appendectomy because the inflamma-tory response is not as excessive during that initial period and the procedure can be performed safely.Nonoperative Management of Acute Appendicitis. Despite the fact that surgical removal of the acutely inflammation appendix is effective in all cases, there has been a growing rec-ognition that certain children will respond to antibiotics alone and thus avoid surgery. Several trials have shown that acute appendicitis may be treated with antibiotics alone effectively in nearly 80% of patients. However, the failure rate is considered unacceptably high for many patients, who effectively will have suffered a delay from definitive care. Furthermore, the hetero-geneity of disease presentation, and varying degree of illness severity, make it quite difficult to predict who will respond to antibiotics alone. This question is currently being answered in the United States in the form of a randomized controlled trial that is recruiting over 1500 patients in eight states, which will be divided into antibiotic therapy versus surgery (ClinicalTrials.gov, identifier NCT02800785).Other Causes of Abdominal Pain That Mimic Appendi-citis in Children. As mentioned earlier, appendicitis can be one of the most difficult diagnoses to establish in children with abdominal pain, in part because of the large number of diseases that present in a similar fashion. Patients with urinary tract infection can present very similarly to those with appen-dicitis. However, patients with urinary tract infection are less likely to present with vomiting and are likely to also experience difficulty with urination, characterized by pressure, burning, and frequency. Constipation may be commonly confused with appendicitis in its earliest stages. However, patients with consti-pation rarely have fever and will not have abnormalities in their blood work. Ovarian torsion can mimic appendicitis, given the severe abdominal pain that accompanies this condition. How-ever, patients with ovarian torsion are generally asymptomatic until the acute onset of severe pain. By contrast, patients with appendicitis generally experience gradual onset of pain asso-ciated with nausea and vomiting. Finally, children and young adults are always at risk for the development of gastroenteritis. However, unlike appendicitis, patients with gastroenteritis gen-erally present with persistent vomiting and occasionally diar-rhea, which precedes the onset of the abdominal pain.Intestinal DuplicationsDuplications represent mucosa-lined structures that are in con-tinuity with the gastrointestinal tract. Although they can occur at any level in the gastrointestinal tract, duplications are found most commonly in the ileum within the leaves of the mesen-tery. Duplications may be long and tubular but usually are cystic masses. In all cases, they share a common wall with the intes-tine. Symptoms associated with enteric duplication cysts include recurrent abdominal pain, emesis from intestinal obstruction, or hematochezia. Such bleeding typically results from ulceration in the duplication or in the adjacent intestine if the duplication contains ectopic gastric mucosa. On examination, a palpable mass is often identified. Children may also develop intestinal obstruction. Torsion may produce gangrene and perforation.The ability to make a preoperative diagnosis of enteric duplication cyst usually depends on the presentation. CT, US, and technetium pertechnetate scanning can be very helpful. Occasionally, a duplication can be seen on small bowel follow-through or barium enema. In the case of short duplications, resection of the cyst and adjacent intestine with end-to-end anastomosis can be performed. If resection of long duplications would compromise intestinal length, multiple enterotomies and mucosal stripping in the duplicated segment will allow the walls to collapse and become adherent. An alternative method is to divide the common wall using the GIA stapler, forming a com-mon lumen. Patients with duplications who undergo complete excision without compromise of the length of remaining intes-tine have an excellent prognosis.Meckel’s DiverticulumA Meckel’s diverticulum is a remnant of a portion of the embryonic omphalomesenteric (vitelline) duct. It is located on the antimesenteric border of the ileum, usually within 2 ft of the ileocecal valve (Fig. 39-22). It may be found incidentally at surgery or may present with inflammation masquerading as appendicitis. Perforation of a Meckel’s diverticulum may occur if the outpouching becomes impacted with food, leading to dis-tention and necrosis. Occasionally, bands of tissue extend from the Meckel’s diverticulum to the anterior abdominal wall, and these may represent lead points around which internal hernias may develop. This is an important cause of intestinal obstruction in the older child who has a scarless abdomen. Similar to dupli-cations, ectopic gastric mucosa may produce ileal ulcerations that bleed and lead to the passage of maroon-colored stools. Pancreatic mucosa may also be present. Diagnosis may be made by technetium pertechnetate scans when the patient presents with bleeding. Treatment is surgical. If the base is narrow and there is no mass present in the lumen of the diverticulum, a wedge resection of the diverticulum with transverse closure of the ileum can be performed. A linear stapler is especially useful in this circumstance. When a mass of ectopic tissue is palpable, if the base is wide, or when there is inflammation, it is prefer-able to perform a resection of the involved bowel and end-to-end ileoileostomy.Mesenteric CystsMesenteric cysts are similar to duplications in their location within the mesentery. However, they do not contain any mucosa or muscular wall. Chylous cysts may result from congenital Figure 39-22. Operative photograph showing the presence of a Meckel’s diverticulum (arrow).Brunicardi_Ch39_p1705-p1758.indd 173312/02/19 11:26 AM 1734SPECIFIC CONSIDERATIONSPART IIlymphatic obstruction. Mesenteric cysts can cause intestinal obstruction or may present as an abdominal mass. The diagno-sis may be made by abdominal US or CT. Treatment involves surgical excision. This may require resection of the adjacent intestine, particularly for extensive, multicystic lesions. In cases where complete excision is not possible due to the close proxim-ity to vital structures, partial excision or marsupialization should be performed.Hirschsprung’s DiseasePathogenesis. In his classic textbook entitled Pediatric Sur-gery, Dr. Orvar Swenson, who is eponymously associated with one of the classic surgical treatments for Hirschsprung’s dis-ease, described this condition as follows: “Congenital megaco-lon is caused by a malformation in the pelvic parasympathetic system which results in the absence of ganglion cells in Auer-bach’s plexus of a segment of distal colon. Not only is there an absence of ganglion cells, but the nerve fibers are large and excessive in number, indicating that the anomaly may be more extensive than the absence of ganglion cells.” This narrative of Hirschsprung’s disease is as accurate today as it was more than 50 years ago and summarizes the essential pathologic fea-tures of this disease: absence of ganglion cells in Auerbach’s plexus and hypertrophy of associated nerve trunks. The cause of Hirschsprung’s disease remains incompletely understood, although current thinking suggests that the disease results from a defect in the migration of neural crest cells, which are the embryonic precursors of the intestinal ganglion cell. Under normal conditions, the neural crest cells migrate into the intes-tine from cephalad to caudad. The process is completed by the 12th week of gestation, but the migration from midtransverse colon to anus takes 4 weeks. During this latter period, the fetus is most vulnerable to defects in migration of neural crest cells. This may explain why most cases of aganglionosis involve the rectum and rectosigmoid. The length of the aganglionic segment of bowel is therefore determined by the most distal region that the migrating neural crest cells reach. In rare instances, total colonic aganglionosis may occur.Recent studies have shed light on the molecular basis for Hirschsprung’s disease. Patients with Hirschsprung’s disease have an increased frequency of mutations in several genes, including GDNF, its receptor Ret, or its coreceptor Gfra-1. Moreover, mutations in these genes also lead to aganglionic megacolon in mice, which provides the opportunity to study the function of the encoded proteins. Initial investigations indicate that GDNF promotes the survival, proliferation, and migration of mixed populations of neural crest cells in culture. Other studies have revealed that GDNF is expressed in the gut in advance of migrating neural crest cells and is chemoattrac-tive for neural crest cells in culture. These findings raise the possibility that mutations in the GDNF or Ret genes could lead to impaired neural crest migration in utero and the development of Hirschsprung’s disease.Clinical Presentation. The incidence of sporadic Hirschsprung’s disease is 1 in 5000 live births. There are reports of increased frequency of Hirschsprung’s disease in multiple generations of the same family. Occasionally, such families have mutations in the genes described earlier, includ-ing the Ret gene. Because the aganglionic colon does not permit normal peristalsis to occur, the presentation of children with Hirschsprung’s disease is characterized by a functional distal intestinal obstruction. In the newborn period, the most common symptoms are abdominal distention, failure to pass meconium, and bilious emesis. Any infant who does not pass meconium beyond 48 hours of life must be investigated for the presence of Hirschsprung’s disease. Occasionally, infants present with a dra-matic complication of Hirschsprung’s disease called enteroco-litis. This pattern of presentation is characterized by abdominal distention and tenderness, and it is associated with manifesta-tions of systemic toxicity that include fever, failure to thrive, and lethargy. Infants are often dehydrated and demonstrate a leukocytosis or increase in circulating band forms on hemato-logic evaluation. On rectal examination, forceful expulsion of foul-smelling liquid feces is typically observed and represents the accumulation of stool under pressure in an obstructed dis-tal colon. Treatment includes rehydration, systemic antibiotics, nasogastric decompression, and rectal irrigations while the diag-nosis of Hirschsprung’s disease is being confirmed. In children that do not respond to nonoperative management, a decompres-sive stoma is required. It is important to ensure that this stoma is placed in ganglion-containing bowel, which must be confirmed by frozen section at the time of stoma creation.In approximately 20% of cases, the diagnosis of Hirschsprung’s disease is made beyond the newborn period. These children have severe constipation, which has usually been treated with laxatives and enemas. Abdominal distention and failure to thrive may also be present at diagnosis.Diagnosis. The definitive diagnosis of Hirschsprung’s disease is made by rectal biopsy. Samples of mucosa and submucosa are obtained at 1 cm, 2 cm, and 3 cm from the dentate line. This can be performed at the bedside in the neonatal period without anes-thesia, as samples are taken in bowel that does not have somatic innervation and is thus not painful to the child. In older children, the procedure should be performed using IV sedation. The histo-pathology of Hirschsprung’s disease is the absence of ganglion cells in the myenteric plexuses, increased acetylcholinesterase staining, and the presence of hypertrophied nerve bundles.It is important to obtain a barium enema in children in whom the diagnosis of Hirschsprung’s disease is suspected. This test may demonstrate the location of the transition zone between the dilated ganglionic colon and the distal constricted aganglionic rectal segment. Our practice is to obtain this test before instituting rectal irrigations if possible so that the differ-ence in size between the proximal and distal bowel is preserved. Although the barium enema can only suggest, but not reliably establish, the diagnosis of Hirschsprung’s disease, it is very useful in excluding other causes of distal intestinal obstruction. These include small left colon syndrome (as occurs in infants of diabetic mothers), colonic atresia, meconium plug syndrome, or the unused colon observed in infants after the administration of magnesium or tocolytic agents. The barium enema in total colonic aganglionosis may show a markedly shortened colon. Some surgeons have found the use of rectal manometry helpful, particularly in older children, although it is relatively inaccurate.Treatment. The diagnosis of Hirschsprung’s disease requires surgery in all cases. The classic surgical approach consisted of a multiple stage procedure. This included a colostomy in the newborn period, followed by a definitive pull-through operation after the child was over 10 kg. There are three viable options for the definitive pull through procedure that are currently used. Although individual surgeons may advocate one procedure over another, studies have demonstrated that the outcome after each type of operation is similar. For each of 6Brunicardi_Ch39_p1705-p1758.indd 173412/02/19 11:26 AM 1735PEDIATRIC SURGERYCHAPTER 39the operations that is performed, the principles of treatment include confirming the location in the bowel where the transition zone between ganglionic and aganglionic bowel exists, resecting the aganglionic segment of bowel, and performing an anastomosis of ganglionated bowel to either the anus or a cuff of rectal mucosa (Fig. 39-23).It is now well established that a primary pull-through pro-cedure can be performed safely, even in the newborn period. This approach follows the same treatment principles as a staged procedure and saves the patient from an additional surgical Figure 39-23. The three operations for surgical correction of Hirschsprung’s disease. A. The Duhamel procedure leaves the rec-tum in place and brings ganglionic bowel into the retrorectal space. B. The Swenson procedure is a resection with end-to-end anastomo-sis performed by exteriorizing bowel ends through the anus. C. The Soave operation is performed by endorectal dissection and removal of mucosa from the aganglionic distal segment and bringing the ganglionic bowel down to the anus within the seromuscular tunnel.procedure. Many surgeons perform the intra-abdominal dissec-tion using the laparoscope. This approach is especially useful in the newborn period as this provides excellent visualization of the pelvis. In children with significant colonic distention, it is important to allow for a period of decompression using a rectal tube if a single-staged pull-through is to be performed. In older children with very distended, hypertrophied colon, it may be prudent to perform a colostomy to allow the bowel to decom-press prior to performing a pull-through procedure. However, it should be emphasized that there is no upper age limit for per-forming a primary pull-through.Of the three pull-through procedures performed for Hirschsprung’s disease, the first is the original Swenson pro-cedure. In this operation, the aganglionic rectum is dissected in the pelvis and removed down to the anus. The ganglionic colon is then anastomosed to the anus via a perineal approach. In the Duhamel procedure, dissection outside the rectum is confined to the retrorectal space, and the ganglionic colon is anastomosed posteriorly just above the anus. The anterior wall of the gangli-onic colon and the posterior wall of the aganglionic rectum are anastomosed, using a stapler. Although both of these procedures are extremely effective, they are limited by the possibility of damage to the parasympathetic nerves that are adjacent to the rectum. To circumvent this potential problem, Soave’s proce-dure involves dissection entirely within the rectum. The rectal mucosa is stripped from the muscular sleeve, and the gangli-onic colon is brought through this sleeve and anastomosed to the anus. This operation may be performed completely from below. In all cases, it is critical that the level at which ganglion-ated bowel exists be determined. Most surgeons believe that the anastomosis should be performed at least 5 cm from the point at which ganglion cells are found. This avoids performing a pull-through in the transition zone, which is associated with a high incidence of complications due to inadequate emptying of the pull-through segment. Up to one-third of patients who undergo a transition zone pull through will require a reoperation.The main complications of all procedures include post-operative enterocolitis, constipation, and anastomotic stricture. There is also a reported incidence of recurrent Hirschsprung’s disease, which may reflect either residual aganglionic bowel left behind after the pull-through, or the presence of ischemia in the pulled-through segment leading to ganglion cell loss. Long-term results with the three procedures are comparable and generally excellent in experienced hands. These three procedures also can be adapted for total colonic aganglionosis in which the ileum is used for the pull-through segment.Anorectal MalformationsAnatomic Description. Anorectal malformations describe a spectrum of congenital anomalies that include imperforate anus and persistent cloaca. Anorectal malformations occur in approximately 1 in 5000 live births and affect males and females almost equally. The embryologic basis includes failure of descent of the urorectal septum. The level to which this septum descends determines the type of anomaly that is present, which subsequently influences the surgical approach.In patients with imperforate anus, the rectum fails to descend through the external sphincter complex. Instead, the rectal pouch ends “blindly” in the pelvis, above or below the levator ani muscle. In most cases, the blind rectal pouch com-municates more distally with the genitourinary system or with the perineum through a fistulous tract. Traditionally, anatomic Brunicardi_Ch39_p1705-p1758.indd 173512/02/19 11:26 AM 1736SPECIFIC CONSIDERATIONSPART IIFigure 39-24. Low imperforate anus in a male. Note the well-developed buttocks. The perineal fistula was found at the midline raphe.Figure 39-25. Imperforate anus in a female. A catheter has been placed into the fistula, which is in the vestibule of the vagina.description of imperforate anus has been characterized as either “high” or “low” depending on whether the rectum ends above the levator ani muscle complex or partially descends through this muscle (Fig. 39-24). Based upon this classification system, in male patients with high imperforate anus the rectum usually ends as a fistula into the membranous urethra. In females, high imperforate anus often occurs in the context of a persistent clo-aca. In both males and females, low lesions are associated with a fistula to the perineum. In males, the fistula connects with the median raphe of the scrotum or penis. In females, the fistula may end within the vestibule of the vagina, which is located immediately outside the hymen or at the perineum.Because this classification system is somewhat arbitrary, Peña proposed a classification system that specifically and unambiguously describes the location of the fistulous opening. In men, the fistula may communicate with: (a) the perineum (cutaneous perineal fistula); (b) the lowest portion of the poste-rior urethra (rectourethral bulbar fistula); (c) the upper portion of the posterior urethra (rectourethral prostatic fistula); or (d) the bladder neck (rectovesicular fistula). In females, the ure-thra may open to the perineum between the female genitalia and the center of the sphincter (cutaneous perineal fistula) or into the vestibule of the vagina (vestibular fistula) (Fig. 39-25). In both sexes, the rectum may end in a completely blind fashion (imperforate anus without fistula). In rare cases, patients may have a normal anal canal, yet there may be total atresia or severe stenosis of the rectum.The most frequent defect in males is imperforate anus with rectourethral fistula, followed by rectoperineal fistula, then rectovesical fistula or rectobladder neck. In females, the most frequent defect is the rectovestibular defect, followed by the cutaneous perineal fistula. The third most common defect in females is the persistent cloaca. This lesion represents a wide spectrum of malformations in which the rectum, vagina, and urinary tract meet and fuse into a single common channel. On physical examination, a single perineal orifice is observed, and it is located at the place where the urethra normally opens. Typi-cally, the external genitalia are hypoplastic.Associated Malformations. Approximately 60% of patients have an associated malformation. The most common is a urinary tract defect, which occurs in approximately 50% of patients. Skeletal defects are also seen, and the sacrum is most commonly involved. Spinal cord anomalies especially tethered cored are common, particularly in children with high lesions. Gastroin-testinal anomalies occur, most commonly esophageal atresia. Cardiac anomalies may be noted, and occasionally patients pres-ent with a constellation of defects as part of the VACTERLL syndrome (described earlier).Management of Patients With Imperforate Anus. Patients with imperforate anus are usually stable, and the diagnosis is readily apparent. Despite the obstruction, the abdomen is initially not distended, and there is rarely any urgency to intervene. The principles of management center around diagnosing the type of defect that is present (high vs. low), and evaluating the presence of associated anomalies. It may take up to 24 hours before the presence of a fistula on the skin is noted, and thus it is important to observe the neonate for some period of time before defini-tive surgery is undertaken. All patients should therefore have an orogastric tube placed and be monitored for the appearance of meconium in or around the perineum or in the urine. Investiga-tion for associated defects should include an US of the abdomen to assess for the presence of urinary tract anomaly. Other tests should include an echocardiogram and spinal radiographs. An US of the spine should be performed to look for the presence of a tethered cord. To further classify the location of the fistula as either “high” versus “low,” a lateral abdominal radiograph can be obtained with a radiopaque marker on the perineum. By placing the infant in the inverted position, the distance between the most distal extent of air in the rectum and the perineal surface can be measured. This study is imprecise, however, and may add little to the overall management of these patients.The surgical management of infants with imperforate anus is determined by the anatomic defect. In general, when a low lesion is present, only a perineal operation is required without a colostomy. Infants with a high lesion require a colostomy in the newborn period, followed by a pull-through procedure at approximately 2 months of age. When a persistent cloaca is present, the urinary tract needs to be carefully evaluated at the time of colostomy formation to ensure that normal emptying can occur and to determine whether the bladder needs to be drained by means of a vesicostomy. If there is any doubt about the type of lesion, it is safer to perform a colostomy rather than jeopardize the infant’s long-term chances for continence by an injudicious perineal operation.Brunicardi_Ch39_p1705-p1758.indd 173612/02/19 11:26 AM 1737PEDIATRIC SURGERYCHAPTER 39The type of pull-through procedure favored by most pedi-atric surgeons today is the posterior sagittal anorectoplasty (PSARP procedure), as described by Peña and DeVries. This involves placing the patient in the prone jack-knife position, dividing the levator ani and external sphincter complex in the midline posteriorly, dividing the communication between the gastrointestinal tract and the urinary tract, and bringing down the rectum after sufficient length is achieved. The muscles are then reconstructed and sutured to the rectum. The outcome of 1192 patients who had undergone this procedure has been reviewed by Peña and Hong. Seventy-five percent of patients were found to have voluntary bowel movements, and nearly 40% were considered totally continent. As a rule, patients with high lesions demonstrate an increase incidence of incontinence, whereas those with low lesions are more likely to be consti-pated. Management of patients with high imperforate anus can be greatly facilitated using a laparoscopic assisted approach, in which the patient is operated on in the supine position, and the rectum is mobilized down to the fistulous connection to the bladder neck. This fistulous connection is then divided, and the rectum is completely mobilized down to below the peritoneal reflection. The operation then proceeds at the perineum, and the location of the muscle complex is determined using the nerve stimulator. A Veress needle is then advanced through the skin at the indicated site, with the laparoscope providing guidance to the exact intrapelvic orientation. Dilators are then placed over the Veress needle, the rectum is then pulled through this perito-neal opening, and an anoplasty is performed.JAUNDICEThe Approach to the Jaundiced InfantJaundice is present during the first week of life in 60% of term infants and 80% of preterm infants. There is usually accumula-tion of unconjugated bilirubin, but there may also be deposition of direct bilirubin. During fetal life, the placenta is the principal route of elimination of unconjugated bilirubin. In the newborn infant, bilirubin is conjugated through the activity of glucoronyl transferase. In the conjugated form, bilirubin is water soluble, which results in its excretion into the biliary system and then into the gastrointestinal tract. Newborns have a relatively high level of circulating hemoglobin and relative immaturity of the conjugating machinery. This results in a transient accumulation of bilirubin in the tissues, which is manifested as jaundice. Physi-ologic jaundice is evident by the second or third day of life and usually resolves within approximately 5 to 7 days. By definition, jaundice that persists beyond 2 weeks is considered pathologic.Pathologic jaundice may be due to biliary obstruction, increased hemoglobin load, or to liver dysfunction. The workup of the jaundiced infant therefore should include a search for the following possibilities: (a) obstructive disorders, including biliary atresia, choledochal cyst, and inspissated bile syndrome; (b) hematologic disorders, including ABO incompatibility, Rh incompatibility, spherocytosis; (c) metabolic disorders, includ-ing α-1 antitrypsin deficiency, galactosemia; pyruvate kinase deficiency; and (d) congenital infection, including syphilis and rubella.Biliary AtresiaPathogenesis. Biliary atresia is a rare disease associated with significant morbidity and mortality. This disease is character-ized by a fibroproliferative obliteration of the biliary tree which progresses toward hepatic fibrosis, cirrhosis, and end-stage liver failure. The incidence of this disease is approximately 1 in 8000 to 1 in 18,000. The etiology of biliary atresia is likely multifac-torial. In the classic textbook, Abdominal Surgery of Infancy and Childhood, Ladd and Gross described the cause of biliary atresia as an “arrest of development during the solid stage of bile duct formation.” Previously proposed theories on the eti-ology of biliary atresia have focused on defects in hepatogen-esis, prenatal vasculogenesis, immune dysregulation, infectious agents, and exposure to toxins. More recently, genetic mutations in the cfc1 gene, implicated in left-right axis determinations, were identified in patients with biliary atresia-splenic malforma-tion syndrome. Additionally, the detection of higher incidence of maternal microchimerism in the livers of males with biliary atresia has led to the suggestion that consequent expression of maternal antigens may lead to an autoimmune process leading to inflammation and obliteration of the biliary tree. Recent ani-mal studies strongly implicate perinatal exposure to reovirus or rotavirus. Such viral exposure may lead to periportal inflamma-tion mediated by interferon-γ and other cytokines.Clinical Presentation. Infants with biliary atresia present with jaundice at birth or shortly thereafter. The diagnosis of biliary atresia is frequently not entertained by pediatricians in part because physiologic jaundice of the newborn is so common and biliary atresia is so uncommon. As such, it is not unusual for there to be a delay in diagnosis. However, infants with bili-ary atresia characteristically have acholic, pale gray appearing stools, secondary to obstructed bile flow. With further passage of time, these infants manifest progressive failure to thrive, and if untreated, develop stigmata of liver failure and portal hyper-tension, particularly splenomegaly and esophageal varices.The obliterative process of biliary atresia involves the common duct, cystic duct, one or both hepatic ducts, and the gallbladder, in a variety of combinations. The histopathology of patients with biliary atresia includes inflammatory changes within the parenchyma of the liver, as well as fibrous deposi-tion at the portal plates that is observed on trichrome staining of frozen tissue sections. In certain cases, bile duct prolifera-tion may be seen, a relatively nonspecific marker of liver injury. Approximately 25% of patients with biliary atresia have coin-cidental malformations, often associated with polysplenia, and may include intestinal malrotation, preduodenal portal vein, and intrahepatic vena cava.Diagnosis. In general, the diagnosis of biliary atresia is made utilizing a combination of studies, as no single test is suffi-ciently sensitive or specific. Fractionation of the serum bilirubin is performed to determine if the associated hyperbilirubinemia is conjugated or unconjugated. Workup commonly includes the analysis of TORCH infection titers as well as viral hepatitis. Typically, a US is performed to assess the presence of other causes of biliary tract obstruction, including choledochal cyst. The absence of a gallbladder is highly suggestive of the diagno-sis of biliary atresia. However, the presence of a gallbladder does not exclude the diagnosis of biliary atresia because in approxi-mately 10% of biliary atresia patients, the distal biliary tract is patent and a gall bladder may be visualized, even though the proximal ducts are atretic. It is important to note that the intrahe-patic bile ducts are never dilated in patients with biliary atresia. In many centers, a nuclear medicine scan using technetium 99m IDA (DISIDA), performed after pretreatment of the patient with phenobarbital, has proven to be an accurate and reliable study. Brunicardi_Ch39_p1705-p1758.indd 173712/02/19 11:26 AM 1738SPECIFIC CONSIDERATIONSPART IIIf radionuclide appears in the intestine, there is patency of the biliary tree, and the diagnosis of biliary atresia is excluded. If radionuclide is concentrated by the liver but not excreted despite treatment with phenobarbital, and the metabolic screen, particu-larly α1-antitrypsin determination, is normal, the presumptive diagnosis is biliary atresia. A percutaneous liver biopsy might potentially distinguish between biliary atresia and other sources of jaundice such as neonatal hepatitis. When these tests point to or cannot exclude the diagnosis of biliary atresia, surgical exploration is warranted. At surgery, a cholangiogram may be performed if possible, using the gallbladder as a point of access. This may be performed using a laparoscope. The cholangio-gram demonstrates the anatomy of the biliary tree, determines whether extrahepatic bile duct atresia is present, and evaluates whether there is distal bile flow into the duodenum. The cholan-giogram may demonstrate hypoplasia of the extrahepatic biliary system. This condition is associated with hepatic parenchymal disorders that cause severe intrahepatic cholestasis, including α1-antitrypsin deficiency and biliary hypoplasia (Alagille’s syn-drome). Alternatively, a cursory assessment of the extrahepatic biliary tree may clearly delineate the atresia.Inspissated Bile Syndrome. This term is applied to patients with normal biliary tracts who have persistent obstructive jaun-dice. Increased viscosity of bile and obstruction of the canaliculi are implicated as causes. The condition has been seen in infants receiving parenteral nutrition, but it is also encountered in con-ditions associated with hemolysis, or in cystic fibrosis. In some instances, no etiologic factors can be defined. Neonatal hepatitis may present in a similar fashion to biliary atresia. This disease is characterized by persistent jaundice due to acquired biliary inflammation without obliteration of the bile ducts. There may be a viral etiology, and the disease is usually self-limited. In this case, cholangiography is both diagnostic and therapeutic.Treatment. If the diagnosis of biliary atresia is confirmed intraoperatively, then surgical treatment is undertaken at the same setting. Currently, first-line therapy consists of creation of a hepatoportoenterostomy, as described by Kasai. The purpose of this procedure is to promote bile flow into the intestine. The procedure is based on Kasai’s observation that the fibrous tissue at the porta hepatis invests microscopically patent biliary duct-ules that, in turn, communicate with the intrahepatic ductal sys-tem (Fig. 39-26). Transecting this fibrous tissue at the portal Figure 39-26. Operative photograph showing Kasai portoenteros-tomy. Arrows denote the site of the anastomosis. Note the engorged liver.Figure 39-27. Schematic illustration of the Kasai portoenteros-tomy for biliary atresia. An isolated limb of jejunum is brought to the porta hepatis and anastomosed to the transected ducts at the liver plate.plate, invariably encountered cephalad to the bifurcating portal vein, opens these channels and establishes bile flow into a surgi-cally constructed intestinal conduit, usually a Roux-en-Y limb of jejunum (Fig. 39-27). Some authors believe that an intussus-cepted antireflux valve is useful in preventing retrograde bile reflux, although the data suggest that it does not impact out-come. A liver biopsy is performed at the time of surgery to determine the degree of hepatic fibrosis that is present. The diameter of bile ducts at the portal plate is predictive of likeli-hood of long-term success of biliary drainage through the por-toenterostomy. Numerous studies also suggest that the likelihood of surgical success is inversely related to the age at the time of portoenterostomy. Infants treated prior to 60 days of life are more likely to achieve successful and long-term biliary drainage than older infants. Although the outlook is less favor-able for patients after the 12th week, it is reasonable to proceed with surgery even beyond this time point, as the alternative is certain liver failure. It is noteworthy that a significant number of patients have had favorable outcomes after undergoing portoen-terostomy despite advanced age at time of diagnosis.Bile drainage is anticipated when the operation is carried out early; however, bile flow does not necessarily imply cure. Approximately one-third of patients remain symptom free after portoenterostomy, the remainder require liver transplantation due to progressive liver failure. Independent risk factors that predict failure of the procedure include bridging liver fibrosis at the time of surgery and postoperative cholangitic episodes. A review of the data of the Japanese Biliary Atresia Registry (JBAR), which 7Brunicardi_Ch39_p1705-p1758.indd 173812/02/19 11:26 AM 1739PEDIATRIC SURGERYCHAPTER 39includes the results of 1381 patients, showed that the 10-year survival rate was 53% without transplantation, and 66.7% with transplantation. A common postoperative complication is cholangitis. There is no effective strategy to completely eliminate this complication, and the effectiveness of long-term prophylactic antibiotics has not been fully resolved. The Childhood Liver Research and Education Network (ChiLDREN, formerly the Biliary Atresia Research Consortium) is an active consortium of 15 children’s hospitals in the United States, funded by the National Institutes of Health (NIH) that studies rare cholestatic liver diseases of infants and children (http://childrennetwork.org). An NIH-funded, randomized, double-blinded, placebo-controlled trial designed to determine if adjuvant steroids improve outcome of infants undergoing Kasai portoenterostomy has been completed. This trial showed that among infants with biliary atresia who have undergone hepatoportoenterostomy, high-dose steroid therapy following surgery did not result in statistically significant treatment differences in bile drainage at 6 months, although a small clinical benefit could not be excluded. Steroid treatment was associated with earlier onset of serious adverse events in children with biliary atresia.Previous authors have published merits of revising the portoenterostomy in select patients if drainage of bile stops. Recently, Bondoc et al reported on their experience with revision of portoenterostomies. Specifically, the authors reported on 183 patients who underwent Kasai portoenterostomy for biliary atresia, of which 24 underwent revision for recurrence of nondrainage after successful bypass. Of the patients who underwent revision for nondrainage, 75% ultimately achieved drainage after the second procedure, of which nearly 50% survived long term with their native livers. The authors conclude that in selected patients in which bile flow was established following the Kasai procedure and then lost, revision of the portoenterostomy is a reasonable treatment option with good success.Choledochal CystClassification. The term choledochal cyst refers to a spec-trum of congenital biliary tract disorders that were previously grouped under the name idiopathic dilation of the common bile duct. After the classification system proposed by Alonso-Lej, five types of choledochal cyst are described. Type I cyst is char-acterized by fusiform dilatation of the bile duct. This is the most common type and is found in 80% to 90% of cases. Type II choledochal cysts appear as an isolated diverticulum protruding from the wall of the common bile duct. The cyst may be joined to the common bile duct by a narrow stalk. Type III choledochal cysts arise from the intraduodenal portion of the common bile duct and are also known as choledochoceles. Type IVA cysts consist of multiple dilatations of the intrahepatic and extra-hepatic bile ducts. Type IVB choledochal cysts are multiple dilatations involving only the extrahepatic bile ducts. Type V (Caroli’s disease) consists of multiple dilatations limited to the intrahepatic bile ducts.Choledochal cyst is most appropriately considered the pre-dominant feature in a constellation of pathologic abnormalities that can occur within the pancreato-biliary system. Frequently associated with choledochal cyst is an anomalous junction of the pancreatic and common bile ducts. The etiology of choledochal cyst is controversial. Babbit proposed an abnormal pancreatic and biliary duct junction, with the formation of a “common channel” into which pancreatic enzymes are secreted. This process results in weakening of the bile duct wall by gradual enzymatic destruction, leading to dilatation, inflammation, and finally cyst formation. Not all patients with choledochal cyst demonstrate an anatomic common channel, which raises ques-tions regarding the accuracy of this model.Clinical Presentation. Choledochal cyst is more common in females than in males (4:1). Typically, these present in children beyond the toddler age group. The classic symptom triad consists of abdominal pain, mass, and jaundice. However, this complex is actually encountered in fewer than half of the patients. The more usual presentation is that of episodic abdominal pain, often recurring over the course of months or years, and generally asso-ciated with only minimal jaundice that may escape detection. If left undiagnosed, patients may develop cholangitis or pancreatitis. Cholangitis may lead to the development of cirrhosis and portal hypertension. Choledochal cyst can present in the newborn period, where the symptoms are very similar to those of biliary atresia. Often neonates will have an abdominal mass at presentation.Diagnosis. Choledochal cyst is frequently diagnosed in the fetus at a screening prenatal US. In the older child or adoles-cent, abdominal US may reveal a cystic structure arising from the biliary tree. CT will confirm the diagnosis. These studies will demonstrate the dimensions of the cyst and define its rela-tionship to the vascular structures in the porta hepatis, as well as the intrahepatic ductal configuration. Endoscopic retrograde cholangiopancreatography (ERCP) is reserved for patients in whom confusion remains after evaluation by less invasive imag-ing modalities. Magnetic resonance cholangiopancreatography may provide a more detailed depiction of the anatomy of the cyst and its relationship to the bifurcation of the hepatic ducts and into the pancreas.Treatment. The cyst wall is composed of fibrous tissue and is devoid of mucosal lining. As a result, the treatment of cho-ledochal cyst is surgical excision followed by biliary-enteric reconstruction. There is no role for internal drainage by cys-tenterostomy, which leaves the cyst wall intact and leads to the inevitable development of cholangitis. Rarely, choledochal cyst can lead to the development of a biliary tract malignancy. This provides a further rationale for complete cyst excision.Resection of the cyst may be performed via open or laparo-scopic approach, and where possible, requires circumferential dis-section. The posterior plane between the cyst and portal vein must be carefully dissected to accomplish removal. The pancreatic duct, which may enter the distal cyst, is vulnerable to injury dur-ing distal cyst excision but can be avoided by avoiding entry into the pancreatic parenchyma. In cases were the degree of pericystic inflammation is dense, it may be unsafe to attempt complete cyst removal. In this instance, it is reasonable to dissect within the posterior wall of the cyst, which allows the inner lining of the back wall to be dissected free from the outer layer that directly overlies the portal vascular structures. The lateral and anterior cyst, as well as the internal aspect of the back wall, is removed, yet the outer posterior wall remains behind. Cyst excision is accomplished, and the proximal bile duct is anastomosed to the intestinal tract typically via a Roux-en Y limb of jejunum. More recently, laparoscopic-assisted resections of choledochal cysts have been described. In these cases, the end-to-side jejunojeju-nostomy is performed extracorporeally, but the remainder of the procedure is completed utilizing minimally invasive techniques.The prognosis for children who have undergone com-plete excision of choledochal cyst is excellent. Complications include anastomotic stricture, cholangitis, and intrahepatic stone Brunicardi_Ch39_p1705-p1758.indd 173912/02/19 11:26 AM 1740SPECIFIC CONSIDERATIONSPART IIformation. These complications may develop a long time after surgery has been completed.DEFORMITIES OF THE ABDOMINAL WALLEmbryology of the Abdominal WallThe abdominal wall is formed by four separate embryologic folds: cephalic, caudal, right, and left lateral folds. Each of these is com-posed of somatic and splanchnic layers and develops toward the anterior center portion of the coelomic cavity, joining to form a large umbilical ring that surrounds the two umbilical arteries, the vein, and the yolk sac or omphalomesenteric duct. These struc-tures are covered by an outer layer of amnion, and the entire unit composes the umbilical cord. Between the 5th and tenth weeks of fetal development, the intestinal tract undergoes rapid growth outside the abdominal cavity within the proximal portion of the umbilical cord. As development is completed, the intestine gradu-ally returns to the abdominal cavity. Contraction of the umbilical ring completes the process of abdominal wall formation.Failure of the cephalic fold to close results in sternal defects such as congenital absence of the sternum. Failure of the caudal fold to close results in exstrophy of the bladder and, in more extreme cases, exstrophy of the cloaca. Interruption of central migration of the lateral folds results in omphalocele. Gastroschisis, originally thought to be a variant of omphalocele, possibly results from a fetal accident in the form of intrauterine rupture of a hernia of the umbilical cord, although other hypoth-eses have been advanced.Umbilical HerniaFailure of the umbilical ring to close results in a central defect in the linea alba. The resulting umbilical hernia is covered by nor-mal umbilical skin and subcutaneous tissue, but the fascial defect allows protrusion of abdominal contents. Hernias less than a cen-timeter in size at the time of birth usually will close spontaneously by 4 to 5 years of life and in most cases should not undergo early repair. Sometimes the hernia is large enough that the protrusion is disfiguring and disturbing to both the child and the family. In such circumstances, early repair may be advisable (Fig. 39-28).Figure 39-28. Umbilical hernia in a 1-year-old female.Umbilical hernias are generally asymptomatic protrusions of the abdominal wall. They are generally noted by parents or physicians shortly after birth. All families of patients with umbilical hernia should be counseled about signs of incarcera-tion, which is rare in umbilical hernias and more common in smaller (1 cm or less) rather than larger defects. Incarceration presents with abdominal pain, bilious emesis, and a tender, hard mass protruding from the umbilicus. This constellation of symp-toms mandates immediate exploration and repair of the hernia to avoid strangulation. More commonly, the child is asymptomatic and treatment is governed by the size of the defect, the age of the patient, and the concern that the child and family have regard-ing the cosmetic appearance of the abdomen. When the defect is small and spontaneous closure is likely, most surgeons will delay surgical correction until 5 years of age. If closure does not occur by this time or a younger child has a very large or symp-tomatic hernia, it is reasonable to proceed to repair.Repair of uncomplicated umbilical hernia is performed under general anesthesia as an outpatient procedure. A small curving incision that fits into the skin crease of the umbilicus is made, and the sac is dissected free from the overlying skin. The fascial defect is repaired with permanent or long-lasting absorb-able, interrupted sutures that are placed in a transverse plane. The skin is closed using subcuticular sutures. The postoperative recovery is typically uneventful and recurrence is rare, but it is more common in children with elevated intraabdominal pres-sures, such as those with a VP shunt.Patent UrachusDuring the development of the coelomic cavity, there is free communication between the urinary bladder and the abdominal wall through the urachus, which exits adjacent to the omphalo-mesenteric duct. Persistence of this tract results in a communi-cation between the bladder and the umbilicus. The first sign of a patent urachus is moisture or urine flow from the umbilicus. Recurrent urinary tract infection can result. The urachus may be partially obliterated, with a remnant beneath the umbilicus in the extraperitoneal position as an isolated cyst that may be identi-fied by US. A urachal cyst usually presents as an inflammatory mass inferior to the umbilicus. Initial treatment is drainage of the infected cyst followed by cyst excision as a separate proce-dure once the inflammation has resolved.In the child with a persistently draining umbilicus, a diag-nosis of patent urachus should be considered. The differential diagnosis includes an umbilical granuloma, which generally responds to local application of silver nitrate. The diagnosis of patent urachus is confirmed by umbilical exploration. The ura-chal tract is excised and the bladder is closed with an absorbable suture. A patent vitelline duct may also present with umbilical drainage. In this circumstance, there is a communication with the small intestine, often at the site of a Meckel’s diverticulum. Treatment includes umbilical exploration with resection of the duct remnant (Fig. 39-29).OmphalocelePresentation. Omphalocele refers to a congenital defect of the abdominal wall in which the bowel and solid viscera are covered by peritoneum and amniotic membrane (Fig. 39-30). The umbil-ical cord inserts into the sac. Omphalocele can vary from a small defect with intestinal contents to giant omphalocele in which the abdominal wall defect measures 4 cm or more in diameter and contains liver. The overall incidence is approximately 1 in 5000 Brunicardi_Ch39_p1705-p1758.indd 174012/02/19 11:26 AM 1741PEDIATRIC SURGERYCHAPTER 39Figure 39-29. Patent vitelline duct. Note the communication between the umbilicus and the small bowel at the site of a Meckel’s diverticulum.Figure 39-30. Giant omphalocele in a newborn male.live births, with 1 in 10,000 that are giant omphaloceles. Omphalocele occurs in association with special syndromes such as exstrophy of the cloaca (vesicointestinal fissure), the Beckwith-Wiedemann constellation of anomalies (macroglos-sia, macrosomia, hypoglycemia, and visceromegaly and omphalocele) and Cantrell’s Pentalogy (lower thoracic wall malformations [cleft sternum], ectopia cordis, epigastric omphalocele, anterior midline diaphragmatic hernia and cardiac anomalies). There is a 60% to 70% incidence of associated anomalies, especially cardiac (20–40% of cases) and chromo-somal abnormalities. Chromosomal anomalies are more common in children with smaller defects. Omphalocele is associated with prematurity (10–50% of cases) and intrauterine growth restriction (20% of cases).Treatment. Immediate treatment of an infant with omphalocele consists of attending to the vital signs and maintaining the body 8temperature. A blood glucose should be evaluated because of the association with Beckwith-Wiedemann. The omphalocele should be covered to reduce fluid loss, but moist dressings may result in heat loss and are not indicated. No pressure should be placed on the omphalocele sac in an effort to reduce its contents because this maneuver may increase the risk of rupture of the sac or may interfere with abdominal venous return. Prophylac-tic broad-spectrum antibiotics should be administered in case of rupture. The subsequent treatment and outcome is determined by the size of the omphalocele. In general terms, small to medium-sized defects have a significantly better prognosis than extremely large defects in which the liver is present. In these cases, not only is the management of the abdominal wall defect a significant challenge, but these patients often have concomitant pulmonary insufficiency that can lead to significant morbidity and mortality. If possible, and if the pulmonary status will permit it, a primary repair of the omphalocele should be undertaken. This involves resection of the omphalocele membrane and closure of the fas-cia. A layer of prosthetic material may be required to achieve closure. In infants with a giant omphalocele, the defect cannot be closed primarily because there is not adequate intraperitoneal domain to reduce the viscera (see Fig. 39-30). Some infants may have associated congenital anomalies that complicate surgical repair, and because cardiac anomalies are common, an echocar-diogram should be obtained prior to any procedure. If repair is contraindicated, such as with a very large defect, a nonopera-tive approach can be used. The omphalocele sac can be treated with topical treatments, which serve to harden the sac to allow for more protective coverage where muscle and skin cannot be used given the large defect. Various authors describe success with iodine-containing solutions, silver sulfadiazine, or saline, and some surgeons rotate these solutions because of the impact of iodine on the thyroid and the difficulty of cleaning off all of the silver sulfadiazine and its association with leukopenia. It typically takes 2 to 3 months before reepithelialization occurs. In the past, mercury compounds were used, but they have been discontinued because of associated systemic toxicity. After epi-thelialization has occurred, attempts should be made to achieve closure of the anterior abdominal wall but may be delayed by associated pulmonary insufficiency. Such procedures typically require complex measures to achieve skin closure, including the use of biosynthetic materials or component separation. In cases of giant omphalocele, prolonged hospitalization is typical. If the base is very narrow—which can occur even for babies with very large omphaloceles—it may be wise to open the base in order to allow the abdominal contents and the liver to reenter the abdominal cavity, and thereby achieve abdominal domain. This approach will, by necessity, require sewing in some synthetic material in order to achieve fascial closure, and prolonged hos-pitalization will be required to allow for skin coverage to occur. These patients require high amounts of caloric support, given the major demands for healing.GastroschisisPresentation. Gastroschisis represents a congenital anom-aly characterized by a defect in the anterior abdominal wall through which the intestinal contents freely protrude. Unlike omphalocele, there is no overlying sac, and the size of the defect is usually <4 cm. The abdominal wall defect is located at the junction of the umbilicus and normal skin, and is almost always to the right of the umbilicus (Fig. 39-31). The umbilicus becomes partly detached, allowing free communication with the Brunicardi_Ch39_p1705-p1758.indd 174112/02/19 11:26 AM 1742SPECIFIC CONSIDERATIONSPART IIFigure 39-31. Gastroschisis in a newborn. Note the location of the umbilical cord and the edematous, thickened bowel.Figure 39-32. Prenatal ultrasound of a 30-week gestation age fetus with a gastroschisis. Arrows point to the bowel outside within the amniotic fluid.Figure 39-33. Use of a silo in a patient with a gastroschisis to allow for the bowel wall edema to resolve so as to facilitate closure of the abdominal wall.abdominal cavity. The appearance of the bowel provides some information with respect to the in-utero timing of the defect. The intestine may be normal in appearance, suggesting that the rupture occurred relatively late during the pregnancy. More commonly, however, the intestine is thick, edematous, discol-ored, and covered with exudate, implying a more longstanding process. Progression to full enteral feeding is usually delayed, with diminished motility that may be related to these changes.Unlike infants born with omphalocele, associated anoma-lies are not usually seen with gastroschisis except for a 10% rate of intestinal atresia. This defect can readily be diagnosed on prenatal US (Fig. 39-32). There is no advantage to perform-ing a cesarean section instead of a vaginal delivery. In a decade long retrospective review, early deliver did not affect the thick-ness of bowel peel, yet patients delivered before 36 weeks had significantly longer length of stay in the hospital and time to enteral feeds. Based upon these findings, it is thought that fetal well-being should be the primary determinant of delivery for gastroschisis.Treatment. All infants born with gastroschisis require urgent surgical treatment. Of equal importance, these infants require vigorous fluid resuscitation in the range of 160 to 190 cc/kg per day to replace significant evaporative fluid losses. In many instances, the intestine can be returned to the abdominal cavity, and a primary surgical closure of the abdominal wall is per-formed. Some surgeons believe that they facilitate primary closure with mechanical stretching of the abdominal wall, thor-ough orogastric suctioning with foregut decompression, rectal irrigation, and evacuation of meconium. Care must be taken to prevent markedly increased abdominal pressure during the reduction, which will lead to compression of the inferior vena cava, respiratory embarrassment, and abdominal compartment syndrome. To avoid this complication, it is helpful to moni-tor the bladder or airway pressures during reduction. In infants whose intestine has become thickened and edematous, it may be impossible to reduce the bowel into the peritoneal cavity in the immediate postnatal period. Under such circumstances, a plastic spring-loaded silo can be placed onto the bowel and secured beneath the fascia or a sutured silastic silo constructed. The silo covers the bowel and allows for graduated reduc-tion on a daily basis as the edema in the bowel wall decreases (Fig. 39-33). It is important to ensure that the silo-fascia junc-tion does not become a constricting point or “funnel,” in which case the intestine will be injured upon return to the peritoneum. In this case, the fascial opening must be enlarged. Surgical clo-sure can usually be accomplished within approximately 1 to 2 weeks. A prosthetic piece of material may be required to bring the edges of the fascia together. If an atresia is noted at the time of closure, it is prudent to reduce the bowel at the first operation and return after several weeks once the edema has resolved to correct the atresia. Intestinal function does not typically return for several weeks in patients with gastroschisis. This is especially true if the bowel is thickened and edematous. As a result, these patients will require central line placement and institution of total parenteral nutrition in order to grow. Feeding advancement should be slow and typically requires weeks to arrive at full enteral nutrition.Brunicardi_Ch39_p1705-p1758.indd 174212/02/19 11:27 AM 1743PEDIATRIC SURGERYCHAPTER 39There has been recent success with the utilization of non-surgical closure of gastroschisis. In this technique, the umbili-cal cord is placed over the defect, which is then covered with a transparent occlusive dressing. Over the ensuing days, the cord provides a tissue barrier, and the defect spontaneously closes. This approach allows for nonsurgical coverage in a majority of cases of gastroschisis, even in the setting of very large openings. Questions remain regarding the long-term presence of umbilical hernias in these children and the total hospitalization.Prune-Belly SyndromeClinical Presentation. Prune-belly syndrome refers to a dis-order that is characterized by extremely lax lower abdominal musculature, dilated urinary tract including the bladder, and bilateral undescended testes (Fig. 39-34). The term prune-belly syndrome appropriately describes the wrinkled appearance of the anterior abdominal wall that characterizes these patients. Prune-belly syndrome is also known as Eagle-Barrett syn-drome as well as the triad syndrome because of the three major manifestations. The incidence is significantly higher in males. Patients manifest a variety of comorbidities. The most signifi-cant is pulmonary hypoplasia, which can be unsurvivable in the most severe cases. Skeletal abnormalities include dislocation or dysplasia of the hip and pectus excavatum.The major genitourinary manifestation in prune-belly syn-drome is ureteral dilation. The ureters are typically long and tortuous and become more dilated distally. Ureteric obstruction is rarely present, and the dilation may be caused by decreased smooth muscle and increased collagen in the ureters. Approxi-mately eighty percent of these patients will have some degree of vesicureteral reflux, which can predispose to urinary tract infection. Despite the marked dilatation of the urinary tract, most children with prune-belly syndrome have adequate renal parenchyma for growth and development. Factors associated with the development of long-term renal failure include the presence of abnormal kidneys on US or renal scan and persis-tent pyelonephritis.Treatment. Despite the ureteric dilation, there is currently no role for ureteric surgery unless an area of obstruction develops. The testes are invariably intraabdominal, and bilateral orchido-pexy can be performed in conjunction with abdominal wall recon-struction at 6 to 12 months of age. Despite orchiopexy, fertility in Figure 39-34. Eagle-Barrett (prune-belly) syndrome. Notice the lax, flaccid abdomen.a boy with prune-belly syndrome is unlikely as spermatogenesis over time is insufficient. Deficiencies in the production of pros-tatic fluid and a predisposition to retrograde ejaculation contrib-ute to infertility. Abdominal wall repair is accomplished through an abdominoplasty, which typically requires a transverse inci-sion in the lower abdomen extending into the flanks.Inguinal HerniaAn understanding of the management of pediatric inguinal her-nias is a central component of modern pediatric surgical prac-tice. Inguinal hernia repair represents one of the most common operations performed in children. The presence of an inguinal hernia in a child is an indication for surgical repair. The opera-tion is termed a herniorrhaphy because it involves closing off the patent processus vaginalis. This is to be contrasted with the hernioplasty that is performed in adults, which requires a recon-struction of the inguinal floor.Embryology. In order to understand how to diagnose and treat inguinal hernias in children, it is critical to understand their embryologic origin. It is very useful to describe these events to the parents, who often are under the misconception that the her-nia was somehow caused by their inability to console their crying child, or the child’s high activity level. Inguinal hernia results from a failure of closure of the processus vaginalis; a finger-like projection of the peritoneum that accompanies the testicle as it descends into the scrotum. Closure of the processus vaginalis normally occurs a few months prior to birth. This explains the high incidence of inguinal hernias in premature infants. When the processes vaginalis remains completely patent, a commu-nication persists between the peritoneal cavity and the groin, resulting in a hernia. Partial closure can result in entrapped fluid, which results in the presence of a hydrocele. A communicating hydrocele refers to a hydrocele that is in communication with the peritoneal cavity and can therefore be thought of as a hernia. Using the classification system that is typically applied to adult hernias, all congenital hernias in children are by definition indi-rect inguinal hernias. Children also present with direct inguinal and femoral hernias, although these are much less common.Clinical Manifestation. Inguinal hernias occur more com-monly in males than females (10:1) and are more common on the right side than the left. Infants are at high risk for incar-ceration of an inguinal hernia because of the narrow inguinal ring. Patients most commonly present with a groin bulge that is noticed by the parents as they change the diaper (Fig. 39-35). Figure 39-35. Right inguinal hernia in a 4-month-old male. The arrows point to the bulge in the right groin.Brunicardi_Ch39_p1705-p1758.indd 174312/02/19 11:27 AM 1744SPECIFIC CONSIDERATIONSPART IIOlder children may notice the bulge themselves. On examina-tion, the cord on the affected side will be thicker, and pressure on the lower abdomen usually will display the hernia on the affected side. The presence of an incarcerated hernia is mani-fested by a firm bulge that does not spontaneously resolve and may be associated with fussiness and irritability in the child. The infant that has a strangulated inguinal hernia will manifest an edematous, tender bulge in the groin, occasionally with over-lying skin changes. The child will eventually develop intestinal obstruction, peritonitis, and systemic toxicity.Usually an incarcerated hernia can be reduced. Occasion-ally this may require light sedation. Gentle pressure is applied on the sac from below in the direction of the internal inguinal ring. Following reduction of the incarcerated hernia, the child may be admitted for observation, and herniorrhaphy is per-formed within the next 24 hours to prevent recurrent incarcera-tion. Alternatively, the child may be scheduled for surgery at the next available time slot. If the hernia cannot be reduced, or if evidence of strangulation is present, emergency operation is necessary. This may require a laparotomy and bowel resection.When the diagnosis of inguinal hernia is made in an oth-erwise normal child, operative repair should be planned. Spon-taneous resolution does not occur, and therefore a nonoperative approach cannot ever be justified. An inguinal hernia in a female infant or child frequently contains an ovary rather than intestine. Although the gonad usually can be reduced into the abdomen by gentle pressure, it often prolapses in and out until surgical repair is carried out. In some patients, the ovary and fallopian tube constitute one wall of the hernial sac (sliding hernia), and in these patients, the ovary can be reduced effectively only at the time of operation. If the ovary is irreducible, prompt hernia repair is indicated to prevent ovarian torsion or strangulation.When a hydrocele is diagnosed in infancy and there is no evidence of a hernia, observation is proper therapy until the child is older than 12 months. If the hydrocele has not disappeared by 12 months, invariably there is a patent processus vaginalis, and operative hydrocelectomy with excision of the processus vaginalis is indicated. When the first signs of a hydrocele are seen after 12 months of age, the patient should undergo elective hydrocelectomy, which in a child is always performed through a groin incision. Aspiration of hydroceles is discouraged because almost all without a patent processus vaginalis will resorb spon-taneously and those with a communication to the peritoneum will recur and require operative repair eventually. Transillumi-nation as a method to distinguish between hydrocele and hernia is nonspecific. A noncommunicating hydrocele is better identi-fied by palpation of a nonreducible oval structure that appears to have a blunt end below the external ring, indicating an isolated fluid collection without a patent connection to the peritoneum.Surgical Repair. The repair of a pediatric inguinal hernia can be extremely challenging, particularly in the premature child with incarceration. A small incision is made in a skin crease in the groin directly over the internal inguinal ring. Scarpa’s fascia is seen and divided. The external oblique muscle is dis-sected free from overlying tissue, and the location of the exter-nal ring is confirmed. The external oblique aponeurosis is then opened along the direction of the external oblique fibers over the inguinal canal. The undersurface of the external oblique is then cleared from surrounding tissue. The cremasteric fibers are separated from the cord structures and hernia sac, and these are then elevated into the wound. Care is taken not to grasp the vas deferens. The hernia sac is then dissected up to the internal ring and doubly suture ligated. The distal part of the hernia sac is opened widely to drain any hydrocele fluid. When the hernia is very large and the patient very small, tightening of the internal inguinal ring or even formal repair of the inguinal floor may be necessary, although the vast majority of children do not require any treatment beyond high ligation of the hernia sac.Controversy exists regarding the role for exploration of an asymptomatic opposite side in a child with an inguinal hernia. Several reports indicate that frequency of a patent processus vaginalis on the side opposite the obvious hernia is approxi-mately 30%, although this figure decreases with increasing age of the child. Management options include never exploring the opposite side, to exploring only under certain conditions such as in premature infants or in patients in whom incarceration is pres-ent. The opposite side may readily be explored laparoscopically. To do so, a blunt 3-mm trochar is placed into the hernia sac of the affected side. The abdominal cavity is insufflated, and the 2.7-mm 70° camera is placed through the trochar such that the opposite side is visualized. The status of the processes vaginalis on the opposite side can be visualized. However, the presence of a patent processus vaginalis by laparoscopy does not always imply the presence of a hernia.There has been quite widespread adoption of laparoscopic approach in the management of inguinal hernias in children, especially those under the age of 2 years. This technique requires insufflation through the umbilicus and the placement of an extra-peritoneal suture to ligate the hernia sac. Proponents of this pro-cedure emphasize the fact that no groin incision is used, so there is a decreased chance of injuring cord structures, and that visu-alization of the contralateral side is achieved immediately. The long-term results of this technique have been quite excellent.Inguinal hernias in children recur in less than 1% of patients, and recurrences usually result from missed hernia sacs at the first procedure, a direct hernia, or a missed femoral hernia. All children should have local anesthetic administered either by caudal injection or by direct injection into the wound. Spinal anesthesia in preterm infant decreases the risk of postoperative apnea when compared with general anesthesia.GENITALIAUndescended testisEmbryology. The term undescended testicle (cryptorchidism) refers to the interruption of the normal descent of the testis into the scrotum. The testicle may reside in the retroperineum, in the internal inguinal ring, in the inguinal canal, or even at the external ring. The testicle begins as a thickening on the uro-genital ridge in the fifth to sixth week of embryologic life. In the seventh and eighth months, the testicle descends along the inguinal canal into the upper scrotum, and with its progress the processus vaginalis is formed and pulled along with the migrat-ing testicle. At birth, approximately 95% of infants have the testicle normally positioned in the scrotum.A distinction should be made between an undescended testicle and an ectopic testicle. An ectopic testis, by definition, is one that has passed through the external ring in the normal pathway and then has come to rest in an abnormal location over-lying either the rectus abdominis or external oblique muscle, or the soft tissue of the medial thigh, or behind the scrotum in the perineum. A congenitally absent testicle results from failure of normal development or an intrauterine accident leading to loss of blood supply to the developing testicle.Brunicardi_Ch39_p1705-p1758.indd 174412/02/19 11:27 AM 1745PEDIATRIC SURGERYCHAPTER 39Clinical Presentation. The incidence of undescended testes is approximately 30% in preterm infants, and 1% to 3% at term. For diagnosis, the child should be examined in the supine posi-tion, where visual inspection may reveal a hypoplastic or poorly rugated scrotum. Usually a unilateral undescended testicle can be palpated in the inguinal canal or in the upper scrotum. Occa-sionally, the testicle will be difficult or impossible to palpate, indicating either an abdominal testicle or congenital absence of the gonad. If the testicle is not palpable in the supine position, the child should be examined with his legs crossed while seated. This maneuver diminishes the cremasteric reflex and facilitates identification of the location of the testicle. If there is uncer-tainty regarding location of a testis, repeated evaluations over time may be helpful.It is now established that cryptorchid testes demonstrate an increased predisposition to malignant degeneration. In addition, fertility is decreased when the testicle is not in the scrotum. For these reasons, surgical placement of the testicle in the scrotum (orchidopexy) is indicated. It should be emphasized that this procedure does improve the fertility potential, although it is never normal. Similarly, the testicle is still at risk of malignant change, although its location in the scrotum facilitates poten-tially earlier detection of a testicular malignancy. Other reasons to consider orchidopexy include the risk of trauma to the testicle located at the pubic tubercle and incidence of torsion, as well as the psychological impact of an empty scrotum in a developing male. The reason for malignant degeneration is not established, but the evidence points to an inherent abnormality of the testicle that predisposes it to incomplete descent and malignancy rather than malignancy as a result of an abnormal environment.Treatment. Males with bilateral undescended testicles are often infertile. When the testicle is not present within the scrotum, it is subjected to a higher temperature, resulting in decreased spermatogenesis. Mengel and coworkers studied 515 undescended testicles by histology and demonstrated reduced spermatogonia after 2 years of age. It is now recommended that the undescended testicle be surgically repositioned by 1 year of age. Despite orchidopexy, the incidence of infertility is approx-imately two times higher in men with unilateral orchidopexy compared to men with normal testicular descent.The use of chorionic gonadotropin occasionally may be effective in patients with bilateral undescended testes, suggest-ing that these patients are more apt to have a hormone insuf-ficiency than children with unilateral undescended testicle. The combination of micro-penis and bilateral undescended testes is an indication for hormonal evaluation and testoster-one replacement if indicated. If there is no testicular descent after a month of endocrine therapy, operative correction should be undertaken. A child with unilateral cryptorchidism should have surgical correction of the problem. The operation is typi-cally performed through a combined groin and scrotal incision. The cord vessels are fully mobilized, and the testicle is placed in a dartos pouch within the scrotum. An inguinal hernia often accompanies a cryptorchid testis. This should be repaired at the time of orchidopexy.Patients with a nonpalpable testicle present a challenge in management. The current approach involves laparoscopy to identify the location of the testicle. If the spermatic cord is found to traverse the internal ring or the testis is found at the ring and can be delivered into the scrotum, a groin incision is made and an orchidopexy is performed. If an abdominal testis is identified that is too far to reach the scrotum, a two-staged Fowler-Stephens approach is used. In the first stage, the testicular vessels are clipped laparoscopically, which promotes the development of new blood vessels along the vas deferens. Several months later, the second stage is performed during which the testis is mobilized laparoscopically along with a swath of peritoneum with collateralized blood supply along the vas. Preservation of the gubernacular attachments with its collaterals to the testicle may confer improved testicular survival following orchidopex in over 90%. It is, nonetheless, preferable to preserve the testicular vessels whenever possible and complete mobilization of the testicle with its vessels intact.Vaginal AnomaliesSurgical diseases of the vagina in children are either congenital or acquired. Congenital anomalies include a spectrum of dis-eases that range from simple defects (imperforate hymen) to more complex forms of vaginal atresia, including distal, proxi-mal, and, most severe, complete. These defects are produced by abnormal development of müllerian ducts and/or urogenital sinus. The diagnosis is made most often by physical examina-tion. Secretions into the obstructed vagina produce hydrocol-pos, which may present as a large, painful abdominal mass. The anatomy may be defined using US. Pelvic magnetic resonance imaging provides the most thorough and accurate assessment of the pelvic structures. Treatment is dependent on the extent of the defect. For an imperforate hymen, division of the hymen is curative. More complex forms of vaginal atresia require mobi-lization of the vaginal remnants and creation of an anastomosis at the perineum. Laparoscopy can be extremely useful, both in mobilizing the vagina, in draining hydrocolpos, and in evaluat-ing the internal genitalia. Complete vaginal atresia requires the construction of skin flaps or the creation of a neovagina using a segment of colon.The most common acquired disorder of the vagina is the straddle injury. This often occurs as young girls fall on blunt objects which cause a direct injury to the perineum. Typical manifestations include vaginal bleeding and inability to void. Unless the injury is extremely superficial, patients should be examined in the operating room where the lighting is optimal and sedation can be administered. Examination under anesthe-sia is particularly important in girls who are unable to void, suggesting a possible urethral injury. Vaginal lacerations are repaired using absorbable sutures, and the proximity to the ure-thra should be carefully assessed. Prior to hospital discharge, it is important that girls are able to void spontaneously. In all cases of vaginal trauma, it is essential that the patient be assessed for the presence of sexual abuse. In these cases, early contact with the sexual abuse service is necessary so that the appropriate microbiologic and photographic evidence can be obtained.Ovarian Cysts and TumorsPathologic Classification. Ovarian cysts and tumors may be classified as nonneoplastic or neoplastic. Nonneoplastic lesions include cysts (simple, follicular, inclusion, paraovarian, or cor-pus luteum), endometriosis, and inflammatory lesions. Neo-plastic lesions are classified based on the three primordia that contribute to the ovary: mesenchymal components of the uro-genital ridge, germinal epithelium overlying the urogenital ridge, and germ cells migrating from the yolk sac. The most common variety is germ cell tumors. Germ cell tumors are classified based on the degree of differentiation and the cellular components Brunicardi_Ch39_p1705-p1758.indd 174512/02/19 11:27 AM 1746SPECIFIC CONSIDERATIONSPART IIinvolved. The least differentiated tumors are the dysgermino-mas, which share features similar to the seminoma in males. Although these are malignant tumors, they are extremely sensi-tive to radiation and chemotherapy. The most common germ cell tumors are the teratomas, which may be mature, immature, or malignant. The degree of differentiation of the neural elements of the tumor determines the degree of immaturity. The sex cord stromal tumors arise from the mesenchymal components of the urogenital ridge. These include the granulosa-theca cell tumors and the Sertoli-Leydig cell tumors. These tumors often produce hormones that result in precocious puberty or hirsutism, respec-tively. Although rare, epithelial tumors do occur in children. These include serous and mucinous cystadenomas.Clinical Presentation. Children with ovarian lesions usually present with abdominal pain. Other signs and symptoms include a palpable abdominal mass, evidence of urinary obstruction, symp-toms of bowel obstruction, and endocrine imbalance. The surgical approach depends on the appearance of the mass at operation (i.e., whether it is benign-appearing or is suspicious for malignancy). In the case of a simple ovarian cyst, surgery depends on the size of the cyst and the degree of symptoms it causes. In general, large cysts (over 4–5 cm) in size should be resected, as they are unlikely to resolve, may be at risk of torsion, and may mask an underlying malignancy. Resection may be performed laparoscopically, and ovarian tissue should be spared in all cases.Surgical Management. For ovarian lesions that appear malignant, it is important to obtain tumor markers including α-fetoprotein (teratomas), LDH (dysgerminoma), β-human cho-rionic gonadotropin (choriocarcinoma), and CA-125 (epithelial tumors). Although the diagnostic sensitivity of these markers is not always reliable, they provide material for postoperative follow-up and indicate the response to therapy. When a malig-nancy is suspected, the patient should undergo a formal cancer operation. This procedure is performed through either a mid-line incision or a Pfannenstie approach. Ascites and peritoneal washings should be collected for cytologic study. The liver and diaphragm are inspected carefully for metastatic disease. An omentectomy is performed if there is any evidence of tumor present. Pelvic and para-aortic lymph nodes are biopsied, and the primary tumor is resected completely. Finally, the contra-lateral ovary is carefully inspected, and if a lesion is seen, it should be biopsied. Dysgerminomas and epithelial tumors may be bilateral in up to 15% of cases. The surgical approach for a benign lesion of the ovary should include preservation of the ipsi-lateral fallopian tube and preservation of the noninvolved ovary.Ovarian Cysts in the Newborn. Ovarian cysts may be detected by prenatal US. The approach to lesions less than 4 cm should include serial US evaluation every 2 months or so as many of these lesions will resolve spontaneously. Consid-eration should be given to laparoscopic excision of cysts larger than 4 cm to avoid the risks of ovarian torsion or development of abdominal symptoms. For smaller lesions, resolution occurs by approximately 6 months of age. A laparoscopic approach is preferable in these cases. By contrast, complex cysts of any size require surgical intervention at presentation to exclude the pos-sibility of malignancy.Ambiguous GenitaliaEmbryology. Normal sexual differentiation occurs in the sixth fetal week. In every fetus, wolffian (male) and müllerian (female) ducts are present until the onset of sexual differentiation. Normal sexual differentiation is directed by the sex determining region of the Y chromosome (SRY). This is located on the distal end of the short arm of the Y chromosome. SRY provides a genetic switch that initiates gonadal differentiation in the mammalian urogenital ridge. Secretion of Müllerian-inhibiting substance (MIS) by the Sertoli cells of the seminiferous tubules results in regression of the müllerian duct, the anlage of the uterus, Fal-lopian tubes, and the upper vagina. The result of MIS secretion therefore is a phenotypic male. In the absence of SRY in the Y chromosome, MIS is not produced, and the müllerian duct derivatives are preserved. Thus, the female phenotype prevails.In order for the male phenotype to develop, the embryo must have a Y chromosome, the SRY must be normal with-out point mutations or deletions, testosterone and MIS must be produced by the differentiated gonad, and the tissues must respond to these hormones. Any disruption of the orderly steps in sexual differentiation may be reflected clinically as variants of the intersex syndromes.These may be classified as (a) true hermaphroditism (with ovarian and testicular gonadal tissue), (b) male pseudohermaph-roditism (testicles only), (c) female pseudohermaphroditism (ovarian tissue only), and (d) mixed gonadal dysgenesis (usually underdeveloped or imperfectly formed gonads).True Hermaphroditism This represents the rarest form of ambiguous genitalia. Patients have both normal male and female gonads, with an ovary on one side and a testis on the other. Occasionally, an ovotestis is present on one or both sides. The majority of these patients have a 46,XX karyotype. Both the tes-tis and the testicular portion of the ovotestis should be removed.Male Pseudohermaphroditism This condition occurs in infants with an XY karyotype but deficient masculinization of the external genitalia. Bilateral testes are present, but the duct structures differentiate partly as phenotypic females. The causes include inadequate testosterone production due to biosynthetic error, inability to convert testosterone to dihy-drotestosterone due to 5α-reductase deficiency or deficiencies in androgen receptors. The latter disorder is termed testicular feminization syndrome. Occasionally, the diagnosis in these children is made during routine inguinal herniorrhaphy in a phenotypic female at which time testes are found. The testes should be resected due to the risk of malignant degeneration, although this should be performed only after a full discussion with the family has occurred.Female Pseudohermaphroditism The most common cause of female pseudohermaphroditism is congenital adrenal hyper-plasia. These children have a 46,XX karyotype but have been exposed to excessive androgens in utero. Common enzyme deficiencies include 21-hydroxylase, 11-hydroxylase, and 3β-hydroxysteroid dehydrogenase. These deficiencies result in overproduction of intermediary steroid hormones, which results in masculinization of the external genitalia of the XX fetus. These patients are unable to synthesize cortisol. In 90% of cases, deficiency of 21-hydroxylase causes adrenocorticotropic hor-mone (ACTH) to stimulate the secretion of excessive quantities of adrenal androgen, which masculinizes the developing female (Fig. 39-36). These infants are prone to salt loss, and require cortisol replacement. Those with mineralocorticoid deficiency also require fluorocortisone replacement.Mixed Gonadal Dysgenesis This syndrome is associated with dysgenetic gonads and retained mullerian structures. The typical karyotype is mosaic, usually 45XO,46XY. A high incidence of Brunicardi_Ch39_p1705-p1758.indd 174612/02/19 11:27 AM 1747PEDIATRIC SURGERYCHAPTER 39Figure 39-36. Ambiguous genitalia manifest as enlarged clitoris and labioscrotal folds in a baby with the adrenogenital syndrome.malignant tumors occur in the dysgenetic gonads, most com-monly gonadoblastoma. Therefore, they should be removed.Management. In the differential diagnosis of patients with intersex anomalies, the following diagnostic steps are necessary: (a) evaluation of the genetic background and family history; (b) assessment of the anatomic structures by physical exami-nation, US, and/or chromosome studies; (c) determination of biochemical factors in serum and urine to evaluate the presence of an enzyme defect; and (d) laparoscopy for gonadal biopsy. Treatment should include correction of electrolyte and volume losses, in cases of congenital adrenal hyperplasia, and replace-ment of hormone deficiency. Surgical assignment of gender should never be determined at the first operation. Although his-torically female gender had been assigned, there is abundant and convincing evidence that raising a genotypic male as a female has devastating consequences, not only anatomically but also psychosocially. This is particularly relevant given the role of preand postnatal hormones on gender imprinting and identity. In general terms, surgical reconstruction should be performed after a full genetic workup and with the involvement of pediatric endocrinologists, pediatric plastic surgeons, and ethicists with expertise in gender issues. Discussion with the family also plays an important role. This approach will serve to reduce the anxi-ety associated with these disorders and will help to ensure the normal physical and emotional development of these patients.PEDIATRIC MALIGNANCYCancer is the second leading cause of death in children after trauma and accounts for approximately 11% of all pediatric deaths in the United States. The following description will be restricted to the most commonly encountered tumors in children.Wilms’ TumorClinical Presentation. Wilms’ tumor is the most common primary malignant tumor of the kidney in children. There are approximately 500 new cases annually in the United States, and most are diagnosed between 1 and 5 years with the peak inci-dence at age 3. Advances in the care of patients with Wilms’ tumor has resulted in an overall cure rate of roughly 90%, even in the presence of metastatic spread. The tumor usually develops in otherwise healthy children as an asymptomatic mass in the flank or upper abdomen. Frequently, the mass is discovered by a parent while bathing or dressing the child. Other symptoms include hypertension, hematuria, obstipation, and weight loss. Occasionally the mass is discovered following blunt abdominal trauma.Genetics of Wilms’ Tumor. Wilms’ tumor can arise from both germline and somatic mutations and can occur in the presence or absence of a family history. Nearly 97% of Wilms’ tumors are sporadic in that they occur in the absence of a heritable or congenital cause or risk factor. When a heritable risk factor is identified, the affected children often present at an earlier age, and the tumors are frequently bilateral. Most of these tumors are associated with germline mutations. It is well established that there is a genetic predisposition to Wilms’ tumor in WAGR syndrome, which consists of Wilms’ tumor, aniridia, genitouri-nary abnormalities, and mental retardation. In addition, there is an increased incidence of Wilms’ tumor in certain overgrowth conditions, particularly Beckwith–Wiedemann syndrome and hemihypertrophy. WAGR syndrome has been shown to result from the deletion of one copy each of the Wilms’ tumor gene, WT1, and the adjacent aniridia gene, PAX6, on chromosome 11p13. Beckwith–Wiedemann syndrome is an overgrowth syn-drome that is characterized by visceromegaly, macroglossia, and hyperinsulinemic hypoglycemia. It arises from mutations at the 11p15.5 locus. There is evidence to suggest that analysis of the methylation status of several genes in the 11p15 locus could predict the individual risk to the development of Wilms’ tumor. Importantly, most patients with Wilms’ tumor do not have mutations at these genetic loci.Surgical Treatment. Before operation, all patients suspected of having Wilms’ tumor should undergo abdominal and chest computerized tomography. These studies characterize the mass, identify the presence of metastases, and provide information on the opposite kidney (Fig. 39-37). CT scanning also indicates the presence of nephrogenic rests, which are precursor lesions to Wilms’ tumor. An abdominal US should be performed to evalu-ate the presence of renal vein or vena caval extension.The management of patients with Wilms’ tumor has been carefully analyzed within the context of large studies involving thousands of patients. These studies have been coordinated by the National Wilms’ Tumor Study Group (NWTSG) in North America and the International Society of Paediatric Oncology Figure 39-37. Wilms’ tumor of the right kidney (arrow) in a 3-year-old girl.Brunicardi_Ch39_p1705-p1758.indd 174712/02/19 11:27 AM 1748SPECIFIC CONSIDERATIONSPART IITable 39-3Staging of Wilms’ tumorStage I: Tumor limited to the kidney and completely excised.Stage II: Tumor that extends beyond the kidney but is completely excised. This includes penetration of the renal capsule, invasion of the soft tissues of the renal sinus, or blood vessels within the nephrectomy specimen outside the renal parenchyma containing tumor. No residual tumor is apparent at or beyond the margins of excision.a Stage III: Residual nonhematogenous tumor confined to the abdomen. Lymph nodes in the abdomen or pelvis contain tumor. Peritoneal contamination by the tumor, such as by spillage or biopsy of tumor before or during surgery. Tumor growth that has penetrated through the peritoneal surface. Implants are found on the peritoneal surfaces. Tumor extends beyond the surgical margins either microscopically or grossly. Tumor is not completely resectable because of local infiltration into vital structures. The tumor was treated with preoperative chemotherapy with or without biopsy. Tumor is removed in greater than one piece.Stage IV: Hematogenous metastases or lymph node involvement outside the abdomino-pelvic region.Stage V: Bilateral renal involvement.International Neuroblastoma Staging SystemStage 1: Localized tumor with complete gross resection, with or without microscopic residual diseaseStage 2A: Localized tumor with incomplete gross excision; representative ipsilateral nonadherent lymph nodes negative for tumorStage 2B: Localized tumor with or without complete gross excision, with ipsilateral nonadherent lymph nodes positive for tumor. Enlarged contralateral lymph nodes must be negative microscopicallyStage 3: Unresectable unilateral tumor crossing midline, with or without regional lymph node involvement; or localized unilateral tumor with contralateral regional lymph node involvement; or midline tumorStage 4: Any primary tumor with dissemination to distant lymph nodes, bone, bone marrow, liver, skin, and/or other organsStage 4S: In infants <1 year of age; localized primary tumor with dissemination limited to skin, liver, and/or bone marrowInternational Neuroblastoma Risk Group Staging SystemL1 Localized tumor not involving vital structures as defined by the list of IDRFs and confined to one body compartmentL2 Locoregional tumor with the presence of one or more IDRFsM Distant metastatic disease (except MS)MS Metastatic disease in children <18 months confined to skin, liver, and bone marrow aRupture or spillage confined to the flank, including biopsy of the tumor, is no longer included in stage II and is now included in stage III.(SIOP), mainly involving European countries. Significant dif-ferences in the approach to patients with Wilms’ tumor have been highlighted by these studies. NWTSG supports a strat-egy of surgery followed by chemotherapy in most instances, whereas the SIOP approach is to shrink the tumor using preoper-ative chemotherapy. There are instances were preoperative che-motherapy is supported by both groups, including the presence of bilateral involvement or inferior vena cava involvement that extends above the hepatic veins and involvement of a solitary kidney by Wilms’ tumor. The NWTSG proponents argue that preoperative therapy in other instances results in a loss of impor-tant staging information, and therefore places patients at higher risk for recurrence; alternatively, it may lead to overly aggres-sive treatment in some cases and greater morbidity. However, the overall survival rates are not different between the NWTSG and SIOP approaches.The goal of surgery is complete removal of the tumor. It is crucial to avoid tumor rupture or injury to contiguous organs. A sampling of regional lymph nodes should be included, and all suspicious nodes should be sampled. Typically, a large transverse abdominal incision is made, and a transperitoneal approach is used. The opposite side is carefully inspected to ensure that there is no disease present. Although historically this involved the complete mobilization of the contralateral kidney, current evidence indicates that preoperative, high-resolution CT scanning is of sufficient accuracy for the detection of clinically significant lesions if they are present. Provided only unilateral disease is present, a radical nephroureterectomy is then performed with control of the renal pedicle as an initial step. If there is spread above the hepatic veins, an intrathoracic approach may be required. If bilateral disease is encountered, both lesions are biopsied, and chemotherapy is administered followed by a nephron-sparing procedure.Chemotherapy. Following nephroureterectomy for Wilms’ tumor, the need for chemotherapy and/or radiation therapy are determined by the histology of the tumor and the clinical stage of the patient (Table 39-3). Essentially, patients who have dis-ease confined to one kidney completely excised surgically receive a short course of chemotherapy and can expect a 97% 4-year survival, with tumor relapse rare after that time. Patients with more advanced disease or with unfavorable histol-ogy receive more intensive chemotherapy and radiation. Even in stage IV, high cure rates may be achieved. The survival rates are worse in the small percentage of patients considered to have unfavorable histology.NeuroblastomaClinical Presentation. Neuroblastoma is the third most com-mon pediatric malignancy and accounts for approximately 10% of all childhood cancers. The vast majority of patients have advanced disease at the time of presentation, and unlike Wilms’ tumor, in which cure is expected in the vast majority of patients, the overall survival of patients with neuroblastoma is significantly lower. Over 80% of cases present before the age of 4 years, and the peak incidence is two years of age. Neuro-blastomas arise from the neural crest cells and show different levels of differentiation. The tumor originates most frequently in the adrenal glands, posterior mediastinum, neck, or pelvis but can arise in any sympathetic ganglion. The clinical presen-tation depends on the site of the primary and the presence of metastases.9Brunicardi_Ch39_p1705-p1758.indd 174812/02/19 11:27 AM 1749PEDIATRIC SURGERYCHAPTER 39Two-thirds of these tumors are first noted as an asymp-tomatic abdominal mass. The tumor may cross the midline, and a majority of patients will already show signs of metastatic disease. Occasionally, children may experience pain from the tumor mass or from bony metastases. Proptosis and perior-bital ecchymosis may occur due to the presence of retrobulbar metastasis. Because they originate in paraspinal ganglia, neuro-blastomas may invade through neural foramina and compress the spinal cord, causing muscle weakness or sensory changes. Rarely, children may have severe watery diarrhea due to the secretion of vasoactive intestinal peptide by the tumor, or with paraneoplastic neurologic findings including cerebellar ataxia or opsoclonus/myoclonus. The International Neuroblastoma Stag-ing System and the International Neuroblastoma Risk Group Staging System are provided in Table 39-3.Diagnostic Evaluation. Since these tumors derive from the sympathetic nervous system, catecholamines and their metabo-lites will be produced at increased levels. These include elevated levels of serum catecholamines (dopamine, norepinephrine) or urine catecholamine metabolites: vanillylmandelic acid (VMA) or homovanillic acid (HVA). Measurement of VMA and HVMA in serum and urine aids in the diagnosis and in monitoring ade-quacy of future treatment and recurrence. The minimum criterion for a diagnosis of neuroblastoma is based on one of the following: (a) an unequivocal pathologic diagnosis made from tumor tissue by light microscopy (with or without immunohistology, electron microscopy, or increased levels of serum catecholamines or uri-nary catecholamine metabolites); (b) the combination of bone marrow aspirate or biopsy containing unequivocal tumor cells and increased levels of serum catecholamines or urinary catechol-amine metabolites as described earlier.The patient should be evaluated by abdominal computer-ized tomography, which may show displacement and occasion-ally obstruction of the ureter of an intact kidney (Fig. 39-38). Prior to the institution of therapy, a complete staging workup should be performed. This includes radiograph of the chest, bone marrow biopsy, and radionuclide scans to search for metastases. Any abnormality on chest X-ray should be followed up with CT of the chest.Prognostic Indicators. A number of biologic variables have been studied in children with neuroblastoma. An open biopsy is required in order to provide tissue for this analysis. Hyperdip-loid tumor DNA is associated with a favorable prognosis, and Figure 39-38. Abdominal neuroblastoma arising from the right retroperitoneum (arrow).N-myc amplification is associated with a poor prognosis regard-less of patient age. The Shimada classification describes tumors as either favorable or unfavorable histology based on the degree of differentiation, the mitosis-karyorrhexis index, and the pres-ence or absence of schwannian stroma. In general, children of any age with localized neuroblastoma and infants younger than 1 year of age with advanced disease and favorable disease char-acteristics have a high likelihood of disease-free survival. By contrast, older children with advanced-stage disease have a sig-nificantly decreased chance for cure despite intensive therapy. For example, aggressive multiagent chemotherapy has resulted in a 2-year survival rate of approximately 20% in older children with stage IV disease. Neuroblastoma in the adolescent has a worse long-term prognosis regardless of stage or site and, in many cases, a more prolonged course.Surgery. The goal of surgery is complete resection. However, this is often not possible at initial presentation due to the exten-sive locoregional spread of the tumor at the time of presenta-tion. Under these circumstances, a biopsy is performed, and preoperative chemotherapy is provided based upon the stage of the tumor. After neoadjuvant treatment has been administered, surgical resection is performed. The principal goal of surgery is to obtain at least 95% resection without compromising major structures. Abdominal tumors are approached through a trans-verse incision. Thoracic tumors may be approached through a posterolateral thoracotomy or through a thoracoscopic approach. These may have an intraspinal component. In all cases of intra-thoracic neuroblastoma, particularly those at the thoracic inlet, it is important to be aware of the possibility of a Horner’s syn-drome (anhidrosis, ptosis, meiosis) developing. This typically resolves, although it may take many months to do so.Neuroblastoma in Infants. Spontaneous regression of neu-roblastoma has been well described in infants, especially in those with stage 4S disease. Regression generally occurs only in tumors with a near triploid number of chromosomes that also lack N-myc amplification and loss of chromosome 1p. Recent studies indicate that infants with asymptomatic, small, low-stage neuroblastoma detected by screening may have tumors that spontaneously regress. These patients may be observed safely without surgical intervention or tissue diagnosis.RhabdomyosarcomaRhabdomyosarcoma is a primitive soft tissue tumor that arises from mesenchymal tissues. The most common sites of origin include the head and neck (36%), extremities (19%), genitourinary tract (2%), and trunk (9%), although the tumor can arise virtually anywhere. The clinical presentation of the tumor depends on the site of origin. The diagnosis is confirmed with incisional or excisional biopsy after evaluation by MRI, CT scans of the affected area and the chest, and bone marrow biopsy. The tumor grows locally into surrounding structures and metastasizes widely to lung, regional lymph nodes, liver, brain, and bone marrow. The staging system for rhabdomyosarcoma is based upon the TNM system, as established by the Soft Tissue Sarcoma Committee of the Children’s Oncology Group. It is shown in Table 39-4. Surgery is an important component of the staging strategy and involves biopsy of the lesion and evaluation of lymphatics. Primary resection should be undertaken when complete excision can be performed without causing disability. If this is not possible, the lesion is biopsied, and intensive che-motherapy is administered. It is important to plan the biopsy so that it does not interfere with subsequent resection. After the Brunicardi_Ch39_p1705-p1758.indd 174912/02/19 11:27 AM 1750SPECIFIC CONSIDERATIONSPART IItumor has decreased in size, resection of gross residual disease should be performed. Radiation therapy is effective in achieving local control when microscopic or gross residual disease exists following initial treatment. Patients with completely resected tumors of embryonal histology do well without radiation ther-apy, but radiation therapy benefits patients with group I tumors with alveolar or undifferentiated histology.Prognosis. The prognosis for rhabdomyosarcoma is related to the site of origin, resectability, presence of metastases, number of metastatic sites, and histopathology. Primary sites with more favorable prognoses include the orbit and nonparameningeal head and neck, paratestis and vagina (nonbladder, nonprostate genitourinary), and the biliary tract. Patients with tumors less than 5 cm in size have improved survival compared to children with larger tumors, while children with metastatic disease at diagnosis have the poorest prognosis. Tumor histology influ-ences prognosis and the embryonal variant is favorable while the alveolar subtype is unfavorable.TeratomaTeratomas are tumors composed of tissue from all three embry-onic germ layers. They may be benign or malignant, they may arise in any part of the body, and they are usually found in mid-line structures. Thoracic teratomas usually present as an anterior mediastinal mass. Ovarian teratomas present as an abdominal mass often with symptoms of torsion, bleeding, or rupture. Ret-roperitoneal teratomas may present as a flank or abdominal mass.Mature teratomas usually contain well-differentiated tis-sues and are benign, while immature teratomas contain vary-ing degrees of immature neuroepithelium or blastemal tissues. Immature teratomas can be graded from 1 to 3 based on the amount of immature neuroglial tissue present. Tumors of higher grade are more likely to have foci of yolk sac tumor. Malignant germ cell tumors usually contain frankly neoplastic tissues of germ cell origin (i.e., yolk sac carcinoma, embryonal carcinoma, germinoma, or choriocarcinoma). Yolk sac carci-nomas produce α-fetoprotein (AFP), while choriocarcinomas produce β-human chorionic gonadotropin (BHCG) resulting in elevation of these substances in the serum, which can serve as tumor markers. In addition, germinomas can also produce elevation of serum BHCG but not to the levels associated with choriocarcinoma.Table 39-4Staging of RhabdomyosarcomaSTAGESITESTSIZENM1Orbit, nonparameningeal head and neck, genitourinary (other than kidney, bladder, and prostate), and biliaryT1 or T2a or bAny NM02Bladder/prostate, extremity, cranial parameningeal, otherT1 or T2a N0 or NXM03Bladder/prostate, extremity, cranial parameningeal, otherT1 or T2aN1M0   bAny NM04AllT1 or T2a or bAny NM1T1 = tumor confined to anatomic site of origin; T2 = tumor extension and/or fixed to surrounding tissues; a = ≤5 cm; b = >5 cm; N0 = regional nodes not clinically involved; N1 = regional nodes clinically involved; NX = regional node status unknown; M0 = no distant metastasis; M1 = metastasis present.Clinical group:Group 1: Localized disease, completely resected, no regional lymph node involvement.Group 2: Localized disease, gross total resection but microscopic residual disease; or regional lymph nodes involved.Group 3: Localized disease with gross residual disease after incomplete resection or biopsy only.Group 4: Metastatic disease at diagnosis.Figure 39-39. Sacrococcygeal teratoma in a 2-day-old boy.Sacrococcygeal Teratoma. Sacrococcygeal teratoma usually presents as a large mass extending from the sacrum in the new-born period. Diagnosis may be established by prenatal US. In fetuses with evidence of hydrops and a large sacrococcygeal teratoma, prognosis is poor; thus, prenatal intervention has been advocated in such patients. The mass may be as small as a few centimeters in diameter or as massive as the size of the infant (Fig. 39-39). The tumor has been classified based upon the location and degree of intrapelvic extension. Lesions that grow predominantly into the presacral space often present later in childhood. The differential diagnosis consists of neural tumors, lipoma, and myelomeningoceles.Most tumors are identified at birth and are benign. Malig-nant yolk sac tumor histology occurs in a minority of these tumors. Complete resection of the tumor as early as possible is essential. The rectum and genital structures are often distorted by the tumor but usually can be preserved in the course of resection. Perioperative complications of hypothermia and hemorrhage can occur with massive tumors and may prove lethal. This is of particular concern in small, preterm infants with large tumors. The cure rate is excellent if the tumor is excised completely. Brunicardi_Ch39_p1705-p1758.indd 175012/02/19 11:27 AM 1751PEDIATRIC SURGERYCHAPTER 39The majority of patients who develop recurrent disease are sal-vageable with subsequent platinum-based chemotherapy.Liver TumorsMore than two-thirds of all liver tumors in children are malig-nant. There are two major histologic subgroups: hepatoblastoma and hepatocellular carcinoma. The age of onset of liver cancer in children is related to the histology of the tumor. Hepatoblastoma is the most common malignancy of the liver in children, with most of these tumors diagnosed before 4 years of age. Hepatocel-lular carcinoma is the next most common, with a peak age inci-dence between 10 and 15 years. Malignant mesenchymomas and sarcomas are much less common but constitute the remainder of the malignancies. The finding of a liver mass does not necessar-ily imply that a malignancy is present. Nearly 50% of all masses are benign, and hemangiomas are the most common lesion.Most children with a liver tumor present with an abdomi-nal mass that is usually painless, which the parents note while changing the child’s clothes or while bathing the child. The patients are rarely jaundiced but may complain of anorexia and weight loss. Most liver function tests are normal. AFP levels are increased in 90% of children with hepatoblastomas but much less commonly in other liver malignancies. Radiographic evaluation of these children should include an abdominal CT scan to identify the lesion and to determine the degree of local invasiveness (Fig. 39-40). For malignant appearing lesions, a biopsy should be performed unless the lesion can be completely resected easily. Hepatoblastoma is most often unifocal, while hepatocellular carcinoma is often extensively invasive or multi-centric. If a hepatoblastoma is completely removed, the majority of patients survive, but only a minority of patients have lesions amenable to complete resection at diagnosis.A staging system based on postsurgical extent of tumor and surgical resectability is shown in Table 39-5. The overall survival rate for children with hepatoblastoma is 70%, but it is only 25% for hepatocellular carcinoma. Children diagnosed with stage I and II hepatoblastoma have a cure rate of greater than 90% compared to 60% for stage III and approximately 20% for stage IV. In children diagnosed with hepatocellular carcinoma, those with stage I have a good outcome, whereas stages III and IV are usually fatal. The fibrolamellar variant of hepatocel-lular carcinoma may have a better prognosis.Surgery. The abdominal CT scan usually will determine the resectability of the lesion, although occasionally this can only Figure 39-40. Computed tomography of the abdomen showing a hepatocellular carcinoma in a 12-year-old boy.be determined at the time of exploration. Complete surgical resection of the tumor is the primary goal and is essential for cure. For tumors that are unresectable, preoperative chemother-apy should be administered to reduce the size of the tumor and improve the possibility for complete removal. Chemotherapy is more successful for hepatoblastoma than for hepatocellular carcinoma. Areas of locally invasive disease, such as the dia-phragm, should be resected at the time of surgery. For unre-sectable tumors, liver transplantation may be offered in select patients. The fibrolamellar variant of hepatocellular carcinoma may have a better outcome with liver transplantation than other hepatocellular carcinomas.TRAUMA IN CHILDRENInjury is the leading cause of death among children older than 1 year. In fact, trauma accounts for almost half of all pediatric deaths, more than cancer, congenital anomalies, pneumonia, heart disease, homicide, and meningitis combined. Death from unintentional injuries accounts for 65% of all injury-related deaths in children younger than 19 years. Motor vehicle colli-sions are the leading cause of death in people age 1 to 19 years, followed by homicide or suicide (predominantly with firearms) and drowning. Each year, approximately 20,000 children and teenagers die as a result of injury in the United States. For every child who dies from an injury, it is calculated that 40 others are hospitalized and 1120 are treated in emergency departments. An estimated 50,000 children acquire permanent disabilities each year, most of which are the result of head injuries. Thus, the problem of pediatric trauma continues to be one of the major threats to the health and well-being of children.Specific considerations apply to trauma in children that influence management and outcome. These relate to the mecha-nisms of injury, the anatomic variations in children compared to adults, and the physiologic responses.Mechanisms of InjuryMost pediatric trauma is blunt. Penetrating injuries are seen in the setting of gun violence, falls onto sharp objects, or penetra-tion by glass after falling through windows. Age and gender significantly influence the patterns of injury. Male children between 14 and 18 years of age are exposed to contact sports, gun violence, and in some jurisdictions drive motor vehicles. As a result, they have a different pattern of injury than younger children, characterized by higher injury severity scores. In the infant and toddler age group, falls are a 10Table 39-5Staging of pediatric liver cancerStage I: No metastases, tumor completely resectedStage II: No metastases, tumor grossly resected with microscopic residual disease (i.e., positive margins); or tumor rupture, or tumor spill at the time of surgeryStage III: No distant metastases, tumor unresectable or resected with gross residual tumor, or positive lymph nodesStage IV: Distant metastases regardless of the extent of liver involvementData from Douglass E, Ortega J, Feusner J, et al. Hepatocellular carcinoma (HCA) in children and adolescents: results from the Pediatric Intergroup Hepatoma Study (CCG 8881/POG 8945), Proc Am Soc Clin Oncol. 1994;13:A-1439.Brunicardi_Ch39_p1705-p1758.indd 175112/02/19 11:27 AM 1752SPECIFIC CONSIDERATIONSPART IIcommon cause of severe injury. Injuries in the home are extremely common. These include falls, near-drownings, caustic ingestion, and nonaccidental injuries.Initial ManagementThe goals of managing the pediatric trauma patient are similar to those of adults and follow Advanced Trauma Life Support guidelines as established by the American College of Surgeons Committee on Trauma. Airway control is the first priority. In a child, respiratory arrest can proceed quickly to cardiac arrest. It is important to be aware of the anatomic differences between the airway of the child and the adult. The child has a large head, shorter neck, smaller and anterior larynx, floppy epiglottis, short trachea, and large tongue. The size of the endotracheal tube can be estimated by the formula (age + 16)/4. It is important to use uncuffed endotracheal tubes in children younger than 8 years in order to minimize tracheal trauma. After evaluation of the airway, breathing is assessed. It is important to consider that gastric distention from aerophagia can severely compromise respirations. A nasogastric tube should therefore be placed early during the resuscitation if there is no head injury suspected, or an orogastric tube in cases of head injury. Pneumothorax or hemothorax should be treated promptly. When evaluating the circulation, it is important to recognize that tachycardia is usu-ally the earliest measurable response to hypovolemia. Other signs of impending hypovolemic shock in children include changes in mentation, delayed capillary refill, skin pallor, and hypothermia. IV access should be rapidly obtained once the patient arrives in the trauma bay. The first approach should be to use the antecubital fossae. If this is not possible, a cut-down into the saphenous at the groin can be performed quickly and safely. Intraosseous cannulation can provide temporary access in children and young adults until IV access is established. US-guided central line placement in the groin or neck should be considered in patients in whom large bore peripheral IV access is not obtained. Blood is drawn for cross-match and evaluation of liver enzymes, lipase, amylase, and hematologic profile after the IV lines are placed.In patients who show signs of volume depletion, a 20 mL/kg bolus of saline or lactated Ringer’s should be promptly given. If the patient does not respond to three boluses, blood should be transfused (10 mL/kg). The source of bleeding should be established. Common sites include the chest, abdomen, pel-vis, extremity fractures, or large scalp wounds. These should be carefully sought. Care is taken to avoid hypothermia by infusing warmed fluids and by using external warming devices.Evaluation of InjuryAll patients should receive an X-ray of the cervical spine, chest, and abdomen with pelvis. All extremities that are suspicious for fracture should also be evaluated by X-ray. Plain cervical spine films are preferable to performing routine neck CT scans in the child, as X-rays provide sufficient anatomic detail. But if a head CT is obtained, it may be reasonable to obtain images down to C-2 since odontoid views in small children are difficult to obtain. In most children, it is possible to diagnose clinically sig-nificant cervical spine injuries using this approach while mini-mizing the degree of radiation exposure. Screening blood work that includes AST, ALT, and amylase/lipase is useful for the evaluation of liver and pancreatic injures. Significant elevation in these tests requires further evaluation by CT scanning. The child with significant abdominal tenderness and a mechanism of injury that could cause intra-abdominal injury should undergo abdominal CT scanning using IV and oral contrast in all cases. There is a limited role for diagnostic peritoneal lavage (DPL) in children as a screening test. However, this can be occasionally useful in the child who is brought emergently to the operating room for management of significant intracranial hemorrhage. At the time of craniotomy, a DPL, or alternatively, a diagnostic laparoscopy, can be performed concurrently to identify abdomi-nal bleeding. Although focused abdominal US (FAST exam) is extremely useful in the evaluation of adult abdominal trauma, it is not widely accepted in the management of pediatric blunt abdominal trauma. In part, this relates to the widespread use of nonoperative treatment for most solid-organ injuries. Thus, a positive abdominal US scan would not alter this approach in a hemodynamically stable patient.Injuries to the Central Nervous SystemThe central nervous system (CNS) is the most commonly injured organ system and is the leading cause of death among injured children. In the toddler age group, nonaccidental trauma is the most common cause of serious head injury. Findings suggestive of abuse include the presence of retinal hemorrhage on fundo-scopic evaluation and intracranial hemorrhage without evidence of external trauma (indicative of a shaking injury) and fractures at different stages of healing on skeletal survey. In older children, CNS injury occurs most commonly after falls and bicycle and motor vehicle collisions. The initial head CT can often underesti-mate the extent of injury in children. Criteria for head CT include any loss of consciousness or amnesia to the trauma, or inabil-ity to assess the CNS status as in the intubated patient. Patients with mild, isolated head injury (GCS 14-15) and negative CT scans can be discharged if their neurologic status is normal after 6 hours of observation. Young children and those in whom there is multisystem involvement should be admitted to the hospital for observation. Any change in the neurologic status warrants neu-rosurgical evaluation and repeat CT scanning. In patients with severe head injury (GCS 8 or less), urgent neurosurgical consulta-tion is required. These patients are evaluated for intracranial pres-sure monitoring and for the need to undergo craniotomy.Thoracic InjuriesThe pediatric thorax is pliable due to incomplete calcification of the ribs and cartilages. As a result, blunt chest injury com-monly results in pulmonary contusion, although rib fractures are infrequent. Diagnosis is made by chest radiograph and may be associated with severe hypoxia requiring mechanical ventila-tion. Pulmonary contusion usually resolves with careful venti-lator management and judicious volume resuscitation. Children who have sustained massive blunt thoracic injury may develop traumatic asphyxia. This is characterized by cervical and facial petechial hemorrhages or cyanosis associated with vascular engorgement and subconjunctival hemorrhage. Management includes ventilation and treatment of coexisting CNS or abdomi-nal injuries. Penetrating thoracic injuries may result in damage to the lung or to major disruption of the bronchi or great vessels.Abdominal InjuriesIn children, the small rib cage and minimal muscular coverage of the abdomen can result in significant injury after seemingly minor trauma. The liver and spleen in particular are relatively unprotected and are often injured after direct abdominal trauma. Duodenal injuries are usually the result of blunt trauma, which may arise from child abuse or injury from a bicycle handlebar. Duodenal hematomas usually resolve without surgery. Brunicardi_Ch39_p1705-p1758.indd 175212/02/19 11:27 AM 1753PEDIATRIC SURGERYCHAPTER 39Small intestinal injury usually occurs in the jejunum in the area of fixation by the ligament of Treitz. These injuries are usually caused by rapid deceleration in the setting of a lap belt. There may be a hematoma on the anterior abdominal wall caused by a lap belt, the so-called seat belt sign (Fig. 39-41A). This should alert the caregiver to the possibility of an underlying small bowel injury (Fig. 39-41B), as well as to a potential lumbar spine injury (Chance fracture).The spleen is injured relatively commonly after blunt abdominal trauma in children. The extent of injury to the spleen is graded (Table 39-6), and the management is governed by the injury grade. Current treatment involves a nonoperative approach in most cases, even for grade 4 injuries, assuming the patient is hemodynamically stable. This approach avoids surgery in most cases. All patients should be placed in a monitored unit, and type-specific blood should be available for transfusion. When nonoperative management is successful, as it is in most cases, an extended period of bed rest is prescribed. This optimizes the chance for healing and minimizes the likelihood of reinjury. A typical guideline is to keep the children on extremely restricted activity for 2 weeks longer than the grade of spleen injury (i.e., a child with a grade 4 spleen injury receives 6 weeks of restricted activity). In children who have an ongoing fluid requirement, BAFigure 39-41. Abdominal computed tomography of patient who sustained a lapbelt injury. A. Bruising is noted across the abdomen from the lapbelt. B. At laparotomy, a perforation of the small bowel was identified.or when a blood transfusion is required, exploration should not be delayed. At surgery, the spleen can often be salvaged. If a splenectomy is performed, prophylactic antibiotics and immuni-zations should be administered to protect against overwhelming post splenectomy sepsis. The liver is also commonly injured after blunt abdominal trauma. A grading system is used to character-ize hepatic injuries (Table 39-7), and nonoperative management is usually successful (Fig. 39-42). Recent studies have shown that associated injuries are more significant predictors of out-come in children with liver injuries than the actual injury grade. Criteria for surgery are similar to those for splenic injury and primarily involve hemodynamic instability. The intraoperative considerations in the management of massive hepatic injury are similar in children and adults. Renal contusions may occur after significant blunt abdominal trauma. Nonoperative management is usually successful, unless patients are unstable due to active renal bleeding. It is important to confirm the presence of a nor-mal contralateral kidney at the time of surgery.FETAL INTERVENTIONOne to the most exciting developments in the field of pediatric surgery has been the emergence of fetal surgery. In general terms, performance of a fetal intervention may be justified in the setting where a defect is present that would cause devastating consequences to the infant if left uncorrected. For the vast majority of congenital anomalies, postnatal surgery is the preferred modality. However, in specific circumstances, fetal surgery may offer the best possibility for a successful outcome. Table 39-6Grading of splenic injuriesGrade I: Subcapsular hematoma, <10% surface area capsular tear, <1 cm in depthGrade II: Subcapsular hematoma, nonexpanding, 10%–50% surface area; intraparenchymal hematoma, nonexpanding, <2 cm in diameter; capsular tear, active bleeding, 1–3 cm, does not involve trabecular vesselGrade III: Subcapsular hematoma, >50% surface area or expanding; intraparenchymal hematoma, >2 cm or expanding; laceration >3 cm in depth or involving trabecular vesselsGrade IV: Ruptured intraparenchymal hematoma with active bleeding; laceration involving segmental or hilar vessels producing major devascularizatrion (>25% of spleen).Grade V: Shattered spleen; hilar vascular injury that devascularizes spleenTable 39-7Liver injury grading systemGrade I: Capsular tear <1 cm in depthGrade II: Capsular tear 1–3 cm in depth, <10 cm lengthGrade III: Capsular tear >3 cm in depthGrade IV: Parenchymal disruption 25%–75% of hepatic lobe or 1–3 Couinaud’s segmentsGrade V: Parenchymal disruption >75% of hepatic lobe or >3 Couinaud’s segments within a single lobe, injury to retrohepatic vena cavaReproduced with permission from Moore EE, Cogbill TH, Malangoni MA, et al: Organ injury scaling, Surg Clin North Am. 1995 Apr;75(2):293-303.Brunicardi_Ch39_p1705-p1758.indd 175312/02/19 11:27 AM 1754SPECIFIC CONSIDERATIONSPART IIFigure 39-43. The EXIT procedure (ex utero intrapartum treat-ment) in a 34-week gestation age baby with a large cervical tera-toma. Intubation is being performed while the fetus is on placental support.Figure 39-42. Abdominal computed tomography in a child dem-onstrating a grade 3 liver laceration (arrows).Fetal Surgery for MyelomeningoceleMyelomeningocele refers to a spectrum of anomalies in which portions of the spinal cord are uncovered by the spinal column. This leaves the neural tissue exposed to the injurious effects of the amniotic fluid, as well as to trauma from contact with the uterine wall. Nerve damage ensues, resulting in varying degrees of lower extremity paralysis as well as bowel and bladder dys-function. Initial observations indicated that the extent of injury progressed throughout the pregnancy, which provided the ratio-nale for fetal intervention. The current in utero approach for the fetus with myelomeningocele has focused on obtaining cover-age of the exposed spinal cord. The efficacy of in utero treat-ment versus postnatal repair was recently compared in a large multicenter trial as described earlier and showed that prenatal surgery for myelomeningocele reduced the need for shunting and improved motor outcomes at 30 months but was associ-ated with maternal and fetal risks. The results of this study have paved the way for the acceptance of in utero repair of myelome-ningocele in certain centers with the experience and expertise to perform this procedure safely.The EXIT ProcedureThe EXIT procedure is an abbreviation for ex utero intrapar-tum treatment. It is utilized in circumstances where airway obstruction is predicted at the time of delivery due to the pres-ence of a large neck mass, such as a cystic hygroma or teratoma (Fig. 39-43), or congenital tracheal stenosis. The success of the procedure is dependent upon the maintenance of utero-placen-tal perfusion for a sufficient duration to secure the airway. To achieve this, deep uterine relaxation is obtained during a cae-sarian section under general anesthesia. Uterine perfusion with warmed saline also promotes relaxation and blood flow to the placenta. On average, between 20 and 30 minutes of placental perfusion can be achieved. The fetal airway is secured either by placement of an orotracheal tube or performance of a tracheos-tomy. Once the airway is secured, the cord is cut, and a defini-tive procedure may be performed to relieve the obstruction in the postnatal period. In general terms, cystic neck masses such as lymphangiomas have a more favorable response to an EXIT procedure as compared to solid tumors, such as teratomas, par-ticularly in premature infants.The decision to perform a fetal intervention requires careful patient selection, as well as a multidisciplinary center that is dedicated to the surgical care of the fetus and the mother. Patient selection is dependent in part upon highly accurate prenatal imaging that includes US and MRI. Significant risks may be associated with the performance of a fetal surgical procedure, to both the mother and the fetus. From the maternal viewpoint, open fetal surgery may lead to uterine bleeding due to the uterine relaxation required during the procedure. The long-term effects on subsequent pregnancies remain to be established. For the fetus, in utero surgery carries the risk of premature labor and amniotic fluid leak. As a result, these procedures are performed only when the expected benefit of fetal intervention outweighs the risk to the fetus of standard postnatal care. Currently, open fetal intervention may be efficacious in certain instances of large congenital lung lesions with hydrops, large teratomas with hydrops, twin-twin transfusion syndrome, certain cases of congenital lower urinary tract obstruction, and myelomeningocele. The Management of Myelomeningocele Study, which was funded by the NIH, compared prenatal with postnatal repair of myelomeningocele, and determined that prenatal repair was associated with improved motor skills and independent walking. There are ongoing trials for the evaluation of fetal tracheal occlusion in the setting of severe congenital diaphragmatic hernia, from which early results are very promising. The field has undertaken a rigorous evaluation of the potential benefit of prenatal as compared to postnatal management of many of these conditions, given the significant risk that may be associated with fetal therapy.Fetal Surgery for Lower Urinary Tract ObstructionLower urinary tract obstruction refers to a group of diseases characterized by obstruction of the distal urinary system. Com-mon causes include the presence of posterior urethral valves and urethral atresia, as well as other anomalies of the urethra and bladder. The pathologic effects of lower urinary tract obstruc-tion lie in the resultant massive bladder distention that occurs, which can lead to reflux hydronephrosis. This may result in oligohydramnios, and cause limb contractures, facial anoma-lies (Potter sequence), and pulmonary hypoplasia. Carefully selected patients with lower urinary tract obstruction may ben-efit from vesicoamniotic shunting. By relieving the obstruction and improving renal function, fetal growth and lung develop-ment may be preserved.Brunicardi_Ch39_p1705-p1758.indd 175412/02/19 11:27 AM 1755PEDIATRIC SURGERYCHAPTER 39BIBLIOGRAPHYEntries highlighted in bright blue are key references.Adzick NS, Thom EA, Spong CY, et al. A randomized trial of prenatal versus postnatal repair of myelomeningocele. N Engl J Med. 2011;364:993-1004.Adzick NS, Thom EA, Spong CY, et al. A randomized trial of prenatal versus postnatal repair of myelomeningocele. N Engl J Med. 2011;364:993-1004.American Academy of Pediatrics Section on Orthopaedics; American Academy of Pediatrics Committee on Pediatric Emergency Medicine; American Academy of Pediatrics Section on Critical Care, et al. Management of pediatric trauma. Pediatrics. 2008;121(4):849-854.Andersen B, Kallehave F, Andersen HK. Antibiotics versus placebo for prevention of postoperative infection after appendicectomy. Cochrane Database Syst Rev. 2003;(2):CD001439.Anderson KD, Rouse TM, Randolph JG. A controlled trial of corticosteroids in children with corrosive injury of the esophagus. N Engl J Med. 1990;323(10):637-640.Azarow K, Messineo A, Pearl R, Filler R, Barker G, Bohn D. Congenital diaphragmatic hernia—a tale of two cities: the Toronto experience. J Pediatr Surg. 1997;32(3):395-400.Ballance WA, Dahms BB, Shenker N, Kliegman RM. Pathology of neonatal necrotizing enterocolitis: a ten-year experience. J Pediatr. 1990;117(1 pt 2):S6-S13.Barraco RD, Cheng JD, Bromberg WJ, et al. Child passenger safety: an evidence-based review. J Trauma. 2010;69(6):1588-1590.Barthel ER, Pierce JR, Goodhue CJ, Burke RV, Ford HR, Upperman JS. Can a pediatric trauma center improve the response to a mass casualty incident? J Trauma Acute Care Surg. 2012;73(4):885-889.Bell MJ, Ternberg JL, Feigin RD, et al. Neonatal necrotizing enterocolitis. Therapeutic decisions based upon clinical staging. Ann Surg. 1978;187(1):1-7.Bezerra JA, Spino C, Magee JC, et al. Use of corticosteroids after hepatoportoenterostomy for bile drainage in infants with biliary atresia: the START randomized clinical trial. JAMA. 2014;311:1750-1759.Bohn D. Congenital diaphragmatic hernia. Am J Respir Crit Care Med. 2002;166(7):911-915.Boloker J, Bateman DA, Wung JT, Stolar CJ. Congenital diaphragmatic hernia in 120 infants treated consecutively with permissive hypercapnea/spontaneous respiration/elective repair. J Pediatr Surg. 2002;37(3):357-366.Bouchard S, Johnson MP, Flake AW, et al. The EXIT procedure: experience and outcome in 31 cases. J Pediatr Surg. 2002; 37(3):418-426.Branstetter BF, Weissman JL, Kennedy TL, Whitaker M. The CT appearance of thyroglossal duct carcinoma. AJNR Am J Neuroradiol. 2000;21(8):1547-1550.Bratton S, Annich G. Packed red blood cell transfusions for critically ill pediatric patients: when and for what conditions? J Pediatr. 2003;142:95-97.Breneman JC, Lyden E, Pappo AS, et al. Prognostic factors and clinical outcomes in children and adolescents with metastatic rhabdomyosarcoma—a report from the Intergroup Rhabdomyosarcoma Study IV. J Clin Oncol. 2003;21(1): 78-84.Brown RL. Epidemiology of injury and the impact of health disparities. Curr Opin Pediatr. 2010;22(3):321-325.Bruner JP, Tulipan N, Paschall RL, et al. Fetal surgery for myelomeningocele and the incidence of shunt-dependent hydrocephalus. JAMA. 1999;282(19):1819-1825.Callaghan WM, MacDorman MF, Rasmussen SA, Qin C, Lackritz EM. The contribution of preterm birth to infant mortality rates in the United States. Pediatrics. 2006;118(4):1566-1573.Cassady G, Crouse DT, Kirklin JW, et al. A randomized, controlled trial of very early prophylactic ligation of the ductus arteriosus in babies who weighed 1000 g or less at birth. N Engl J Med. 1989;320(23):1511-1516.Chertin B, De Caluwé D, Gajaharan M, Piaseczna-Piotrowska A, Puri P. Is contralateral exploration necessary in girls with unilateral inguinal hernia? J Pediatr Surg. 2003;38(5): 756-757.Choi RS, Vacanti JP. Preliminary studies of tissue-engineered intestine using isolated epithelial organoid units on tubular synthetic biodegradable scaffolds. Transplant Proc. 1997;29(1-2):848-851.Cikrit D, Mastandrea J, West KW, Schreiner RL, Grosfeld JL. Necrotizing enterocolitis: factors affecting mortality in 101 surgical cases. Surgery. 1984;96(4):648-655.Cohen J, Schanen NC. Branchial cleft anomaly, congenital heart disease, and biliary atresia: Goldenhar complex or Lambert syndrome? Genet Couns. 2000;11(2):153-156.Cohn SL, London WB, Huang D, et al. MYCN expression is not prognostic of adverse outcome in advanced-stage neuroblastoma with nonamplified MYCN. J Clin Oncol. 2000;18(21):3604-3613.Collins SR, Griffin MR, Arbogast PG, et al. The rising prevalence of gastroschisis and omphalocele in Tennessee. J Pediatr Surg. 2007;42(7):1221-1224.Cook RC, Blinman TA. Nutritional support of the pediatric trauma patient. Semin Pediatr Surg. 2010;19(4):242-251.Coppes MJ, Haber DA, Grundy PE. Genetic events in the development of Wilms’ tumor. N Engl J Med. 1994;331(9):586-590.Cotterill SJ, Pearson ADJ, Pritchard J, et al. Clinical prognostic factors in 1277 patients with neuroblastoma: results of the European Neuroblastoma Study Group “Survey” 1982-1992. Eur J Cancer. 2000;36(7):901-908.Crystal P, Hertzanu Y, Farber B, Shabshin N, Barki Y. Sonographically guided hydrostatic reduction of intussusception in children. J Clin Ultrasound. 2002;30(6):343-348.Davidson GH, Flum DR, Talan DA, et al. 2017 Comparison of outcomes of antibiotic drugs and appendectomy (coda) trial: a protocol for the pragmatic randomised study of appendicitis treatment. BMJ Open. 2017;7(11):e016117.Deprest J, Gratacos E, Nicolaides KH. Fetoscopic tracheal occlusion (FETO) for severe congenital diaphragmatic hernia: evolution of a technique and preliminary results. US Obstet Gynecol. 2004;24:121-126.DeRusso PA, Ye W, Shepherd R, et al; Biliary Atresia Research Consortium. Growth failure and outcomes in infants with biliary atresia: a report from the Biliary Atresia Research Consortium. Hepatology. 2007;46(5):1632-1638.Doné E, Gucciardo L, Van Mieghem T, et al. Prenatal diagnosis, prediction of outcome and in utero therapy of isolated congenital diaphragmatic hernia. Prenat Diagn. 2008;28(7):581-591.Dunn J, Fonkalsrud E, Atkinson JB. Simplifying the Waterston’s stratification of infants with tracheoesophageal fistula. Am Surg. 1999;65(10):908-910.Ein SH, Njere I, Ein A. Six thousand three hundred sixty-one pediatric inguinal hernias: a 35-year review. J Pediatr Surg. 2006;41(5):980-986.Evans GS, Flint N, Somers AS, Eyden B, Potten CS. The development of a method for the preparation of rat intestinal epithelial cell primary cultures. J Cell Sci. 1992;101(pt 1): 219-231.Feenstra B, Geller F, Carstensen L, et al. Plasma lipids, genetic variants near APOA1, and the risk of infantile hypertrophic pyloric stenosis. JAMA. 2013;310:714-721.Ferrari A, Bisogno G, Cassanova M, et al. Paratesticular rhabdomyosarcoma: report from the Italian and German Cooperative Group. J Clin Oncol. 2002;20(2):449-455.Brunicardi_Ch39_p1705-p1758.indd 175512/02/19 11:27 AM 1756SPECIFIC CONSIDERATIONSPART IIFisher JC, Jefferson RA, Arkovitz MS, Stolar CJ. Redefining outcomes in right congenital diaphragmatic hernia. J Pediatr Surg. 2008;43:373-379.Freedman AL, Johnson MP, Smith C, et al. Long-term outcome in children after antenatal intervention for obstructive uropathies. Lancet. 1999;354:374-377.Gajewski JL, Johnson VV, Sandler SG, Sayegh A, Klumpp TR. A review of transfusion practice before, during, and after hematopoietic progenitor cell transplantation. Blood. 2008;112(8):3036-3047.Geiger S, Bobylev A, Schadelin S, Mayr J, Holland-Cunz S, Zimmermann P. Single-center, retrospective study of the outcome of laparoscopic inguinal herniorrhaphy in children. Medicine (Baltimore). 2007;96:e9486.Geisler DP, Jegathesan S, Parmley M, et al. Laparoscopic exploration for the clinically undetected hernia in infancy and childhood. Am J Surg. 2001;182:693-696.Geneviève D, de Pontual L, Amiel J, Sarnacki S, Lyonnet S. An overview of isolated and syndromic oesophageal atresia. Clin Genet. 2007;71:392-399.Georgeson K. Laparoscopic-assisted pull-through for Hirschsprung’s disease. Semin Pediatr Surg. 2002;11:205-210.Georgeson K. Results of laparoscopic antireflux procedures in neurologically normal infants and children. Semin Laparosc Surg, 2002;9(3):172-176.Georgoula C, Gardiner M. Pyloric stenosis a 100 years after Ramstedt. Arch Dis Child. 2012;97:741-745.Gollin GA, Abarbanell AA, Baerg J, et al. Peritoneal drainage as definitive management of intestinal perforation in extremely low-birth-weight infants. J Pediatr Surg. 2003;38:1814.Gorsler C, Schier F. Laparoscopic herniorrhaphy in children. Surg Endosc. 2003;17:571-573.Grant D, Abu-Elmagd K, Reyes J, et al. 2003 report of the intestine transplant registry: a new era has dawned. Ann Surg. 2005;241:607-613.Grikscheit TC, Ochoa ER, Ramsanahie A, et al. Tissueengineered large intestine resembles native colon with appropriate in vitro physiology and architecture. Ann Surg. 2003; 238:35-41.Gura KM, Lee S, Valim C, et al. Safety and efficacy of a fishoil-based fat emulsion in the treatment of parenteral nutritionassociated liver disease. Pediatrics. 2008;121:e678-e686.Guthrie S, Gordon P, Thomas V, et al. Necrotizing enterocolitis among neonates in the United States. J Perinatol. 2003;23:278.Hackam D, Caplan M. Necrotizing enterocolitis: pathophysiology from a historical context. Semin Pediatr Surg. 2018;27:11-18.Hackam DJ, Filler R, Pearl R. Enterocolitis after the surgical treatment of Hirschsprung’s disease: risk factors and financial impact. J Pediatr Surg. 1998;33:830-833.Hackam DJ, Potoka D, Meza M, et al. Utility of radiographic hepatic injury grade in predicting outcome for children after blunt abdominal trauma. J Pediatr Surg. 2002;37:386-389.Hackam DJ, Reblock K, Barksdale E, et al. The influence of Down’s syndrome on the management and outcome of children with Hirschsprung’s disease. J Pediatr Surg. 2003;38:946-949.Hackam DJ, Superina R, Pearl R, et al. Single-stage repair of Hirschsprung’s disease: a comparison of 109 patients over 5 years. J Pediatr Surg. 1997;32:1028-1031.Hamner CE, Groner JI, Caniano DA, Hayes JR, Kenney BD. Blunt intraabdominal arterial injury in pediatric trauma patients: injury distribution and markers of outcome. J Pediatr Surg. 2008;43:916-923.Harnoss JC, Zelienka I, Probst P, et al. Antibiotics versus surgical therapy for uncomplicated appendicitis: systematic review and meta-analysis of controlled trials (PROSPERO 2015: CRD42015016882). Ann Surg. 2016;265:889-900.Harrison MR. Fetal surgery: trials, tribulations, and turf. J Pediatr Surg. 2003;38:275-282.Harrison MR, Keller RL, Hawgood S, et al. A randomized trial of fetal endoscopic tracheal occlusion for severe fetal congenital diaphragmatic hernia. N Engl J Med. 2003;349:1916-1924.Harrison MR, Sydorak RM, Farrell J, et al. Fetoscopic temporary tracheal occlusion for congenital diaphragmatic hernia: prelude to a randomized, controlled trial. J Pediatr Surg. 2003;38:1012-1020.Heath JK. Transcriptional networks and signaling pathways that govern vertebrate intestinal development. Curr Top Dev Biol. 2010;90:159-192.Hedrick H, Flake A, Crombleholme T, et al. History of fetal diagnosis and therapy: Children’s Hospital of Philadelphia experience. Fetal Diagn Ther. 2003;18:65-82.Hilton EN, Manson FD, Urquhart JE, et al. Left-sided embryonic expression of the BCL-6 corepressor, BCOR, is required for vertebrate laterality determination. Hum Mol Genet. 2007;16:1773-1782.Hirschl RB, Philip WF, Glick L, et al. A prospective, randomized pilot trial of perfluorocarbon-induced lung growth in newborns with congenital diaphragmatic hernia. J Pediatr Surg. 2003;38:283-289.Huh JW, Raghupathi R. New concepts in treatment of pediatric traumatic brain injury. Anesthesiol Clin. 2009;27(2):213-240.Hutchings L, Willett K. Cervical spine clearance in pediatric trauma: a review of current literature. J Trauma. 2009;67(4):687-691.Jani J, Nicolaides KH, Keller RL, et al. Observed to expected lung area to head circumference ratio in the prediction of survival in fetuses with isolated diaphragmatic hernia. Ultrasound Obstet Gynecol. 2007;30:67-71.Jani JC, Peralta CF, Nicolaides KH. Lung-to-head ratio: a need to unify the technique. Ultrasound Obstet Gynecol. 2012;39:2-6.Johnigan RH, Pereira KD, Poole MD. Community-acquired methicillin-resistant Staphylococcus aureus in children and adolescents: changing trends. Arch Otolaryngol Head Neck Surg. 2003;129(10):1049-1052.Johnson MP, Sutton LN, Rintoul N, et al. Fetal myelomeningocele repair: short-term clinical outcomes. Am J Obstet Gynecol. 2003;189:482-487.Kalapurakal J, Li S, Breslow N, et al. Influence of radiation therapy delay on abdominal tumor recurrence in patients with favorable histology Wilms’ tumor treated on NWTS-3 and NWTS-4: a report from the National Wilms’ Tumor Study Group. Int J Radiat Oncol Biol Phys. 2003;57:495-499.Kamata S, Ishikawa S, Usui N, et al. Prenatal diagnosis of abdominal wall defects and their prognosis. J Pediatr Surg. 1996;31:267-271.Kantarci S, Al-Gazali L, Hill RS, et al. Mutations in LRP2, which encodes the multiligand receptor megalin, cause Donnai-Barrow and facio-oculo-acoustico-renal syndromes. Nat Genet. 2007;39:957-959.Katzenstein HM, Krailo MD, Malogolowkin M, et al. Hepatocellular carcinoma in children and adolescents: results from the Pediatric Oncology Group and the Children’s Cancer Group Intergroup Study. J Clin Oncol. 2002;20:2789-2797.Kim HB, Fauza D, Garza J, Oh JT, Nurko S, Jaksic T. Serial transverse enteroplasty (STEP): a novel bowel lengthening procedure. J Pediatr Surg. 2003;38:425-429.Kim HB, Lee PW, Garza J, et al. Serial transverse enteroplasty for short bowel syndrome: a case report. J Pediatr Surg. 2003;38:881-885.Kim JR, Suh CH, Yoon HM, et al. Performance of MRI for suspected appendicitis in pediatric patients and negative appendectomy rate: a systematic review and meta-analysis. J Magn Reson Imaging. 2018;47(3):767-778.Brunicardi_Ch39_p1705-p1758.indd 175612/02/19 11:27 AM 1757PEDIATRIC SURGERYCHAPTER 39Kliegman RM. Models of the pathogenesis of necrotizing enterocolitis. J Pediatr. 1990;117:S2-S5.Kliegman RM, Fanaroff AA. Necrotizing enterocolitis. N Engl J Med. 1984;310:1093-1103.Koivusalo AI, Korpela R, Wirtavuori K, Piiparinen S, Rintala RJ, Pakarinen MP. A single-blinded, randomized comparison of laparoscopic versus open hernia repair in children. Pediatrics. 2009;123:332-337.Konkin D, O’hali W, Webber EM, Blair GK. Outcomes in esophageal atresia and tracheoesophageal fistula. J Pediatr Surg. 2003;38:1726-1729.Kosloske AM. Operative techniques for the treatment of neonatal necrotizing enterocolitis. Surg Gynecol Obstet. 1979;149:740-744.Kosloske AM. Indications for operation in necrotizing enterocolitis revisited. J Pediatr Surg. 1994;29:663-666.Kosloske AM, Lilly JR. Paracentesis and lavage for diagnosis of intestinal gangrene in neonatal necrotizing enterocolitis. J Pediatr Surg. 1978;13:315-320.Lacroix J, Hebert PC, Hutchison JS, et al. Transfusion strategies for patients in pediatric intensive care units. N Engl J Med. 2007;356:1609-1619.Langer J, Durrant A, de la Torre L, et al. One-stage transanal Soave pullthrough for Hirschsprung disease: a multicenter experience with 141 children. Ann Surg. 2003;238:569-583.Levitt MA, Ferraraccio D, Arbesman M, et al. Variability of inguinal hernia surgical technique: a survey of North American pediatric surgeons. J Pediatr Surg. 2002;37:745-751.Lille ST, Rand RP, Tapper D, Gruss JS. The surgical management of giant cervicofacial lymphatic malformations. J Pediatr Surg. 1996;31:1648-1650.Limmer J, Gortner L, Kelsch G, Schutze F, Berger D. Diagnosis and treatment of necrotizing enterocolitis. A retrospective evaluation of abdominal paracentesis and continuous postoperative lavage. Acta Paediatr Suppl. 1994;396:65-69.Lintula H, Kokki H, Vanamo K. Single-blind randomized clinical trial of laparoscopic versus open appendicectomy in children. Br J Surg. 2001;88:510-514.Lipshutz G, Albanese C, Feldstein V, et al. Prospective analysis of lung-to-head ratio predicts survival for patients with prenatally diagnosed congenital diaphragmatic hernia. J Pediatr Surg. 1997;32:1634-1636.Little D, Rescorla F, Grosfeld J, et al. Long-term analysis of children with esophageal atresia and tracheoesophageal fistula. J Pediatr Surg. 2003;38:852-856.Loeb DM, Thornton K, Shokek O. Pediatric soft tissue sarcomas. Surg Clin North Am. 2008;88:615-627.Luig M, Lui K. Epidemiology of necrotizing enterocolitis—part I: changing regional trends in extremely preterm infants over 14 years. J Paediatr Child Health. 2005;41:169-173.Lynch L, O’Donoghue D, Dean J, O’Sullivan J, O’Farrelly C, Golden-Mason L. Detection and characterization of hemopoietic stem cells in the adult human small intestine. J Immunol. 2006;176:5199-5204.Maheshwari A, Patel RM, Christensen RD. Anemia, red blood cell transfusions, and necrotizing enterocolitis. Semin Pediatr Surg. 2018;27:47-51.Mallick IH, Yang W, Winslet MC, Seifalian AM. Ischemia-reperfusion injury of the intestine and protective strategies against injury. Dig Dis Sci. 2004;49:1359-1377.Marianowski R, Ait Amer JL, Morisseau-Durand MP, et al. Risk factors for thyroglossal duct remnants after Sistrunk procedure in a pediatric population. Int J Pediatr Otorhinolaryngol. 2003;67:19-23.Maris JM, Weiss MJ, Guo C, et al. Loss of heterozygosity at 1p36 independently predicts for disease progression but not decreased overall survival probability in neuroblastoma patients: a Children’s Cancer Group Study. J Clin Oncol. 2000;18:1888-1899.Martinez-Tallo E, Claure N, Bancalari E. Necrotizing enterocolitis in full-term or near-term infants: risk factors. Biol Neonate. 1997;71:292-298.Meyers RL, Book LS, O’Gorman M, et al. High-dose steroids, ursodeoxycholic acid, and chronic intravenous antibiotics improve bile flow after Kasai procedure in infants with biliary atresia. J Pediatr Surg. 2003;38:406-411.Miyano T, Yamataka A, Kato Y, et al. Hepaticoenterostomy after excision of choledochal cyst in children: a 30-year experience with 180 cases. J Pediatr Surg. 1996;31:1417-1421.Molik KA, West KW, Rescorla F, et al. Portal venous air: the poor prognosis persists. J Pediatr Surg. 2001;36:1143-1145.Moss R, Dimmitt R, Henry M, et al. A meta-analysis of peritoneal drainage versus laparotomy for perforated necrotizing enterocolitis. J Pediatr Surg. 2001;36:1210-1213.Moss RL, Das JB, Raffensperger JG. Necrotizing enterocolitis and total parenteral nutrition-associated cholestasis. Nutrition. 1996;12:340-343.Moyer V, Moya F, Tibboel F, et al. Late versus early surgical correction for congenital diaphragmatic hernia in newborn infants. Cochrane Database Syst Rev. 2002;CD001695.Mullassery D, Ba’ath ME, Jesudason EC, Losty PD. Value of liver herniation in prediction of outcome in fetal congenital diaphragmatic hernia: a systematic review and meta-analysis. Ultrasound Obstet Gynecol. 2010;35:609-614.Nadler E, Stanford A, Zhang X, et al. Intestinal cytokine gene expression in infants with acute necrotizing enterocolitis: interleukin-11 mRNA expression inversely correlates with extent of disease. J Pediatr Surg. 2001;36:1122-1129.Neville HL, Andrassy RJ, Lally K, et al. Lymphatic mapping with sentinel node biopsy in pediatric patients. J Pediatr Surg. 2000;35:961-964.Nino DF, Sodhi CP, Hackam DJ. Necrotizing enterocolitis: new insights into pathogenesis and mechanisms. Nat Rev Gastroenterol Hepatol. 2016;13:590-600.Nio M, Ohi R, Miyano T, et al. Fiveand 10-year survival rates after surgery for biliary atresia: a report from the Japanese Biliary Atresia Registry. J Pediatr Surg. 2003;38:997-1000.O’Donovan DJ, Baetiong A, Adams K, et al. Necrotizing enterocolitis and gastrointestinal complications after indomethacin therapy and surgical ligation in premature infants with patent ductus arteriosus. J Perinatol. 2003;23: 286-290.Olutoye OO, Coleman BG, Hubbard A, et al. Prenatal diagnosis and management of congenital lobar emphysema. J Pediatr Surg. 2000;35:792-795.Ortega JA, Douglass EC, Feusner J, et al. Randomized comparison of cisplatin/vincristine/fluorouracil and cisplatin/continuous infusion doxorubicin for treatment of pediatric hepatoblastoma: a report from the Children’s Cancer Group and the Pediatric Oncology Group. J Clin Oncol. 2000;18:2665.Pandya S, Heiss K. Pyloric stenosis in pediatric surgery: an evidence based review. Surg Clin North Am. 2012;92:527-539, vii-viii.Panesar J, Higgins K, Daya H, et al. Nontuberculous mycobacterial cervical adenitis: a ten-year retrospective review. Laryngoscope. 2003;113:149-154.Pedersen A, Petersen O, Wara P, et al. Randomized clinical trial of laparoscopic versus open appendicectomy. Br J Surg. 2001;88:200-205.Pena A, Guardino K, Tovilla J, et al. Bowel management for fecal incontinence in patients with anorectal malformations. J Pediatr Surg. 1998;33:133-137.Poenaru D, Laberge J, Neilson IR, et al. A new prognostic classification for esophageal atresia. Surgery. 1993;113:426-432.Potoka D, Schall L, Ford H. Improved functional outcome for severely injured children treated at pediatric trauma centers. J Trauma. 2001;51:824-832.Brunicardi_Ch39_p1705-p1758.indd 175712/02/19 11:27 AM 1758SPECIFIC CONSIDERATIONSPART IIPotoka DA, Schall LC, Ford H. Risk factors for splenectomy in children with blunt splenic trauma. J Pediatr Surg. 2002;37:294-299.Powers CJ, Levitt MA, Tantoco J, et al. The respiratory advantage of laparoscopic Nissen fundoplication. J Pediatr Surg. 2003;38:886-891.Pritchard-Jones K. Controversies and advances in the management of Wilms’ tumour. Arch Dis Child. 2002;87:241-244.Puapong D, Kahng D, Ko A, et al. Ad libitum feeding: safely improving the cost-effectiveness of pyloromyotomy. J Pediatr Surg. 2002;37:1667-1668.Quinton AE, Smoleniec JS. Congenital lobar emphysema—the disappearing chest mass: antenatal ultrasound appearance. Ultrasound Obstet Gynecol. 2001;17:169-171.Rai SE, Sidhu AK, Krishnan RJ. Transfusion-associated necrotizing enterocolitis re-evaluated: a systematic review and meta-analysis. J Perinat Med. 2018;46(6):665-676.Reyes J, Bueno J, Kocoshis S, et al. Current status of intestinal transplantation in children. J Pediatr Surg. 1998;33:243-254.Rosen NG, Hong AR, Soffer S, et al. Rectovaginal fistula: a common diagnostic error with significant consequences in girls with anorectal malformations. J Pediatr Surg. 2002;37:961-965.Rothenberg S. Laparoscopic Nissen procedure in children. Semin Laparosc Surg. 2002;9:146-152.Sandler A, Ein S, Connolly B, et al. Unsuccessful air-enema reduction of intussusception: is a second attempt worthwhile? Pediatr Surg Int. 1999;15:214-216.Sarioglu A, McGahren ED, Rodgers BM. Effects of carotid artery repair following neonatal extracorporeal membrane oxygenation. Pediatr Surg Int. 2000;16:15-18.Schier F, Montupet P, Esposito C. Laparoscopic inguinal herniorrhaphy in children: a three-center experience with 933 repairs. J Pediatr Surg. 2002;37:395-397.Schonfeld D, Lee LK. Blunt abdominal trauma in children. Curr Opin Pediatr. 2012;24:314-318.Shamberger R, Guthrie K, Ritchey M, et al. Surgery-related factors and local recurrence of Wilms tumor in National Wilms Tumor Study 4. Ann Surg. 1999;229:292-297.Shimada H, Ambros I, Dehner L, et al. The International Neuroblastoma Pathology Classification (the Shimada system). Cancer. 1999;86:364-372.Shivakumar P, Campbell KM, Sabla GE, et al. Obstruction of extrahepatic bile ducts by lymphocytes is regulated by IFNgamma in experimental biliary atresia. J Clin Invest. 2004;114:322-329.Simons SHP, van Dijk M, van Lingen R, et al. Routine morphine infusion in preterm newborns who received ventilatory support: a randomized controlled trial. JAMA. 2003;290:2419-2427.Soffer SZ, Rosen NG, Hong AR, et al. Cloacal exstrophy: a unified management plan. J Pediatr Surg. 2000;35:932-937.Spitz L, Kiely E, Morecroft J, et al. Oesophageal atresia: at-risk groups for the 1990s. J Pediatr Surg. 1994;29:723-725.Sun L, Rommens JM, Corvol H, et al. Multiple apical plasma membrane constituents are associated with susceptibility to meconium ileus in individuals with cystic fibrosis. Nat Genet. 2012;44:562-569.Teich S, Barton D, Ginn-Pease M, et al. Prognostic classification for esophageal atresia and tracheoesophageal fistula: Waterston versus Montreal. J Pediatr Surg. 1997;32:1075-1079.Teitelbaum D, Coran A. Reoperative surgery for Hirschsprung’s disease. Semin Pediatr Surg. 2003;12:124-131.Thibeault DW, Olsen SL, Truog W, et al. Pre-ECMO predictors of nonsurvival in congenital diaphragmatic hernia. J Perinatol. 2002;22:682-683.Tolia V, Wureth A, Thomas R. Gastroesophageal reflux disease: review of presenting symptoms, evaluation, management, and outcome in infants. Dig Dis Sci. 2003;48:1723-1729.Tsao K, St Peter SD, Sharp SW, et al. Current application of thoracoscopy in children. J Laparoendosc Adv Surg Tech A. 2008;18:131-135.Tulipan N, Sutton L, Bruner J, et al. The effect of intrauterine myelomeningocele repair on the incidence of shunt-dependent hydrocephalus. Pediatr Neurosurg. 2003;38:27-33.Vargas JV, Vlassov D, Colman D, Brioschi ML. A thermodynamic model to predict the thermal response of living beings during pneumoperitoneum procedures. J Med Eng Technol. 2005;29:75-81.Wang KS, Shaul DB. Two-stage laparoscopic orchidopexy with gubernacular preservation: preliminary report of a new approach to the intraabdominal testis. J Pediatr Endosurg Innovative Tech. 2004;8:252-255.Wenzler D, Bloom D, Park J. What is the rate of spontaneous testicular descent in infants with cryptorchidism? J Urol. 2004;171:849-851.Wildhaber B, Coran A, Drongowski R, et al. The Kasai portoenterostomy for biliary atresia: a review of a 27-year experience with 81 patients. J Pediatr Surg. 2003;38:1480-1485.Wood JH, Partrick DA, Johnston RB, Jr. The inflammatory response to injury in children. Curr Opin Pediatr. 2010;22:315-320.Xu J, Adams S, Liu YC, Karpelowsky J. Nonoperative management in children with early acute appendicitis: a systematic review. J Pediatr Surg. 2017;52:1409-1415.Yang EY, Allmendinger N, Johnson SM, Chen C, Wilson JM, Fishman SJ. Neonatal thoracoscopic repair of congenital diaphragmatic hernia: selection criteria for successful outcome. J Pediatr Surg. 2005;40:1369-1375.Brunicardi_Ch39_p1705-p1758.indd 175812/02/19 11:27 AM
UrologyAhmad Shabsigh, Michael Sourial, Fara F. Bellows, Christopher McClung, Rama Jayanthi, Stephanie Kielb, Geoffrey N. Box, Bodo E. Knudsen, and Cheryl T. Lee 40chapterANATOMYThe anatomic structures that generally require urologic man-agement include the kidneys, adrenal glands, ureters, bladder, prostate, seminal vesicles, vas deferens, penis, urethra, scrotum, and testes. These organs are located in retroperitoneal or extra-peritoneal spaces. However, a transperitoneal approach may be utilized to access the kidney, ureters, bladder, or retroperitoneal lymph nodes during certain urologic operations.Kidney and Adrenal GlandThe kidneys are paired retroperitoneal organs that are invested in a fibro-fatty layer of tissue known as Gerota’s fascia. This natural barrier helps to tamponade bleeding and thus may provide renal and hemodynamic protection in cases of renal trauma or spontaneous renal hemorrhage. It also may assist in preventing tumor invasion into surrounding struc-tures in the case of large renal masses. The kidneys are bor-dered posterolaterally by the quadratus lumborum muscle and posteromedially by the psoas muscle. Additionally, the diaphragm drapes across the posterior aspect of the superior pole of each kidney.The left kidney is bordered anterolaterally by the spleen and descending colon. The pancreatic tail borders the antero-medial left kidney. The right kidney is bordered anterolaterally by the liver and the ascending colon. The second portion of the duodenum may be encountered near the right renal vessels and thus sometimes requires anteromedial reflection, known as the Kocher maneuver, to achieve intraoperative vascular control during right renal surgery.The kidneys are end organs, which are responsible for their vulnerability to infarction. The renal arteries extend from the aorta and then branch into several segmental arteries and arterioles before becoming glomeruli. Each artery runs poste-rior to their respective renal vein. Occasionally, an accessory renal artery will arise, but in general, each kidney receives a single main renal artery. Each renal vein drains directly into the IVC and is located anteriorly to its respective renal artery when entering the kidney. The right renal vein is much shorter than the left and does not receive collateral venous drainage. The left renal vein passes anteriorly to the aorta and receives drainage from the left gonadal vein, the left inferior adrenal vein, and a lumbar vein.The collecting system of the kidney begins as minor caly-ces near the renal papillae and then coalesces into major calyces. Major calyces join to form the renal pelvis, which then tapers down to the ureteropelvic junction (UPJ), from which the ureter emanates. The pelvis is located posterior to its respective renal artery.The adrenal gland is superomedial to its respective kidney within Gerota’s fascia. Adrenal arterial supply arises from mul-tiple sources: the inferior phrenic artery, aortic branches, and renal arterial branches. Venous drainage mirrors arterial supply. On the right side, the adrenal gland drains directly into the IVC. The right adrenal vein can be quite short (<1 cm) and can be Anatomy 1759Kidney and Adrenal Gland / 1759Ureter / 1760Bladder and Prostate / 1760Penis / 1760Scrotum and Testes / 1760Infection 1761Cystitis / 1761Pyelonephritis / 1761Prostatitis / 1761Epididymo-Orchitis / 1761Balanitis and Balanoposthitis / 1762Urinary Tract Obstruction 1762Urolithiasis / 1762Benign Prostatic Hyperplasia / 1763Urethral Stricture / 1764Other Causes of Obstruction / 1764Genitourinary Trauma 1764Kidneys / 1765Ureters / 1765Bladder / 1766Urethral Injuries / 1766External Genital Injuries / 1767Emergencies 1768Acute Urinary Retention / 1768Testicular Torsion / 1769Fournier’s Gangrene / 1769Priapism / 1769Paraphimosis / 1770Emphysematous Pyelonephritis / 1770Urologic Malignancies 1770Bladder Cancer / 1770Testicular Cancer / 1771Kidney Cancer / 1772Prostate Cancer / 1774Urethral Cancer / 1775Common Urologic Conditions 1775Urinary Incontinence and Voiding Dysfunction / 1775Erectile Dysfunction / 1775Pediatric Urology 1776Hypospadias / 1776Urinary Tract Infections in Children / 1777Prenatal Hydronephrosis / 1777Cryptorchidism / 1777Brunicardi_Ch40_p1759-p1782.indd 175901/03/19 6:34 PM 1760Key Points1 Most small ureteral calculi will pass spontaneously or with the use of medical expulsive therapy, but larger stones (>6 mm) are better treated with ureteral stenting or lithotripsy.2 Benign prostatic hyperplasia can be managed effectively with medical therapy or minimally invasive endoscopic and robotic surgical techniques depending on the urinary symp-toms, patient bother, prostate size, and patient’s therapeutic choice. 3 Patients with recurrent urethral stricture after endoscopic treatment are unlikely to derive sustained benefit from future endoscopic therapies and should be referred for urethral reconstruction.4 The vast majority of renal trauma can be treated conserva-tively, with early surgical intervention reserved for persistent bleeding, renal vascular, or ureteral injuries. 5 Extraperitoneal bladder ruptures can be treated conserva-tively, but intraperitoneal ruptures typically require surgical repair.6 Testicular torsion is an emergency where successful testicu-lar salvage is inversely related to the delay in repair, so cases with a high degree of clinical suspicion should not wait for a radiologic diagnosis.7 Fournier’s gangrene is a rapidly progressive and potentially lethal condition that requires aggressive débridement and close follow-up due to the frequent need for repeat débridement.8 The management of early stage prostate cancer has changed significantly, with a much greater emphasis on risk stratifi-cation. Low risk patients are largely treated with active surveillance. 9 Treatments for urinary incontinence and voiding dysfunction are varied depending on the etiology, severity, and bother of the symptom. Behavior modification, bladder retraining, and medical therapies can all be effective in improving symptoms without the need for surgery.a source of significant bleeding if inadvertently injured during renal or adrenal surgery.UreterThe ureters are smooth muscle–based tubular structures that connect the renal pelvis to the bladder. The blood supply arises from the surrounding vasculature. The proximal blood supply inserts on the medial aspect of the ureter and arises from the aorta and renal artery, and the distal blood supply inserts lat-erally and arises from the surrounding iliac vessels and their branches. The arterial supply inserts via a fatty layer of tissue around the ureter, and thus surgical preservation of the periure-teral tissue is essential to maintain vascularization and achieve successful ureteral reconstruction.The ureters initially course along the psoas muscle and then run distally along the pelvic sidewall. They generally pass posterior to the uterine arteries, making them susceptible to injury during hysterectomy. The ureters enter the bladder lat-erally and pass through the bladder wall at an oblique angle, which helps prevent reflux of urine during bladder filling. The ureters propel urine into the bladder via the ureteral orifices.Bladder and ProstateThe bladder is located extraperitoneally in the pelvis and pos-terior to the pubis. A portion of the bladder dome is draped by peritoneum, and rupture or injury at this location can result in intraperitoneal urine leakage and subsequent chemical peritoni-tis. The average adult bladder holds approximately 500 mL of urine; however, in rare cases, capacity can reach up to or greater than 1000 mL, in which case the bladder extends towards the umbilicus. The sigmoid colon lies adjacent to the bladder and can fistulize to the lateral wall or dome of the bladder in cases of diverticulitis or colon cancer. The rectum lies posteriorly to the bladder in men, and the uterus and vagina lie posteriorly to the bladder in women.The prostate is a walnut-shaped gland that encircles the urethra and is located in males immediately beneath the blad-der neck. Smooth muscle fibers distribute throughout the gland, which can contract and facilitate bladder outlet obstruction. The average prostate measures approximately 30 mL in volume. Puboprostatic ligaments suspend the prostate to the pubis, and in the instance of pelvic trauma, shearing forces can cause disrup-tion of the posterior urethra (known as pelvic fracture urethral injury). The external urethral sphincter houses the membranous urethra and sits just below the apex of the prostate. Vasculature to the bladder and prostate arises from the superior and inferior vesical arteries, which branch from the internal iliac arteries.PenisThe penis is comprised of three bodies: two corpora cavernosa, which are responsible for erection, and the corpus spongiosum, which surrounds the urethra and gives rise to the glans penis. These three structures are all encased by skin and dartos fascia, as well as an inner investing layer of fascia called Buck’s fascia. The corpora cavernosa are spongy sinusoidal bodies that expand with parasympathetic neural stimulation to create an erection. Thick fascia, called tunica albuginea, assists in producing rigid-ity during erection. Each corpus cavernosum features a centrally located cavernosal artery, which arises from the penile artery. A porous septum separates the two corpora and allows for trans-corporal blood exchange. The corpus spongiosum is located on the ventrum of the penis. The corpus spongiosum lacks a tough fascia similar to tunica albuginea and thus does not exhibit the same rigidity during erection.Scrotum and TestesThe scrotum is a potential space that surrounds the testes, epididymis, and spermatic cords. The scrotum is comprised of many layers aside from skin and dartos fascia, and each derives from a particular layer of the anterior abdominal wall. The external spermatic fascia arises from the external oblique fascia, the cremasteric fascia arises from the internal oblique fascia, and the internal spermatic fascia arises from the transver-sus abdominis fascia. The testes are separated from the scrotal layers by the visceral and parietal layers of the tunica vaginalis, between which hydroceles form. The spermatic cord contains Brunicardi_Ch40_p1759-p1782.indd 176001/03/19 6:34 PM 1761UROLOGYCHAPTER 40the vas deferens, the venous pampiniform plexus, and arterial blood supply to the superior pole of the testis via three separate sources. The testicular artery arises directly from the aorta; the deferential artery, which supplies the vas deferens, arises from the internal iliac artery; and the cremasteric artery, which sup-plies the cremaster musculature, arises from the external iliac artery. The presence of multiple arterial sources provides col-lateral flow and prevents ischemia in the event of injury to a particular vascular branch. The venous pampiniform plexus can dilate to form a palpable or visible varicocele, which can serve as an etiology of chronic testicular pain or infertility.INFECTIONCystitisUncomplicated cystitis usually presents as new onset urinary frequency, urgency, and dysuria. Patients may also report lower back pain, suprapubic pain, foul-smelling urine, or gross hema-turia. Urinalysis with microscopy assists with diagnosis by confirming the presence of pyuria, hematuria, and bacteriuria. Office dipstick may be helpful, as the presence of nitrites reflects bacterial colonization and the presence of leukocyte esterase reflects pyuria. Risk factors for the development of uncompli-cated cystitis include female gender, sexual activity, and use of spermicides.1 Three days of antibiotics are generally sufficient for treatment of uncomplicated cystitis. Fluoroquinolones and trimethoprim-sulfamethoxazole are well tolerated and are eas-ily available. Nitrofurantoin, which is also commonly used for uncomplicated cystitis, requires 5 days of treatment. Men with uncomplicated cystitis should undergo 7 days of treatment.Complicated cystitis may arise in the setting of structural or functional urinary tract abnormalities, recent urinary tract instru-mentation, recent antimicrobial use, immunosuppressed states, pregnancy, or hospital-acquired infection. Symptoms may be simi-lar to uncomplicated cystitis but can progress to pyelonephritis if left untreated. Elderly or very young patients tend to exhibit leth-argy, change in mental status, or anorexia, which may confound the diagnosis of a urinary tract infection. Patients may require hos-pitalization if febrile or if symptoms are severe. Treatment consists of 10 to 14 days of antibiotics. Fluoroquinolones or trimethoprim-sulfamethoxazole are usually effective and should be administered based on culture results and/or regional bacteriograms. Asymp-tomatic bacteriuria does not require treatment unless detected dur-ing pregnancy or if urinary tract instrumentation is planned.1PyelonephritisPyelonephritis arises when a bladder infection ascends proxi-mally along the ureters to the renal parenchyma. It may also result from hematogenous spread, such as in the case of intra-venous drug abuse or in patients with bacteremia from other sources. Patients with pyelonephritis may present with fevers, flank pain, nausea, vomiting, and lower urinary tract symptoms. Physical exam may reveal tenderness of the costovertebral angle. Patients may appear toxic, with poor oral intake. Labora-tory evaluation may reveal leukocytosis with elevated neutro-phils. Urinalysis usually demonstrates the presence of pyuria and bacteriuria, and urine culture should be sent prior to start-ing broad-spectrum antibiotics. Imaging should be considered to rule out obstruction, which could prolong the recovery period despite appropriate antimicrobial treatment.Acute pyelonephritis requires 7 to 14 days of antibiotic therapy. Mild or moderate cases, even if febrile, can safely be treated as an outpatient with oral antibiotics. Fluoroquino-lones and trimethoprim-sulfamethoxazole are ideal for treating pyelonephritis. Nitrofurantoin should not be used as it does not penetrate renal parenchyma. Patients with concern for sepsis or inability to tolerate oral intake may require hospitalization with IV antibiotics while awaiting culture results. Fevers may persist for up to 72 hours despite appropriate treatment. The presence of persistent fevers or symptoms after this time period warrants cross-sectional imaging to rule out renal or perinephric abscess. Treatment for renal or perinephric abscess usually consists of percutaneous drainage and broad-spectrum IV antibiotics.ProstatitisAcute prostatitis is marked by fever, suprapubic or perineal pain, and new onset lower urinary tract symptoms, namely dys-uria, frequency, urgency, changes in stream caliber, or difficulty emptying the bladder. It is most often caused by urinary patho-gens. Digital rectal exam may reveal a tender and soft pros-tate. Bladder drainage with a Foley or suprapubic tube may be required if urinary retention is present. Treatment consists of a long-term course (4–6 weeks) of antibiotics. If not treated in a timely fashion, acute prostatitis can develop into severe sepsis or a prostatic abscess. Prostatic abscesses may require drainage via a transurethral approach or transrectal needle aspiration.Chronic prostatitis may be bacterial or abacterial. Symptoms in both cases include perineal, suprapubic, or penile pain, along with urinary frequency, urgency, or change in stream caliber. Men may also report pain in the groin, lower back, or testes. Fever is not observed in chronic prostatitis, and onset may occur over many months. Patients with chronic bacterial prostatitis may also report recurrent UTIs, with cultures consistently exhibiting the same bacteria. Differentiation between the two etiologies requires culture of expressed prostatic secretion to confirm the presence or absence of bacteria. Treatment of chronic bacterial prostatitis includes long-term antibiotics and α-blockers.Chronic abacterial prostatitis is also known as chronic pel-vic pain syndrome (CPPS). Symptoms are similar to chronic bacterial prostatitis, but generally do not respond well to long-term antibiotics for treatment. It is generally somewhat more difficult to achieve symptomatic relief when treating CPPS, and options include α-blockers, NSAIDs, neuromodulators, and/or pelvic floor physical therapy.2Epididymo-OrchitisEpididymitis refers to inflammation of the epididymis. In most cases of bacterial infection, the testis is also affected, thus is encompassed by the term “epididymo-orchitis.” Common eti-ologies include sexually transmitted infection, especially in younger males, or urinary tract infection, which is more com-monly seen in older males. Other possible etiologies include underlying congenital urologic abnormality or incomplete blad-der emptying. Symptoms include pain and swelling of the epi-didymis and testis. Some men may report nausea or vomiting, which arises as a result of irritation of the spermatic cord. Uri-nary symptoms may be present, but absence of symptoms does not rule out bacterial epididymo-orchitis. Physical exam gen-erally reveals a tender, swollen epididymis and testis. Scrotal skin erythema or reactive hydrocele may be present as well. A complete blood count should be performed to rule out leukocy-tosis, and urinalysis with urine culture should be collected prior to initiation of antibiotics. Urethral swab should be performed if sexually transmitted infection is a possible etiology. The clini-cal presentation of testicular torsion can be quite similar to that of Brunicardi_Ch40_p1759-p1782.indd 176101/03/19 6:34 PM 1762SPECIFIC CONSIDERATIONSPART IIepididymo-orchitis. It may be quite difficult to clinically differenti-ate the two entities, but one should keep in mind that the onset of torsion tends to be slightly more acute (within 4–8 hours) than that of epididymo-orchitis (which generally arises over the course of 24–48 hours). Scrotal ultrasound can assist in diagnosis; how-ever, in cases of severe orchitis, testicular flow can be compro-mised, which may raise concern for torsion. Scrotal exploration should be considered in any equivocal case: a missed torsion can result in testicular loss secondary to necrosis.Treatment of epididymo-orchitis consists of single dose of ceftriaxone and azithromycin if there is concern for sexu-ally transmitted infection, as well as 14 days of oral antibiotic therapy, NSAIDs, and scrotal support. If the patient exhibits fevers or toxic presentation, hospitalization with IV antibiotics may be required.Balanitis and BalanoposthitisBalanitis refers to inflammation of the glans penis. Balano-posthitis arises when the foreskin is also involved. Common etiologies include fungal infection, bacterial infection, contact dermatitis, or local trauma. Exam reveals a diffusely erythema-tous and warm glans penis, with inner preputial erythema as well if balanoposthitis is present. Treatment includes appropri-ate hygiene, topical antibiotics or antifungals, and occasionally topical steroids. If there is an inappropriate response to treat-ment, the differential diagnosis should include malignancy, pso-riasis, or infectious agents such as HPV.3URINARY TRACT OBSTRUCTIONUrolithiasisRenal stone disease is a common problem that is a major health care burden to society today. The prevalence of stone disease in the United States has increased over the past several decades as reported by the National Health and Nutrition Examination Survey (NHANES), and was estimated at 8.8% for the period between 2007 and 2010.4 This prevalence has increased with factors such as global warming, poor diet choices, and the obesity trend. Overall, the total estimated annual expenditure for individuals with claims for a diagnosis of urolithiasis was almost $2.1 billion in 2000, representing a 50% increase since 1994.5 Risk factors for stone formation include dietary habits, family history, white race, geographical location or occupa-tional exposure to heat/dehydration, intestinal disease, and male gender, although the gender gap is decreasing.6 More recently, stone formation has also been associated with obesity, metabolic syndrome, and diabetes mellitus.7,8Stones are most commonly composed of calcium oxa-late. Other stone compositions include calcium phosphate, uric acid, cystine, medication-related, and infectious stones (stru-vite or carbonate apatite) or a mix thereof. Stone composition can vary based on a number of underlying pathophysiological processes. For example, hyperoxaluria may be seen in patients who have undergone small bowel resection, particularly the ter-minal ileum. This can result in an increase in unabsorbed fatty acids and bile salts which undergo saponification by binding with calcium in the bowel. The increase in unbound oxalate is absorbed by the large intestine and subsequently excreted in the urine, favoring the formation of calcium oxalate stones. Uric acid stones will form in a context of acidic urinary pH, low uri-nary volume, and high oral intake of purines. Countering these factors by alkalinizing the urine and increasing urine output Figure 40-1. Struvite (infectious) stones are evident on a plain radiograph of the abdomen. The red arrows highlight a left Stag-horn calculus filling the renal pelvis and calyces and several stones in the right lower pole of the kidney.may lead to dissolution of uric acid stones and reduced fur-ther formation.9 Proteus species, Klebsiella species, and other urease-producing bacteria metabolize urea into ammonium and bicarbonate. The alkaline milieu (pH >7) predisposes to infec-tious (struvite) stones with the precipitation of magnesium, ammonium, and phosphate (Fig. 40-1).Evaluation for first-time stone formers should include a complete medical history and physical exam, basic metabolic panel, calcium, uric acid, urinalysis and culture, and radio-graphic imaging. A noncontrast computed tomography (CT) scan is the most sensitive (98%) and specific (97%) exam to detect urolithiasis10 and can provide additional anatomical infor-mation useful for surgical planning, although its use in recurrent stone formers should be balanced by cost and radiation expo-sure. Low-dose CT is currently the preferred imaging study for patients with a body mass index (BMI) <30. This imaging study uses less than one-third of the estimated effective ionizing radiation dose (3 mSv) compared to standard dose noncontrast CT (10 mSv),10 while maintaining excellent sensitivity (95%) and specificity (97%).11 Plain abdominal X-ray can be used to follow radiopaque stones such as calcium-containing stones or struvite stones, although at times struvite can be difficult to see on plain X-ray, especially when the fragments are small. Uric acid and triamterene stones are radiolucent on plain abdominal X-ray but will be visible on noncontrast CT. A full metabolic evaluation with a 24-hour urine collection is indicated in recur-rent stone formers, high-risk stone formers, or interested first-time stone formers.12The natural history of stones is variable and depends pri-marily on their size and location. Smaller and more distal stones are much more likely to pass spontaneously without the need for surgical intervention.13,14 Patients with ureteral stones ≤10 mm can be offered a period of observation if their pain is well controlled without signs of infection or renal insuf-ficiency. α-Blockers, which inhibit ureteral peristalsis, have been shown in meta-analyses to be particularly useful in patients with distal ureter stones ≤10 mm, improving the rate of stone passage from 54% to 77%,15,16 with shortened time to expulsion and fewer colic episodes.171Brunicardi_Ch40_p1759-p1782.indd 176201/03/19 6:34 PM 1763UROLOGYCHAPTER 40Patients who have not passed their stone after a 4to 6-week observation period, those with larger stones, or those who desire immediate intervention, may be offered one of three definitive surgical interventions: shockwave lithotripsy (SWL), ureteroscopy (URS), or percutaneous nephrolithotomy (PCNL). Open surgical management of stones has been relegated to historic interest for the most part with less than 1% of stone surgery needing to be done open with access to modern endou-rologic equipment. The choice of the procedure will depend primarily on stone-related factors (e.g., stone size, location, and composition/density), and patient-related factors (e.g., comor-bidities, coagulopathy, obesity, renal anatomy, and surrounding structures).Shockwave lithotripsy is the procedure associated with the least morbidity and the lowest complication rate but is also associated with a lower success rate at treating stones as a single procedure and requires the patient to pass the stone fragments afterwards.15,16 The modality can be used for stones in the prox-imal ureter (particularly if <10 mm) or non–lower-pole renal stones <2 cm.15,16 The stone is located under fluoroscopic guid-ance, which is coupled to an extracorporeal lithotripter aimed at the stone. The stone is fragmented in a completely nonin-vasive manner. Complications associated with this procedure include subcapsular or perinephric renal hematoma and ureteral obstruction by stone fragments (“Steinstrausse”; Fig. 40-2). Ureteroscopy is the procedure of choice for patients with middle or distal ureteral stones. It also has a higher success rate than SWL in treating >10-mm proximal ureteral stones and renal stones.15,16 This procedure involves advancing a semi-rigid or flexible ureteroscope to the level of the stone and fragmenting it under direct visualization, often using a holmium:YAG laser. The surgeon is able to visualize the stone during fragmentation and thereby has some control over how small the fragments are. In addition, stone fragments may also be actively removed with a small nitinol stone basket. This is where the procedure may have an advantage over SWL. However, many patients have a ureteral stent placed after ureteroscopy, and, although tempo-rary, this remains a major source of morbidity for the patient. Specific complications of URS include ureteral injury or stric-ture. PCNL is reserved for patients with larger or more complex Figure 40-2. Ureteral obstruction in a patient with Steinstrausse. A plain abdominal radiograph (KUB) demonstrates Steinstrausse in the right distal ureter between the white arrows.stone burden, and requires a percutaneous tract into the kidney. Most stones larger than 2 cm are treated with PCNL although there is a role for PCNL for smaller stones located in the lower pole of the collecting system.18,19 More powerful lithotripters (pneumatic, ultrasound) and larger instruments (stone graspers) can be used to fragment and remove these larger stones through the percutaneous tract. Complications include injury to adjacent organs, acute and delayed renal bleeding due to pseudoaneu-rysm or arteriovenous fistula formation, sepsis, or renal pelvis perforation.General preventative measures include correcting dietary habits, particularly increasing fluid intake to produce >2.5 liters of urine per day, limiting sodium, reducing animal protein intake, and monitoring foods high in oxalate. Medical therapy such as thiazide diuretics (helpful for hypercalciuria), urinary alkalization with potassium citrate, or allopurinol may also be indicated depending on the clinical situation.12Benign Prostatic HyperplasiaBenign prostatic hyperplasia (BPH) refers to the histological findings of smooth muscle and fibroblast/epithelial cell pro-liferation in the transition zone of the prostate. Lower urinary tract symptoms (LUTS) may be secondary to benign prostatic enlargement (BPE) causing progressive bladder outlet obstruc-tion but may also be due to numerous other conditions (e.g., urethral stricture, infection, overactive or neurogenic bladder, malignancy). Although some male patients with LUTS may have BPE, not all patients with an enlarged prostate have LUTS. The prevalence of LUTS attributed to BPH in men over the age of 50 is estimated at 50% to 75% and increases with age with a prevalence of 80% in men over the age of 70.20 The treatment modalities have dramatically evolved over the past decades, with medical management typically used for first-line therapy. Endoscopic and minimally invasive techniques are used for those failing or intolerant of medical therapy.Men with BPH/LUTS are evaluated with a complete his-tory and physical exam including digital rectal exam. LUTS should be clearly defined, in addition to their severity and degree of bother. Validated questionnaires to quantify the patient’s symptoms and degree of bother include the American Urologi-cal Association Symptom Index (AUA-SI) and the International Prostate Symptom Score (IPSS).21,22 Complications of BPH such as urinary retention, incontinence, renal failure, hema-turia, or recurrent infections should also be considered. Basic workup includes a urinalysis and culture to rule out infection. After an informative discussion about the risks and benefits of prostate cancer screening, a serum PSA is measured when life expectancy is >10 years and if the diagnosis of prostate can-cer will alter management.23 Other diagnostic testing such as cystoscopy, cytology, postvoid residual (PVR), urodynamics, and radiologic imaging of the prostate, although not done rou-tinely, may be required in patients with a definite indication (e.g., hematuria), uncertain diagnosis, poor response to therapy, or for surgical planning.24The first line of treatment is most commonly pharmaco-therapy for those men with bothersome symptoms. α-Blockers work by relaxing the smooth muscle of the prostate and bladder neck. All α-blocker agents are equally effective,25 and their side effects may include orthostatic hypo-tension, dizziness, asthenia, headache, nasal congestion, and retrograde ejaculation. Their effect is usually seen within days. Five-α reductase inhibitors (5-ARIs) block the conversion of 2Brunicardi_Ch40_p1759-p1782.indd 176301/03/19 6:34 PM 1764SPECIFIC CONSIDERATIONSPART IItestosterone to dihydrotestosterone (DHT), the hormone primar-ily responsible for BPH progression. These reduce prostatic size by 20% to 25%,26 but their effects are seen only after 4 to 6 months. Side effects include erectile dysfunction, decreased libido, and, rarely, gynecomastia. 5-ARIs, but not α-blockers, can alter disease progression as demonstrated by two landmark tri-als, the MTOPS27 and CombAT28 trials. These trials evaluated combination therapy using α-blockers and 5-ARIs. Patients on 5-ARIs, particularly those with larger prostates, had a reduced risk of both developing acute urinary retention and requiring surgical intervention. More recently, daily phosphodiesterase-5 inhibitors, which are most often used for erectile dysfunction (ED), have now been approved for treating patients with BPH. These can be particularly valuable in patients with concomitant ED.29,30Surgical modalities for BPH continue to evolve towards less invasive endoscopic procedures. Transurethral resection of the prostate (TURP) remains the mainstay of endoscopic pro-cedures, with low treatment failure and complication rates.31 TUR syndrome is associated with prolonged use of hypotonic irrigation fluid, resulting in fluid overload and dilutional hypo-natremia. Symptoms include nausea/vomiting, bradycardia and hypertension, pulmonary edema, mental status changes, and rarely death. Other endoscopic modalities used today include bipolar TURP and various laser procedures (e.g., Ho:YAG laser enucleation of the prostate, Ho:YAG laser ablation of the prostate, and photoselective vaporization of the prostate) with the goal of enucleating or vaporizing prostatic tissue. Normal saline is used for irrigation with these modalities, which greatly reduces the risk of TUR syndrome. Generally, laser procedures have been associated with shorter catheterization time and length of stay with comparable improvements in LUTS to open prostatectomy or TURP.32-34 Open, and more recently laparo-scopic and robotic simple prostatectomy can also be performed for patients with moderate-severe, bothersome LUTS due to BPH. These are usually reserved for patients with larger pros-tatic volumes (>100 cc), or patients requiring concomitant blad-der surgery (e.g., bladder diverticulectomy or stones).23Urethral StrictureA urethral stricture is an area of scarring or fibrosis that causes concentric narrowing of the urethra, impeding the flow of urine as it drains from the bladder. Strictures occur at a prevalence of 0.9% of the population in the United States.35 Causes of urethral stricture disease include trauma (19%), iatrogenic causes (33%), inflammatory causes (15%), and idiopathic causes (33%).36 Symptoms of urethral stricture disease include incomplete emptying, weak urinary stream, urinary urgency/frequency, and pain.37,38The anatomy of the urethra in men can be divided into the following segments proceeding from cephalad to caudad: prostatic, membranous, bulbous (the area between the pelvic floor and the penoscrotal junction), and penile. A stricture can occur in any segment of the urethra, but it is most common in the bulbar urethra.Options to treat urethral stricture disease can be divided into two general categories: endoscopic and surgical reconstruc-tion. Endoscopic treatments include a urethral dilation or stric-ture incision with a cystoscope. The latter is referred to as a direct vision internal urethrotomy. The success rate of one endo-scopic attempt to treat a urethral stricture is around 30%.39 The success of repeat endoscopic treatments of a urethral stricture drops to 13%, and recurrent dilations have been associated with the need for more complex reconstructive surgeries for definitive management.39,40 For that reason, com-mon practice is to attempt one endoscopic intervention prior to referral for reconstructive surgery.Surgical reconstruction of the urethra, referred to as a ure-throplasty, can be divided into two general categories: excisional and tissue substitution. An excisional repair involves resection of the strictured segment of the urethra, and direct anastomo-sis of the two healthy urethral ends. This repair technique is generally reserved for membranous strictures and short bulbar strictures. Tissue substitution involves augmenting a narrowed urethral lumen with free tissue grafts. The most common tissue substitute is buccal (oral) mucosal graft.Other Causes of ObstructionRetroperitoneal fibrosis (RPF) is a rare cause of ureteric obstruction secondary to an inflammatory and fibrotic pro-cess of the retroperitoneal structures. Most cases (>70%) are idiopathic. Identifiable causes in the remaining cases include periaortic inflammation due to aneurysms, medications (e.g., methysergide, ergot derivatives, β-blockers, phenacetin), infec-tions (e.g., tuberculosis, schistosomiasis), and malignancy (e.g., lymphoma, multiple myeloma, sarcoma). Symptoms are non-specific and may include general abdominal discomfort or back pain, flank pain due to ureteral obstruction, or lower extremity edema due to vena caval compression. Laboratory abnormali-ties such as normocytic anemia, an elevated C-reactive protein, or ESR are identified in about two-thirds of cases.41 The classic radiological findings consist of a well-defined retroperitoneal soft tissue mass encasing the great vessels with medialization of the ureters. Contrast enhancement on CT scan, magnetic reso-nance imaging (MRI), and positron emission tomography (PET) scan can also be used to monitor disease activity and assess response to treatment.42Patients with symptomatic renal obstruction, renal insuf-ficiency, or signs of infection should be decompressed with either ureteral stents or nephrostomy and monitored for postob-structive diuresis. Biopsy of the retroperitoneal mass to exclude malignancy should be considered prior to commencing treat-ment. Steroid therapy remains the mainstay of medical treat-ment, although other immunosuppressive agents have been described.43 If medical treatment fails, open or minimally inva-sive bilateral ureterolysis with intraperitonealization or omental wrapping of the ureters is indicated.Ureteral obstruction secondary to tumor (benign or malig-nant) is commonly encountered. Ureteral stenting can be tried initially, but it fails in approximately one-half of cases.44 Other strategies such as percutaneous nephrostomy, ureteral stenting in tandem, metallic, and metal-mesh stents have been described. Metallic stents may be more cost-effective due to less frequent stent exchanges,45-47 although cost savings may be offset by the limited life expectancy in this patient population.44GENITOURINARY TRAUMAGenitourinary (GU) trauma is rare. Approximately 10% of vic-tims of abdominal trauma will have a urologic injury.48 Any portion of the GU tract can be injured including the follow-ing: kidneys, ureters, bladder, urethra, and the external genita-lia including the testicles. Mechanisms of trauma parallel other injury mechanisms, the majority of which include blunt and penetrating injuries. This section will be divided into the man-agement of each organ involved in the GU system.3Brunicardi_Ch40_p1759-p1782.indd 176401/03/19 6:34 PM 1765UROLOGYCHAPTER 40Table 40-1The American Association for the Surgery of Trauma (AAST) renal trauma grading systemGRADEDESCRIPTIONMANAGEMENT1Contusion or nonenlarging subcapsular perirenal hematomaGenerally managed conservatively.2Perinephric hematoma without obvious parenchymal laceration on CT, or a <1 cm laceration into the cortex of the kidneyGenerally managed conservatively in a stable patient.3>1 cm laceration into the cortex without involvement of the collecting systemGenerally managed conservatively in a stable patient.4A deep laceration into the collecting system with evidence of urinary extravasation on CT, or a segmental renal artery or vein injury with contained hematoma, or partial vessel laceration, or vessel thrombosisCan be observed expectantly in the stable patient, but may require subsequent urgent or delayed repair. Renal artery embolization may be an option for those who fail conservative therapy.5Renal pedicle injury or multiple deep renal lacerations (“shattered kidney”)Patients often require surgical exploration, but stable patients with only parenchymal injury may be safely treated conservatively.CT = computed tomography.KidneysThe prime goal of renal trauma management is preservation of renal function. Renal trauma has become largely nonop-erative in modern times, especially in the setting of lowto intermediate-grade renal injuries from a blunt mechanism of action. The role of angioembolization through vascular and interventional radiology has further increased this nonopera-tive management.49,50The first goal of renal trauma is to accurately grade the renal injury. The gold standard test to diagnose and stage a renal injury includes a CT scan with IV contrast, with delayed images. In most centers, this is referred to as a “CT urogram,” in which delayed contrast imaging delineates the upper urinary tract collecting system. Criteria that would mandate renal imaging include the presence of gross hematuria, microscopic hematuria with hypotension, and mechanisms increasing the prevalence of renal injury (sudden deceleration injuries, flank contusion, etc). The American Association for the Surgery of Trauma (AAST) renal trauma grading system is described in Table 40-1.51,52The management of renal injuries depends not only on the grade but also on the injury mechanism and clinical symptoms. Absolute indications for surgical or radiological intervention on renal trauma include life-threatening hemorrhage, renal pedicle avulsion, or pulsatile/expanding retroperitoneal hematoma. Moreover, those suffering penetrating renal trauma with a ret-roperitoneal hematoma should undergo exploration when hemo-dynamic instability exists.In a hemodynamically stable patient with a renal injury, renal trauma should be initially observed. Data suggests that this approach may even be feasible in the setting of isolated, penetrating renal injuries.53 Conservative management entails bed rest and hemodynamic monitoring. Patients with a grade 4 renal injury (Fig. 40-3A to D) should be treated in the same manner, and a repeat CT scan should be done to make certain that the urinary extravasation has resolved.54 Otherwise, urinoma and subsequent abscess formation may occur. If uri-nary extravasation is persistent, placement of a ureteral stent or nephrostomy tube should be considered.Across the board, the most common surgery for renal sur-gery in modern times is unfortunately a nephrectomy.55 Early renal vascular control may minimize nephrectomy rates.56 This is accomplished by isolating the renal vascular medially prior to opening the perinephric hematoma. If uncontrolled bleeding is encountered once the hematoma is opened, occlusion of the renal vasculature can be performed. At that time, a renorrhaphy can be safely done as can a nephrectomy in the setting of a grade 5 renal injury.UretersThere is no association between the magnitude of ureteral injury and the degree of hematuria that is present.57 A high index of suspicion is required. Diagnosis requires either a CT urogram, IVP, or a cystoscopy with a retrograde pyelogram. Unlike renal injury, the ureters more commonly are injured through iatro-genic mechanisms. Common surgical procedures in which the ureters are injured include gynecological, colorectal, and uro-logical surgeries. The repair of ureteric injuries depends on the time of identification from initial injury, location, and length of the injured ureteral segment involved.Iatrogenic ureteral injuries should be initially managed with ureteral stent placement when possible. When stenting is not fea-sible, open repair may be attempted when the patient presents shortly after injury. When stent placement is not feasible or when presentation is delayed, nephrostomy tube placement should be considered until formal repair can be safely done.Ureteral injuries of traumatic origin (penetrating injuries, multiple intra-abdominal traumas) should be repaired during the index admission when possible. Hemodynamically stable patients undergoing laparotomy for other reasons in which a high index of suspicion of a ureteral injury is present should have ureteral exploration. Stable patients in this same situation that are identified to have a ureteral injury should have primary repair at the time of exploration. If a patient is hemodynamically unstable, the ureter can be ligated with subsequent nephrostomy tube placement. Ureteral repair can then be delayed until the patient is stable for surgery.4Brunicardi_Ch40_p1759-p1782.indd 176501/03/19 6:34 PM 1766SPECIFIC CONSIDERATIONSPART IIABCDFigure 40-3. Grade 4 renal injury as demonstrated on abdominal computed tomography imaging with intravenous contrast. A. The yellow arrow points to extravasated contrast in the right perirenal fat. B and C. The right kidney has been fractured, as seen at the yellow arrow. Hematoma and extravasated contrast are seen in the mid-anterior pole of the kidney. D. Coronal view. The yellow arrow reveals the upper pole renal fracture with disruption of the collecting system.The definitive operative management of a ureteral injury depends on the location and the extent of devitalization. It is important to debride devitalized ends of the ureter, whether it is from a contusion via a gunshot wound or an iatrogenic ther-mal injury. Upper ureteral injuries that are short can generally be resected and anastomosed primarily.58 Ureteral mobilization with preservation of ureteral adventitia to maintain vascular supply can aid in bridging short defects. In modern times, more aggressive maneuvers to directly anastomose more proximal ureteral injuries to the bladder are possible. Maneuvers used to bridge the defect of ureteral length for direct anastomosis to the bladder include the following: bladder mobilization with liga-tion of the contralateral bladder pedicles, psoas hitch (tacking the bladder down to the ipsilateral psoas tendon), and the Boari flap with downward nephropexy. Creation of a Boari flap uti-lizes a tubularized flap of anterior bladder wall to bridge long defects. Bridging defects as high as the proximal ureter have been reported in association with this technique.59 When blad-der-to-ureter anastomosis is not possible with these maneuvers, the remaining options include trans-ureteroureterostomy (anas-tomosing the injured ureter to the contralateral ureter), creation of an ileal ureter, or renal auto transplantation to the pelvis.BladderThe bladder can be injured through iatrogenic and classic trau-matic mechanisms. Indications for bladder imaging include gross hematuria in the setting of injuries with a correlation for bladder injury. The most common clinical scenario is gross hematuria associated with a pelvic fracture, which is associated with a 29% chance of bladder laceration.60 Diagnosis of bladder injuries requires either a CT cystogram or a fluoroscopic cysto-gram. The sensitivities and specificities of these two modalities are similar.61,62 The bladder should be filled with approximately 300 cc of contrast for either of these imaging modalities. Contrast may be visible at the sight of injury, within the perito-neal space (Fig. 40-4A), or in the perivesical space (Fig. 40-4B). Simply capping the Foley catheter alone on a delayed excretory phase of abdominal CT imaging is insufficient to diagnose a bladder injury.61Two general categories of bladder injuries are extraperito-neal and intraperitoneal injuries. An intraperitoneal injury requires repair during the index admission after the patient has been resuscitated. Delayed repairs are associated with abdominal sepsis. Conversely, extra peritoneal injuries can gen-erally be managed with Foley catheter drainage alone. Situa-tions in which extraperitoneal bladder injuries should be treated with operative repair include complex injuries involving bone spicules from a pelvic fracture within the laceration and concur-rent rectal or bladder lacerations, which increase the possibility of fistula formation. Bladder neck injuries should also be treated operatively during the index admission as these injuries occa-sionally do no heal with Foley catheter drainage alone. Repeat cystography should be done 7 to 14 days later prior to Foley removal to ensure that the laceration, or operative repair, has healed.63Urethral InjuriesCommon mechanisms of trauma of the urethra include pelvic fracture associated injuries and straddle injuries. Pelvic fracture associated injuries occur at the level of the membranous urethra, whereas straddle injuries occur at the level of the bulbar urethra. The clinical hallmark of a urethral injury is blood at the meatus. A retrograde urethrogram should be done when this clinical sign is present to diagnose an injury, prior to attempted Foley cath-eter placement (Fig. 40-5A).64,65The initial step in management of a urethral injury is bladder drainage to prevent urinoma formation and subsequent abscess formation. In general, this is accomplished through 5Brunicardi_Ch40_p1759-p1782.indd 176601/03/19 6:35 PM 1767UROLOGYCHAPTER 40Figure 40-4. Intraperitoneal and extraperitoneal bladder injuries. A. During a computed tomography (CT) cystogram, intraperitoneal contrast is seen within the peritoneal space at the red arrow. B. During a CT cystogram, extravesical contrast is seen contained within the extraperitoneal space at the red arrow.ABFigure 40-5. A. Retrograde urethrogram showing an area of nar-rowing at the double white arrow. This indicates a bulbar urethral stricture. B. After urethroplasty, a retrograde urethrogram demon-strates a normal-appearing and patent bulbar urethra at the arrow.ABplacement of an SP tube. After stabilization, some centers per-form “primary urethral alignment.” This is a dual antegrade and retrograde endoscopic procedure utilizing fluoroscopy to bridge the urethral defect and to place a Foley catheter across the injury. Subsequent restructure rates are high, but the severity of stricture formation may be less when primary alignment is performed.66 If patients are managed with an SP tube alone, the site of disruption leaves the patient with a urethral stricture and subsequent restructure. This requires a treatment with a urethro-plasty after the patient’s period of convalescence has resolved (Fig. 40-5B).Penetrating injuries to the anterior urethra are rare. In a hemodynamically stable patient with an uncomplicated injury, it is expert opinion to perform exploration with primary repair during index admission. Complicated injuries with extensive tissue devitalization should be managed with SP tube urinary diversion and delayed reconstruction.67External Genital InjuriesPenile fractures classically occur with excessive torqueing of the erect penis. This excessive torqueing results in rupture of the tunica albuginea, the fascial coating of the erectile bodies. Common symptoms include immediate detumescence with subsequent development of a hematoma. Clinical history and examination alone are sufficient to warrant surgical exploration with primary suture repair of the corporal body laceration. For equivocal cases, ultrasonography or an MRI may be done.68,69 Up to 10% of penile fractures are associated with urethral inju-ries. Blood at the meatus signifies the possibility of a coexisting urethral injury. This should be evaluated with either a retrograde urethrogram or cystoscopy at the time of repair.Scrotal trauma generally occurs from a blunt mechanism. Injuries to the testis, epididymis, and spermatic cord may occur. Hematomas with subsequent ecchymosis are common with such injuries. Testicular rupture occurs with fracture of the fascial coating of the testicle, called the tunica albuginea. This may occur with blunt or penetrating mechanisms. The most spe-cific findings on ultrasonography are loss of testicular contour and heterogeneous echotexture of parenchyma. The highest reported sensitivity for testicular rupture on ultrasound is 93%.70 With diagnosis of a testicular rupture or when a high index of Brunicardi_Ch40_p1759-p1782.indd 176701/03/19 6:35 PM 1768SPECIFIC CONSIDERATIONSPART IIBladderUrethraPosterior prostateAnterior prostateABFigure 40-6. Coudé catheter. A. A schematic drawing of a lat-eral view of the prostatic urethra showing the upward angulation at the bladder neck, which a coudé catheter is helpful in negotiating. B. The tip of a coudé catheter. Note the curved tip, which should always point to 12 o’clock when inserted.suspicion is present (especially with penetrating trauma), explo-ration should be performed. Testicular salvage rates are high in modern times and involve suture repair of the site of rupture.70 When primary repair is not possible, a simple orchiectomy should be performed.EMERGENCIESAcute Urinary RetentionAcute urinary retention (AUR) can happen in men or women and results from a variety of causes, although it most commonly occurs in men with benign prostatic hyperplasia (BPH).71,72 Other chronic causes of poor bladder emptying, such as diabetic neuropathy, urethral stricture, multiple sclerosis, or Parkinson’s disease, can result in episodes of complete urinary retention, often when the bladder becomes overdistended. This frequently occurs in the hospital setting when patients have limited mobil-ity and are receiving medications that decrease bladder con-tractility, including opiates or anticholinergics. Constipation, a common side effect of those medications, can itself worsen uri-nary retention. Significant hematuria can result in the formation of blood clots, which may block the urethra and cause retention.Although some patients receiving large doses of narcot-ics or those with chronically decompensated bladders may not experience discomfort, most patients with AUR have significant pain. Untreated severe urinary retention (often accompanied by overflow incontinence) may result in acute renal failure. Treat-ment should include placement of a urethral catheter as quickly as possible. However, BPH or urethral strictures often make the placement of a catheter difficult. For men with BPH, a coude (French for curved) catheter is helpful in negotiating past the angulation in the prostatic urethra (Fig. 40-6A). The curved por-tion (which is angled in line with the balloon port) is maintained at the 12 o’clock position as it is passed through the urethra (Fig. 40-6B). A common mistake is to use a smaller catheter to bypass the enlarged prostate. However, a larger (18F to 20F) catheter is less flexible and is more likely to push into the blad-der rather than curl in the prostatic urethra.Smaller catheters, however, are quite useful for bypass-ing a urethral stricture. A urethral stricture should be suspected when the catheter meets resistance closer to the meatus, as many strictures occur in the distal urethra, which is narrower than the proximal portion. Using a 12F or 14F catheter often will allow the passage of the catheter into the bladder. If cath-eter placement is not successful, a urologic consultation should be requested. The urologist can either choose to (a) use a cys-toscope, guidewire, and urethral dilators to dilate the stricture and place a Council-tip catheter via Seldinger technique; or (b) place a suprapubic tube approximately two fingerbreadths above the pubic symphysis. With regard to the suprapubic tube, ultrasound-guidance or aspiration with a finder needle should be used first to localize the bladder and avoid intra-abdominal contents, although bowel injury is unlikely with a distended bladder filling the pelvis. If hematuria is the cause of retention, continuous bladder irrigation often is necessary to prevent clot formation. This is done through a large three-way catheter that has an additional port for fluid inflow. Fluid is infused by grav-ity only because the use of higher pressure may result in bladder rupture if outflow is occluded.Once the bladder is adequately drained, the cause of AUR should be addressed. For men with suspected BPH, an α-blocker such as tamsulosin should be started, and these have been shown to increase the likelihood of a successful trial without a catheter.73 Although finasteride and dutasteride (5α-reductase inhibitors) have been shown to reduce the incidence of urinary retention by 50%, they require several months to take effect and are most beneficial in large prostates; therefore, they will not provide significant benefit in the short term. Narcotics should be tapered as tolerated, and constipation should be treated.Acute spinal cord compression, which is accompanied by saddle paresthesias, is a neurologic emergency that requires neurosurgical or orthopedic consultation. In most cases, except severe neurologic injuries, patients will be able to resume void-ing, and the catheter can be removed after 1 to 2 days. Postvoid residuals should be checked with a portable ultrasound device (bladder scanner) or by “straight” catheterization to determine the residual amount of urine left after the patient tries to empty his or her bladder. In patients with severe liver dysfunction, the bladder scanner may inadvertently misinterpret ascites for urine. The inability to void or the presence of a postvoid residual over 200 mL is concerning for development of another episode of AUR. Patients may be given the option of an indwelling cath-eter for another few days with a subsequent voiding trial or to perform clean intermittent catheterization (CIC), whereby, after Brunicardi_Ch40_p1759-p1782.indd 176801/03/19 6:35 PM 1769UROLOGYCHAPTER 40Figure 40-7. Fournier’s gangrene. A. Necrotic scrotal skin from Fournier’s gangrene. B. Debridement of gangrenous tissue. Note the extensive debridement, which is commonly required. The right testicle required removal in this case (the left is wrapped in gauze), but typically, the testes are not involved with the necrotic process.predetermined intervals (4–6 hours) or after voiding attempts, the patient passes a catheter into the bladder and empties it. This is the preferred method because it reduces the likelihood of infections from indwelling catheters and may improve blad-der functionality. However, most patients are resistant to this approach.Testicular TorsionThe differential diagnosis of acute scrotal pain includes testicu-lar torsion.74 This usually occurs in neonates or adolescent boys but may be observed in other age groups. The blood supply to the testicle is compromised due to twisting of the spermatic cord within the tunica vaginalis, resulting in ischemia to the epididy-mis and the testis. In newborns, an extravaginal torsion also can occur with twisting of the tunica vaginalis and spermatic cord together. Risk factors for torsion include undescended testis, testicular tumor, and a “bell-clapper” deformity—poor guber-nacular fixation of the testicles to the scrotal wall.Clinical history is vital for diagnosis.75 Patients describe a sudden onset of pain at a distinct point in time, with subsequent swelling. Physical examination may demonstrate a swollen, asymmetric scrotum with a tender, high-riding testicle. Children normally have a brisk cremasteric reflex that usually is lost in the setting of torsion. The diagnosis is made by clinical history and examination but can be supported by a Doppler ultrasound, which typically shows decreased intratesticular blood flow rela-tive to the contralateral testis. If an ultrasound is not promptly available, timely surgical exploration should be performed.Immediate surgical exploration can salvage an ischemic testis.76 At the time of surgery, the contralateral testes also must be explored and fixed to the dartos fascia due to the pos-sibility that the same anatomic defect allowing torsion exists on the contralateral side. Midline (along the median raphe) or bilateral transverse scrotal incisions are made. Once the testis is detorsed, it should be assessed for viability after being given time for normal blood flow to resume. One can assess the blood flow using intraoperative Doppler or by incis-ing the tunica vaginalis and observing tissue viability. The testes are fixed to the dartos fascia with a small, nonabsorbable suture on their medial, lateral, and dependent aspects, taking care to ensure that the spermatic cord is not twisted before doing so. An orchiectomy should be performed to avoid later risk of abscess formation only if the testis is clearly necrotic.Fournier’s GangreneFournier’s gangrene is a necrotizing fasciitis of the male geni-talia and perineum that can be rapidly progressive and fatal if not treated promptly (Fig. 40-7). The mortality rate has been reported to be as high as 67%.77 Risk factors for Fournier’s gangrene include perirectal abscesses, diabetes, obesity, and chronic alcoholism.78 The often polymicrobial infection spreads along dartos, Scarpa’s, and Colles’ fascia. Clinical signs include perineal and scrotal pain, inflammation, necrosis, and crepitus.78 The diagnosis is largely made on clinical suspicion; however, radiographic findings on CT imaging often assist with the diag-nosis, including soft tissue air associated with fluid collections within the deep fascia.79Prompt and aggressive surgical debridement of nonvia-ble tissue and broad spectrum antibiotics are necessary to prevent further spread (Fig. 40-7A). Fecal diversion with endorectal tubes serve as an option for conservative fecal diversion.80 If there is damage to the external anal sphincter, 67patients may require a colostomy. Patients frequently require return trips to the operating room for further debridement. Negative pressure wound therapy systems have been shown to reduce hospitalization time by aiding in wound healing.81 Reconstructive strategies involving skin grafting are needed when large tissue defects result from extensive tissue damage.PriapismPriapism is a persistent erection for greater than 4 hours unre-lated to sexual stimulation.82 Priapism is divided into two types, based on the underlying pathophysiology. The most common type—low-flow/ischemic priapism—is a medical emergency. On examination, the penis is very tender, and both cavernosal bodies will be rigid while the glans will be flaccid. Decreased venous outflow with persistent inflow results in increased intracorporal pressure and tumescence, which is the normal process of erection. Diminished arterial inflow due to elevated Brunicardi_Ch40_p1759-p1782.indd 176901/03/19 6:35 PM 1770SPECIFIC CONSIDERATIONSPART IIintrapenile pressure usually is brief under normal circumstances. Priapism is essentially a compartment syndrome. With pro-longed erection (priapism), the sustained decrease in arterial inflow ultimately causes tissue hypoxia, acidosis, and edema and results in long-term fibrosis and impotence, and sometimes frank necrosis. Risk factors include sickle cell disease or trait, malignancy, medications, cocaine abuse, certain antidepres-sants, and total parenteral nutrition.82-84 If a cause is not identi-fied, a hematologic workup is necessary to rule out malignancy or blood dyscrasias.The management of priapism is rapid detumescence with the goal of preservation of future erectile function. The ability to achieve normal erections is directly related to the length of the episode of priapism. Ischemic priapism can be confirmed with a penile blood gas from the cavernosal bodies demonstrating hypoxic, acidotic blood. Initial management can include sys-temic treatment of the underlying disorder (fluid and oxygen for sickle cell patients) but this should be done concurrently with an active treatment to reduce the priapism.82 The initial intervention may be therapeutic aspiration or injection of sym-pathomimetics (phenylephrine). Insertion of a large-gauge needle (16–21 gauge) into the lateral aspect of one corporal body allows thorough aspiration and irrigation of both corporal bod-ies because of widely communicating intercavernosal channels. Injection of phenylephrine (diluted 100–500 mcg/mL and given in 1 mL increments every 3–5 minutes for up to 1 hour before determining failure) into the corporal bodies works to cause vasoconstriction, but the patient should be monitored for acute hypertension and reflex bradycardia especially in patients with high cardiovascular risk.A surgical shunt is sometimes necessary to resolve the episode if phenylephrine fails. Distal (corporoglanular) shunts should be performed first because they are the easiest to perform and the lowest amount of complications. A Winter shunt uses a large biopsy needle to create holes between the glans and cor-pora; however, if this fails, an operative procedure can be per-formed to remove the distal tips from each corpora (Al-Ghorab). Proximal shunts such as Grayhack (corporal-saphenous vein) or Quackel (proximal cavernosumspongiosum) shunts may be required in refractory cases.The other form of priapism (high-flow/traumatic priapism) is rare and is related to penile or perineal trauma resulting in a cavernous artery–corporal body fistula. This form is not painful because it is not related to ischemia and can be managed con-servatively with observation. Many cases will resolve with time; those that do not can undergo selective arterial embolization.82ParaphimosisParaphimosis is a common problem that represents a true medi-cal emergency for uncircumcised men. When the foreskin is retracted for prolonged periods, constriction of the glans penis may ensue. This is particularly likely in hospitalized patients who are confined to bed or who have altered mental status and are unable to respond to pain. Delay can be catastrophic as penile necrosis may occur due to ischemia. Penile blocks, pain medication, and sedation are sometimes necessary before manual reduction. It is useful to apply firm pressure to the edematous distal penis for several minutes.85 Although painful, this reduction in penile edema can be the key to success. With the fingers pulling the constricting band distally, the thumbs can push the glans penis back into normal location. Compres-sion wraps have shown some benefit without the need for the physician to use hand compression.86 If the foreskin cannot be manually reduced, surgical intervention is required.Emphysematous PyelonephritisEmphysematous pyelonephritis is a life-threatening infection that results from complicated pyelonephritis by gas-producing organisms. It is an acute necrotizing infection of the kidney that occurs predominantly in diabetic patients.87 Patients frequently present with sepsis and ketoacidosis. Escherichia coli appears to be the most frequent organism responsible for this infection. Patients require supportive care, IV antibiotics, and relief of any urinary tract obstruction. Third-generation cephalosporins have been suggested as the initial antibiotic of choice and fluoroqui-nolones avoided due to high rates of resistance.88 Emphysema-tous pyelonephritis can be subdivided based on the extent of infection. Cases where gas is isolated to the kidney frequently can be managed conservatively with the placement of a neph-rostomy tube to allow drainage of purulent material. When there is extensive involvement of the perirenal tissue, conservative management may not be successful and strong consideration should be given to nephrectomy, particularly if the patient is displaying signs of sepsis.89,90UROLOGIC MALIGNANCIESBladder CancerEpidemiology and Presentation. In 2018, 81,190 men and women will be diagnosed with bladder cancer, and 17, 240 will die from their disease.91 The disease is highly prevalent, with over 700,000 patients living with the disease in the United States as of 2016. Men have nearly three times the incidence of women. Tobacco use is the most frequent risk factor, followed by occupational exposure to various carcinogenic materials such as industrial solvents (e.g., aromatic amines). Other risk fac-tors include arsenic, radiation, cyclophosphamide, and chronic exposure to foreign bodies (stones and catheters) and specific urinary parasites. The most common bladder cancer histology in the United States is urothelial carcinoma (UC), accounting for 90% of tumors, which tends towards a better prognosis as compared to the rarer forms, including squamous cell carcinoma (<10%), adenocarcinoma (1–2%), and small cell cancer (<1%). Unfortunately, there is no reliable screening test for bladder cancer, although patients felt to be at high risk may undergo urine sampling for microhematuria or abnormal cytology. Smoking cessation should be advised in all tobacco users as a preventive measure. The most common symptoms at presentation are hema-turia (gross or microscopic) and/or irritable voiding (urgency, frequency, and dysuria). Office cystoscopy is an effective means to diagnose bladder cancer.Staging. Clinical staging is completed with CT or MRI to assess intraabdominal nodal and visceral sites of metastasis. The upper tracts should be evaluated with CT urography or retro-grade pyelography. Chest radiograph provides initial evaluation of the thorax and mediastinum. A bone scan should be obtained if the patient complains of bone pain, has known locally advanced or metastatic disease, or an unexplained elevation in the serum alkaline phosphatase level. Pathologic staging has been outlined by the American Joint Committee on Cancer.92Transurethral resection of bladder tumor (TURBT) should include an examination under anesthesia (EUA) and sampling of the bladder muscular wall to fully assess depth of invasion. The presence of induration or a mass on EUA denotes extravesical Brunicardi_Ch40_p1759-p1782.indd 177001/03/19 6:35 PM 1771UROLOGYCHAPTER 40tumor extension and may alter the patient’s treatment plan. It may also be appropriate to biopsy multiple areas of mucosa to identify multifocal carcinoma in situ (CIS). Restaging TURBT within 2 to 6 weeks is recommended in the patient with incom-plete, under-sampled, or uncertain resection. This is especially important in the patient with Tis, Ta, or T1 disease, as well as the patient with suspected T2 disease who is being considered for a bladder preservation treatment strategy. Invasion into the lamina propria and certainly the muscular wall demonstrates increased potential for distant metastases; muscle invasion is rarely treated completely with TURBT and requires additional therapy for adequate local control.Recurrence rates of non–muscle-invasive bladder can-cers are high, ranging from 50% to 70%.93 Adjuvant treatment strategies have thus been adopted after TURBT to reduce these rates. Intravesical chemotherapy used in conjunction with TURBT can reduce the risk of recurrence by 44% to 73% in patients with primary Ta and T1 tumors and by 38% to 65% in patients with recurrent Ta, T1, and Tis tumors when compared to TURBT alone.94 Intravesical immunotherapy using bacil-lus Calmette-Guérin (BCG) also provides a significant reduc-tion in recurrence that is greater than 50% in this population. Despite improved rates of disease-free survival, standard induc-tion courses of intravesical chemotherapy and immunotherapy do not improve disease-specific survival.94 However, when an induction course of BCG is followed by a series of maintenance doses consisting of weekly BCG given for 3 weeks at 3, 6, 12, 18, 24, 30, and 36 months after induction, disease-free and over-all survival can be prolonged.95 In patients who fail an initial or maintenance course of intravesical therapy, it may be rea-sonable to try another agent; however, one must consider the risk of progression and not delay definitive treatment. Roughly 15% to 30% of patients presenting with non–muscle-invasive tumors will eventually progress to muscle invasion. Radical cys-tectomy remains the most effective single-modality treatment for patients with muscle-invasive bladder cancer, refractory high-risk non–muscle-invasive disease, and especially lymph node–negative disease with a reported 10-year recurrence-free survival of organ-confined lymph node–negative (<pT2N0) dis-ease between 69% and 87%.94,96,97Surgical Considerations. Cystectomy is indicated in the treat-ment of refractory NMIBC or to assert local control for muscle invasive bladder cancer (MIBC).98 Effective local control in the pelvis is achieved in 93% of cases with cystectomy. Indica-tions for partial cystectomy are limited and generally apply to isolated tumors or those within diverticulum. Classic teaching suggests that patients with CIS should not be candidates, though the use of intravesical BCG to treat CIS may have broadened this application. For patients with MIBC, neoadjuvant systemic chemotherapy with M-VAC or gemcitabine and cisplatin (prior to cystectomy) offers a survival advantage when compared to radical cystectomy alone.98Robotic approaches for cystectomy are increasingly used, but the urinary diversion is still usually performed through an open incision. The benefits of the robotic portion are decreased blood loss during the pelvic dissection (due to the pneumoperi-toneum). However, recent evidence (randomized controlled trials of open vs. robot-assisted radical cystectomy) did not demonstrate any difference in oncologic efficacy or complica-tion rates.Complications of bladder cancer surgery involve bladder perforation during transurethral resection of the bladder tumor, which require catheter drainage for several days if small (com-mon) or open repair if large and intraperitoneal (rare). Cys-tectomy and urinary diversion may result in prolonged ileus, bowel obstruction, intestinal anastomotic leak, urine leak, or rectal injury. A urine leak from the ureteroileal anastomoses is a common cause of ileus, intra-abdominal urinoma, abscess formation, and wound dehiscence. Deep venous thrombosis is common after cystectomy due to the advanced age of most patients, proximity of the iliac veins to the resection and lymph node dissection, and the presence of malignancy. The utility of subcutaneous heparin in the perioperative period can minimize the risk of venous thromboembolism. Contemporary series from high volume centers report readmission rates of 25%, complica-tion rates of 50% to 60%, and perioperative mortality in the first 90 days at 5% to 10%.99,100Urinary diversion can be accomplished using an incon-tinent or continent abdominal stoma or orthotopic continent reconstruction. The evolution of patient selection and surgical technique has led to improved outcomes for orthotopic diver-sion, although there are still patients who are better served with an ileal conduit. Motivated patients are considered for ortho-topic neobladder diversion if they have a preoperative serum creatinine less than 2.0 mg/mL, normal preoperative bowel function, a negative urethral margin based on intraoperative frozen section at the time of cystectomy, and an intact sphincter after complete tumor resection.Alternatives to cystectomy include observation, systemic chemotherapy, radiation therapy, or a combination of chemo-therapy and radiation. These modalities may be required in patients who are a poor surgical risk, who refuse surgery, or who are elderly.Bladder preservation using radiation as the definitive ther-apy may be feasible in selected patients. In this context, trimo-dality therapy is preceded by aggressive TURBT and offers an improved rate of survival when performed in conjunction with chemotherapy. Up to 42% 5-year disease-specific survival can be achieved in patients with preserved bladders, with the best overall survival outcome in younger patients with lower stage tumors without lymphovascular or nodal involvement.More recently, immunotherapeutic treatments have shown significant promise in the treatment of locally advanced and metastatic bladder cancer. Five agents have recently been approved for patients who have progressed on or after platinum-based chemotherapy or have progressed within 12 months of neoadjuvant or adjuvant treatment. These agents include PD-L1 inhibitors (atezolizumab, avelumab, durvalumab) and PD-1 inhibitors (nivolumab and pembrolizumab). Response rates for these agents are ∼15% to 20% but may have extended median overall survival as much as 10.3 months when compared to chemotherapy.101,102Testicular CancerTesticular cancer is the most common cancer in men age 20 to 40 years and the second most common cancer in young men age 15 to 19 years. Metastases to the testis (usually lymphoma in older men) are rare. In 2018 there were 9310 new cases and 400 deaths from the disease.91 The incidence of testis cancer varies around the world.103 It contains a heterogeneous group of tumors, of which 95% are germ cell tumors; the rest originate from stromal cells (Leydig or Sertoli cells). Germ cell tumors can be classified as either seminomatous or nonseminomatous. Seminoma constitutes more than 50% of all testis cancer. The Brunicardi_Ch40_p1759-p1782.indd 177101/03/19 6:35 PM 1772SPECIFIC CONSIDERATIONSPART IIFigure 40-8. Scrotal ultrasound of the right testis. A heteroge-neous echoic mass is seen.incidence of bilateral GCT is approximately 2.5%.104,105 There are four established risk factors for testis cancer: cryptorchidism, family history of testis cancer, a personal history of testis can-cer, and intratubular germ cell neoplasia. Most patients present with testicular pain or a testicular mass. Respiratory symptoms, back pain, weight loss, or gynecomastia may indicate metastatic disease (10–20%). A testicular mass is considered malignant till proven otherwise. Similarly, retroperitoneal lymphadenopathy in young men should be considered metastatic testicular cancer.Standard initial workup includes scrotal ultrasound (Fig. 40-8) and serum tumor markers (α-fetoprotein, quanti-tative human chorionic gonadotropin, and lactate dehydroge-nase). Most consider percutaneous biopsy contraindicated due to the rare but historical risk of disturbing the natural lymphatic drainage to the retroperitoneum and possible seeding of the scrotum.106 Radical inguinal orchiectomy is the gold standard treatment for excision of the primary tumor. Partial orchiec-tomy through an inguinal approach may be considered in some cases, including a suspected diagnosis of lymphoma. Chest and abdominal axial imaging are the main staging tools. Testicular cancer has a very predictable pattern of spread. Right testicular cancer tends to metastasize to the interaortocaval lymph node, followed by paracaval and paraaortic lymph nodes. Left-sided testicular cancer rarely crosses to the paracaval lymph nodes.107 Clinical TNM staging includes local stage, distant metastasis, and tumor markers.Depending on the stage and histology of the primary tumor, multiple treatment options are available. These include active surveillance, retroperitoneal lymph node dissection (RPLND), and adjuvant chemotherapy or radiation therapy. Active surveillance for localized disease follows a tight sched-ule of physical exams, tumor markers and imaging studies. The cancer recurs in 20% to 30% of patients on active surveillance. The presence of embryonal carcinoma and vascular invasion seem to be interrelated predictors of recurrence.108 Recurrence usually occurs within the first 2 years and in the retroperito-neum.109 Pure seminoma is radiosensitive; stages I, IIa, and IIb disease can be treated with external-beam radiation to the retro-peritoneal nodes. Alternatively, a single dose of carboplatin for stage I seminoma was found to be just as effective as radiation therapy.110 More advanced seminoma is treated with platinum-based systemic chemotherapy.Stages I to IIA nonseminomatous testis cancer is poten-tially cured with RPLND or chemotherapy.111 Persistently high tumor markers after radical orchiectomy or high-stage meta-static germ cell tumors warrant systemic chemotherapy. Due to the high rates of teratoma or viable germ cell tumor, postchemo-therapy bulky masses are resected by RPLND or other surgi-cal procedures. The overall survival rate of localized disease is outstanding (99% at 5 years). Patients with more advanced distant metastatic disease (stage III) have 75% survival rates. The overall prognosis is generally better for seminomatous than nonseminomatous germ cell tumors.112Surgical Considerations. Radical orchiectomy is done through an inguinal incision extending from the external inguinal ring to the internal inguinal ring. The spermatic cord is ligated at the internal ring with long silk sutures for easier identification during a future RPLND. Integrity of the scrotal skin during orchiectomy is important. Complications of radi-cal orchiectomy include scrotal hematoma, chronic pain, and hernia.For RPLND, a midline incision is usually made from the xiphoid process to the pubic symphysis. All the lymphatic tissue is removed from the targeted areas using the classical split and roll technique, and all lumbar vessels are tied. Postganglionic sympathetic nerve sparing is possible in most cases for pres-ervation of ejaculatory function.113 Robotic-assisted RPLND is growing, with faster recovery time and similar short term oncologic results.114 Complications after RPLND include bowel obstruction, excessive bleeding, chylous ascites, and ejaculatory dysfunction.Kidney CancerRenal cell carcinoma (RCC) results in approximately 3.8% of all new cancers, with an estimated 65,340 new cases and 14,970 deaths related to kidney cancer in 2018.91 Despite several advancements with immune-based and targeted molecular ther-apies demonstrating durable clinic responses, RCC still remains primarily a surgical disease and classically does not respond to conventional chemotherapy regimens or radiation therapy.Most patients diagnosed with RCC in the modern era typically present with an incidentally discovered renal mass on abdominal radiographic imaging. Differential diagnosis of a renal mass includes malignant tumors (e.g., RCC, urothelial carcinoma, sarcomas, lymphoma, metastasis), benign tumors (e.g., cysts, angiomyolipoma, oncocytoma), and inflammatory lesions (e.g. abscesses, xanthogranulomatous pyelonephritis, tuberculosis). Renal CT imaging with intravenous contrast remains the single most important radiographic test to delineate the nature of the mass. In general, any solid renal mass that enhances by more than 15 Hounsfield units is an RCC until proven otherwise. However, even if there is contrast enhance-ment on axial imaging, approximately 15% to 30% of solid renal masses are benign on final surgical pathology.115 Renal tumor biopsy can help distinguish between malignant or benign tumors, but this has not been widely adopted by the urological community, despite series showing their high diagnostic yield, concordance with surgical pathology, and safety.116-118 Biopsy remains particularly useful in patients considering surveillance or thermoablative therapy, or in patients with suspicion of metastasis or lymphoma.Major recognized risk factors for RCC include smoking, obesity, and hypertension. Although most RCCs are discovered incidentally, some patients present with signs or symptoms Brunicardi_Ch40_p1759-p1782.indd 177201/03/19 6:35 PM 1773UROLOGYCHAPTER 40which may be the result of local tumor growth (e.g., flank pain, hematuria, perirenal hematoma), paraneoplastic syndromes (e.g., hypertension, weight loss, hypercalcemia, polycythemia/anemia, abnormal liver function tests), or metastatic disease. RCC metastasizes primarily to the lungs, lymph nodes, bone, liver, adrenal glands, and brain. Familial RCC subtypes with classical clinical manifestations are also well described. The von Hippel-Lindau disease, occurring as a result of a mutation in the tumor suppressor gene VHL (3p25-26), commonly mani-fests itself with clear cell RCC, pheochromocytomas, retinal angiomas, central nervous system hemangioblastomas, pancre-atic cysts, and other tumors. Other familial syndromes include hereditary papillary RCC (papillary type 1 RCC), familial leiomyomatosis (papillary type 2 RCC), and Birt-Hogg-Dube syndrome (chromophobe RCC, hybrid oncocytic tumors, and oncocytoma). Familial RCC syndromes should be suspected in younger patients and patients with multicentric and/or bilateral tumors.Clear cell RCC is the most common subtype, accounting for 70% to 80% of all RCCs. Papillary RCC occurs in 10% to 15%, type 1 being associated with a better prognosis, and type 2 a worse prognosis. Other subtypes include chromophobe RCC, collecting duct carcinoma, and unclassified type.RCC may locally progress and cause invasion of the renal capsule and perirenal fat or the collecting system. RCC may also directly progress into the venous system in the form of a tumor thrombus that can extend into the IVC and into the right atrium. Staging is the single most important prognostic factor for RCC.119,120 Studies demonstrate a 70% to 90% 5-year survival rate for organ confined disease (stages I–II), compared to 0% to 10% for patients with systemic metastases (stage IV).119 Other important prognostic factors include histological subtype,121 tumor size, lymph node involvement, and site of metastases.122Management options for small renal masses (<4 cm) includes active surveillance, thermoablative techniques, or sur-gical excision (Fig. 40-9). Percutaneous or laparoscopic ther-moablative techniques (cryoablation, radiofrequency ablation, high-intensity focused ultrasound) have been used to treat small renal masses, but they are associated with an increased risk of local recurrence.123,124Since the first laparoscopic radical nephrectomy described by Clayman et al in 1991,125 minimally invasive Figure 40-9. Computed tomography scan of the abdomen with intravenous and oral contrast. A small mid right posterior mass is seen.Figure 40-10. Intraoperative image of a small renal mass in prepa-ration for partial nephrectomy.surgical approaches, including laparoscopy with robotic assis-tance, have virtually supplanted open procedures for localized RCC (Fig. 40-10). Partial nephrectomy is most appropriate for patients with small tumors, solitary kidney, bilateral tumors, or familial RCC. Some tumors may not be amenable to abla-tive therapies or partial nephrectomy, in which case radical nephrectomy would be employed.126Radical nephrectomy involves removal of the entire kidney with dissection external to Gerota’s fascia. The colon is retracted medially after incising the white line of Toldt, fol-lowed by meticulous hilar dissection with ligation of the renal artery and vein. The adrenal gland is usually spared unless the tumor involves the gland or is immediately adjacent to it. Lymphadenectomy remains controversial, and it is usually per-formed in patients with adenopathy on preoperative imaging or in patients with palpable lymph nodes intraoperatively. In partial nephrectomy, renal artery clamping is often performed to minimize blood loss while the tumor is excised. The goal is to remove the tumor with negative surgical margins while minimizing warm ischemia time to preserve as many func-tional nephrons as possible. With increasing experience, partial nephrectomy is now also performed on much more complex renal masses, including completely endophytic, central, and hilar tumors. Very large tumors or tumors with vena-caval thrombi can be removed robotically in experienced hands,127,128 but most are still removed using an open approach.In minimally invasive surgery, both partial and radical nephrectomy can be done via either a transperitoneal or retro-peritoneal approach. In open cases, a subcostal flank approach provides direct access to the retroperitoneum and is preferred for lower pole exposure, but it can limit access to the hilum, particularly with large renal masses. The anterior subcostal approach is preferred for larger renal masses. Bilateral ante-rior subcostal incisions (chevron incision) provides excellent vascular exposure (e.g., IVC thrombectomy, bilateral tumors). Midline incisions are usually reserved for renal trauma and for reconstructive procedures. Less commonly performed, the thoracoabdominal approach involves access usually above the 10th rib and is used for large upper pole or adrenal masses, IVC thrombectomy, or tumors involving adjacent structures. Complications include injury to adjacent organs, and for partial nephrectomy, pseudoaneurysms/arteriovenous fistula formation and delayed urinary leak.Brunicardi_Ch40_p1759-p1782.indd 177301/03/19 6:35 PM 1774SPECIFIC CONSIDERATIONSPART IIProstate CancerProstate cancer is the most common noncutaneous cancer in men; 164,690 new cases of prostate cancer were diagnosed in 2018 and 29,430 men died from their disease.91 Screening for prostate cancer with detailed history, digital rectal examination, and serum prostate specific antigen (PSA) tests have changed the natural history of the disease. Since the introduction of pros-tate cancer screening in the mid-1980s, the incidence of meta-static prostate cancer has decreased by half. Currently 99% of newly diagnosed patients will survive more than 10 years.91While early screening for African American patients or patients with a family history of prostate cancer is widely accepted, screening for all men is more controversial. Despite data from large randomized clinical trials showing a decrease in mortality after prostate cancer screening, the U.S. Preventive Services Task Force recommended against the routine use of prostate cancer screening.129 Its recommendation was based on the harm and toxicity of overtreatment of nonlethal disease.130 The American Urologic Association subsequently recom-mended informed and shared decision-making and screening for high-risk disease for men between the ages of 55 and 69 with a life expectancy more than 10 years.131If the digital rectal examination is abnormal or if the PSA level is above expected for patients’ age and size of the prostate, a prostate biopsy is usually performed. Newer tests such as the 4K score, prostate health index, and PCA3 are sometimes used to inform the decision to proceed with biopsy. Recently, MRI fusion transrectal ultrasound-guided biopsy improved the accu-racy of prostate biopsy.Since most patients survive the disease, risk stratification systems are routinely utilized to guide staging and treatment. Clinical TNM stage, serum PSA levels, and the Gleason grading system are utilized in clinical practice. More recently, genetic testing on biopsy specimen was included in national guidelines. Historically, the Gleason scoring (GS) system included a pri-mary and secondary score based on the most common and sec-ond most common histologic patterns. Grades range from 1 for the most differentiated to 5 for the least. The grades are added to create a resultant Gleason score.132 However, since no patients are assigned a score of less than 5 anymore, the grading system has been modified to a scale from 1 to 5. Grade one includes a GS of 3 + 3 = 6 or less, grade 2 for GS 3 + 4, grade 3 for GS 4 + 3, grade 4 for GS 4 + 4 and grade 5 for Gleason score of 9 or 10.133 Imaging studies like CT and bone scans are used to rule out metastatic disease in high-risk patients. The two most common sites of metastatic disease are pelvic/retroperitoneal lymph nodes and boney structures. Modern CT PET scans have a limited role at this point.Treatment for localized prostate cancer is guided by can-cer aggressiveness and patient’s preferences. Active sur-veillance is recommended for patients with low-risk disease grade 1–2, early-stage disease (cT1c), and small volume disease as determined by biopsy. Large prospective cohorts and randomized clinical trials have established the safety of this approach.134,135 The risk of progression to metastatic disease with close follow-up and repeat prostate biopsies is less than 2% in over 12 years. Radical prostatectomy and pelvic lymph node dissection (robotic, laparoscopic, or open), image modulated radiation therapy (IMRT), and brachytherapy are the standard of care for curative treatments. All provide equal cancer specific survival for low and intermediate risk cancers. For higher risk prostate cancer patients, both surgery and IMRT with androgen 8Figure 40-11. The da Vinci Surgical System used commonly for radical prostatectomy.deprivation therapy provide excellent cancer control. Cryother-apy, or high intensity focused ultrasound (HIFU) and focal therapy are emerging options that may be acceptable for some patients with low-risk disease.Level I evidence has established the role of adjuvant radia-tion therapy after radical prostatectomy for patients with posi-tive surgical margins, extracapsular extension, and high-grade disease.136,137 After definitive treatment of localized prostate cancer, rising PSA is an extremely reliable indicator of recur-rence or progression. However, it may take over 10 years for metastasis to appear on imaging studies.138 Once prostate cancer metastasizes, it is no longer curable. Medications that lower serum testosterone or androgen receptor blockers are able to control the disease, often for years. In addition, chemotherapy, immunotherapy, and radioisotope therapy at different stages of the disease increase the life expectancy of the patients or improve the quality of life. The cancer inevitably becomes resis-tant to these treatments. Nevertheless, patients with incurable prostate cancer can live many years, and a large number die of causes other than prostate cancer.Over the past few years, we have witnessed major devel-opments in the management of metastatic castrate resistant prostate cancer (mCRPC). New agents that interrupt androgen synthesis (e.g., abiraterone acetate)139,140 and new modulators of androgen receptors (e.g., enzalutamide)141,142 have significantly improved the life expectancy of patients with both androgen sensitive and resistant metastatic prostate cancer. Similarly, innovations in immunotherapy and chemotherapy delivery have advanced the management of advanced prostate cancer.Surgical Considerations. Open radical retropubic prostatec-tomy is done through a lower midline incision from below the umbilicus to the pubic symphysis. After entering the space of Retzius, the external iliac, obturator, and internal iliac lymph nodes are removed. The cavernosal nerves located on the pos-terolateral surface of the prostate capsule are usually spared on the side(s) with low risk of extracapsular extension of the dis-ease. Then the prostate is removed in a retrograde fashion, and the urethrovesical anastomosis is completed in an interrupted fashion.Robotic radical prostatectomy using the da Vinci robotic surgical system (Fig. 40-11) is now the most common tech-nique (over 90% of all patients in the United States) for the Brunicardi_Ch40_p1759-p1782.indd 177401/03/19 6:35 PM 1775UROLOGYCHAPTER 40surgical treatment of localized prostate cancer. Robotic surgery has lower blood loss and faster convalescence, less bladder neck contracture, and lower early postoperative complications. Some data show a faster return of continence and lower rates of erectile dysfunction. The most common postoperative compli-cations include infection, urine leaks, ileus, lymphocele, and, very rarely, rectal or ureteral injury.To minimize the impact of these side effects, researchers have used different ablative techniques to obliterate the areas of significant cancer. By avoiding the need for whole gland radia-tion or removal, these focal ablative therapies aim to balance the long-term impact on quality of life with survival. Laser, high-focused ultrasound, cryotherapy, and photodynamic ablations have showed similar results in early studies.Urethral CancerUrethral carcinoma (UC) is a rare disease, the true incidence of which is unknown. It accounts for less than 1% of genito-urinary cancers.143,144 It is a disease of the older adult. Risk fac-tors include chronic inflammation from sexually transmitted diseases (human papillomavirus 16 and 18 in squamous cell carcinoma),145 chronic urethral stricture, and indwelling cath-eterization. Furthermore, urethral diverticulum and recurrent urinary tract infections increase the risk for women.The majority of patients present with irritative and obstructive voiding symptoms, bleeding, or a palpable mass. Urothelial carcinoma is the most common histology; 29% of women have adenocarcinoma, and both genders can have squamous cell carcinoma. Untreated or refractory UC typically metastasizes through lymphatic channels to the inguinal and pelvic lymph nodes and hematologically to distant organs. Cys-toscopic biopsy establishes the diagnoses. An MRI of the pelvis is extremely helpful for defining local extension of the disease while CT scans of the chest, abdomen, and pelvis identify meta-static disease. Finally, it is also important to evaluate the entire urinary tract.The 5-year overall survival rates for distal urethral tumors is significantly better than for proximal cancers, 68% versus 40%, respectively.143,146 The median 5-year cancer-specific sur-vival is approximately 46%.144 Prognosis is dictated by patients’ age, race, clinical stage, and location of the tumor.If feasible, local endoscopic resection for low-volume, low-stage disease is preferable. Adjuvant intravesical instilla-tion of Bacillus Calmette-Guérin (BCG) should be considered for patients with proximal noninvasive disease.147 Due to the paucity of robust data, management of locally advanced dis-ease is more challenging. Either radical cystectomy or radiations are acceptable options. Unfortunately, local recurrence rates are high after aggressive monotherapy (63%).148 More recent data support the use of multimodal therapy.149,150 Small series of combinations of perioperative chemotherapy, surgery, and radiation indicate the best cancer control.151COMMON UROLOGIC CONDITIONSUrinary Incontinence and Voiding DysfunctionUrinary incontinence is defined as the involuntary loss of urine. This is more common in women than men for a variety of rea-sons, including anatomic differences such as a shorter urethra and risk factors such as childbirth. Many patients may also suf-fer from bothersome symptoms without leakage of urine such as overactive bladder (frequency and urgency of urination and often nocturia), or obstructive symptoms such as hesitancy, weak stream, and incomplete bladder emptying. These condi-tions can have a negative impact on quality of life,152-154 but they are also associated with serious health issues, including depres-sion, anxiety, social isolation,155 and even falls and fractures in the elderly.156Urinary incontinence can be divided into several catego-ries, although patients (particularly women) may suffer from more than one type.157 Urge incontinence is the involuntary loss of urine associated with an urge to void. Stress leakage occurs with increases in intra-abdominal pressure, such as coughing or sneezing, and may relate to loss of sphincteric function, urethral hypermobility from pelvic floor laxity (often related to parity), or following prostate surgery in men. Overflow incontinence occurs in the setting of obstruction, with urine leakage occurring with movement causing over-flow of urine from a distended bladder. Genitourinary fistulas typically result in the most severe form of incontinence with constant leakage of urine regardless of presence or absence of activity or movement. Examples include vesicovaginal or ureterovaginal fistulae most often due to gynecologic surgery, or rectourethral fistulae in men from cancer, radiation, or sur-gical intervention.Treatments for urinary incontinence and voiding dysfunc-tion are varied depending on the etiology, severity, and bother of the symptom. Urge leakage and overactive blad-der can be treated by (a) behavioral modification (timed void-ing, adjustment to fluid intake, timing of diuretic medication, and improved constipation); (b) bladder retraining (pelvic floor physical therapy158); (c) medications (anticholinergics159 and β-3 agonists160); or (d) minimally invasive procedures (sacral neuro-modulation,161 percutaneous tibial nerve stimulation,162 or blad-der chemodenervation with detrusor botulinum toxin injection163).Stress incontinence in women can be addressed by pelvic floor strengthening exercises, vaginally placed removable sup-port with a pessary, injection of urethral bulking agent, or sling procedures using polypropylene mesh or autologous tissue. In men, stress leakage is due to either iatrogenic causes or neuro-logic disease. Treatments include strengthening exercises as in women, slings, or implantation of an artificial urinary sphincter. Overflow incontinence treatment is directed at the cause of obstruction, often benign prostatic enlargement in men, with bladder drainage, medications such as α-blockers or 5-α reduc-tase inhibitors, or surgical removal of the obstructing gland. When fistulas are present, adherence to surgical principles such as tension-free multilayer closure, nonoverlapping suture lines, and tissue interposition when possible offers the highest likeli-hood for success.Erectile DysfunctionErectile dysfunction (ED) is defined as the inability to achieve and maintain an erection adequate for sexual intercourse. For-merly, this was known as a type of sexual dysfunction, but it is now understood that ED may be an early symptom of cardiovas-cular disease due to endothelial dysfunction. ED is a common disease for men later in life with a prevalence rate believed to range anywhere from 30% to 50% depending on age. Two large population-based studies, the Massachusetts Male Aging Study (MMAS) and the European Male Aging Study (EMAS), exam-ined men age 40 to 79 years and found that ED rates increased with age.164,1659Brunicardi_Ch40_p1759-p1782.indd 177501/03/19 6:35 PM 1776SPECIFIC CONSIDERATIONSPART IIErections are triggered via sexual stimulation setting off a cascade of events. Nitric oxide is released from nerve fibers and activating guanylyl cyclase leading to an increase in cyclic guanosine monophosphate (cGMP). The cGMP pathway leads to smooth muscle relaxation within the corpora cavernosa allow-ing blood to fill the lacunar spaces. Once the lacunar spaces are full, the expanded tissue compresses the subtunical venules thereby trapping blood within the penis and blocking venous out-flow. Phosphodiesterase type-5 hydrolyzes cGMP to reverse the process.166There are multiple mechanisms leading to ED including vasculogenic, neurogenic, iatrogenic, and psychologic, but often it is multifactorial. Vasculogenic ED can be a result of cardiovascular disease and endothelial dysfunction leading to cavernosal artery insufficiency. Diseases such as hypertension (odds ratio [OR] 1.35–3.04), diabetes (OR 2.57), dyslipidemia (OR 1.83), and tobacco abuse (OR 1.4) all may increase the risk for ED.167 Nerve injuries due to diseases (diabetes, Parkin-son’s, multiple sclerosis, spinal cord injury) or surgery (radical prostatectomy, abdominoperineal resection, and other radical pelvic procedures) can lead to interruptions in the nerve signal-ing that causes nitric oxide release and therefore lead to ED. Iatrogenic causes may be a result of surgery (described earlier) or medication use, as in some antihypertensives, opiates, anti-androgens, and psychotherapeutics.168 Psychogenic ED, a com-mon reaction to stress and anxiety, is a result of noradrenaline release causing smooth muscle contraction and thereby inhibit-ing erections.169Treatment for ED begins with lifestyle modification by identifying any reversible risk factors such as stress/anxiety, medications, unhealthy diets, lack of exercise, and tobacco abuse.170 Medical therapy then begins with the use of phospho-diesterase type-5 inhibitors (PDE5i). These work by prolonging the activity of cGMP, leading to continued smooth muscle relax-ation allowing more blood inflow into the penis. Common drugs include sildenafil, tadalafil, vardenafil, and avanafil. They differ in time to peak concentration (lowest in avanafil, sildenafil, and vardenafil), half-life (highest in tadalafil), and the impact of lip-ids in foods (sildenafil and vardenafil must be taken on an empty stomach). Common side effects include a headache, heartburn, facial flushing, nasal congestion, and myalgias.171 Patients on nitrate-containing medications should not be given PDE5i due to the risk of severe hypotension. Vision related conditions like macular degeneration, retinitis pigmentosa, and nonarter-itic anterior ischemic optic neuropathy are cause for increased awareness and possible ophthalmologic consult.172Second-line options for ED include vacuum erection devices (VED), intracavernosal injections (ICI), and intraure-thral suppositories. The VED is a mechanical device composed of a cylinder placed around the penis which then uses a vacuum to create negative pressure and pull blood into the penis. In order for blood to stay in the penis after the vacuum is released, a tight constriction band must be placed at the base of the penis. There is poor compliance due to difficulty with use and the common reactions of petechia, temporary paresthesia, color changes, and the penis being cold to touch.173,174 Alternatively, ICI uses vasoactive substances (prostaglandin E1 [alprostadil], papaverine, and phentolamine) either alone or in combination to trigger the erection cascade.168 Patients are trained to give themselves a self-injection when they want an erection, and it takes approximately 5 to 15 minutes until they are fully rigid if they respond. With ICI, there is greater concern for prolonged Figure 40-12. A three-piece penile implant for the treatment of erectile dysfunction. The prosthesis is composed of two cylinders placed in the penis, a fluid reservoir placed in the pelvis (upper left), and a pump placed within the scrotum (bottom left).erection or priapism, so dose titration must be closely moni-tored. Intraurethral suppositories are composed of alprostadil in the form of a pellet which is then placed in the urethra and mas-saged for absorption. With suppository use, there are concerns about efficacy (only 46–65%) and compliance due to a burning sensation that limits the interest of some users.175,176Third-line treatment of ED is with surgery placement of a penile prosthesis. There are three main types (malleable, two-piece, and three-piece). The malleable device does not inflate/deflate and merely bends in and out of position for intercourse. The two-piece and three-piece devices are inflatable and dif-fer on the presence of a separate fluid reservoir. The two-piece device has the fluid maintained in the lower half of the penile cylinders, whereas, the three-piece device has a fluid reservoir placed in the pelvis or abdominal wall (Fig. 40-12). Overall, the inflatable prosthesis has high patient and partner satisfaction rates, >92% and >91%, respectively.177PEDIATRIC UROLOGYHypospadiasHypospadias, a condition which may be considered a form of incomplete maturation of the genitalia, is a common abnormal-ity that occurs in 1 out of 250 to 300 newborn boys. The most obvious aspect of hypospadias is a urethral opening that is not at the tip of the glans, and 70% to 80% of affected babies will have a meatus on the mid to distal shaft or proximal glans. A lesser number will have more proximal openings, whether penoscrotal, scrotal, or perineal. In addition to an abnormally located meatus, boys usually have deficient ventral foreskin. Associated penile Brunicardi_Ch40_p1759-p1782.indd 177601/03/19 6:35 PM 1777UROLOGYCHAPTER 40curvature, more common in the severe varieties, is referred to as chordee.No diagnostic studies are needed for the majority of boys with hypospadias as there is typically no increased risk of renal or bladder anomalies. Children with associated cryptorchidism, especially with proximal hypospadias and a nonpalpable tes-tis, have an increased risk of a having a coexisting disorder of sexual differentiation (DSD) and need to undergo a thorough evaluation including hormonal studies, karyotype, and pelvic ultrasonography.178Distal hypospadias can usually be repaired in one stage with success rates of greater than 95%. Most would advocate a staged approach to proximal hypospadias with correction of penile curvature at the first stage and formal urethral reconstruc-tion at the second.179 Adults with corrected hypospadias usually have normal sexual function and fertility.Urinary Tract Infections in ChildrenUrinary tract infections (UTI) are common in children, and there is a greater chance of underlying anatomic abnormalities. Children may have conditions such as vesicoureteral reflux, ureteropelvic junction obstruction, ureteroceles, or ectopic ure-ters as causes of these infections. Because of this association, in the past all children with febrile infections would undergo complete evaluations including renal ultrasonography (US) as well as invasive studies such as voiding cystourethrogra-phy (VCUG). However, defining pyelonephritis as having a positive renal cortical scan, only 30% to 40% of children with febrile UTI will have reflux. Thus the majority of children with febrile infections, and a greater percentage of those with afe-brile infections (cystitis), will be anatomically normal.180 These data have led to a change in imaging guidelines for children with UTI.Guidelines put out by the American Academy of Pediat-rics have markedly changed the way children with infections are evaluated.181 These guidelines suggest that infants less than 2 months of age with febrile infections should undergo both a renal US and VCUG. Children between 2 months and 2 years who have their first documented infection only need have a renal ultrasound performed. A VCUG is only needed if there are abnormalities detected on the ultrasound such as hydrone-phrosis, scarring, or other evidence of anatomic abnormality. A VCUG may also be performed if a child has recurrent infections despite empirical treatment. These guidelines do not address children older than 2 years of age but one can assume that simi-lar algorithms of treatment would be appropriate.There is now greater understanding that most children with UTIs, whether pyelonephritis or cystitis, have some ele-ment of bladder and/or bowel dysfunction as the major factor in the development of the infection. Thus, all children with UTIs need to have a thorough assessment of daily bladder and bowel habits. The latter may be difficult to ascertain in younger children, but bowel dysfunction, even subclinical, may be the most important factor in the development of UTIs. Behavioral therapies such as regular and complete voiding in conjunction with a bowel program should be considered the mainstay of the prevention of infections as opposed to prophylactic antibiotics.Prenatal HydronephrosisAntenatal imaging will show hydronephrosis in nearly 1% of all babies. Though the majority of children will have benign hydro-nephrosis of no clinical significance, it may also be related to vesicoureteral reflux, ureteropelvic junction obstruction, ectopic ureter/ureteroceles, and other upper tract abnormalities. Typi-cally, nothing needs to be done for these children until after birth, at which point a baseline renal ultrasound can be per-formed. Other studies such as a VCUG or Lasix renal scans can then be done depending on the degree of dilation. Diagnosis of upper tract obstruction is usually based on progressive worsen-ing of dilation or renal function on serial examinations.Special consideration must be given for children with bilateral hydronephrosis or hydronephrosis associated with a solitary kidney, especially if linked to oligohydramnios. Since fetal urine production accounts for much of the amniotic fluid, low levels can be a sign of a severe abnormality of the urinary tract. Reduced amniotic fluid is of great consequence since nor-mal lung development is dependent on normal amniotic fluid volumes and children with oligohydramnios can be born with significant pulmonary insufficiency. Boys with bilateral hydro-nephrosis and low amniotic fluid are at high risk for having posterior urethral valves (PUV). Boys with PUV have as much as a 25% risk of developing end stage renal disease at some point in their lives.182 Prenatal intervention such as placement of vesicoamniotic shunts have not been shown to reduce the risk of renal failure.CryptorchidismCryptorchidism or undescended testes (UDT) is a common condition occurring in 3% of full term and 30% of premature babies. Many of these testes will descend spontaneously due to the normal gonadotropin release that occurs in the first few months of life, so the true incidence is roughly 1% of boys. Untreated cryptorchidism will lead to testis damage, and there is evidence that permanent changes may occur by 3 years of age. Ideally, surgical treatment should occur prior to this age. UDT is usually an isolated finding, but it may occur as a part of a systemic condition such as Prader-Willi, Eagle-Barrett, or other such complex multisystem syndrome. Surgery is the treatment of choice; hormonal treatment has no role.The consequences of untreated cryptorchidism include infertility and malignant degeneration. One study on fertility suggested that men with a history of unilateral cryptorchidism will have no difference in paternity rates compared to normal controls. In contrast, men with bilateral cryptorchidism have up to a 50% rate of infertility.183 There is data to suggest that orchidopexy in the first year of life is associated with better total sperm counts in adulthood.184 With regard to malignancy, untreated UDT has a fivefold increase risk of tumor develop-ment compared to the normal population. However, there is data to suggest that prepubertal orchidopexy is protective and that these boys only have a twofold greater risk.185REFERENCESEntries highlighted in bright blue are key references. 1. Schaeffer A, Matulewicz R, Klumpp D. Infections of the urinary tract. In: Wein AJ, Kavoussi LR, Partin AW, et al, eds. Campbell-Walsh Urology. 11th ed. Philadelphia: Elsevier; 2016. 2. Polackwich AS, Shoskes DA. Chronic prostatitis/chronic pel-vic pain syndrome: a review of evaluation and therapy. Pros-tate Cancer Prostatic Dis. 2016;19(2):132-138. 3. Link R, Rosen T. Cutaneous diseases of the external genitalia. In: Wein AJ KL, Partin AW, et al, ed. Campbell-Walsh Urology. 11 ed. Philadelphia, Penn: Elsevier; 2016.Brunicardi_Ch40_p1759-p1782.indd 177701/03/19 6:35 PM 1778SPECIFIC CONSIDERATIONSPART II 4. Scales CD, Smith AC, Hanley JM, Saigal CS, Project UDiA. Prevalence of kidney stones in the United States. Eur Urol. 2012;62(1):160-165. 5. Pearle MS, Calhoun EA, Curhan GC, Project UDoA. Uro-logic diseases in America project: urolithiasis. J Urol. 2005;173(3):848-857. 6. Scales CD, Curtis LH, Norris RD, et al. Changing gender prevalence of stone disease. J Urol. 2007;177(3):979-982. 7. Taylor EN, Stampfer MJ, Curhan GC. Diabetes mellitus and the risk of nephrolithiasis. Kidney Int. 2005;68(3):1230-1235. 8. Taylor EN, Stampfer MJ, Curhan GC. Obesity, weight gain, and the risk of kidney stones. JAMA. 2005;293(4):455-462. 9. Heilberg IP. Treatment of patients with uric acid stones. Urolithiasis. 2016;44(1):57-63. 10. Fulgham PF, Assimos DG, Pearle MS, Preminger GM. Clini-cal effectiveness protocols for imaging in the management of ureteral calculous disease: AUA technology assessment. J Urol. 2013;189(4):1203-1213. 11. Poletti PA, Platon A, Rutschmann OT, Schmidlin FR, Iselin CE, Becker CD. Low-dose versus standard-dose CT protocol in patients with clinically suspected renal colic. AJR Am J Roentgenol. 2007;188(4):927-933. 12. Pearle MS, Goldfarb DS, Assimos DG, et al. Medical management of kidney stones: AUA guideline. J Urol. 2014;192(2):316-324. 13. Hubner WA, Irby P, Stoller ML. Natural history and current concepts for the treatment of small ureteral calculi. Eur Urol. 1993;24(2):172-176. 14. Miller OF, Kane CJ. Time to stone passage for observed ureteral calculi: a guide for patient education. J Urol. 1999;162 (3 Pt 1):688-690; discussion 690-681. 15. Assimos D, Krambeck A, Miller NL, et al. Surgical management of stones: American Urological Associa-tion/Endourological Society guideline, PART I. J Urol. 2016;196(4):1153-1160. 16. Assimos D, Krambeck A, Miller NL, et al. Surgical management of stones: American Urological Associa-tion/Endourological Society guideline, PART II. J Urol. 2016;196(4):1161-1169. 17. Lu Z, Dong Z, Ding H, Wang H, Ma B, Wang Z. Tamsulosin for ureteral stones: a systematic review and meta-analysis of a randomized controlled trial. Urol Int. 2012;89(1):107-115. 18. Albala DM, Assimos DG, Clayman RV, et al. Lower pole I: a prospective randomized trial of extracorporeal shock wave lith-otripsy and percutaneous nephrostolithotomy for lower pole nephrolithiasis-initial results. J Urol. 2001;166(6):2072-2080. 19. Ozturk U, Sener NC, Goktug HN, Nalbant I, Gucuk A, Imamoglu MA. Comparison of percutaneous nephroli-thotomy, shock wave lithotripsy, and retrograde intrarenal surgery for lower pole renal calculi 10-20 mm. Urol Int. 2013;91(3):345-349. 20. Egan KB. The epidemiology of benign prostatic hyperplasia associated with lower urinary tract symptoms: prevalence and incident rates. Urol Clin North Am. 2016;43(3):289-297. 21. Barry MJ, Fowler FJ, O’Leary MP, et al. The American Urological Association symptom index for benign prostatic hyperplasia. The Measurement Committee of the American Urological Association. J Urol. 1992;148(5):1549-1557; discussion 1564. 22. O’Leary M. The importance of standardisation and validation of symptom scores and quality of life: the urologist’s point of view. Eur Urol. 1997;32(suppl 2):48-49. 23. McVary KT, Roehrborn CG, Avins AL, et al. Update on AUA guideline on the management of benign prostatic hyperplasia. J Urol. 2011;185(5):1793-1803. 24. Nickel JC, Herschorn S, Corcos J, et al. Canadian guidelines for the management of benign prostatic hyperplasia. Can J Urol. 2005;12(3):2677-2683. 25. Djavan B, Marberger M. A meta-analysis on the efficacy and tolerability of alpha1-adrenoceptor antagonists in patients with lower urinary tract symptoms suggestive of benign pros-tatic obstruction. Eur Urol. 1999;36(1):1-13. 26. Roehrborn CG, Boyle P, Nickel JC, Hoefner K, Andriole G, Investigators AAaAS. Efficacy and safety of a dual inhibitor of 5-alpha-reductase types 1 and 2 (dutasteride) in men with benign prostatic hyperplasia. Urology. 2002;60(3):434-441. 27. McConnell JD, Roehrborn CG, Bautista OM, et al. The long-term effect of doxazosin, finasteride, and combination therapy on the clinical progression of benign prostatic hyperplasia. N Engl J Med. 2003;349(25):2387-2398. 28. Roehrborn CG, Barkin J, Siami P, et al. Clinical outcomes after combined therapy with dutasteride plus tamsulo-sin or either monotherapy in men with benign prostatic hyperplasia (BPH) by baseline characteristics: 4-year results from the randomized, double-blind combination of Avodart and Tamsulosin (CombAT) trial. BJU Int. 2011;107(6):946-954. 29. McVary KT, Monnig W, Camps JL, Young JM, Tseng LJ, van den Ende G. Sildenafil citrate improves erectile function and urinary symptoms in men with erectile dysfunction and lower urinary tract symptoms associated with benign pros-tatic hyperplasia: a randomized, double-blind trial. J Urol. 2007;177(3):1071-1077. 30. Wang C. Phosphodiesterase-5 inhibitors and benign prostatic hyperplasia. Curr Opin Urol. 2010;20(1):49-54. 31. Wasson JH, Reda DJ, Bruskewitz RC, Elinson J, Keller AM, Henderson WG. A comparison of transurethral surgery with watchful waiting for moderate symptoms of benign prostatic hyperplasia. The Veterans Affairs Cooperative Study Group on Transurethral Resection of the Prostate. N Engl J Med. 1995;332(2):75-79. 32. Montorsi F, Naspro R, Salonia A, et al. Holmium laser enu-cleation versus transurethral resection of the prostate: results from a 2-center, prospective, randomized trial in patients with obstructive benign prostatic hyperplasia. J Urol. 2004;172 (5 pt 1):1926-1929. 33. Tan AH, Gilling PJ, Kennett KM, Frampton C, Westenberg AM, Fraundorfer MR. A randomized trial comparing holmium laser enucleation of the prostate with transurethral resection of the prostate for the treatment of bladder outlet obstruction secondary to benign prostatic hyperplasia in large glands (40 to 200 grams). J Urol. 2003;170(4 Pt 1):1270-1274. 34. Elzayat EA, Elhilali MM. Holmium laser enucleation of the prostate (HoLEP): long-term results, reoperation rate, and possible impact of the learning curve. Eur Urol. 2007;52(5):1465-1471. 35. Anger JT, Buckley JC, Santucci RA, Elliott SP, Saigal CS, Urologic Diseases in America P. Trends in stricture management among male Medicare beneficiaries: underuse of urethro-plasty? Urology. 2011;77(2):481-485. 36. Fenton AS, Morey AF, Aviles R, Garcia CR. Anterior ure-thral strictures: etiology and characteristics. Urology. 2005;65(6):1055-1058. 37. Nuss GR, Granieri MA, Zhao LC, Thum DJ, Gonzalez CM. Presenting symptoms of anterior urethral stricture disease: a disease specific, patient reported questionnaire to measure outcomes. J Urol. 2012;187(2):559-562. 38. Bertrand LA, Warren GJ, Voelzke BB, et al. Lower urinary tract pain and anterior urethral stricture disease: prevalence and effects of urethral reconstruction. J Urol. 2015;193(1):184-189. 39. Pal DK, Kumar S, Ghosh B. Direct visual internal urethrotomy: is it a durable treatment option? Urol Ann. 2017;9(1):18-22. 40. Hudak SJ, Atkinson TH, Morey AF. Repeat transurethral manipulation of bulbar urethral strictures is associated with increased stricture complexity and prolonged disease dura-tion. J Urol. 2012;187(5):1691-1695.Brunicardi_Ch40_p1759-p1782.indd 177801/03/19 6:35 PM 1779UROLOGYCHAPTER 40 41. Pipitone N, Vaglio A, Salvarani C. Retroperitoneal fibrosis. Best Pract Res Clin Rheumatol. 2012;26(4):439-448. 42. Cronin CG, Lohan DG, Blake MA, Roche C, McCarthy P, Murphy JM. Retroperitoneal fibrosis: a review of clini-cal features and imaging findings. AJR Am J Roentgenol. 2008;191(2):423-431. 43. Li KP, Zhu J, Zhang JL, Huang F. Idiopathic retroperitoneal fibrosis (RPF): clinical features of 61 cases and literature review. Clin Rheumatol. 2011;30(5):601-605. 44. Elsamra SE, Leavitt DA, Motato HA, et al. Stenting for malig-nant ureteral obstruction: Tandem, metal or metal-mesh stents. Int J Urol. 2015;22(7):629-636. 45. Lopez-Huertas HL, Polcari AJ, Acosta-Miranda A, Turk TM. Metallic ureteral stents: a cost-effective method of managing benign upper tract obstruction. J Endourol. 2010;24(3):483-485. 46. Taylor ER, Benson AD, Schwartz BF. Cost analysis of metal-lic ureteral stents with 12 months of follow-up. J Endourol. 2012;26(7):917-921. 47. Baumgarten AS, Hakky TS, Carrion RE, Lockhart JL, Spiess PE. A single-institution experience with metallic ureteral stents: a cost-effective method of managing deficiencies in ureteral drainage. Int Braz J Urol. 2014;40(2):225-231. 48. McAninch JW. Genitourinary trauma. World J Urol. 1999;17(2):65. 49. Breyer BN, McAninch JW, Elliott SP, Master VA. Minimally invasive endovascular techniques to treat acute renal hemor-rhage. J Urol. 2008;179(6):2248-2252; discussion 2253. 50. Hotaling JM, Sorensen MD, Smith TG 3rd, Rivara FP, Wessells H, Voelzke BB. Analysis of diagnostic angiography and angioembolization in the acute management of renal trauma using a national data set. J Urol. 2011;185(4):1316-1320. 51. Moore EE, Shackford SR, Pachter HL, et al. Organ injury scaling: spleen, liver, and kidney. J Trauma. 1989;29(12): 1664-1666. 52. Anselmo da Costa I, Amend B, Stenzl A, Bedke J. Contem-porary management of acute kidney trauma. Journal of Acute Disease. 2016;5(1):29-36. 53. Jansen JO, Inaba K, Resnick S, et al. Selective non-operative management of abdominal gunshot wounds: survey of prac-tise. Injury. 2013;44(5):639-644. 54. Dugi DD 3rd, Morey AF, Gupta A, Nuss GR, Sheu GL, Pruitt JH. American Association for the Surgery of Trauma grade 4 renal injury substratification into grades 4a (low risk) and 4b (high risk). J Urol. 2010;183(2):592-597. 55. McClung CD, Hotaling JM, Wang J, Wessells H, Voelzke BB. Contemporary trends in the immediate surgical management of renal trauma using a national database. J Trauma Acute Care Surg. 2013;75(4):602-606. 56. Atala A, Miller FB, Richardson JD, Bauer B, Harty J, Amin M. Preliminary vascular control for renal trauma. Surg Gyne-col Obstet. 1991;172(5):386-390. 57. Elliott SP, McAninch JW. Ureteral injuries from external violence: the 25-year experience at San Francisco General Hospital. J Urol. 2003;170(4 Pt 1):1213-1216. 58. Elliott SP, McAninch JW. Ureteral injuries: external and iat-rogenic. Urol Clin North Am. 2006;33(1):55-66, vi. 59. Mauck RJ, Hudak SJ, Terlecki RP, Morey AF. Central role of Boari bladder flap and downward nephropexy in upper ure-teral reconstruction. J Urol. 2011;186(4):1345-1349. 60. Morey AF, Iverson AJ, Swan A, et al. Bladder rupture after blunt trauma: guidelines for diagnostic imaging. J Trauma. 2001;51(4):683-686. 61. Quagliano PV, Delair SM, Malhotra AK. Diagnosis of blunt bladder injury: A prospective comparative study of com-puted tomography cystography and conventional retrograde cystography. J Trauma. 2006;61(2):410-421; discussion 421-412. 62. Wirth GJ, Peter R, Poletti PA, Iselin CE. Advances in the man-agement of blunt traumatic bladder rupture: experience with 36 cases. BJU Int. 2010;106(9):1344-1349. 63. Inaba K, McKenney M, Munera F, et al. Cystogram follow-up in the management of traumatic bladder disruption. J Trauma. 2006;60(1):23-28. 64. Elgammal MA. Straddle injuries to the bulbar urethra: management and outcome in 53 patients. Int Braz J Urol. 2009;35(4):450-458. 65. Mouraviev VB, Coburn M, Santucci RA. The treatment of posterior urethral disruption associated with pelvic fractures: comparative experience of early realignment versus delayed urethroplasty. J Urol. 2005;173(3):873-876. 66. Koraitim MM. Effect of early realignment on length and delayed repair of postpelvic fracture urethral injury. Urology. 2012;79(4):912-915. 67. Morey AF, Brandes S, Dugi DD, 3rd, et al. Urotrauma: AUA guideline. J Urol. 2014;192(2):327-335. 68. Nasser TA, Mostafa T. Delayed surgical repair of penile frac-ture under local anesthesia. J Sex Med. 2008;5(10):2464-2469. 69. el-Assmy A, el-Tholoth HS, Mohsen T, Ibrahiem el HI. Does timing of presentation of penile fracture affect outcome of surgical intervention? Urology. 2011;77(6):1388-1391. 70. Buckley JC, McAninch JW. Use of ultrasonography for the diagnosis of testicular injuries in blunt scrotal trauma. J Urol. 2006;175(1):175-178. 71. Fitzpatrick JM, Desgrandchamps F, Adjali K, et al. Man-agement of acute urinary retention: a worldwide survey of 6074 men with benign prostatic hyperplasia. BJU Int. 2012;109(1):88-95. 72. Fitzpatrick JM, Kirby RS. Management of acute urinary reten-tion. BJU Int. 2006;97(suppl 2):16-20; discussion 21-12. 73. Zeif HJ, Subramonian K. Alpha blockers prior to removal of a catheter for acute urinary retention in adult men. Cochrane Database Syst Rev. 2009(4):Cd006744. 74. Ringdahl E, Teague L. Testicular torsion. Am Fam Physician. 2006;74(10):1739-1743. 75. Srinivasan A, Cinman N, Feber KM, Gitlin J, Palmer LS. History and physical examination findings predictive of tes-ticular torsion: an attempt to promote clinical diagnosis by house staff. J Pediatr Urol. 2011;7(4):470-474. 76. Pogorelic Z, Mustapic K, Jukic M, et al. Management of acute scrotum in children: a 25-year single center experience on 558 pediatric patients. Can J Urol. 2016;23(6):8594-8601. 77. Norton KS, Johnson LW, Perry T, Perry KH, Sehon JK, Zibari GB. Management of Fournier’s gangrene: an eleven year ret-rospective analysis of early recognition, diagnosis, and treat-ment. Am Surg. 2002;68(8):709-713. 78. Oguz A, Gümüs M, Turkoglu A, et al. Fournier’s gangrene: a summary of 10 years of clinical experience. In: Int Surg. 2015;100:934-941. 79. Sherman J, Solliday M, Paraiso E, Becker J, Mydlo JH. Early CT findings of Fournier’s gangrene in a healthy male. Clin Imaging. 1998;22(6):425-427. 80. Rosen DR, Brown ME, Cologne KG, Ault GT, Strumwasser AM. Long-term follow-up of Fournier’s Gangrene in a tertiary care center. J Surg Res. 2016;206(1):175-181. 81. Ozkan OF, Koksal N, Altinli E, et al. Fournier’s gangrene cur-rent approaches. Int Wound J. 2016;13(5):713-716. 82. Montague DK, Jarow J, Broderick GA, et al. American Uro-logical Association guideline on the management of priapism. J Urol. 2003;170(4 Pt 1):1318-1324. 83. Anele UA, Le BV, Resar LMS, Burnett AL. How I treat pria-pism. Blood. 2015;125(23):3551-3558. 84. Burnett AL, Sharlip ID. Standard operating procedures for priapism. J Sex Med. 2013;10(1):180-194. 85. Mackway-Jones K, Teece S. Ice, pins, or sugar to reduce para-phimosis. Emerg Med J. 2004;21(1):77-78.Brunicardi_Ch40_p1759-p1782.indd 177901/03/19 6:35 PM 1780SPECIFIC CONSIDERATIONSPART II 86. Pohlman GD, Phillips JM, Wilcox DT. Simple method of paraphimosis reduction revisited: point of technique and review of the literature. J Pediatr Urol. 2013;9(1): 104-107. 87. Ubee SS, McGlynn L, Fordham M. Emphysematous pyelone-phritis. BJU Int. 2011;107(9):1474-1478. 88. Lu YC, Hong JH, Chiang BJ, et al. Recommended initial antimicrobial therapy for emphysematous pyelonephritis: 51 cases and 14-year-experience of a tertiary referral center. Medicine (Baltimore). 2016;95(21):e3573. 89. Misgar RA, Mubarik I, Wani AI, Bashir MI, Ramzan M, Laway BA. Emphysematous pyelonephritis: a 10-year experience with 26 cases. Indian J Endocrinol Metab. 2016;20(4):475-480. 90. Lu YC, Chiang BJ, Pong YH, et al. Predictors of failure of conservative treatment among patients with emphysematous pyelonephritis. BMC Infect Dis. 2014;14:418. 91. Siegel RL, Miller KD, Jemal A. Cancer statistics, 2018. CA Cancer J Clin. 2018;68(1):7-30. 92. American Joint Committee on Cancer. Urinary bladder. In: Edge SB, Byrd DR, Compton CC, Fritz AG, L. GF, Trotti A, eds. AJCC Cancer Staging Handbook: From the AJCC Cancer Staging Manual. 7th ed. New York: Springer-Verlag; 2010:569-577. 93. Sylvester RJ, van der Meijden AP, Oosterlinck W, et al. Predicting recurrence and progression in individual patients with stage Ta T1 bladder cancer using EORTC risk tables: a combined analysis of 2596 patients from seven EORTC trials. Eur Urol. 2006;49(3):466-465; discussion 475-467. 94. Babjuk M, Bohle A, Burger M, et al. EAU guidelines on non–muscle-invasive urothelial carcinoma of the bladder: update 2016. Eur Urol. 2017;71(3):447-461. 95. Lamm DL, Blumenstein BA, Crissman JD, et al. Maintenance bacillus Calmette-Guerin immunotherapy for recurrent TA, T1 and carcinoma in situ transitional cell carcinoma of the bladder: a randomized Southwest Oncology Group Study. J Urol. 2000;163(4):1124-1129. 96. Fernandez-Gomez J, Solsona E, Unda M, et al. Prognostic factors in patients with non–muscle-invasive bladder cancer treated with bacillus Calmette-Guerin: multivariate analysis of data from four randomized CUETO trials (see comment). Eur Urol. 2008;53(5):992-1001. 97. Fernandez-Gomez J, Madero R, Solsona E, et al. The EORTC tables overestimate the risk of recurrence and progression in patients with non–muscle-invasive bladder cancer treated with bacillus Calmette–Guérin: external validation of the EORTC risk tables. Eur Urol. 2011;60(3):423-430. 98. Chang SS, Bochner BH, Chou R, et al. Treatment of non-metastatic muscle-invasive bladder cancer: AUA/ASCO/ASTRO/SUO guideline. J Urol. 2017;198(3):552-559. 99. Shabsigh A, Korets R, Vora KC, et al. Defining early morbid-ity of radical cystectomy for patients with bladder cancer using a standardized reporting methodology. Eur Urol. 2009;55(1):164-174. 100. Johnson SC, Smith ZL, Golan S, Rodriguez JF, 3rd, Smith ND, Steinberg GD. Temporal trends in perioperative morbid-ity for radical cystectomy using the National Surgical Quality Improvement Program database. Urol Oncol. 2017;35(11):659 e613-659 e619. 101. Balar AV. Immune checkpoint blockade in metastatic urothe-lial cancer. J Clin Oncol. 2017;35(19):2109-2112. 102. Godwin JL, Hoffman-Censits J, Plimack E. Recent devel-opments in the treatment of advanced bladder cancer. Urol Oncol. 2018;36(3):109-114. 103. Znaor A, Lortet-Tieulent J, Jemal A, Bray F. International variations and trends in testicular cancer incidence and mor-tality. Eur Urol. 2014;65(6):1095-1106. 104. Che M, Tamboli P, Ro JY, et al. Bilateral testicular germ cell tumors: twenty-year experience at M. D. Anderson Cancer Center. Cancer. 2002;95(6):1228-1233. 105. Powles TB, Bhardwa J, Shamash J, Mandalia S, Oliver T. The changing presentation of germ cell tumours of the testis between 1983 and 2002. BJU Int. 2005;95(9):1197-1200. 106. Capelouto CC, Clark PE, Ransil BJ, Loughlin KR. A review of scrotal violation in testicular cancer: is adjuvant local ther-apy necessary? J Urol. 1995;153(3 Pt 2):981-985. 107. Donohue JP, Zachary JM, Maynard BR. Distribution of nodal metastases in nonseminomatous testis cancer. J Urol. 1982;128(2):315-320. 108. Pont J, Holtl W, Kosak D, et al. Risk-adapted treatment choice in stage I nonseminomatous testicular germ cell cancer by regarding vascular invasion in the primary tumor: a prospec-tive trial. J Clin Oncol. 1990;8(1):16-20. 109. Divrik RT, Akdogan B, Ozen H, Zorlu F. Outcomes of sur-veillance protocol of clinical stage I nonseminomatous germ cell tumors-is shift to risk adapted policy justified? J Urol. 2006;176(4 pt 1):1424-1429; discussion 1429-1430. 110. Oliver RT, Mead GM, Rustin GJ, et al. Randomized trial of carboplatin versus radiotherapy for stage I seminoma: mature results on relapse and contralateral testis cancer rates in MRC TE19/EORTC 30982 study (ISRCTN27163214). J Clin Oncol. 2011;29(8):957-962. 111. Hartmann M, Siener R, Krege S, et al. [Results of the ran-domised phase III study of the German Testicular Cancer Study Group. Retroperitoneal lymphadenectomy versus one cycle BEP as adjuvant therapy for non-seminomatous testicular tumours in clinical stage I.] Der Urologe Ausg A. 2009;48(5):523-528. 112. N H, AM N, M K, et al. SEER Cancer Statistics Review, 1975-2014, National Cancer Institute. Bethesda, MD. Available at: https://seer.cancer.gov/csr/1975_2014/, based on November 2016 SEER data submission, posted to the SEER web site. 2017. Accessed August 9, 2018. 113. Luz MA, Kotb AF, Aldousari S, et al. Retroperitoneal lymph node dissection for residual masses after chemotherapy in nonseminomatous germ cell testicular tumor. World J Surg Oncol. 2010;8:97. 114. Pearce SM, Golan S, Gorin MA, et al. Safety and early onco-logic effectiveness of primary robotic retroperitoneal lymph node dissection for nonseminomatous germ cell testicular cancer. Eur Urol. 2017;71(3):476-482. 115. Frank I, Blute ML, Cheville JC, Lohse CM, Weaver AL, Zincke H. Solid renal tumors: an analysis of patho-logical features related to tumor size. J Urol. 2003;170 (6 pt 1):2217-2220. 116. Richard PO, Jewett MA, Tanguay S, et al. Safety, reliability and accuracy of small renal tumour biopsies: results from a multi-institution registry. BJU Int. 2017;119(4):543-549. 117. Richard PO, Jewett MA, Bhatt JR, et al. Renal tumor biopsy for small renal masses: a single-center 13-year experience. Eur Urol. 2015;68(6):1007-1013. 118. Marconi L, Dabestani S, Lam TB, et al. Systematic review and meta-analysis of diagnostic accuracy of percutaneous renal tumour biopsy. Eur Urol. 2016;69(4):660-673. 119. Lane BR, Kattan MW. Prognostic models and algorithms in renal cell carcinoma. Urol Clin North Am. 2008;35(4): 613-625; vii. 120. Kanao K, Mizuno R, Kikuchi E, et al. Preoperative prog-nostic nomogram (probability table) for renal cell carcinoma based on TNM classification. J Urol. 2009;181(2):480-485; discussion 485. 121. Krejci KG, Blute ML, Cheville JC, Sebo TJ, Lohse CM, Zincke H. Nephron-sparing surgery for renal cell carcinoma: clinicopathologic features predictive of patient outcome. Urology. 2003;62(4):641-646.Brunicardi_Ch40_p1759-p1782.indd 178001/03/19 6:35 PM 1781UROLOGYCHAPTER 40 122. Mekhail TM, Abou-Jawde RM, Boumerhi G, et al. Validation and extension of the Memorial Sloan-Kettering prognos-tic factors model for survival in patients with previously untreated metastatic renal cell carcinoma. J Clin Oncol. 2005;23(4):832-841. 123. Smith ZL. Current status of minimally invasive surgery for renal cell carcinoma. Curr Urol Rep. 2016;17(6):43. 124. Kunkle DA, Uzzo RG. Cryoablation or radiofrequency ablation of the small renal mass : a meta-analysis. Cancer. 2008;113(10):2671-2680. 125. Clayman RV, Kavoussi LR, Soper NJ, et al. Laparoscopic nephrectomy: initial case report. J Urol. 1991;146(2):278-282. 126. Motzer RJ, Jonasch E, Agarwal N, et al. Kidney cancer, ver-sion 2.2017, NCCN clinical practice guidelines in oncology. J Natl Compr Canc Netw. 2017;15(6):804-834. 127. Abaza R. Initial series of robotic radical nephrectomy with vena caval tumor thrombectomy. Eur Urol. 2011;59(4):652-656. 128. Gill IS, Metcalfe C, Abreu A, et al. Robotic level III infe-rior vena cava tumor thrombectomy: initial series. J Urol. 2015;194(4):929-938. 129. Schroder FH, Hugosson J, Roobol MJ, et al. Screening and prostate cancer mortality: results of the European Ran-domised Study of Screening for Prostate Cancer (ERSPC) at 13 years of follow-up. Lancet. 2014;384(9959):2027-2035. 130. Moyer VA, Force USPST. Screening for prostate cancer: U.S. Preventive Services Task Force recommendation statement. Ann Intern Med. 2012;157(2):120-134. 131. Carter HB, Albertsen PC, Barry MJ, et al. Early detection of prostate cancer: AUA Guideline. J Urol. 2013;190(2): 419-426. 132. Gleason DF, Mellinger GT. Prediction of prognosis for pros-tatic adenocarcinoma by combined histological grading and clinical staging. J Urol. 1974;111(1):58-64. 133. Epstein JI, Zelefsky MJ, Sjoberg DD, et al. A contemporary prostate cancer grading system: a validated alternative to the gleason score. Eur Urol. 2016;69(3):428-435. 134. Hamdy FC, Donovan JL, Lane JA, et al. 10-year outcomes after monitoring, surgery, or radiotherapy for localized prostate cancer. N Engl J Med. 2016;375(15):1415-1424. 135. Chung MS, Lee SH. Current status of active surveillance in prostate cancer. Investig Clin Urol. 2016;57(1):14-20. 136. Wiegel T, Bartkowiak D, Bottke D, et al. Adjuvant radiother-apy versus wait-and-see after radical prostatectomy: 10-year follow-up of the ARO 96-02/AUO AP 09/95 trial. Eur Urol. 2014;66(2):243-250. 137. Thompson IM, Tangen CM, Paradelo J, et al. Adjuvant radiotherapy for pathological T3N0M0 prostate cancer significantly reduces risk of metastases and improves sur-vival: long-term followup of a randomized clinical trial. J Urol. 2009;181(3):956-962. 138. Pound CR, Partin AW, Eisenberger MA, Chan DW, Pear-son JD, Walsh PC. Natural history of progression after PSA elevation following radical prostatectomy. JAMA. 1999;281(17):1591-1597. 139. Ryan CJ, Smith MR, Fizazi K, et al. Abiraterone acetate plus prednisone versus placebo plus prednisone in chemother-apy-naive men with metastatic castration-resistant prostate cancer (COU-AA-302): final overall survival analysis of a randomised, double-blind, placebo-controlled phase 3 study. Lancet Oncol. 2015;16(2):152-160. 140. Logothetis CJ, Basch E, Molina A, et al. Effect of abiraterone acetate and prednisone compared with placebo and predni-sone on pain control and skeletal-related events in patients with metastatic castration-resistant prostate cancer: explor-atory analysis of data from the COU-AA-301 randomised trial. Lancet Oncol. 2012;13(12):1210-1217. 141. Loriot Y, Miller K, Sternberg CN, et al. Effect of enzalutamide on health-related quality of life, pain, and skeletal-related events in asymptomatic and minimally symptomatic, che-motherapy-naive patients with metastatic castration-resistant prostate cancer (PREVAIL): results from a randomised, phase 3 trial. Lancet Oncol. 2015;16(5):509-521. 142. Sternberg CN, de Bono JS, Chi KN, et al. Improved outcomes in elderly patients with metastatic castration-resistant prostate cancer treated with the androgen receptor inhibitor enzalu-tamide: results from the phase III AFFIRM trial. Ann Oncol. 2014;25(2):429-434. 143. Dalbagni G, Zhang ZF, Lacombe L, Herr HW. Male ure-thral carcinoma: analysis of treatment outcome. Urology. 1999;53(6):1126-1132. 144. Swartz MA, Porter MP, Lin DW, Weiss NS. Incidence of primary urethral carcinoma in the United States. Urology. 2006;68(6):1164-1168. 145. Cupp MR, Malek RS, Goellner JR, Espy MJ, Smith TF. Detection of human papillomavirus DNA in primary squa-mous cell carcinoma of the male urethra. Urology. 1996;48(4): 551-555. 146. Dinney CP, Johnson DE, Swanson DA, Babaian RJ, von Eschenbach AC. Therapy and prognosis for male ante-rior urethral carcinoma: an update. Urology. 1994;43(4): 506-514. 147. Gofrit ON, Pode D, Pizov G, Zorn KC, Katz R, Shapiro A. Prostatic urothelial carcinoma: is transurethral prostatectomy necessary before bacillus Calmette-Guerin immunotherapy? BJU Int. 2009;103(7):905-908. 148. Gakis G, Witjes JA, Comperat E, et al. EAU guidelines on primary urethral carcinoma. Eur Urol. 2013;64(5):823-830. 149. Gakis G, Morgan TM, Daneshmand S, et al. Impact of perioperative chemotherapy on survival in patients with advanced primary urethral cancer: results of the international collaboration on primary urethral carcinoma. Ann Oncol. 2015;26(8):1754-1759. 150. Kent M, Zinman L, Girshovich L, Sands J, Vanni A. Com-bined chemoradiation as primary treatment for invasive male urethral cancer. J Urol. 2015;193(2):532-537. 151. Dayyani F, Pettaway CA, Kamat AM, Munsell MF, Sircar K, Pagliaro LC. Retrospective analysis of survival outcomes and the role of cisplatin-based chemotherapy in patients with ure-thral carcinomas referred to medical oncologists. Urol Oncol. 2013;31(7):1171-1177. 152. Aguilar-Navarro S, Navarrete-Reyes AP, Grados-Chavarria BH, Garcia-Lara JM, Amieva H, Avila-Funes JA. The sever-ity of urinary incontinence decreases health-related quality of life among community-dwelling elderly. J Gerontol A Biol Sci Med Sci. 2012;67(11):1266-1271. 153. Bettez M, Tu le M, Carlson K, et al. 2012 update: guidelines for adult urinary incontinence collaborative consensus docu-ment for the Canadian urological association. Can Urol Assoc J. 2012;6(5):354-363. 154. Tennstedt SL, Chiu GR, Link CL, Litman HJ, Kusek JW, McKinlay JB. The effects of severity of urine leakage on qual-ity of life in Hispanic, white, and black men and women: the Boston community health survey. Urology. 2010;75(1):27-33. 155. Ramage-Morin PL, Gilmour H. Urinary incontinence and loneliness in Canadian seniors. Health Rep. 2013;24(10): 3-10. 156. Brown JS, Vittinghoff E, Wyman JF, et al. Urinary inconti-nence: does it increase risk for falls and fractures? Study of Osteoporotic Fractures Research Group. J Am Geriatr Soc. 2000;48(7):721-725. 157. Abrams P, Cardozo L, Fall M, et al. The standardisation of terminology in lower urinary tract function: report from the standardisation sub-committee of the International Conti-nence Society. Urology. 2003;61(1):37-49. 158. Dumoulin C, Hunter KF, Moore K, et al. Conservative management for female urinary incontinence and pelvic Brunicardi_Ch40_p1759-p1782.indd 178101/03/19 6:35 PM 1782SPECIFIC CONSIDERATIONSPART IIorgan prolapse review 2013: Summary of the 5th Interna-tional Consultation on Incontinence. Neurourol Urodyn. 2016;35(1):15-20. 159. Chapple C, Khullar V, Gabriel Z, Dooley JA. The effects of antimuscarinic treatments in overactive bladder: a systematic review and meta-analysis. Eur Urol. 2005;48(1):5-26. 160. Chapple CR, Cardozo L, Nitti VW, Siddiqui E, Michel MC. Mirabegron in overactive bladder: a review of efficacy, safety, and tolerability. Neurourol Urodyn. 2014;33(1):17-30. 161. van Kerrebroeck PE, van Voskuilen AC, Heesakkers JP, et al. Results of sacral neuromodulation therapy for urinary voiding dysfunction: outcomes of a prospective, worldwide clinical study. J Urol. 2007;178(5):2029-2034. 162. Burton C, Sajja A, Latthe PM. Effectiveness of percutane-ous posterior tibial nerve stimulation for overactive bladder: a systematic review and meta-analysis. Neurourol Urodyn. 2012;31(8):1206-1216. 163. Rovner E, Kennelly M, Schulte-Baukloh H, Zhou J, Haag-Molkenteller C, Dasgupta P. Urodynamic results and clinical outcomes with intradetrusor injections of onabotulinum-toxinA in a randomized, placebo-controlled dose-finding study in idiopathic overactive bladder. Neurourol Urodyn. 2011;30(4):556-562. 164. Johannes CB, Araujo AB, Feldman HA, Derby CA, Kleinman KP, McKinlay JB. Incidence of erectile dysfunction in men 40 to 69 years old: longitudinal results from the Massachusetts male aging study. J Urol. 2000;163(2):460-463. 165. Corona G, Lee DM, Forti G, et al. Age-related changes in gen-eral and sexual health in middle-aged and older men: results from the European Male Ageing Study (EMAS). J Sex Med. 2010;7(4 Pt 1):1362-1380. 166. Lue TF. Erectile dysfunction. N Engl J Med. 2000;342(24): 1802-1813. 167. Francis ME, Kusek JW, Nyberg LM, Eggers PW. The con-tribution of common medical conditions and drug exposures to erectile dysfunction in adult males. J Urol. 2007;178(2): 591-596; discussion 596. 168. Yafi FA, Jenkins L, Albersen M, et al. Erectile dysfunction. Nat Rev Dis Primers. 2016;2:16003. 169. McCabe MP, Althof SE. A systematic review of the psycho-social outcomes associated with erectile dysfunction: does the impact of erectile dysfunction extend beyond a man’s inability to have sex? J Sex Med. 2014;11(2):347-363. 170. The process of care model for evaluation and treatment of erectile dysfunction. The Process of Care Consensus Panel. Int J Impot Res. 1999;11(2):59-70; discussion 70-54. 171. Yuan J, Zhang R, Yang Z, et al. Comparative effective-ness and safety of oral phosphodiesterase type 5 inhibitors for erectile dysfunction: a systematic review and network meta-analysis. Eur Urol. 2013;63(5):902-912. 172. Giuliano F, Jackson G, Montorsi F, Martin-Morales A, Raillard P. Safety of sildenafil citrate: review of 67 double-blind placebo-controlled trials and the postmarket-ing safety database. Int J Clin Pract. 2010;64(2):240-255. 173. Baltaci S, Aydos K, Kosar A, Anafarta K. Treating erectile dysfunction with a vacuum tumescence device: a retro-spective analysis of acceptance and satisfaction. Br J Urol. 1995;76(6):757-760. 174. Ganem JP, Lucey DT, Janosko EO, Carson CC. Unusual complications of the vacuum erection device. Urology. 1998;51(4):627-631. 175. Guay AT, Perez JB, Velasquez E, Newton RA, Jacobson JP. Clinical experience with intraurethral alprostadil (MUSE) in the treatment of men with erectile dysfunction. A retrospec-tive study. Medicated urethral system for erection. Eur Urol. 2000;38(6):671-676. 176. Fulgham PF, Cochran JS, Denman JL, et al. Disappointing initial results with transurethral alprostadil for erectile dys-function in a urology practice setting. J Urol. 1998;160 (6 pt 1):2041-2046. 177. Rajpurkar A, Dhabuwala CB. Comparison of satisfaction rates and erectile function in patients treated with silde-nafil, intracavernous prostaglandin E1 and penile implant surgery for erectile dysfunction in urology practice. J Urol. 2003;170(1):159-163. 178. Kaefer M, Diamond D, Hendren WH, et al. The incidence of intersexuality in children with cryptorchidism and hypospa-dias: stratification based on gonadal palpability and meatal position. J Urol. 1999;162(3 pt 2):1003-1006; discussion 1006-1007. 179. Keays MA, Dave S. Current hypospadias management: Diag-nosis, surgical management, and long-term patient-centred outcomes. Can Urol Assoc J. 2017;11(1-2 suppl 1):S48-S53. 180. Preda I, Jodal U, Sixt R, Stokland E, Hansson S. Normal dimercaptosuccinic acid scintigraphy makes voiding cystoure-thrography unnecessary after urinary tract infection. J Pediatr. 2007;151(6):581-584, 584.e581. 181. Roberts KB. Urinary tract infection: clinical practice guide-line for the diagnosis and management of the initial UTI in febrile infants and children 2 to 24 months. Pediatrics. 2011;128(3):595-610. 182. Bilgutay AN, Roth DR, Gonzales ET, Jr., et al. Posterior urethral valves: risk factors for progression to renal failure. J Pediatr Urol. 2016;12(3):179 e171-e177. 183. Lee PA. Fertility after cryptorchidism: epidemiology and other outcome studies. Urology. 2005;66(2):427-431. 184. Feyles F, Peiretti V, Mussa A, et al. Improved sperm count and motility in young men surgically treated for cryptorchidism in the first year of life. Eur J Pediatr Surg. 2014;24(5):376-380. 185. Pettersson A, Richiardi L, Nordenskjold A, Kaijser M, Akre O. Age at surgery for undescended testis and risk of testicular cancer. N Engl J Med. 2007;356(18):1835-1841.Brunicardi_Ch40_p1759-p1782.indd 178201/03/19 6:35 PM
GynecologySarah M. Temkin, Thomas Gregory, Elise C. Kohn, and Linda Duska 41chapterPATHOPHYSIOLOGY AND MECHANISMS OF DISEASEThe female reproductive system includes the external (vulva including the labia, clitoris, and vaginal opening) sex organs as well as the internal organs (uterus and cervix, fallopian tubes, and ovaries) that function in human reproduction. The female reproductive tract has a multitude of tightly regulated functions. The ovaries produce the ova (egg cells) and hormones necessary for maintenance of reproductive function. The fallopian tubes accommodate transit of an ovum to the uterus and provide a location for fertilization. The uterus accommodates an embryo that develops into the fetus. The cervix provides a barrier between the external and internal genital tract. Ongoing activities, such as angiogenesis and physiologic invasion, are necessary in order for the reproductive organs to fulfill their purpose and are usurped in disease. Immune surveillance is regulated in a fashion that allows implantation, placentation, and development of the fetus.Because the pelvis contains a multitude of spatially and temporally varied functions, pathologies range from mechanical events, such as ovarian torsion or ruptured ectopic pregnancy, to infection, such as pelvic inflammatory disease, to mass effects, including leiomyomata and malignancy, that can present with similar and even overlapping symptoms and signs. An acute abdomen presentation in a woman of child bearing potential can range from pregnancy-related catastrophes, to appendicitis, to a hemorrhagic ovarian cyst.The ongoing rupture, healing, and regrowth of the ovarian capsule and endometrium during the menstrual cycle use the same series of biologic and biochemic events that are also active in pathologic events such as endometriosis and endometriomas, mature teratomas, dysgerminomas, and progression to malig-nancy. Genetic abnormalities, both germ line and somatic, that may cause competence and/or promote disease are increasingly well understood. Incorporation of genetic and genomic infor-mation in disease diagnosis and assessment has altered how we diagnose and follow disease, in whom we increase our diligence in searching for disease, and ultimately how we use the drug and other therapeutic armamentarium available to the treating physician.These points will be incorporated with surgical approaches into discussions of anatomy, diagnostic workup, infection, sur-gical and medical aspects of the obstetric patient, pelvic floor dysfunction, and neoplasms.ANATOMYClinical gynecologic anatomy centers on the pelvis (L. basin). Aptly named, the bowl-shaped pelvis houses the confluence and intersection of multiple organ systems. Understanding 1Pathophysiology and Mechanisms of Disease 1783Anatomy 1783Structure and Support of the Pelvis and Genitalia / 1784Vulva / 1785Vagina / 1785Uterus / 1785Cervix / 1785Fallopian Tubes / 1786Ovaries / 1786Fibrovascular Ligaments and Avascular Tissue Planes / 1786Vasculature and Nerves of the Pelvis / 1787Evaluation and Diagnosis 1787Elements of a Gynecologic History / 1787The Gynecologic Examination / 1787Commonly Used Testing / 1789Common Office Procedures for Diagnosis / 1790Benign Gynecologic Conditions 1791Vulvar Lesions / 1791Vaginal Lesions / 1793Cervical Lesions / 1794Uterine Corpus / 1794Procedures Performed for Structural Causes of Abnormal Uterine Bleeding / 1796Benign Ovarian and Fallopian Tube Lesions / 1801Other Benign Pelvic Pathology / 1802Pregnancy-Related Surgical Conditions 1804Conditions and Procedures Performed Before Viability / 1804Conditions and Procedures Performed After Viability / 1805Pelvic Floor Dysfunction 1807Evaluation / 1807Surgery for Pelvic Organ Prolapse / 1807Surgery for Stress Urinary Incontinence / 1808Gynecologic Cancer 1809Vulvar Cancer / 1809Vaginal Cancer / 1810Cervical Cancer / 1811Uterine Cancer / 1813Ovarian Cancer / 1815Minimally Invasive Gynecologic Surgery 1820Hysteroscopy / 1820Laparoscopy / 1820Robotic Surgery / 1820Complications Pertinent to Gynecologic Surgery / 1821Brunicardi_Ch41_p1783-p1826.indd 178318/02/19 4:33 PM 1784those structural and functional relationships is essential for the surgeon and allows an appreciation for the interplay of sexual function and reproduction as well as a context for understanding gynecologic pathology.Structure and Support of the Pelvis and GenitaliaThe bony pelvis is comprised by the sacrum posteriorly and the ischium, ilium, and pubic bones anteromedially. It supports the upper body and transmits the stresses of weight bearing to the lower limbs in addition to providing anchors for the supporting tissues of the pelvic floor.1 The opening of the pelvis is spanned by the muscles of the pelvic diaphragm (Fig. 41-1). The muscles of the pelvic sidewall include the iliacus, the psoas, and the obturator internus muscle (Fig. 41-2). These muscles contract tonically and include, from anterior to posterior, bilaterally, the pubococcygeus, puborectalis, iliococcygeus, and coccygeus muscles. The first two of these muscles contribute fibers to the fibromuscular perineal body. The urogenital hiatus is bordered laterally by the pubococcygeus muscles and anteriorly by the symphysis pubis. It is through this muscular defect that the urethra and vagina pass, and it is the focal point for the study of disorders of pelvic support such as cystocele, rectocele, and uterine prolapse.Pudendal nerveand arterySuperficial transverseperineii muscleIschiocavernosusmuscleVestibularbulbClitorisPubicramusUrethralmeatusBulbocavernosusmuscleBartholin’sglandPerinealmembranePerinealbodyExternal analsphincterGluteusmaximusAnusVaginalintroitusLevator animusclesFigure 41-1. Deeper muscles of the pelvic floor.Key Points1 Gynecologic causes of acute abdomen include PID and tubo-ovarian abscess, ovarian torsion, ruptured ectopic pregnancy, septic abortion. Pregnancy must be ruled out early in assessment of reproductive age patients presenting with abdominal or pelvic pain.2 The general gynecology exam must incorporate the whole physical examination in order to adequately diagnosis and treat gynecologic disorders.3 Benign gynecologic pathologies that are encountered at the time of surgery include endometriosis, endometriomas, fibroids, and ovarian cysts.4 It is critical that abnormal lesions of vulva, vagina, and cervix are biopsied for diagnosis before any treatment is planned; postmenopausal bleeding should always be investigated to rule out malignancy.5 Pelvic floor dysfunction (pelvic organ prolapse, urinary and fecal incontinence) is common; 11% of women will undergo a reconstructive surgical procedure at some point in their lives.6 Pregnancy confers important changes to both the cardio-vascular system and the coagulation cascade. Trauma in pregnancy must be managed with these changes in mind.7 Early-stage cervical cancer is managed surgically, whereas chemoradiation is preferred for stages Ib2 and above.8 Risk-reducing salpingo-oopherectomy is recommended in women with BRCA1 or BRCA2 mutations.9 Optimal debulking for epithelial ovarian cancer is a criti-cal element in patient response and survival. The preferred postoperative therapy for optimally debulked advanced-stage ovarian epithelial ovarian cancer is intraperitoneal chemotherapy.10 Long-term sequelae of intestinal and urologic injury can be avoided by intraoperative identification.Brunicardi_Ch41_p1783-p1826.indd 178418/02/19 4:33 PM 1785GYNECOLOGYCHAPTER 41VulvaThe labia majora form the cutaneous boundaries of the lateral vulva and represent the female homologue of the male scrotum (Fig. 41-4). The labia majora are fatty folds covered by hair-bearing skin in the adult. They fuse anteriorly over the ante-rior prominence of the symphysis pubis, the mons pubis. The deeper portions of the adipose layers are called Colles fascia and insert onto the inferior margin of the perineal membrane, limiting spread of superficial hematomas inferiorly. Adjacent and medial to the labia majora are the labia minora, smaller folds of connective tissue covered laterally by non–hair-bearing skin and medially by vaginal mucosa. The anterior fusion of the labia minora forms the prepuce and frenulum of the clitoris; posteriorly, the labia minora fuse to create the fossa navicularis and posterior fourchette. The term vestibule refers to the area medial to the labia minora bounded by the fossa navicularis and the clitoris. Both the urethra and the vagina open into the vestibule. Skene’s glands lie lateral and inferior to the urethral meatus. Cysts, abscesses, and neoplasms may arise in these glands.Erectile tissues and associated muscles are in the space between the perineal membrane and the vulvar subcutaneous tissues (see Fig. 41-1). The clitoris is formed by two crura and is suspended from the pubis. Overlying the crura are ischio-cavernosus muscles, which run along the inferior surfaces of the ischiopubic rami. Extending medially from the inferior end of the ischiocavernosus muscles are the superficial transverse perinei muscles. These terminate in the midline in the perineal body, caudal and deep to the posterior fourchette. Vestibular bulbs lie just deep to the vestibule and are covered laterally by bulbocavernosus muscles. These originate from the perineal body and insert into the body of the clitoris. At the inferior end of the vestibular bulbs are Bartholin’s glands, which connect to the vestibular skin by ducts.VaginaThe vagina is an elastic fibromuscular tube opening from the vestibule running superiorly and posteriorly, passing through the perineal membrane. The lower third is invested by the superficial and deep perineal muscles; it incorporates the ure-thra in its anterior wall and has a rich blood supply from the vaginal branches of the external and internal pudendal arteries. The upper two-thirds of the vagina are not invested by muscles. This portion lies in opposition to the bladder base anteriorly and the rectum and posterior pelvic cul-de-sac superiorly. The cervix opens into the posterior vaginal wall bulging into the vaginal lumen.UterusThe typically pear-shaped uterus consists of a fundus, cornua, body, and cervix. It lies between the bladder anteriorly and the rectosigmoid posteriorly. The endometrium lines the inside cavity and has a superficial functional layer that is shed with menstruation and a basal layer from which the new functional layer is formed. Sustained estrogenic stimulation without asso-ciated progestin maturation can lead to hyperplastic changes or carcinoma. Adenomyosis is a condition in which benign endo-metrial glands infiltrate into the muscle or myometrium of the uterus. The myometrium is composed of smooth muscle and the contraction of myometrium is a factor in menstrual pain and is essential in childbirth. The myometrium can develop benign smooth muscle neoplasms known as leiomyoma or fibroids.CervixThe cervix connects the uterus and vagina and projects into the upper vagina. The vagina forms an arched ring around the cervix described as the vaginal fornices—lateral, anterior, and posterior. The cervix is about 2.5-cm long with a fusiform endo-cervical canal lined by columnar epithelium lying between an internal and external os, or opening. The vaginal surface of the cervix is covered with stratified squamous epithelium, similar to that lining the vagina. The squamo-columnar junction, also referred to as the transformation zone, migrates at different stages of life and is influenced by estrogenic stimulation. The transformation zone develops as the columnar epithelium is replaced by squamous metaplasia. This transformation zone is Internal iliac arteryLateral sacralarterySuperiorglutealarteryInferior gluteal arteryCoccygeus muscleInternal pudendalarteryUterine arteryMiddle rectal arteryObturator internusmuscleObturator arterySuperior vesical arteryExternal iliac arteryCommon iliac arteryFigure 41-2. The muscles and vasculature of the pelvis.Hypogastric plexusObturator nerveVesical plexusUterovaginal plexus Rectal plexusLeft pelvic plexusSacral plexusSympathetic ganglionFigure 41-3. The nerve supply of the female pelvis.Brunicardi_Ch41_p1783-p1826.indd 178518/02/19 4:33 PM 1786SPECIFIC CONSIDERATIONSPART IIvulnerable to human papilloma virus (HPV) infection and resul-tant premalignant changes. These changes can be detected by microscopic assessment of cervical cytological (or Pap) smear. If the duct of a cervical gland becomes occluded, the gland dis-tends to form a retention cyst or Nabothian follicle.Fallopian TubesThe bilateral fallopian tubes arise from the upper lateral cornua of the uterus and course posterolaterally within the upper border of the broad ligament. The tubes can be divided into four parts. The interstitial part forms a passage through the myometrium. The isthmus is the narrow portion extending out about 3 cm from the myometrium. The ampulla is thin-walled and tortuous with its lateral end free of the broad ligament. The infundibulum is the distal end fringed by a ring of delicate fronds or fimbriae. The fallopian tubes receive the ovum after ovulation. Peristal-sis carries the ovum to the ampulla where fertilization occurs. The zygote transits the tube over the course of 3 to 4 days to the uterus. Abnormal implantation in the fallopian tube is the most common site of ectopic pregnancies. The tubes may also be infected by ascending organisms, resulting in tubo-ovarian abscesses. Scarring of the fallopian tubes can lead to hydrosal-pinx. Recent evidence suggests most high-grade serous ovarian cancer originates in the fallopian tubes.OvariesThe ovaries are attached to the uterine cornu by the proper ovarian ligaments, or the utero-ovarian ligaments. The ovaries are sus-pended from the lateral pelvis by their vascular pedicles, the infundibulopelvic ligaments (IP) or ovarian arteries. These are also called the suspensory ligaments of the ovaries, and cor-respond to the genital vessels in the male. The IP’s are paired branches from the abdominal aorta arising just below the renal arteries. They merge with the peritoneum over the psoas major muscle and pass over the pelvic brim and the external iliac ves-sels. The ovarian veins ascend at first with the ovarian arteries, then track more laterally. The right ovarian vein ascends to drain BladderUterusRound ligamentExternal iliacartery and veinFallopian tubeOvarianvesselsOvarian ligamentBroad ligamentUterosacral ligamentSigmoid colonUreterOvaryFigure 41-5. Internal pelvic anatomy, from above.Figure 41-4. External genitalia. (Reproduced with permission from Rock J, Jones HW: TeLinde’s Operative Gynecology, 9th ed. Philadelphia, PA: Lippincott Williams & Wilkins; 2003.)ClitorisLabiumminusLabiummajusMouth ofBartholin’s glandFossa navicularisFourchetteAnusHymenVaginaSkene’sductsUrethralorificePrepuce ofclitorisdirectly into the inferior vena cava while the left vein drains into the left renal vein. Lymphatic drainage follows the arteries to the para-aortic lymph nodes. The ovaries are covered by a single layer of cells that is continuous with the mesothelium of the peritoneum. Beneath this is a fibrous stroma within which are embedded germ cells. At ovulation, an ovarian follicle ruptures through the ovarian epithelium.Fibrovascular Ligaments and Avascular Tissue PlanesFigure 41-5 is a view of the internal genitalia and deep pelvis as one would approach the pelvis from a midline abdominal incision. The central uterus and uterine cervix are supported by the pelvic floor muscles (Fig. 41-5). They are suspended by Brunicardi_Ch41_p1783-p1826.indd 178618/02/19 4:34 PM 1787GYNECOLOGYCHAPTER 41the lateral fibrous cardinal, or Mackenrodt’s ligament, and the uterosacral ligaments, which insert into the paracervical fascia medially and into the muscular sidewalls of the pelvis laterally. Posteriorly, the uterosacral ligaments provide support for the vagina and cervix as they course from the sacrum lateral to the rectum and insert into the paracervical fascia. Emanating from the uterine cornu and traveling through the inguinal canal are the round ligaments, eventually attaching to the subcutaneous tissue of the mons pubis. The peritoneum enfolding the adnexa (tube, round ligament, and ovary) is referred to as the broad ligament, which separates the pelvic cavity into an anterior and posterior component.The peritoneal reflections in the pelvis anterior and pos-terior to the uterus are referred to as the anterior and posterior cul-de-sacs. The latter is also called the pouch or cul-de-sac of Douglas. On transverse section, seven avascular, and therefore important, surgical planes can be identified (Fig. 41-6). These include the right and left lateral paravesical and right and left pararectal spaces, and from anterior to posterior, the retropubic or prevesical space of Retzius and the vesicovaginal, rectovagi-nal, and retrorectal or presacral spaces.These avascular tissue planes are often preserved and provide safe surgical access when the intraperitoneal pelvic anatomy is distorted by tumor, endometriosis, adhesions, or infection. Utilizing the avascular retroperitoneal planes, the ure-ter can be traced into the pelvis as it crosses the distal common iliac arteries laterally into the pararectal space and then courses inferior to the ovarian arteries and veins until crossing under the uterine arteries into the paravesical space just lateral to the cervix. After traveling to the cervix, the ureters course down-ward and medially over the anterior surface of the vagina before entering the base of the bladder in the vesicovaginal space.Vasculature and Nerves of the PelvisThe rich blood supply to the pelvis arises largely from the internal iliac arteries except for the middle sacral artery originating at the aortic bifurcation and the ovarian arteries originating from the abdominal aorta. There is also collateral flow and anastomo-ses to the pelvic vessels from the inferior mesenteric artery. The internal iliac, or hypogastric, arteries divide into anterior and pos-terior branches. The latter supply lumbar and gluteal branches. From the anterior division of the hypogastric arteries arise the Prevesical spaceParavesical spaceVesicovaginalspaceVesicouterine ligamentCardinal ligamentUterosacralligamentRetrovaginal spaceRetrorectal spaceSacrumRectumPararectal spaceCervicalfasciaCervixVesicalfasciaBladderPubovesical ligamentFigure 41-6. The avascular spaces of the female pelvis.obturator, uterine, pudendal, middle rectal, inferior gluteal, along with superior and middle vesical arteries (see Fig. 41-2).The major motor nerves found in the pelvis are the sci-atic, obturator, and femoral nerves (Fig. 41-3). Also important to the pelvic surgeon are the ilioinguinal, iliohypogastric and genitofemoral nerves, which arise as upper abdominal nerves, but are encountered on the most caudal portion of the anterior abdominal wall and the ventral portion of the external genitalia. Sympathetic fibers course along the major arteries and para-sympathetics form the superior and inferior pelvic plexus. The pudendal nerve arises from S2–S4 and travels laterally, exiting the greater sciatic foramen, hooking around the ischial spine and sacrospinous ligament, and returning via the greater sciatic foramen. It travels through Alcock’s canal and becomes the sen-sory and motor nerve of the perineum (see Figs. 41-1 and 41-3). The motor neurons serve the tonically contracting urethral and anal sphincter, and direct branches from the S2–S4 nerves serve the levator ani muscles. During childbirth and other excessive straining, this tethered nerve (along with the levator ani muscles) is subject to stretch injury and is at least partially responsible for many female pelvic floor disorders.EVALUATION AND DIAGNOSISElements of a Gynecologic HistoryA complete history is a seminal part of any assessment (Table 41-1). Many gynecologic diseases can present with broad constitutional symptoms, occur secondary to other conditions, or be related to medications. A full history should include particular attention to family history, organ system history, including breast, gastrointestinal, and urinary tract symptoms, and a careful medication, anesthesia, and surgical history. The key elements of a focused gynecologic history include the following:• Date of last menstrual period• History of contraceptive and postmenopausal hormone use• Obstetrical history• Age at menarche and menopause (method of menopause, [e.g., drug, surgical])• Menstrual bleeding pattern• History of pelvic assessments, including cervical smear and HPV DNA results• History of pelvic infections, including HPV and HIV status• Sexual history• Prior gynecologic surgery(s)The Gynecologic ExaminationFor many young women, their gynecologist is their primary care physician. When that is the case, it is necessary that a full medical and surgical history be taken and that, in addition to the pelvic examination, the minimum additional examination should include assessment of the thyroid, breasts, and cardiopul-monary system. Screening, reproductive counseling, and age-appropriate health services should be available to women of all ages with or without a routine pelvic examination, but the deci-sion to proceed with regular, annual pelvic examinations in oth-erwise healthy women is controversial.2,3 The U.S. Preventive Services Task Force recently evaluated the current evidence regarding the balance of benefits and harms of performing screening pelvic examinations in asymptomatic, nonpregnant adult women and concluded that the evidence is insufficient.32Brunicardi_Ch41_p1783-p1826.indd 178718/02/19 4:34 PM 1788SPECIFIC CONSIDERATIONSPART IIThe pelvic examination starts with a full abdominal exam-ination. Inguinal node evaluation is performed before placing the patient’s legs in the dorsal lithotomy position (in stirrups). A flexible, focused light source is essential, and vaginal instru-ments including speculums of variable sizes and shapes (Graves and Pederson), including pediatric sizes, are required to assure that the patient’s anatomy can be fully and comfortably viewed.The external genitalia are inspected first, noting the distri-bution of pubic hair, the skin color and contour, the Bartholin and Skene’s glands, and perianal area. Abnormalities are docu-mented and a map with measurements of abnormalities drawn. A warmed lubricated speculum is inserted into the vagina and gently opened to identify the cervix if present or the vaginal apex if not. To avoid confounding the location of pelvic pain with immediate speculum exam, or if there is a concern that a malignancy is present, careful digital assessment of a vaginal mass and location may be addressed prior to speculum place-ment in order to avoid abrading a vascular lesion and inducing hemorrhage. The speculum would then be inserted just short of the length to the mass in order to view that area directly before advancing. An uncomplicated speculum exam includes examination of the vaginal sidewalls, assessment of secretions, including culture if necessary, and collection of the cervical cytologic specimen and HPV test if indicated (see “Common Screening”).A bimanual examination is performed by placing two fin-gers in the vaginal canal; one finger may be used if patient has significant vaginal atrophy or has had prior radiation with ste-nosis (Fig. 41-7). Carefully and sequentially assess the size and shape of the uterus by moving it against the abdominal hand, and the adnexa by carefully sweeping the abdominal hand down the side of the uterus. The rectovaginal examination, consisting of one finger in the vagina and one in the rectal vault, is used to further examine and characterize the location, shape, fixation, size, and complexity of the uterus, adnexa, cervix, and anterior and posterior cul-de-sacs. The rectovaginal exam also allows examination of the uterosacral ligaments from the back of the uterus sweeping laterally to the rectal finger and the sacrum, as well as assessment of the rectum and anal canal for masses.It is critical that presurgical assessments include a full gen-eral examination. This is particularly important with potential oncologic diagnoses or infectious issues in order to assure that the proposed surgery is both safe and appropriate. Issues such as sites of metastatic cancer or infection, associated bleeding and/Table 41-1Key elements of the gynecologic historyISSUEELEMENTS TO EXPLOREASSOCIATED ISSUESMenstrual historyAge at menarche, menopause.Bleeding pattern, postmenopausal bleeding, spotting between periods.Any medications (warfarin, heparin, aspirin, herbals, others) or personal or family history that might lead to prolonged bleeding timesIdentifies abnormal patterns related to endocrine, structural, infectious, and oncologic etiologiesObstetrical historyNumber of pregnancies, dates, type of deliveries, pregnancy loss, abortion, complicationsIdentifies predisposing pregnancy for GTD, possible surgical complicationsSexual historyPartners, practices, protection; pregnancy intentionGuide the assessment of patient risk, risk-reduction strategies, the determination of necessary testing, and the identification of anatomical sites from which to collect specimens for STD testingInfectious diseasesSexually transmitted diseases and treatment and/or testing for theseAlso need to explore history of other GI diseases that may mimic STD (Crohn’s, diverticulitis)Contraceptive historyPresent contraception if appropriate, prior use, type and durationConcurrent pregnancy with procedure or complications of contraceptivesCytologic screeningFrequency, results (normal, prior abnormal Pap), any prior surgery or diagnoses, HPV testing historyProlonged intervals increase risk of cervical cancerRelationship to anal, vaginal, vulvar cancersPrior gynecologic surgeryType (laparoscopy, vaginal, abdominal); diagnosis (endometriosis? ovarian cysts? tubo-ovarian abscess?); actual pathology if possibleAssess present history against this background (for example, granulosa cell pathology, is it now recurrent?)Pain historySite, location, relationship (with urination, with menses, with intercourse at initiation or deep penetration, with bowel movements), referralAssesses relationship to other organ systems, and potential involvement of these with process. Common examples presenting as pelvic pain, ureteral stone, endometriosis with bowel involvement, etcBrunicardi_Ch41_p1783-p1826.indd 178818/02/19 4:34 PM 1789GYNECOLOGYCHAPTER 41or clotting issues and history, and drug exposure, allergies, and current medications must be addressed.Commonly Used Testinga-Human Chorionic Gonadotropin Testing. Qualitative uri-nary pregnancy tests for human chorionic gonadotropin (b-hCG) are standard prior to any surgery in a woman of reproductive age and potential, regardless of contraception history. In addition, serum quantitative b-hCG testing is appropriate for evaluation of suspected ectopic pregnancy, gestational trophoblastic dis-ease, or ovarian mass in a young woman. In the case of ectopic pregnancy, serial levels are required when a pregnancy cannot be identified in the uterine cavity by imaging. As a general rule, 85% of viable, very early intrauterine pregnancies will have at least a 66% rise in the b-hCG level over 48 hours.Table 41-2Features of common causes of vaginitis BACTERIAL VAGINOSISVULVOVAGINAL CANDIDIASISTRICHOMONIASISPathogenAnaerobic organismsCandida albicansTrichomonas vaginalis% of vaginitis403020pH>4.5<4.5>4.5Signs and symptomsMalodorous, adherent dischargeWhite discharge, vulvar erythema, pruritus, dyspareuniaMalodorous purulent discharge, vulvovaginal erythema, dyspareuniaWet mountClue cellsPseudohyphae or budding yeasts in 40% of casesMotile trichomonadsKOH mount Pseudohyphae or budding yeasts in 70% of cases Amine test+−−TreatmentMetronidazole 500 mg twice a day for 7 d or 2 g single dose, metronidazole or clindamycin vaginal creamOral fluconazole 150 mg single dose, vaginal antifungal preparationsMetronidazole 2 g single dose and treatment of partner+ = positive; − = negative; KOH = potassium hydroxide.Figure 41-7. Bimanual abdominovaginal palpation of the uterus.Microscopy of Vaginal Discharge. During a speculum exam, a cotton-tipped applicator is used to collect the vaginal dis-charge; it is smeared on a slide with several drops of 0.9% nor-mal saline to create a saline wet mount. A cover slide is placed and the slide is evaluated microscopically for the presence of mobile trichomonads (Trichomonas vaginalis) or clue cells (epithelial cells studded with bacteria, seen in bacterial vagi-nosis; Table 41-2). A potassium hydroxide (KOH) wet mount is the slide application of the collected vaginal discharge with 10% KOH; this destroys cellular elements. The test is posi-tive for vaginal candidiasis when pseudohyphae are seen (see Table 41-2).Chlamydia/Gonorrhea Testing. Nucleic acid amplification testing (NAAT) has emerged as the diagnostic test of choice for N gonorrhea and C trachomatis. A vaginal swab, endocervical swab, and/or urine sample, can be used for this test.Cervical Cancer Screening and Prevention. HPV infection is required for the development of epithelial cervical carcino-mas (squamous and adenocarcinomas), and HPV DNA can be identified in virtually all primary cervical malignancies. HPV is a ubiquitous double-stranded DNA virus commonly acquired in the female lower genital tract through sexual contact. After entry into the cell, the HPV protein E6 degrades the tumor sup-pressor p53, resulting in deregulation of cell cycle arrest. E7 inactivates the tumor suppressor RB and releases E2F transcrip-tion factors, causing cellular hyperproliferation. More than 100 HPV types have been identified, and up to 40 of these subtypes infect the anogenital region. At least 12 are considered high-risk or oncogenic, and HPV genotypes 16 and 18 cause approxi-mately 70% of cervical cancers worldwide.4Recent cervical cytology guidelines have increased the intervals between screenings for most women given the known natural history of HPV-related cervical dysplasia progression to cancer and the high negative predictive value of a negative HPV test.6 The current recommendations call for cervical smear screening every 3 to 5 years in women ages 21 to 65 years. If an Brunicardi_Ch41_p1783-p1826.indd 178918/02/19 4:34 PM 1790SPECIFIC CONSIDERATIONSPART IIHPV test performed at the same time also is negative, test-ing should be repeated every 5 years for women ages 30 to 65 years. Screening is not recommended for women age older than 65 or without a cervix (prior hysterectomy) unless they have a history of high-grade precancerous lesions. Women with a history of cervical dysplasia, HPV infection, or cervical cancer need more frequent screening based on their diagnosis. Primary high-risk HPV (hrHPV) screening is also an acceptable alterna-tive to cytologic screening for women ages 30-65 because of an increased detection of high-grade squamous intraepithelial lesion (HSIL) and increased negative predictive value.6HPV Vaccine. Three HPV vaccines have been approved by the U.S. Food and Drug Administration (FDA).7 In 2006, a quad-rivalent (4vHPV) vaccine was approved that targets HPV 16 and 18, which cause 70% of cervical cancers, and HPV geno-types 6 and 11, which cause 90% of genital warts. In Decem-ber 2014, a nine-valent vaccine (9cHPV) was introduced to replace the 4vHPV vaccine, which includes protection against the HPV strains covered by the first generation of 4vHPV as well as five other HPV strains responsible for 20% of cervical cancers (HPV-31, HPV-33, HPV-45, HPV-52, and HPV-58).7 The 9vHPV may be used to continue or complete a series started with a different HPV vaccine product. Vaccination with 9vHPV after completion of 4vHPV at least 12 months earlier is safe and may provide protection against additional HPV strains. A biva-lent vaccine that targets HPV genotypes 16 and 18 with a dif-ferent adjuvant that may have led to higher immunogenicity was approved in 2009 but is no longer marketed in the United States.Vaccination generates high concentrations of neutralizing antibodies to HPV L1 protein, the antigen in all HPV vaccines. The vaccines are highly immunogenic, activating both humoral and cellular immune responses. Multiple randomized clinical trials have demonstrated nearly 100% efficacy in the preven-tion of the HPV subtype-specific precancerous cervical cell changes.7,8 These major clinical trials have used prevention of HSIL as the efficacy endpoints. Vaccination does not protect women who are already infected with HPV-16 or -18 at the time of vaccination.Current recommendations include HPV vaccination for boys and girls at age 11 or 12 years. (Vaccination can be started at age 9.) The Advisory Committee on Immunization Prac-tices (ACIP) also recommends vaccination for females aged 13 through 26 years and males aged 13 through 21 years not adequately vaccinated previously. Catch-up vaccination is also recommended through age 26 years for gay, bisexual, and other men who have sex with men, transgender people, and for immu-nocompromised persons (including those with HIV infection) not adequately vaccinated previously.8 Two doses are given 6 to 12 months apart for patients with an intact immune system, age less than 15 years; three doses are recommended for those ages 15 to 26 years and immunocompromised persons.10 Cervical cancer screening continues to play an important role in detection and treatment of premalignant cervical lesions and prevention of cervical cancer in these high-risk patients and is currently recommended following HPV vaccination.Serum Cancer Antigen 125. Cancer antigen (CA) 125 is a large membrane glycoprotein belonging to the wide mucin family commonly used as a tumor marker in patients known to have ovarian cancer. An elevated CA-125 in the patient without known ovarian cancer should be interpreted in conjunction with patient information and symptoms as well as imaging. In the setting of an adnexal mass, the serum CA-125 test may help with triage of a patient to the appropriate surgical management. The test should be used with caution as it is a nonspecific test and may be elevated with multiple benign conditions including endometriosis, fibroids, infection, and pregnancy and may even vary with the menstrual cycle. For these reasons, the CA-125 test is less useful in the premenopausal woman for triaging an adnexal mass. In the postmenopausal woman, a CA-125 greater than 35 in the setting of a complex adnexal mass merits referral of the patient to a gynecologic oncologist.10Common Office Procedures for DiagnosisVulvar/Vaginal Biopsy. Any abnormal vulvar or vaginal lesion including skin color changes, raised lesions, or ulcer-ations should be biopsied. Local infiltration with local anes-thetic is followed by a 3to 5-mm punch biopsy appropriate to the lesion. The specimen is elevated with Adson forceps and cut from its base with scissors. The vaginal biopsy can sometimes be difficult to perform because of the angle of the lesion. After injection with local anesthetic, traction of the area with Allis forceps and direct resection of the lesion with scissors or cervi-cal biopsy instrument (Schubert, Kevorkian, etc) can achieve an adequate biopsy.Colposcopy and Cervical Biopsy. In cases of an abnormal Pap smear cytology or positive HPV testing, a colposcopy is performed for a histologic evaluation. A colposcope is used to achieve 2x to 15x magnification of the cervix. Once the cer-vix is visualized, cervical mucus, if present, is removed, and then 3% acetic acid is applied to the cervix for one minute. This application dehydrates cells and causes dysplastic cells with dense nuclei to appear white. The lining of the cervix consists of squamous epithelium on the ectocervix, whereas columnar epithelium lines the endocervical canal. The ectocervix there-fore appears smooth and pale pink in color while the endocervix forms epithelial fronds or “grape-like” structures visible through the colposcope. The junction between columnar and squamous cell types is called the squamocolumnar junction (SCJ), which in younger women is usually visible on the ectocervix. When columnar epithelium extends onto the ectocervix, it appears as a red zone surrounding the os and is called ectropion or ectopy. The transformation zone (TZ) is the area between mature squa-mous epithelium distally and columnar epithelium proximally, and it is the site of active squamous metaplasia. For colposcopy to be deemed adequate, the entire SCJ must be visualized dur-ing an adequate colposcopy. Areas with acetowhite, punctation, mosaicism, or atypical blood vessels seen during colposcopy may represent dysplasia or cancer and should be biopsied. A green filter enhances visualization of blood vessels by making them appear darker in contrast to the surrounding epithelium.An alternative to dilute acetic acid is Lugol’s solution—a concentrated solution of iodine that reacts with the glycogen in normal squamous epithelium to make it appear dark brown. High-grade CIN lesions have low amounts of glycogen because the epithelium is poorly differentiated, and hence they do not turn brown with Lugol’s solution. This is termed Lugol’s nonstaining or Lugol’s negative. Historically, this used to be referred to as the Schiller’s test. Lugol’s can be useful for determining whether a colposcopically equivocal area warrants biopsy: Lugol’s staining areas are most likely normal epithelium, whereas Lugol’s nonstaining areas may be CIN, metaplasia, or inflammation.Brunicardi_Ch41_p1783-p1826.indd 179018/02/19 4:34 PM 1791GYNECOLOGYCHAPTER 41Endometrial Biopsy. Endometrial sampling should be per-formed before planned hysterectomy if there is a history of bleeding between periods, heavy and/or frequent menstrual peri-ods, or postmenopausal bleeding. A patient with the potential for pregnancy should have a pregnancy test before the procedure. A pipelle endometrial biopsy can be performed in the office and is a cost-effective and safe procedure that is generally well tolerated by patients. The pipelle is a flexible polypropylene suction cannula with an outer diameter of 3.1 mm. The pipelle is inserted through the endocervix after cervical cleaning, and the depth of the uterine cavity is noted. If difficulty in entering the endometrium with the pipelle is encountered, a tenaculum may be used to straighten the cervix and/or an OS-finder may be use-ful in overcoming resistance within the endocervix. The endo-metrial specimen is obtained by pulling on the plunger within the pipelle, creating a small amount of suction. The pipelle is rotated and pulled back from the fundus to the lower uterine segment within the cavity to access all sides.11 Additional passes may be needed in order to acquire an adequate amount of tis-sue. If office biopsy is not possible due to patient discomfort or cervical stenosis, a dilatation and curettage in the operating room may be indicated depending on the clinical circumstances.Evaluation for Fistula. When a patient presents with copi-ous vaginal discharge, the provider should be concerned about a fistula with the urinary or gastrointestinal tract. A simple office procedure can be performed when there is a concern for a vesi-covaginal fistula. A vaginal tampon is placed followed by instil-lation of sterile blue dye through a transurethral catheter into the bladder; a positive test is blue staining of the tampon. If the test is negative, one can evaluate for a ureterovaginal fistula. The patient is given phenazopyridine, which changes the color of urine to orange. If a tampon placed in the vagina stains orange, the test is positive. Alternatively, the patient can be given an intravenous injection of indigo carmine.Rectal fistula must be considered when a patient reports stool evacuation per vagina. It can be identified in a similar fashion using a large Foley catheter placed in the distal rectum through which dye may be injected, or with the use of an oral charcoal slurry and timed examination. Common areas for fis-tulae are at the vaginal apex, at the site of a surgical incision, or around the site of a prior episiotomy or perineal repair after a vaginal delivery.BENIGN GYNECOLOGIC CONDITIONSVulvar LesionsPatients presenting with vulvar symptoms should be carefully interviewed and examined, and a vulvar biopsy should be obtained whenever the diagnosis is in question, the patient does not respond to treatment, or premalignant and malignant disease is suspected. Vulvar conditions such as contact derma-titis, atrophic vulvovaginitis, lichen sclerosis, lichen planus, lichen chronicus simplex, Paget’s disease, Bowen’s disease, and invasive vulvar cancer are common particularly in postmeno-pausal women. Systemic diseases like psoriasis, eczema, Crohn’s disease, Behçet’s disease, vitiligo, and seborrheic der-matitis may also involve the vulvar skin.Leukoplakias. There are three types of leukoplakia, a flat white abnormality. Lichen sclerosis is the most common cause of leukoplakia.12 There are two peaks of onset: prepubertal girls and perimenopausal or postmenopausal women.13 Classically, it results in a figure-of-eight pattern of white epithelium around the anus and vulva resulting in variable scarring and itching, and less commonly pain. Diagnosis is confirmed with biopsy, and treatment consists of topical steroids. An established association between lichen sclerosis and vulvar squamous cell carcinoma estimates risk of malignant transformation up to 5%.13Lichen planus is a cause of leukoplakia with an onset in the fifth and sixth decade of life. Lichen planus, in contrast to lichen sclerosis which is limited to the vulva and perianal skin, can involve the vagina and oral mucosa, and erosions occur in the majority of patients leading to a variable degree of scarring. Patients usually have a history and dysuria and dyspareunia, and complain of a burning vulvar pain. Histology is not specific, and biopsy is recommended. Treatment is with topical steroids. Systemic steroids are indicated for severe and/or unresponsive cases.Lichen simplex chronicus is the third cause of leukoplakia, but is distinguished from the other lichen diseases by epidermal thickening, absence of scarring, and a severe intolerable itch.13 Intense scratching is common, and contributes to the severity of the symptoms and predisposes the cracked skin to infections. Treatment consists of cessation of the scratching which some-times requires sedation, elimination of any allergen or irritant, suppression of inflammation with potent steroid ointments, and treatment of any coexisting infections.Bartholin’s Cyst or Abscess. Bartholin’s glands, great ves-tibular glands, are located at the vaginal orifice at the four and eight o’clock positions; they are rarely palpable in normal patients. They are lined with cuboidal epithelium and secrete mucoid material to keep the vulva moist. Their ducts are lined with transitional epithelium, and their obstruction secondary to inflammation may lead to the development of a Bartholin’s cyst or abscess. Bartholin’s cysts or abscesses are usually symptom-atic and are easily diagnosed on examination. Infections are usu-ally polymicrobial. Treatment consists of incision and drainage and placement of a Word catheter, a small catheter with a bal-loon tip, for 2 to 3 weeks to allow for formation and epitheliali-zation of a new duct. Recurrent cysts or abscesses may require marsupialization, but on occasion these necessitate excision of the whole gland. Marsupialization is performed by incising the cyst or abscess wall and securing its lining to the skin edges with interrupted sutures.14 Cysts or abscesses that fail to resolve after drainage and those occurring in patients over 40 years old should be biopsied to exclude malignancy.Molluscum Contagiosum. Molluscum contagiosum presents with dome-shaped papules and are caused by the poxvirus. The papules are usually 2 to 5 mm in diameter and classically have a central umbilication. They are spread by direct skin contact, and present on the vulva, as well as abdomen, trunk, arms, and thighs. Lesions typically clear in several months, but they can be treated with cryotherapy, curettage, or cantharidin, a topical blistering agent.Genital Ulcers. The frequency of the infectious etiologies of genital ulcers varies by geographic location. The most common causes of sexually transmitted genital ulcers in young adults in the United States are, in descending order of prevalence, herpes simplex virus (HSV), syphilis, and chancroid.15 Other infec-tious causes of genital ulcers include lymphogranuloma vene-reum and granuloma inguinale. Noninfectious etiologies include Behçet’s disease, neoplasms, and trauma. Table 41-3 outlines a rational approach to their evaluation and diagnosis.3Brunicardi_Ch41_p1783-p1826.indd 179118/02/19 4:34 PM 1792SPECIFIC CONSIDERATIONSPART IIVulvar Condyloma. Condylomata acuminata (anogenital warts) are viral infections caused by HPV.16 Genital infection with HPV is the most common sexually transmitted infection in the United States today. HPV 6 and 11 are the most common low-risk types and are implicated in 90% of cases of genital warts.17 Women with immunosuppression due to HIV or solid organ transplant are at higher risk of vulvar condyloma than immunocompetent women.18,19 Genital warts are skin-colored or pink and range from smooth flattened papules to verrucous papilliform lesions. Lesions may be single or multiple and extensive. Diagnosis should be confirmed with biopsy as verru-cous vulvar cancers can be mistaken for condylomata.20 If small, self-administered topical imiquimod 5% cream or trichloroace-tic acid for in-office applications may be tried. Extensive lesions may require surgical modalities that include cryotherapy, laser ablation, cauterization, and surgical excision.Paget’s Disease of the Vulva. Paget’s disease of the vulva is an intraepithelial disease of unknown etiology that affects Table 41-3Clinical features of genital ulcers syndromes HERPESSYPHILISCHANCROIDLYMPHOGRANULOMA VENEREUMGRANULOMA INGUINALE (DONOVANOSIS)PathogenHSV type 2 and less commonly HSV type 1Treponema palladiumHaemophilus ducreyiChlamydia trachomatis L1-L3Calymmato-bacterium granulomatisIncubation period2–7 days2–4 weeks (1–12 weeks)1–14 days3 days–6 weeks1–4 weeks (up to 6 months)Primary lesionVesiclePapulePapule or pustulePapule, pustule, or vesiclePapuleNumber of lesionsMultiple, may coalesceUsually oneUsually multiple, may coalesceUsually oneVariableDiameter (mm)1–25–152–202–10VariableEdgesErythematousSharply demarcated, elevated, round, or ovalUndermined, ragged, irregularElevated, round, or ovalElevated, irregularDepthSuperficialSuperficial or deepExcavatedSuperficial or deepElevatedBaseSerous, erythematousSmooth, nonpurulentPurulentVariableRed and rough (“beefy”)IndurationNoneFirmSoftOccasionally firmFirmPainCommonUnusualUsually very tenderVariableUncommonLymph-adenopathyFirm, tender, often bilateralFirm, nontender, bilateralTender, may suppate, usually unilateralTender, may suppurate, loculated, usually unilateralPseudo-adenopathyTreatmentacyclovir (ACV) 400 mg POI three times a day for 7–10 days for primary infection and 400 mg PO three times a day for 5 days for episodic managementPrimary, secondary, and early latent (<1 year): benzathine PCN-G 2.4 million U IM × 1Late latent (>1 year) and latent of unknown duration: benzathine PCN-G 2.4 million units IM every week × 3azithromycin 1 g po or ceftriaxone 250 mg IM × 1 OR Ciprofloxacin 500 mg po twice a day for 3 daysErythromycin base 500 mg po three times a day for 7 daysDoxycycline 100 mg po twice a day × 21 days ORErythromycin base 500 mg po four times a day for 21 daysDoxycycline 100 mg po twice a day for 3 weeks until all lesions have healedSuppressionacyclovir 400 mg po twice a day for those with frequent outbreaks    Data from Stenchever M, Droegemueller W, Herbst A, et al: Comprehensive Gynecology, 4th ed. St Louis, MO: Elsevier/Mosby; 2001.Brunicardi_Ch41_p1783-p1826.indd 179218/02/19 4:34 PM 1793GYNECOLOGYCHAPTER 41mostly postmenopausal women in their sixth decade of life. It causes chronic vulvar itching and is sometimes associated with an underlying invasive vulvar adenocarcinoma or invasive cancers of the breast, cervix, or gastrointestinal tract. Grossly, the lesion is variable but usually confluent, raised, erythema-tous to violet, and waxy in appearance. Biopsy is required for diagnosis; the disease is intraepithelial and characterized by Paget’s cells with large pale cytoplasm. Treatment is assess-ment for other potential concurrent adenocarcinomas and then surgical removal by wide local resection of the involved area with a 2-cm margin. Free margins are difficult to obtain because the disease usually extends beyond the clinically visible area.21 Intraoperative frozen section of the margins can be done; how-ever, Paget’s vulvar lesions have a high likelihood of recurrence even after securing negative resection margins.Vulvar Intraepithelial Neoplasia.  Two pathologically dis-tinct premalignant lesions of the vulva are currently recog-nized. Vulvar intraepithelial neoplasia (VIN) of usual type (uVIN) is caused by the HPV virus, tends to occur in younger women, and presents as multifocal disease. VIN of differenti-ated type (dVIN) develops independently of HPV and is typi-cally unifocal and seen in postmenopausal women. VIN is similar to its cervical intraepithelial neoplasia (CIN) counterpart in the cervix. In 2012, the pathologic terminology of HPV-related disease in the anogenital region was harmonized into a two-tier system where LSIL is equivalent to uVIN 1 and HSIL encompasses uVIN 2 and uVIN 3.22 Additional risk factors for the development of VIN include HIV infection, immunosup-pression, smoking, vulvar dermatoses such as lichen sclerosis, CIN, and a history of cervical cancer. Vulvar pruritus is the most common complaint in women with symptoms. Lesions may be vague or raised, and they may be velvety with sharply demar-cated borders. Diagnosis is made with a vulvar skin biopsy and multiple biopsies are sometimes necessary. Evaluation of the perianal and anal area is important as the disease may involve these areas. Once invasive disease is ruled out, treatment usually involves wide surgical excision; however, the treatment approaches may also include 5% imiquimod cream, CO2 laser ablation, or cavitational ultrasonic surgical aspiration (CUSA), and depends on the number of lesions and their severity. When laser ablation is used, a 1-mm depth in hair-free areas is usually sufficient, while hairy lesions require ablation to a 3-mm depth because the hair follicles’ roots can reach a depth of 2.5 mm. Unfortunately, VIN tends to recur in up to 30% of cases, and high-grade lesions will progress to invasive disease in approxi-mately 10% of patients if left untreated.23Vaginal LesionsVaginitis (see Table 41-2). Vulvovaginal symptoms are extremely common, accounting for over 10 million office visits per year in the United States. The causes of vaginal complaints are commonly infectious in origin, but they include a number of noninfectious causes, such as chemicals or irritants, hormone deficiency, foreign bodies, systemic diseases, and malignancy. Symptoms include abnormal vaginal discharge, pruritus, irrita-tion, burning, odor, dyspareunia, bleeding, and ulcers. A puru-lent discharge from the cervix should always raise suspicion of upper genital tract infection even in the absence of pelvic pain or other signs.Normal vaginal discharge is white or transparent, thick, and mostly odorless. It increases during pregnancy, with use of estrogen-progestin contraceptives, or at mid-cycle around the time of ovulation. Complaints of foul odor and abnormal vaginal discharge should be investigated. Candidiasis, bacte-rial vaginosis, and trichomoniasis account for 90% of vaginitis cases. The initial workup includes pelvic examination, vagi-nal pH testing, microscopy, vaginal cultures if microscopy is normal, and gonorrhea/Chlamydia NAAT (see earlier section, “Common Screening and Testing”).24 The pH of normal vaginal secretions is 3.8 to 4.4, which is hostile to growth of pathogens, and pH greater than or equal to 4.9 is indicative of a bacterial or protozoal infection. Treatment of vaginal infection before anticipated surgery is appropriate, particularly for BV, which may be associated with a higher risk for vaginal cuff infections (Fig. 41-8).Bacterial Vaginosis Bacterial vaginosis (BV) accounts for 50% of vaginal infections. It results from reduction in concentration of the normally dominant lactobacilli and increase in concentration of anaerobic organisms like Gardnerella vaginalis, M hominis, Bacteroides species, and others.25 Diagnosis is made by microscopic demonstration of clue cells. The discharge typically produces a fishy odor upon addition of KOH (amine or Whiff test). Initial treatment is usually a 7-day course of metronidazole.Vulvovaginal Candidiasis Vulvovaginal candidiasis (VVC) is the most common cause of vulvar pruritus. It is generally caused by C albicans and occasionally by other Candida species. It is common in pregnancy, diabetics, patients taking antibiotics, and in immunocompromised hosts. Initial treatment is usually with topical antifungals, although one dose oral antifungal treatments is also effective.Trichomonas Vaginalis Trichomoniasis is a sexually transmit-ted infection of a flagellated protozoan and can present with malodorous, purulent discharge. It is typically diagnosed with visualization of the trichomonads during saline wet mount microscopy. Initial treatment is usually a 7-day course of metronidazole.Gartner’s Duct Cyst. A Gartner’s duct cyst is a remnant of the Wolffian tract; it is typically found on the lateral vaginal walls. Patients can be asymptomatic or present with complaints of dyspareunia or difficulty inserting a tampon. If symptom-atic, these cysts may be surgically excised or marsupialized. If surgery is planned, preoperative magnetic resonance imaging (MRI) should be obtained to determine the extent of the cyst and verify the diagnosis.Vaginal Condyloma. The etiology and treatment of vaginal condyloma is similar to vulvar condyloma (see earlier section, “Vulvar Condyloma”).Vaginal Intraepithelial Neoplasia. Vaginal intraepithelial neoplasia, or VaIN, is similar to VIN and is classified based on the degree of epithelial involvement as mild (I), moderate (II), severe (III), or carcinoma in situ.26 Upwards of 65% to 80% of VaIN or vaginal cancers are associated with HPV infection. Typically, a patient will have a history of cervical dysplasia and a prior hysterectomy. The majority of lesions are located in the upper one-third of the vagina. Lesions are usually asymptomatic and found incidentally on cytological screening. Biopsy at the time of colposcopy is diagnostic and rules out invasive disease. VaIN is treated with laser ablation, surgical excision, or topical 5-FU therapy.4Brunicardi_Ch41_p1783-p1826.indd 179318/02/19 4:34 PM 1794SPECIFIC CONSIDERATIONSPART IICervical LesionsBenign Cervical Lesions. Benign lesions of the cervix include endocervical polyps, nabothian cysts (clear, fluid filled cysts with smooth surfaces), trauma (such as delivery-related cervi-cal tear or prior cervical surgery), malformation of the cervix, and cervical condyloma. For endocervical polyps, exploration of the base of the polyp with a cotton swab tip to identify that it is cervical and not uterine and to identify the stalk characteris-tics can help identify the appropriate surgical approach. Small polyps with identifiable base can be removed by grasping the polyp with ring forceps and slowly rotating it until separated from its base. Use of loop electroexcisional procedure (LEEP) is appropriate for larger lesions. Laser or other ablative procedures are appropriate for condyloma proven by biopsy.Cervical Intraepithelial Neoplasia. Following HPV expo-sure, dysplastic changes are common. Low grade dysplasia (cer-vical intraepithelial neoplasia [CIN] I) can be observed and will most often regress to normal within 2 years. However, for girls or women in whom HPV infection is persistent, progression to high-grade cervical dysplasia (CIN II or III) usually require additional treatment due to the high risk of transformation to malignancy. Excisional procedures serve the therapeutic pur-pose of removal of dysplastic cells, and a diagnostic purpose as histologic review to rule out concomitant early stage cervical cancer can be performed. Either a LEEP or cold knife conization (CKC) may be used for surgical excision of the squamocolum-nar junction (SCJ) and outer endocervical canal. Risks of both procedures include bleeding, postprocedure infection, cervical stenosis, and risk of preterm delivery with subsequent pregnan-cies. The benefit of a LEEP is that it can be performed in the office under local anesthesia. A looped wire attachment for a standard monopolar electrosurgical unit is used to perform a LEEP excision. Loops range in a variety of shapes and sizes to accommodate different sizes of cervix. Optimally, one pass of the loop should excise the entire SCJ. Hemostasis of the remain-ing cervix is achieved with the ball electrode and ferrous sulfate paste (Monsel’s solution).A cervical cold knife conization allows for an excision where the margin status is not obscured by cauterized artifact. This may be particularly useful when the endocervical margin is of interest, or in cases of adenocarcinoma in situ and microin-vasive squamous cell carcinoma, where margin status dictates the type and need for future therapy. After injection with dilute vasopressin and the placement of stay sutures at three and nine o’clock on the cervix, a #11 blade is used to circumferentially excise the conical biopsy. Hemostasis is achieved with the cau-tery or Monsel’s solution.Uterine CorpusThe average age of menarche, or first menstrual period, in the United States is 12 years and 5 months. Duration of normal menstruation is between 2 to 7 days, with a flow of less than 80 mL, cycling every 21 to 35 days.27 Nonpregnant patients, who present with heavy bleeding and are 35 years of age and older or have risk factors for endometrial cancer, must be ruled out for malignancy as the first step in their management (see earlier section, “Endometrial Biopsy”).Abnormal Uterine Bleeding. The classification of abnormal uterine bleeding (AUB) has been recently updated.28 Abnormal uterine bleeding may be heavy (AUB/HMB) or intermenstrual (AUB/IMB) and is further divided into acute and chronic cat-egories. Acute AUB is an episode of heavy bleeding that is of sufficient quantity to require immediate intervention to pre-vent further blood loss. Acute AUB may occur in the setting of chronic AUB. Women with acute AUB should be assessed Vaginal dischargeand/or pruritusInterviewExamWet & KOH mountsVaginal pHMetronidazoleorClindamycinCandidiasisAntifungalsTrichomoniasispH <4.5HyphaeBudding yeastspH >4.5TrichomonadspH >4.5Clue cellsPositive whiff testUlcersPruritic lesionsVaginalatrophyAtrophic vaginitisTopical estrogenBiopsyOral metronidazoleBacterialvaginosisFigure 41-8. Treatment algorithm for vulvovaginitis.Brunicardi_Ch41_p1783-p1826.indd 179418/02/19 4:34 PM 1795GYNECOLOGYCHAPTER 41rapidly to determine acuity, determine most the likely etiol-ogy of bleeding, and choose the appropriate treatment. Chronic AUB is abnormal uterine bleeding present for most of the previ-ous 6 months.The many causes of AUB are further divided into two cat-egories: structural causes and nonstructural causes. Structural causes include polyps, adenomyosis, leiomyomata, and malig-nancy. Nonstructural causes can include coagulopathy, ovulatory dysfunction, endometrial effects, and iatrogenic causes. Clini-cal screening for underlying disorders of hemostasis is recom-mended in women with heavy menses since menarche, and other risk factors such as bleeding with dental work, epistaxis one or more times per month, or a family history of bleeding symptoms. Poly-, oligo-, and amenorrhea are menstrual cycles of less than 21 days, longer than 35 days, or the absence of uterine bleeding for 6 months or a period equivalent to three missed cycles.Endometrial Polyps. Endometrial polyps are localized hyper-plastic growth of endometrial glands and stroma around a vas-cular core forming sessile or pedunculated projections from the surface of the endometrium.29 Endometrial polyps are rarely neo-plastic (<1%) and may be single or multiple. Many are asymp-tomatic; however, they are responsible for about 25% of cases of abnormal uterine bleeding, usually metrorrhagia. Polyps are common in patients on tamoxifen therapy and in periand post-menopausal women. Up to 2.5% of patients with a polyp may harbor foci of endometrial carcinoma.30 Diagnosis can be made with saline-infused hysterosonography, hysterosalpingogram, or by direct visualization at the time of hysteroscopy. Defini-tive treatment, in the absence of malignancy, involves resection with operative hysteroscopy or by sharp curettage.Adenomyosis. Adenomyosis refers to ectopic endometrial glands and stroma situated within the myometrium. When dif-fuse, it results in globular uterine enlargement secondary to hyperplasia and hypertrophy of the surrounding myometrium. Adenomyosis is very common, tends to occur in parous women, and is frequently an incidental finding at the time of surgery. Symptoms include menorrhagia, dysmenorrhea, and diffuse globular uterine enlargement. MRI typically reveals islands within the myometrium with increased signal intensity.31 Defini-tive diagnosis is obtained via hysterectomy and pathologic examination.Uterine Leiomyomas. Leiomyomas, also known colloqui-ally as fibroids, are the most common female pelvic tumor and occurs in response to growth of the uterine smooth muscle cells (myometrium). They are common in the reproductive years, and by age 50. Leiomyomas are described according to their anatomic location (Fig. 41-9) as intramural, subserosal, submu-cosal, pedunculated, and cervical. Rarely, they can be ectopic.27 Most are asymptomatic; however, abnormal uterine bleeding caused by leiomyomas is the most common indication for hys-terectomy in the United States. Other manifestations include pain, pregnancy complications, and infertility. Pain may result from degenerating myomas that outgrow their blood supply or from compression of other pelvic organs such as the bowel, bladder, and ureters. Hormonal changes during pregnancy can cause significant enlargement of preexisting myomas, which may lead to significant distortion of the uterine cavity resulting in recurrent miscarriages, fetal malpresentations, intrauterine growth restriction, obstruction of labor or abnormal placenta-tion, and the subsequent need for cesarean delivery, abruption, preterm labor, and pain from degeneration.SubserousPedunculatedSubmucousProlapsedIntercavitaryIntramuralFigure 41-9. Types of uterine myomas.Menorrhagia resulting from leiomyomas can be severe at times, requiring hospitalization or transfusion. Examination typically reveals an enlarged and irregular uterus. Diagnosis is usually made by transvaginal ultrasonography. Other diagnos-tic modalities, including MRI, computed tomography (CT), and hysterosalpingogram or saline-infused hysterosalpingography, are especially useful in the cases of submucosal and intrauterine myomas. Management options of leiomyomas are tailored to the individual patient depending on her age and desire for fertil-ity and the size, location, and symptoms of the myomas. Con-servative management options include oral contraceptive pills (OCPs), medroxyprogesterone acetate, GnRH agonists, uterine artery embolization, myomectomy, and hysterectomy.32-34 Uter-ine artery embolization is contraindicated in patients planning future pregnancy and may result in acute degeneration of myo-mas requiring hospitalization for pain control. Myomectomy is indicated in patients with infertility thought secondary to fibroids and for those with symptomatic fibroids who wish to preserve their reproductive capacity. Hysterectomy is the only definitive therapy. Treatment with GnRH agonists for 3 months prior to surgery may be administered in anemic patients, and it may allow them time to normalize their hematocrit, avoiding transfusions; GnRH also decreases blood loss at hysterectomy and shrinks the myomas by an average of 30%. The latter may make the preferred vaginal surgical approach more feasible.Endometrial Hyperplasia. Endometrial hyperplasia is caused by chronic unopposed hyperestrogenic state (relative absence of progesterone) and is characterized by proliferation of endo-metrial glands resulting in increased gland-to-stroma ratio. It can be asymptomatic or, more commonly, result in abnormal vaginal bleeding. Hyperplasia can be either simple or complex, based on the architecture of the glands. Of greater importance is the presence or absence of nuclear atypia, described by the WHO classification.35 A classic retrospective review suggested that untreated endometrial hyperplasia progresses to malig-nancy in 1%, 3%, 8%, and 29% of cases of simple, complex, simple with atypia, and complex hyperplasia with atypia, respectively.36 A more modern prospective study noted that of patients who had complex atypical hyperplasia on endometrial biopsy performed prior to hysterectomy, 42.5% had cancer at the time of hysterectomy.37 Simple and complex hyperplasias can be treated with progestins, and women should have repeat Brunicardi_Ch41_p1783-p1826.indd 179518/02/19 4:34 PM 1796SPECIFIC CONSIDERATIONSPART IIendometrial sampling in 3 to 6 months. Atypical hyperplasia is considered a premalignant condition and is treated ideally with simple hysterectomy. If preservation of fertility is desired or surgery is contraindicated, treatment with high-dose progestins such as megesterol acetate 40 to 160 mg per day or with a pro-gesterone IUD usually reverses these lesions. Close follow-up and repeated sampling are necessary.The reliability of the pathologic diagnosis of complex atypical hyperplasia is poor, and better and more objective clas-sifications predictive of malignant endometrial behavior are needed.38 These observations led to the new classification of endometrial intraepithelial neoplasia (EIN). In 2014, the WHO Classification system introduced the diagnosis of EIN into a binary system that aligns with clinical options: hyperplasias are divided into hyperplasia without atypia, and EIN. The new clas-sification is intended to have clinical implications: hyperplasia without atypia may be managed with hormonal therapy, while EIN should be considered a premalignant lesion.The new classification moves the focus away from cyto-logic atypia and puts more emphasis on glandular crowding and complexity. While atypia is still important, proliferations can get to EIN without it. For example, the diagnosis of EIN includes cases that lack overt cytologic atypia but show a distinct popu-lation from the background epithelium. Morphometric data is utilized to calculate the so-called D-score, which takes into account percentage of stroma, glandular complexity, and gland pleomorphism in an objective manner. A D-score of less than 1 connotes a high rate of progression to endometrial cancer and therefore a diagnosis of EIN. EIN is more predictive than CAH of underlying endometrial malignancy.39 Most pathology reports are provided with both diagnoses as the transition is made.Clinicians should be careful to not confuse EIN with endometrial intraepithelial carcinoma (EIC). EIC is a precursor lesion for serous endometrial cancer, and women with a preop-erative diagnosis of EIC should always have hysterectomy and appropriate surgical staging performed.Procedures Performed for Structural Causes of Abnormal Uterine BleedingDilation and Curettage. The patient is placed on the operat-ing table in a lithotomy position, and the vagina and cervix are prepared as for any vaginal operation. The cervix is grasped on the anterior lip with a tenaculum. Some traction on the cervix is necessary to straighten the cervical canal and the uterine cavity. A uterine sound is inserted into the uterine cavity, and the depth of the uterus is noted. The cervical canal is then systematically dilated beginning with a small cervical dilator. Most operations can be performed after the cervix is dilated to accommodate a number 8 or 9 Hegar dilator or its equivalent. Dilatation is accomplished by firm, constant pressure with a dilator directed in the axis of the uterus (Fig. 41-10). The endometrial cavity is then systemically scraped with a uterine curette. Using the larg-est curette available or suction curettage is a safer choice than a small curette, which tends to cause perforation with less pres-sure. Uterine perforation is the major complication of dilatation and curettage, diagnosed when the operator finds no resistance to a dilator or curette. Laparoscopy can identify any damage to vessels or bowel if clinically indicated. A uterine perforation through the fundus of the uterus with a dilator or uterine sound is low risk for injury and may be observed without laparoscopy if there is no significant vaginal bleeding noted.CommonductstonesearcherBACFigure 41-10. Dilatation and curettage of the uterus.Brunicardi_Ch41_p1783-p1826.indd 179618/02/19 4:34 PM 1797GYNECOLOGYCHAPTER 41Hysteroscopy. Hysteroscopy, like laparoscopy, has gained widespread support for use both for diagnosis and treatment of intrauterine pathology and for ablation of the endometrium as an alternative to hysterectomy for the treatment of abnormal uterine bleeding. Hysteroscopes can have an objective lens that is offset from the long axis from 0° to 30°.Diagnostic Hysteroscopy The diagnostic hysteroscope usu-ally has an external diameter of 5 mm. Some diagnostic sheaths allow passage of flexible instruments for biopsy and cutting. Following dilation of the cervix, a diagnostic hysteroscope is placed, and the uterine cavity is distended with the media of choice. Inspection of the cavity includes identifying the uter-ine fundus, cornua, and any other anomalies to include polyps, leiomyomas, or uterine septum. A dilation and curettage or directed polypectomy with forceps can be performed following identification.Newer office hysteroscopes can be used to perform hyster-oscopy in the office. A paracervical block is placed, and a flex-ible 3-mm hysteroscope is used. Generally, office hysteroscopy is performed only for diagnostic purposes.Operative Hysteroscopy An operative hysteroscope is wider than a diagnostic hysteroscope and usually has an inte-gral unipolar or bipolar resecting loop identical to a urologic resectoscope. Electrolyte contacting media are incompatible with conventional monopolar resectocopic instruments, but electrolyte-free isotonic solutions such as 5% mannitol, 1.5% glycine and 3% sorbitol are acceptable. Large volume deficits have been associated with secondary hyponatremic hypervol-emia due to their metabolism to free water after intravasation. Fluid-management systems are available to monitor the amount of distension media lost during hysteroscopy in order to prevent fluid overload. When fluid deficits reach 1000 to 1500 mL, the procedure should be terminated, and the patient’s serum elec-trolytes should be assessed.40 If bipolar instruments are used, resectoscopic instruments can be used without the unique issues related to electrolyte-free hypotonic solutions.43Hysteroscopic Polypectomy Removal of an intrauterine polyp can be performed following diagnostic hysteroscopy through grasping with a polyp forceps. Alternatively, using operative hysteroscopy the base of the polyp is incised with hysteroscopic scissors. The hysteroscope, sleeve, and polyp are removed simultaneously because most polyps will not fit through the operating channel. Extremely large polyps may have to be removed piecemeal. Any residual base of the polyp may be removed with biopsy forceps.Endometrial Ablation A common treatment for abnormal uterine bleeding in the absence of endometrial hyperplasia is ablation of the endometrium. Historically, this was performed with an operative hysteroscope using an electrosurgical “roller ball,” where the endometrium was destroyed down to the myo-metrium in a systematic fashion. Currently, hysteroscopic endo-metrial ablation has been widely supplanted by various devices, including heated free fluid, cryotherapy, thermal balloon, microwave, and radiofrequency electricity. Most ablation tech-niques result in amenorrhea in approximately half the patients and decreased menstruation in another third of the patients over the first year of therapy.42 Subsequent hysterectomy fol-lowing endometrial ablation is common with rates as high as 40%.43Ablation is not recommended in postmenopausal women.Myomectomy Myomectomy (Fig. 41-11) is the removal of fibroids, and it can be treatment for abnormal uterine bleeding, bulk symptoms, or infertility. Hemostasis during myomectomy can be aided medically by direct injection of dilute vasopressin. Submucosal leiomyoma can be removed safely hysteroscopi-cally. Because myoma tissue is relatively dense, a power cut-ting instrument is required. The most common method is use of electrosurgery. Both pedunculated and submucosal fibroids are shaved into small pieces with the hysteroresectoscope. Stalk resection should only be done to release a pedunculated fibroid if it is 10 mm or less in size; larger fibroids are difficult to remove in one piece without excessive cervical dilatation.44Subserosal, or pedunculated fibroids may require an open or laparoscopic approach depending on the size and location or the leiomyoma. In addition to vasopressin, hemostasis can be further managed through the placement of a Penrose drain around the base of the uterus, pulled through small perforations in the broad ligament lateral to the uterine blood supply on either side and clamped to form a tourniquet for uterine blood flow. An incision is then made through the uterine serosa into the myoma. The pseudocapsule surrounding the tumor is identified, and the tumor is bluntly dissected out with scissors, or bluntly if open. Vessels to the myoma are dessicated with the electrosurgical unit. Several myomas may be removed through a single incision, depending upon size. The uterine incisions are then closed with absorbable sutures to obliterate the dead space and provide hemostasis. The uterine serosa is closed with a 3-0 absorbable suture, placed subserosally if possible. Because myomectomies are associated with considerable postoperative adhesion formation, barrier techniques are used to decrease adhesion formation.During a laparoscopic myomectomy, hemostasis is assisted by intrauterine injection of dilute vasopressin (10 U in 50 mL) at the site of incision, similar to an open procedure. This is usually performed percutaneously with a spinal needle. Pedunculated leiomyomas can be excised at the base using scissors or a power instrument. Intramural leiomyomas require deep dissection into the uterine tissue, which must be closed subsequently with laparoscopic suturing techniques. Removing the specimen may require morcellation; this should be performed after placement of the specimen in a bag. Although power morcellators were previously used for this purpose, an FDA warning in 2014 has virtually eliminated their use. Severe complications including damage to surrounding bowels and vascular structures caused by the spinning blade of the morcellator were reported. Multiple reports of benign tissues such as leiomyoma and endometriosis scattering and dispersing onto abdominal organ surfaces lead-ing to inflammation, infection, and intestinal obstruction often requiring additional surgical interventions and treatments were made. The unintentional dissemination of malignant cells wors-ens prognosis if an undiagnosed malignancy (most frequently leiomyosarcoma) was morcellated. Although contained morcel-lation (in a bag) may reduce these risks, informed consent to the patient is prudent.45Total Abdominal Hysterectomy (Fig. 41-12) After the abdomen is entered, the upper abdomen is examined for evi-dence of extrapelvic disease, and a suitable retractor is placed in the abdominal incision. The uterus is grasped at either cornu with clamps and pulled up into the incision. The round ligament is identified and divided. The peritoneal incision is extended from the round ligament to just past the ovarian hilum, lat-eral the infundibulopelvic ligament, if the ovaries are to be removed. The retroperitoneal space is bluntly opened, the ure-ter identified on the medial leaf of the broad ligament, and the Brunicardi_Ch41_p1783-p1826.indd 179718/02/19 4:34 PM 1798SPECIFIC CONSIDERATIONSPART IIinfundibulopelvic ligament isolated, clamped, cut, and suture-ligated; a similar procedure is carried out on the opposite side. If the ovaries are to be left in situ, the ureter is identified and an opening below the utero-ovarian ligament and fallopian tube created. The fallopian tube and utero-ovarian ligament are clamped, cut, and ligated. The bladder is mobilized by sharply dissecting it free of the anterior surface of the uterus and cervix. Clamps are placed on the uterine vessels at the cervicouterine junction, and the vessels are cut and suture-ligated. The cardinal ligaments are then serially clamped, cut, and ligated. Follow-ing division of the remaining cardinal ligaments, the uterus is elevated and the vagina clamped. The cervix is amputated from the vagina with scissors or a knife. Sutures are placed at each lateral angle of the vagina, and the remainder of the vagina is closed with a running or interrupted absorbable suture. Pelvic reperitonealization is not necessary.Transvaginal Hysterectomy (Fig. 41-13) Vaginal hysterectomy is the preferred approach in patients in whom the uterus descends and the pubic arch allows enough space for a vaginal operation. A bladder catheter can be placed before the procedure and the patient is placed in a lithotomy position. A weighted vaginal speculum is placed in the vagina, and the cervix is grasped with a tenaculum and pulled in the axis of the vagina. Injection of the cervix and paracervical tissue with analgesic with epinephrine may be helpful in defining planes and decreasing obscuring bleeding. A circumferential incision may be made with a scalpel or scissors. The posterior cul-de-sac is identified and entered with scissors. A long, weighted speculum is then placed through this opening into the peritoneal cavity. Metzenbaum scissors are used to dissect anteriorly on the cervix down to the pubocervical-vesical fascia, reflecting the bladder off the lower uterine segment. When the peritoneum of the anterior cul-de-sac is identified, it is entered with the scissors, and a retractor is placed in the defect. The uterosacral ligaments are identified, doubly clamped, cut, and ligated. Serial clamps are placed on the parametrial structures above the uterosacral ligament; these pedicles are cut and ligated. At the cornu of the uterus, the tube, round ligament, and utero-ovarian ligament of the ovary are doubly clamped and cut. The procedure is carried out usually concurrently on the opposite side, and the uterus is removed. The pelvis is inspected for hemostasis; all bleeding must be meticulously controlled at this point.The pelvic peritoneum is closed with a running purse-string suture incorporating the uterosacral and ovarian pedicles, those that were held. This exteriorizes those areas that might tend to bleed. The sutures attached to the ovarian pedicles are cut. The vagina may be closed with interrupted mattress stitches, ABCDEFFigure 41-11. Myomectomy.Brunicardi_Ch41_p1783-p1826.indd 179818/02/19 4:34 PM 1799GYNECOLOGYCHAPTER 41Figure 41-12. Hysterectomy.BladderBladderRound ligamentRound ligamentFallopian tubeFallopian tubeOvaryBADCFEOvarian ligamentUterinevesselsUreterUreterCardinalligamentUterusBrunicardi_Ch41_p1783-p1826.indd 179918/02/19 4:34 PM 1800SPECIFIC CONSIDERATIONSPART IIincorporating the uterosacral ligaments into the corner of the vagina with each lateral stitch. On occasion, the uterus, which is initially too large to remove vaginally, may be reduced in size by morcellation (Fig. 41-14). After the uterine vessels have been clamped and ligated, serial wedges are taken from the central portion of the uterus in order to reduce the uterine mass. This procedure will allow the vaginal delivery of even very large uterine leiomyomas.Laparoscopic Hysterectomy The advantages of laparoscopy over laparotomy include decreased postoperative pain, shorter hospital stays, and reduced blood loss. Laparoscopy has been used to augment vaginal hysterectomy to avoid laparotomy in patients with known pelvic adhesions, endometriosis, or to ensure removal of the entire ovary if oophorectomy is planned or an adnexal mass is present. Over 20% of benign hysterec-tomies performed in the United States are estimated to be per-formed laparoscopically.46Although multiple variations in technique exist, there are three basic laparoscopic approaches for hysterectomy: lapa-roscopic-assisted vaginal hysterectomy (LAVH), total lapa-roscopic hysterectomy (TLH), and laparoscopic supracervical hysterectomy (LSH). The technically simplest is the LAVH. A multiple-port approach is used to survey the peritoneal cavity, and any pelvic adhesions are lysed. The round ligaments are then occluded and divided, and the uterovesical peritoneum and peritoneum lateral to the ovarian ligament are incised. The course of the ureter and any adhesions or implants, such as endometriosis that might place the ureter in the way of the surgical dissection, are carefully dissected. Next, the proximal uterine blood supply is dissected for identification and then occluded with a laparoscopic energy device. When the ova-ries are removed, the infundibulopelvic ligaments containing the ovarian vessels are divided. If the ovaries are conserved, the utero-ovarian ligament and blood vessels are divided and occluded. In many cases, the posterior cul-de-sac is also incised laparoscopically and the uterosacral ligaments separated with an energy device. The amount of dissection that is done prior to the vaginal portion depends on individual patient characteristics and operator comfort with the vaginal approach, and it may include as little as ovarian and adhesion management to full dissection, including bladder dissection, with only the last vaginal incision done by the vaginal approach. During a TLH, the vaginal inci-sion is performed laparoscopically, and the vaginal incision may be closed with laparoscopic suturing. This procedure is used for the indications listed earlier and also when lack of uterine descent makes the vaginal approach impossible.VaginaVaginaGIHCardinalligamentVaginaFigure 41-12. (Continued)Brunicardi_Ch41_p1783-p1826.indd 180018/02/19 4:34 PM 1801GYNECOLOGYCHAPTER 41During an LSH, the uterine vessels are divided after the bladder is dissected from the anterior uterus. The ascending branches of the uterine arteries are occluded, and the entire uterine fundus is amputated from the cervix. The endocervix is either cauterized or cored out. The fundus is then morcellated and removed an abdominal port. The end result is an intact cer-vix, with no surgical dissection performed below the uterine artery. This approach avoids both a large abdominal incision and a vaginal incision. The risks of LSH including subsequent bothersome bleeding from the remaining endometrium or endo-cervix and cancer risk from the residual cervical stump combin-ing with concerns about power morcellation (see earlier section, “Myomectomy”) have made this procedure less attractive.Benign Ovarian and Fallopian Tube LesionsThe most common ovarian benign findings include functional follicular cysts, endometriomas (due to ovarian endometriosis), and serous cystadenomas or cystadenofibromas. These can present with varying degrees or pelvic pain, or sometimes be completely asymptomatic. Ultrasound is the best initial imaging modality for evaluating ovarian abnormalities.Ovarian Cystectomy. When a cystic lesion persists or causes pelvic pain, surgical intervention is usually justified. Perform-ing a cystectomy with ovarian preservation is recommended in women who desire future fertility. Whether the cystectomy is performed laparoscopically or by laparotomy, the procedure is Figure 41-13. Vaginal hysterectomy.Brunicardi_Ch41_p1783-p1826.indd 180118/02/19 4:34 PM 1802SPECIFIC CONSIDERATIONSPART IIinitiated with inspection of the peritoneal cavity, peritoneum, diaphragm, liver, and pelvis. In the absence of signs of malig-nancy, pelvic washings are obtained, and the ovarian capsule is incised superficially sharply or with the electrosurgical unit. The cyst is shelled out carefully through the incision. During laparos-copy, it is placed in a bag, intact if possible, and the bag opening is brought through a 10-mm port. If a cyst should rupture before removal, contents are aspirated thoroughly, and the cyst wall is removed and sent for pathologic evaluation. The peritoneal cavity is copiously rinsed with Ringer’s lactate solution. This is especially important when a dermoid cyst is ruptured because the sebaceous material can cause a chemical peritonitis unless all the visible oily substance is carefully removed. A cyst may need to be drained to facilitate removal, but only after bag edges are completely out of the abdomen assuring no leakage within the abdomen. Hemostasis of the ovary is achieved with bipolar electrocoagulation, but the ovary is usually not closed. If there are solid growths within the cyst, it should be sent for frozen section to verify the absence of the malignancy. If malignancy is detected, immediate definitive surgery is recommended.Removal of Adnexa. Indications for removal of adnexae include persistent ovarian cyst, pelvic pain, concern for malig-nancy, and risk reduction surgery in women with genetic predis-position for ovarian or endometrial cancers (BRCA1/2 mutation carrier, Lynch syndrome). In general, the peritoneum lateral to the infundibulopelvic (IP) ligament is incised in a parallel fashion to allow retroperitoneal dissection and identification of the ureter. Once this has been accomplished, the IP ligament is ligated with suture or an energy source (ultrasonic or bipolar). The remaining posterior leaf of the broad ligament is incised toward the uterus in a direction parallel to the utero-ovarian liga-ment to avoid ureteral injury. The fallopian tube and utero-ovarian ligaments are then ligated with either suture or an energy source. If performed laparoscopically, the specimen(s) is/are removed in a bag as described earlier.Tubal Sterilization. As in diagnostic laparoscopy, a oneor two-port technique can be used. Fallopian tubes are occluded in the mid-isthmic section, approximately 3 cm from the cornua, using clips, elastic bands, or bipolar electrosurgery. With elec-trosurgery, approximately 2 cm of tube should be desiccated. Pregnancy rates after any of these techniques have been reported Figure 41-14. Uterine morcellation through the vagina.in the range of 3 per 1000 women. Complete removal of the fal-lopian tube (salpingectomy) at the time of tubal sterilization for the purposes of ovarian cancer prevention has recently become more common.47A transvaginal tubal occlusion technique may also be used for tubal sterilization. A routine hysteroscopy is first performed to inspect the cavity and identify the tubal ostia. The tubal insert introducer sheath is then placed into the working channel of the hysteroscope. The insert is then threaded into the fallopian tube. Following this procedure, the patient must undergo a hys-terosalpingogram to confirm tubal occlusion at 3 months post procedure. Prior to the hysterosalpingogram, the patient is coun-seled to use a reliable birth control method. Transvaginal tubal sterilization has been associated with perforation of the uterus and/or fallopian tubes, identification of inserts in the abdominal or pelvic cavity, persistent pain, and suspected allergic or hyper-sensitivity reactions.Other Benign Pelvic PathologyChronic Pelvic Pain. Chronic pelvic pain is defined as pain below the umbilicus that has lasted at least 6 months or causes functional disability, requiring treatment. While there can be gastrointestinal and urologic causes of chronic pelvic pain, gynecologic causes are frequently identified. Oftentimes, a surgical evaluation is needed for diagnosis and/or intervention. The most common gynecologic causes of chronic pelvic pain include endometriosis, adenomyosis, uterine leiomyomas, and adhesive disease.Endometriosis Endometriosis is the finding of ectopic endo-metrial glands and stroma outside the uterus. It affects 10% of the general population, and it is an incidental finding at the time of laparoscopy in more than 20% of asymptomatic women. Chronic pelvic pain (80%) and infertility (20–50%) are the two most common symptoms.27 The pathophysiology of endometrio-sis is poorly understood; etiologic theories explaining dissemi-nation of endometrial glands include retrograde menstruation, lymphatic and vascular spread of endometrial glands, and coe-lomic metaplasia. Endometriosis commonly involves the ova-ries, pelvic peritoneal surfaces, and uterosacral ligaments. Other possible sites include the rectovaginal septum, sigmoid colon, intraperitoneal organs, retroperitoneal space, ureters, incisional scars, umbilicus, and even the thoracic cavity. Involvement of the fallopian tubes may lead to scarring, blockage, and subse-quent infertility. Ovarian involvement varies from superficial implants to large complex ovarian masses called endometriomas or “chocolate cysts.” Endometriomas are found in approximately one-third of women with endometriosis and are often bilateral.While endometriosis can be totally asymptomatic, com-plaints vary from mild dyspareunia and cyclic dysmenorrhea, to debilitating chronic pelvic pain with dysmenorrhea. Less com-mon manifestations include painful defecation, hematochezia, and hematuria if there is bowel and/or bladder involvement. Catamanial pneumothorax has been reported from endometrio-sis implanted in the pleura. Pelvic examination in symptomatic patients typically demonstrates generalized pelvic tenderness, nodularity of the uterosacral ligaments, and at times a pelvic mass may be appreciated if an endometrioma is present. The severity of symptoms does not correlate with the degree of clini-cal disease present. Endometriosis commonly causes of eleva-tions in serum CA-125. Definitive diagnosis usually requires laparoscopy and visualization of the pathognomonic endome-triotic implants. These appear as blue, brown, black, white, or yellow lesions that can be raised and at times puckered giving Brunicardi_Ch41_p1783-p1826.indd 180218/02/19 4:34 PM 1803GYNECOLOGYCHAPTER 41Table 41-4Centers for Disease Control and Prevention recommended treatment of pelvic inflammatory disease (2015)RECOMMENDED INTRAMUSCULAR/ORAL REGIMENSCeftriaxone 250 mg IM in a single dosePLUSDoxycycline 100 mg orally twice a day for 14 dayswith* or withoutMetronidazole 500 mg orally twice a day for 14 daysORCefoxitin 2 g IM in a single dose and Probenecid, 1 g orally administered concurrently in a single dosePLUSDoxycycline 100 mg orally twice a day for 14 dayswith or withoutMetronidazole 500 mg orally twice a day for 14 daysOROther parenteral third-generation cephalosporin (e.g., ceftizoxime or cefotaxime)PLUSDoxycycline 100 mg orally twice a day for 14 dayswith* or withoutMetronidazole 500 mg orally twice a day for 14 daysRECOMMENDED PARENTERAL REGIMENSCefotetan 2 g IV every 12 hoursPLUSDoxycycline 100 mg orally or IV every 12 hoursORCefoxitin 2 g IV every 6 hoursPLUSDoxycycline 100 mg orally or IV every 12 hoursORClindamycin 900 mg IV every 8 hoursPLUSGentamicin loading dose IV or IM (2 mg/kg), followed by a maintenance dose (1.5 mg/kg) every 8 hours. Single daily dosing (3–5 mg/kg) can be substituted.ALTERNATIVE PARENTERAL REGIMENAmpicillin/Sulbactam 3 g IV every 6 hoursPLUSDoxycycline 100 mg orally or IV every 12 hours*The addition of metronidazole to treatment regimens with third-generation cephalosporins should be considered until the need for extended anaerobic coverage is ruled out.Data from Centers for Disease Control and Prevention. 2015 Sexually Transmitted Diseases Treatment Guidelines: Pelvic Inflammatory Disease.them a “gunpowder” appearance. Biopsy is not routinely done but should be obtained if the diagnosis is in doubt.Treatment is guided by severity of the symptoms and whether preservation of fertility is desired and varies from expectant, to medical, to surgical.48,49 Expectant management is appropriate in asymptomatic patients. Those with mild symp-toms can be managed with oral contraceptive pills and/or non-steroidal anti-inflammatory analgesia; moderate symptoms are treated with medroxyprogesterone acetate. Severe symptoms are treated with gonadotropin releasing hormone (GnRH) ago-nists to induce medical pseudomenopause.Surgical management for endometriosis varies depend-ing on the age and fertility desires of the patient. A diagnos-tic laparoscopy with biopsies may be indicated to confirm the diagnosis of endometriosis. If endometriosis is suspected, an operative laparoscopy with ablation of endometriotic implants usually decreases the severity of pelvic pain. Ablation of endo-metriotic implants can be performed with CO2 laser or elec-trocautery, and/or resection of deep endometriotic implants.48 Endometriomas can cause pain and if found should be treated by ovarian cystectomy. Complete resection of the cyst wall is required as recurrence of the endometrioma is common after partial removal. Unfortunately, endometriosis is a chronic dis-ease, and conservative therapy, medical or surgical, provides only temporary relief, with the majority of patients relapsing with 1 to 2 years. For patients with severe debilitating symp-toms who do not desire future fertility and have not responded to conservative management extirpative surgery to remove the uterus, ovaries, and fallopian tubes; this intervention is curative and should be considered.Although endometriosis is not generally thought to be a premalignant lesion, there is an increased risk of type I ovar-ian cancer in women with a history of endometriosis.50 Molecu-lar evidence that endometriosis is likely a precursor lesion to clear cell carcinoma and endometrioid carcinomas includes the presence of mutations in both PIK3CA and ARID1A in benign endometriotic lesions in close proximity, suggesting that loss of expression of these genes likely occurs early in the development of endometrioid carcinomas.51,52Pelvic Adhesive Disease Pelvic adhesions usually are related to previous surgery, endometriosis, or infection, the latter of which can be either genital (i.e., pelvic inflammatory disease) or extragenital (e.g., ruptured appendix) in origin. Adhesions can be lysed mechanically and preferably with minimal cautery.Pelvic Inflammatory Disease. Pelvic inflammatory disease (PID) is an inflammatory disorder of the upper female genital tract, including any combination of endometritis, salpingitis, tubo-ovarian abscess, and pelvic peritonitis. Sexually transmitted organisms, especially N gonorrhoeae and C trachomatis, are implicated in many cases although microorganisms that comprise the vaginal flora (e.g., anaerobes, G vaginalis, Haemophilus influenzae, enteric Gram-negative rods, and Streptococcus agalactiae) have been implicated as well. PID can additionally result from extension of other pelvic and abdominal infections, such as appendicitis and diverticulitis, or may be precipitated by medical procedure, such as hysterosalpingography, endometrial biopsy, or dilation and curettage.53,54The presentation of PID can be subtle. Differential diagnosis includes appendicitis, cholecystitis, inflammatory bowel disease, pyelonephritis, nephrolithiasis, ectopic pregnancy, and ovarian torsion. Long-term sequelae can include infertility, chronic pelvic pain, and increased risk of ectopic pregnancy. Because of the severity of these sequelae, presumptive treatment is recommended in young, sexually active women experiencing pelvic or lower abdominal pain, when no cause for the illness other than PID can be identified and if cervical motion tenderness, uterine tenderness, or adnexal tenderness is present on examination. Because of the psychosocial complexity associated with a diagnosis of PID, additional criteria should be used to enhance the specificity of the minimum clinical criteria when possible. These include the following: oral temperature >101°F (>38.3°C); abnormal cervical mucopurulent discharge or cervical friability; presence Brunicardi_Ch41_p1783-p1826.indd 180318/02/19 4:34 PM 1804SPECIFIC CONSIDERATIONSPART IIof abundant numbers of white blood cells on saline microscopy of vaginal fluid; elevated erythrocyte sedimentation rate; elevated C-reactive protein; and laboratory documentation of cervical infection with N gonorrhoeae or C trachomatis. Laparoscopy can be used to obtain a more accurate diagnosis of salpingitis and a more complete bacteriologic diagnosis and is often useful in ruling out other causes of peritonitis. Laparoscopic findings may include swollen erythematous tubes with purulent exudates.55Several outpatient parenteral and oral antimicrobial regi-mens have been effective in achieving clinical and microbio-logic cure. Hospitalization for intravenous antibiotics may be necessitated in cases of where surgical emergencies cannot be ruled out, tubo-ovarian abscess is identified, pregnancy, severe illness (nausea and vomiting, or high fever), inability to follow or tolerate an outpatient oral regimen; or failure of outpatient oral antimicrobial therapy. Treatment of a tubo-ovarian abscess may include placement of a percutaneous drain in addition to intravenous antibiotics.55Surgical intervention becomes necessary if medical therapy fails or if the patient becomes unstable. Hysterec-tomy and bilateral salpingo-oophorectomy is the procedure of choice; however, conservative surgery must be considered in young patients desiring future fertility. The abdomen should be explored for metastatic abscesses, and special attention must be paid to bowel, bladder, and ureteral safety due to the friabil-ity of the infected tissue and the adhesions commonly encoun-tered at the time of surgery. Placement of an intraperitoneal drain and mass closure of the peritoneum, muscle, and fascia with delayed-absorbable sutures is advised. Conservative sur-gery, when feasible, may be attempted by laparoscopy and may involve unilateral salpingo-oophorectomy or drainage of the abscess and liberal irrigation of the abdomen and pelvis.53PREGNANCY-RELATED SURGICAL CONDITIONSMany pregnant women will undergo invasive diagnostic proce-dures for prenatal diagnosis, and in the United States, nearly one-third of all births are cesarean deliveries.56 About 1 in 500 pregnant women will require surgery for nonob-stetrical issues.57,58 Diagnostic challenges and physiologic changes due to pregnancy, as well as the unique anesthesia risks and potential risks to the pregnancy, should be kept in mind whether the primary surgeon is an obstetrician, gynecologist, or a general surgeon (Table 41-5).58Trauma in the obstetric patient requires stabilization of the mother while considering the fetal compartment.58,59 Trauma-related hypovolemia may be compounded by pregnancy-induced decreases in systemic vascular resistance, and when supine, the weight of the gravid uterus on the vena cava. When feasible, a left lateral tilt should be instituted to improve venous return to the right heart. Later in pregnancy, the small bowel is dis-placed into the upper abdomen, making it vulnerable to complex injury from penetrating upper abdominal trauma. Though small bowel is displaced from the pelvis, the dramatic increase in pel-vic blood flow can lead to rapid blood loss due to penetrating pelvic trauma, fractures, or avulsion of pelvic vessels. Gastric motility is decreased increasing the risk of aspiration. Peritoneal signs may be attenuated by the stretching of the abdominal wall. Several coagulation factors are also increased in pregnancy, increasing the likelihood for thromboembolic events, but also giving the unsuspecting surgeon false security when low-normal levels are observed during resuscitative efforts. Only the third 5Table 41-5Physiologic changes due to pregnancyCardiovascular changes Increased cardiac output Increased blood volume Increased heart rate Decreased blood pressure Decreased systemic vascular resistance Decreased venous return from lower extremitiesRespiratory changes Increased minute ventilation Decreased functional residual capacityGastrointestinal changes Decreased gastric motility Delayed gastric emptyingCoagulation changes Increased clotting factors (II, VII, VIII, IX, X) Increased fibrinogen Increased risk for venous thromboembolismRenal changes Increased renal plasma flow and GFR Ureteral dilationReproduced with permission from Gabbe S NJ, Simpson J: Obstetrics: Normal and Problem Pregnancies, 6th ed. Philadelphia, PA: Elsevier/Saunders; 2012.trimester fetus has any ability to autoregulate in the context of decreased uterine blood flow and oxygen delivery. In the third trimester, perimortem cesarean delivery should be considered as part of maternal resuscitation in cases of maternal hemodynamic collapse. Though treating the maternal compartment is the pri-mary concern, it should also be recognized that the fetus will be impacted significantly by maternal hypotension, as blood may be shunted away from the uterus.Conditions and Procedures Performed Before ViabilityAmniocentesis/Chorionic Villus Sampling. Noninvasive prenatal testing has for the most part replaced invasive fetal testing. Amniocentesis is a procedure in which amniotic fluid is aspirated from the uterine cavity and sent for genetic or labora-tory testing typically under ultrasound guidance with a 20to 22-gauge needle. This procedure may be used to confirm abnor-mal noninvasive testing.Miscarriage and Pregnancy Terminations. Spontaneous pregnancy loss is common. Although the miscarriage rate among women who know they are pregnant is roughly 10% to 20%, if the start of pregnancy is set to fertilization, rates are as high as 50%. Chromosomal abnormalities are the underlying cause of miscarriage and are present in over half of cases. Patient may report cramping, bleeding and passage of tissue. If products of conception are not passed, diagnosis can be made by transvagi-nal ultrasound if an empty gestational sac is identified or an embryo is noted to not have a heartbeat. Treatment can include expectant management, medical management with misoprostol, or surgical management with dilation and curettage.60Half of all pregnancies in the United States are unintended, and many of these are undesired. Additional reasons for termi-nation of pregnancy include fetal anomalies such as trisomies, fetal infections, and maternal health. Medical terminations are Brunicardi_Ch41_p1783-p1826.indd 180418/02/19 4:34 PM 1805GYNECOLOGYCHAPTER 41available up to 10 weeks of gestation, and surgical terminations can be performed to viability. Rates of pregnancy termination have been declining due decreasing access to abortion ser-vices and widespread availability of long-acting contraceptives (LARC). LARCs are safe, effective, easy to use and protect against unintended pregnancy for up to 10 years.61Up to 15 weeks’ gestation, manual vacuum aspiration can be used following cervical dilation to mechanically evacuate the fetus or embryo, placenta, and membranes by suction using a manual syringe. Alternatively, cervical dilation and suction curettage can be performed. The uterine cervix is grasped with a tenaculum, then mechanically dilated occasionally using adjunc-tive prostaglandins, and an appropriately sized vacuum cannula is inserted into the uterus and rotated on its axis to remove the products of conception. Dilation and extraction is performed for pregnancies in the second trimester. The additional cervical dilation required at greater gestational ages is usually a two-step (often over 2 days) process. Osmotic dilators are placed within the cervix a day prior to the procedure and expand as water is absorbed, passively dilating the endocervical canal. These are removed immediately prior to the procedure and mechanical dilation is then performed as needed. Forceps are then used to remove fetal parts. Curettage of the postabortal uterus must be approached carefully because the uterus is extremely soft and perforation can occur with very little warning. Complications are rare (particularly when contrasted to the risks of pregnancy and term delivery) but include infection, hemorrhage due to uterine atony, cervical lacerations, uterine perforations, and inadvertent bowel injury from the vacuum cannula or forceps.Cerclage. Cervical insufficiency is defined as painless cervical dilation leading to recurrent second trimester pregnancy loss, or shortened cervical length as determined by transvaginal ultra-sound, or advanced cervical change before 24 weeks’ gestation in a woman with either prior preterm birth/loss or significant risk factors for insufficiency. A cervical cerclage refers to a procedure in which suture or synthetic tape is used to circum-ferentially reinforce the cervix to improve pregnancy outcome in at-risk patients.62 Shirodkar and McDonald techniques have been described63,64; both involve transvaginally placing a non-absorbable suture at the uterocervical junction to lengthen and close the cervix. An abdominal cerclage of the lower uterine segment performed laparoor by laparotomy can be considered for a patient with a severely shortened or absent cervix who has previously failed a transvaginal cerclage.Ectopic Pregnancies. Extrauterine pregnancies are most com-monly located along the fallopian tubes but can also implant on the ovary. Rarely, implantation can occur primarily on other abdominal organs or peritoneal surfaces. A high index of suspi-cion and early diagnosis typically includes an abnormal rise in b-hCG assays and presence of an adnexal mass on transvaginal ultrasound. Early ectopic pregnancies can be managed medi-cally with a methotrexate injection; however, close follow-up with twice-weekly b-hCG testing is required. Laparoscopy is the definitive management and can be used either as primary treatment or when medical management fails. The tube should be removed (salpingectomy) in its entirety if the ectopic is iden-tified within the fallopian tube. This can be performed using a vessel sealing device or even an endo-loop and endo-shears. Laparotomy is reserved for unstable patients with a known hemoperitoneum where Kelly clamps can be placed along the mesosalpinx to control bleeding. Cornual ectopic pregnancies may require wedge resection of the uterine serosa and myo-metrium, which is then closed in two layers.65 Linear salpin-gostomy along the antimesenteric border and removal of the products of conception is now rarely used due to low rates of postoperative tubal function and high recurrent ectopic pregnan-cies presumably due to scarring.Conditions and Procedures Performed After ViabilityObstetric Lacerations and Repair. At the time of vaginal delivery, perineal lacerations are common. These lacerations involve, in varying degrees, the vaginal mucosa, the muscular elements inserting onto the perineal body, the levator ani, and in 4% to 5% of vaginal deliveries, the anal sphincter or anorectal mucosa. Although episiotomies were historically cut prophy-lactically to prevent unstructured tearing of the perineum, this practice has fallen out of favor as the benefit of episiotomy has not been demonstrated.Perineal Laceration First-degree tears involve only the perineal skin and may or may not need to be reapproximated. Second-degree tears involve the perineal body and can gener-ally be repaired with some variation using a single continuous, nonlocking suture technique, typically a 2-0 or 3-0 synthetic delayed absorbable suture. The apex of the vaginal epithelial is approximated first including epithelium and underlying tissue to build up the rectovaginal septum. Upon reaching the hymenal ring, the perineal body and bulbocavernosus muscle are reap-proximated, and a transition stitch is placed from the vaginal mucosa, which was repaired along a horizontal plane, to the deep perineal layer, which lies in a vertically-oriented plane. A running closure is then completed incorporating the deep peri-neal tissues from the introitus to the extent of the perineal defect. At this point, the perineal skin is closed from inferior to superior in a subcuticular fashion and tied just inside the introitus.Third-degree lacerations extend through the perineal body and involve the external anal sphincter, while fourth-degree lac-erations involve the internal anal sphincter and rectal mucosa. When present, thirdand fourth-degree lacerations should be repaired first before proceeding with the second-degree repair. This is accomplished by first closing the anal mucosa, and then identifying and closing the internal anal sphincter in a second layer. The external anal sphincter is then identified, and the muscular cylinder is reconstructed by suturing the severed ends together using either an end-to-end or overlapping technique. Although these are typically straightforward layered closures, knowledge of the anatomy is important. Incomplete reconstruc-tion, particularly of thirdor fourth-degree lacerations, can contribute to future pelvic floor disorders, as well as the devel-opment of fistulae or incontinence.Cervical and Vaginal Lacerations Significant lacerations to the cervix or vagina may also occur during childbirth, particu-larly with instrumented deliveries or macrosomic infants. These lacerations may present as persistent bleeding, not readily rec-ognized due to their location, and often in association with a firmly contracted uterus. Vaginal lacerations may be repaired primarily but should only be closed after deeper tissues are inspected to insure no active bleeding. Cervical lacerations can be repaired in a running, locking fashion, insuring that the apex of the laceration is incorporated in the closure. If the apex is challenging to reach, the closure can be started more distally using the suture to apply traction so that the apex may be closed.Brunicardi_Ch41_p1783-p1826.indd 180518/02/19 4:34 PM 1806SPECIFIC CONSIDERATIONSPART IIPuerperal Hematoma Trauma during childbirth can occasion-ally result in significant hematoma formation with or without a visible laceration. These hematomas may hide significant blood loss and most commonly occur in the vulva, paravaginal, and pelvic retroperitoneum. Typical presentation is pain and mass effect. Small hematomas can be managed conservatively with close observation and patient monitoring. Though there are no evidence-based size criteria, an unstable patient or expand-ing hematomas should prompt surgical intervention. After the hematoma is incised and drained, diffuse venous oozing is usu-ally encountered rather than a single bleeding vessel. Hemo-stasis can be achieved using electrosurgery or fine absorbable suture, though caution must be used due to the proximity of bowel, bladder, and ureters to some hematomas. Pressure on the vulva or packing the vagina, rather than the hematoma cavity, may prevent further bleeding.Cesarean Deliveries. Typical indications for cesarean deliv-ery include nonreassuring fetal status, breech or other malpre-sentations, triplet and higher order gestations, cephalopelvic disproportion, failure to progress in labor, placenta previa, and active genital herpes. Previous low transverse cesarean deliv-ery is not a contraindication to subsequent vaginal birth after cesarean; however, much of the increase in cesarean delivery in the past two decades is attributable to planned repeat cesareans. Cesarean deliveries typically are performed via a lower anterior (caudal) uterine transverse incision because there is decreased blood loss, and the uterine rupture rate with future pregnancies is about 0.5% (Fig. 41-15). A prior classical cesarean delivery is an absolute indication for a planned repeat cesarean delivery because of a high rate of uterine rupture during labor, unlike with the lower anterior uterine transverse incision. Abdominal access is obtained by a Pfannenstiel, Maylard or vertical inci-sion. Once the abdomen is entered, a vesicouterine reflection is created if a low transverse uterine incision is planned. The uter-ine incision is then made and extended laterally, avoiding the uterine vessels. After amniotomy, the baby is delivered, and the uterus is closed. Approximately 1000 mL of blood is typically lost during a cesarean delivery. Along with rapid closure of the uterine incision, uterotonics, such as intravenous oxytocin, are administered. A classical, vertical, uterine incision is made in EDABCFigure 41-15. Uterine incisions for cesarean delivery. (Reproduced with permission from Gabbe S, Niebyl J, Simpson J: Obstetrics: Normal and Problem Pregnancies, 5th ed. Philadelphia, PA: Elsevier/ Churchill Livingstone; 2007.)certain very early viable gestations, or in the case of certain transverse lies or abnormal placentation. Infection, excessive blood loss due to uterine atony, and urinary tract and bowel inju-ries are potential complications at the time of cesarean delivery. The risk of those injuries, as well as abnormal placentation (pla-centa accreta, increta, and percreta) rises with each subsequent cesarean delivery. Bleeding can only be controlled in some instances by performing a cesarean hysterectomy.Postpartum Hemorrhage. Postpartum hemorrhage is an obstetrical emergency that can follow either vaginal or cesarean delivery. Hemorrhage is usually caused by uterine atony, trauma to the genital tract, or rarely, coagulation disorders. Hemorrhage may also be caused by abnormal placentation (also called mor-bidly adherent placenta). Management consists of mitigating potential obstetric causes while simultaneously acting to avert or treat hypovolemic shock. In the absence of atony, the genital tract should be thoroughly evaluated for trauma. Atony is the most common cause of postpartum hemorrhage. It is typically treated with fundal massage and uterotonics such as oxytocin, methylergonovine, carboprost tromethamin, and misoprostol. When aggressive medical management fails, surgical manage-ment may be necessary and life-saving.66Uterine Curettage Retained products of conception may result in uterine atony. It may be possible to remove retained prod-ucts via manual extraction or with ring forceps. Bedside ultra-sound may be helpful in localization. When clinical suspicion is high, uterine curettage is indicated. A blunt, large curette, banjo curette, is introduced and removal of retained tissue typi-cally results in contraction of the myometrium and cessation of bleeding.Procedures Short of Hysterectomy As bleeding from post-partum hemorrhage becomes increasingly acute, interventions short of hysterectomy should be carried out expeditiously while supporting the hemodynamic status of the patient and prepar-ing for possible definitive surgery. A number of techniques for packing and tamponade of the uterus have been described, including a balloon device reported by Bakri and colleagues.67 These are typically left in place for 24 to 36 hours and appear to be safe and often effective conservative measures short of laparotomy and hysterectomy. The B-Lynch compression suture may control bleeding of atony at the time of cesarean section. A suture is placed through the hysterotomy, around the fundus of the uterus anterior to posterior, and then through the posterior lower uterine segment, to the contralateral side. At this point, the steps are reversed with the suture brought around the fundus posterior to anterior, through the contralateral side of the hys-terotomy, and then tied in the midline to compress the uterus. Additional procedures described include the O’Leary uterine artery ligation and the hypogastric artery ligation. “O’Leary stitches” are a series of sutures placed around the branches of the uterine artery and through the myometrium, resulting in compression of the vessels against the uterus. Hypogastric artery ligation entails the isolation of the internal iliac artery at its bifurcation with the external iliac artery. The hypogastric artery is ligated at least 3 cm distal to the bifurcation to avoid compromising the posterior division.Postpartum/Cesarean Hysterectomy A cesarean or postpar-tum (absent a prior cesarean delivery) hysterectomy involves the same steps as in a nonpregnant patient, but it is distinctly different due to the engorged vessels and the pliability of the tis-sues. If a cesarean section has been performed, occasionally the Brunicardi_Ch41_p1783-p1826.indd 180618/02/19 4:34 PM 1807GYNECOLOGYCHAPTER 41incision can be used for traction to keep the vessels and tissues attenuated. Vascular pedicles should be secured with clamps, but not ligated until both uterine arteries have been secured, to fully control bleeding. Lack of typical anatomic landmarks requires careful identification of the ureters and the dilated cervix visu-ally or by palpation, to separate from the bladder and vagina (Fig. 41-16). This procedure is often done for life-threatening hemorrhage, thus appropriate blood products, including packed red blood cells, fresh frozen plasma, platelets, and fibrinogen should be on call and are usually required. Fibrinogen is typi-cally elevated in a pregnant woman, such that a low-normal fibrinogen level can be cause for alarm, and further fibrinogen may be required before consumptive coagulopathy reverses. A massive transfusion protocol is helpful.Abnormal Placentation. Placenta accreta describes the clinical condition when the placenta invades and is inseparable from the uterine wall. When the chorionic villi invades the myometrium, the term placenta increta is used; whereas placenta percreta describes invasion through the myometrium and serosa, and even into adjacent organs such as the bladder. Abnormal placentation has increased in parallel to the cesarean section rate in the United States. When cytotrophoblasts invade decidualized endometrium and encounter a uterine scar, they do not encounter the normal myometrial signals to stop invasion. In the setting of a placenta previa, the presence of a uterine scare is a particular risk for placenta accreta with rates of 11%, 40%, and 61% for one, two, or three prior cesarean deliveries, respectively.68 Ultrasound or MRI can assist in the diagnosis, depending on the experience and comfort of the imager.69,70Women at risk for abnormal placentation should ideally be identified during pregnancy and be prepared for cesarean sec-tion followed by cesarean hysterectomy. Since the blood supply to the gravid uterus is 500 cc per minute, these surgeries have the potential to have very high blood loss, which can then lead to the development of disseminated intravascular coagulation. Over 50% of cases require more than 4 units of blood transfused. BladderUreter identifiedClamps on uterine vesselsFigure 41-16. Demonstration of location of distal ureter and bladder, and their relationship to uterine vessels. (Reproduced with permission from Nichols DH: Gynecologic and Obstetric Surgery, Vol. 1. Philadelphia, PA: Elsevier; 1993.)Unintentional bladder or ureteral injuries are common as well due to impaired visualization and poor dissection planes. For these reasons, patients with suspected placenta accreta should be delivered in a tertiary care center with a multidisciplinary team that has the capacity for massive blood transfusion pro-tocol. While some sites have implemented protocols involving interventional radiology with placement of occlusive balloons in the uterine arteries prior to delivery, these protocols have not been shown to decrease morbidity or overall blood loss. Postop-erative embolization should be available. Even with scheduled delivery in a well-resourced setting with a highly experienced and prepared multidisciplinary team, the morbidity of abnormal placentation is high. ICU stays are common, and maternal mor-tality as high as 7% has been reported.69Delayed hysterectomy where the placenta is left in situ after delivery of the baby if there is not significant bleeding and the mother is stable is advocated by certain centers but remains controversial.71 The risks of leaving the placenta in utero include later hemorrhage, infection, and sepsis. Planned hysterectomy at 6 to 12 weeks postpartum is recommended unless subsequent fertility is strongly desire.69-71PELVIC FLOOR DYSFUNCTIONPelvic floor disorders can be categorized, from a urogyneco-logic perspective, into three main topics: female urinary incontinence and voiding dysfunction, pelvic organ pro-lapse, and disorders of defecation.72 Approximately 11% of women will undergo surgery for incontinence or prolapse.73 The normal functions of support, storage, and evacuation can be altered by derangements in neuromuscular function both cen-trally and peripherally and through acquired changes in connec-tive tissue. Reconstructive surgeons aim to repair or compensate for many of these losses.EvaluationDiagnostic evaluations, in addition to the history and examina-tions previously described, can aid in the diagnosis of many pel-vic floor disorders. Cystoscopy, multichannel urodynamics, and/or fluoroscopic evaluation of the urinary tract can be obtained for patients with urinary incontinence or voiding dysfunction.74 Defecography, anal manometry, and endorectal ultrasound may be useful for diagnosis of defecatory dysfunction. A standard-ized examination called the pelvic organ prolapse quantifica-tion (POP-Q)74 helps to clarify which vaginal compartment, and therefore which specific structure, has lost its anatomic integrity in women with uterovaginal prolapse. Finally, dynamic MRI and pelvic floor electromyography has growing utility for all three disorders.Surgery for Pelvic Organ ProlapseMany factors are important in determining which reconstruc-tive operation is optimal for a given patient with pelvic organ prolapse. Surgical decisions are often based on case series and expert opinions that may not have universal applicability. How-ever, the few reports with the highest level of evidence sug-gests that failure rates for prolapse reconstruction may be twice as high using the vaginal approach when compared with the abdominal route.75,76Colporrhaphy. Anterior colporrhaphy, also known as an “anterior repair,” is performed for a symptomatic cystocele. The procedure begins with incision of the anterior vaginal epithelium 6Brunicardi_Ch41_p1783-p1826.indd 180718/02/19 4:34 PM 1808SPECIFIC CONSIDERATIONSPART IIin a midline sagittal direction. The epithelium is dissected away from the underlying vaginal muscularis. The vaginal muscularis is plicated with interrupted delayed absorbable stitches, after which the epithelium is trimmed and reapproximated. The vaginal canal is therefore shortened and narrowed proportionate to the amount of removed epithelium. Posterior colporrhaphy is performed for a symptomatic rectocele. This procedure is performed in a similar manner, often including the distal pubococcygeus muscles in the plication. Recently, in attempts to decrease surgical failures alluded to previously, many surgeons have opted to utilize grafts and meshes to augment these vaginally performed procedures. Unfortunately, the apparent number of postoperative complications, including mesh erosion, pelvic pain, and dyspareunia, prompted the FDA to publish a warning encouraging a much more limited use of vaginal mesh for prolapse repair until greater surveillance and more rigorous studies could be completed.77Sacrospinous and Uterosacral Ligament Fixations. Both the sacrospinous ligament fixation (SSLF) and uterosacral ligament fixation (USLF) procedures are vaginal procedures that suspend the apex of the vagina using native tissue for treatment of apical prolapse. The sacrospinous ligament is found embedded in and continuous with the coccygeus muscle, which extends from the ischial spine to the lateral surface of the sacrum. The procedure begins with entry into the rectovaginal space, usually by incising the posterior vaginal wall at its attachment to the perineal body. The space is developed to the level of the vaginal apex and the rectal pillar is penetrated to gain access to the pararectal space. A long-ligature carrier is used to place sutures medial to the ischial spine, through the substance of the ligament-muscle complex. Structures at risk in this procedure include the pudendal neurovascular bundle, the inferior gluteal neurovascular bundle, lumbosacral plexus, and sciatic nerve. After the stitches are placed, the free ends are sewn to the undersurface of the vaginal cuff. The sacrospinous stitches are tied to firmly approximate the vagina to the ligament without suture bridging.When using the uterosacral ligaments for repair of prolapse, it is important to recall that these structures are not “ligaments” in the true sense of the word, but rather condensations of smooth muscle, collagen, and elastin. Several support sutures are placed from the lateral-most portion of the vaginal cuff to the distal-most part of the ligament, and the medial vaginal cuff to the proximal ligament. Intraoperative evaluation of the lower urinary tract is important to confirm the absence of ureteral compromise.Colpocleisis. Colpocleisis is reserved for patients who are elderly, who do not wish to retain coital ability, and for whom there is good reason not to perform a more extensive recon-structive operation. A colpocleisis removes of part or all of the vaginal epithelium, obliterating the vaginal vault and leaving the external genitalia unchanged. The procedure can be performed with or without a hysterectomy. Successive purse-string sutures through the vaginal muscularis are used to reduce the prolapsed organs to above the level of the levator plate.Sacrocolpopexy. The procedure with the lowest risk of recurrence for patients with prolapse of the vaginal apex is an abdominal sacral colpopexy. In these patients, the natural apical support structure, the cardinal–uterosacral ligament complex, is often damaged and attenuated. The abdominal placement, as opposed to vaginal placement, of graft material to compensate for defective vaginal support structures is well described.78 Api-cal support defects rarely exist in isolation, and the sacrocol-popexy may be modified to include the anterior and posterior vaginal walls as well as the perineal body in the suspension. Sacrocolpopexies can be performed via laparotomy as well as via laparoscopy or robotically. Like rectopexies and low anterior resections, deep pelvic access is needed. Significant suturing at varied angles is required. The advent of the DaVinci robotic laparoscopic system has made visualization and adequate place-ment of the mesh and sutures easier to perform when using the minimally invasive approach.During a sacrocolpopexy, a rigid stent (usually an EEA sizer) is placed into the vagina to facilitate its dissection from the overlying bladder and rectum and to allow the graft material to be spread evenly over its surface. A strip of synthetic mesh is fixed to the anterior and posterior vaginal walls. The peritoneum overlying the presacral area is opened, extending to the poste-rior cul-de-sac. The sigmoid colon is retracted medially, and the anterior surface of the sacrum is skeletonized. Two to four permanent sutures are placed through the anterior longitudinal ligament in the midline, starting at the S2 level and proceeding distally. The sutures are passed through the graft at an appropri-ate location to support the vaginal vault without tension. The peritoneum is then closed with an absorbable running suture. The most dangerous potential complication of sacrocolpopexy is sacral hemorrhage.Surgery for Stress Urinary IncontinenceStress incontinence is believed to be caused by lack of urethro-vaginal support (urethral hypermobility) or intrinsic sphincter deficiency (ISD). ISD is a term applied to a subset of stress-incontinent patients who have particularly severe symptoms, including urine leakage with minimal exertion. This condition is often recognized clinically as the low pressure or “drainpipe” urethra. The urethral sphincter mechanism in these patients is severely damaged, limiting coaptation of the urethra. Standard surgical procedures used to correct stress incontinence share a common feature: partial urethral obstruction that achieves ure-thral closure under stress.Burch Procedure. Despite the wide acceptance of midurethral sling procedures, a retropubic urethropexy procedure called the Burch procedure is still performed for stress incontinence.79 The space of Retzius is approached extraperitoneally, from an abdominal approach, allowing the bladder to be mobilized from the surrounding adipose tissue and lateral pelvis. Two pairs of large-caliber nonabsorbable sutures are placed through the peri-urethral vaginal wall, one pair at the midurethra and one at the urethrovesical junction. Each stitch is then anchored to the ipsi-lateral Cooper’s (iliopectineal) ligament. The sutures are tied to give preferential support to the urethrovesical junction relative to the anterior vaginal wall without overcorrection. Long-term outcome studies up to 10 years have shown the Burch procedure yields cure rates of 80% to 85%.Tensionless Sling. The tension-free vaginal tape (TVT) is a modified sling that uses a strip of polypropylene mesh. Unlike traditional sling procedures, the mesh is positioned at the midurethra, not the urethrovesical junction, and it is not sutured or otherwise fixed into place. Advantages of TVT include the ability to perform the procedure under local anesthesia on an outpatient basis. Small subepithelial tunnels are made bilater-ally to the descending pubic rami through an anterior vaginal wall incision. A specialized conical metal needle coupled to a handle is used to drive one end of the sling through the peri-neal membrane, space of Retzius, and through one of two small suprapubic stab incisions. The tape is set in place without any Brunicardi_Ch41_p1783-p1826.indd 180818/02/19 4:34 PM 1809GYNECOLOGYCHAPTER 41tension after bringing up the other end of the tape through the other side. Recently, multiple modifications have been made to carry the tape through the bilateral medial portions of the obtu-rator space (TVT-O). Risks of the procedure include visceral injury from blind introduction of the needle, bleeding, and nerve and muscle injury in the obturator space. Additionally, voiding dysfunction and delayed erosion of mesh into the bladder or urethra has been seen.Urethral Bulking Injections. A transurethral or periurethral injection of bulking agents is indicated for patients with intrin-sic sphincter deficiency. Several synthetic injectable agents, such as polydimethylsiloxane and calcium hydroxylapatite are now used, as glutaraldehyde cross-linked (GAX) bovine dermal collagen is no longer commercially available.80 Anesthesia is easily obtained by using intraurethral 2% lidocaine jelly and/or transvaginal injection of the periurethral tissues with 5 mL of 1% lidocaine. The material is injected underneath the urethral mucosa at the bladder neck and proximal urethra at multiple positions, until mucosal bulk has improved. Patients must dem-onstrate a negative reaction to a collagen skin test prior to injec-tion. The long-term cure rate is 20% to 30%, with an additional 50% to 60% of patients demonstrating improvement.72 Repeat injections are frequently necessary because of migration and dissolution of the collagen material.Mesh in Reconstructive Pelvic Surgery. As noted earlier, pelvic reconstructive surgery frequently uses polypropylene mesh to augment procedures in the hopes of providing long-lasting repair. However, use of permanent mesh is associated with complications, most notably mesh erosion. In 2011, the FDA issued an updated statement to stipulate the risks when using transvaginally inserted mesh for prolapse.81 Ultimately, this has led to categorizing transvaginal mesh products as class III devices in 2016. In addition to appropriate patient selection, and extensive informed consent, the American Urogynecologic Society recommends appropriate training to perform the proce-dures and manage the complications.82,83GYNECOLOGIC CANCERVulvar CancerVulvar cancer is the fourth most common gynecologic cancer. The mean age at diagnosis is 65, though this has trended down over the last several decades.84 Evidence supports an HPV-dependent pathway of carcinogenesis with risk factors similar to VIN in approximately 60% of cases. A second pathway inde-pendent of HPV is associated with chronic inflammation, vul-var dystrophy.85 Patients usually present with a vulvar ulcer or mass. Pruritus is a common complaint, and vulvar bleeding or enlarged inguinal lymph nodes are signs of advanced disease. Careful evaluation of the patient is necessary to rule out con-current lesions of the vagina and cervix. Biopsy is required and should be sufficiently deep to allow evaluation of the extent of stromal invasion. Vulvar carcinomas are squamous in 90% of cases. Other less common histologies include melanoma (5%), basal cell carcinoma (2%), and soft tissue sarcomas (1–2%).Spread of vulvar carcinoma is by direct local extension and via lymphatic microembolization. Hematogenous spread is uncommon except for vulvar melanoma. Lymphatic spread seems to follow a stepwise, predictable pattern traveling from superficial, above the cribriform fascia, to deep inguinofemo-ral nodes and ultimately the pelvic, external iliac, nodal basin Superficial inferiorepigastric v.Superficialexternalpudendal v.Superficial femorallymph nodesGreat saphenous v.Fossa ovalisSuperficialcircumflex iliac v.Superficial inguinallymph nodesInguinal ligamentExternalinguinal ringRound ligamentFigure 41-17. Lymphatic drainage of the vulva delineated by Stanley Way.(Fig. 41-17).86,87 The node of Cloquet is an important sentinel node situated in the route of spread to the pelvic lymph nodes.Staging and primary surgical treatment are typically pre-formed as a single procedure and tailored to the individual patient (Table 41-6). Surgical staging accounts for the most important prognostic factors including tumor size, depth of invasion, inguinofemoral node status, and distant spread. The most conservative procedure should be performed in view of the high morbidity of aggressive surgical management. This typi-cally involves radical resection of the vulvar tumor targeting a 1 to 2 cm margin around the lesion, and carried to the deep perineal fascia of the urogenital diaphragm with and ipsilateral or bilateral inguinofemoral lymphadenectomy (Fig. 41-18). For tumors ≤2 cm in size with ≤1 mm invasion (FIGO stage IA), lymphadenectomy may be safely omitted, and wide local or Table 41-62009 FIGO staging of vulvar carcinomaIATumor confined to the vulva or perineum, ≤2 cm in size with stromal invasion ≤1 mm, negative nodes1BTumor confined to the vulva or perineum, >2 cm in size or with stromal invasion >1 mm, negative nodesIITumor of any size with adjacent spread (1/3 lower urethra, 1/3 lower vagina, anus), negative nodesIIIATumor of any size with positive inguino-femoral lymph nodes(i) 1 lymph node metastasis ≥5 mm(ii) 1–2 lymph node metastasis(es) of <5 mmIIIB(i) 2 or more lymph nodes metastases ≥5 mm(ii) 3 or more lymph nodes metastases <5 mmIIICPositive node(s) with extracapsular spreadIVA(i) Tumor invades other regional structures (2/3 upper urethra, 2/3 upper vagina), bladder mucosa, rectal mucosa, or fixed to pelvic bone(ii) Fixed or ulcerated inguino-femoral lymph nodesIVBAny distant metastasis including pelvic lymph nodesModified with permission from Pecorelli S: Revised FIGO staging for carcinoma of the vulva, cervix, and endometrium, Int J Gynaecol Obstet. 2009 May;105(2):103-104.Brunicardi_Ch41_p1783-p1826.indd 180918/02/19 4:34 PM 1810SPECIFIC CONSIDERATIONSPART IIradical local excision are adequate. Patients with IB tumors have deeper invasion but negative nodes and therefore carry an excellent prognosis. Stage II includes patients with local exten-sion and negative nodes and therefore carry a prognosis similar to other node-negative patients.Stage III disease includes patients with lymph node metas-tases, and stage IV disease is either locally advanced or distant metastasis. Treatment options for stage III and stage IV dis-ease include (a) chemoradiation followed by limited resection if needed; (b) radical vulvectomy; and (c) radical vulvectomy coupled with pelvic exenteration. External beam radiotherapy combined with radiosensitizing chemotherapy of cisplatin and 5-fluorouracil (5-FU) is emerging as the preferred initial management of advanced disease, followed by limited surgical resection of residual disease.88-90 Reconstruction of the vulva and groin, if needed, can be accomplished using grafts and rota-tional or myocutaneous flaps depending on the size and type of defect.Inguinofemoral lymphadenectomy is indicated beyond clinical stage IA. Unilateral lymphadenectomy is recom-mended for lateralized lesions or bilateral for central lesions that cross the midline, or those involving the periclitoral area (Figs. 41-19 and 41-20). Complications of complete inguino-femoral lymphadenectomy include wound dehiscence or infec-tion and lymphedema. Sentinel lymph node biopsy (SLNB) is an alternative to inguinofemoral lymphadenectomy for selected patients with stage I or II disease and no palpable inguinofemo-ral nodes. SLNB appears to be effective in detecting inguino-femoral lymph node metastases without increasing the risk of groin recurrence while avoiding the morbidities associated with complete inguinofemoral lymphadenectomy. Several prospec-tive studies support this approach.91,92 However, it is recognized that successful SLNB depends on operator experience. Surgeons with limited experience in SLNB (have performed fewer than 10 of these procedures) may choose to perform complete groin node dissection or use this procedure only for tumors that are less than 2 cm in size.Nodal failure in the groin and pelvis is difficult to treat successfully, and attention to primary management of these areas is key. Postoperative adjuvant inguinal and pelvic radio-therapy is indicated when inguinal lymph nodes are positive and is superior to pelvic lymphadenectomy, which has been largely abandoned. It is also indicated when the vulvectomy margins are positive or close positive for disease and further surgical management is not anatomically feasible.Vaginal CancerVaginal carcinoma is a rare gynecologic malignancy and accounts for about 3% of cancers affecting the female repro-ductive system.84 Squamous cell carcinomas account for 85% to 90% of cases; more than two-thirds of vaginal cancers are diagnosed in women 60 years of age or older. Risk factors are similar to other HPV-related cervical and vulvar cancers. Rare clear cell carcinoma of the vagina is associated to in utero expo-sure to diethylstilbestrol (DES), which is now largely of his-torical interest due to aging of the exposed cohort.93 Patients with vaginal cancer usually present with postmenopausal and/or postcoital bleeding and may also complain of vaginal discharge, vaginal mass, dysuria, hematuria, rectal bleeding, or pelvic pain, which may be indicative of advanced disease. Diagnosis is made via biopsy of suspicious lesions, which may require colposcopic guidance.85Figure 41-18. Extent of modified radical hemivulvectomy for stages I and II squamous cancer of the vulva.Superficial femoral nodesCribriformfasciaDeep femoral nodesFemoral a.Femoral n.Sartorius m.Iliopsoas m.FemurEpidermuslateralmedialAdductor longusPectineus m.Femoral v.Camper’s fasciaFigure 41-19. The anatomy of the inguinal triangle by cross-section.Pubic tubercleFemoral v.Sapheno-femoraljunctionFigure 41-20. Landmarks for choosing an incision for an inguinal lymphadenectomy.Brunicardi_Ch41_p1783-p1826.indd 181018/02/19 4:34 PM 1811GYNECOLOGYCHAPTER 41Vaginal cancer is staged clinically by pelvic exam, chest X-ray, cystoscopy, and proctoscopy (Table 41-7).94 Vaginal cancer spreads by local extension to adjacent pelvic structures, by lymphatic embolization to regional lymph nodes, and, less commonly, via the hematogenous route. Lymphatic drainage is complex, but in general, lesions in the upper vagina drain to the pelvic lymph nodes while lesions involving the lower third drain to the inguinofemoral lymph nodes.Stage I disease, involving the upper vagina, may be treated surgically or with intracavitary radiation therapy.86,87,95 Surgery consists of a radical hysterectomy, upper vaginectomy, and bilateral pelvic lymphadenectomy. Stage I disease in the mid to lower vagina is treated with radiation and concurrent chemo-therapy. External beam pelvic radiation is the mainstay of treat-ment for stages II to IV and may be followed by intracavitary Table 41-7FIGO staging of vaginal carcinoma0Carcinoma in situ; intraepithelial neoplasia grade 3ITumor limited to the vaginal wallIITumor has involved the subvaginal tissue but has not extended to the pelvic wallIIITumor extends to the pelvic wallIVTumor has extended beyond the true pelvis or has involved the mucosa of the bladder or rectumIVATumor invades bladder and/or rectal mucosa and/or direct extension beyond the true pelvisIVBDistant metastasisand/or interstitial brachytherapy. Prognosis for treated early stage disease is excellent with more than 90% 5-year survival rates. Advanced stage disease, however, carries a poor progno-sis with only 15% to 40% 5-year survival rates.Cervical CancerGeneral Principles.  There are over 12,000 new cases of cervical cancer and over 4000 cervical cancer deaths annually in the United States.96 It is a major killer worldwide causing 275,000 deaths annually.97 Risk factors for cervical squamous cell and adenocarcinoma, the two most common histologies, are largely related to acquisition of and immune response to carcinogenic subtypes of the HPV virus. Cervical screening is correlated with early identification and treatment of preinvasive disease.98 Cervical cancer is most commonly identified in women with long intervals between screenings, or with no prior screening. It is also associated with early age at first intercourse, multiple sexual partners, smoking, and oral contraceptive use.Early cervical cancer is usually asymptomatic, though irregu-lar or postcoital bleeding may be present, particularly in more advanced disease. The diagnosis of cervical cancer is made by cervical biopsy, either of a gross lesion or a colposcopically-identified lesion. Cervical cancer is staged clinically due to the high disease burden in the developing world.99 Despite the prog-nostic value of clinical staging, in the developed world, surgical and radiologic staging is used to determine the extent of tumor spread and identify lymph node involvement. Lymph node metastasis is common and one of the most important prognostic factors in this disease, and positron emission tomography scans are useful in pretreatment planning and determination of radia-tion fields for women with locally advanced disease. Staging and management options are outlined in Table 41-8.7Table 41-82009 FIGO cervical cancer staging and management optionsSTAGEDESCRIPTIONOPTIONS FOR MANAGEMENT0Carcinoma in situAdenocarcinoma in situ: simple hysterectomy, may be followed for fertility preservation if all margins negative on coneSquamous cell carcinoma in situ: local excision with LEEP or cone or laser ablationIConfined to the cervixA1: Confined to the cervix, diagnosed only by microscopy with invasion of ≤3 mm in depth and lateral spread ≤7 mmA2: Confined to the cervix, diagnosed with microscopy with invasion of >3 mm and <5 mm with lateral spread ≤7 mmB1: Clinically visible lesion or greater than A2, ≤4 cm in greatest dimensionB2: Clinically visible lesion, >4 cm in greatest dimensionA1 and some A2: fertility preservation through large cone followed by close monitoring, followed by hysterectomyB1 and B2: radical hysterectomy or chemoradiation; radical trachelectomy with uterine preservation for childbearing is under investigation for highly selected patients with small lesionsIIA1: Involvement of the upper two-thirds of the vagina, without parametrial invasion, ≤4 cm in greatest dimensionA2: >4 cm in greatest dimensionB: Parametrial involvementFor some IIA radical hysterectomy may be consideredIIA and B: chemoradiation is preferredIIIA. Involvement of the lower third of the vaginaB. Involvement of a parametria to the sidewall or obstruction of one or both ureters on imagingChemoradiationIVA. Local involvement of the bladder or rectumB. Distant metastasesA. ChemoradiationB. Chemotherapy with palliative radiation as indicatedData from Pecorelli S: Revised FIGO staging for carcinoma of the vulva, cervix, and endometrium, Int J Gynaecol Obstet. 2009 May;105(2):103-104.Brunicardi_Ch41_p1783-p1826.indd 181118/02/19 4:34 PM 1812SPECIFIC CONSIDERATIONSPART IIProcedures for Cervical Cancer Treatment. Certain cervical cancers that are confined to the cervix may be treated surgically. Very small lesions (less than 7 mm wide, less than 3 mm deep) with no LVSI may be treated with simple hysterectomy. In a woman who desires future fertility, a cone biopsy with negative surgical margins may be an acceptable alternative. Any tumor larger than this (larger than stage IA1) should be treated with radical hysterectomy or in special cases radical trachelectomy for fertility preservation. Some authors advocate a large cone biopsy with lymph node dissection for stage IA2 tumors in patients who desire future fertility, though this recommenda-tion is somewhat controversial. Tumors that are greater than 4 cm in size are most often treated with chemoRT even if they Figure 41-21. Radical hysterectomy.BAUterusOvaryFallopian tubeCRound ligamentVesicouterinefoldUterinevesselsEDPararectalspaceLymphnodesParavesical spaceFExternal iliac vesselsInternal iliac arteryGHISuperior vesicalarteryUterine arteryare confined to the cervix, given the high likelihood of need for postoperative radiotherapy due to cervical risk factors.Radical Hysterectomy This procedure may be performed via laparotomy, or increasingly via a minimally invasive (laparo-scopic or robotic) approach.100 The key elements are dissection of the pelvic and periaortic nodes and the dissection of the para-metrium from the pelvic sidewall to allow en bloc removal with the uterus. The principle steps of an open procedure are demon-strated in Fig. 41-21. In contrast to a typical simple hysterectomy, the radical hysterectomy involves dissection much closer to the bowel, bladder, ureters, and great vessels, resulting in a higher complication rate to these organs. Additionally, disruption of the Brunicardi_Ch41_p1783-p1826.indd 181218/02/19 4:35 PM 1813GYNECOLOGYCHAPTER 41MUreterVaginaJKOvary and ligamentFallopian tubeUreterLUterosacralligamentFigure 41-21. (Continued)nerves supplying the bladder and the rectum, which traverse the cardinal and uterosacral ligaments, may result in temporary or long-term bladder and bowel dysfunction. Radical hysterecto-mies allow for the maintenance of the ovaries since the incidence of metastases to this area is very low, providing a clear advantage of surgery over radiation therapy in the younger patient.Radical Trachelectomy Interest in fertility preservation with stages IA1 and 2, and stage IB1 lesions has led to the develop-ment of methods of radical trachelectomy with uterine preserva-tion. This procedure depends on an adequate blood supply to the uterus from the ovarian anastamoses, as the cervical portion is removed. The lower uterine segment closed with a cerclage and attached directly to the vaginal cuff. The rates of recurrence, pregnancy outcomes, and the best surgical candidates for this surgery are still under study,101 but there are sufficient numbers and experience, both obstetric and surgical, to suggest that this procedure is oncologically safe and allows live births.Pelvic Exenteration for Recurrent Disease (Fig. 41-22)  Cervical cancer recurrences after primary surgical management are treated with radiation. Surgery may be a consideration in selected patients with recurrent cervical cancer who have received maximal radiation therapy. If the recurrence is locally confined with no evidence of spread or metastatic disease, then pelvic exenteration may be considered. Attempted exenteration procedures are aborted intraoperatively if metastatic disease is found. Exenteration is tailored for the disease size and location and may be supralevator or extend below the levator ani muscle and require vulvar resection. Reconstruction of the pelvis may require a continent urinary pouch (if radiation enteritis is limited) or ileal conduit and colostomy, as well as rebuilding of the pelvic floor and vagina with grafts or myocutaneous flaps.Uterine CancerEndometrial Cancer. Endometrial cancer is the most com-mon gynecologic malignancy and fourth most common cancer in women.96 It is most common in menopausal women in the fifth decade of life; up to 15% to 25% of cases occur prior to menopause, and 1% to 5% occur before age 40. Risk factors for the most common type of endometrial cancer include increased exposure to estrogen without adequate opposition by progester-one, either endogenous (obesity, chronic anovulation) or exog-enous (hormone replacement). Additional risk factors include diabetes, Lynch II syndrome (hereditary nonpolyposis coli syn-drome), and prolonged use of tamoxifen. Tamoxifen is a mixed agonist/antagonist ligand for the estrogen receptor. It is an ago-nistic in the uterus and an antagonistic to the breast and ovary. Protective factors for endometrial cancer include smoking and use of combination oral contraceptive pills. Adenocarcinomas are the most prevalent histologic type.Endometrial adenocarcinomas have historically been divided into type I and type II tumors with five classic histologic subtypes. Type I tumors are estrogen-dependent endometrioid Brunicardi_Ch41_p1783-p1826.indd 181318/02/19 4:35 PM 1814SPECIFIC CONSIDERATIONSPART IIFigure 41-22. Pelvic exenteration.histology and have a relatively favorable prognosis; they can be broken down further by presence or absence of microsatellite instability. Type II endometrial cancers are estrogen-independent, aggressive, and characterized by nonendometrioid, serous or clear cell, histology, or carcinosarcoma.102 Emerging data, however, suggest that the molecular features could provide reproducible subtypes that have the potential to guide and refine treatment. The most comprehensive molecular study of endometrial cancer to date has been The Cancer Genome Atlas, which included a combination of whole genome sequencing, exome sequencing, microsatellite instability assays, copy number analysis, and proteomics.103 Molecular information was used to classify 232 endometrial cancer patients into four groups: POLE ultramutated, MSI hypermutated, copy number low, and copy number high that correlated with progression-free survival.103 Two practical pared-down classification systems to identify four molecular subgroups with distinct prognostic outcomes have been described.104,105Postmenopausal bleeding is the most common presenta-tion of endometrial cancer and often permits early stage diag-nosis, resulting in a favorable prognosis. Abnormal bleeding should prompt endometrial evaluation and sampling, which is usually done with an office endometrial biopsy, though at times requires operative curettage or diagnostic hysteroscopy. Transvaginal ultrasonography (TVUS) often reveals a thickened endometrial stripe. An endometrial stripe measuring 5 mm or more in a postmenopausal patient with vaginal bleeding raises concern and should be followed by endometrial sampling; patients with stripe of 4 mm or less rarely have occult malig-nancy, and TVUS may thus be used to triage patients before invasive endometrial sampling. Even with a normal endometrial stripe, endometrial sampling should be performed for persistent postmenopausal bleeding. Uterine cancer is surgically staged and is graded based on the degree of histologic differentiation of the glandular components (Table 41-9).99 Grade is an important prognostic factor, independent of stage.Treatment is surgical, and most commonly involves hysterectomy, bilateral salpingo-oophorectomy, peritoneal cytology, and resection of any gross disease.87 Evidence supports equivalent oncologic outcomes with minimally invasive approaches.106 The inclusion and utility of lymphadenectomy remains an area of controversy. If a lymph node dissection is performed, it may be performed via laparotomy or laparoscopy. Generally, the bilateral pelvic and para-aortic lymph nodes are removed. The pelvic node dissection includes: bilateral removal of nodal tissue from the distal one-half of each common iliac artery, the anterior and medial aspect of the proximal half of the external iliac artery and vein, and the distal half of the obturator fat pad anterior to the obturator nerve. Most of the pelvic lymph nodes lie anterior, medially, and posteriorly to the external and internal iliac vessels and the obturator nerve. There are a few nodes that lie lateral to these structures, between the vessels and the pelvic sidewall, and these are generally removed in a complete dissection. The para-aortic lymph nodes include resection of nodal tissue over the distal vena cava from the level of the inferior mesenteric artery to the mid right common iliac artery and between the aorta and the left ureter from the inferior mesenteric artery to the left mid common iliac artery. Some also advocate resection of lymph nodes between the IMA and the gonadal vessels, as some uterine fundal tumors may drain directly into these lymph nodes.107The need for postoperative intervention is individualized based on the histology, stage, and risk factors such as age, lym-phvascular space invasion, and histology. Early-stage patients Table 41-92009 International Federation of Gynecology and Obstetrics staging of carcinoma of the uterine corpusI ATumor confined to the uterus, no or <½ myometrial invasionI BTumor confined to the uterus, >½ myometrial invasionIICervical stromal invasion, but not beyond uterusIII ATumor invades serosa or adnexaIII BVaginal and/or parametrial involvementIII C1Pelvic-node involvementIII C2Para-aortic involvementIV ATumor invasion bladder and/or bowel mucosaIV BDistant metastases including abdominal metastases and/or inguinal lymph nodesData from Pecorelli S: Revised FIGO staging for carcinoma of the vulva, cervix, and endometrium, Int J Gynaecol Obstet. 2009 May;105(2):103-104.Brunicardi_Ch41_p1783-p1826.indd 181418/02/19 4:35 PM 1815GYNECOLOGYCHAPTER 41are typically cured with surgery alone, while patients with high-intermediate risk factors, as defined by collaborative tri-als groups, commonly receive intracavitary brachytherapy to decrease local recurrence.108,109 Patients with advanced disease and high-grade histologies commonly receive platinum-based chemotherapy with or without radiation.Similar to the case with vulvar cancer described earlier, sentinel node biopsy is becoming more prevalent in endome-trial cancer. A sentinel lymph node biopsy may be considered in apparent uterine-confined malignancy when there is no metasta-sis demonstrated by imaging studies or no obvious extrauterine disease at exploration. For this procedure, most frequently the cervix is injected with ICG dye, and the immunofluorescence detecting camera is used either robotically or laparoscopically to identify the sentinel node. If no node is mapped, a full lymph-adenectomy is generally advised.110Lynch Syndrome. Lynch syndrome, a cancer family syn-drome also known as hereditary nonpolyposis colorectal cancer (HNPCC), is an autosomal dominant inherited predisposition to develop colorectal carcinoma and extracolonic cancers, pre-dominantly including tumors of the uterus and ovaries, now also including breast cancer.111 Genes involved in HNPCC are those required for proper single-strand DNA repair via the mismatch repair pathway; most commonly involved are MLH1, MSH2, MSH6, and PMS2. The risk of colorectal carcinoma is as high as 75% by age 75 years. Affected women have a 40% and 10% lifetime risk of developing uterine and ovarian cancers, respec-tively. Surveillance has not been proven to identify disease in early stage for these patients, though it is recommended and should include annual cervical cytology, mammography, trans-vaginal ultrasonography, CA-125 measurements, and an endo-metrial biopsy. Risk-reducing salpingo-oophorectomy with hysterectomy is now being recommended for women who have completed childbearing, ideally 5 to 10 years earlier than the first case of endometrial or ovarian cancer in the family. Dys-regulation of the mismatch repair pathway leads to the micro-satellite instability phenotype, now known be associated with susceptibility to select immunotherapy agents.Uterine Sarcomas. Uterine sarcomas arise from the uterine muscle and connective tissue elements and are typically aggres-sive tumors with a poorer prognosis compared to the more common endometrial carcinomas. The most common histopath-ologic types are endometrial stromal sarcomas, undifferentiated endometrial sarcomas, and leiomyosarcomas. Risk factors are challenging to assess but may include prior pelvic radiation and tamoxifen exposure. Patients typically present with bleeding or mass effects, although some are discovered incidentally at the time of hysterectomy for other indications. Leiomyosarcoma is the most common uterine sarcoma, and hysterectomy with salpingoophorectomy is the treatment of choice. Lymph node metastases are rare in sarcomas in general, and in the absence of palpable nodes or extrauterine disease. There are limited data to support cytoreduction when extrauterine disease is present. The benefits of adjuvant therapy are unknown. Advanced disease is typically treated with systemic chemotherapy.112Ovarian CancerEpithelial Ovarian, Tubal, and Primary Peritoneal Cancer.  Ovarian cancer is a rare disease affecting 1 in 70 women with a median age at diagnosis of 62 years.96 Epithelial malignancies make up the vast majority of ovarian cancers. The majority of women (70%) are diagnosed at with advanced staged disease leading to the poor survival associated with this malignancy. Survival in advanced disease is due both to late diagnosis and lack of effective second-line cytotoxic therapy for the major-ity of patients who relapse following initial clinical complete response to platinum-based chemotherapy. Despite multiple pro-spective population based trials evaluating the use of CA-125, ultrasound, or combinations of these tests for early detection of disease, a mortality benefit to screening programs has not been demonstrated.113-116 Symptoms for either benign or malignant ovarian tumors are nonspecific but frequent, and they include bloating, pelvic or abdominal pain, difficulty eating or feeling full quickly, and urinary symptoms of urgency or frequency,117 which form the basis of an ovarian cancer symptom index (Table 41-10). When newly developed and persistent, these symptoms should prompt an evaluation specifically targeted for identification of gynecologic malignancy.The histologic heterogeneity of ovarian cancer has long been recognized, but with the emergence of more robust clini-copathologic, molecular, and genetic data over the past decade these distinctions have become more clearly defined. Type I tumors consist of low-grade serous (LGS), low-grade endome-trioid, clear cell carcinomas (CCC), and mucinous carcinomas and are characterized by mutations in KRAS, BRAF, PTEN, PIK3CA, CTNNB1, ARID1A, and PPP2R1A. Type II ovarian cancers are the most common of the ovarian cancer histotypes, consisting of high-grade serous (70%), high-grade endometri-oid, carcinosarcoma, and undifferentiated carcinomas. Type II tumors are defined by TP53 mutations, which are rare in type I cancers.118-121 Each of these types have distinct risk factors and potential precursor lesions.121Risk factors for development of ovarian cancer include hormonal factors such as early menarche, late menopause, and nulliparity. The use of oral contraceptives reduces risk of ovar-ian carcinoma—this risk reduction persists for up to 30 years after cessation of use.122 Additionally, tubal ligation and hyster-ectomy decrease population level epithelial ovarian cancer risk. Genetic predisposition to breast or ovarian cancer is the most important known risk for the development of ovarian cancer, and 18% to 24% of ovarian carcinomas may arise in conjunction with a hereditary predisposition.123-128 Germline genetic muta-tions are far more common among type II ovarian cancers, while endometriosis and hormonal factors predispose to type I ovarian malignancies.121,126,129Since 2007, the National Comprehensive Cancer Network guidelines began recommending that all women diagnosed with ovarian cancer receive genetic testing as up to 20% of ovarian cancer patients are BRCA1/2 mutation carriers.127,130-134 Although family history of breast and/or epithelial ovarian cancer is one of the strongest factors for lifetime risk of having breast or epithelial ovarian cancer, up to 50% of women with ovarian cancer who test positive for a BRCA mutation have no fam-ily history of either malignancy, supporting the importance of testing all women with a personal diagnosis of ovarian cancer, regardless of family history. The identification of deleterious mutations allows for cascade testing. Relatives of the affected patient are referred for genetic testing limited to the identified mutation. The lifetime risk for the development of ovarian can-cer for carriers of mutations in the BRCA1 and BRCA2 genes Brunicardi_Ch41_p1783-p1826.indd 181518/02/19 4:35 PM 1816SPECIFIC CONSIDERATIONSPART IIis estimated to be between 20% and 45% and 10% and 20%, respectively.123,130,135One of the challenges associated with early detection of ovarian cancer has historically been the lack of an identifiable precursor lesion. In 2001, however, “dysplastic changes” in the fallopian tubes removed from women with increased risk of developing ovarian carcinoma were first described.136 Subse-quent careful microscopic examination using a newly developed “sectioning and extensively examining of the fimbriated end” protocol (SEE-FIM) of the grossly normal fallopian tubes and ovaries from women with BRCA1/2 mutations revealed occult tubal cancer and precancers designated as serous tubal intraepi-thelial carcinoma. The relationship between serous tubal intraep-ithelial carcinomas and high-grade serous and endometrioid cancers is supported by the ubiquitous presence of TP53 muta-tions and their typical location within the fimbriated end of the fallopian tube.118,121,137 High-grade, serous epithelial cancers of the ovary, fallopian tube, and peritoneum are now recognized to have a common fallopian tubal precursor lesion and often com-bined under the rubric of epithelial ovarian cancer (HGSOC).For women at increased risk of ovarian cancer, the only confirmed prevention strategy is risk-reducing salpingo-oopherectomy.138,139 The lifetime risk of HGSOC is reduced to under 3% with risk-reducing salpingo-oopherectomy. A modern understanding of the fallopian tube as the site of origin for many ovarian cancers has led to the suggestion that opportunistic salpingectomy could be implemented as a potential cancer prevention strategy in the general population. Scandinavian population-based cohort studies have demon-strated a significant decrease in epithelial ovarian cancer following salpingectomy.140,141 Opportunistic salpingectomy is feasible among women undergoing tubal ligation, hysterectomy, or other pelvic surgery.142 Early Staged Ovarian Cancer. Early stage epithelial ovarian cancer has an excellent outcome. Low grade, stages IA and B disease can be cured in up to 90% to 95% of cases by a complete surgical procedure. The prevailing position in the United States is that such patients do not benefit from chemotherapy.143 8The standard of care for women with stages IC and II, and all women with grade 3 or clear cell histology, is adjuvant che-motherapy with 3 to 6 cycles of platinumand taxane-based chemotherapy.144Advanced Ovarian Cancer. A pelvic mass with ascites, an omental cake, and an elevated CA-125 is pathognomonic for advanced ovarian cancer. CT scan is the imaging modality of choice to evaluate the upper abdomen and potential resect-ability of disease. Concerning physical or radiographic exam findings should prompt referral to a gynecologic oncologist (Table 41-10), as studies demonstrate inferior patient outcome for women who have had primary surgery by nongynecologic oncologists.The objectives of surgery in ovarian cancer are threefold. The first is to make the histologic diagnosis. The second is to assess the extent of disease through complete surgical staging (Tables 41-11 and 41-12). When epithelial ovarian cancer is identified on frozen section and disease is grossly limited to the pelvis, complete staging with node dissection will upstage nearly one-third of patients.145 The third objective is (when feasible) surgical cytoreduction or debulking. The extent of disease upon entering the abdomen and the residual disease upon completion of the debulking surgery are independent prognostic variables for patient outcome. The Gynecologic Oncology Group has defined optimal residual disease as residual tumor ≤1 cm in the largest diameter. However, more contemporary data suggest that the most favorable survival outcomes are associated with complete cytoreduction to no gross residual disease.146 Decisions about the benefits and risks of radical debulking for individual presentations and diverse pathology depend on the age and medical stability of the patient, as well as the pathologic type of the cancer.The publication of two randomized prospective trials of neoadjuvant chemotherapy (NACT) for ovarian cancer has led to a questioning of the dogma of maximum surgical effort. Both trials revealed no survival difference compared to primary deb-ulking.147,148 In a patient who is medically compromised or in whom complete primary cytoreduction is unlikely, neoadjuvant Table 41-10Ovarian cancer symptom index (2007) and ACOG guidelines for patient referral to gynecologic oncologyOVARIAN CANCER SYMPTOM INDEXACOG GUIDELINES FOR REFERRAL OF PREMENOPAUSAL WOMEN WITH MASS SUSPICIOUS FOR OVCAACOG GUIDELINES FOR REFERRAL OF POSTMENOPAUSAL WOMEN WITH MASS SUSPICIOUS FOR OVCADevelopment of, change in, and/or persistence in:1 or more of:1 or more of:BloatingCA-125 >200 U/mLElevated CA-125Pelvic or abdominal painAscitesAscitesDifficulty eating or feeling full quicklyEvidence of abdominal or distant metastasisNodular or fixed pelvic massUrinary symptoms of urgency or frequencyFamily history of 1 or more first degree relatives with ovarian or breast cancerEvidence of abdominal or distant metastasisFamily history of one or more first-degree relatives with ovarian or breast cancer  ACOG = American Congress of Obstetricians and Gynecologists.Data from Goff BA, Mandel LS, Drescher CW, et al. Development of an ovarian cancer symptom index: possibilities for earlier detection. Cancer. 2007;109:221-227; Dearking AC, Aletti GD, McGree ME, Weaver AL, Sommerfield MK, Cliby WA. How relevant are ACOG and SGO guidelines for referral of adnexal mass? Obstet Gynecol. 2007;110:841-848.Brunicardi_Ch41_p1783-p1826.indd 181618/02/19 4:35 PM 1817GYNECOLOGYCHAPTER 41Table 41-112014 International Federation of Gynecology and Obstetrics staging of epithelial ovarian cancerITumor confined to ovaries or fallopian tube(s)T1IATumor limited to one ovary (capsule intact) or fallopian tubeNo tumor on ovarian or fallopian tube surfaceNo malignant cells in the ascites or peritoneal washingsT1aIBTumor limited to both ovaries (capsules intact) or fallopian tubesNo tumor on ovarian or fallopian tube surfaceNo malignant cells in the ascites or peritoneal washingsT1bICTumor limited to one or both ovaries or fallopian tubes, with any of the following:IC1 Surgical spill intraoperativelyIC2 Capsule ruptured before surgery or tumor on ovarian or fallopian tube surfaceIC3 Malignant cells present in the ascites or peritoneal washingsT1cIITumor involves one or both ovaries or fallopian tubes with pelvic extension (below pelvic brim) or peritoneal cancer (Tp)T2IIAExtension and/or implants on the uterus and/or fallopian tubes/and/or ovariesT2aIIBExtension to other pelvic intraperitoneal tissuesT2bIIITumor involves one or both ovaries, or fallopian tubes, or primary peritoneal cancer, with cytologically or histologically confirmed spread to the peritoneum outside the pelvis and/or metastasis to the retroperitoneal lymph nodesT3IIIAMetastasis to the retroperitoneal lymph nodes with or without microscopic peritoneal involvement beyond the pelvisT1, T2, T3aN1IIIA1Positive retroperitoneal lymph nodes only (cytologically or histologically proven) IIIA1(i)Metastasis ≤10 mm in greatest dimension (note this is tumor dimension and not lymph node dimension)T3a/T3aN1IIIA1(ii)Metastasis >10 mm in greatest dimension IIIA 2Microscopic extrapelvic (above the pelvic brim) peritoneal involvement with or without positive retroperitoneal lymph nodesT3a/T3aN1IIIBMacroscopic peritoneal metastases beyond the pelvic brim ≤2 cm in greatest dimension, with or without metastasis to the retroperitoneal lymph nodesT3b/T3bN1III CMacroscopic peritoneal metastases beyond the pelvic brim >2 cm in greatest dimension, with or without metastases to the retroperitoneal nodes (Note 1)T3c/T3cN1IVDistant metastasis excluding peritoneal metastases  Stage IV A: Pleural effusion with positive cytologyStage IV B: Metastases to extra-abdominal organs (including inguinal lymph nodes and lymph nodes outside of abdominal cavity) (Note 2)Any T, any N, M1Reproduced with permission from Mutch DG, Prat J: 2014 FIGO staging for ovarian, fallopian tube and peritoneal cancer, Gynecol Oncol. 2014 Jun; 133(3):401-404.Table 41-12Components of comprehensive surgical staging and debulking of epithelial ovarian cancerVertical abdominal incision adequate to visualize the diaphragmsEvacuation of ascitesPeritoneal washings of each pelvic gutter and diaphragmEn bloc hysterectomy and bilateral salpingo-oopherectomyInfragastric omentectomyRetroperitoneal and pelvic lymph node dissectionExamination of the entire bowelRandom biopsies of apparently uninvolved areas of peritoneum, pericolic gutters, diaphragmchemotherapy followed by interval debulking may be more appropriate and is supported by recent randomized controlled trials. Typically, treatment with NACT includes three cycles of platinum-based chemotherapy prior to open debulking, then three additional cycles after surgery. Diagnostic laparoscopic evaluation prior to cytoreductive surgery has been suggested as a means to avoid unnecessary laparotomy, resulting in subop-timal cytoreduction. Patients deemed not to be candidates for cytoreduction could proceed immediately to NACT at the time of tissue collection for definitive diagnosis. A Fagotti predictive index ≥8 (Table 41-13) is a predictor of suboptimal cytoreduc-tion in advanced ovarian cancer with reasonable sensitivity and high specificity.149 These recommendations currently apply to HGSOC, clear cell cancer, and high-grade endometrioid ovarian Brunicardi_Ch41_p1783-p1826.indd 181718/02/19 4:35 PM 1818SPECIFIC CONSIDERATIONSPART IIcancers. Low-grade tumors are less chemotherapy sensitive, and primary surgical resection is recommended when feasible. Standard of care adjuvant therapy of advanced stage epithe-lial ovarian cancer remains intravenous platinumand tax-ane-based chemotherapy.150 In 2006, the National Cancer Institute issued a clinical alert indicating that combination intrave-nous/intraperitoneal platinum/taxane postoperative chemotherapy should be considered first line for women with optimally cytore-duced EOC. This was the result of completion and analysis of three independent randomized clinical trials showing a significant survival advantage for intraperitoneal therapy.151,152 Intraperitoneal (IP) therapy is administered via an implanted 9.6 French venous port catheter with the port placed over the right or left costal 9margin. The catheter is tunneled caudad with insertion through the fascia in the lower abdomen and the tip in the pelvis. The IP cath-eter may be placed at the time of surgical debulking via an open laparotomy approach or prior to initiating chemotherapy via a laparoscopic approach. In some centers, the IP catheter may be placed by interventional radiology with CT guidance.Patients who have suboptimally debulked advanced stage disease and/or who are not candidates for intraperitoneal ther-apy should receive intravenous adjuvant chemotherapy. Interest has increased in both dose dense IV chemotherapy dosing as well as incorporation of biologic agents.Secondary cytoreduction upon recurrence can be con-sidered (Table 41-14). Patients who have had a disease-free Table 41-13Laparoscopic assessment of advanced ovarian cancer to predict surgical resectabilityLAPAROSCOPIC FEATURESCORE 0SCORE 2Peritoneal carcinomatosisCarcinomatosis involving a limited area (along the paracolic gutter or the pelvic peritoneum) and surgically removable by peritonectomyUnresectable massive peritoneal involvement as well as with a miliary pattern of distributionDiaphragmatic diseaseNo infiltrating carcinomatosis and no nodules confluent with the most part of the diaphragmatic surfaceWidespread infiltrating carcinomatosis or nodules confluent with the most part of the diaphragmatic surfaceMesenteric diseaseNo large infiltrating nodules and no involvement of the root of the mesentery as would be indicated by limited movement of the various intestinal segmentsLarge infiltrating nodules or involvement of the root of the mesentery indicated by limited movement of the various intestinal segmentsOmental diseaseNo tumor diffusion observed along the omentum up to the large stomach curvatureTumor diffusion observed along the omentum up to the large stomach curvatureBowel infiltrationNo bowel resection was assumed and no miliary carcinomatosis on the ansae observedBowel resection assumed or miliary carcinomatosis on the ansae observedStomach infiltrationNo obvious neoplastic involvement of the gastric wallObvious neoplastic involvement of the gastric wallLiver metastasesNo surface lesionsAny surface lesionTable 41-14Guidelines for secondary therapy of epithelial ovarian cancerTIME FROM COMPLETION OF PRIMARY THERAPYDEFINITIONINTERVENTIONProgression on therapyPlatinum-refractoryNo value of secondary debulking unless remediating complication such as bowel obstructionNon–platinum-based chemotherapyConsider clinical trialProgression within 6 months of completion of primary therapyPlatinum-resistantNo value of secondary debulking unless remediating complication such as bowel obstructionNon–platinum-based chemotherapy consider adding bevacizumabConsider clinical trialProgression after 6 months post completion of primary therapyPlatinum-sensitiveConsider secondary debulking if greater than 12 months intervalConsider platinum +/− taxane +/− bevacizumab, +/− pegylated liposomal doxorubicin, +/− gemcitabineConsider maintenance PARP inhibitorConsider clinical trialBrunicardi_Ch41_p1783-p1826.indd 181818/02/19 4:35 PM 1819GYNECOLOGYCHAPTER 41period of at least 12 months following an initial complete clini-cal response to surgery and initial chemotherapy, who have no evidence of carcinomatosis on imaging, and who have disease that can be completely resected are considered optimal candi-dates. A randomized controlled trial reported in abstract form demonstrated a benefit of secondary cytoreduction under strict entry criteria (DESKTOP3); the GOG-0213 study of secondary cytoreduction is maturing. Debulking surgery done after subse-quent relapses or in women with early recurrence has not been shown to result in an outcome benefit and should be used only to palliate disease complications.The most common cause of palliative surgery is bypass of bowel obstruction. The majority of women with advanced ovarian cancer will eventually develop and potentially die from malignant bowel obstruction. While management of these cases is controversial, in some cases surgical correction has been shown to prolong life and improve quality of life.153 Nonsurgical options include placement of a venting gastrostomy tube, per-formed endoscopically or surgically. Management of malignant bowel obstruction in women with recurrent advanced disease should be individualized.Chemotherapy is the mainstay of therapy for recurrent EOC. Treatment approaches are based upon platinum sensitivity.154 Referral to an oncologist with specific expertise in chemothera-peutic treatment of ovarian cancer and access to clinical trials is important. In determining secondary and subsequent ther-apy, consideration of prior therapies, sites of disease, organs at risk from cancer, organs sustaining injury from prior ther-apy, and quality of life desires of patient should be taken into consideration.Ovarian Germ Cell Tumors. Ovarian germ cell tumors occur most commonly in women under age 30. The most common benign germ cell neoplasm is the mature cystic teratoma; approximately 1% of teratomas contain a secondary malig-nancy arising from one of the components, most commonly squamous cell cancer and most commonly in postmenopausal women. Malignant germ cell tumors often grow and dissemi-nate rapidly and are symptomatic. The rapid growth may be accompanied by torsion or rupture, producing an acute abdo-men and the need for emergent intervention. Because they are derived from primordial germ cells, many produce charac-teristic tumor markers. Immature teratomas comprise a sig-nificant proportion of malignant germ cell tumors and may be associated with elevated lactate dehydrogenase (LDH) or α-fetoprotein (AFP). Excluding teratomas, the most common malignant germ cell tumor is dysgerminoma, made up of pure undifferentiated germ cells. Bilaterality occurs in up to 15% of patients; lactate dehydrogenase is commonly elevated, and elevated b-hCG may occur.Less common malignant germ cell tumors include endo-dermal sinus or yolk sac tumors, embyronal carcinomas, mixed germ cell neoplasms, polyembryomas, and choriocarcinomas. Endodermal sinus tumors may have elevated AFP levels in the blood while embryonal and mixed germ cell tumors may have elevated b-hCG, LDH, or AFP. Tumor markers are useful to fol-low during surveillance and definitive therapy. Other than com-pletely resected stage I, grade I immature teratoma, adjuvant chemotherapy with a platinum-containing regimen has been his-torically recommended.155 Because of the high response rates to chemotherapy and the long-term toxicity of treatment, a “watch and wait” approach with treatment only upon recurrence has been suggested as safe for selected, well-staged patients with germ cell tumors.156 The cure rate remains high, near 90% even when metastatic disease is present; recurrent disease is more difficult to eradicate.155Fertility preservation is the standard surgical approach for ovarian germ cell tumors as disease tends to be diagnosed at stage I, and salvage chemotherapy is overall extremely suc-cessful. Staging should include removal of the involved ovary, biopsy of any suspicious areas, pelvic and para-aortic node dis-section, and omentectomy. Hysterectomy or removal of the sec-ond ovary is rarely indicated.Growing teratoma syndrome is a rare sequela of germ cell malignancies. Characteristically, during or after chemotherapy slow-growing tumors will increase in size and may even com-press surrounding organs. Malignant transformation within these masses has been described. Treatment is with surgical resection.157Ovarian Sex Cord-Stromal Tumors. Sex cord-stromal cell tumors, rare tumors, are derived from cells that support and surround the oocyte and can present with symptoms referable to endocrine activity of the tumor. These include granulosa cell tumors (female differentiated), fibroma-thecomas, and Sertoli-Leydig cell tumors (male differentiated). Granulosa cell tumors are the most common in this group and are a low-grade malignancy with fewer than 3% bilaterality. They are treated with conservative surgery, similar to germ cell tumors in young women.155 Hysterectomy and bilateral salpingo-oophorectomy is recommended for women who have completed childbearing. Nodal staging can be safely omitted in the absence of grossly involve nodes and fertility preservation is possible in disease limited to one ovary, the most common presentation. Debulking surgery is recommended for more extensive disease. These tumors and the thecomas in the same class often stimulate estrogen production and can be found in association with endometrial hyperplasia and cancer (5%). Granulosa cell tumors can recur over a prolonged period given their low rate of proliferation and tendency for local or intraperitoneal recurrence. Inhibin has been shown to be elaborated by these tumors and often is followed to identify recurrence of the disease. The Sertoli/Leydig cell tumors can present with virilization as a primary symptom. Evaluation of the ovary when this symptom is found is always of value.Gestational Trophoblastic Disease. Gestational trophoblas-tic disease (GTD) is a spectrum of abnormal pregnancy–related trophoblastic proliferations. Premalignant histologic types include partial and complete hydatidiform moles. Primary sur-gery for diagnosis and initial therapy is a suction dilatation and curettage. Clinically, partial moles present as missed abortions and usually resolve with observation. Partial moles are triploid, usually XXY, which can result from dispermic fertilization of an egg. A previously described classical presentation of hyper-emesis gravidarum, hyperthyroidism, preeclampsia, pulmonary trophoblastic embolization, and uterine size larger than dates is rarely seen today because of routine ultrasound assessments during early pregnancy. Even in the first trimester, however, a characteristic “snow storm” appearance may be seen on ultra-sound. Pathologic examination will demonstrate no fetal tissue and have a diploid karyotype resulting from paternal duplication occurring after loss of maternal genetic material, or occasionally Brunicardi_Ch41_p1783-p1826.indd 181918/02/19 4:35 PM 1820SPECIFIC CONSIDERATIONSPART IIwith dispermic fertilization of an empty egg. Often associated theca lutein ovarian cysts, which can be greater than 6 cm in diameter, are seen on ultrasound. They should be followed without surgical intervention as they resolve with removal or treatment of the GTD. Following uterine evacuation, patients with molar pregnancies must be followed closely with weekly b-hCGs until normal for 3 weeks and then monthly for at least 6 months. Contraception should be provided to allow for sur-veillance. Any increase in b-hCG should trigger further evalua-tion and consideration of chemotherapy.158,159Invasive moles, choriocarcinoma, and placental site tro-phoblastic tumors are malignant disorders. Invasive moles are diagnosed following the diagnosis of a molar pregnancy if any of the following are demonstrated: (a) a plateau of b-hCG lasts for four measurements over a period of 3 weeks or longer; (b) a rise in b-hCG for three consecutive weekly measurements over at least a period of 2 weeks or more; or (c) b-hCG level remains elevated for 6 months or more. Metastatic GTD can present on the cervix, vagina, liver, lung, or brain and should not be man-aged surgically. In a woman of reproductive age, a diagnosis of metastatic GTN can be made without biopsy if a b-hCG is found to be elevated in the setting of widespread metastatic disease. In fact, given the incidence of bleeding complications biopsy is not recommend.Chemotherapy is the primary recommended therapy. Per 2000 FIGO staging and classification, a risk score of 6 and below is classified as low risk and above 6 is considered high risk (Table 41-15). Low-risk patients are treated with single agent chemotherapy (methotrexate or actinomycin-D); high-risk patients receive multiagent chemotherapy. In either case, chemotherapy continues until b-hCG levels have normalized. Modern salvage and cure rates are high, with 5-year survival of high-risk patients reported as high as 90%.160 Twelve months of surveillance with contraception is recommended following treatment in order to allow complete surveillance for relapse.Beyond dilation and curettage, surgery may have a role in the management of GTD. Hysterectomy is recommended for placental site trophoblastic tumors for which metastasis is rare. Laparotomy may be indicated in the cases of uncontrolled intra-abdominal or uterine bleeding. Neurosurgery may be required if there is intracranial bleeding or increased intracranial pressure due to metastatic disease.159MINIMALLY INVASIVE GYNECOLOGIC SURGERYHysteroscopySee earlier section, “Hysteroscopy” under “Procedures Per-formed for Structural Causes of Abnormal Uterine Bleeding.”LaparoscopyThe standard method for gynecologic laparoscopy follows the same methods as all minimally invasive surgery. In general, a camera port is placed near the umbilicus. Sometimes it must be placed more cephalad if the patient has a larger fibroid uterus. Two additional ports are placed laterally, usually just superior and medial to the anterior superior iliac spines. Single site lapa-roscopic procedures may improve cosmesis and reduce post-operative pain, but challenges including lack of triangulation and instrument crowding at the umbilicus make this technique challenging to apply to more complex procedures.161Robotic SurgeryOver the last decade, there has been increased use of robot-ics for gynecologic surgery. With the DaVinci robotic system, the surgeon sits at a console and visualizes the operative field with three-dimensional optics. The use of robotic surgery has been described for virtually every gynecologic procedure that has been performed abdominally or laparoscopically. The lapa-roscopic instruments are “wristed” and move as the surgeon’s hands/fingers move the actuators at the console. Robotic surgery Table 41-15International Federation of Gynecology and Obstetrics/World Health Organization scoring system for gestational trophoblastic disease based on prognostic factors SCORE 0124Age<40>40––Antecedent pregnancyMoleAbortionTermInterval from index pregnancy, months<44–67–12>12Pretreatment hCG mIU/mL<103>103–104>104–105>105Largest tumor size including uterus, cm–3–4≥5–Site of metastases including uterusLungSpleen, kidneyGastrointestinal tractBrain, liverNumber of metastases identified–1–45–8>8Previous failed chemotherapy––Single drugTwo or more drugsBrunicardi_Ch41_p1783-p1826.indd 182018/02/19 4:35 PM 1821GYNECOLOGYCHAPTER 41uses a camera port, two to three robotic ports, and an accessory port. More meticulous dissection, improved visualization, and ability to operate with lower intra-abdominal pressures make the robotic platform advantageous, especially in obese patients. Longer set-up time and increased cost, however, are distinct disadvantages. The robotic unit costs up to $2.3 million and is associated with annual maintenance costs of $180,000 a year.162There is significant data to support robotic surgery in gynecologic malignancy; however, most procedures can be per-formed successfully with either robotic or laparoscopic platform depending on operator comfort and skill set. One large study sug-gested a lower conversion to laparotomy rate for robotic versus laparoscopic hysterectomy, but this was not statistically signifi-cant: conversion to laparotomy for laparoscopic hysterectomy was 9.9% compared with 4.9% for robotic cases (P =.06).163Complications Pertinent to Gynecologic SurgeryAbdominal Wall Vessels. The vessel at greatest risk of injury during the lateral trocar placement is the inferior epigastric artery. The superficial epigastric vessels and the superficial circumflex iliac vessels can be injured as well (Fig. 41-23). The primary methods to avoid vessel injury are knowledge of the vessels at risk and their visualization prior to trocar placement, when possible. The superficial vessels often can be seen and avoided by transillumination of the abdominal wall with the laparoscope. In contrast, the larger inferior epigastric vessels cannot be seen by transillumination because of their deeper location; these vessels often can be seen laparoscopically and avoided as they course along the peritoneum between the lateral umbilical fold of the bladder and the insertion of the round ligament into the inguinal canal. Anatomic variation and anastomoses between vessels make it impossible to know the exact location of all the abdominal wall vessels. For this reason, other strategies also should be used to avoid vessel injury, including the use of trocars with conical tips rather than pyramid tips and the use of the smallest trocars possible lateral to the midline.Intestinal Injury. Another potentially serious complication of laparoscopic surgery is injury to either small or large intestines. 10An estimated incidence of bowel injury during laparoscopic gynecologic surgery is estimated to be 0.13%, 41% of which had a delayed diagnosis.164 Bowel injury can occur at the time of trocar insertion, especially if the patient has had previous abdominal procedures that often result in bowel adhesions to the anterior abdominal wall peritoneum, but rates appear simi-lar regardless of entry technique. Due to the proximity of sur-gery to the bowel, thermal injury due to electrosurgery is also frequently implicated in intestinal injury. Time to diagnosis in these cases is typically several days postoperatively as a thermal injury takes time to mature and necrose.Urologic Injuries. A risk of injury to the urogenital tract is inherent to gynecologic surgery due to proximity. Prevention of injury and intraoperative recognition and repair are crucial to avoiding long-term sequelae. Most urogenital fistulae are the result of unrecognized injuries to the urogenital tract at the time of surgery.Bladder Injury. Placement of a Foley catheter prior to gyne-cologic surgery is critical to reducing risk of bladder injuries. Bladder injury during open or laparoscopic surgery results from retroperitoneal perforation during lower trocar placement or during sharp dissection of the bladder from the lower uterine segment during hysterectomy. The latter of these two situa-tions is usually recognized intraoperatively; the first sign of the former may be postoperative hematuria, lower-port incisional drainage, or pneumoturia during laparoscopy. Once diagnosed, large defects require layered closure, whereas smaller defects usually close spontaneously within days or weeks with the aid of transurethral catheter drainage.Ureteral Injury. Although ureteral injury is rare, occurring in less than 1% of gynecologic procedures, it is the most serious of the complications related to gynecologic surgery, particularly if unrecognized.165,166 There are three anatomic locations where the ureter is at risk during gynecologic procedures (see Fig. 41-5): (a) the ureter descends over the pelvic brim as it courses over the bifurcation of the common iliac artery into the external and internal iliac arteries just below the ovarian vessels; (b) in the pelvis, the ureter courses along the lateral aspect of the broad ligament to enter the base of the broad ligament; and (c) the ure-ter is found less than 2 cm lateral to the cervix, passing under the uterine artery and then medially over the anterior vaginal for-nix before entering the trigone of the bladder—this is the most common location of ureteral injury. Ureteral injuries, including complete ligation, partial resection, or thermal injuries, usually will manifest within hours to days of surgery. Complete obstruc-tion most often manifests as flank pain, whereas the first sign of partial or complete transection may be symptoms of intra-abdominal irritation caused by urine leakage. Transperitoneal thermal injuries resulting from fulguration of endometriosis may be similar to those after transection, but the appearance of symp-toms may be delayed several days until tissue necrosis occurs.Routine cystoscopy following hysterectomy is advocated by some gynecologists. For procedures performed for prolapse or incontinence where injury to the urinary tract is highest, rou-tine cystoscopy is recommended. Consideration of a surgeon’s individual complication rate and the difficulty of an individ-ual procedure are considerations for the provision of routine cystoscopy.166Vaginal Vault Dehiscence. This complication of hysterec-tomy seems to be more common in laparoscopic and robotic DeepvesselsSuperficial vessels Inferiorepigastric DeepcircumflexiliacSuperficial epigastricSuperficialcircumflex iliacFigure 41-23. Location of anterior abdominal wall blood vessels.Brunicardi_Ch41_p1783-p1826.indd 182118/02/19 4:35 PM 1822SPECIFIC CONSIDERATIONSPART IIsurgeries. This may be due to the use of cautery in dividing the vaginal cuff or in the method of vaginal closure when done mini-mally invasively. Vaginal closure of the cuff appears to decrease the rate of vaginal cuff dehiscence in MIS hysterectomy.Hemodynamically stable women without bowel eviscera-tion may be candidates for transvaginal repair without abdomi-nal exploration. Vaginal approach may also be appropriate in select cases of evisceration in which the bowel can be com-pletely evaluated vaginally. Since bowel evisceration can lead to peritonitis and sepsis, all women with bowel eviscerations are considered to have a surgical emergency, and surgery should not be delayed for imaging. In most cases of bowel eviscera-tion, evaluation of the bowel by laparoscopy or laparotomy is indicated to ensure bowel integrity.REFERENCES 1. Anson B. Atlas of Human Anatomy. Philadelphia: WB Saunders, 1950. 2. Force USPST. Screening for gynecologic conditions with pel-vic examination: US Preventive Services Task Force recom-mendation statement. JAMA. 2017;317:947-953. 3. McNicholas C, Peipert JF. Is it time to abandon the routine pel-vic examination in asymptomatic nonpregnant women? JAMA. 2017;317:910-911. 4. Schiffman M, Wentzensen N, Wacholder S, Kinney W, Gage JC, Castle PE. Human papillomavirus testing in the prevention of cervical cancer. J Natl Cancer Inst. 2011;103:368-383. 5. US Preventive Services Task Force. Cervical cancer: screen-ing. Available at: https://www.uspreventiveservicestaskforce.org/Page/Document/RecommendationStatementFinal/cervi-cal-cancer-screening2. Accessed August 11, 2018. 6. US Preventive Services Task Force. Screening for Cervical CancerUS Preventive Services Task Force Recommendation Statement. JAMA. 2018;320(7):674-686. 7. Petrosky E, Bocchini Jr JA, Hariri S, et al. Use of 9-valent human papillomavirus (HPV) vaccine: updated HPV vac-cination recommendations of the advisory committee on immunization practices. MMWR Morb Mortal Wkly Rep. 2015;64:300-304. 8. Paavonen J, Naud P, Salmeron J, et al. Efficacy of human papillomavirus (HPV)-16/18 AS04-adjuvanted vaccine against cervical infection and precancer caused by onco-genic HPV types (PATRICIA): final analysis of a double-blind, randomised study in young women. Lancet. 2009;374: 301-314. 9. Meites E. Use of a 2-dose schedule for human papillomavi-rus vaccination—updated recommendations of the Advisory Committee on Immunization Practices. MMWR Morb Mortal Wkly Rep. 2016;65(49):1405-1408. 10. Gynecologists ACoOa. ACOG committee opinion: number 280, December 2002. The role of the generalist obstetrician-gynecologist in the early detection of ovarian cancer. Obstet Gynecol. 2002;100(6):1413-1416. 11. Mutch DG, Powell MA, Allsworth JE, Taylor NP, Brooks RA. How accurate is Pipelle sampling: a study by Huang et al. Am J Obstet Gynecol. 2007;196:280-281. 12. Margesson LJ. Vulvar disease pearls. Dermatol Clin. 2006;24:145-155. 13. McPherson T, Cooper S. Vulval lichen sclerosus and lichen planus. Dermatol Ther. 2010;23:523-532. 14. Downs MC, Randall HW, Jr. The ambulatory surgical manage-ment of Bartholin duct cysts. J Emerg Med. 1989;7:623-626. 15. Workowski KA, Berman SM. Sexually transmitted diseases treatment guidelines, 2006. MMWR Morb Mortal Wkly Rep. 2006;55:1-94. 16. Stanley M. Chapter 17: genital human papillomavirus infec-tions—current and prospective therapies. J Natl Cancer Inst Monogr. 2003;(31):117-124. 17. Habel LA, Van Den Eeden SK, Sherman KJ, McKnight B, Stergachis A, Daling JR. Risk factors for incident and recur-rent condylomata acuminata among women. A population-based study. Sex Transm Dis. 1998;25:285-292. 18. Massad LS, Xie X, Darragh T, et al. Genital warts and vulvar intraepithelial neoplasia: natural history and effects of treat-ment and human immunodeficiency virus infection. Obstet Gynecol. 2011;118:831-839. 19. Tan H-H, Goh C-L. Viral infections affecting the skin in organ transplant recipients. American J Clin Dermatol. 2006;7:13-29. 20. Brodell LA, Mercurio MG, Brodell RT. The diagnosis and treatment of human papillomavirus-mediated genital lesions. Cutis. 2007;79:5-10. 21. Fanning J, Lambert HC, Hale TM, Morris PC, Schuerch C. Paget’s disease of the vulva: prevalence of associated vulvar adenocarcinoma, invasive Paget’s disease, and recurrence after surgical excision. Am J Obstet Gynecol. 1999;180:24-27. 22. Darragh TM, Colgan TJ, Cox JT, et al. The lower anogenital squamous terminology standardization project for hpv-asso-ciated lesions: background and consensus recommendations from the college of American pathologists and the American society for colposcopy and cervical pathology. Arch Pathol Lab Med. 2012;136:1266-1297. 23. Modesitt SC, Waters AB, Walton L, Fowler WC Jr, Van Le L. Vulvar intraepithelial neoplasia III: occult cancer and the impact of margin status on recurrence. Obstet Gynecol. 1998;92:962-966. 24. Anderson MR, Klink K, Cohrssen A. Evaluation of vaginal complaints. JAMA. 2004;291:1368-1379. 25. Eschenbach DA, Davick PR, Williams BL, et al. Prevalence of hydrogen peroxide-producing Lactobacillus species in normal women and women with bacterial vaginosis. J Clin Microbiol. 1989;27:251-256. 26. Cardosi RJ, Bomalaski JJ, Hoffman MS. Diagnosis and man-agement of vulvar and vaginal intraepithelial neoplasia. Obstet Gynecol Clin North Am. 2001;28:685-702. 27. Stenchever M, Droegemueller W, Herbst A, Mishell D. Com-prehensive Gynecology. St Louis: Mosby; 2001. 28. The American College of Obstetricians and Gynecologists. Management of acute abnormal uterine bleeding in non-pregnant reproductive-aged women. ACOG Committe Opin-ion. Reaffirmed 2017. Available at: https://www.acog.org/Clinical-Guidance-and-Publications/Committee-Opinions/Committee-on-Gynecologic-Practice/Management-of-Acute-Abnormal-Uterine-Bleeding-in-Nonpregnant-Reproductive-Aged-Women. Accessed August 11, 2018. 29. Van Bogaert LJ. Clinicopathologic findings in endometrial polyps. Obstet Gynecol. 1988;71:771-773. 30. Costa-Paiva L, Godoy CE, Jr, Antunes A, Jr, Caseiro JD, Arthuso M, Pinto-Neto AM. Risk of malignancy in endome-trial polyps in premenopausal and postmenopausal women according to clinicopathologic characteristics. Menopause. 2011;18:1278-1282. 31. Byun JY, Kim SE, Choi BG, Ko GY, Jung SE, Choi KH. Dif-fuse and focal adenomyosis: MR imaging findings. Radio-graphics. 1999;19:S161-S170. 32. Filicori M, Hall DA, Loughlin JS, Rivier J, Vale W, Crowley WF, Jr. A conservative approach to the management of uter-ine leiomyoma: pituitary desensitization by a luteinizing hormone-releasing hormone analogue. Am J Obstet Gynecol. 1983;147:726-727. 33. Matsuo H, Maruo T. GnRH analogues in the manage-ment of uterine leiomyoma (in Japanese). Nippon Rinsho. 2006;64(suppl 4):75-79.Brunicardi_Ch41_p1783-p1826.indd 182218/02/19 4:35 PM 1823GYNECOLOGYCHAPTER 41 34. Szabo E, Nagy E, Morvay Z, Palko A, Csernay L. Uterine artery embolization for the conservative management of leio-myoma (in Hungarian). Orv Hetil. 2001;142:675-680. 35. Mutter GL. Diagnosis of premalignant endometrial disease. J Clin Pathol. 2002;55:326-331. 36. Kurman RJ, Kaminski PF, Norris HJ. The behavior of endome-trial hyperplasia. A long-term study of “untreated” hyperplasia in 170 patients. Cancer. 1985;56:403-412. 37. Trimble CL, Kauderer J, Zaino R, et al. Concurrent endome-trial carcinoma in women with a biopsy diagnosis of atypi-cal endometrial hyperplasia: a Gynecologic Oncology Group study. Cancer. 2006;106:812-819. 38. Zaino RJ, Kauderer J, Trimble CL, et al. Reproducibility of the diagnosis of atypical endometrial hyperplasia: a Gynecologic Oncology Group study. Cancer. 2006;106:804-811. 39. Baak JP, Mutter GL, Robboy S, et al. The molecular genet-ics and morphometry-based endometrial intraepithelial neo-plasia classification system predicts disease progression in endometrial hyperplasia more accurately than the 1994 World Health Organization classification system. Cancer. 2005;103:2304-2312. 40. Cooper JM, Brady RM. Intraoperative and early postoperative complications of operative hysteroscopy. Obstet Gynecol Clin North Am. 2000;27:347-366. 41. Worldwide AAMIG. AAGL practice report: practice guide-lines for the management of hysteroscopic distending media: (replaces hysteroscopic fluid monitoring guidelines. J Am Assoc Gynecol Laparosc. 2000;7:167-168.). J Minim Invasive Gynecol. 2013;20:137-148. 42. ACOG Practice Bulletin. Clinical management guidelines for obstetrician-gynecologists. Number 81, May 2007. Obstet Gynecol. 2007;109:1233-1248. 43. Longinotti MK, Jacobson GF, Hung Y-Y, Learman LA. Prob-ability of hysterectomy after endometrial ablation. Obstet Gynecol. 2008;112:1214-1220. 44. van Dongen H, Emanuel MH, Wolterbeek R, Trimbos JB, Jansen FW. Hysteroscopic morcellator for removal of intra-uterine polyps and myomas: a randomized controlled pilot study among residents in training. J Minim Invasive Gynecol. 2008;15:466-471. 45. Steller CJ, Miller CE. Uterine Morcellation 15. Hyster-ectomy: a comprehensive surgical approach. JSLS. 2017; 21(1):e2016.00095. 46. Cohen SL, Vitonis AF, Einarsson JI. Updated hysterectomy surveillance and factors associated with minimally invasive hysterectomy. JSLS. 2014;18:e2014.00096. 47. Creinin MD, Zite N. Female tubal sterilization: the time has come to routinely consider removal. Obstet Gynecol. 2014;124:596-599. 48. Boing C, Kimmig R. Surgical management of endometriosis— an overview (in German). Gynakol Geburtshilfliche Rundsch. 2007;47:124-131. 49. Petta CA, Matos AM, Bahamondes L, Faundes D. Current practice in the management of symptoms of endometriosis: a survey of Brazilian gynecologists. Rev Assoc Med Bras. 2007;53:525-529. 50. Pearce CL, Templeman C, Rossing MA, et al. Association between endometriosis and risk of histological subtypes of ovarian cancer: a pooled analysis of case–control studies. Lancet Oncol. 2012;13:385-394. 51. Wiegand KC, Shah SP, Al-Agha OM, et al. ARID1A muta-tions in endometriosis-associated ovarian carcinomas. N Engl J Med. 2010;363:1532-1543. 52. Yamamoto S, Tsuda H, Takano M, Tamai S, Matsubara O. Loss of ARID1A protein expression occurs as an early event in ovarian clear-cell carcinoma development and frequently coexists with PIK3CA mutations. Mod Pathol. 2012;25: 615-624. 53. Soper DE. Pelvic inflammatory disease. Obstet Gynecol. 2010;116:419-428. 54. Brunham RC, Gottlieb SL, Paavonen J. Pelvic inflammatory disease. N Engl J Med. 2015;372:2039-2048. 55. Control CfD, Prevention. Sexually transmitted diseases treat-ment guidelines, 2015. Ann Emerg Med. 2015;66:526-528. 56. Menacker F, Hamilton BE. Recent trends in cesarean delivery in the United States. NCHS Data Brief. 2010;(35):1-8. 57. Dietrich CS 3rd, Hill CC, Hueman M. Surgical diseases pre-senting in pregnancy. Surg Clin North Am. 2008;88:403-419, vii-viii. 58. Gabbe S, Niebyl J, Simpson J. Obstetrics: Normal and Problem Pregnancies. 6th ed. Philadelphia: Saunders; 2012. 59. Brown HL. Trauma in pregnancy. Obstet Gynecol. 2009;114:147-160. 60. Early pregnancy loss. Practice Bulletin No. 150. American College of Obstetricians and Gynecologists. Obstet Gynecol. 2015;125:1258-1267. 61. Secura GM, Madden T, McNicholas C, et al. Provision of no-cost, long-acting contraception and teenage pregnancy. N Engl J Med. 2014;2014:1316-1323. 62. Owen J, Mancuso M. Cervical cerclage for the prevention of preterm birth. Obstet Gynecol Clin North Am. 2012;39:25-33. 63. McDonald IA. Suture of the cervix for inevitable miscarriage. J Obstet Gynaecol Br Emp. 1957;64:346-350. 64. Shirodkar V. New method of operative treatment for habitual abortions in the second trimester of pregnancy. Antiseptic. 1955;52:299. 65. Stock L, Milad M. Surgical management of ectopic pregnancy. Clin Obstet Gynecol. 2012;55:448-454. 66. Porreco RP, Stettler RW. Surgical remedies for postpartum hemorrhage. Clin Obstet Gynecol. 2010;53:182-195. 67. Bakri YN, Amri A, Abdul Jabbar F. Tamponade-balloon for obstetrical bleeding. Int J Gynaecol Obstet 2001;74:139-142. 68. Silver RM, Landon MB, Rouse DJ, et al. Maternal morbid-ity associated with multiple repeat cesarean deliveries. Obstet Gynecol. 2006;107:1226-1232. 69. Silver RM, Barbour KD. Placenta accreta spectrum: accreta, increta, and percreta. Obstet Gynecol Clin North Am. 2015; 42:381-402. 70. American College of Obstetricians and Gynecologists. Placenta Accreta Committee Opinion, Number 529. Obstet Gynecol. 2012;120:207-211. 71. Sentilhes L, Ambroselli C, Kayem G, et al. Maternal out-come after conservative treatment of placenta accreta. Obstet Gynecol. 2010;115:526-534. 72. Walters M, Karram M. Urogynecology and Reconstructive Pelvic Surgery. Philadelphia: Mosby; 2007. 73. Olsen AL, Smith VJ, Bergstrom JO, Colling JC, Clark AL. Epidemiology of surgically managed pelvic organ prolapse and urinary incontinence. Obstet Gynecol. 1997;89:501-506. 74. Bump RC, Mattiasson A, Bo K, et al. The standardization of terminology of female pelvic organ prolapse and pelvic floor dysfunction. Am J Obstet Gynecol. 1996;175:10-17. 75. Benson JT, Lucente V, McClellan E. Vaginal versus abdomi-nal reconstructive surgery for the treatment of pelvic support defects: a prospective randomized study with long-term out-come evaluation. Am J Obstet Gynecol. 1996;175:1418-1421; discussion 1421-1412. 76. Maher CF, Qatawneh AM, Dwyer PL, Carey MP, Cornish A, Schluter PJ. Abdominal sacral colpopexy or vaginal sacrospi-nous colpopexy for vaginal vault prolapse: a prospective ran-domized study. Am J Obstet Gynecol. 2004;190:20-26. 77. Center for Devices and Radiological Health. Urogynecologic surgical mesh: update on the safety and effectiveness of trans-vaginal placement for pelvic organ prolapse. Available at: http://www.fda.gov/downloads/medicaldevices/safety/alert-sandnotices/ucm262760.pdf. Accessed August 11, 2018.Brunicardi_Ch41_p1783-p1826.indd 182318/02/19 4:35 PM 1824SPECIFIC CONSIDERATIONSPART II 78. Nygaard IE, McCreery R, Brubaker L, et al. Abdominal sacrocolpopexy: a comprehensive review. Obstet Gynecol. 2004;104:805-823. 79. Tanagho EA. Colpocystourethropexy: the way we do it. J Urol. 1976;116:751-753. 80. Reynolds WS, Dmochowski RR. Urethral bulking: a urology perspective. Urol Clin North Am. 2012;39:279-287. 81. The US Food and Drug Administration. Urogynecologic surgi-cal mesh: update on the safety and effectiveness of transvaginal placement for pelvic organ prolapse. Safety Communication. Silver Spring, MD; 2011. 82. American Urogynecologic Society’s Guidelines Development Committee. Guidelines for providing privileges and creden-tials to physicians for transvaginal placement of surgical mesh for pelvic organ prolapse. Female Pelvic Med Reconstr Surg. 2012;18:194-197. 83. American Urogynecologic Society’s Guidelines Development Committee. Guidelines for privileging and credentialing phy-sicians for sacrocolpopexy for pelvic organ prolapse. Female Pelvic Med Reconstr Surg. 2013;19:62-65. 84. Siegel R, Naishadham D, Jemal A. Cancer statistics, 2012. CA Cancer J Clin. 2012;62:10-29. 85. Carter JS, Downs LS, Jr. Vulvar and vaginal cancer. Obstet Gynecol Clin North Am. 2012;39:213-231. 86. Berek JS, Hacker NF. Practical Gynecologic Oncology. 5th ed. Philadelphia: Lippincott, Williams and Wilkins; 2010. 87. Disaia P, Creasman W. Clinical Gynecologic Oncology. 8th ed. Philadelphia: Saunders; 2012. 88. Montana GS, Thomas GM, Moore DH, et al. Preoperative chemo-radiation for carcinoma of the vulva with N2/N3 nodes: a gynecologic oncology group study. Int J Radiat Oncol Biol Phys. 2000;48:1007-1013. 89. Moore DH, Thomas GM, Montana GS, Saxer A, Gallup DG, Olt G. Preoperative chemoradiation for advanced vulvar cancer: a phase II study of the Gynecologic Oncology Group. Int J Radiat Oncol Biol Phys. 1998;42:79-85. 90. Shylasree TS, Bryant A, Howells RE. Chemoradiation for advanced primary vulval cancer. Cochrane Database Syst Rev. 2011:CD003752. 91. Levenback CF, Ali S, Coleman RL, et al. Lymphatic mapping and sentinel lymph node biopsy in women with squamous cell carcinoma of the vulva: a gynecologic oncology group study. J Clin Oncol. 2012;30:3786-3791. 92. Te Grootenhuis NC, van der Zee AG, van Doorn HC, et al. Sentinel nodes in vulvar cancer: long-term follow-up of the GROningen INternational Study on Sentinel nodes in Vulvar cancer (GROINSS-V) I. Gynecol Oncol. 2016;140:8-14. 93. Goodman A, Schorge J, Greene MF. The long-term effects of in utero exposures—the DES story. N Engl J Med. 2011;364:2083-2084. 94. Beller U, Benedet JL, Creasman WT, et al. Carcinoma of the vagina. FIGO 6th Annual report on the results of treatment in gynecological cancer. Int J Gynaecol Obstet. 2006;95 (suppl 1): S29-S42. 95. Barakat RMM, Randall M. Principles and Practice of Gyne-cologic Oncology. 5th ed. Philadelphia: Lippincott, Williams, and Wilkins; 2009. 96. Siegel RL, Miller KD, Jemal A. Cancer statistics, 2017. CA Cancer J Clin. 2017;67:7-30. 97. Jemal A, Bray F, Center MM, Ferlay J, Ward E, Forman D. Global cancer statistics. CA Cancer J Clin. 2011;61:69-90. 98. Wright TC, Jr, Massad LS, Dunton CJ, Spitzer M, Wilkinson EJ, Solomon D. 2006 consensus guidelines for the manage-ment of women with cervical intraepithelial neoplasia or ade-nocarcinoma in situ. J Low Genit Tract Dis. 2007;11:223-239. 99. Pecorelli S. Revised FIGO staging for carcinoma of the vulva, cervix, and endometrium. Int J Gynaecol Obstet. 2009;105:103-104. 100. Pikaart DP, Holloway RW, Ahmad S, et al. Clinical-patho-logic and morbidity analyses of Types 2 and 3 abdominal radical hysterectomy for cervical cancer. Gynecol Oncol. 2007;107:205-210. 101. Kim CH, Abu-Rustum NR, Chi DS, et al. Reproductive out-comes of patients undergoing radical trachelectomy for early-stage cervical cancer. Gynecol Oncol. 2012;125:585-588. 102. Leslie KK, Thiel KW, Goodheart MJ, De Geest K, Jia Y, Yang S. Endometrial cancer. Obstet Gynecol Clin North Am. 2012;39:255-268. 103. Cancer Genome Atlas Research N, Kandoth C, Schultz N, et al. Integrated genomic characterization of endometrial carcinoma. Nature. 2013;497:67-73. 104. Stelloo E, Bosse T, Nout RA, et al. Refining prognosis and iden-tifying targetable pathways for high-risk endometrial cancer; a TransPORTEC initiative. Mod Pathol. 2015;28(6):836-844. 105. Talhouk A, McConechy MK, Leung S, et al. A clinically appli-cable molecular-based classification for endometrial cancers. Br J Cancer. 2015;113:299-310. 106. Walker JL, Piedmonte MR, Spirtos NM, et al. Recurrence and survival after random assignment to laparoscopy versus laparotomy for comprehensive surgical staging of uterine cancer: Gynecologic Oncology Group LAP2 study. J Clin Oncol. 2012;30:695-700. 107. Whitney C, Spirtos N. Gynecologic Oncology Group Surgical Procedures Manual. Philadelphia: Gynecologic Oncology Group; 2009. 108. Creutzberg CL, Nout RA, Lybeert ML, et al. Fifteen-year radiotherapy outcomes of the randomized PORTEC-1 trial for endometrial carcinoma. Int J Radiat Oncol Biol Phys. 2011;81:e631-e638. 109. Keys HM, Roberts JA, Brunetto VL, et al. A phase III trial of surgery with or without adjunctive external pelvic radia-tion therapy in intermediate risk endometrial adenocarci-noma: a Gynecologic Oncology Group study. Gynecol Oncol. 2004;92:744-751. 110. Holloway RW, Abu-Rustum NR, Backes FJ, et al. Sentinel lymph node mapping and staging in endometrial cancer: a Society of Gynecologic Oncology literature review with consensus recommendations. Gynecologic Oncology. 2017;146:405-415. 111. Aarnio M, Mecklin JP, Aaltonen LA, Nystrom-Lahti M, Jarvinen HJ. Life-time risk of different cancers in hereditary non-polyposis colorectal cancer (HNPCC) syndrome. Int J Cancer. 1995;64:430-433. 112. Reichardt P. The treatment of uterine sarcomas. Ann Oncol. 2012;23(suppl 10):x151-x157. 113. Jacobs IJ, Menon U, Ryan A, et al. Ovarian cancer screening and mortality in the UK Collaborative Trial of Ovarian Cancer Screening (UKCTOCS): a randomised controlled trial. Lancet. 2016;387:945-956. 114. Buys SS, Partridge E, Black A, et al. Effect of screening on ovarian cancer mortality: the prostate, lung, colorectal and ovarian (PLCO) cancer screening randomized controlled trial. JAMA. 2011;305:2295-2303. 115. van Nagell Jr JR, Miller RW, DeSimone CP, et al. Long-term survival of women with epithelial ovarian cancer detected by ultrasonographic screening. Obstet Gynecol. 2011;118:1212-1221. 116. Kobayashi H, Yamada Y, Sado T, et al. A randomized study of screening for ovarian cancer: a multicenter study in Japan. Int J Gynecol Cancer. 2008;18:414-420. 117. Goff BA, Mandel LS, Drescher CW, et al. Development of an ovarian cancer symptom index: possibilities for earlier detec-tion. Cancer. 2007;109:221-227. 118. Kurman RJ, Shih Ie M. Molecular pathogenesis and extraovar-ian origin of epithelial ovarian cancer—shifting the paradigm. Hum Pathol. 2011;42:918-931.Brunicardi_Ch41_p1783-p1826.indd 182418/02/19 4:35 PM 1825GYNECOLOGYCHAPTER 41 119. Jarboe EA, Folkins AK, Drapkin R, Ince TA, Agoston ES, Crum CP. Tubal and ovarian pathways to pelvic epithelial cancer: a pathological perspective. Histopathology. 2009; 55:619. 120. Steffensen KD, Waldstrom M, Grove A, Lund B, Pallisgard N, Jakobsen A. Improved classification of epithelial ovarian cancer: results of 3 Danish cohorts. Int J Gynecol Cancer. 2011;21:1592-1600. 121. Kurman RJ, Shih Ie M. The dualistic model of ovarian car-cinogenesis: revisited, revised, and expanded. Am J Pathol. 2016;186:733-747. 122. Collaborative Group on Epidemiological Studies of Ovarian C. Ovarian cancer and oral contraceptives: collabora-tive reanalysis of data from 45 epidemiological studies includ-ing 23 257 women with ovarian cancer and 87 303 controls. Lancet. 2009;371:303-314. 123. Al Bakir M, Gabra H. The molecular genetics of hereditary and sporadic ovarian cancer: implications for the future. Br Med Bull. 2014;112:57-69. 124. Weissman SM, Weiss SM, Newlin AC. Genetic testing by cancer site: ovary. Cancer J. 2012;18:320-327. 125. Walsh T, Casadei S, Lee MK, et al. Mutations in 12 genes for inherited ovarian, fallopian tube, and peritoneal carcinoma identified by massively parallel sequencing. Proc Natl Acad Sci U S A. 2011;108:18032-18037. 126. Walker JL, Powell CB, Chen LM, et al. Society of Gyneco-logic Oncology recommendations for the prevention of ovar-ian cancer. Cancer. 2015;121:2108-2120. 127. Pal T, Permuth-Wey J, Betts JA, et al. BRCA1 and BRCA2 mutations account for a large proportion of ovarian carcinoma cases. Cancer. 2005;104:2807-2816. 128. Norquist BM, Harrell MI, Brady MF, et al. Inherited muta-tions in women with ovarian carcinoma. JAMA Oncol. 2016;2:482-490. 129. Wentzensen N, Poole EM, Trabert B, et al. Ovarian can-cer risk factors by histologic subtype: an analysis from the Ovarian Cancer Cohort Consortium. J Clin Oncol. 2016;34: 2888-2898. 130. Antoniou A, Pharoah PDP, Narod S, et al. Average risks of breast and ovarian cancer associated with BRCA1 or BRCA2 mutations detected in case series unselected for family his-tory: a combined analysis of 22 studies. Am J Human Genet. 2003;72:1117-1130. 131. Alsop K, Fereday S, Meldrum C, et al. BRCA mutation frequency and patterns of treatment response in brca mutation– positive women with ovarian cancer: a report from the Australian Ovarian Cancer Study Group. J Clin Oncol. 2012;30:2654-2663. 132. Arts-de Jong M, de Bock GH, van Asperen CJ, Mourits MJE, de Hullu JA, Kets CM. Germline BRCA1/2 mutation testing is indicated in every patient with epithelial ovarian cancer: a systematic review. Eur J Cancer. 2016;61:137-145. 133. Zhang S, Royer R, Li S, et al. Frequencies of BRCA1 and BRCA2 mutations among 1,342 unselected patients with inva-sive ovarian cancer. Gynecol Oncol. 2011;121:353-357. 134. Daly MB, Axilbund JE, Buys S, et al. Genetic/familial high-risk assessment: breast and ovarian. J Natl Compr Canc Netw. 2010;8:562-594. 135. Mavaddat N, Peock S, Frost D, et al. Cancer risks for BRCA1 and BRCA2 mutation carriers: results from pro-spective analysis of EMBRACE. J Natl Cancer Inst Monogr. 2013;105:812-822. 136. Piek JM, van Diest PJ, Zweemer RP, et al. Dysplastic changes in prophylactically removed Fallopian tubes of women predisposed to developing ovarian cancer. J Pathol. 2001;195:451-456. 137. Kuhn E, Kurman R, Shih I-M. Ovarian cancer is an imported disease: fact or fiction? Curr Obstet Gynecol Rep. 2012;1:1-9. 138. Kauff ND, Satagopan JM, Robson ME, et al. Risk-reducing salpingo-oophorectomy in women with a BRCA1 or BRCA2 mutation. N Engl J Med. 2002;346:1609-1615. 139. ACOG. Elective and risk-reducing salpingo-oopherectomy. ACOG Practice Bulletin. 2008;89:1-12. 140. Madsen C, Baandrup L, Dehlendorff C, Kjær SK. Tubal ligation and salpingectomy and the risk of epithelial ovarian cancer and borderline ovarian tumors: a nationwide case– control study. Acta Obstetricia et Gynecologica Scandinavica. 2015;94:86-94. 141. Bijron JG, Seldenrijk CA, Zweemer RP, Lange JG, Verheijen RH, van Diest PJ. Fallopian tube intraluminal tumor spread from noninvasive precursor lesions: a novel meta-static route in early pelvic carcinogenesis. Am J Surg Pathol. 2013;37:1123-1130. 142. McAlpine JN, Hanley GE, Woo MM, et al. Opportunistic sal-pingectomy: uptake, risks, and complications of a regional initiative for ovarian cancer prevention. Am J Obstet Gynecol. 2014;210:e471. 143. Young RC, Walton LA, Ellenberg SS, et al. Adjuvant therapy in stage I and stage II epithelial ovarian cancer. N Engl J Med. 1990;322:1021-1027. 144. Bell J, Brady MF, Young RC, et al. Randomized phase III trial of three versus six cycles of adjuvant carboplatin and paclitaxel in early stage epithelial ovarian carcinoma: a Gynecologic Oncology Group study. Gynecol Oncol. 2006;102:432-439. 145. Young RC, Decker DG, Wharton JT, et al. Staging laparotomy in early ovarian cancer. JAMA. 1983;250:3072-3076. 146. Chang SJ, Hodeib M, Chang J, Bristow RE. Survival impact of complete cytoreduction to no gross residual disease for advanced-stage ovarian cancer: a meta-analysis. Gynecol Oncol. 2013;130:493-498. 147. Vergote I, Trope CG, Amant F, et al. Neoadjuvant chemo-therapy or primary surgery in stage IIIC or IV ovarian cancer. N Engl J Med. 2010;363:943-953. 148. Kehoe S, Hook J, Nankivell M, et al. Primary chemotherapy versus primary surgery for newly diagnosed advanced ovar-ian cancer (CHORUS): an open-label, randomised, controlled, non-inferiority trial. Lancet. 2015;386:249-257. 149. Gómez-Hidalgo NR, Martinez-Cannon BA, Nick AM, et al. Predictors of optimal cytoreduction in patients with newly diagnosed advanced-stage epithelial ovarian cancer: time to incorporate laparoscopic assessment into the standard of care. Gynecol Oncol. 2015;137:553-558. 150. McGuire WP, Hoskins WJ, Brady MF, et al. Cyclophospha-mide and cisplatin compared with paclitaxel and cisplatin in patients with stage III and stage IV ovarian cancer [see com-ments]. N Engl J Med. 1996;334:1-6. 151. Armstrong DK, Bundy BN, Wenzel L, et al. Intraperitoneal cisplatin and paclitaxel in ovarian cancer. N Engl J Med. 2006;354:34-43. 152. Walker JL, Armstrong DK, Huang HQ, et al. Intraperitoneal catheter outcomes in a phase III trial of intravenous versus intraperitoneal chemotherapy in optimal stage III ovarian and primary peritoneal cancer: a Gynecologic Oncology Group Study. Gynecol Oncol. 2006;100:27-32. 153. Chi DS, Phaeton R, Miner TJ, et al. A prospective outcomes analysis of palliative procedures performed for malignant intestinal obstruction due to recurrent ovarian cancer. Oncolo-gist. 2009;14:835-839. 154. Markman M, Reichman B, Hakes T, Jones W. Responses to second-line cisplatin-based intraperitoneal therapy in ovarian cancer: influence of a prior response to intravenous cisplatin. J Clin Oncol. 1991;9:1801-1805. 155. Gershenson DM. Treatment of ovarian cancer in young women. Clin Obstet Gynecol. 2012;55:65-74. 156. Mangili G, Sigismondi C, Lorusso D, et al. The role of stag-ing and adjuvant chemotherapy in stage I malignant ovarian Brunicardi_Ch41_p1783-p1826.indd 182518/02/19 4:35 PM 1826SPECIFIC CONSIDERATIONSPART IIgerm cell tumors (MOGTs): the MITO-9 study. Ann Oncol. 2017;28:333-338. 157. Merard R, Ganesan R, Hirschowitz L. Growing teratoma syn-drome: a report of 2 cases and review of the literature. Int J Gynecol Pathol. 2015;34:465-472. 158. Lurain JR. Gestational trophoblastic disease II: classification and management of gestational trophoblastic neoplasia. Am J Obstet Gynecol. 2011;204:11-18. 159. Ngan HYS, Seckl MJ, Berkowitz RS, et al. Update on the diagnosis and management of gestational trophoblastic dis-ease. Int J Gynecol Obstet. 2015;131:S123-S126. 160. Seckl MJ, Sebire NJ, Berkowitz RS. Gestational trophoblastic disease. Lancet. 2010;376:717-729. 161. Sinha R, Sundaram M, Mahajan C, et al. Single-incision total laparoscopic hysterectomy. J Minim Access Surg. 2011;7:78-82. 162. Sinha RY, Raje SR, Rao GA. Three-dimensional lapa-roscopy: principles and practice. J Minim Access Surg. 2017;13:165-169. 163. Gaia G, Holloway RW, Santoro L, Ahmad S, Di Silverio E, Spinillo A. Robotic-assisted hysterectomy for endome-trial cancer compared with traditional laparoscopic and laparotomy approaches: a systematic review. Obstet Gynecol. 2010;116:1422-1431. 164. Llarena NC, Shah AB, Milad MP. Bowel injury in gyneco-logic laparoscopy: a systematic review. Obstet Gynecol. 2015;125:1407-1417. 165. Sharp HT, Adelman MR. Prevention, recognition, and man-agement of urologic injuries during gynecologic surgery. Obstet Gynecol. 2016;127:1085-1096. 166. Teeluckdharry B, Gilmour D, Flowerdew G. Urinary tract injury at benign gynecologic surgery and the role of cystos-copy: a systematic review and meta-analysis. Obstet Gynecol. 2015;126:1161-1169. 167. Centers for Disease Control and Prevention. Sexually Trans-mitted Diseases Treatment Guidelines: Pelvic Inflammatory Disease. Available: https://www.cdc.gov/std/tg2015/pid.htm. Accessed August 11, 2018. 168. Dearking AC, Aletti GD, McGree ME, Weaver AL, Som-merfield MK, Cliby WA. How relevant are ACOG and SGO guidelines for referral of adnexal mass? Obstet Gynecol. 2007;110:841-848. 169. Mutch DG, Prat J. 2014 FIGO staging for ovarian, fallopian tube and peritoneal cancer. Gynecol Oncol. 2014;133:401-404.Brunicardi_Ch41_p1783-p1826.indd 182618/02/19 4:35 PM
NeurosurgeryAshwin G. Ramayya, Saurabh Sinha, and M. Sean Grady 42chapterOverview 1827Neuroanatomy 1827Neurologic Examination 1829Diagnostic Studies / 1829Neurologic and Neurosurgical  Emergencies 1831Raised Intracranial Pressure / 1831Brain Stem Compression / 1833Stroke / 1833Seizure / 1833Trauma 1833Head Trauma / 1833Spine Trauma / 1842Peripheral Nerve Trauma / 1847Cerebrovascular Disease 1849Ischemic Diseases / 1849Thrombotic Disease / 1849Embolic Disease / 1849Hemorrhagic Diseases / 1850Tumors of the Central Nervous  System 1854Intracranial Tumors / 1854Metastatic Tumors / 1854Glial Tumors / 1855Neural Tumors and Mixed Tumors / 1857Neural Crest Tumors / 1857Miscellaneous Tumors / 1857Embryologic Tumors / 1858Spinal Tumors / 1859Future Directions / 1861Spine: Basic Concepts 1861Stability / 1861Neural Compression / 1862Patterns of Disease / 1862Spine Fusion Surgery / 1865Spinal Instrumentation / 1865Arthrodesis / 1866Peripheral Nerve 1866Peripheral Nerve Tumors / 1866Entrapment Neuropathies / 1867Autoimmune and Inflammatory Disorders / 1867Infection 1867Cranial / 1867Spine / 1868Functional Neurosurgery 1869Epilepsy Surgery / 1869Deep Brain Stimulation / 1869Trigeminal Neuralgia / 1871Stereotactic Radiosurgery 1871Arteriovenous Malformations / 1872Vestibular Schwannomas / 1872Intracranial Metastases / 1872Congenital and Developmental  Anomalies 1872Dysraphism / 1872Spina Bifida Occulta / 1872Spina Bifida With Myelomeningocele / 1872Encephalocele / 1872Craniosynostosis / 1872Hydrocephalus / 1873Chiari I Malformation / 1873OVERVIEWNeurologic surgery provides the operative and nonoperative man-agement (i.e., prevention, diagnosis, evaluation, treatment, criti-cal care, and rehabilitation) of disorders of the central, peripheral, and autonomic nervous systems (ANSs). Such disorders include those of the brain, meninges, skull and skull base, and their blood supply, including surgical and endovascular treat-ment of disorders of the intracranial and extracranial vasculature supplying the brain and spinal cord; disorders of the pituitary gland; disorders of the spinal cord, meninges, and vertebral col-umn, including those that may require treatment by fusion, instru-mentation, or endovascular techniques; and disorders of the cranial and spinal nerves throughout their distribution.An accurate history is the first step toward neurologic diagnosis. A history of trauma or of neurologic symptoms is of obvious interest, but general constitutional symptoms are also important. Neurologic disease may have systemic effects, while diseases of other systems may affect neurologic function. The patient’s general medical ability to withstand the physi-ologic stress of anesthesia and surgery should be understood. A detailed history from the patient and/or family, along with a reliable physical examination, will clarify these issues.NEUROANATOMYAn understanding of neuroanatomy is the foundation of com-prehensive neurologic examination and diagnosis. Salient fea-tures will be considered, from cephalad to caudad. The cerebral hemispheres (or telencephalon) consist of the cerebral cortex, underlying white matter, the basal ganglia, hippocampus, and amygdala. The cerebral cortex is the most recently evolved part of the nervous system. Its functions are mapped to discrete ana-tomic areas. The frontal areas are involved in executive function, decision making, and restraint of emotions. The motor strip, or precentral gyrus, is the most posterior component of the frontal lobes, and is arranged along a homunculus with the head inferior and lateral to the lower extremities superiorly and medially. The motor speech area (Broca’s area) lies in the left posterior inferior frontal lobe in almost all right-handed people and in up to 90% of left-handed people. The parietal lobe lies between the central sulcus anteriorly and the occipital lobe posteriorly. The postcen-tral gyrus is the sensory strip, also arranged along a homunculus. The rest of the parietal lobe is involved with awareness of one’s body in space and relative to the immediate environment, body orientation, and spatial relationships. The occipital lobes are most posterior. The visual cortex is arrayed along the apposing 1Brunicardi_Ch42_p1827-p1878.indd 182701/03/19 7:16 PM 1828medial surfaces of the occipital lobes. The left occipital lobe receives and integrates data from the left half of each retina. A left occipital lesion would therefore result in an inability to see objects right of center. The temporal lobes lie below the Sylvian fissures. The hippocampus, amygdala, and lower optic radia-tions (Meyer’s loops) are important components of the temporal lobe and are involved in memory, emotion, and vision, respec-tively. The receptive speech area (Wernicke’s area) typically is found in the area of the left posterior superior temporal lobe and inferior parietal lobe. The basal ganglia include the caudate, putamen, globus pallidus, subthalamic nucleus, substantia nigra, and nucleus accumbens. These structures are involved in the selection, activation and termination of movement, and facilitate learning of appropriate context-dependent motor behaviors.Lying deep to the cerebral hemispheres is the diencepha-lon, which includes the thalamus and hypothalamus. The thala-mus is a key processor and relay circuit for most motor and sensory information traveling to or from cortex. The hypothala-mus regulates homeostasis via the autonomic and neuroendo-crine systems.The brain stem consists of the midbrain (mesencephalon), pons (metencephalon), and medulla (myelencephalon). Longi-tudinal fibers run through the brain stem, carrying motor and sensory information between the cerebral hemispheres and spi-nal cord. The corticospinal tract is the major motor tract, while the medial lemniscus and spinothalamic tracts are the major sensory tracts. The nuclei of cranial nerves III through XII are also located within the brain stem. These nerves relay the motor, sensory, and special sense functions of the eye, face, mouth, and throat.The cerebellum arises from the dorsal aspect of the brain stem. It integrates somatosensory, vestibular, and motor infor-mation for coordination and timing of movement. Midline, or vermian, lesions lead to truncal ataxia. Lateral, or hemispheric, lesions lead to tremor and dyscoordination in the extremities.The ventricular system is the cerebrospinal fluid (CSF)–containing contiguous space inside the brain, continuous with the subarachnoid space outside the brain. The paired lateral ventricles consist of temporal, occipital, and frontal horns, as well as the main body. CSF travels from each lateral ventricle through the foramina of Monroe to the third ventricle, located between the left and right thalami. CSF then drains through the cerebral aqueduct to the fourth ventricle within the brain stem. The foramen of Magendie (midline) and paired foram-ina of Luschka (lateral) drain to the subarachnoid space. The approximate CSF volume in an average adult is 150 mL, and the choroid plexus produces approximately 500 mL of CSF per day.The spinal cord starts at the bottom of the medulla and extends caudally through the spinal canal to the first lumbar ver-tebra, approximately. Motor tracts (efferent pathways) continue from the brain stem down via the lateral and anterior corticospi-nal tracts to anterior horn cells, and then exit via ventral nerve roots. Sensory information (afferent pathways) enters via dorsal nerve roots, travels cranially via the dorsal columns (proprio-ception and fine touch) or spinothalamic tract (pain and tem-perature), and into the brain stem. Paired nerves exit the spinal cord at each level. There are 31 pairs: 8 cervical, 12 thoracic, 5 lumbar, 5 sacral, and 1 coccygeal.The dorsal and ventral nerve roots at each level fuse to form mixed motor-sensory spinal nerves and spread through the body to provide innervation to muscles and sensory organs. The C5–T1 spinal nerves intersect in the brachial plexus and divide to form the main nerve branches to the arm, including the median, ulnar, and radial nerves. The L2–S4 spinal nerves intersect in the lumbosacral plexus, and divide to form the main nerve branches to the leg, including the femoral and sciatic nerves.The principal motor tract of the spinal cord is the cortico-spinal tract. It is a two-neuron path, including an upper motor neuron and a lower motor neuron. The upper motor neuron cell body is located within the motor strip of the cerebral cortex. The axon travels through the internal capsule to the brain stem, decussates at the brain stem–spinal cord junction, and travels down the contralateral corticospinal tract to the lower motor Key Points1 Neurologic surgery specializes in primarily surgical manage-ment of central, peripheral, and autonomic nervous system disorders.2 Although clinical examination is paramount, neurosurgical diagnosis and treatment are aided largely by a variety of modalities, such as magnetic resonance imaging and intra-cranial pressure monitoring.3 The common treatment goals for traumatic brain and spinal injury are aimed at preventing secondary insults of hypoxia and hypotension.4 Aneurysmal subarachnoid hemorrhage remains one of the most morbid and intensive neurosurgical diseases. Endovas-cular therapy is a growing technology that allows for safer securing of ruptured aneurysms.5 Brain tumors can arise from primary or metastatic tissues. Treatment typically involves resection, followed by radia-tion and/or chemotherapy, depending on the type and grade of tumor.6 Spinal instrumentation is used for surgical stabilization of many types of spinal instability, including traumatic, infec-tious, oncologic, and degenerative.7 Infection of the nervous system is a serious and prevalent medical problem. Operative management is indicated for most conditions in which there is symptomatic compression of neural structures.8 Functional neurosurgery via device implantation is a rapidly evolving discipline that has already become the standard of care in treating medically refractory Parkinson’s disease and essential tremor. A wider variety of deep brain stimulation targets will treat additional neuropsychiatric diseases.9 Stereotactic radiosurgery is a powerful treatment option for intracranial disease, whether it is primary or adjunct. Gamma knife surgery can be used to treat tumors, vascular malfor-mations, and cranial neuralgias.Brunicardi_Ch42_p1827-p1878.indd 182801/03/19 7:16 PM 1829NEUROSURGERYCHAPTER 42neuron in the anterior horn at the appropriate level. The lower motor neuron axon then travels via peripheral nerves to its tar-get muscle. Damage to upper motor neurons typically results in hyperreflexia and mild atrophy. Damage to lower motor neurons results in flaccidity and significant atrophy.The two major sensory tracts are three-neuron pathways. Fine touch and proprioceptive signals enter the spinal cord via the dorsal root ganglia and then ascend ipsilaterally via the dorsal columns. Then they synapse and decussate in the lower medulla, travel up the contralateral medial lemniscus to make a second synapse in the thalamus, and then finally ascend to the sensory cortex. Pain and temperature fibers first synapse in the dorsal horn of the spinal cord at their entry level, decussate, and then travel up the contralateral spinothalamic tracts to the thalamus. The second synapse occurs in the thalamus, and the output axons ascend to the sensory cortex.The aforementioned motor and sensory tracts together constitute the somatic nervous system. In addition to this sys-tem, the ANS is the other constituent of the nervous system. The ANS carries messages for homeostasis and visceral regu-lation from the central nervous system (CNS) to target struc-tures such as arteries, veins, the heart, sweat glands, and the digestive tract.1 CNS control of the ANS arises particularly from the hypothalamus and the nucleus of the tractus solitarius. The ANS is divided into the sympathetic, parasympathetic, and enteric systems. The sympathetic system drives the “fight or flight” response, using epinephrine to increase heart rate, blood pressure, blood glucose, and temperature, as well as to dilate the pupils. It arises from the thoracolumbar spinal segments. The parasympathetic system promotes the “rest and digest” state and uses acetylcholine to maintain basal metabolic func-tion under nonstressful conditions. Parasympathetic fibers arise from cranial nerves III, VII, IX, and X, and from the second to fourth sacral segments. The enteric nervous system controls the complex synchronization of the digestive tract, especially the pancreas, gallbladder, and small and large bowels. It can run autonomously but is regulated by the sympathetic and parasym-pathetic systems.NEUROLOGIC EXAMINATIONThe neurologic examination is divided into several components and generally is done from head to toe. First, one must assess men-tal status. A patient may be awake, lethargic (will follow com-mands and answer questions, but then returns to sleep), stuporous (difficult to arouse), or comatose (no purposeful response to voice or pain). Cranial nerves may be thoroughly tested in the awake patient, but pupil reactivity, eye movement, facial symmetry, and gag are the most relevant measures when mental status is impaired. Motor testing is based on maximal effort of major muscle groups in those able to follow commands, while assessing for amplitude and symmetry of movement to deep central pain may be all that is possible for stuporous patients. Table 42-1 details scoring for motor assessment tests. Characteristic motor reactions to pain in patients with depressed mental status include withdrawal from stimulus, localization to stimulus, flexor (decorticate) posturing, extensor (decerebrate) posturing, or no reaction (in order of wors-ening pathology). Figure 42-1 diagrams the clinical patterns of posturing. This forms the basis of determining the Glasgow Coma Scale (GCS) motor score, as detailed in Table 42-2. Light touch, proprioception, temperature, and pain testing may be useful in awake patients but is often impossible without good cooperation. It is critical to document sensory patterns in spinal cord injury (SCI) patients. Muscle stretch reflexes should be examined. Often com-paring left to right or upper extremity to lower extremity reflexes for symmetry is the most useful for localizing a lesion. Check for ankle-jerk clonus or up-going toes (Babinski’s test). Presence of either is pathologic and signifies upper motor neuron disease.Diagnostic StudiesPlain Films. Plain X-rays of the skull may demonstrate frac-tures, osteolytic or osteoblastic lesions, radiolucent foreign bodies, or pneumocephaly (air in the head). Plain films of the cervical, thoracic, and lumbar spine are used to assess for evi-dence of bony trauma or soft tissue swelling suggesting fracture. Spinal deformities and osteolytic or osteoblastic pathologic pro-cesses also will be apparent. However, the use of plain films has decreased given the rapid availability and significantly increased detail of computed tomography (CT) scans. They are typically used for assessing alignment in patients with known fractures, for intraoperative localization, and postoperative assessment of spinal instrumentation.Computed Tomography. The noncontrast CT scan of the head is an extremely useful diagnostic tool in the setting of new focal neurologic deficit, decreased mental status, or trauma. It is rapid and almost universally available in hospitals in the United States. Its sensitivity allows for the detection of acute hemorrhage. Fine-slice CT scanning of the spine is helpful for defining bony anatomy and pathology and is the method of choice for iden-tifying fractures of the spine. By providing an assessment of spinal alignment, CT scans can provide an indirect assessment of ligamentous injury, for example, “Rule of Spence” for assess-ing transverse ligament injury during Jefferson fractures (see “Spine Trauma” section later in this chapter). Conventional con-trast-enhanced CT scan will help show neoplastic or infectious processes. In the current era, contrast CT generally is used for those patients who cannot undergo magnetic resonance imaging (MRI) scanning due to pacemakers or metal in the orbits (see following section for discussion of CT angiography, venogra-phy, and perfusion).Magnetic Resonance Imaging. Magnetic resonance imaging (MRI) provides excellent imaging of soft tissue structures in the head and spine. It is a complex and evolving science. Several of the most clinically useful MRI sequences are worth describing. T1 sequences made before and after gadolin-ium administration are useful for detecting neoplastic and infec-tious processes. T2 sequences facilitate assessment of 2Table 42-1Motor scoring systemGRADEDESCRIPTION0No muscle contraction1Visible muscle contraction without movement across the joint2Movement in the horizontal plane, unable to overcome gravity3Movement against gravity4Movement against some resistance5Normal strengthBrunicardi_Ch42_p1827-p1878.indd 182901/03/19 7:16 PM 1830SPECIFIC CONSIDERATIONSPART IITable 42-2The Glasgow Coma Scale scoreaMOTOR RESPONSE VERBAL RESPONSE EYE-OPENING RESPONSE Obeys commands6Oriented5Opens spontaneously4Localizes to pain5Confused4Opens to speech3Withdraws from pain4Inappropriate words3Opens to pain2Flexor posturing3Unintelligible sounds2No eye opening1Extensor posturing2No sounds1  No movement1    aAdd the three scores to obtain the Glasgow Coma Scale (GCS) score, which can range from 3 to 15. Add “T” after the GCS if intubated and no verbal score is possible. For these patients, the GCS can range from 3T to 10T.lesion-associated edema in the brain and neural compression in the spine by the presence or absence of bright T2 CSF signals. Fluid-attenuated inversion recovery (FLAIR) imaging is a T2 sequence with suppression of the CSF signal, so as to emphasize lesions and edema, particularly adjacent to the ventricles. Diffu-sion-weighted images is the gold-standard for identifying isch-emic stroke within 12 hours of symptom onset.2 Gradient echo sequences (GRE) can be used to identify acute-subacute blood products and are used to assess for micro-hemorrhages in trau-matic diffuse axonal injury (DAI), amyloid angiopathy, and also in the diagnosis of cavernous malformations. In the spine, short-tau inversion recovery (STIR) or fat-suppressed T2 sequences are useful for assessing for the acuity of fractures (by measuring bone edema), and identifying ligamentous injury.CT and MR Angiography. Recent advances in CT technol-ogy such as short acquisition times with multidetector technol-ogy has allowed for imaging of vascular anatomy. Fine-slice CT scans can be combined with a timed-bolus of intravenous contrast in the arterial phase (angiography, CTA) and venous phase (venography, CTV) to assess arterial and venous vascu-lature, respectively. Although traditional catheter-based angiog-raphy still serves as the gold-standard, CTA and CTV provide Figure 42-1. Patterns of motor responses associated with various lesions. A. Left hemispheric lesion with right hemiplegia and left local-ization. B. Deep cerebral/thalamic lesion with bilateral flexor posturing. C. Midbrain or pontine lesion with bilateral extensor posturing. D. Medullary lesion with general flaccidity. (Adapted with permission from Rengachary SS, Ellenbogen RG: Principles of Neurosurgery, 2nd ed. New York, NY: Elsevier/Mosby; 2005.)Brunicardi_Ch42_p1827-p1878.indd 183001/03/19 7:16 PM 1831NEUROSURGERYCHAPTER 42noninvasive alternative for the initial screening assessment and follow-up of patients with suspected or known vascular lesions, as well as the evaluation of vasospasm. Similarly, fine-slice time-of-flight axial images can be reformatted in three dimen-sions to build MRI angiograms and MRI venograms. MRI angiograms can detect stenosis of the cervical carotid arteries or intracranial aneurysms >3 mm in diameter. MRI venograms can assess the dural venous sinuses for patency or thrombosis. Two-dimensional time of flight imaging performs vascular reconstructions purely based on flow and does not require gado-linium contrast administration.CT and MR Perfusion. Perfusion scans have recently emerged as a method to a global assessment of the vascular integrity in the cerebral hemispheres, which is very important in the assess-ment of ischemic stroke (see “Stroke”). CT perfusion scans gen-erate quantitative color maps that indicate various physiologic parameters such as cerebral blood flow (CBF), cerebral blood volume (CBV), and mean transit time (MTT) through quan-titative analysis of rapidly acquired image sequences during intravenous contrast administration. Similar to perfusion CT, perfusion MRI can be used to generate quantitative color maps of relative cerebral CBV and MTT. These perfusion-based mea-sures can be used along with diffusion-weighted imaging in the evaluation of ischemic stroke, particularly to identify an isch-emic “penumbra” or tissue that is ischemic but not yet infarcted, and may be salvageable with intervention.3,4Angiography. Transarterial catheter-based angiography remains the gold standard for evaluation of vascular pathology of the brain and spine. The current state of the art is biplanar imaging to reduce dye load and facilitate interventional proce-dures. Digital subtraction technologies minimize bony inter-ference in the resultant images. Bilateral carotid arteries and bilateral vertebral arteries may be injected and followed through arterial, capillary, and venous phases for a complete cerebral angiogram.Electroencephalography. Electroencephalography (EEG) involves measuring weak electrical signals from the brain that are transmitted through the skull through electrodes that are applied to the scalp. The voltage fluctuations detected by EEG are thought to reflect summed membrane potentials from under-lying brain tissue. Clinically, EEG is useful for detecting sei-zures, interictal markers of epileptogenic tissue, and widespread abnormalities in brain function, such as diffuse encephalopathy. EEG is also used in concert with electrical stimulation to detect sensory evoked potentials that can be useful for intraoperative mapping during cranial and spine surgery.Electromyography and Nerve Conduction Studies.  Electromyography and nerve conduction studies (EMG/NCS) are useful for assessing the function of peripheral nerves. EMG records muscle activity in response to a proximal stimulation of the motor nerve. NCS record the velocity and amplitude of the nerve action potential. EMG/NCS typically is performed approximately 3 to 4 weeks after an acute injury, as nerves distal to the injury continue to transmit electrical impulses normally until degeneration of the distal nerve progresses.Invasive Monitoring. The most reliable monitor, always, is an alert patient with a reliable neurologic examination. If a reliable neurologic examination is not possible due to the pres-ence of brain injury, sedatives, or paralytics, or if there is active and unstable intracranial pathology, invasive monitoring is required. There are several methods of monitoring intracranial physiology. The methods described in the following sections are bedside intensive care unit (ICU) procedures that allow for continuous monitoring. Both procedures involve making a small hole in the skull with a hand-held drill. They generally are placed in the right frontal region to minimize the neurologic impact of possible complications such as hemorrhage.External Ventricular Drain. An external ventricular drain is also known as a ventriculostomy. A perforated plastic catheter is inserted into the frontal horn of the lateral ventricle. An uninter-rupted fluid column through a rigid tube allows transduction of intracranial pressure (ICP). CSF also can be drained to reduce ICP or sampled for laboratory studies.Intraparenchymal Physiologic Monitoring. Intraparenchy-mal monitors can be inserted into the brain through a threaded post locked securely into a burr hole, commonly referred to as a bolt. A bolt allows ICP monitoring with a fiber-optic pressure transducer, but it is smaller and less invasive than a ventriculos-tomy and may be associated with fewer complications, although the data do not clearly support this. Furthermore, a bolt can also be used to introduce probes to measure brain tissue oxygenation, brain temperature, and to perform microdialysis of parenchymal samples; however, the utility of these latter measures in clinical practice is still under investigation. Patients with severe brain injury due to trauma or aneurysmal hemorrhage may benefit from placement of these sensors in addition to a ventriculos-tomy to drain CSF for control of ICP. Such monitoring requires two twist-drill holes, which may be placed on adjacent or oppo-site sides of the head.NEUROLOGIC AND NEUROSURGICAL EMERGENCIESRaised Intracranial PressureICP normally varies between 4 and 14 mmHg. Sustained ICP levels above 20 mmHg can injure the brain. The Monro-Kellie doctrine states that the cranial vault is a rigid structure, and therefore, the total volume of the contents determines ICP. The three normal contents of the cranial vault are brain tis-sue, blood, and CSF. The brain’s contents can expand due to swelling from traumatic brain injury (TBI), stroke, or reactive edema. Blood volume can increase by extravasation to form a hematoma, or by reactive vasodilation in a hypoventilating, hypercarbic patient. CSF volume increases in the setting of hydrocephalus. Figure 42-2 demonstrates the classic CT find-ings of hydrocephalus. The addition of a lesion, such as a tumor or abscess, also will increase ICP. The pressure-volume curve depicted in Fig. 42-3 demonstrates a compensated region with a small ΔP/ΔV, and an uncompensated region with large ΔP/ΔV. In the compensated region, increased volume is offset by decreased volume of CSF and blood.Increased ICP can injure the brain in several ways. Focal mass lesions cause shift and herniation. Temporal lesions push the uncus medially and compress the midbrain. This phenom-enon is known as uncal herniation. The posterior cerebral artery (PCA) passes between the uncus and midbrain and may be occluded, leading to an occipital infarct. Masses higher up in the hemisphere can push the cingulate gyrus under the falx cerebri. This process is known as subfalcine herniation. The anterior cerebral artery (ACA) branches run along the medial surface of the cingulate gyrus and may be occluded in this case, leading to medial frontal and parietal infarcts. Diffuse increases in pressure Brunicardi_Ch42_p1827-p1878.indd 183101/03/19 7:16 PM 1832SPECIFIC CONSIDERATIONSPART IIin the cerebral hemispheres can lead to central, or transtento-rial, herniation. Increased pressure in the posterior fossa can lead to upward central herniation or downward tonsillar hernia-tion through the foramen magnum. Uncal, transtentorial, and tonsillar herniation can cause direct damage to the brain stem. Figure 42-4 diagrams patterns of herniation.Patients with increased ICP, or intracranial hypertension, often will present with headache, nausea, vomiting, and progres-sive mental status decline. Cushing’s triad is the classic presen-tation of hypertension, bradycardia, and irregular respirations. Focal neurologic deficits such as hemiparesis may be present if there is a focal mass lesion causing the problem. Patients with these symptoms should undergo an immediate head CT and rapid neurosurgical evaluation.Initial management of intracranial hypertension includes airway protection and adequate ventilation. A bolus of man-nitol up to 1 g/kg causes free water diuresis, increased serum osmolality, and extraction of water from the brain. The effect is delayed by about 20 minutes and has a transient benefit. Driv-ing serum osmolality above 300 mOsm/L is of indeterminate benefit and can have deleterious cardiovascular side effects, such as hypovolemia that leads to hypotension and decreased brain perfusion. A ventriculostomy and/or craniectomy may be needed for definitive decompression.It is critical to note that lethargic or obtunded patients often have decreased respiratory drive. This causes the partial pressure of arterial carbon dioxide (Paco2) to increase, resulting in cerebral vasodilation and worsening of intracranial hyperten-sion. This cycle causes a characteristic “crashing patient,” who rapidly loses airway protection, becomes apneic, and herniates. Emergent intubation and ventilation to reduce Paco2 to roughly 35 mmHg can reverse this process.Figure 42-2. Head computed tomography scan demonstrating hydrocephalus. The third ventricle (3rd) is widened and rounded, the anterior horns of the lateral ventricles are plump, and pressure-driven flow of cerebrospinal fluid into brain parenchyma adjacent to the ventricles is seen (arrowhead). This is known as transepen-dymal flow of cerebrospinal fluid.Intracranial volume (arbitrary units)Intracranial pressure (mmHg)0102030405060708090100110120130102030405060708090100˜V˜P˜V˜P˜V˜PLow complianceecnailpmoc oNecnailpmoc hgiHFigure 42-3. Pressure-volume curve demonstrating the effect of changing the volume of intracranial contents on intracranial pressure. Note the compensated zone, with little change of pressure with change of volume, and the uncompensated zone, with significant change of pres-sure with change of volume. (Adapted with permission from Ellenbogen RG, Abdulrauf SI, Sekhar LN: Principles of Neurosurgery, 3rd ed. Philadelphia, PA: Elsevier/Saunders; 2012.)Brunicardi_Ch42_p1827-p1878.indd 183201/03/19 7:16 PM 1833NEUROSURGERYCHAPTER 42Brain Stem CompressionThe posterior fossa (brain stem and cerebellum) requires special consideration because the volume of the posterior fossa within the cranial vault is small. Posterior fossa lesions such as tumors, hemorrhage, or stroke can cause mass effect that can rapidly kill the patient in two ways. Occlusion of the fourth ventricle can lead to acute obstructive hydrocephalus, raised ICP, herniation, and eventually death. This mass effect can also lead directly to brain stem compression (Fig. 42-5). Symptoms of brain stem compression include hypertension, agitation, and progressive obtundation, followed rapidly by brain death. A patient exhibit-ing any of these symptoms needs an emergent neurosurgical evaluation for possible ventriculostomy or suboccipital crani-ectomy (removal of the bone covering the cerebellum). This situation is especially critical, as expeditious decompression can lead to significant functional recovery.StrokePatients presenting with acute focal neurologic deficits at a clearly defined time of onset (i.e., when the patient was last seen in a normal state of health) must be evaluated as rapidly as possible. An emergent head CT scan should be done. The study is often normal because CT changes from ischemic stroke may take up to 24 hours to appear (Fig. 42-6). A patient with a clinical diagnosis of acute stroke <4.5 hours old, without hemor-rhage on CT, may be a candidate for thrombolytic therapy with tissue plasminogen activator (tPA). When a proximal large-vessel obstruction is suspected, patients should be evaluated for endovascular mechanical thrombectomy if therapy can be initiated within 6 to 8 hours of symptom onset. Intravenous tPA should be given regardless, but a noninvasive intracranial vas-cular study such as CT angiography should also be obtained in these cases. An emergent MRI is helpful but not always diag-nostically necessary.SeizureA seizure is defined as an uncontrolled synchronous organiza-tion of neuronal electrical activity. A new-onset seizure often signifies an irritative mass lesion in the brain, particularly in adults, in whom tumors commonly present with seizure. Patients with traumatic intracranial hemorrhage are at risk for seizure. In addition to airway and ventilatory problems, a seizing patient is also at risk for neural excitotoxicity if the activity is prolonged, such as in status epilepticus. Any patient with a new-onset sei-zure should have imaging of the brain after the seizure is con-trolled and the patient is resuscitated.TRAUMATrauma is the leading cause of death in children and young adults; however, the incidence of death and disability from trauma has been slowly decreasing. This decline is partly attrib-utable to increased awareness of safety devices such as seat belts and motorist helmets. Nonetheless, trauma remains a major cause of morbidity and mortality, and it can affect every major organ system in the body. The three main areas of neurosurgical focus are: traumatic brain injury (TBI), spinal cord injury (SCI), and peripheral nerve injury.Head TraumaGlasgow Coma Scale Score. The initial assessment of the trauma patient includes the primary survey, resuscitation, 1324Figure 42-4. Schematic drawing of brain herniation patterns. 1. Subfalcine herniation. The cingulate gyrus shifts across midline under the falx cerebri. 2. Uncal herniation. The uncus (medial tem-poral lobe gyrus) shifts medially and compresses the midbrain and cerebral peduncle. 3. Central transtentorial herniation. The dien-cephalon and midbrain shift caudally through the tentorial inci-sura. 4. Tonsillar herniation. The cerebellar tonsil shifts caudally through the foramen magnum. (Reproduced with permission from Wilkins RH, Rengachary SS: Neurosurgery, 2nd ed. New York, NY: McGraw Hill Education; 1996.)Figure 42-5. Maturing cerebellar stroke seen as a hypodense area in the right cerebellar hemisphere (arrowhead) on head computed tomography in a patient with rapidly progressing obtundation 2 days after the initial onset of symptoms. Swelling of the infarcted tissue causes posterior fossa mass effect. The fourth ventricle is obliterated and not visible, and the brain stem is being compressed.Brunicardi_Ch42_p1827-p1878.indd 183301/03/19 7:16 PM 1834SPECIFIC CONSIDERATIONSPART IIsecondary survey, and definitive care. Neurosurgical evalua-tion begins during the primary survey with the determination of the GCS score (usually referred to simply as the GCS) for the patient. The GCS is determined by adding the scores of the best responses of the patient in each of three categories. The motor score ranges from 1 to 6, verbal from 1 to 5, and eyes from 1 to 4. The GCS therefore ranges from 3 to 15, as detailed in Table 42-2. Tracheal intubation or severe facial or eye swelling can impede verbal and eye responses. In these circumstances, the patient is given the score of 1 with a modifier, such as verbal “1T” where T = tube.Scalp Injury. Blunt or penetrating trauma to the head can cause injury to the densely vascularized scalp, and significant blood loss can result. Direct pressure initially controls the bleeding, allowing close inspection of the injury. If a simple laceration is found, it should be copiously irrigated and closed primarily. If the laceration is short, a single-layer, percutaneous suture clo-sure will suffice. If the laceration is long or has multiple arms, the patient may need debridement and closure in the operating room, with its superior lighting and wider selection of instru-ments and suture materials. Careful reapproximation of the galea will provide a more secure closure and better hemostasis. ACBFigure 42-6. A. Head computed tomography scan of a patient with a 4-day-old stroke that occluded the right middle cerebral and posterior cerebral arteries. The infarcted tissue is the hypodense (dark) area indicated by the arrowheads. The patient presented with left-sided weakness and left visual field loss, but then became less responsive, prompting this head computed tomography. Note the right-to-left midline shift. B. Same patient status post decompressive right hemicraniectomy. Note the free expansion of swollen brain outside the normal confines of the skull. C. Patient with a right middle cerebral artery ischemic stroke with areas of hemorrhagic conversion, seen as hyperdense (bright) areas within the infarcted tissue. This patient also required hemicraniectomy for severe mass effect. Note the lack of midline shift postoperatively.Brunicardi_Ch42_p1827-p1878.indd 183401/03/19 7:16 PM 1835NEUROSURGERYCHAPTER 42Blunt trauma also can cause crush injury with subsequent tissue necrosis. These wounds require debridement and consideration of advancement flaps to cover the defect.Skull Fractures. The usual classification system for bony fractures may be applied to the skull. The fracture may be characterized by skull X-rays or head CT.5 A closed fracture is covered by intact skin. An open, or compound, fracture is associated with disrupted overlying skin. The fracture lines may be single (linear); multiple and radiating from a point (stellate); or multiple, creating fragments of bone (comminuted). Closed skull fractures do not normally require specific treatment. Open fractures require repair of the scalp and operative debridement. Indications for craniotomy include depression greater than the cranial thickness, intracranial hematoma, and frontal sinus involvement.6 Skull fractures generally indicate that a signifi-cant amount of force was transmitted to the head and should increase the suspicion for intracranial injury. Fractures that cross meningeal arteries can cause rupture of the underlying vessels and subsequent epidural hematoma (EDH) formation.Depressed skull fractures may result from a focal injury of significant force. The inner and outer cortices of the skull are disrupted, and a fragment of bone is pressed in toward the brain in relation to adjacent intact skull. The fragment may overlap the edge of intact bone, or it may plunge completely below the level of adjacent normal skull. The inner cortex of the bone fragments often has multiple sharp edges that can lacerate dura, brain, and vessels. Craniotomy is required to ele-vate the fracture, repair dural disruption, and obtain hemostasis in these cases (Fig. 42-7). However, fractures overlying dural venous sinuses require restraint. Surgical exploration can lead to life-threatening hemorrhage from the lacerated sinus.Fractures of the skull base are common in head-injured patients, and they indicate significant impact. They are gener-ally apparent on routine head CT, but they should be evaluated with dedicated fine-slice coronal-section CT scan to document and delineate the extent of the fracture and involved structures. If asymptomatic, they require no treatment. Skull base fractures requiring intervention include those with an associated cranial nerve deficit or CSF leak. A fracture of the temporal bone, for instance, can damage the facial or vestibulocochlear nerve, resulting in vertigo, ipsilateral deafness, or facial paralysis. A communication may be formed between the subarachnoid space and the middle ear, allowing CSF drainage into the pharynx via the Eustachian tube or from the ear (otorrhea). Extravasation of blood results in ecchymosis behind the ear, known as Battle’s sign. A fracture of the anterior skull base can result in anos-mia (loss of smell from damage to the olfactory nerve), CSF drainage from the nose (rhinorrhea), or periorbital ecchymosis, known as raccoon eyes.Copious clear drainage from the nose or ear makes the diagnosis of CSF leakage obvious. Often, however, the drain-age may be discolored with blood or small in volume if some drains into the throat. In indeterminate cases, it is important to consider radiographic findings on the CT scan near the fracture that suggest CSF leak, such as pneumocephalus, subarachnoid, or intraparenchymal blood at the fracture site. The “halo” test assesses for a double ring when a drop of the fluid is allowed to fall on an absorbent surface, but it has been shown to have poor clinical utility.7 The fluid can be sent for β-2 transferrin testing, a carbohydrate-free isoform of transferrin exclusively found in the CSF; however, these tests often take 1 to 2 weeks to result and also can be difficult to incorporate into clinical practice.BAFigure 42-7. A. Bone-window axial head computed tomography (CT) of a patient who presented aphasic after being struck with the bot-tom of a beer bottle. CT demonstrates a depressed skull fracture in the left posterior temporoparietal area. B. Brain-window axial head CT demonstrating intraparenchymal hematoma caused by laceration of cortical vessels by the edge of the fractured bone. Arrowhead indicates traumatic subarachnoid hemorrhage in the sylvanian fissure.Brunicardi_Ch42_p1827-p1878.indd 183501/03/19 7:16 PM 1836SPECIFIC CONSIDERATIONSPART IIMany CSF leaks will heal with elevation of the head of the bed for several days. An elevation of the head of the bed reduces the hydrostatic pressure of the CSF fluid column in the cranial vault, near the site of the defect. As such, when the CSF leak is in the lumbar thecal sac, the head of the bed should be flat so as to maximize hydrostatic pressure of the CSF fluid column at the cranial vault, away from the site of the defect. In addi-tion, lumbar drain can be used to reduce CSF pressure. When there is a contraindication, to lumbar drain placement (such as an intracranial mass lesion or hematoma), an extraventricular drain should be used for CSF diversion. Although persistent CSF leaks have been shown to increase the risk of meningitis,8 there is no evidence supporting the use of prophylactic antibi-otic use for preventing meningitis in patients with CSF leaks.9Traumatic cranial neuropathies generally can be managed conservatively, with documentation of the extent of impairment and signs of recovery. Patients with traumatic facial nerve pal-sies may benefit from a course of steroids, although their benefit is unproven. Patients with facial nerve palsy of abrupt onset, who do not respond to steroids within 48 to 72 hours, may be considered for surgical decompression of the petrous portion of the facial nerve. Patients also may present with delayed-onset facial nerve palsy. Again, steroids are used and surgery can be considered, with mixed results.Closed Head Injury. Closed head injury (CHI) is the most common type of TBI and a significant cause of morbidity and mortality in the United States. There are two important factors that affect the outcome of CHI in general. The initial impact causes the primary injury, defined as the immediate injury to neurons from transmission of the force of impact. The long, delicate axons of the neurons can shear as they undergo differ-ential acceleration or deceleration along their projecting path-ways. Prevention strategies, such as wearing helmets, remain the best means to decrease disability from primary injury. Sub-sequent neuronal damage due to the sequelae of trauma is referred to as secondary injury. Hypoxia, hypotension, hydro-cephalus, intracranial hypertension, thrombosis, and intracranial hemorrhage may all be mechanisms of secondary injury. One focus of basic research in TBI, critical care medicine, and neurosurgical intervention is to decrease the effects of sec-ondary injury.The Brain Trauma Foundation’s most recent summary of management recommendations for TBI patients was published in 2016 and is endorsed by the American Association of Neuro-logical Surgeons, Congress of Neurological Surgeons, and the World Health Organization.10 The guidelines standardize the care of these patients with the hope of improving outcomes. Level I recommendations are based on a body of high-quality evidence, such as large, well-received randomized controlled trials. Level II and III recommendations are based on moderate and low quality evidence, respectively. Some of the common patterns of CHI, including concussion, contusion, and diffuse axonal injury, are discussed in “Types of Closed Head Injury.”11Initial Assessment The initial evaluation of a trauma patient remains the same whether or not the primary surveyor suspects head injury. The first three elements of the ABCDs of resus-citation—airway, breathing, and circulation—must be assessed and stabilized. Hypoxia and hypotension are known to worsen outcome in TBI (due to secondary injury), making cardiopul-monary stabilization critical. Patients who cannot follow com-mands require intubation for airway protection and ventilatory control. The fourth element, assessment of “D,” for disability, is undertaken next. Motor activity, speech, and eye opening can be assessed in a few seconds and a GCS score assigned.The following is an example of how a primary surveyor may efficiently assess disability and GCS: Approach the patient and enter his or her field of view. Observe whether the patient is visually attentive. Clearly command: “Tell me your name.” Then ask the patient to lift up two fingers on each side sequen-tially, and wiggle the toes. A visually or verbally unresponsive patient should be assessed for response to peripheral stimuli such as nail-bed pressure, or deep central painful stimulation, such as a firm, twisting pinch of the sensitive supraclavicular skin. Watch for eye opening and movement of the extremities, whether purposeful or reflexive. Assess the verbal response. The motor, verbal, and eye-opening scores may be correctly assigned using this rapid examination. An initial assessment of the probability of significant head injury can be made, assuming that pharmacologic and toxic elements have not obscured the examination. The surveyor must also take note of any external signs of head injury, including bleeding from the scalp, nose, or ear, or deformation of the skull or face.Classification TBI can be classified as mild, moderate, or severe. For patients with a history of head trauma, classifica-tion is as follows: severe head injury if the GCS score is 3 to 8, moderate head injury if the GCS score is 9 to 12, and mild head injury if the GCS score is 13 to 15. Many patients present to emergency rooms and trauma bays with a history of TBI. A tri-age system must be used to maximize resource utilization while minimizing the chance of missing occult or progressing injuries.TBI patients who are asymptomatic, who have only headache, dizziness, or scalp lacerations, and who did not lose consciousness, have a low risk for intracranial injury and may be discharged home without a head CT scan.12,13 Head-injured patients who are discharged should be sent home with reliable family or friends who can observe the patient for the first postin-jury day. Printed discharge instructions, which describe moni-toring for confusion, persistent nausea, weakness, or speech difficulty, should be provided to the caretaker. The patient should return to the emergency department for evaluation of such symptoms.Patients with a history of altered consciousness, amne-sia, progressive headache, skull or facial fracture, vomiting, or seizure have a moderate risk for intracranial injury and should undergo a prompt head CT. If the CT is normal, and the neuro-logic examination has returned to baseline (excluding amnesia of the event), then the patient can be discharged to the care of a responsible adult, again with printed criteria for returning to the emergency room. Otherwise the patient must be admitted for a 24-hour observation period.Patients with depressed consciousness, focal neurologic deficits, penetrating injury, depressed skull fracture, or changing neurologic examination have a high risk for intracranial injury. These patients should undergo immediate head CT and admis-sion for observation or intervention as needed.Types of Closed Head Injury Concussion A concussion is defined as temporary neuronal dysfunction following nonpenetrating head trauma. The head CT is normal, and deficits resolve over minutes to hours. Defini-tions vary; some require transient loss of consciousness, while others include patients with any alteration of mental status. Memory difficulties, especially amnesia of the event, are very 3Brunicardi_Ch42_p1827-p1878.indd 183601/03/19 7:16 PM 1837NEUROSURGERYCHAPTER 42common. Concussions may be graded. One method is the Col-orado grading system.14 Head trauma patients with confusion only are grade 1, patients with amnesia are grade 2, and patients who lose consciousness are grade 3. Studies have shown that the brain remains in a hypermetabolic state for up to a week after injury. The brain is also much more susceptible to injury from even minor head trauma in the first 1 to 2 weeks after concus-sion. This is known as second-impact syndrome, and patients should be informed that, even after mild head injury, they might experience memory difficulties or persistent headaches. Return to play guidelines after sports-related concussions are contro-versial and are under active debate.15Contusion A contusion is a bruise of the brain, and occurs when the force from trauma is sufficient to cause breakdown of small vessels and extravasation of blood into the brain. The contused areas appear bright on CT scan, as seen in Fig. 42-8. The frontal, occipital, and temporal poles are most often involved. The brain sustains injury as it collides with rough, bony surfaces. Contu-sions themselves rarely cause significant mass effect as they represent small amounts of blood in injured parenchyma rather than coherent blood clots. Edema may develop around a contu-sion, causing mass effect. Contusions may enlarge or progress to frank hematoma, particularly during the first 24 hours. Contu-sions also may occur in brain tissue opposite the site of impact. This is known as a contre-coup injury. These contusions result from deceleration of the brain against the skull.Diffuse Axonal Injury Diffuse axonal injury (DAI) is caused by damage to axons throughout the brain, due to rotational acceleration and then deceleration. Axons may be completely disrupted and then retract, forming axon balls. Small hemor-rhages can be seen in more severe cases, especially on MRI. Hemorrhage is classically seen in the corpus callosum and the dorsolateral midbrain. DAI can be considered to be a severe form of a concussion, often with irreversible consequence. It can often explain a poor neurological examination (such as impaired arousal) in cases without clear radiographic signs of global bran injury, particularly when there is damage in struc-tures, such as the pontine reticular activating system or bilateral thalami, that are necessary for arousal. In these cases, alternative explanations of poor arousal, such as a basilar thrombus, must also be investigated.Penetrating Injury These injuries are complex and must be evaluated individually. The two main subtypes are missile (e.g., due to bullets or fragmentation devices) and nonmissile (e.g., due to knives or ice picks). Some general principles apply. If available, skull X-rays and CT scans are useful in assessing the nature of the injury. Cerebral angiography must be considered if the object passes near a major artery or dural venous sinus. Operative exploration is necessary to remove any object extend-ing out of the cranium, as well as for debridement, irrigation, hemostasis, and definitive closure. Small objects contained within brain parenchyma are often left in place to avoid iat-rogenic secondary brain injury. High-velocity missile injuries (from high-powered hunting rifles or military weapons) are especially deadly, because the associated shock wave causes cavitary tissue destruction of an area that is much larger than the projectile itself. Projectiles that penetrate both hemispheres or traverse the ventricles are almost universally fatal. Antibiot-ics are given to decrease the chances of meningitis or abscess formation; however, the evidence supporting the use of antibi-otics following missile injury is weak and largely comes from retrospective case studies and expert opinion. Recent guidelines published in regard to preventing combat-related infections recommend antimicrobial therapy for 5 days or until resolu-tion of the associated CSF leak, albeit with limited supporting evidence.16Traumatic Intracranial Hematomas. The various traumatic intracranial hematomas contribute to death and disability sec-ondary to head injury. Hematomas can expand rapidly and cause brain shift and subsequent herniation. Emergent neurosurgical evaluation and intervention often are necessary.Epidural Hematoma EDH is the accumulation of blood between the skull and the dura. EDH usually results from arte-rial disruption, especially of the middle meningeal artery. The dura is adherent to bone, and some pressure is required to dis-sect between the two. On head CT, the blood clot is bright, biconvex in shape (lentiform), and has a well-defined border that usually respects cranial suture lines. An EDH is typically found over the convexities but may rarely occur in the posterior fossa as well. EDH has a classic, three-stage clinical presenta-tion that is probably seen in only 20% of cases. The patient is initially unconscious from the concussive aspect of the head trauma. The patient then awakens and has a “lucid interval,” while the hematoma subclinically expands. As the volume of the hematoma grows, the decompensated region of the pressure-volume curve is reached, ICP increases, and the patient rapidly becomes lethargic and herniates. Uncal herniation from an EDH classically causes ipsilateral third nerve palsy and contralateral hemiparesis.Open craniectomy for evacuation of the congealed clot and hemostasis generally is indicated for EDH. In some cases, EDH can be caused from bony venous bleeding that is self-limited Figure 42-8. Severe bilateral contusions in the basal aspect of the frontal lobes, caused by the brain moving over the rough, irregular skull base during sudden cranial acceleration.Brunicardi_Ch42_p1827-p1878.indd 183701/03/19 7:16 PM 1838SPECIFIC CONSIDERATIONSPART IIand may not require surgical intervention. Generally, patients who meet all of the following criteria may be managed conser-vatively: clot volume <30 cm3, maximum thickness <1.5 cm, and GCS score >8.10 Prognosis after successful evacuation is better for EDH than subdural hematoma (SDH). EDHs are associ-ated with lower-energy trauma with less resultant primary brain injury. Good outcomes may be seen in 85% to 90% of patients, with rapid CT scan and intervention.11 In some cases, EDH can also be caused by dural venous sinus tears that rapidly expand and are typically associated with a high degree of morbidity when treated surgically.Acute Subdural Hematoma An acute SDH is the result of an accumulation of blood between the arachnoid membrane and the dura. Acute SDH usually results from venous bleed-ing, typically from tearing of a bridging vein running from the cerebral cortex to the dural sinuses. The bridging veins are sub-ject to stretching and tearing during acceleration/deceleration of the head because the brain shifts in relation to the dura, which firmly adheres to the skull. Elderly and alcoholic patients are at higher risk for acute SDH formation after head trauma due to brain atrophy.On head CT scan, the clot is bright or mixed-density, cres-cent-shaped (lunate), may have a less distinct border, and does not cross the midline due to the presence of the falx. Most SDHs occur over the cerebral hemispheres, but they may also occur between the hemispheres or layer over the tentorium.Open craniotomy for evacuation of acute SDH is indicated for any of the following: thickness >1 cm, midline shift >5 mm, or GCS drop by two or more points from the time of injury to hospitalization. Nonoperatively managed hematomas may sta-bilize and eventually reabsorb, or evolve into chronic SDHs.17 This management requires frequent neurologic examinations until the clot stabilizes based on serial head CT scans.The prognosis for functional recovery is significantly worse for acute SDH than EDH because it is associated with greater primary injury to brain parenchyma from high-energy impacts. Prompt recognition and intervention minimizes sec-ondary injury. The elderly patients with low admission GCS, or high postoperative ICP do poorly, with as few as 5% attaining functional recovery.18Chronic Subdural Hematoma Chronic SDH is a collection of blood breakdown products that is at least 2 to 3 weeks old. Acute hematomas are bright white (hyperdense) on CT scan for approximately 3 days, after which they fade to isodensity with brain, and then to hypodensity after 2 to 3 weeks. A true chronic SDH will be nearly as dark as CSF on CT. Traces of white are often seen due to small, recurrent hemorrhages into the col-lection. These small bleeds may expand the collection enough to make it symptomatic. This phenomenon is referred to as an acute-on-chronic SDH. Figure 42-9 demonstrates the CT appearance of an acute-on-chronic SDH. Vascularized mem-branes form within the hematoma as it matures. These mem-branes may be the source of acute hemorrhage.Chronic SDHs often occur in patients without a clear his-tory of head trauma as they may arise from minor head injury. Alcoholics, the elderly, and patients on anticoagulation are at higher risk for developing chronic SDH. Patients may present with headache, seizure, confusion, contralateral hemiparesis, or coma.A chronic SDH >1 cm or any symptomatic SDH should be surgically drained. Unlike acute SDH, which consists of a thick, congealed clot, chronic SDH typically consists of a viscous fluid with the texture and dark brown color reminiscent of motor oil. A simple burr hole can effectively drain most chronic SDHs. However, the optimal treatment of chronic SDH remains con-troversial.19 Recent data suggest that open craniotomy is effec-tive at reducing recurrence, but may be associated with more short-term complications.20 Most authorities agree that burr hole drainage should be attempted first to obviate the risks of formal craniotomy.21 A single burr hole placed over the dependent edge of the collection can be made, and the space is copiously irri-gated until the fluid is clear. A second, more anterior burr hole can then be placed if the collection does not drain satisfactorily due to containment by membranes. The procedure is converted to open craniotomy if the SDH is too congealed for irrigation drainage, the complex of membranes prevents effective drain-age, or persistent hemorrhage occurs that cannot be reached with bipolar cautery through the burr hole. The required surgi-cal prepping and draping are always performed to allow simple conversion to craniotomy, and the scalp incision and burr holes are placed to allow easy incorporation into larger skin flaps.There are various strategies to prevent reaccumulation of blood. Subdural or subgaleal drains may be left in place for 1 to 2 days. Subdural drains have been shown to reduce the risk of recurrence, whereas corticosteroid use in this patient popula-tion has been associated with higher morbidity without benefit.20 Mild hydration and bedrest with the head of the bed flat may Figure 42-9. Head computed tomography scan of an elderly patient with progressing left hemiplegia and lethargy, demonstrat-ing an acute-on-chronic subdural hematoma. History revealed that the patient sustained a fall 4 weeks before presentation. Arrowheads outline the hematoma. The acute component is slightly denser and is seen as the hyperdense area in the dependent portion.Brunicardi_Ch42_p1827-p1878.indd 183801/03/19 7:16 PM 1839NEUROSURGERYCHAPTER 42encourage brain expansion. High levels of inspired oxygen may help draw nitrogen out of the cavity. Regardless of the strategy used, follow-up head CT scans are required postoperatively and approximately 1 month later to document resolution.Intraparenchymal Hemorrhage Isolated hematomas within the brain parenchyma are most often associated with hyper-tensive hemorrhage or arteriovenous malformations (AVMs). Bleeding may occur in a contused area of brain. Mass effect from developing hematomas may present as a delayed neuro-logic deficit. Delayed traumatic intracerebral hemorrhage is most likely to occur within the first 24 hours. Patients with contusion on the initial head CT scan should be reimaged 24 hours after the trauma to document stable pathology. Indica-tions for craniotomy include: any clot volume >50 cm3 or a clot volume >20 cm3 with referable neurologic deterioration (GCS 6–8) and associated midline shift >5 mm or basal cistern compression.22Pneumocephalus Pneumocephalus, or air in the intracranial cavity, is commonly seen in neurosurgical patients following head trauma or following intracranial surgery.23 Pneumoceph-alus requires a defect in the skull that allows air to enter the intracranial cavity. This may occur following may represent an iatrogenic defect created following cranial surgery or follow-ing head trauma. Approximately 66% of postcraniotomy CT scans demonstrate some extent of pneumocephalus.24 The iden-tification of pneumocephalus following head trauma can offer important clues about the extent of injury, such as the presence of skull based fractures or a CSF leak. In rare cases, pneumo-cephalus can also be seen in association with skull based tumors or infections.A tension pneumocephalus occurs when the intracranial air pocket is under tension which can result in life threatening herniation if left untreated. This is a neurosurgical emergency and requires an urgent neurosurgical consultation. Two radio-graphic features have been associated with a tension pneumo-cephalus25 (Fig. 42-10). First, the “Mount Fuji” sign, where the air pocket separates the frontal lobes and widens the inter-hemi-spheric fissure, mimicking the silhouette of Mount Fuji. Second, the “air bubble” sign, where there are multi-focal pockets of air throughout the subarachnoid cisterns, putatively within the sub-arachnoid space. These radiographic findings are helpful clues; however, the diagnosis of tension pneumocephalus also requires a worsening neurological exam consistent with increased intra-cranial pressure and impending herniation. A burr hole may be used to relieve intracranial pressure per the discretion of the neurosurgical team.When not associated with tension dynamics, the clinical significance and management of pneumocephalus depends on the underlying mechanism. There are thought to be two major mechanisms by which pneumocephalus develops.24 First, the “ball valve” mechanism involves the passage of air into the intracranial cavity during periods of positive pressure, whereby the defect in the skull acts as a one-way valve. In these cases, management involves avoiding positive pressure ventilation, and laying the head of the bed flat to minimize air traveling upwards into the cranial cavity. Second, the “inverted bottle” mechanism involves air entering the intracranial space due to a negative pressure gradient created by the drainage of CSF. In most cases, drainage occurs through a traumatic or iatrogenic CSF leak, but it may also occur through ventricular or lumbar drainage. In these cases, management should be focused on minimizing CSF drainage through the defect. If the CSF leak is at the skull base, as is the case following basilar skull fractures, or those involving the mastoid air cells, then the head of bed must be elevated so as to reduce hydrostatic pressure in the ven-tricular CSF fluid column, and controlled CSF diversion can be performed using an extraventricular or lumbar drain (see “Skull Fractures” for further discussion). Definitive repair of the skull-based defect can also be considered, but this is often done on an elective basis. In general, nontension pneumocephalus will resolve on its own with time as it is resorbed into the blood stream. Supplemental 100% oxygen may be used to increase the rate of resorption by increasing the diffusion gradient of nitro-gen-predominant intracranial air pocket and the blood stream.26Management of Traumatic Brain Injury General Medical Management Several medical steps may be taken to minimize secondary injury and the systemic con-sequences of head injury. Patients with a documented CHI and evidence of intracranial hemorrhage or a depressed skull fracture should receive a 1 g Keppra loading dose, followed by 1 week of therapeutic maintenance Keppra, typically 500 mg twice a day. Antiseizure prophylaxis has been shown to decrease the incidence of early posttraumatic seizures.27 There is no evi-dence to support long-term use of prophylactic antiepileptic agents. Even though the clinical studies supporting early anti-seizure prophylaxis used phenytoin, Keppra is typically used in clinical practice due to a more favorable side effect profile. Blood glucose levels should be closely monitored by free blood sugar checks and controlled with sliding scale insulin. Fevers also should be evaluated and controlled with antipyretics, as well as source-directed therapy when possible. Hyperglycemia and hyperthermia are toxic to injured neurons and contribute to secondary injury. Head-injured patients have an increased prevalence of peptic ulceration and GI bleeding. Peptic ulcers occurring in patients with head injury or high ICP are referred to as Cushing’s ulcers. Ulcer prophylaxis should be used. Com-pression stockings or athrombic pumps should be used when the patient cannot be mobilized rapidly for prophylaxis of deep venous thrombosis.Steroids and Traumatic Brain Injury Per a level 1 recom-mendation (high-quality evidence) from the Brain Trauma Foundation,10 steroids are not recommended for the management of TBI or reduction of elevated ICP. Also, high-dose methyl-prednisolone is contraindicated in severe TBI. A large random-ized controlled trial (CRASH; n = 9673, 6-month follow-up,28 Figure 42-10. CT image on left illustrates “Mt. Fuji sign” (arrow-head) and intraparnchymal air (arrow). CT image on R illustrates brain herniation into the ethmoid sinus (arrowhead).Brunicardi_Ch42_p1827-p1878.indd 183901/03/19 7:16 PM 1840SPECIFIC CONSIDERATIONSPART IIdemonstrated an increased risk of 6-month mortality in severe TBI (GCS 3–8) that received methylprednisolone (47%), as compared to placebo (42%, P = 0.0024). This effect was also present when analyzing TBI of all severity levels (25.7% meth-ylprednisolone vs. 22.3% placebo, P = 0.0001).Blood Pressure Management Blood pressure management in TBI is a complex issue. On one hand, hypotension results in hypoperfusion that may worsen brain injury that occurs follow-ing TBI. On another hand, hypertension may result in expansion of intracranial hematomas that are often seen in TBI.There is clear evidence from retrospective studies, that frank hypotension (SBP <90 mmHg) is associated with increased mortality in TBI, particularly in the prehospital setting and during resuscitation.29 A large retrospective cohort study (n = 15,733) identified hypotension thresholds that were associ-ated with an increased risk of mortality in patients with TBI of varying age.30 Based on these data, the Brain Trauma Founda-tion guidelines10 provide a level III (low-quality) recommenda-tion that maintaining systolic blood pressures >100 mmHg (ages 50–69 years), or >110 mmHg (ages 15–49 years or >70 years) may be considered to reduce mortality and improve outcomes. More recently, a large retrospective study31 demonstrated a dose-dependent relation between the duration of prehospital hypotension and increased mortality in patients with TBI, such that a 10-point increase in systolic blood pressure across a broad range (40–119 mmHg) was associated with an 18.8% decrease in adjusted odds of inhospital mortality. These results suggest that having a single “hypotension threshold” may not be suf-ficient in management of TBI and may require more aggressive management than currently employed. Furthermore, an impor-tant and underappreciated consideration in blood pressure man-agement is the baseline blood pressure of the patient. Future studies should assess blood pressure management goals that are tailored to each individual patient’s baseline blood pressure.On the other hand, hypertension in TBI may have impli-cations for intracranial hematoma expansion. It is common in clinical practice to recommend that systolic blood pressures are maintained <160 mmHg to mitigate the risk of hematoma expan-sion. Evidence supporting this practice is largely extrapolated from non-TBI patients. A small retrospective study (n = 69)32 demonstrated an increased risk of postcraniotomy intracranial hematoma in patients with intraoperative hypertension (62% vs. 34% controls, P <0.001), and postoperative hyperten-sion in the first 12 hours after surgery (62% vs. 25% controls, P <0.001). A recent large retrospective study in patients with anti-coagulant-associated intracranial hematoma demonstrated that lowering SBP to less than 160 mmHg within 4 hours of admis-sion was associated with a reduced risk of hematoma expan-sion (n = 691, 33.1% <160 mmHg vs. 52.4 % in ≥160 mmHg; P <.001).33 However, there are no specific recommendations from the Brain Trauma Foundation on a hypertension threshold to avoid in patients with traumatic intracranial hematoma.Anticoagulation Reversal and Prophylaxis Patients with intracranial hematoma who are on anticoagulation for car-diovascular indications (atrial fibrillation, cardiac stents, or mechanical valves) or stroke prevention present a challenging population. Anticoagulation reversal is important to reduce the risk of hematoma expansion; however, anticoagulant reversal is also associated with thrombotic cardiovascular complications. A recent retrospective study in patients with nontraumatic, oral-anticoagulant–associated intracranial hematoma showed that lowering the INR to <1.3 within 4 hours of admission was an independent predictor of hematoma expansion (n = 853; 19.8% vs. 41.5% in INR of ≥1.3; P <.001). Furthermore, this study showed that the risk of ischemic complications was greater in patients that were not restarted on oral anticoagulation as com-pared to those that were subsequently restarted (n = 719; 5.2% vs. 15%, no restart, P <0.001); however, they did not observe a significant increase in the risk of hemorrhage with anticoagula-tion restart (n = 719; 8.1%, vs. 6.6%, P = 0.48). The median time to anticoagulation restart was 30 days after discharge (inter-quartile range 18–65), as such, these data do not speak to risks and benefits of restarting anticoagulation in the acute post-bleed interval. It is important to note that the risks and benefits of restarting anticoagulation will vary based on the individual patient and the patient’s indications for anticoagulation (e.g., mechanical heart valve vs. atrial fibrillation). As such, close collaboration between the neurosurgery and cardiology teams are important in optimizing a management strategy for these patients.Anticoagulation prophylaxis for prevention of venous thrombosis also involves a risk-benefit analysis. Per a level III (low-quality) recommendation of Brain Trauma Foundation Guidelines,10 anticoagulation prophylaxis with low-molecular-weight heparin or low-dose unfractionated heparin may be used to reduce the risk of venous thrombosis, even though it is associ-ated with an increased risk of intracranial hematoma expansion. It may be reasonable to initiate prophylactic anticoagulation 24 hours after an intracranial hematoma is deemed to be stable. A single-center retrospective study (n = 236) found that such a strategy was associated with a decreased risk of DVT (0% vs. 5.6% (n = 6), P <0.001), but did not observe significant differ-ences in the rates of pulmonary embolism (0.78% (n = 1) vs. 3.74% (n = 4), P = 0.18) or intracranial hematoma expansion (0.7% [1] vs. 2.8% [3], P = 0.3). However, because of the low rate of clinical events observed in this series, the study may have been underpowered to identify small differences in pulmonary embolism or hematoma expansion.Indications for Invasive Intracranial Monitoring In patients with severe TBI (GCS <8), the Brain Trauma Founda-tion guidelines endorse a level IIB recommendation (low-quality of evidence) for ICP and cerebral perfusion pressure (CPP) to reduce short-term mortality (within 2 weeks of hospitalization). They also provide level IIB recommendations for treating ICP >22 mmHg and treating CPP level between 60 and 70 mmHg to optimize outcomes. These recommendations are supported by a recent retrospective cohort study (n = 459)34 that identified ICP and CPP thresholds that best discriminated between survi-vors and nonsurvivors in severe TBI, and also between survivors with “poor” and “favorable’ outcomes (Glasgow Outcome Scale 1–3 vs. 4–6). A large, multicenter randomized controlled trial performed in 6 hospitals in Equador and Bolivia did not sup-port the claim that intracranial monitoring in severe TBI results in improved clinical outcomes. Chestnut et al in 2012 did not observe a significant difference in mortality or favorable out-comes (as assessed by the Glasgow Outcome Scale) when severe TBI patients were managed with an intracranial monitor (n = 56), or with imaging and clinical exam (n = 53, P = 0.43). Advanced multimodal monitoring such as brain tissue oxygen (PbrO2) mon-itoring, jugular bulb monitoring of arteriovenous oxygen content difference (AVDO2), cerebral autoregulation with TCD, and micro dialysis are under active investigation. Only jugular bulb monitoring of AVDO2 is associated with a level III (poor-quality evidence) recommendation to guide management in severe TBI. Brunicardi_Ch42_p1827-p1878.indd 184001/03/19 7:16 PM 1841NEUROSURGERYCHAPTER 42The Brain Tissue Oxygen Monitoring in TBI (BOOST) trials are actively investigating the added benefit of brain tissue oxygen-ation beyond intracranial pressure monitoring in severe TBI.Decompressive Craniectomy for Severe TBI Decompressive craniectomy can be performed to relieve intracranial pressure associated with diffuse cerebral edema in cases of severe TBI without mass lesions (e.g., extra-axial hematoma). This is a controversial issue as there is a paucity of high-quality evi-dence providing clear support for or against this intervention. The DECRA trial (a multicenter, randomized, controlled trial, n = 155) compared bifrontal decompressive craniectomy to medical management for the treatment of patients with severe TBI and elevated intracranial pressure refractory to first-tier therapies (ICP >20 mmHg for at least 15 minutes within an hour). They found no significant difference in mortality at six months, and found that functional outcomes (as measured by the Extended Glasgow Outcome Scale) were worse in patients who underwent surgery. They found a clear improvement in ICP and number of days in the ICU in patients that underwent surgery as compared to medical management. Of note, they used an intention-to-treat analysis, such that 18% of patients in the medical management group underwent a delayed cra-niotomy as a life-saving procedure. More recently, the RES-CUE-ICP trial36 (a multicenter, randomized, controlled trial, n = 408) compared decompressive craniotomy and ongoing medical care in patients with severe TBI (without mass lesions) with elevated ICP (>25 mmHg) refractory to firstand second-tier interventions (medical management and ventriculostomy). Patients were randomized to either receive a barbiturate infu-sion (medical group) or undergo decompressive craniotomy (surgery group; unilateral hemicraniectomy vs. bifrontal crani-otomy depending on degree of bilateral swelling and surgeon discretion). Again, they used an intention-to-treat analysis such that 37% of patients of the medical group underwent decom-pressive hemicraniectomy. At 6 months, decompressive crani-ectomy in patients with traumatic brain injury and refractory intracranial hypertension resulted in lower mortality and higher rates of vegetative state, lower severe disability, and upper severe disability than medical care. The rates of moderate dis-ability and good recovery were similar in the two groups. The recent Brain Trauma Foundation Guidelines offer a level II (moderate-quality) recommendation against performing a bifrontal decompressive hemicraniectomy to improve func-tional outcomes at 6 months in patients with severe TBI with diffuse injury and no mass lesions, and with elevated ICP that is medically refractory. They note that this procedure has been demonstrated to reduce time in the ICU and ICP. However, they have not made an updated recommendation since the results of the RESCUE-ICP trial have been published.The results of the DECRA and RESCUE-ICP trials suggest caution and careful consideration prior to perform-ing decompressive craniotomy in treating severe TBI without mass lesions. There is now evidence that this procedure can be lifesaving and reduce mortality at 6 months; however, it is not clear that the survivors have a favorable functional outcome (as grossly measured by the Extended Glasgow Outcome Scale). By improving ICP and reducing time in the ICU, it may hasten the recovery process by allowing patients to begin rehabilita-tion earlier. Also, several unanswered questions remain. For example, might outcomes be improved if decompressive cra-niectomy was performed earlier, prior to the patient develop-ing refractory ICP, and presumably secondary brain injury? As such, the decision of whether or not to perform decompressive craniotomy must be carefully considered within the context of each individual patient’s clinical scenario, the patient’s avail-able social support system, and the family’s disposition and goals of care.Vascular Injury. Trauma to the head or neck may cause damage to the carotid or vertebrobasilar systems. Generally, dissection refers to violation of the vessel wall intima. Blood at arterial pressures can then open a plane between the intima and media, within the media, or between the media and adventitia. The newly created space within the vessel wall is referred to as the false lumen. Tissue or organs supplied by dissected ves-sels may subsequently be injured in several ways. Expansion of the hematoma within the vessel wall can lead to narrowing of the true vessel lumen and reduction or cessation of distal blood flow. Slow-flowing or stagnant blood within the false lumen exposed to thrombogenic vessel wall elements may thrombose. Pieces of thrombus may then detach and cause distal embolic arterial occlusion. Also, the remaining partial-thickness vessel wall may rupture, damaging adjacent structures.Traumatic dissection may occur in the carotid artery (ante-rior circulation) or the vertebral or basilar arteries (posterior cir-culation). Dissections may be extradural or intradural. Intradural dissection can present with subarachnoid hemorrhage (SAH). Traditional angiography remains the basis of diagnosis and characterization of arterial dissection. Angiographic abnormali-ties include stenosis of the true lumen, or “string-sign,” visible intimal flaps, and the appearance of contrast in the false lumen. Four-vessel cerebral angiography should be performed when suspicion of dissection exists.Historically, patients with documented arterial dissec-tion have been anticoagulated with heparin and then warfarin to prevent thromboembolic stroke. Trauma patients often have concomitant absolute or relative contraindications to anticoagu-lation, complicating management. Antiplatelet therapy is often implemented in lieu of full anticoagulation, however, there is no randomized clinical trial comparing the two therapies.37 Consider surgical or interventional techniques for persisting embolic disease and for vertebral dissections presenting with SAH. Surgical options include vessel ligation and bypass graft-ing. Interventional radiology techniques include stenting and vessel occlusion. Occlusion techniques require sufficient col-lateral circulation to perfuse the vascular territory previously supplied by the occluded vessel.Carotid Dissection Carotid dissection may result from neck extension combined with lateral bending to the opposite side, or trauma from an incorrectly placed shoulder belt tightening across the neck in a motor vehicle accident. Extension or bend-ing stretches the carotid over the bony transverse processes of the cervical vertebrae, while seat belt injuries cause direct trauma. Symptoms of cervical carotid dissection include con-tralateral neurologic deficit from brain ischemia, headache, and ipsilateral Horner’s syndrome from disruption of the sympa-thetic tracts ascending from the stellate ganglion on the surface of the carotid artery. The patient may complain of a bruit.Traumatic vessel wall injury to the portion of the carotid artery running through the cavernous sinus may result in a carotid-cavernous fistula (CCF). This creates a high-pressure, high-flow pathophysiologic blood flow pattern. CCFs clas-sically present with pulsatile proptosis (the globe pulses out-ward with arterial pulsation), retro-orbital pain, and decreased visual acuity or loss of normal eye movement (due to damage Brunicardi_Ch42_p1827-p1878.indd 184101/03/19 7:16 PM 1842SPECIFIC CONSIDERATIONSPART IIto cranial nerves III, IV, and VI as they pass through the cav-ernous sinus). Symptomatic CCFs should be treated to preserve eye function. Fistulae may be closed by balloon occlusion using interventional neuroradiology techniques. Fistulae with wide necks are difficult to treat and may require total occlusion of the parent carotid artery.Vertebrobasilar Dissection Vertebrobasilar dissection may result from sudden rotation or flexion/extension of the neck, chiropractic manipulation, or a direct blow to the neck. Com-mon symptoms are neck pain, headache, and brain stem stroke or SAH. The risks and benefits of aspirin therapy are unclear when a vertebral dissection extends intracranially. The theoreti-cally increased friability of the vessel wall may increase the risk of SAH when coupled with an antiplatelet agent. Consultation of a stroke neurologist is recommended in this situation.Brain Death. Brain death occurs when there is an absence of signs of brain stem function or motor response to deep central pain in the absence of pharmacologic or systemic medical con-ditions that could impair brain function.Clinical Examination A neurologist, neurosurgeon, or inten-sivist generally performs the clinical brain death examination. Two examinations consistent with brain death 12 hours apart, or one examination consistent with brain death followed by a consistent confirmatory study generally is sufficient to declare brain death (see following paragraphs). Hospital regulations and local laws regarding documentation should be followed closely.Establish the absence of complicating conditions before beginning the examination. The patient must be normotensive, euthermic, and oxygenating well. The patient may not be under the effects of any sedating or paralytic drugs.Documentation of no brain stem function requires the fol-lowing: nonreactive pupils; lack of corneal blink, oculocephalic (doll’s eyes), oculovestibular (cold calorics) reflexes; and loss of drive to breathe (apnea test). The apnea test demonstrates no spontaneous breathing even when Paco2 is allowed to rise above 60 mmHg.Deep central painful stimuli are provided by bilateral forceful twisting pinch of the supraclavicular skin and pressure to the medial canthal notch. Pathologic responses such as flexor or extensor posturing are not compatible with brain death. Spi-nal reflexes to peripheral pain, such as triple flexion of the lower extremities, are compatible with brain death.Confirmatory Studies Confirmatory studies are performed after a documented clinical examination consistent with brain death. A study consistent with brain death may obviate the need to wait 12 hours for a second examination. This is especially important when the patient is a potential organ donor, as brain-dead patients often have progressive hemodynamic instability. Lack of cerebral blood flow consistent with brain death may be documented by cerebral angiography or technetium radio-nuclide study. A “to-and-fro” pattern on transcranial Doppler ultrasonography indicates no net forward flow through the cere-bral vasculature, consistent with brain death. An electroenceph-alogram (EEG) documenting electrical silence has been used but generally is not favored because there is often significant artifact which impairs interpretation.Spine TraumaThe spine is a complex biomechanical structure. The spine pro-vides structural support for the body as the principal compo-nent of the axial skeleton, while protecting the spinal cord and nerve roots. Trauma may fracture bones or cause ligamentous disruption. Often, bone and ligament damage occur together. Damage to these elements reduces the strength of the spine and may cause instability, which compromises both supportive and protective functions. Spine trauma may occur with or without neurologic injury.Neurologic injury from spine trauma is classified as either incomplete or complete. If there is some residual motor or sensory neurologic function below the level of the lesion, as assessed by clinical examination, the injury is defined as incom-plete.38 A patient with complete neurologic dysfunction persist-ing 24 hours after injury has a very low probability of return of function in the involved area.Neurologic injury from spine trauma may occur immedi-ately or in delayed fashion. Immediate neurologic injury may be due to direct damage to the spinal cord or nerve roots from pen-etrating injuries, especially from stab wounds or gunshots. Blunt trauma may transfer sufficient force to the spine to cause acute disruption of bone and ligament, leading to subluxation, which is a shift of one vertebral element in relation to the adjacent level. Subluxation decreases the size of the spinal canal and neu-ral foramina and causes compression of the cord or roots. Such neural impingement can also result from retropulsion of bone fragments into the canal during a fracture. Transection, crush injury, and cord compression impairing perfusion are mecha-nisms leading to SCI. Delayed neurologic injury may occur dur-ing transportation, examination of an improperly immobilized patient, or during a hypotensive episode.The Mechanics of Spine Trauma. Trauma causes a wide variety of injury patterns in the spine due to its biomechanical complexity. A mechanistic approach facilitates an understand-ing of the patterns of injury, as there are only a few types of forces that can be applied to the spine. Although these forces are discussed individually, they often occur in combination. Several of the most common injury patterns are then presented to illus-trate the clinical results of these forces applied at pathologically high levels.Flexion/Extension Bending the head and body forward into a fetal position flexes the spine. Flexion loads the spine anteriorly (the vertebral bodies) and distracts the spine posteriorly (the spi-nous process and interspinous ligaments). High flexion forces occur during front-end motor vehicle collisions, and backward falls when the head strikes first. Arching the neck and back extends the spine. Extension loads the spine posteriorly and distracts the spine anteriorly. High extension forces occur dur-ing rear-end motor vehicle collisions (especially if there is no headrest), frontward falls when the head strikes first, or diving into shallow water.Compression/Distraction Force applied along the spinal axis (axial loading) compresses the spine. Compression loads the spine anteriorly and posteriorly. High compression forces occur when a falling object strikes the head or shoulders, or when landing on the feet, buttocks, or head after a fall from height. A pulling force in line with the spinal axis distracts the spine. Dis-traction unloads the spine anteriorly and posteriorly. Distraction forces occur during a hanging, when the chin or occiput strikes an object first during a fall, or when a passenger submarines under a loose seat belt during a front-end motor vehicle collision.Rotation Force applied tangential to the spinal axis rotates the spine. Rotation depends on the range of motion of interverte-bral facet joints. High rotational forces occur during off-center Brunicardi_Ch42_p1827-p1878.indd 184201/03/19 7:16 PM 1843NEUROSURGERYCHAPTER 42impacts to the body or head or during glancing automobile accidents.Patterns of Injury. Certain patterns of injury resulting from combinations of the previously mentioned forces occur com-monly and should be recognized during plain film imaging of the spine. Always completely evaluate the spine. A patient with a spine injury at one level has a significant risk for additional injuries at other levels.Cervical The cervical spine is more mobile than the thoraco-lumbar spine. Stability comes primarily from the multiple liga-mentous connections of adjacent vertebral levels. Disruption of the cervical ligaments can lead to instability in the absence of fracture. The mass of the head transmits significant forces to the cervical spine during abrupt acceleration or deceleration, increasing risk for injury.Jefferson Fracture A Jefferson fracture is a bursting fracture of the ring of C1 (the atlas) due to compression forces. There are usually two or more fractures through the ring of C1. The open-mouth odontoid view may show lateral dislocation of the lateral masses of C1. The rule of Spence states that 7 mm or greater combined dislocation indicates disruption of the transverse liga-ment. The transverse ligament stabilizes C1 with respect to C2. Jefferson fractures dislocated <7 mm usually are treated with a rigid collar, while those dislocated 7 mm or greater usually are treated with a halo vest. Surgical intervention is not indicated.Odontoid Fractures The odontoid process, or dens, is the large ellipse of bone arising anteriorly from C2 (the axis) and projecting up through the ring of C1 (the atlas). Several strong ligaments connect the dens to C1 and to the base of the skull. Odontoid fractures usually result from flexion forces. Odontoid fractures are classified as type I, II, or III. A type I fracture involves the tip only. A type II fracture passes through the base of the odontoid process. A type III fracture passes through the body of C2. Types II and III are considered unstable and should be externally immobilized or fused surgically. Surgery often is undertaken for widely displaced fractures (poor chance of fus-ing) and for those that fail external immobilization. Type I frac-tures usually fuse with external immobilization only.Hangman’s Fracture Traditionally considered a hyperexten-sion/distraction injury from placement of the noose under the angle of the jaw, hangman’s fractures also may occur with hyperextension/compression, as with diving accidents, or hyper-flexion. The injury is defined by bilateral C2 pars interarticularis fractures. The pars interarticularis is the bone between superior and inferior facet joints. Thus, the posterior bony connection between C1 and C3 is lost. Hangman’s fractures heal well with external immobilization. Surgery is indicated if there is spinal cord compression or after failure of external immobilization.Jumped Facets—Hyperflexion Injury The facet joints of the cervical spine slope forward. In a hyperflexion injury, the supe-rior facet can “jump” over the inferior facet of the level above if the joint capsule is torn. Hyperflexion/rotation can cause a unilateral jumped facet, whereas hyperflexion/distraction leads to bilateral jumped facets. Patients with unilateral injury usually are neurologically intact. Those with bilateral injury, however, typically suffer from spinal cord damage, since the anteropos-terior diameter of the spinal canal is compromised by bilateral injury, leading to spinal cord compression (Fig. 42-11).Thoracolumbar The thoracic spine is stabilized significantly by the rib cage. The lumbar spine has comparatively large vertebrae. Thus, the thoracolumbar spine has a higher thresh-old for injury than the cervical spine. A three-column model is useful for categorizing thoracolumbar injuries.39 The anterior longitudinal ligament and the anterior half of the vertebral body constitute the anterior column. The posterior half of the ver-tebral body and the posterior longitudinal ligament constitute the middle column. The pedicles, facet joints, laminae, spinous processes, and interspinous ligaments constitute the posterior column.Compression Fracture Compression fracture is a compression/flexion injury causing failure of the anterior column only. It is stable and not associated with neurologic deficit, although the patient may still have significant pain (Fig. 42-12).Burst Fracture Burst fracture is a pure axial compression injury causing failure of the anterior and middle columns. It is unstable, and perhaps half of patients have neurologic deficit due to compression of the cord or cauda equina from bone frag-ments retropulsed into the spinal canal.Chance Fracture Chance fracture is a flexion-distraction injury causing failure of the middle and posterior columns, sometimes with anterior wedging. Typical injury is from a lap seat-belt hyperflexion with associated abdominal injury. It often is unsta-ble and associated with neurologic deficit.Fracture-Dislocation Fracture-dislocation is failure of the anterior, middle, and posterior columns caused by flexion/dis-traction, shear, or compression forces. Neurologic deficit can result from retropulsion of middle column bone fragments into the spinal canal, or from subluxation causing decreased canal diameter (Fig. 42-13).Initial Assessment and Management. The possibility of a spine injury must be considered in all trauma patients. A patient with no symptoms referable to neurologic injury, a normal neu-rologic examination, no neck or back pain, and a known mecha-nism of injury unlikely to cause spine injury is at minimal risk for significant injury to the spine. Victims of moderate or severe trauma, especially those with injuries to other organ systems, usually fail to meet these criteria or cannot be assessed ade-quately. The latter often is due to impaired sensorium or signifi-cant pain. Because of the potentially catastrophic consequences of missing occult spine instability in a neurologically intact patient, a high level of clinical suspicion should govern patient care until completion of clinical and radiographic evaluation.The trauma patient should be kept on a hard, flat board with straps and pads used for immobilization. A hard cervical collar is kept in place. These steps minimize forces transferred through the spine and therefore decrease the chance of causing dislocation, subluxation, or neural compression during transport to the trauma bay. The patient is then moved from the board to a flat stretcher. The primary survey and resuscitation are com-pleted. Physical examination and initial X-rays follow.For the examination, approach the patient as described in “Neurologic Examination” earlier in this chapter. Evaluation for spine or SCI is easier and more informative in awake patients. If the patient is awake, ask if he or she recalls details of the nature of the trauma, and if there was loss of consciousness, numbness, or inability to move any or all limbs. Assess motor function by response to commands or pain, as appropriate. Assess pinprick, light touch, and joint position, if possible. Determining the ana-tomically lowest level of intact sensation can pinpoint the level of the lesion along the spine. Testing sensation in an ascending fashion will allow the patient to better discern the true stimulus Brunicardi_Ch42_p1827-p1878.indd 184301/03/19 7:16 PM 1844SPECIFIC CONSIDERATIONSPART IIas opposed to determine when it is extinguished. Document muscle stretch reflexes, lower sacral reflexes (i.e., anal wink and bulbocavernosus), and rectal tone.American Spinal Injury Association Classification The American Spinal Injury Association provides a method of clas-sifying patients with spine injuries. The classification indicates completeness and level of the injury and the associated deficit. A form similar to that shown in Fig. 42-14 should be available in the trauma bay and completed for any spine injury patient. The association also has worked to develop recommendations and guidelines to standardize the care of SCI patients in an effort to improve the quality of care.Neurologic Syndromes. Penetrating, compressive, or isch-emic cord injury can lead to several characteristic presentations Figure 42-11. A. Lateral cervical spine X-ray of an elderly woman who struck her head during a backward fall. Arrowhead points to jumped facets at C5–C6. Note the anterior displace-ment of the C5 body with respect to the C6 body. B. Sagittal T2-weighted magnetic resonance imaging of the same patient, revealing compromise of the spinal canal and compression of the cord. Note the bright signal within the cord at the level of compression, indicating spinal cord injury. C. Lateral cervical spine X-ray of same patient after application of cervical trac-tion and manual reduction. Note restoration of normal alignment. D. Lateral cervical spine X-ray after posterior cervical fusion to restabilize the C5–C6 segment of the spine.ABCDBrunicardi_Ch42_p1827-p1878.indd 184401/03/19 7:16 PM 1845NEUROSURGERYCHAPTER 42Figure 42-12. A. Lateral lumbar spine X-ray showing a compres-sion fracture of L2. Arrowhead points to anterior wedge deformity. Note the posterior wall of the vertebral body has retained normal height and alignment. B. Axial computed tomography scan through the same fracture. Arrowhead demonstrates a transverse discontinu-ity in the superior endplate of the L2 body.ABFigure 42-13. Sagittal reconstruction of an axial fine-slice com-puted tomography scan through the lumbar spine demonstrating a severe fracture-dislocation through the body of L2.based on the anatomy of injury. The neurologic deficits may be deduced from the anatomy of the long sensory and motor tracts and understanding of their decussations (Fig. 42-15). Four pat-terns are discussed. First, injury to the entire cord at a given level results in anatomic or functional cord transection with total loss of motor and sensory function below the level of the lesion. The typical mechanism is severe traumatic vertebral subluxation reducing spinal canal diameter and crushing the cord. Second, injury to half the cord at a given level results in Brown-Séquard syndrome, with loss of motor control and proprioception ipsilat-erally and loss of nociception and thermoception contralaterally. The typical mechanism is a stab or gunshot wound. Third, injury to the interior gray matter of the cord in the cervical spine results in a central cord syndrome, with upper extremity worse than lower extremity weakness and various degrees of numbness. The typical mechanism is transient compression of the cervical cord by the ligamentum flavum buckling during traumatic neck hyperextension. This syndrome occurs in patients with preex-isting cervical stenosis. Fourth, injury to the ventral half of the cord results in the anterior cord syndrome, with paralysis and loss of nociception and thermoception bilaterally. The typical mechanism is an acute disc herniation or ischemia from anterior spinal artery occlusion.Studies. Anteroposterior and lateral plain films provide a rapid survey of the bony spine. Plain films detect fractures and dislo-cations well. Adequate visualization of the lower cervical and upper thoracic spine often is impossible because of the shoul-der girdle. Complete plain film imaging of the cervical spine includes an open-mouth view to assess the odontoid process and the lateral masses of C1. Fine-slice CT scan with sagittal and coronal reconstructions provides good detail of bony anatomy and is good for characterizing fractures seen on plain films, as well as visualizing C7–T1 when not well seen on plain films. MRI provides the best soft tissue imaging. Canal compromise from subluxation, acute disc herniations, or ligamentous disrup-tion is clearly seen. MRI also may detect EDHs or damage to the spinal cord itself, including contusions or areas of ischemia.Brunicardi_Ch42_p1827-p1878.indd 184501/03/19 7:16 PM 1846SPECIFIC CONSIDERATIONSPART IIIndications for Screening for Vascular Injury With Cer-vical Spine Trauma It is important to consider the pres-ence of blunt cerebrovascular injury in patents with cervical spine trauma; however, the specific indications for obtaining a screening CT angiography study are controversial. Many trauma centers rely on the Denver Criteria.40 These criteria indicate that screening should be employed for a cervical ver-tebral body or transverse foramen fracture, subluxation, or ligamentous injury at any level, or any fracture at the level of C1–C3, among other indications such as concerning mecha-nism, Lefort mid-face fractures, or basilar fractures through the carotid canal. A recent single-center retrospective study41 (n = 1717 cervical spine fractures) found a higher risk of ver-tebral artery injury only in the setting of fractures of C1 and C2 (combined), those that involve the transverse foramen, or had significant subluxation. They did not find that “high-risk” cervical spine fractures as defined by the Denver Criteria were associated with an increased risk of blunt cerebrovascular injury. Based on these data, we feel that it is appropriate to use a more defined set of screening criteria as outlined by Lock-wood et al to reduce cost and contrast-exposure in patients with cervical spine fractures.Figure 42-14. The American Spinal Injury Association system for categorizing spinal cord injury patients according to level and degree of neurologic deficit.Dorsal column(touch, vibration)Corticospinal tract(upper motor)Anterior horn(lower motor)Spinothalmic tract(pain, temperature)TransectionCentral cordBrown-SequardAnterior spinal a.Figure 42-15. Spinal cord injury patterns. a. = artery. (Adapted with permission from Hoff J, Boland M: Neurosurgery, in Schwartz SI: Principles of Surgery, 7th ed., New York, NY: McGraw-Hill Education; 1999.)Brunicardi_Ch42_p1827-p1878.indd 184601/03/19 7:16 PM 1847NEUROSURGERYCHAPTER 42Definitive Management Spinal-Dose Steroids Several studies have investigated the use of methylprednilosone in acute spinal cord injury. The National Acute Spinal Cord Injury studies (NASCIS I, II, and III) provided some support for the view that administration of high-dose methylprednilosone in acute spinal cord injury results in improved neurologic outcomes. A post-hoc analy-sis performed as part of NASCIS II demonstrated improved neurologic outcomes if methylprednilosone was administered within 8 hours of injury. A post-hoc analysis in NASCIS III showed improved outcomes at 6 weeks and 6 months, but not 1 year when methylprednilosone was administered within 3 and 8 hours of injury.42,43,44 However, these findings are tempered by the fact that these benefits were modest and only demonstrated in post-hoc analyses, and by the high rate of medical compli-cations associated with corticosteroid administration. All three NASCIS trials showed that methylprednilosone was associated with a higher rate of complications such as pneumonia, severe sepsis, and poor wound healing. A recent Cochrane review did not observe a significant increase in complications or mortal-ity associated with methylprednilosone administration in acute spinal cord injury, but did observe a trend towards this effect.45 Despite the lack of clear evidence on this issue, the most recent acute spinal cord injury guidelines provide a controversial level I recommendation against the use of corticosteroids in acute spinal cord injury.46 Some authors have argued for the use of methylprednilosone within 8 hours of acute spinal cord injury in carefully selected patients (e.g., young males that are less prone to medical complications associated with corticosteroids47). Thus, clear consensus on the use of spinal-dose steroids does not exist.48 A decision to use or not use spinal-dose steroids may be dictated by local or regional practice patterns, especially given the legal liability issues surrounding SCI. Patients with gunshot or nerve root (cauda equina) injuries, or those who are pregnant, <14 years old, or on chronic steroids were excluded from the NASCIS studies and should not receive spinal-dose steroids. In addition to steroids, hypothermia for SCI has also received attention. There is even less evidence supporting the use of this treatment, and thus, it is not currently recommended.49Orthotic Devices Rigid external orthotic devices can stabilize the spine by decreasing range of motion and minimizing stress transmitted through the spine. Commonly used rigid cervical orthoses include Philadelphia and Miami-J collars. Cervical collars are inadequate for C1, C2, or cervicothoracic instability. Cervicothoracic orthoses brace the upper thorax and the neck, improving stabilization over the cervicothoracic region. Minerva braces improve high cervical stabilization by brac-ing from the upper thorax to the chin and occiput. Halo vest assemblies provide the most external cervical stabilization. Four pins are driven into the skull to lock the halo ring in position. Four posts arising from a tight-fitting rigid plastic vest immobilize the halo ring. Lumbar stabilization may be provided by thoracolumbosacral orthoses. A variety of compa-nies manufacture lines of spinal orthotics. A physician familiar with the technique should fit a halo vest. Assistance from a trained orthotics technician improves fitting and adjustment of the other devices.Surgery Neurosurgical intervention has two goals: decompres-sion of the spinal cord and nerve roots, and stabilization of the spine. When spinal cord injury is caused by a hyperflexiondistraction injury that results in cord compression and an unstable spine, both surgical decompression and fusion are typically required. However, in cases of a hyperextension injury causing central cord syndrome due to chronic cervical stenosis, surgi-cal decompression may be needed without the need for inter-nal fixation. In cases where there significant anterolisthesis (subaxial cervical jumped or perched facets), reduction of the fracture may be important for both decompression and stabili-zation. However, in some cases, reduction of the fracture may not be sufficient for decompression, and further decompressive surgery may still be needed.50Several controversial topics require consideration here. First, the timing of surgery has been a controversial topic. In the past, it has been suggested that patients with incomplete injury, or a deteriorating exam warrant emergent decompres-sion, whereas patients with complete injuries can undergo sur-gery in a nonemergent manner. It is important to appreciate the risks of taking a medically unstable patient to surgery, such as a polytrauma patient with hemorrhagic shock or a complete spinal cord injury patient in neurogenic shock. However, there are clear benefits to early surgical decompression: it can allow early mobilization, aggressive nursing care, and physical ther-apy. Furthermore, a recent prospective cohort study found that the odds of observing a two-point increase in ASIA grade at 6 months was higher in patients that underwent surgery within 24 hours, as compared to those that underwent surgery after 24 hours.51 These data suggest that a subpopulation of patients may significantly benefit from early surgery; however, the char-acteristics of these patients were not described, suggesting a het-erogeneous population in terms of preoperative ASIA grade and imaging.In general, spine trauma patients with complete neurologic deficit, without any signs of recovery, or those without any neu-rologic deficits who have bony or ligamentous injury requiring open fixation, may be medically stabilized before undergoing surgery. Surgical stabilization may be indicated for some inju-ries that would eventually heal with conservative treatment. Solid surgical stabilization may also allow a patient to be man-aged with a rigid cervical collar who would otherwise require halo-vest immobilization.Continued Care. Regional SCI centers with nurses, respira-tory therapists, pulmonologists, physical therapists, physiat-rists, and neurosurgeons specifically trained in caring for these patients may improve outcomes. Frequently encountered ICU issues include hypotension due to neurogenic shock (due to loss of sympathetic tone) and aspiration pneumonia. The recent guidelines recommend maintaining MAPs >85 for 7 days after injury.46 Chronically, prevention and treatment of deep venous thrombosis, autonomic hyperreflexia, and decubitus ulcer for-mation are important. Many patients with cervical or high tho-racic cord injuries require prolonged ventilatory support until the chest wall becomes stiff enough to provide resistance for diaphragmatic breathing. Patients with high cervical cord inju-ries (C4 or above) will often require permanent ventilatory sup-port. Patients should be transferred to SCI rehabilitation centers after stabilization of medical and surgical issues.Peripheral Nerve TraumaThe peripheral nervous system extends throughout the body and is subject to injury from a wide variety of trauma. Periph-eral nerves transmit motor and sensory information from the CNS to the body. An individual nerve may have pure motor, pure sensory, or mixed motor and sensory functions. The key Brunicardi_Ch42_p1827-p1878.indd 184701/03/19 7:16 PM 1848SPECIFIC CONSIDERATIONSPART IIinformation-carrying structure of the nerve is the axon. The axon transmits information from the neuronal cell body and may measure from <1 mm to >1 m in length. Axons that travel a significant distance are often covered with myelin, which is a lipid-rich, electrically insulating sheath formed by Schwann cells. Myelinated axons transmit signals much more rapidly than unmyelinated axons because the voltage shifts and currents that define action potentials effectively jump from gap to gap over the insulated lengths of the axon.Axons, whether myelinated or unmyelinated, travel through a collagenous connective tissue known as endoneurium. Groups of axons and their endoneurium form bundles known as fascicles. Fascicles run through a tubular collagenous tissue known as perineurium. Groups of fascicles are suspended in mesoneurium. Fascicles and their mesoneurium run through another tubular collagenous tissue known as epineurium. The epineurium and its contents form the nerve.There are four major mechanisms of injury to peripheral nerves. Nerves may be lacerated, stretched, compressed, or contused. Knives, passing bullets, or jagged bone fractures may lacerate nerves. Adjacent expanding hematomas or dislocated fractures may stretch nerves. Expanding hematomas, external orthoses such as casts or braces, or blunt trauma over a super-ficial nerve may compress or crush nerves. Shock waves from high-velocity bullets may contuse nerves. These mechanisms of injury cause damage to the various anatomic components of the nerve. The patterns of damage are categorized in “Types of Injury.”Certain nerve segments are particularly vulnerable to injury. The following four characteristics make a nerve seg-ment more vulnerable: proximity to a joint, superficial course, passage through a confined space, and being fixed in position.Types of Injury. The traditional classification system for peripheral nerve injury is the Seddon classification. Seddon described three injury patterns as defined in the “Neurapraxia,” “Axonotmesis,” and “Neurotmesis” sections. The Seddon clas-sification provides a simple, anatomically based approach to peripheral nerve injury.52Neurapraxia Neurapraxia is defined as the temporary failure of nerve function without physical axonal disruption. Axon degeneration does not occur. Return of normal axonal function occurs over hours to months, often in the 2to 4-week range.Axonotmesis Axonotmesis is the disruption of axons and myelin. The surrounding connective tissues, including endo-neurium, are intact. The axons degenerate proximally and dis-tally from the area of injury. Distal degeneration is known as Wallerian degeneration. Axon regeneration within the con-nective tissue pathways can occur, leading to restoration of function. Axons regenerate at a rate of 1 mm per day. Significant functional recovery may occur for up to 18 months. Scarring at the site of injury from connective tissue reaction can form a neuroma and interfere with regeneration.Neurotmesis Neurotmesis is the disruption of axons and endoneurial tubes. Peripheral collagenous components, such as the epineurium, may or may not be intact. Proximal and distal axonal degeneration occurs. The likelihood of effective axonal regeneration across the site of injury depends on the extent of neuroma formation and on the degree of persisting anatomic alignment of the connective tissue structures. For instance, an injury may damage axons, myelin, and endoneurium, but leave perineurium intact. In this case, the fascicle sheath is intact, and appropriate axonal regeneration is more likely to occur than if the sheath is interrupted.Management of Peripheral Nerve Injury. The sensory and motor deficits should be accurately documented. Deficits are usually immediate. Progressive deficit suggests a process such as an expanding hematoma and may warrant early sur-gical exploration. Clean, sharp injuries may also benefit from early exploration and reanastomosis. Most other peripheral nerve injuries should be observed. EMG/NCS studies should be done 3-6 to weeks postinjury if deficits persist. Axon seg-ments distal to the site of injury will conduct action potentials normally until Wallerian degeneration occurs, rendering EMG/NCS before 3 weeks uninformative. Continued observation is indicated if function improves. Surgical exploration of the nerve may be undertaken if no functional improvement occurs over 3 months. If intraoperative electrical testing reveals conduction across the injury, continue observation. In the absence of con-duction, the injured segment should be resected and end-to-end primary anastomosis attempted. However, anastomoses under tension will not heal. A nerve graft may be needed to bridge the gap between the proximal and distal nerve ends. The sural nerve often is harvested, as it carries only sensory fibers and leaves a minor deficit when resected. The connective tissue structures of the nerve graft may provide a pathway for effective axonal regrowth across the injury.Patterns of Injury Brachial Plexus The brachial plexus may be injured in a variety of ways. Parturition or a motorcycle accident can lead to plexus injury due to dislocation of the glenohumeral joint. Attempting to arrest a fall with one’s hands can lead to a stretch injury of the plexus due to abrupt movement of the shoulder girdle. An api-cal lung (Pancoast) tumor can cause compression injury to the plexus. There are many patterns of neurologic deficits possible with injury to the various components of the brachial plexus, and understanding them all would require extensive neuroana-tomic discussion. Two well-known eponymous syndromes are Erb’s palsy and Klumpke’s palsy. Injury high in the plexus to the C5 and C6 roots resulting from glenohumeral dislocation causes Erb’s palsy with the characteristic “bellhop’s tip” posi-tion. The arm hangs at the side, internally rotated. Hand move-ments are not affected. Injury low in the plexus, to the C8 and T1 roots, resulting from stretch or compression injury, causes Klumpke’s palsy with the characteristic “claw hand” deformity. There is weakness of the intrinsic hand muscles, similar to that seen with ulnar nerve injury.Radial Nerve The radial nerve courses through the axilla, then laterally and posteriorly in the spiral groove of the humerus. Improper crutch use can cause damage to the axillary portion. The section of the nerve traversing the spiral groove can be damaged by humerus fractures or pressure from improper posi-tioning during sleep. This classically occurs when the patient is intoxicated and is called “Saturday night palsy.” The key find-ing is wrist drop (i.e., weakness of hand and finger extensors). Axillary (proximal) injury causes triceps weakness in addition to wrist drop.Common Peroneal Neuropathy The common peroneal nerve forms the lateral half of the sciatic nerve (the medial half being the tibial nerve). It receives contributions from L4, L5, S1, and S2. It emerges as a separate nerve in the popliteal fossa and laterally wraps around the fibular neck, after which it splits to Brunicardi_Ch42_p1827-p1878.indd 184801/03/19 7:16 PM 1849NEUROSURGERYCHAPTER 42form the deep and superficial peroneal nerves. The superficial, fixed location at the fibular neck makes the common peroneal nerve susceptible to compression. The classic cause of traumatic peroneal neuropathy is crush injury from a car bumper striking the lateral aspect of the leg at the knee. Symptoms of common peroneal neuropathy include foot drop (weakness of the tibialis anterior), eversion weakness, and numbness over the anterolat-eral surface of the lower leg and dorsum of the foot. In contrast, a foot drop due to L5 radiculopathy spares eversion because the S1 fibers are intact. Surgical exploration of a common peroneal crush lesion is typically a low yield endeavor. Rare cases may be due to compressive fibers or adhesions that may be lysed, with the possibility of return of function.CEREBROVASCULAR DISEASECerebrovascular disease is the most frequent cause of new, rapid-onset, nontraumatic neurologic deficit. It is far more common than seizures or tumors. Vascular structures are subject to a vari-ety of chronic pathologic processes that compromise vessel wall integrity. Diabetes, high cholesterol, high blood pressure, and smoking – common comorbidities in the general population – are important risk factors for vascular disease. These conditions can lead to vascular damage by such mechanisms as atheroma deposition causing luminal stenosis, endothelial damage promot-ing thrombogenesis, and weakening of the vessel wall result-ing in aneurysm formation or dissection. These processes may coexist. For instance, a vessel containing an atheromatous plaque will have a decreased luminal diameter. The plaque also may have compromised endothelium, providing the opportunity for thrombus formation, which can lead to acute total occlusion of the remaining lumen. Aneurysms and dissection often occur in atheromatous vessels. Specific patterns of disease relevant to the cerebrovascular system include atheromatous and thrombotic carotid occlusion, brain ischemia from proximal embolic disease, vessel wall rupture leading to hemorrhage, and rupture of abnor-mal, thin-walled structures, specifically aneurysms and AVMs.Ischemic DiseasesIschemic stroke accounts for approximately 85% of acute cerebrovascular events. Symptoms of acute ischemic stroke vary based on the functions of the neural tissues supplied by the occluded vessel, and the presence or absence of collateral circulation. The circle of Willis provides extensive collateral circulation, as it connects the right and left carotid arteries to each other and each to the vertebrobasilar system. Patients with complete occlusion of the carotid artery proximal to the circle of Willis may be asymptomatic if the blood flow patterns can shift and provide sufficient circulation to the ipsilateral cerebral hemisphere from the contralateral carotid and the basilar artery. However, the anatomy of the circle of Willis is highly variable. Patients may have a congenitally hypoplastic or missing com-municating artery with resultant bilateral ACA supply by one carotid, or the PCA may be supplied by the carotid artery rather than the basilar. Similarly, one vertebral artery is often domi-nant and the other is hypoplastic. These variations may make disease in a particular vessel more neurologically devastating than in a patient with full collateral circulation. Occlusion distal to the circle of Willis generally results in a stroke in the territory supplied by that particular artery.Neurologic deficit from occlusive disease may be tempo-rary or permanent. A patient with sudden-onset focal neurologic deficit that resolves within 24 hours has had a transient ischemic attack (TIA). A patient with permanent deficit has had a com-pleted stroke.Thrombotic DiseaseThe most common area of neurologically significant vessel thrombosis is the carotid artery in the neck. Disease occurs at the carotid bifurcation. Thrombosis of a carotid artery chronically narrowed by atheroma can lead to acute carotid occlusion. As discussed previously, this can be asymptomatic due to sufficient collateralization. The more common concern is thromboem-bolus. Intracranial arterial occlusion by local thrombus formation may occur, but it is rare compared to embolic occlusion.Management. Complete occlusion of the carotid artery with-out referable neurologic deficit requires no treatment. A patient with new neurologic deficit and an angiographically confirmed complete carotid occlusion contralateral to the symptoms should be considered for emergent carotid endarterectomy.53 Surgery should be performed within 2 hours of symptom onset and should not be performed on obtunded or comatose patients. These restrictions significantly reduce the number of opera-tive candidates. In nonemergent cases, the results of the large-scale North American Symptomatic Carotid Stenosis Trial (NASCET) demonstrated a stroke reduction benefit to surgical revascularization in patients with severe stenosis, defined as occlusion of 70% to 99% of the carotid.54 Practice guidelines recommend revascularization at this level of stenosis even if asymptomatic. Surgical options for these patients include both carotid endarterectomy and carotid stenting, which have been shown to produce equal outcomes over long-term follow-up.55Embolic DiseaseEmboli causing strokes may originate from a number of sources, including: the left atrium in atrial fibrillation, a hypokinetic left ventricular wall segment, valvular vegetations, an atheromatous aortic arch, stenotic/atheromatous carotid bifurcations, or from the systemic venous system in the presence of a right-to-left shunt, such as a patent foramen ovale. The majority of emboli enter the anterior (carotid) circulation rather than the posterior (vertebro-basilar) circulation. Characteristic clinical syndromes result from embolic occlusion of various vessels within these circulations.Common Types of Strokes Anterior Cerebral Artery Stroke The ACA supplies the medial frontal and parietal lobes as it courses into the inter-hemispheric fissure. Due to its vascular supply of the motor cortex, ACA stroke characteristically results in contralateral leg weakness.Middle Cerebral Artery Stroke The MCA supplies the lateral frontal and parietal lobes and the temporal lobe. MCA stroke results in contralateral face and arm weakness. Dominant-hemisphere MCA stroke causes language deficits due to its sup-ply of Broca’s area, Wernicke’s area, and the white matter tracts that connect the two. Proximal MCA occlusion with ischemia and swelling in the entire MCA territory can lead to significant intracranial mass effect and midline shift (see Fig. 42-6), termed malignant MCA stroke.Posterior Cerebral Artery Stroke The PCA supplies the occipital lobe. PCA stroke results in a contralateral homony-mous hemianopsia (see Fig. 42-6).Posterior Inferior Cerebellar Artery Stroke The PICA sup-plies the lateral medulla and the inferior half of the cerebellar Brunicardi_Ch42_p1827-p1878.indd 184901/03/19 7:16 PM 1850SPECIFIC CONSIDERATIONSPART IIhemispheres. PICA stroke results in nausea, vomiting, nystag-mus, dysphagia, ipsilateral Horner’s syndrome, and ipsilateral limb ataxia. The constellation of symptoms resulting from PICA occlusion is referred to as the lateral medullary or Wallenberg’s syndrome.Management. Ischemic stroke management has two goals: reopen the occluded vessel and maintain blood flow to ischemic “penumbra” tissues bordering the vascular territory. Reopen-ing the vessel has historically been attempted with recombinant tPA.56 tPA administration within 3 hours of the onset of neu-rologic deficit improves outcome at 3 months. In the setting of suspected ischemic stroke, a head CT must be performed immediately to differentiate ischemic from hemorrhagic stroke. Intracranial hemorrhage, major surgery within the previous 2 weeks, GI or genitourinary hemorrhage in the previous 3 weeks, platelet count less than 100,000/µL, and systolic blood pressure >185 mmHg are among the contraindications to tPA therapy.In recent years, a paradigm shift in ischemic stroke man-agement has occurred with the advent of endovascular mechani-cal thrombectomy. Though tPA can be effective for strokes of smaller vessels, it produces recanalization in only 20% of large vessel ischemic strokes, and even less for internal carotid artery occlusion.57 In mechanical thrombectomy, the intracra-nial circulation is accessed endovascularly, and stent-retriever devices can be deployed to definitively remove clot and stent open involved vessels. Initial investigations into the technol-ogy began in 1999 with varied success. Technological advances proceeded, and in 2015, large-scale clinical trials investigating mechanical thrombectomy for large vessel occlusion were pub-lished. The MR-CLEAN trial was one of these. In this trial, 500 patients were randomized to tPA and medical therapy vs. mechanical thrombectomy. The latter group had a significantly better 90-day outcome. A domino effect ensued in which four other similarly large-scale trials (e.g., REVASCAT)58 were ter-minated early.Benefits to mechanical thrombectomy include less strin-gent criteria than tPA administration, focused therapy, and time windows between 6 and 12 hours in trials. Currently, mechani-cal thrombectomy is being used for large vessel occlusion within 6 hours of symptom onset for those patients not eligible for tPA, which accounts for about 10% of ischemic stroke. Its indica-tions and associated technology continue to evolve. It should be noted that current guidelines still support tPA as first-line therapy even for those eligible for mechanical thrombectomy.Patients not eligible for tPA or mechanical thrombectomy require hemodynamic optimization and neurologic monitoring. Admit such patients to the ICU stroke service for blood pres-sure management and frequent neurologic checks. Permissive hypertension allows for maximal cerebral perfusion. Systolic blood pressure >180 mmHg may require treatment, but the opti-mal mean arterial pressure goal is between 100 and 140 mmHg. Give normal saline solution without glucose (which could injure neurons in the penumbra due to osmotic fluid shift), and aim for normovolemia. A stroke patient who worsens clinically should undergo repeat head CT to evaluate for hemorrhage or increas-ing mass effect from swelling, which typically peaks 3 to 5 days after the stroke. Significant swelling from an MCA or cerebellar stroke may cause herniation and brain stem injury. A decom-pressive hemicraniectomy or suboccipital craniectomy can be a life-saving intervention for these select stroke patients. In stud-ies of malignant MCA syndrome, decompressive hemicraniec-tomy showed favorable mortality and functional outcomes.59 This treatment option, however, should be considered with the understanding of potentially poor functional recovery regardless of therapy. One study showed that less than half of malignant MCA patients who underwent decompressive hemicraniectomy returned home following rehabilitation, which is even fewer for those undergoing medical therapy.60Hemorrhagic DiseasesIntracranial hemorrhage from abnormal or diseased vascular structures accounts for approximately 15% of acute cerebrovas-cular events. Hypertension and amyloid angiopathy account for most intraparenchymal hemorrhages, although AVMs, aneu-rysms, venous thrombosis, tumors, hemorrhagic conversion of ischemic infarct, and fungal infections also may be the cause. The term intracranial hemorrhage is frequently used to signify intraparenchymal hemorrhage and will be used here. Intracra-nial hemorrhage causes local neuronal injury and dysfunction and also may cause global dysfunction due to mass effect if sufficiently large. The Intracerebral Hemorrhage (ICH Score) is commonly used to risk-stratify these patients, and it takes into account GCS, age, hemorrhage volume, presence of intraven-tricular hemorrhage, and location to predict mortality. AVM or aneurysm rupture (along with trauma, discussed previously in this chapter) result in subarachnoid hemorrhage (SAH) because the major cerebral and cortical blood vessels travel in the sub-arachnoid space, between the pia and the arachnoid membranes. SAH can cause immediate concussive-like neuronal dysfunc-tion by exposure of the brain to intra-arterial pressure pulsa-tions during the hemorrhage. Moreover, it can cause delayed ischemia from cerebral arterial vasospasm, which can present as acute worsening of the patient’s neurological status days to weeks after the injury. Patients presenting with intracranial hemorrhages that do not follow typical patterns should undergo cerebral angiography or MRI to evaluate for possible underlying lesions, such as AVM or tumor.Hemorrhagic stroke most commonly occurs within the basal ganglia or cerebellum. The patient is usually hypertensive on admission and has a history of poorly controlled hyperten-sion. Such patients are more likely to present with lethargy or obtundation compared to those who suffer an ischemic stroke. Depressed mental status results from mass effect from the hema-toma in deep structures, which can produce midline shift or herniation. Ischemic stroke does not cause mass effect acutely. Therefore, patients are more likely to present with normal con-sciousness and a focal neurologic deficit. Hemorrhagic strokes tend to present with a relatively gradual decline in neurologic function as the hematoma expands, rather than the immediately maximal symptoms caused by ischemic stroke. Table 42-3 pro-vides a listing of relative incidences of intracranial hemorrhage by anatomic distribution.Hypertension. Hypertension increases the relative risk of intracranial hemorrhage by approximately fourfold, likely due to chronic degenerative vasculopathy. Hypertensive hemor-rhages often present in the basal ganglia, thalamus, or pons, and result from breakage of small perforating arteries that branch off of much larger parent vessels (Fig. 42-16).Most hypertensive hemorrhages should be medically man-aged. The hematoma often contains intact, salvageable axons because the blood dissects through and along neural tracts, and surgical clot evacuation destroys these axons. Factors potentially favoring surgery include: superficial clot location, young age, nondominant hemisphere, rapid deterioration, and significant Brunicardi_Ch42_p1827-p1878.indd 185001/03/19 7:16 PM 1851NEUROSURGERYCHAPTER 42Table 42-3Anatomic distribution of intracranial hemorrhages and correlated symptoms% OF INTRACRANIAL HEMORRHAGESLOCATIONCLASSIC SYMPTOMS50Basal ganglia (putamen, globus pallidus), internal capsuleContralateral hemiparesis15ThalamusContralateral hemisensory loss10–20Cerebral white matter (lobar)Depends on location (weakness, numbness, partial loss of visual field)10–15PonsHemiparesis; may be devastating10CerebellumLethargy or coma due to brain stem compression and/or hydrocephalus1–6Brain stem (excluding pons)Often devastatingFigure 42-16. A. Head computed tomography scan of a patient with left-sided weakness and progressive lethargy reveals a right basal ganglia hemorrhage (arrowhead). The blood clot is bright white. Hypodensity around the clot represents cerebral edema. There is blood within the ventricular system. B. Another patient with intraventricular extension of a basal ganglia hemorrhage. The patient developed right-sided weak-ness and then lethargy. Head computed tomography indicated hydrocephalus. A ventriculostomy was placed for cerebrospinal fluid drainage (arrowhead indicates cross-sectional view of the catheter entering the anterior horn of the right lateral ventricle).mass effect. However, the most comprehensive randomized clinical trials to date did not show an overall improved outcome in surgically evacuated intracranial hemorrhage, except for the subgroup of patients with clot <1 cm from the cortical surface.61 More recent studies have assessed the role of minimally-invasive catheter evacuation of clot; these investigations are ongoing.62 Medical management remains the gold standard, however, and includes moderate blood pressure control, normalizing platelet and clotting function, phenytoin or levetiracetam for seizure prophylaxis, and electrolyte management. Intubate patients who cannot clearly follow commands to prevent aspiration and hypercarbia. Follow and document the neurologic examination and communicate with the family regarding appropriateness for rehabilitation vs. withdrawal of care.Amyloid Angiopathy. The presence of pathologic amyloid deposition in the media of small cortical vessels compromises vessel integrity and tends to cause more superficial (lobar) hemorrhages than hypertensive intracranial hemorrhage. Amy-loid laden vessels may hemorrhage multiple times. The super-ficial location of amyloid hemorrhages may make surgical evacuation less morbid compared to typical deep hypertensive hemorrhages. Nonetheless, medical management and family counseling should be approached similarly to patients with hypertensive hemorrhages.Brunicardi_Ch42_p1827-p1878.indd 185101/03/19 7:16 PM 1852SPECIFIC CONSIDERATIONSPART IITable 42-5The Hunt-Hess clinical grading system for subarachnoid hemorrhageHUNT-HESS GRADECLINICAL PRESENTATION0Asymptomatic; unruptured aneurysm1Awake; asymptomatic or mild headache; mild nuchal rigidity2Awake; moderate to severe headache, cranial nerve palsy (e.g., cranial nerve III or IV), nuchal rigidity3Lethargic; mild focal neurologic deficit (e.g., pronator drift)4Stuporous; significant neurologic deficit (e.g., hemiplegia)5Comatose; posturingTable 42-4Prevalence of cerebral aneurysm by locationPREVALENCEANEURYSM LOCATION (VERNACULAR NAME)Anterior circulation 85%   30% Anterior communicating artery (A-Comm)25% Posterior communicating artery (P-Comm)20% Middle cerebral artery bifurcation10% OtherPosterior circulation 15% 10% Basilar artery, most frequently at the basilar tip5% Vertebral artery, usually at the posterior inferior cerebellar arteryCerebral Aneurysm. An aneurysm is a focal dilatation of the vessel wall and is most often a balloon-like outpouching, but may also be fusiform. Aneurysms usually occur at branch points of major vessels (e.g., internal carotid artery bifurca-tion), or at the origin of smaller vessels (e.g., posterior com-municating artery or ophthalmic artery). Approximately 85% of aneurysms arise from the anterior circulation (carotid) and 15% from the posterior circulation (vertebrobasilar). Table 42-4 shows the percentage distribution of cerebral aneurysms by location. Aneurysms are thin walled and at risk for rupture. The major cerebral vessels, and therefore aneurysms, lie in the subarachnoid space. Rupture results in SAH. The aneurys-mal tear may be small and seal quickly, or it may not. SAH may consist of a thin layer of blood in the CSF spaces, or thick layers of blood around the brain and extending into brain parenchyma, resulting in a clot with mass effect. Because the meningeal linings of the brain are sensitive with free nerve endings, SAH usually results in a sudden, severe “thunderclap” headache. A patient will classically describe “the worst head-ache of my life.” Presenting neurologic symptoms may range from mild headache to coma to sudden death. The Hunt-Hess grading system categorizes patients clinically (Table 42-5). The World Federation of Neurological Surgery (WFNS) SAH Grading Scale is also used for this purpose. The Fisher Scale and a more recent modified form use head CT characteristics, described in the following section, to stratify patients based on risk of vasospasm-induced delayed cerebral ischemia. Both scales are used in conjunction as a quick way to communicate severity of aneurysmal SAH.Patients with symptoms suspicious for SAH should have a head CT immediately. Acute SAH appears as a bright signal in the fissures and CSF cisterns around the base of the brain, as shown in Fig. 42-17. CT is rapid, noninvasive, and approxi-mately 95% sensitive. In patients with suspicious symptoms but negative head CT, a lumbar puncture (LP) should be per-formed. An LP with xanthochromia and high red blood cell counts (usually 100,000/mL), which do not decrease between tubes 1 and 4, is consistent with SAH. Negative CT and LP essentially rules out SAH. Patients diagnosed with SAH require four-vessel cerebral angiography within 24 hours to assess for aneurysm or other vascular malformation. Cathe-ter angiography remains the gold standard for assessing the patient’s cerebral vasculature, relevant anomalies, and pres-ence, location, and morphology of the cerebral aneurysms. Figure 42-18A demonstrates the typical anteroposterior digital subtraction angiographic view of a cerebral aneurysm. Figure 42-18B shows the anatomy of the circle of Willis in a simplified graphic representation to assist in visualizing the locations of various cerebral aneurysms.SAH patients should be admitted to the neurologic ICU. Hunt-Hess grade 4 and 5 patients require intubation and hemo-dynamic monitoring and stabilization. The current standard of care for ruptured aneurysms requires early aneurysmal occlu-sion. There are two options for occlusion. The patient may undergo craniotomy with microsurgical dissection and place-ment of a titanium clip across the aneurysm neck to exclude the aneurysm from the circulation and reconstitute the lumen of the parent vessel. The second option is to utilize an endovascular approach for treatment, which has traditionally taken the form of “coiling.” The patient is taken to the interventional neuro-radiology suite for placement of looped titanium coils inside the aneurysm dome. The coils support thrombosis and prevent Figure 42-17. Non contrast CT scan on the left shows diffuse subarachnoid blood in the cisterns with some concentration in the region of the anterior cerebral arteries. This is confirmed by the image on the right, a CT angiogram, where the arrow indicates an anterior communicating artery aneurysm.Brunicardi_Ch42_p1827-p1878.indd 185201/03/19 7:16 PM 1853NEUROSURGERYCHAPTER 42Figure 42-18. A. Anteroposterior view after injection of contrast dye in the right internal carotid artery demonstrates an aneurysm of the middle cerebral artery bifurcation. B. Figure depicting the anatomy of the circle of Willis and the common sites for aneu-rysms. ICA = internal cerebral artery; MCA = middle cerebral artery. (Reproduced with permission from Osborn AG: Handbook of Neuroradiology: Brain and Skull. St. Louis, MO: Mosby-Year Book, Inc; 1991.)AIntracranial aneurysumsAnteriorcommunicating artery30% – 35%MCA bifurcation20%Basilar5%Posterior fossaMiscellaneous sites distalto circle of Willis1% – 3%ICA/posteriorcommunicating30% – 35%Bblood flow into the aneurysm. Newer endovascular options include flow diversion and stent-assisted coiling. Factors favor-ing craniotomy and clipping include young age, good medical condition, and broad aneurysm necks. Factors favoring coil-ing include age, medical comorbidities, and narrow aneurysm necks. Due to coil migration or compaction over time, surgical clipping is believed to result in a more definitive cure. The decision to clip or coil is complex and should be fully explored. Practice standards have changed in recent years with the advent of more nuanced endovascular techniques and treatment options, as described earlier. Current guidelines favor endovas-cular therapy as the preferred first-line approach. The Interna-tional Subarachnoid Aneurysm Trial researchers suggested that endovascular occlusion resulted in better mortality outcomes for certain types of cerebral aneurysms, although this trial was marred by poor selection and randomization techniques, and the validity of its conclusions have been questioned.63 Long-term outcomes may be better in younger patients with clipped aneurysms, as demonstrated in the Barrow Ruptured Aneurysm Trial (BRAT).64 However, this trial has a number of similar criticisms as well. Debate also continues regarding optimal care for unruptured intracranial aneurysms, with a recent large-scale study showing no clear benefit to open surgical vs. endovascu-lar approaches.65SAH patients often require 1 to 3 weeks of ICU care after aneurysm occlusion for medical complications that accompany neurologic injury. In addition to routine ICU concerns, SAH patients are also at risk for cerebral vasospasm. In vasospasm, cerebral arteries constrict pathologically and can cause isch-emia or stroke from 4 to 21 days after SAH. Current vasospasm prophylaxis includes maintenance of optimal perfusion with hypertension and mild hypervolemia, as well as administration of nimodipine, a calcium channel blocker that may decrease the incidence and degree of spasm, though its mechanism is debated. Neurointerventional options for treating symptomatic vasospasm include intra-arterial papaverine or nicardipine, and balloon angioplasty for larger caliber vessels.Aneurysmal SAH has an approximate mortality rate of 50% in the first month. Approximately one-third of survivors return to pre-SAH function, and the remaining two-thirds have mild to severe disability. Most require rehabilitation after hospitalization.Arteriovenous Malformations. AVMs are abnormal, dilated arteries and veins without an intervening capillary bed. The nidus of the AVM contains a tangled mass of vessels but no neural tissue. AVMs may be asymptomatic or present with SAH, intra-parenchymal hemorrhage, or seizures. Small AVMs present with hemorrhage more often than large AVMs, which tend to present with seizures. Headache, bruit, or focal neurologic deficits are less common symptoms. AVMs hemorrhage at an average rate of 2% to 4% a year. Figure 42-19 demonstrates the angiographic appearance of an AVM in arterial and venous phases.For unruptured AVMs, recent evidence from over two hundred patients supports medical management alone rather than intervention due to risk of stroke.66 Because AVM rupture can present radiographically as SAH, it is important to consider several management differences as compared to aneurysmal SAH. Definitive therapy for the AVM usually is delayed 3 to 4 weeks to allow the brain to recover from acute injury. There is less risk of devastating early rebleeding from AVMs, and vasospasm is much less common. Three therapeutic modalities for AVMs are currently in common use: microsurgical exci-sion, interventional radiology or endovascular embolization, and stereotactic radiosurgery (SRS). AVMs that are large, near eloquent cortex, or that drain to deep venous structures are con-sidered high grade and more difficult to surgically resect with-out causing a significant neurologic deficit. Radiosurgery can treat these lesions, although it is limited to lesions <3 cm in diameter and has a 2-year lag time (i.e., the AVM may bleed in the interval). Embolization reduces flow through the AVM. It is usually considered adjunctive therapy, but it may serve as the sole treatment for deep, inaccessible lesions.4Brunicardi_Ch42_p1827-p1878.indd 185301/03/19 7:16 PM 1854SPECIFIC CONSIDERATIONSPART IITUMORS OF THE CENTRAL NERVOUS SYSTEMA wide variety of tumors affect the brain and spine. Primary benign and malignant tumors arise from the various elements of the CNS, including neurons, glia, and meninges. Tumors metas-tasize to the CNS from many primary sources. Presenta-tion varies widely depending on relevant neuroanatomy. Prognosis depends on histology and anatomy. Modern brain tumor centers use team approaches to CNS tumors, as patients may require a combination of surgery (including newer, more minimally invasive approaches), radiation therapy, chemother-apy, SRS, and research protocol enrollment for studies assessing the efficacy of newer approaches such as immunotherapy. Tumors affecting the peripheral nervous system are discussed in the “Peripheral Nerve” section.Intracranial TumorsIntracranial tumors can cause brain injury from mass effect, dys-function or destruction of adjacent neural structures, swelling, or abnormal electrical activity (seizures). Supratentorial tumors commonly present with focal neurologic deficit, such as contra-lateral limb weakness, visual field deficit, headache, or seizure. Infratentorial tumors often cause increased ICP due to hydro-cephalus from compression of the fourth ventricle, leading to headache, nausea, vomiting, or diplopia. Cerebellar hemisphere or brain stem dysfunction can result in ataxia, nystagmus, or cranial nerve palsies. Infratentorial tumors rarely cause seizures.All patients with symptoms concerning for brain tumor should undergo MRI with and without gadolinium. Gadolinium-based contrast can identify locations of blood-brain barrier break-down of tumors and, when used in conjunction with other MRI sequences, is essential in narrowing the differential diagnosis. Ini-tial management of a patient with a symptomatic brain tumor gen-erally includes dexamethasone for reduction of vasogenic edema, and phenytoin or levetiracetam if the patient has seized. Patients with significant weakness, lethargy, or hydrocephalus should be admitted for observation until definitive care is administered.Metastatic TumorsCerebral metastases are the most common type of intracranial tumor. Prolonged cancer patient survival and improved CNS imaging have increased the likelihood of diagnosing cerebral metastases. The sources of most cerebral metastases are (in decreasing frequency): lung, breast, kidney, GI tract, and mela-noma. Lung and breast cancers account for more than half of cerebral metastases. Metastatic cells usually travel to the brain hematogenously and frequently seed the gray-white junction due to characteristic blood vessel caliber change. Other com-mon locations are the cerebellum and the meninges. Menin-geal involvement may result in carcinomatous meningitis, also known as leptomeningeal carcinomatosis. MRI preand post-contrast administration is the study of choice for evaluation. Figure 42-20 demonstrates bilateral cerebellar metastases. These lesions are typically well circumscribed, round, and multiple. Such findings should prompt a metastatic work-up, including CT scan of the chest, abdomen, and pelvis, and a bone scan.Management largely depends upon the primary tumor, overall tumor burden, patient’s medical condition, and location and number of metastases. The beliefs of the patient and family regarding aggressive care must be considered, with the primary goal of optimizing survival time while maintaining or improv-ing neurological function. Neurosurgical intervention can be indicated for a number of reasons. Biopsy can be obtained to provide a tissue diagnosis and further direct therapy. Hydro-cephalus from increased intracranial pressure due to intracranial tumor burden can be temporized via placement of a ventricu-loperitoneal shunt. Craniotomy can be used for debulking of intracranial tumor burden or resection. Data from random-ized controlled trials have supported the use of craniotomy for tumor resection plus whole-brain radiation therapy (WBRT) or stereotactic radiosurgery (SRS) for patients with a single surgically accessible metastatic lesion, compared to radiation therapy alone. In one randomized trial assessing surgery and WBRT vs. WBRT alone, local recurrence decreased and median 5ABFigure 42-19. A. Lateral view after injection of contrast dye in the left internal carotid artery demonstrates a 3 × 4 cm left frontal arteriove-nous malformation indicated by arrowheads. This image was taken 1.06 seconds after dye injection, and is referred to as an arterial phase image. B. Same view taken 4.10 seconds after dye injection, providing a venous phase image. The arrow points to the arteriovenous malfor-mation nidus. The arrowheads indicate two pathologically enlarged draining veins. ACA = anterior cerebral artery; ICA = internal carotid artery; MCA = middle cerebral artery.Brunicardi_Ch42_p1827-p1878.indd 185401/03/19 7:16 PM 1855NEUROSURGERYCHAPTER 42survival increased from 15 to 40 weeks.67 For multiple metas-tases, it should be noted that craniotomy primarily for resec-tion is typically not indicated unless all detectable metastases can be resected. It may however still be useful for symptomatic relief from a primary lesion. Recent data suggest that SRS (e.g. Gamma Knife) may be applied to multiple metastases in one session with improved outcome.68Glial TumorsGlial cells provide the anatomic and physiologic support for neurons and their processes in the brain. Tumors arising from glial cells are termed gliomas, and they represent the most com-mon primary brain tumor. The several types of glial cells give rise to distinct primary CNS neoplasms.Astrocytoma. Astrocytoma is the most common primary CNS neoplasm. The term glioma often is used to refer to astrocyto-mas specifically, excluding other glial tumors. Astrocytomas are graded from I to IV. Grades I and II are referred to as low-grade astrocytoma or low grade glioma, grade III as anaplastic astro-cytoma, and grade IV as glioblastoma multiforme (GBM). Prog-nosis varies significantly between grades I/II, III, and IV, but not between I and II. Median survival is 8 years after diagnosis with a low-grade tumor, 2 to 3 years with an anaplastic astrocytoma, and roughly 1 year with a GBM. GBMs account for almost two-thirds of all astrocytomas, anaplastic astrocytomas account for two-thirds of the rest, and low-grade astrocytomas the remainder. Fig. 42-21 demonstrates the typical appearance of a GBM.The great majority of astrocytomas infiltrate adjacent brain. Juvenile pilocytic astrocytomas and pleomorphic xantho-astrocytomas are exceptions. These tumors are circumscribed, low grade, and associated with a good prognosis. Histologic features associated with higher grade include hypercellularity, nuclear atypia, and endovascular hyperplasia. Necrosis is pres-ent only with GBMs; it is required for the diagnosis.Gross total resection should be attempted for suspected astrocytomas. Motor cortex, language centers, deep or midline structures, or brainstem location may make this impossible without unacceptable, devastating neurologic deficit. Advanced imaging, such as diffusion tensor imaging (DTI) and functional MRI (fMRI), are seeing increased use as means of assessing peritumoral structure and function to guide surgical decision-making. However, some lesions may be in such precarious regions as to be limited to stereotactic needle biopsy specimen. Gross total resection followed by fractioned radiotherapy (FRT) improves survival for all grades, although radiation therapy may be delayed until recurrence in low-grade tumors. Alongside FRT, adjuvant chemotherapy with temozolomide was demon-strated in a randomized controlled trial to increase short-term survival rate.69 Bevacizumab, an anti-VEGF antibody, is another treatment option under investigation. There are various ongoing research studies for GBM adjuvant therapy; these should be dis-cussed with the patient and family. Other options include Iotrex-containing balloons for conformal radiation brachytherapy (Glia-Site), placed in the resection cavity at the time of surgery ABFigure 42-20. A. Precontrast T1-weighted axial magnetic resonance imaging demonstrating bilateral hemorrhagic cerebellar metastases. Patient presented with ataxia and then lethargy progressing to deep coma. This patient has total effacement of the fourth ventricle and severe brain stem compression. The fourth ventricle cerebrospinal fluid space should be at the tip of the arrowhead. Patient recovered to normal mental status after emergent posterior fossa craniotomy. B. Postcontrast T1-weighted axial magnetic resonance imaging demonstrating a ring-enhancing lesion in the lateral left temporal lobe with moderate edema. The uncus (U) is compressing the left cerebral peduncle (CP) and displacing the brain stem to the right.Brunicardi_Ch42_p1827-p1878.indd 185501/03/19 7:17 PM 1856SPECIFIC CONSIDERATIONSPART IIfor recurrence. Adjuvant therapy remains marginally effective; survival has changed little over the last several decades.Oligodendroglioma. Oligodendroglioma accounts for approx-imately 10% of gliomas, arising from the oligodendrocytes that create myelin in the CNS. They often present with seizures. Calcifications and hemorrhage on CT or MRI suggest the diag-nosis. Oligodendrogliomas are also graded from I to IV; grade portends prognosis. Prognosis is better overall than for astro-cytomas. Median survival ranges from 2 to 7 years for high-est and lowest grade tumors, respectively. Aggressive resection improves survival. Many oligodendrogliomas will respond to procarbazine, lomustine (CCNU), and vincristine (PCV) che-motherapy. A particular chromosomal deletion, 1p19q, has been associated with robust response to the chemotherapeutic agent temozolomide. Radiation has not been clearly shown to prolong survival.Recent updates to brain tumor classification by the WHO (discussed in the following section) note that high-grade (at least II or III) oligodendrogliomas and astrocytomas are classi-fied together as diffuse gliomas. In fact, more similarity is seen between high-grade astrocytomas and oligodendrolgiomas than between high-grade astrocytomas and low-grade astrocytomas. Further discussion of this nosology is beyond the scope of this chapter, but implications for the future of neuro-oncology are discussed here.Ependymoma. The lining of the ventricular system consists of cuboidal/columnar ependymal cells from which ependy-momas may arise. Although most pediatric ependymomas are supratentorial, two-thirds of adult ependymomas are infratento-rial. Supratentorial ependymomas arise from the lateral or third ventricles. The infratentorial tumors arise from the floor of the fourth ventricle (i.e., off the posterior brainstem). The most com-mon symptoms are headache, nausea, vomiting, or vertigo, sec-ondary to increased ICP from obstruction of CSF flow through the fourth ventricle. The tumors may grow out the foramina of Luschka to form a cerebellopontine angle mass. They may also spread through the CSF to form “drop mets” in the spinal canal. The two main histologic subtypes are papillary and anaplastic, the latter characterized by increased mitotic activity and areas of necrosis. Gross total resection often is impossible because the tumor arises from the brain stem. The goal of surgery is to achieve maximal resection without injuring the very delicate brainstem. Suboccipital craniotomy and midline separation of the cerebellar hemispheres allows access to tumors in the fourth ventricle. Postoperative radiation therapy significantly improves survival. Patients with CSF spread documented by LP or con-trast MRI should also have whole-spine radiation plus focused doses to visualized metastases.Choroid Plexus Papilloma. The choroid plexus is composed of many small vascular tufts covered with cuboidal epithelium. It represents part of the interface between blood and brain. The choroid cells create CSF from blood via ultrafiltration and release it into the ventricular system. Choroid plexus papil-lomas and choroid plexus carcinomas (rare, mostly pediatric) may arise from these cells. Papillomas usually occur in infants (typically supratentorial in the lateral ventricle) but also occur in adults (usually infratentorial in the fourth ventricle). Papillomas ABFigure 42-21. A. Postcontrast T1-weighted axial magnetic resonance imaging demonstrating a ring-enhancing lesion in the anteromedial right temporal lobe with central necrosis (dark area) consistent with glioblastoma multiforme. B. T2-weighted axial magnetic resonance imaging with extensive bright signal signifying peritumoral edema seen with glioblastoma multiformes.Brunicardi_Ch42_p1827-p1878.indd 185601/03/19 7:17 PM 1857NEUROSURGERYCHAPTER 42are well circumscribed and vividly enhance due to extensive vasculature. Like ependymomas, adult choroid plexus papillo-mas usually present with symptoms of increased ICP. Treatment is surgical excision. Total surgical excision is curative; recurrent papillomas should be re-resected. Radiation and chemotherapy are not indicated for papillomas. Radiation is adjunctive to aggressive surgery for carcinomas, but the results are generally poor.Neural Tumors and Mixed TumorsNeural and mixed tumors are a diverse group that includes tumors variously containing normal or abnormal neurons and/or normal or abnormal glial cells. Primitive neuroectodermal tumors arise from bipotential cells, capable of differentiating into neurons or glial cells.Medulloblastoma. Medulloblastoma is classically described as the most common type of primitive neuroectodermal tumor (PNET), although this term has been removed in the latest WHO classification of central nervous system tumors. Most occur in the first decade of life, but there is a second peak around age 30. Medulloblastoma is the most common malignant pediatric brain tumor. They are usually midline. Most occur in the cerebellum and present with symptoms of increased ICP. Histologic char-acteristics include densely packed small round cells with large nuclei and scant cytoplasm. They are generally not encapsulated, frequently disseminate within the CNS, and should undergo sur-gical resection followed by radiation therapy and chemotherapy.Ganglioglioma. Ganglioglioma is a mixed tumor in which both neurons and glial cells are neoplastic. They occur in the first three decades of life, often in the medial temporal lobe, as circumscribed masses that may contain cysts or calcium and may enhance. The presenting symptom is usually a seizure, due to the medial temporal location. Patients have a good prognosis after complete surgical resection.Neural Crest TumorsMultipotent neural crest cells develop into a variety of dispa-rate cell types, including smooth muscle cells, sympathetic and parasympathetic neurons, melanocytes, Schwann cells, and arachnoid cap cells. They migrate in early development from the primitive neural tube throughout the body.Miscellaneous TumorsMeningioma. Meningiomas are derived from arachnoid cap cells of the arachnoid mater. They appear to arise from the dura mater grossly and on MRI and are commonly referred to as dural-based tumors. The most common intracranial locations are along the falx (Fig. 42-22), the convexities (i.e., over the cerebral hemispheres), and the sphenoid wing. Less common locations include the foramen magnum, olfactory groove, and inside the lateral ventricle. Most are slow growing, encapsu-lated, benign tumors. Aggressive atypical or malignant menin-giomas may invade adjacent bone or cerebral cortex. Previous cranial irradiation increases the incidence of meningiomas. Approximately 10% of patients with a meningioma have multiple meningiomas. Total resection is curative, although involvement with small perforating arteries or cranial nerves may make total resection of skull base tumors impossible with-out significant neurologic deficit. The Simpson grading scale is used to characterize the extent of resection. Small, asymptom-atic meningiomas can be followed until symptomatic or until significant growth is documented on serial imaging studies. Atypical and malignant meningiomas may require postoperative radiation. Patients may develop recurrences from the surgical bed or distant de novo tumors.Vestibular Schwannoma (Acoustic Neuroma). Vestibular schwannomas predominantly arise from the superior half of the vestibular portion of the vestibulocochlear nerve (cranial nerve VIII) (Fig. 42-23). Commonly, patients present with progressive hearing loss, tinnitus, or balance difficulty. Large tumors may cause brain stem compression and obstructive hydrocephalus. Bilateral acoustic neuromas are pathognomonic for neurofibro-matosis type 2 (NF2), a syndrome resulting from mutation of chromosome 22. NF2 patients have an increased incidence of spinal and cranial meningiomas and gliomas.Vestibular schwannomas may be treated with microsur-gical resection or SRS (Gamma Knife radiosurgery or linear accelerator technology). The main complication with treatment is damage to the facial nerve (cranial nerve VII), which runs through the internal auditory canal with the vestibulocochlear nerve. Risk of facial nerve dysfunction increases with increasing tumor diameter. SRS is preferred for tumors <3 cm, and micro-surgical resection for those >3 cm (SRS can be supplemented for any residual tumor following resection).Pituitary Adenoma. Pituitary adenomas arise from the anterior pituitary gland (adenohypophysis). Tumors <1 cm diameter are considered microadenomas; larger tumors are macroadenomas. Figure 42-22. Postcontrast T1-weighted coronal magnetic reso-nance imaging demonstrating a brightly enhancing lesion arising from the falx cerebri with moderate edema and mass effect on the right lateral ventricle. This is a falcine meningioma. Note also the small separate meningioma arising from the dura over the cerebral convexity.Brunicardi_Ch42_p1827-p1878.indd 185701/03/19 7:17 PM 1858SPECIFIC CONSIDERATIONSPART IIPituitary tumors may be functional (i.e., secrete endocrinologi-cally active compounds at pathologic levels) or nonfunctional (i.e., secrete nothing or inactive compounds). Functional tumors are often diagnosed when quite small, due to endocrine dysfunc-tion. The most common endocrine syndromes are Cushing’s disease, due to adrenocorticotropic hormone secretion, ForbesAlbright syndrome, due to prolactin secretion, and acromegaly, due to growth hormone secretion. Nonfunctional tumors are typically diagnosed as larger lesions causing mass effects such as visual field deficits due to compression of the optic chiasm or panhypopituita-rism due to compression of the gland. Figure 42-24 demonstrates a large pituitary adenoma. Hemorrhage into a pituitary tumor causes abrupt symptoms of headache, visual disturbance, decreased men-tal status, and endocrine dysfunction. This is known as pituitary apoplexy.Symptomatic pituitary tumors should be decompressed surgically to eliminate mass effect and/or to attempt an endo-crine cure. However, prolactin-secreting tumors (prolactinomas) usually shrink with dopaminergic therapy alone. First-line phar-macotherapy for small prolactinomas is cabergoline, a dopamine agonist that inhibits production and secretion of prolactin, and is preferred over bromocriptine for its superior side effect profile. Consider surgery for prolactinomas with persistent mass effect or endocrinologic dysfunction in spite of adequate dopamine agonist therapy. Most pituitary tumors are approached transna-sally via the transsphenoidal approach, and minimally invasive, endoscopic surgical techniques are being used increasingly.Hemangioblastoma. Hemangioblastomas occur almost exclusively in the posterior fossa, with about 20% occurring in patients with von Hippel-Lindau (VHL) disease, a multisys-tem neoplastic disorder. Other tumors associated with VHL are renal cell carcinoma, pheochromocytoma, and retinal angio-mas. Many appear as cystic tumors with an enhancing tumor on the cyst wall known as the mural nodule. Surgical resection is curative for sporadic (non-VHL associated) tumors. Pathology reveals abundant thin-walled vascular channels; internal debulk-ing may be bloody. En bloc resection of the mural nodule alone, leaving the cyst wall, is sufficient.Lymphoma. CNS lymphoma may arise either primarily in the CNS or secondarily from systemic disease. Recent rising inci-dence may be due to growing transplant and AIDS populations. Presenting symptoms include mental status changes, headache due to increased ICP, and cranial nerve palsy due to lymphoma-tous meningitis (analogous to carcinomatous meningitis). Often, lymphoma appears hyperdense on CT due to dense cellularity. Most lesions typically enhance with contrast on MRI, and can be differentiated by diffusion restriction on diffusion-weighted sequences. Surgical excision is not indicated. A stereotactic needle biopsy specimen usually confirms the diagnosis. Sub-sequent treatment includes steroids, whole-brain radiation, and chemotherapy. Intrathecal methotrexate is an additional treat-ment option.Embryologic TumorsEmbryologic tumors result from embryonal remnants that fail to involute completely or differentiate properly during development.Craniopharyngioma. Craniopharyngiomas are benign cystic lesions that occur in the sellar region that occur most frequently in children. A second peak of incidence also exists around 50 years of age. Craniopharyngiomas arise from remnant embry-onic tissue in the pituitary stalk. Calcification occurs in all pedi-atric and roughly half of adult craniopharyngiomas. Symptoms result from compression of adjacent structures, especially the optic chiasm. Pituitary or hypothalamic dysfunction or hydro-cephalus may develop. Treatment is primarily surgical. Excision ABFigure 42-23. A. Postcontrast T1-weighted axial magnetic resonance imaging demonstrating a brightly enhancing mass on the right ves-tibular nerve with an enhancing tail going into the internal auditory canal (arrowhead). Pathology demonstrated vestibular schwannoma. B. Postcontrast T1-weighted sagittal magnetic resonance imaging of the same lesion, indicated by the arrowhead. Note small incidental meningioma at the top of the scan.Brunicardi_Ch42_p1827-p1878.indd 185801/03/19 7:17 PM 1859NEUROSURGERYCHAPTER 42is somewhat easier in children, as the tumor is often soft and easily suctioned. Adult tumors are often firm and adherent to adjacent vital structures. Visual loss, pituitary endocrine hypo-function, diabetes insipidus, and cognitive impairment from basal frontal injury are common complications.Epidermoid. Epidermoid tumors are cystic lesions with strati-fied squamous epithelial walls from trapped ectodermal cell rests that grow slowly and linearly by desquamation into the cyst cavity. The cysts contain keratin, cholesterol, and cellu-lar debris (Fig. 42-25). They occur most frequently in the cer-ebellopontine angle and may cause symptoms due to brainstem compression. Recurrent bouts of aseptic meningitis may occur due to release of irritative cyst contents into the subarachnoid space (Mollaret’s meningitis). Treatment is surgical drainage and removal of the cyst wall. Intraoperative spillage of cyst contents may lead to severe chemical meningitis and must be avoided by containment and aspiration.Dermoid. Dermoids are less common than epidermoid tumors. They contain hair follicles and sebaceous glands in addition to a squamous epithelium. Dermoids may be found anywhere along the craniospinal axis. They are more commonly midline structures and are associated with more anomalies than epidermoids. They may be associated with trauma, as from a lumbar puncture that drags skin structures into the spine. Bacterial meningitis may occur when dermoids are associated with a dermal sinus tract. Treatment of symptomatic lesions is surgical resection, again with care to control cyst contents.Teratoma. Teratomas are germ cell tumors that arise in the midline, often in the pineal region (the area behind the third ventricle, above the midbrain and cerebellum). They contain elements from all three embryonal layers: ectoderm, meso-derm, and endoderm. Teratomas may contain skin, cartilage, GI glands, and teeth. Teratomas with more primitive features are more malignant, while those with more differentiated tissues are more benign. Surgical excision may be attempted. However, the prognosis for malignant teratomas is very poor.Spinal TumorsApproximately 20% of CNS tumors occur in the spine, and a wide variety of spinal tumors exist. Unlike cranial tumors, the majority of spinal tumors are histologically benign. Under-standing two major spinal concepts—stability and neural com-pression—facilitates an understanding of the effects of spinal tumors. Destruction of bones or ligaments can cause spinal instability, leading to deformities such as compression, kyphosis, subluxation, all of which harbor the potential for subsequent neural compression. Tumor growth in the spinal canal or neu-ral foramina can cause direct compression of the spinal cord or nerve roots and cause pain and loss of function. Classically, the pain is worse at night. Anatomic categorization provides the most logical approach to these tumors. Certain tumors present in characteristic locations. An understanding of the anatomy leads to an understanding of the clinical presentation and possible therapeutic options.Extradural Tumors. Extradural tumors account for approxi-mately 55% of spinal tumors. This category includes tumors Figure 42-24. Postcontrast T1-weighted sagittal magnetic reso-nance imaging demonstrating a large sellar/suprasellar lesion (arrowheads) involving the third ventricle superiorly and abut-ting the midbrain and pons posteriorly. The patient presented with progressive visual field and acuity loss. Pathology and lab work revealed a nonfunctioning pituitary adenoma.Figure 42-25. Postcontrast T1-weighted axial magnetic resonance imaging demonstrating a nonenhancing mass in the left cerebello-pontine angle with brain stem compression. White arrowhead indi-cates interface of tumor and brain stem. Black arrowhead indicates deformed fourth ventricle. Pathology revealed epidermoid tumor.Brunicardi_Ch42_p1827-p1878.indd 185901/03/19 7:17 PM 1860SPECIFIC CONSIDERATIONSPART IIarising within the bony vertebral structures and from within the epidural space. Destruction of the bone can lead to instability and fractures, causing pain and/or deformity. Epidural expan-sion can lead to spinal cord or nerve root compression with myelopathy, radiculopathy, or a combination thereof.Metastatic Tumors Metastatic tumors are the most common extradural tumors. Spinal metastases most commonly occur in the thoracic and lumbar vertebral bodies because the greatest volume of red bone marrow is found in these regions. The most common primary sources of spine metastasis are lymphoma, lung, breast, and prostate. Other sources include renal, colon, thyroid, sarcoma, and melanoma. Most spinal metastases create osteolytic lesions. Osteoblastic, sclerotic lesions suggest pros-tate cancer in men and breast cancer in women.Patients with progressive neurologic dysfunction due to a metastatic lesion should undergo urgent surgery followed by radiation therapy.70 Patients with debilitating pain may undergo radiation therapy with close observation for neurologic deterio-ration. Preoperative neurologic function correlates with postop-erative function. Patients may lose function over hours. These patients should be given high-dose IV dexamethasone, taken immediately to MRI, and then to the OR or radiation therapy suite. Indications for surgery include failure of radiation ther-apy, spinal instability, recurrence after radiation therapy, and the need for diagnosis in cases of unknown primary tumors. Most cases with significant bone involvement require both decom-pression and fusion. Bony fusion usually takes 2 to 3 months. Prognosis governs operative decisions. Surgery is unlikely to improve quality of life for patients with a life expectancy of 3 months or less, but it is likely to improve quality of life for patients with life expectancy of 6 months or more. Benefit for patients with 3to 6-months’ life expectancy is unclear and requires frank discussion with the patient and family. Patients who are unlikely to tolerate general anesthesia, are already completely paralyzed, or who have very radiosensitive tumors such as multiple myeloma and lymphoma, should not generally undergo surgery.Management Principles of Spinal Cord Compression in Metastatic Cancer of the Spine Spinal cord compression due to tumor burden is important to distinguish because it can, as with any other form of cord compression, cause paralysis and loss of bowel and bladder function. A randomized controlled trial demonstrated that patients with spinal cord compression from metastatic tumor have better outcomes with decompres-sive surgery and radiotherapy compared to radiotherapy alone.70 Patients with radiosensitive tumors, such as multiple myeloma and lymphoma, are excluded from this group. Another impor-tant tool in assessing these patients is the SINS (Spinal Instabil-ity Neoplastic Score). This scale grades the utility of operative intervention in metastatic cancer to the spine on the basis of pain, deformity, location, type of bone lesion, integrity of verte-bral body, and posterior element involvement.71Primary Tumors Hemangiomas are benign tumors found in 10% of people at autopsy. They occur in the vertebral bodies of the thoracolumbar spine and are frequently asymptomatic. They are often vascular and may hemorrhage, causing pain or neurologic deficit. Large hemangiomas can destabilize the spine and predispose to fracture. Osteoblastic lesions include osteoid osteoma and osteoblastoma. The latter tends to be larger and more destructive. Aneurysmal bone cysts are nonneoplastic, expansile, lytic lesions containing thin-walled blood cavities that usually occur in the lamina or spinous processes of the cer-vicothoracic spine. They may cause pain or sufficiently weaken the bone to cause a fracture. Cancers arising primarily in the bony spine include Ewing’s sarcoma, osteosarcoma, chondro-sarcoma, and plasmacytoma.Intradural Extramedullary Tumors Intradural extramed-ullary tumors constitute approximately 40% of spinal tumors and arise from the meninges or nerve root elements. They may compress the spinal cord, causing myelopathy, or the nerve roots, causing radiculopathy. The most common intradural extramedullary tumors are typically benign, slow growing, and well circumscribed. Rare benign epidural masses include arach-noid cysts, dermoids, and epidermoids. Rare malignant epidural tumors include metastases and high-grade gliomas, or “drop” metastases from posterior fossa gliomas.Meningioma Meningiomas arise from the arachnoidea mater. They appear to be dural based and enhance on MRI. An enhanc-ing “dural tail” may be seen. They occur most commonly in the thoracic spine (Fig. 42-26) but also arise in the cervical and lumbar regions. Some spinal meningiomas grow into the Figure 42-26. T2-weighted sagittal magnetic resonance imaging of the midthoracic spine demonstrating a well-encapsulated tumor arising from the dura posteriorly and compressing the spinal cord. Arrowhead points to dorsal location of the mass. The patient pre-sented with worsening gait and lower extremity spasticity. Pathol-ogy demonstrated meningioma.Brunicardi_Ch42_p1827-p1878.indd 186001/03/19 7:17 PM 1861NEUROSURGERYCHAPTER 42epidural space. Growth causes cord compression and progres-sive myelopathy with hyperreflexia, spasticity, and gait difficul-ties. Surgical excision is the treatment of choice. The surgeon often finds a clean margin between the tumor, dura, and spinal cord, allowing en bloc resection without damage to the cord.Schwannoma Schwannomas are derived from peripheral nerve sheath Schwann cells. They are benign, encapsulated tumors that rarely undergo malignant degeneration. While two-thirds are entirely intradural, one-sixth are entirely extradural, and one-sixth have a classic “dumbbell” shape from intradural and extra-dural components. Symptoms result from radiculopathy, often presenting as pain or myelopathy. Symptomatic lesions should be surgically resected. The parent nerve root usually can be pre-served. Patients with multiple schwannomas likely have NF2. In these patients, a careful neurologic examination is needed to determine which lesions are symptomatic and require resection.Neurofibroma In contrast to schwannomas, neurofibromas tend to appear more fusiform and to grow within the parent nerve, rather than forming an encapsulated mass branching off the nerve. Neurofibromas are benign but not encapsulated. They present similarly to schwannomas, and the two may be difficult to differentiate on imaging. Salvage of the parent nerve is more challenging with neurofibromas. To improve the likelihood of total resection, thoracic and high cervical nerve roots may be sacrificed with minimal deficit. Patients with multiple neurofi-bromas likely have NF1, also known as von Recklinghausen’s neurofibromatosis. Resection for symptomatic lesions should be offered.Intramedullary Tumors. Intramedullary tumors constitute approximately 5% of spinal tumors. They arise from within the parenchyma of the spinal cord. Common presenting symptoms are local dysesthesia, burning pain, radicular pain, sensory loss, weakness, or sphincter dysfunction. Patients with such symp-toms should undergo MRI of the entire spine with and without enhancement.Ependymoma Ependymomas are the most common intramed-ullary tumors in adults. There are several histologic variants. The myxopapillary type occurs in the conus medullaris or the filum terminale in the lumbar region and has the best progno-sis after resection. The cellular type occurs more frequently in the cervical cord. Many spinal ependymomas have cystic areas and may contain hemorrhage. Surgical removal can improve function. A distinct tumor margin often exists, allowing safer excision. Postoperative radiation therapy after subtotal resection may prolong disease control.Astrocytoma Astrocytomas are the most common intramedul-lary tumors in children, although they also occur in adults. They may occur at all levels, although more often in the cervical cord. The tumor may interfere with the CSF-containing central canal of the spinal cord, leading to a dilated central canal, referred to as syringomyelia (syrinx). Spinal astrocytomas are usually low grade, but complete excision is rarely possible due to the nonencapsulated, infiltrative nature of the tumor. As a result, patients with astrocytomas fare worse overall than patients with ependymomas.Other Tumors. Other types of rare tumors include high-grade astrocytomas, dermoids, epidermoids, teratomas, hemangiomas, hemangioblastomas, and metastases. Patients usually present with pain. Prognosis generally depends on preoperative func-tion and the histologic characteristics of the lesion.Future DirectionsFuture directions in the neurosurgical management of brain tumors are related to improved genetic characterization of brain tumors and technological advances. Regarding the former, the recent update of the World Health Organization classification of central nervous system tumors, alluded to earlier in this chap-ter, emphasizes an integrated classification approach utilizing both histologic and molecular characteristics.72 The addition of the latter feature underscores significant advances in the genet-ics of CNS tumors, which are being translated to treatment. Immunotherapy, for example, is an active area of research in the treatment of GBM. In this approach, immune cells such as T cells and dendritic cells are leveraged to target tumor-specific tissue. These approaches will play an important role as adjuvant therapy to neurosurgical approaches.Recent advances in neurosurgical technology are being used to address previous operative limitations. Intraoperative fluorescein is being studied as a means of marking abnor-mal tissue that appears grossly normal in order to maximize resection and minimize recurrence. Indications for SRS are expanding and provide a noninvasive option that can be used as monotherapy or as supplemental therapy to operative inter-vention. Moreover, new minimally invasive techniques, such as MRI-guided laser interstitial thermal therapy (MRgLITT), are actively being studied for less morbid access to otherwise difficult-to-reach tumors.SPINE: BASIC CONCEPTSThe spine is a complex structure and is subject to an extensive array of pathologic processes, including degeneration, inflam-mation, infection, neoplasia, and trauma. Discussions of spine trauma, tumor, and infection are addressed separately in this chapter in the “Infection—Spine,” “Spinal Tumors,” and “Spine Trauma” sections. General concepts, common patterns of dis-ease, and basic operative interventions are presented here.The spine consists of a series of stacked vertebrae, inter-vening discs, and longitudinal ligaments. The vertebrae consist of the vertebral body anteriorly and the pedicles, articular facets, laminae, and spinous processes posteriorly. The intervertebral discs have two components. The tough, fibrous ring that runs around the outer diameter of the two adjacent vertebral bodies is known as the annulus fibrosus. The spongy material inside the ring of the annulus is known as the nucleus pulposus. The annu-lus and the nucleus provide a cushion between adjacent verte-bral bodies, absorb forces transmitted to the spine, and allow some movement between the vertebral bodies. The ligaments stabilize the spine by limiting the motion of adjacent vertebrae.Stability and neural compression are the two concepts crit-ical to understanding the mechanics and pathologic processes affecting the spine.StabilityThe spinal column is the principal structural component of the axial spine, and it must bear significant loads. The vertebrae increase in size from the top to the bottom of the spine, cor-relating with the increased total loads that the more caudal ele-ments must bear. The cervical spine is the most mobile. Cervical stability depends greatly on the integrity of the ligaments that run from level to level. The thoracic spine is the least mobile, due to the stabilizing effect of the rib cage. The lumbar spine has relatively massive vertebrae, supports heavy loads, and has Brunicardi_Ch42_p1827-p1878.indd 186101/03/19 7:17 PM 1862SPECIFIC CONSIDERATIONSPART IIintermediate mobility. The sacral spine is fused together and has no intrinsic mobility. The load borne by the lumbar spine is transmitted to the sacrum, and then the pelvis through the sacro-iliac joints. The coccyx is the most inferior segment of the spine and has no significant contribution to load bearing or mobility.A stable spine is one that can bear normally experienced forces resulting from body mass, movement, and muscle con-traction, while maintaining normal structure and alignment. An unstable spine will shift or sublux under these forces. The determinants of spinal stability vary throughout the cervical, thoracic, and lumbar portions. In elementary form, stability depends on the structural integrity of the hard, bony elements of the vertebral column, as well as the tensile integrity and security of the supporting ligamentous attachments. Plain X-rays and CT scans are sensitive for detecting bony defects such as frac-tures or subluxation, while MRI better detects disruptions of the soft tissues, including ligaments and intervertebral discs. Specific patterns of abnormalities seen on imaging studies may suggest or diagnose spinal instability.A common form of nontraumatic spinal instability is lum-bar spondylolisthesis, which is typically a forward slippage of a lumbar vertebra relative to the lower vertebra on which it rests. This results from congenital or degenerative disruption of the pars interarticularis, the critical bridge of bone that spans adja-cent facet joints. In the setting of a pars defect, there is no solid bony connection between the adjacent vertebrae. The spine is unstable and anterior listhesis (slippage) may result. Patients typically present with severe low back pain that is exacerbated with movement and load bearing (mechanical low back pain). Radiculopathy in this setting indicates neuroforaminal compres-sion. Figure 42-27 demonstrates an L4 and L5 spondylolisthesis.Neural CompressionBesides providing a stable, central element of the body’s support structure, the spine also protects the spinal cord and nerve roots as they pass through the neural foramina to form the peripheral nervous system. In a healthy spine, the spinal cord and nerve roots are suspended in CSF, free of mechanical compression. Patho-logic processes that can lead to CSF space impingement and neural compression include: hypertrophic degenerative changes in the intervertebral discs and facet joints, expansion of epidural masses such as tumors or abscesses, and subluxation (i.e., slip-page) of adjacent vertebral bodies. Subluxation may be due to trauma that exceeds the spine’s load-bearing capabilities and leads to structural failure, or chronic structural degradation by degenerative disease, infection, or tumor. Subluxation reduces the cross-sectional area of the central canal and the neural foramina (see Fig. 42-10B). Reduced central canal area can lead to myelop-athy. Reduced neural foraminal area can lead to radiculopathy.Myelopathy. Compression of the spinal cord can cause distur-bance of function known as myelopathy. This dysfunction may be secondary to the direct effects of compression, cord isch-emia due to reduced perfusion, or pathologic changes due to repeated cord trauma. These mechanisms lead to demyelination of the corticospinal tracts, which are long descending motor tracts. Corticospinal tract damage leads to upper motor neuron signs and symptoms, including hyperreflexia, spasticity, and weakness. These mechanisms also cause damage to the dorsal columns, which carry ascending proprioception, vibration, and two-point discrimination information. Loss of proprioception makes fine motor tasks and ambulation difficult.Radiculopathy. Compression of the nerve roots causes distur-bance of root function, known as radiculopathy. Characteristic features of radiculopathy include lower motor neuron signs and symptoms (hyporeflexia, atrophy, and weakness) and sensory dis-turbances such as numbness or tingling sensations (paresthesias), burning sensations (dysesthesias), and shooting (radicular) pain. Myelopathy and radiculopathy often present together in diseases that involve the central canal and the neural foramina. This com-bination can lead to lower motor neuron dysfunction at the level of disease, and upper motor neuron dysfunction below that level.Patterns of DiseaseCervical Radiculopathy. The cervical nerve roots exit the central canal above the pedicle of the same-numbered verte-bra and at the level of the higher adjacent intervertebral disc. For example, the C6 nerve root passes above the C6 pedicle at the level of the C5–C6 discs. The cervical nerve roots may be compressed acutely by disc herniation, or chronically by hypertrophic degenerative changes of the discs, facets, and liga-ments. Table 42-6 summarizes the effects of various disc her-niations. Most patients with acute disc herniations will improve without surgery. NSAIDs or cervical traction may help alle-viate symptoms. Patients whose symptoms do not resolve or who have significant weakness should undergo decompressive surgery. The two main options for nerve root decompression are anterior cervical discectomy and fusion (ACDF) and posterior cervical foraminotomy (keyhole foraminotomy). ACDF allows more direct access to and removal of the pathology (anterior to the nerve root). However, the procedure requires fusion because discectomy causes a collapse of the interbody space and instabil-ity will likely occur. Figure 42-28 demonstrates a C6–C7 ACDF with the typical interposed graft and plating system. Keyhole foraminotomy allows for decompression without requiring Figure 42-27. Lateral lumbar spine X-ray demonstrates a 25% anterior slippage of L4 on L5 due to a defect in the L4 pars interar-ticularis. This is called spondylolisthesis.Brunicardi_Ch42_p1827-p1878.indd 186201/03/19 7:17 PM 1863NEUROSURGERYCHAPTER 42Table 42-6Cervical disc herniations and symptoms by levelLEVELFREQUENCY (%)ROOT INJUREDREFLEXWEAKNESSNUMBNESSC4–C52C5—DeltoidShoulderC5–C619C6BicepsBiceps brachiiThumbC6–C769C7TricepsWrist extensors (wrist drop)Second and third digitsC7–T110C8—Hand intrinsicsFourth and fifth digitsAdapted with permission from Greenberg MS. Handbook of Neurosurgery, 7th ed. New York, NY: Thieme; 2010.BAFigure 42-28. A. Anteroposterior cervical spine X-ray showing the position of an anterior cervical plate used for stabilization after C6–C7 discectomy. Patient presented with right triceps weakness and dysesthesias in the right fifth digit. Magnetic resonance imaging revealed a right paracentral C6–C7 herniated disc compressing the exiting C7 nerve root. B. Lateral cervical spine X-ray of the same patient clearly demonstrates the position of the plate and screws. The allograft bone spacer placed in the drilled-out disc space is also apparent.fusion, but it is less effective for removing centrally located canal pathology.Cervical Spondylotic Myelopathy. The term spondylosis refers to diffuse degenerative and hypertrophic changes of the discs, intervertebral joints, and ligaments, which collectively result in spinal stenosis. Spinal cord dysfunction (myelopathy) due to cord compression from cervical spinal degenerative dis-ease is therefore referred to as cervical spondylotic myelopathy (CSM). Classically CSM presents with spasticity and hyper-reflexia due to corticospinal tract dysfunction, upper extremity weakness and atrophy from degeneration of the motor neu-rons in the anterior horns of the spinal gray matter, and loss of lower extremity proprioception due to dorsal column injury. Figure 42-29 demonstrates typical findings. Some patients com-plain of difficulty buttoning shirts, using utensils, and ambulating. Spondylosis is usually diffuse, so the usual treatment for CSM is multilevel (usually C3–C7) cervical laminectomy, although patients with disease localized over one to three levels may be can-didates for anterior decompression and fusion. Fig. 42-30 demon-strates the postoperative appearance of a vertebral corpectomy and fusion for CSM. Thorough cervical laminectomy decompresses the cord posteriorly. Patients often have slow recovery due to the extensive chronic changes in the cervical cord and may benefit from rehabilitation programs. The other disease that classically presents with combined upper and lower motor neuron symp-toms is amyotrophic lateral sclerosis (ALS). Care must be taken Brunicardi_Ch42_p1827-p1878.indd 186301/03/19 7:17 PM 1864SPECIFIC CONSIDERATIONSPART IIto avoid offering cervical laminectomy to a patient with undi-agnosed ALS. Two findings help differentiate CSM from ALS: cranial nerve dysfunction such as dysphagia (not typically caused by cervical spine disease) and sensory disturbance (not found in ALS).Thoracic Disc Herniation. Thoracic disc herniation accounts for <1% of herniated discs. A patient may present with radicular pain or sensorimotor changes in the lower extremities due to cord compression. A posterior approach via midline incision and lami-nectomy should be avoided because of the high incidence of cord injury from manipulation and retraction. Anterior approaches via thoracotomy minimize risk to the cord and allow excellent access to the disc. The radicular arteries running from the aorta to the thoracic cord should be spared, when possible, to avoid ischemia. Alternatively, a posterolateral approach is possible via resection of the rib head and facet joint. Finally, a transpedicular approach may be attempted for lateral disc herniations.73Lumbar Radiculopathy. Lumbar nerve roots exit the thecal sac, pass over the higher adjacent disc space, and exit the canal under the pedicle of the same-numbered vertebra. Therefore, the L5 nerve root passes over the L4–L5 disc space and exits under the L5 pedicle (Fig. 42-31). Lumbar discs may herniate with or without a history of trauma or straining. Normally they cause lancinating (radicular) pain down the leg (Table 42-7). Most acute herniated lumbar discs improve symptomatically without surgery. Surgery is indicated for symptoms persisting more than 6 to 8 weeks, progressive motor deficit (e.g., foot drop), or for patients with incapacitating pain not manage-able with analgesics. A recent randomized control trial (Spine Patients Outcome Research Trial [SPORT])74 did not observe significant differences between patients randomized to undergo surgery vs. conservative management when using an intent-to-treat analysis. Because of the high amount of bi-directional cross-over between the surgery and conservative group, a sub-sequent reanalysis of the data as observational cohort analysis, demonstrated improved functional outcomes in terms of pain and physical function, more so at 3 months than at 2 years.74Discectomy is performed using a midline incision, partial removal of the overlying laminae (hemilaminectomy or lami-notomy), identification of the thecal sac and nerve root, and extraction of disc fragments. Free-floating disc fragments may be found. Often, however, the herniated disc material is still contained within the annulus, requiring incision of the poste-rior longitudinal ligament and curettage of the disc space. After lumbar discectomy, approximately two-thirds of patients will have complete relief of pain, and up to 85% will have significant improvement.Neurogenic Claudication. Neurogenic claudication is char-acterized by low back and leg pain that occurs while walking and is relieved by stopping, leaning forward, or sitting. It is normally caused by degenerative lumbar stenosis causing com-pression of the cauda equina. Neurogenic claudication must be distinguished from vascular claudication, which tends to resolve quickly with cessation of walking. There is typically no need to change position, and the pain follows a stocking distribution rather than a dermatomal distribution. Pallor and coldness of the feet, and normal neurologic examination are also typical, though diabetic patients may present a challenge with microvascular Figure 42-29. T2-weighted sagittal magnetic resonance imaging of the cervical spine showing multilevel degenerative changes caus-ing spinal stenosis that is worst at C5–C6. Note the bright signal within the cord at that level, consistent with myelopathy.Figure 42-30. Lateral cervical spine X-ray status post C5 corpec-tomy for cervical spondylotic myelopathy. This involves removal of the C4–C5 disc, C5 vertebral body, and C5–C6 disc, decom-pressing at two levels. A bone strut is visible bridging C4 to C6. The plate and screws stabilize the segments.Brunicardi_Ch42_p1827-p1878.indd 186401/03/19 7:17 PM 1865NEUROSURGERYCHAPTER 42neuropathy. Patients with neurogenic claudication have a slowly progressive course and may be surgical candidates when their pain interferes with their lifestyle. The usual surgery is an L3 to L5 lumbar laminectomy to decompress the nerve roots. A recent randomized control trial did not observe a significant difference in outcomes between surgical and conservative management of lumbar stenosis at 1 year.75 Thus, surgical management of lum-bar stenosis should be reserved for patients that do not improve with physical therapy.Cauda Equina Syndrome. Cauda equina syndrome is due to compression of the cauda equina and may result from massive disc herniation, EDH, epidural abscess, tumor, or subluxation from trauma. Patients with cauda equina compression often present with urinary retention, saddle anesthesia, or progressing leg weakness. Saddle anesthesia is numbness in the perineum, genitals, buttocks, and upper inner thighs. Patients with sus-pected cauda equina syndrome should undergo immediate MRI of the lumbar spine to evaluate for a surgical lesion. Mass lesions should be removed urgently via laminectomy to preserve sphincter function and ambulation.Spine Fusion SurgeryFusion surgery is often required for patients with spinal instabil-ity resulting from disease, surgical intervention, or both. Fusion procedures lock adjacent vertebrae together. Fusion occurs when the body forms a solid mass of bone incorporating the adjacent vertebrae, eliminating normal intervertebral move-ment. Stabilization and immobilization promote bony fusion. Internal instrumentation and external orthoses are often used to stabilize and immobilize the fused spinal segments.Spinal InstrumentationInternal fixation devices for spinal segmental immobilization have been developed for all levels of the spine. Most spinal instrumentation constructs have two elements. The first element is a device that solidly attaches to the vertebral bodies. Options include wires wrapped around laminae or spi-nous processes, hooks placed under the lamina or around the pedicles, or screws placed in the pedicles or the vertebral bodies. The second element is a device that traverses vertebral seg-ments. Options include rods and plates that lock directly to the wires, hooks, or screws at each vertebral level. Spinal instru-mentation devices are available for anterior and posterior fusion in the cervical, thoracic, and lumbar regions. Most modern spi-nal instrumentation devices are made of titanium to minimize problems with future MRI scanning (Fig. 42-32). All spinal instrumentation constructs will eventually fail by loosening or breaking if bony fusion does not occur.6ABFigure 42-31. A. T2-weighted sagittal magnetic resonance imaging shows an L5–S1 disc herniation causing significant canal compromise and displacement of nerve roots. B. T2-weighted axial magnetic resonance imaging of the same patient shows the large left paracentral disc herniation at L5–S1. Arrowheads delineate the extent of the herniation. The arrow indicates the right S1 nerve root passing through free of compression. The left S1 nerve root is under severe compression and is not seen.Table 42-7Lumbar disc herniations and symptoms by levelLEVELFREQUENCY (%)ROOT INJUREDREFLEXWEAKNESSNUMBNESSL3–L45L4PatellarQuadricepsAnterior thighL4–L545L5—Tibialis anterior (foot drop)Great toeL5–S150S1AchillesGastrocnemiusLateral footAdapted with permission from Greenberg MS. Handbook of Neurosurgery, 7th ed. New York, NY: Thieme; 2010.Brunicardi_Ch42_p1827-p1878.indd 186501/03/19 7:17 PM 1866SPECIFIC CONSIDERATIONSPART IIFigure 42-32. A. Lateral lumbar spine X-ray showing pedicle screws and connecting rods used to stabilize L4 with respect to L5. This instrumentation was placed as part of a fusion operation to stabilize progressive L4–L5 spondylolisthesis with intractable low back pain. B. Anteroposterior lumbar spine X-ray showing L3 to L5 instrumentation with pedicle screws and connecting rods. The patient had previously sustained an L4 burst fracture. Note the sig-nificant loss of height of the L4 body compared to adjacent levels. The small row of staples to the right delineates the incision over the iliac crest used to harvest cancellous bone as a nonstructural osteoinductive autograft fusion designed to induce formation of a solid bone bridge from L3 to L5 (arthrodesis).ArthrodesisArthrodesis refers to the obliteration of motion or instability by incorporating the relevant components into a solid mass of bone. Arthrodesis must occur in any fused segment to have long-term stability. Failure of arthrodesis results in failed fusion, often in the form of a fibrous nonunion. The rates of successful fusion are higher in the cervical spine than the lum-bar spine. Arthrodesis requires ingrowth of new bone formed by the patient’s osteoblasts across the unstable defect. Insert-ing graft material, such as autograft or allograft, into the defect provides a bridge for osteoblasts and promotes fusion. The term autograft refers to the patient’s own bone, often harvested from the iliac crest. Iliac crest bone graft is a source of both cortical and cancellous bone. Cortical bone provides structural support, while cancellous bone provides a matrix for bony ingrowth. The term allograft refers to sterilized bone from human tissue banks. Allografts also may be cortical, cancellous, or both. Allograft lacks the array of osteoinductive endogenous compounds intrinsic to autograft, although supplemental products such as demineralized bone matrix paste can be added to encourage new bone formation. Other techniques for increasing the rates of suc-cessful fusion are being developed, including the integration of osteoinductive bone morphogenetic proteins, known as BMPs, into the fusion constructs.Dynamic stabilization refers to the creation of spinal sta-bility without achieving a bony fusion. The concept applies to both cervical and lumbar motion segments. Artificial lumbar and cervical disc replacement therapies are recent developments in degenerative spine disease that address this concept. How-ever, their use is limited to very select cases. Another motion preservation technique that may hold promise is segmental “soft” stabilization.77 In cases of degenerative spondylolisthe-sis, such systems in the lumbar spine allow for decompressive laminectomy without increasing slippage. In theory, adjacent level facets and discs are spared the stresses of a neighboring bony fusion moment arm.PERIPHERAL NERVECommon pathologic processes that compromise function of the peripheral nervous system include mechanical compression, ischemia, inflammation, and neoplasia.Peripheral Nerve TumorsMost peripheral nerve tumors are benign and grow slowly. Significant pain increases the likelihood that the patient has a malignant tumor. Treatment for peripheral nerve tumors is sur-gical resection to establish diagnosis and evaluate for signs of malignancy. These tumors have various degrees of involvement with the parent nerve. Some can be resected with minimal or no damage to the nerve. Tumors that grow within the nerve often contain functioning fascicles. Total excision of these tumors requires sacrifice of the parent nerve. The choice of subtotal resection, nerve preservation, and observation, vs. total resec-tion with nerve sacrifice depends on tumor histology and the function of the parent nerve.Schwannoma. Schwannomas are the most common peripheral nerve tumors, also referred to as neurilemomas or neurinomas. Most occur in the third decade of life. These benign tumors arise from Schwann cells, which form myelin in peripheral nerves. The most characteristic presentation is a mass lesion with point tenderness and shooting pains on direct palpation. Spontaneous ABBrunicardi_Ch42_p1827-p1878.indd 186601/03/19 7:17 PM 1867NEUROSURGERYCHAPTER 42or continuous pain suggests malignancy. Schwannomas tend to grow slowly and eccentrically on parent nerves. The eccentric location and discrete encapsulated nature of these tumors often allow total resection without significant damage to the parent nerve. Subtotal resection and observation is reasonable for schwannomas entwined in important nerves, as the incidence of malignant transformation is extremely low.Neurofibroma. Neurofibromas arise within the nerve and tend to be fusiform masses, unlike schwannomas, which tend to grow out of the nerve. Neurofibromas often present as a mass that is tender to palpation. They usually lack the shooting pains char-acteristic of schwannomas. Neurofibromas are often difficult to resect completely without sacrifice of the parent nerve. Neuro-fibromas have a higher incidence of malignant transformation; therefore, patients with known residual tumors require close observation. Patients with NF1 often have multiple neurofibro-mas. These patients should be offered resection for symptomatic tumors. Risk of malignant degeneration is up to 10%. Malignant neurofibromas have the histologic characteristics of sarcoma.Malignant Nerve Sheath Tumors. Malignant nerve sheath tumors include solitary sarcomas, degenerated neurofibromas, and neuroepitheliomas. Patients with malignant peripheral nerve tumors typically complain of constant pain, rather than pain only on palpation, and are more likely to have motor and sensory deficits in the distribution of the parent nerve. Treat-ment for these tumors is radical excision. This often requires sacrifice of the parent nerve. Invasion of nearby soft tissues may occur and necessitate wide resection or amputation in an attempt to prevent systemic metastasis.Entrapment NeuropathiesEntrapment neuropathy presents as neurologic dysfunction in nerves passing through a pathologically small, fixed space. Nerve dysfunction may result directly from chronic, repetitive pressure on the nerve, or from ischemic damage due to impaired perfusion.77 Entrapment causing dysfunction of nerve signaling may be associated with numbness, paresthesias, weakness, or muscle atrophy. The two most common sites of entrapment neu-ropathy are the ulnar nerve at the medial aspect of the elbow and the median nerve at the wrist. Usually EMG/NCS demon-strate slowing across the entrapped segment of nerve. Mechani-cal peripheral nerve disorders resulting from trauma (brachial plexus disruption, radial nerve damage from humerus fractures, and common peroneal nerve crush injuries) are discussed in the section “Trauma.”Ulnar Neuropathy. The ulnar nerve has contributions from the C7, C8, and T1 nerve roots, arises from the medial cord of the brachial plexus, and supplies most of the intrinsic hand mus-cles (interossei and third and fourth lumbricals) and sensation to the fourth and fifth digits. It passes posteriorly to the medial epicondyle at the elbow in the condylar groove. This segment is superficial and subject to external compression and repeti-tive minor impacts. Patients with ulnar entrapment at the elbow present with numbness and tingling in the medial palm, as well as the fourth and fifth digits. Motor deficits include weakness and wasting of the intrinsic hand muscles. Treatment for symp-tomatic ulnar entrapment neuropathy is surgical exploration and incision of the fibrous aponeurotic arch that overlies the nerve. A 6-cm curvilinear incision centered between the medial epi-condyle and the olecranon allows exploration of up to 10 cm of nerve and lysis of compressive tissues.Carpal Tunnel Syndrome. The median nerve has contribu-tions from the C5 to T1 nerve roots, arises from the medial and lateral cords of the brachial plexus, and supplies the muscles of wrist and finger flexion and sensation to the palmar aspect of the first, second, and third digits. The median nerve passes through the carpal tunnel in the wrist, lying superficial to the four deep and four superficial flexor tendons. The transverse carpal liga-ment is a tough, fibrous band that forms the roof of the carpal tunnel. The ligament attaches to the pisiform and hamate medi-ally and the trapezium and scaphoid laterally. Patients complain of numbness and tingling in the supplied digits, clumsiness, and worsening with sleep or repetitive wrist movement. Patients may notice wasting of the thenar eminence. Treatment for symptomatic carpal tunnel syndrome unresponsive to splinting, analgesics, and rest is surgical division of the flexor retinacu-lum. This often provides prompt relief of pain symptoms and slow recovery of numbness and strength.Autoimmune and Inflammatory DisordersThese are not surgical diseases, but they merit brief mention as they are included in the differential diagnosis for new-onset weakness. Their characteristic presentations help distinguish them from weakness due to structural lesions.Guillain-Barré Syndrome. Guillain-Barré syndrome is an acute inflammatory demyelinating polyradiculopathy often occurring after viral infection, surgery, inoculations, or myco-plasma infections. Patients classically present with weakness ascending from the legs to the body, arms, and even cranial nerves. Symptoms usually progress over 2 to 4 weeks and then resolve. Care is supportive. Respiratory weakness may require ventilatory support.Myasthenia Gravis. Myasthenia gravis is an autoimmune process in which antibodies form to the acetylcholine recep-tors of muscles, leading to fluctuating weakness. Most patients have either thymic hyperplasia or thymoma. The most common symptoms are diplopia, ptosis, dysarthria, and dysphagia. More severe cases have limb or respiratory involvement. Weakness worsens with repetitive movement. Treatment is with acetylcho-linesterase inhibitors and possible thymectomy.Eaton-Lambert Syndrome. Eaton-Lambert syndrome is an autoimmune process with antibodies to the presynaptic calcium channels. This is a paraneoplastic syndrome most commonly associated with oat cell carcinoma. Patients have weakness of proximal limb muscles that improves with repetitive movement. This diagnosis must prompt oncologic evaluation.INFECTIONCNS infections of interest to neurosurgeons include those that cause focal neurologic deficit due to mass effect, require surgi-cal aspiration or drainage because antibiotic therapy alone is insufficient, cause mechanical instability of the spine, or occur after neurosurgical procedures.CranialOsteomyelitis. The skull is highly vascular and resistant to infections. Osteomyelitis of the skull may develop by contigu-ous spread from pyogenic sinus disease or from contamination by penetrating trauma. Staphylococcus aureus and S epidermidis are the most frequent causative organisms. Patients usually present with redness, swelling, and pain. Contrast head CT aids 7Brunicardi_Ch42_p1827-p1878.indd 186701/03/19 7:17 PM 1868SPECIFIC CONSIDERATIONSPART IIdiagnosis and shows the extent of involved bone, along with associated abscesses or empyema. Osteomyelitis treatment entails surgical debridement of involved bone followed by 2 to 4 months of antibiotics. Craniotomy wound infections are a special concern because performing a craniotomy creates a devascularized free bone flap susceptible to infection and not penetrated by antibiotics. These wounds must be debrided and the bone flaps removed and discarded. Subsequent care involves appropriate antibiotic therapy, observation for signs of recurrent infection off antibiotics, and return to the OR for titanium or methylmethacrylate cranioplasty 6 to 12 months later.Subdural Empyema. Subdural empyema is a rapidly progres-sive pyogenic infection. The subdural space lacks significant barriers to the spread of the infection, such as compartmental-ization or septations. Subdural empyemas usually occur over the cerebral convexities. Potential infectious sources include sinus disease, penetrating trauma, and otitis. Streptococci and staphylococci are the most frequent sources. Presenting symp-toms include fever, headache, neck stiffness, seizures, or focal neurologic deficit. Neurologic deficit results from inflammation of cortical blood vessels, leading to thrombosis and stroke. The most common deficit is contralateral hemiparesis. Patients with suggestive symptoms should undergo rapid contrast CT scan. LP frequently fails to yield the offending organism and risks herniation due to mass effect. Typical treatment is wide hemi-craniectomy, dural opening, and lavage. The pus may be thick or septated, making burr hole drainage or small craniotomy insufficient. Patients then require 1 to 2 months of antibiotics. Subdural empyema has 10% to 20% mortality risk and common chronic sequelae, including development of a seizure disorder and residual hemiparesis. However, many patients do make a good recovery.Brain Abscess. Brain abscess is encapsulated infection within the brain parenchyma. It may spread hematogenously in patients with endocarditis or intracardiac or intrapulmonary right-to-left shunts, by migration from the sinuses or ear, or via direct seed-ing by penetrating trauma. Disorganized cerebritis often pre-cedes formation of the organized, walled-off abscess. Patients may present with nonspecific symptoms such as headache, nau-sea, or lethargy, or with focal neurologic deficit such as hemi-paresis. Alternatively, patients may present in extremis if the abscess ruptures into the ventricular system. Abscesses appear as well-demarcated, ring-enhancing, thin-walled lesions on CT scan and MRI, and often have associated edema and mass effect. Patients require antibiotic therapy after needle aspira-tion or surgical evacuation. Antibiotic therapy without surgical evacuation may be considered for patients with small, multiple, or critically located abscesses. Abscesses that are large, cause mass effect, decreased mental status, or that fail to decrease in size after 1 week of antibiotics, should be evacuated. Nonsurgical management still requires aspiration or biopsy specimen for organism culture and sensitivities. Blood and CSF cultures rarely give definitive diagnosis. Removal of an encapsulated abscess significantly shortens the length of antibiotic therapy required to eliminate all organisms. Common chronic sequelae after suc-cessful treatment include seizures or focal neurologic deficit.SpinePyogenic Vertebral Osteomyelitis. Pyogenic vertebral osteomyelitis is a destructive bacterial infection of the vertebrae, usually of the vertebral body. Vertebral osteomyelitis frequently results from hematogenous spread of distant disease, but may occur as an extension of adjacent disease, such as psoas abscess or perinephric abscess. S aureus and Enterobacter spp. are the most frequent etiologic organisms. Patients usually present with fever and back pain. Diabetics, IV drug abusers, and dialysis patients have increased incidence of vertebral osteomyelitis. Epidural extension may lead to compression of the spinal cord or nerve roots with resultant neurologic deficit. Osteomyelitis presents a lytic picture on imaging and must be distinguished from neoplastic disease. Adjacent intervertebral disc involve-ment occurs frequently with pyogenic osteomyelitis, but rarely with neoplasia. Plain films and CT help assess the extent of bony destruction or deformity such as kyphosis. MRI shows adjacent soft tissue or epidural disease. Most cases can be treated suc-cessfully with antibiotics alone, although the organism must be isolated to steer antibiotic choice. Blood cultures may be positive. Surgical intervention may be required for debridement when antibiotics alone fail, or for stabilization and fusion in the setting of instability and deformity.Tuberculous Vertebral Osteomyelitis. Tuberculous verte-bral osteomyelitis, also known as Pott’s disease, occurs most commonly in underdeveloped countries and in the immuno-compromised. Several features differentiate tuberculous osteo-myelitis from bacterial osteomyelitis. The infection is indolent and symptoms often progress slowly over months. Tuberculosis rarely involves the intervertebral disc. The involved bodies may have sclerotic rather than lytic changes. Multiple nonadjacent vertebrae may be involved. The upper lumbar and lower tho-racic vertebrae are most commonly affected. Diagnosis requires documentation of acid-fast bacilli. Treatment involves long-term antimycobacterial drugs. Patients with spinal instability or neural compression from epidural inflammatory tissue should undergo debridement and fusion as needed.Discitis. Primary infection of the intervertebral disc space, or discitis, is most commonly secondary to postoperative infec-tions. Spontaneous discitis occurs more commonly in children. S aureus and S epidermidis account for most cases. The pri-mary symptom is back pain. Other signs and symptoms include radicular pain, fevers, paraspinal muscle spasm, and localized tenderness to palpation. Many cases will resolve without anti-biotics, which generally are given for positive blood or biopsy specimen cultures or persistent constitutional symptoms. Most patients will have spontaneous fusion across the involved disc and do not need debridement or fusion.Epidural Abscess. Epidural abscesses may arise from or spread to the adjacent bone or disc, so distinguishing between vertebral osteomyelitis or discitis and a spinal epidural abscess may be difficult. The most common presenting signs and symp-toms are back pain, fever, and tenderness to palpation of the spine. The most significant risk of epidural abscess is weakness progressing to paralysis due to spinal cord or nerve root dam-age. Cord and root damage may be due to direct compression or to inflammatory thrombosis resulting in venous infarction. S aureus and Streptococcus spp. are the most common organisms. Methicillin-resistant S aureus now constitutes a significant pro-portion of these infections, as high as 40%.78 The source may be hematogenous spread, local extension, or operative contamina-tion. MRI best demonstrates the epidural space and degree of neural compromise. Patients with spinal epidural abscess and neurologic compromise should undergo surgical debridement for decompression and diagnosis, followed by culture-directed Brunicardi_Ch42_p1827-p1878.indd 186801/03/19 7:17 PM 1869NEUROSURGERYCHAPTER 42antibiotic therapy. Relative contraindications to surgery include prohibitive comorbidities or total lack of neurologic function below the involved level. Patients with no neurologic deficits and an identified organism may be treated with antibiotics alone and very close observation. However, this management strat-egy remains somewhat controversial because these patients can undergo rapid and irreversible neurologic decline. Most epidural abscesses can be accessed via laminectomy without fusion. Col-lections predominantly anterior to the cervical or thoracic cord may require anterior approach and fusion.FUNCTIONAL NEUROSURGERYEpilepsy SurgerySeizures result from uncontrolled neuronal electrical activity. Seizures may result from irritative lesions in the brain, such as tumors or hematomas, or from physiologic or structural abnor-malities. Seizures may involve a part of the brain (focal) or the entire brain (generalized). Focal seizures may be associated with normal consciousness (simple) or decreased conscious-ness (complex). All generalized seizures cause loss of con-sciousness. Focal seizures may secondarily generalize. Patients with multiple unprovoked seizures over time are considered to have epilepsy. The type of epilepsy depends on such factors as type of seizures, electroencephalographic (EEG) findings, associated syndromes, and identifiable etiologies. All patients with unexplained seizures (i.e., no obvious cause such as head trauma or alcohol withdrawal) require thorough neurologic evaluation, including imaging to evaluate for a mass lesion. Antiepileptic drugs (AEDs) form the first line of therapy for epilepsy, initially as monotherapy, then as combination ther-apy. Epilepsy patients who have failed satisfactory trials of sev-eral AED combination regimens may be candidates for surgical intervention. Lack of seizure control or patient intolerance of the medications may constitute failure. Epilepsy surgery can decrease the frequency of seizures by resection of the electrical source of the seizures, or decrease the severity of seizures by disconnecting white matter tracts through which the abnormal electrical activity spreads. Four types of epilepsy surgery are discussed in sections that follow. Epilepsy surgery appears to be extremely underused, given the relatively low risk of the procedures, and the crippling social and economic effects of uncontrolled or partially controlled epilepsy.79 Patients with symptoms, imaging abnormalities, and EEG analysis compat-ible with a specific seizure focus are most likely to have good results from epilepsy surgery.Anterior Temporal Lobectomy. Medial temporal lobe struc-tural abnormalities can lead to complex partial seizures (CPS). Many patients with CPS have poor seizure control on medi-cations. Patients with CPS may have significant reduction in seizure frequency or cessation of seizures after resection of the anterior temporal lobe. The amygdala and the head of the hip-pocampus are removed as part of the lobectomy. Resection may be taken back approximately 4.5 cm from the temporal tip in the language-dominant hemisphere, and 6 cm from the temporal tip in the language nondominant hemisphere, with low risk of significant neurologic deficits.80 The two main risks of anterior temporal lobectomy are memory impairment and visual loss. Removal of the hippocampus in a patient with an atrophied or nonfunctional contralateral hippocampus causes a global mem-ory deficit. Interruption of the optic radiations, which carry visual signals from the contralateral superior visual quadrants of both eyes, causes a contralateral superior quadrantanopia, known as a pie in the sky field cut.Corpus Callosotomy. Patients with generalized seizures, atonic seizures associated with drop attacks, or absence sei-zures, who are found to have bilaterally coordinated patho-logic cortical discharges on EEG and who fail AED therapy, may be candidates for corpus callosotomy. The corpus cal-losum is a large white matter tract that connects the cerebral hemispheres. Loss of consciousness requires simultaneous seizure activity in both hemispheres. Focal or partial seizures may spread via the corpus callosum to the contralateral hemi-sphere, causing generalization and loss of consciousness. Divi-sion of the corpus callosum can interrupt this spread. Patients may have decreased numbers of seizures and/or fewer epi-sodes of lost consciousness. Usually only the anterior half or two-thirds of the corpus callosum is divided, as more extensive division increases the risk of disconnection syndrome. Patients with disconnection syndrome are unable to match objects in the opposite visual hemifields, to identify objects held in one hand with the other hemifield, and to write with the left hand or name objects held in the left hand (in left hemisphere–dominant patients).Hemispherectomy. Children with intractable epilepsy, struc-tural anomalies in one hemisphere, and contralateral hemiple-gia, may have improved seizure control after resection of the hemisphere (anatomic hemispherectomy) or disruption of all connections to the hemisphere (functional hemispherectomy). Functional hemispherectomy often is preferred over anatomic hemispherectomy because of the high incidence of complica-tions such as hematoma formation and ventriculoperitoneal shunt dependence associated with the latter.Vagus Nerve Stimulation. Neuromodulatory treatments like vagus nerve stimulation (VNS), approved by the U.S. Food and Drug Administration (FDA) in 1997, are less invasive and offer some titratability in addition to reversibility unlike the resec-tive surgical options previously described. Since first reported in 1985, VNS has proven to be efficacious in certain patient populations for several disorders such as treatment-resistant major depressive disorder, bipolar disorder, and epilepsy. In VNS, a pulse generator is placed under the skin in the chest and is connected to the vagus nerve by an electrical lead. Chronic, intermittent VNS has been proven to be an effective option for patients suffering from medically refractory seizures who are not candidates for surgical resection. Although only a small minority of patients will be entirely seizure-free, three blinded, randomized-controlled trials have examined VNS and demon-strated significant clinical improvement compared to sham.81-83 Generally VNS is well-tolerated and safe, as device implantation is associated with a low rate of perioperative complications. Addi-tionally, the majority of side effects are stimulation-dependent and thus, reversible. For the most part, VNS is limited in its appli-cation because it can only exert its effects by altering neural activ-ity via the vagus nerve. Procedures with brain region-specificity are being investigated.Deep Brain StimulationThe following summary of deep brain stimulation (DBS) will include a review of the current FDA-approved indications, as well the expanding applications of this therapy, currently being investigated preclinically and in clinical trials. While the Brunicardi_Ch42_p1827-p1878.indd 186901/03/19 7:17 PM 1870SPECIFIC CONSIDERATIONSPART IImechanism of action of DBS continues to elude our understand-ing, it is well established that administering electrical stimula-tion to a nucleus in the brain known to be involved in a given disease can disrupt the pathologic signals emanating to or from this brain region. A fine electrical lead is placed in a deep brain nucleus and connected to pulse generators placed in the chest in a manner similar to cardiac pacemakers. Connector wires travel from the generators in the subcutaneous space up the neck and in the subgaleal space in the head, to connect the pulse gen-erators to the electrical leads. Proper lead placement is accom-plished with stereotactic guidance. A frame is rigidly fixed to the patient’s head, and an MRI is obtained with the frame in place. Calculation of the coordinates of the millimeter-sized deep brain nuclei is performed in relation to the three-dimensional space defined by the fixed frame, allowing for accurate targeting of the nucleus (Fig. 42-33). Postoperatively, the pulse generators can be interrogated and adjusted with hand-held, transcutane-ous, noninvasive devices as needed for symptom control.Essential Tremor. Essential tremor is the most common movement disorder in the western world and is characterized by action tremor (4–8 Hz rhythmic oscillations) of the hands, forearms, head, and voice. Essential tremor often starts in the third or fourth decade of life and increases in frequency and amplitude with age. β-Blockers can decrease symptoms, but patients with poor medical control and significant functional impairment significantly benefit from placement of a deep brain stimulator in the contralateral ventralis intermediate nucleus of the thalamus. In properly selected patients, DBS of this region of the thalamus appears to provide robust and durable symptom control.84,85Parkinson’s Disease. Parkinson’s disease is a progressive dis-order characterized by rigidity, bradykinesia, and resting tremor, due to loss of dopamine-secreting neurons in the substantia nigra. Dopaminergic agents such as levodopa/carbidopa and anticholinergic agents such as amantadine and selegiline form the basis of medical therapy. Patients with poor medical control or significant drug side effects may benefit significantly from placement of bilateral deep brain stimulators in the subthalamic nuclei. Although the globus pallidus interna has also been a widely targeted area, the subthalamic nuclei is now the most accepted target in deep brain stimulation for Parkinson’s disease.86 Deep brain stimulation provides durable symp-tom relief with good postoperative neuropsychologic function in properly selected patients.87Recently, a large randomized controlled trial compared bilat-eral DBS (n = 121) to best medical therapy in advanced Parkin-son’s disease (n = 134).88 The DBS group did significantly better in both motor function and quality of life. While adverse events were 3.8 times more likely in the DBS group, 99% of these events had resolved by 6 months. There was a 0.8% risk of death due to the procedure, and there was no difference in risk of adverse events when comparing older (≥70 years) to younger patients (<70 years). Thus, the benefits of DBS over medical therapy are clear, especially when considering quality of life measures.Another recent randomized controlled trial focused on defining the optimal targets for DBS in Parkinson’s disease.89 While the subthalamic nucleus (STN) and the globus pallidus interna (GPi) have been successfully targeted in the past, a direct comparison of the two was lacking. In this study, 299 subjects were randomized to receive either bilateral STN or GPi stimula-tors and were evaluated for 2 years. The primary outcome was motor function, as assessed by part III of the Unified Parkin-son’s Disease Rating Scale (UPDRS). The study found no sig-nificant difference in motor improvement between target sites. However, a significant difference was found in a secondary outcome measuring depression. On the Beck Depression Inven-tory, the pallidal stimulation group improved slightly compared with the STN group, which actually worsened slightly. Never-theless, the actual incidence of depressive episodes requiring prolonged or new hospitalization was 2.6% and 0.7% in GPi and STN, respectively, which was not significantly different. On the other hand, the STN group was found to require less adjunctive dopaminergic pharmacotherapy than the GPi group. In terms of overall severe adverse events, there was no difference between groups. The investigators concluded that both target sites are effective and that nonmotor factors such as psychiatric symp-toms may be a consideration in DBS target selection.Dystonia. The FDA humanitarian device exemption has been made for DBS for dystonia but is limited to patients ≥7 years of age with primary dystonia, including generalized and/or seg-mental dystonia, hemidystonia, or cervical dystonia (torticollis). Dystonia is characterized by sustained muscle contractions that cause repetitive movements and involuntary postures. Cognitive function is typically spared, and pharmacological therapy is fre-quently inadequate. The positive impact of DBS on Parkinson’s and essential tremor has led neurologists and neurosurgeons to direct their attention to DBS for treatment of idiopathic focal and generalized dystonia.Although the pathophysiology of idiopathic dystonia is unclear, positron emission tomography studies have shown disturbed glucose metabolism in the GPi, suggesting secondary pathologic activation of the motor cortex. Indeed, the GPi is cur-rently considered the most efficacious target for dystonia, and controlled trials indicate approximately a 50% improvement in motor function and disability.90 Since many patients undergoing 8Figure 42-33. Fast spin echo coronal magnetic resonance imaging demonstrating position of deep brain stimulator leads in the subtha-lamic nuclei bilaterally. The electrodes appear thick and wavy due to magnetic susceptibility artifact.Brunicardi_Ch42_p1827-p1878.indd 187001/03/19 7:17 PM 1871NEUROSURGERYCHAPTER 42surgery for dystonia are children and young adults, DBS is an attractive surgical option because it can be titrated, revised, and reversed according to individual needs and growth patterns.Obsessive-Compulsive Disorder. The safety and efficacy of DBS, as well as its titratability and reversibility, that have been demonstrated for the treatment of movement disorders in the 1990s and 2000s has spawned an increasing interest and awareness of the capabilities of nonlesional surgical treatments for diseases of the brain. An obvious outgrowth of DBS for movement disorders has been the treatment of medically refrac-tory psychiatric disorders. Despite the dark history of frontal leucotomy procedures that dominated the early 20th century, nonlesional DBS for psychiatric disorders are now considered potential treatment strategies.Functional neuroimaging has implicated certain brain regions in the pathogenesis of a variety of psychiatric disorders. The FDA has approved a humanitarian device exemption for DBS targeting the ventral capsule/ventral striatum for severe obsessive-compulsive disorder (OCD). Recent case reports and pilot studies have reported remission in patients suffering from refractory OCD following DBS. A pilot study using a blinded, staggered-onset design found that four (66.7%) of six patients met a stringent criterion as “responders” (≥35% improvement), according to the Yale-Brown Obsessive Compulsive Scale after 12 months of stimulation.91 In this study, patients did not improve during the sham phase. Adverse events were generally mild and modifiable with setting changes, and stimulation inter-ruption led to rapid yet reversible development of depressive symptoms in two cases. Thus, DBS has promise as a therapy of last resort for carefully selected cases of severe OCD.Expanding Indications of Deep Brain Stimulation. There are multiple disorders, both psychiatric and neurologic, that have exhibited significant promise as potential indications for DBS in large-scale trials. Recently, there have been reports of significant improvements in refractory depression with DBS. Lozano and colleagues performed an open label study with extended follow-up on 20 patients targeting an area within the subcallosal cin-gulate gyrus (SCG) with bilateral DBS.92 At the last follow-up visit in this study (range: 3–6 years), the average response rate was 64%, according to the Hamilton Rating Scale for Depres-sion. Of note, impairment in social functioning was improved, and no significant adverse events were reported. Because two patients died by suicide during depressive relapses, it remains unclear if DBS can only improve quality of life or significantly suppress relapses and extend life-span in this extremely delicate patient population. Of note, as seen in OCD, the ventral capsule/ventral striatum has also been targeted for depression, as well as the nucleus accumbens directly, which lies within the ventral striatum. Studies of DBS in this region report an approximate 40% to 60% response rate, and results from a recent, multicenter randomized controlled trial are pending.93DBS as a potential therapy for epilepsy targeting the ante-rior nucleus of the thalamus has been investigated in a multi-center, double-blind, randomized trial (SANTE).94 In this trial, the group receiving DBS showed a 29% greater reduction in seizure frequency in relation to the sham group in the last month of the blinded phase. Complex partial and the “most severe” seizures were significantly reduced in the cohort who had the stimulator on DBS-on group. After the blinded phase of the trial was complete, 54% of patients had a seizure reduction of at least 50%. Fourteen patients were seizure-free for at least 6 months; eight were seizure-free for at least one year, four for at least two years, and one patient for more than four years. Because of the modest benefit during the blinded phase of this trial, FDA-approval has yet to be granted to DBS for epilepsy targeting the thalamus in the United States, though approval has been given in Europe and Canada.The region-specific, neuromodulatory capabilities of DBS have inspired the open label use of this technique in many other neurologic and psychiatric disorders, including but not limited to Tourette syndrome, Huntington’s disease, and Alzheimer dis-ease. Preclinical studies of both substance abuse and obesity have also shown promise.95,96 The opportunity to model reward-seeking behaviors associated with these disorders in animals provides the ability to not only test safety but also study mecha-nisms and inform the design of future clinical trials.Trigeminal NeuralgiaTrigeminal neuralgia, also known as tic douloureux, is charac-terized by repetitive, unilateral, sharp, and lancinating pains in the distribution of, typically, the second, but sometimes third, branch of cranial nerve V, the trigeminal nerve. The patient may describe a “trigger point,” an area on the face that elicits the pain when touched. A current leading etiologic hypothesis for trigeminal neuralgia is irritation and pulsatile compression of the root entry zone of the nerve by an artery in the posterior fossa, usually a loop of the superior cerebellar artery. The pain is excruciating and can be debilitating. Medical therapy, including carbamazepine and amitriptyline, may reduce the frequency of events. Options for medically refractory cases include percuta-neous injection of glycerol into the path of the nerve, periph-eral transection of the nerve branches, SRS, and microvascular decompression (MVD).MVD involves performing a small posterior fossa crani-otomy on the side of the symptoms, retraction of the cerebellar hemisphere, and exploration of cranial nerve V. If an artery is found near the nerve, the vessel is freed of any adhesions and nonabsorbable material is placed between the nerve root and the artery. MVD remains the first definitive management option because SRS is associated with a substantial incidence of facial numbness.97,98STEREOTACTIC RADIOSURGERYThe term stereotactic radiosurgery (SRS) refers to techniques that allow delivery of high-dose radiation that conforms to the shape of the target and has rapid isodose fall-off, minimiz-ing damage to adjacent neural structures. The two most common devices used for conformal SRS for intracranial lesions are the LINAC (linear accelerator) and the gamma knife. LINAC delivers a focused beam of x-ray radiation from a port that arcs part way around the patient’s head. Linear accelerators are commonly used to provide fractionated radiation for lesions outside the CNS. They are found in most radiation oncology departments. After upgrades to the software and collimators, SRS can be performed with these existing units. The gamma knife delivers 201 focused beams of gamma radiation from cobalt sources through a specially designed colander-like helmet. Gamma knife units are used only for intracranial disease and cost up to $5 million; thus, they are most appropriate in high patient–volume centers. There is ongoing debate in the literature 9Brunicardi_Ch42_p1827-p1878.indd 187101/03/19 7:17 PM 1872SPECIFIC CONSIDERATIONSPART IIregarding the two technologies.99-101 Both continue to evolve, allowing more precise and complex isodose conformation to complex lesions. Most lesions can be treated equally well with either technology. Lesions abutting the medulla or the spinal cord should not be treated with SRS because these structures do not tolerate the radiation dose delivered to structures within mil-limeters of the target. Also, medullary or spinal cord compres-sion can result from swelling of the lesion after the radiosurgery dose, resulting in devastating neurologic deficit.Proton beam is an evolving SRS technology that may play a specialized role in treatment of lesions where posttarget exit-ing radiation limits photon-based therapies.102 For example, the physical properties of photons cause destruction upon entry and exit from tissue, which can be particularly harmful to skull-base or clival lesions such as chordoma, in which the exiting pathway travels through the brain stem. Proton beam therapy uses accel-erated protons, which dissipate energy upon impact and do not cause additional exiting damage. Currently, there are very few centers using this technology.CyberKnife is another radiosurgery system that has neu-rosurgical application. It is a frameless, robotic, LINAC-based system that allows for targeting of spinal neoplasms with higher resolution than conventional external beam radiotherapy.103 Using imaging tracking in real time, the CyberKnife is able to adjust to breathing artifact and patient movement. The applica-tion of this technology is rapidly growing.Arteriovenous MalformationsSRS has been found to be an effective stand-alone therapy for AVMs up to 3 cm in diameter. SRS is best for lesions that are dif-ficult to access surgically due to high likelihood of postoperative neurologic deficit. However, SRS is not effective for lesions >3 cm. Effective obliteration and elimination of the risk of hemorrhage takes 2 to 3 years. Overall, there is an approximately 2% annual incidence of AVM hemorrhage,104 although one study found a 50% decrease in hemorrhage rate during the latency period before angiographic obliteration.105 Nonetheless, surgical excision remains the preferred therapeutic modality, while SRS is reserved for cases deemed very high risk for surgery due to location or patient factors.106 Some patients with large AVMs who undergo surgery will have unresectable residual lesions. In these patients, SRS may be used as an effective adjunctive therapy.Vestibular SchwannomasSRS has been introduced as a therapeutic alternative to micro-surgical resection for vestibular schwannomas up to 2.5 cm in maximum diameter. SRS provides high rates of tumor growth arrest and possible reduction in size with low rates of facial nerve palsy. Patients with functional ipsilateral preprocedure hearing may be more likely to retain functional hearing postpro-cedure than with microsurgery. The limitations of SRS include inability to treat tumors >2.5 cm, the possibility of radiation-induced malignant transformation of these benign tumors, and lack of long-term follow-up. SRS centers are accumulating experience with these tumors and accumulating data on long-term results.107,108 The indications for microsurgery and SRS will continue to evolve. Either approach should be undertaken at a high-volume center, as studies show the patient outcomes improve with increased surgeon experience.109Intracranial MetastasesPatients with solitary or multiple intracranial metastases may be treated primarily with SRS.110 Patients have improved survival after SRS compared to no treatment or WBRT, and similar sur-vival to patients undergoing total surgical resection. Patients with lesions >3 cm in diameter or evidence of ICH should undergo surgical decompression rather than SRS. Some studies show improved survival with up to seven intracranial masses. Patients with multiple intracranial masses have almost zero long-term survival, and most will die of their intracranial dis-ease. Patients with intracranial metastases live 3 to 6 months on average with medical care and WBRT. This can be extended to 9 to 16 months with SRS or surgery, depending on tumor type, age, and patient condition.111CONGENITAL AND DEVELOPMENTAL ANOMALIESDysraphismDysraphism describes defects of fusion of the neural tube involving the neural tube itself, or overlying bone or skin. Dys-raphism may occur in the spine or head. Neural tube defects are among the most common congenital abnormalities. Prenatal vitamins, especially folic acid, reduce the incidence of neural tube defects.Spina Bifida OccultaSpina bifida occulta is congenital absence of posterior vertebral elements. The spinous process is always missing, the laminae may be missing to various degrees, but the underlying neural tissues are not involved. Spina bifida occulta is found in 25% of the general population, and it is asymptomatic unless associated with other developmental abnormalities.Spina Bifida With MyelomeningoceleSpina bifida with myelomeningocele describes the congenital absence of posterior vertebral elements with protrusion of the meninges through the defect, with underlying neural structural abnormalities. Common findings include weakness and atrophy of the lower extremities, gait disturbance, urinary incontinence, constipation, and deformities of the foot. Myelomeningoceles arising from the high lumbar cord usually cause total paraly-sis and incontinence, while those arising from the sacral cord may have only clawing of the foot and partial urinary function loss. Myelomeningocele patients often have hydrocephalus and a Chiari II malformation, an abnormal downward herniation of the cerebellum and brain stem through the foramen magnum. Patients with abnormal protrusion of meninges through the bony defect without abnormalities of the underlying neural tissue have a meningocele. Most of these patients are neurologically normal.EncephaloceleHerniation of brain encased in meninges through the skull that forms an intracranial mass is referred to as encephalocele. Herniation of meninges without brain tissue is referred to as a meningocele. Most occur over the convexity of the skull. More rarely, the tissue protrudes through the skull base into the sinuses. Treatment involves excision of the herniated tissue and closure of the defect. Most patients with encephaloceles and meningoceles have impaired cognitive development. Patients with greater amounts of herniated neural tissue tend to have more severe cognitive deficits.CraniosynostosisCraniosynostosis is the abnormal early fusion of a cranial suture line with resultant restriction of skull growth in the affected area Brunicardi_Ch42_p1827-p1878.indd 187201/03/19 7:17 PM 1873NEUROSURGERYCHAPTER 42Figure 42-34. A. Axial head computed tomography scan revealing dilated ventricular system. Note dilated atria of the lateral ventricles (arrowheads) and rounded third ventricle (arrow). The large size of the ventricles and lack of transependymal flow indicate a chronic process (contrast to Fig. 42-2). The patient had normal-pressure hydrocephalus and had improved ambulation after placement of a ventriculoperitoneal shunt. B. Higher cut from same scan showing ventricular catheter in place in the frontal horn of the right lateral ventricle.ABand compensatory bulging at the other sutures. Skull growth occurs at the cranial sutures for the first 2 years of life, at the end of which the skull has achieved >90% of its eventual adult size. Fusion of the sagittal suture, or sagittal synostosis, results in a boat-shaped head, known as scaphocephaly. Unilateral coronal synostosis results in ipsilateral forehead flattening and outward deviation of the orbit, known as plagiocephaly. The contralat-eral normal forehead appears to bulge by comparison. Bilat-eral coronal synostosis results in a broad, flattened forehead, known as brachycephaly, and is often associated with maxil-lary hypoplasia and proptosis. Unilateral or bilateral lambdoid synostosis results in flattening of the occiput. Occipital flat-tening can result from abnormal suture fusion (synostosis), or from physical remolding of the skull caused by always placing the baby in the supine position for sleep (known as positional plagiocephaly). Placing the baby in the prone position or tilted onto the contralateral side may restore near-normal skull shape in most cases of lambdoid synostosis, avoiding surgery. Treat-ment for synostoses in general is surgical, involving resection of the fused suture, or more complex reconstructive techniques for severe or refractory cases.HydrocephalusExcess CSF in the brain that results in enlarged ventricles is known as hydrocephalus. CSF flows from the ventricles to the subarachnoid space and is then absorbed into the venous blood through the arachnoid granulations. Hydrocephalus may be classified as communicating or obstructive (outlined in the next two sections), and congenital or acquired. Congenital lesions associated with or causing hydrocephalus include stenosis of the cerebral aqueduct, Chiari malformation, myelomeningo-cele, and intrauterine infection. Acquired hydrocephalus may result from occlusion of arachnoid granulations by meningitis, germinal matrix hemorrhage, or SAH. CSF pathways may be occluded by adjacent tumors (Fig. 42-34).Communicating Hydrocephalus. Obstruction at the level of the arachnoid granulations constitutes communicating hydro-cephalus. This usually causes dilation of the lateral, third, and fourth ventricles equally. The most common causes in adults are meningitis and SAH. Hydrocephalus may be transient after SAH, with reestablishment of normal CSF absorption after the protein content of the CSF returns to normal and the granula-tions reopen.Obstructive Hydrocephalus. Obstruction of CSF pathways is known as obstructive hydrocephalus. Ventricles proximal to the obstruction dilate, while those distal to the obstruction remain normal in size. Typical patterns include dilation of the lateral ventricles due to a colloid cyst occluding the foramen of Monro, dilation of the lateral and third ventricles due to a tectal (midbrain) glioma or pineal region tumor occluding the cerebral aqueduct, or dilation of the lateral and third ventricles with obliteration of the fourth ventricle by an intraventricular tumor of the fourth ventricle. Obstructive hydrocephalus may present precipitously and require urgent shunting to prevent herniation.Chiari I MalformationChiari I malformation is the caudal displacement of the cer-ebellar tonsils below the foramen magnum. It may be seen as an incidental finding on MRI scans in asymptomatic patients. Symptomatic patients usually present with headache, neck pain, or symptoms of myelopathy, including numbness or weakness in the extremities. A syrinx may be associated, but the brain stem and lower cranial nerves are normal in Chiari I malfor-mations. Chiari II malformations are more severe and involve caudal displacement of the lower brain stem and stretching of the lower cranial nerves. Symptomatic patients may be treated with suboccipital craniectomy to remove the posterior arch of the foramen magnum, along with removal of the posterior ring Brunicardi_Ch42_p1827-p1878.indd 187301/03/19 7:17 PM 1874SPECIFIC CONSIDERATIONSPART IIFigure 42-35. T1-weighted sagittal magnetic resonance imaging of a patient with a Chiari I malformation. The large arrowhead points to the cerebellar tonsils. The small arrowhead points to the posterior arch of the foramen magnum.of C1. Removal of these bony structures relieves the compres-sion of the cerebellar tonsils and cervicomedullary junction, and may allow reestablishment of normal CSF flow patterns. Figure 42-35 demonstrates typical MRI appearance of a Chiari I malformation.REFERENCESEntries highlighted in bright blue are key references. 1. Kandel E, Schwartz J, Jessell T. Principles of Neural Science, 4th ed. New York: McGraw-Hill Professional; 2000. 2. Schellinger PD, Bryan RN, Caplan LR, et al. Evidence-based guideline: The role of diffusion and perfusion MRI for the diagnosis of acute ischemic stroke. Report of the Therapeutics and Technology Assessment Subcommittee of the American Academy of Neurology. Neurology. 2010;75(2):177-185. 3. Wintermark M, Flanders AE, Velthuis B, et al. Perfusion-CT assessment of infarct core and penumbra. Stroke. 2006;37(4):979-985. 4. Takasawa M, Jones PS, Guadagno JV, et al. How reliable is perfusion MR in acute stroke? Stroke. 2008;39(3):870-877. 5. Masters SJ, McClean PM, Arcarese JS, et al. Skull x-ray examinations after head trauma. Recommendations by a multidisciplinary panel and validation study. N Engl J Med. 1987;316:84-91. 6. Bullock MR, Chesnut R, Ghajar J, et al. Surgical man-agement of depressed cranial fractures. Neurosurgery. 2006;58:S56-S60. 7. Dula DJ, Fales W. The ‘ring sign’: is it a reliable indicator for cerebral spinal fluid? Annals of emergency medicine. 1993 Apr 1; 22(4):718-20. 8. Sonig A, Thakur JD, Chittiboina P, Khan IS, Nanda, A. Is posttraumatic cerebrospinal fluid fistula a predictor of post-traumatic meningitis? A US Nationwide Inpatient Sample database study. Neurosurgical Focus. 2012;32(6):E4. 9. Ratilal BO, Costa J, Sampaio C, Pappamikail L. Antibiotic pro-phylaxis for preventing meningitis in patients with basilar skull fractures. Cochrane Database Syst Rev. 2015;(4):CD004884. 10. Carney N, Totten AM, OMReilly C, et al. Guidelines for the management of severe traumatic brain injury. Neuro-surgery. 2017;80(1):6-15. 11. Brain Trauma Foundation, American Association of Neuro-logical Surgeons, Congress of Neurological Surgeons. Guide-lines for the management of severe traumatic brain injury. J Neurotrauma. 2007;24:S91-S95. 12. Ingebrigtsen T, Romner B. Routine early CT-scan is cost sav-ing after minor head injury. Acta Neurologica Scandinavica. 1996;93:207-210. 13. Stein SC, Ross SE. The value of computed tomographic scans in patients with low-risk head injuries. Neurosurgery. 1990;26:638-640. 14. Kelly JP, Nichols JS, Filley CM, et al. Concussion in sports. Guidelines for the prevention of catastrophic outcome. JAMA. 1991;266:2867-2869. 15. McCrory P, Meeuwisse WH, Aubry M, et al. Consensus state-ment on concussion in sport: the 4th International Conference on Concussion in Sport held in Zurich, November 2012. Br J Sports Med. 2013;47(5):250-258. 16. Forgione MA, Moores, LE, Wortmann GW; Prevention of Combat-Related Infections Guidelines Panel. Prevention of infections associated with combat-related central nervous system injuries. J Trauma Acute Care Surg. 2011;71(2): S258-S263. 17. Bullock MR, Chesnut R, Ghajar J, et al. Surgical man-agement of acute subdural hematomas. Neurosurgery. 2006;58:S16-S24. 18. Howard MA III, Gross AS, Dacey RG Jr, et al. Acute subdural hematomas: an age-dependent clinical entity (see comment). J Neurosurg. 1989;71:858-863. 19. Hamilton MG, Frizzell JB, Tranmer BI. Chronic subdural hematoma: the role for craniotomy reevaluated. Neurosurgery. 1993;33:67-72. 20. Almenawer SA, Farrokhyar F, Hong C, et al. Chronic subdural hematoma management: a systematic review and meta-analysis of 34829 patients. Ann Surg. 2014;259(3):449-457. 21. Lega BC, Danish SF, Malhotra NR, Sonnad SS, Stein SC. Choosing the best operation for chronic subdural hema-toma: a decision analysis: clinical article. J Neurosurg. 2010;113(3):615-621. 22. Bullock MR, Chesnut R, Ghajar J, et al. Surgical manage-ment of traumatic parenchymal lesions. Neurosurgery. 2006;58:S25-S46. 23. Dandy WE. Pneumocephalus (intracranial penumatocele or aerocele). Arch Surg. 1926;12(5):949-982. 24. Schirmer CM, Heilman CB, Bhardwaj A. Pneumocepha-lus: case illustrations and review. Neurocrit Care. 2010; 13(1):152-158. 25. Ishiwata Y, Fujitsu K, Sekino T, et al. Subdural tension pneu-mocephalus following surgery for chronic subdural hema-toma. J Neurosurg. 1988;68(1):58-61. 26. Gore PA, Maan H, Chang S, Pitt AM, Spetzler RF, Nakaji P. Normobaric oxygen therapy strategies in the treatment of post-craniotomy pneumocephalus. 2008;108(5):926-929. 27. Temkin NR, Dikmen SS, Wilensky AJ, et al. A random-ized, double-blind study of phenytoin for the prevention of post-traumatic seizures. N Engl J Med. 1990;323:497-502. 28. Edwards P, Arango M, Balica L, et al. Final results of MRC CRASH, a randomised placebo-controlled trial of intrave-nous corticosteroid in adults with head injury-outcomes at 6 months. Lancet. 2005;365(9475):1957-1959. 29. Chesnut RM, Marshall LF, Klauber MR, et al. The role of sec-ondary brain injury in determining outcome from severe head injury. J Trauma. 1993;34(2):216-222. 30. Berry C, Ley EJ, Bukur M, et al. Redefining hypotension in traumatic brain injury. Injury. 2012;43(11):1833-1837.Brunicardi_Ch42_p1827-p1878.indd 187401/03/19 7:17 PM 1875NEUROSURGERYCHAPTER 42 31. Spaite DW, Hu C. Bobrow BJ, et al. Mortality and prehos-pital blood pressure in patients with major traumatic brain injury: implications for the hypotension threshold. JAMA Surg. 2017;152(4):360-368. 32. Basali A, Mascha EJ, Kalfas I, Schubert A. Relation between perioperative hypertension and intracranial hemorrhage after craniotomy. J Am Soc Anesthesiol. 2000;93(1):48-54. 33. Kuramatsu JB, Gerner ST, Schellinger PD, Glahn J, Endres M, Sobesky J, Flechsenhar J, Neugebauer H, Jüttler E, Grau A, Palm F. Anticoagulant reversal, blood pressure levels, and anti-coagulant resumption in patients with anticoagulation-related intracerebral hemorrhage. Jama. 2015 Feb 24;313(8):824-36. 34. Sorrentino E, Diedler J, Kasprowicz M, et al. Critical thresh-olds for cerebrovascular reactivity after traumatic brain injury. Neurocrit Care. 2012;16(2):258-266. 35. Cooper DJ, Rosenfeld JV, Murray L, et al. Decompressive craniectomy in diffuse traumatic brain injury. N Engl J Med. 2011;364(16):1493-1502. 36. Hutchinson PJ, Kolias AG, Timofeev IS, et al. Trial of decompressive craniectomy for traumatic intracranial hypertension. N Engl J Med. 2016;375(12):1119-1130. 37. Lyrer P, Engelter S. Antithrombotic drugs for carotid artery dissection. Stroke. 2004;35:613-614. 38. Maynard FM Jr, Bracken MB, Creasey G, et al. International standards for neurological and functional classification of spi-nal cord injury. American Spinal Injury Association. Spinal Cord. 1997;35:266. 39. Denis F. The three column spine and its significance in the classification of acute thoracolumbar spinal injuries. Spine. 1983;8:817-831. 40. Biffl WL, Cothren CC, Moore EE, et al. Western Trauma Association critical decisions in trauma: screening for and treatment of blunt cerebrovascular injuries. J Trauma Acute Care Surg. 2009;67(6):1150-1153. 41. Lockwood MM, Smith GA, Tanenbaum J, Lubelski D, Seicean A, Pace J, Benzel EC, Mroz TE, Steinmetz MP. Screening via CT angiogram after traumatic cervical spine fractures: nar-rowing imaging to improve cost effectiveness. Experience of a Level I trauma center. Journal of Neurosurgery: Spine. 2016 Mar;24(3):490-5. 42. Bracken MB, Shepard MJ, Collins WF, et al. A randomized, controlled trial of methylprednisolone or naloxone in the treatment of acute spinal-cord injury. Results of the second national acute spinal cord injury study (see comment). N Engl J Med. 1990;322:1405-1411. 43. Bracken MB, Shepard MJ, Collins WF Jr, et al. Methyl-prednisolone or naloxone treatment after acute spinal cord injury: 1-year follow-up data. Results of the second national acute spinal cord injury study (see comment). J Neurosurg. 1992;76:23-31. 44. Bracken MB, Shepard MJ, Holford TR, et al. Admin-istration of methylprednisolone for 24 or 48 hours or tirilazad mesylate for 48 hours in the treatment of acute spinal cord injury: results of the Third National Acute Spinal Cord Injury Randomized Controlled Trial. JAMA. 1997;277(20):1597-1604. 45. Bracken MB. Steroids for acute spinal cord injury. Cochrane Database Syst Rev. 2012;(1):CD001046. 46. Walters BC, Hadley MN, Hurlbert RJ, et al. Guidelines for the management of acute cervical spine and spinal cord injuries: 2013 update. Neurosurgery. 2013;60:82-91. 47. Fehlings M. Recommendations regarding the use of methyl-prednisolone in acute spinal cord injury: making sense out of the controversy [editorial]. Spine J. 2001;26(suppl):S56-S57. 48. Hugenholtz H, Cass DE, Dvorak MF, et al. High-dose meth-ylprednisolone for acute closed spinal cord injuryord injuryyy Injury Random Can J Neurol Sci. 2002;29:227-235. 49. Resnick DK, Kaiser MG, Fehlings M, et al. Hypothermia and Human Spinal Cord Injury: Position Statement and Evidence Based Recommendations From the AANS/CNS Joint Section on Disorders of the Spine and the AANS/CNS Joint Section on Trauma. Washington: AANS/CNS Joint Section of Disorders of the Spine and Peripheral Nerves; 2007. 50. Vaccaro AR, Falatyn SP, Flanders AE, Balderston RA, Northrup BE, Cotler JM. Magnetic resonance evaluation of the intervertebral disc, spinal ligaments, and spinal cord before and after closed traction reduction of cervical spine disloca-tions. Spine. 1999;24(12):1210-1217. 51. Fehlings MG, Vaccaro A, Wilson JR, et al. Early versus delayed decompression for traumatic cervical spinal cord injury: results of the Surgical Timing in Acute Spinal Cord Injury Study (STASCIS). PloS One. 2012;7(2):e32037. 52. Seddon HJ. Three types of nerve injury. Brain. 1943;66:237. 53. North American Symptomatic Carotid Endarterectomy Trial Collaborators. Beneficial effect of carotid endarterectomy in symptomatic patients with high-grade carotid stenosis. (see comment). N Engl J Med. 1991;325:443-445. 54. Ferguson GG, Eliasziw M, Barr HW, et al. The North Amer-ican Symptomatic Carotid Endarterectomy Trial : surgical results in 1415 patients. Stroke. 1999;30(9):1751-1758. 55. Brott TG, Howard G, Roubin GS, et al; CREST Investigators. Long-term results of stenting versus endarterectomy for carotid-artery stenosis. N Engl J Med. 2016;374(11):1021-1031. 56. The National Institute of Neurological Disorders and Stroke rt-PA Stroke Study Group. Tissue plasminogen activator for acute ischemic stroke. (see comment). N Engl J Med. 1995;333:1581-1588. 57. Bhatia R, Hill MD, Shobha N, et al. Low rates of acute recana-lization with intravenous recombinant tissue plasminogen acti-vator in ischemic stroke: real-world experience and a call for action. Stroke. 2010;41(10):2254-2258. 58. Jovin TG, Chamorro A, Cobo E, et al; REVASCAT Trial Inves-tigators. Thrombectomy within 8 hours after symptom onset in ischemic stroke. N Engl J Med. 2015;372(24):2296-2306. 59. J0. J24 E, Unterberg A, Woitzik J, et al. Hemicraniectomy in older patients with extensive middle-cerebral-artery stroke. N Engl J Med. 2014;370(12):1091-1100. 60. Pledl HW, Hoyer C, Rausch J, et al. Decompressive hemi-craniectomy in malignant middle cerebral artery infarction: the ‘real world’ beyond studies. Eur Neurol. 2016;76(1-2): 48-56. 61. Mendelow AD, Gregson BA, Fernandes HM, et al. Early surgery versus initial conservative treatment in patients with spontaneous supratentorial intracerebral haematomas in the International Surgical Trial in Intracerebral Haemorrhage (STICH): a randomised trial. Lancet. 2005;365:387-397. 62. Fam MD, Hanley D, Stadnik A, et al. Surgical performance in minimally invasive surgery plus recombinant tissue plasmino-gen activator for intracerebral hemorrhage evacuation phase III clinical trial. Neurosurgery. 2017;81(5):860-866. 63. Molyneux A, Kerr R, Stratton I, et al. International sub-arachnoid aneurysm trial (ISAT) of neurosurgical clipping versus endovascular coiling in 2143 patients with ruptured intracranial aneurysms: a randomised trial (see comment) (reprint in J Stroke Cerebrovasc Dis 11:304, 2002). Lancet. 2002;360:1267-1274. 64. Mitchell P, Kerr R, Mendelow AD, et al. Could late rebleeding overturn the superiority of cranial aneurysm coil embolization over clip ligation seen in the international subarachnoid aneu-rysm trial? J Neurosurg. 2008;108:437-442. 65. Raftopoulos C, Goffette P, Vaz G, et al. Surgical clipping may lead to better results than coil embolization: results from a series of 101 consecutive unruptured intracranial aneurysms. Neurosurgery. 2003;52:1280-1287, discussion 1287-1290.Brunicardi_Ch42_p1827-p1878.indd 187501/03/19 7:17 PM 1876SPECIFIC CONSIDERATIONSPART II 66. Mohr JP, Parides MK, Stapf C; International ARUBA Inves-tigators. Medical management with or without interventional therapy for unruptured brain arteriovenous malformations (ARUBA): a multicentre, non-blinded, randomised trial. Lancet. 2014;383(9917):614-621. 67. Patchell RA, Tibbs PA, Walsh JW, et al. A randomized trial of surgery in the treatment of single metastases to the brain. N Engl J Med. 1990;322:494-500. 68. Aoyama H, Shirato H, Tago M, et al. Stereotactic radiosurgery plus whole-brain radiation therapy vs stereotactic radiosurgery alone for treatment of brain metastases: a randomized con-trolled trial. JAMA. 2006;295:2483-2491. 69. Stupp R, Mason WP, van den Bent MJ; European Organisa-tion for Research and Treatment of Cancer Brain Tumor and Radiotherapy Groups; National Cancer Institute of Canada Clinical Trials Group. Radiotherapy plus concomitant and adjuvant temozolomide for glioblastoma. N Engl J Med. 2005;352(10):987-996. 70. Patchell RA, Tibbs PA, Regine WF, et al. Direct decompres-sive surgical resection in the treatment of spinal cord compres-sion caused by metastatic cancer: a randomised trial. Lancet. 2005;366:643-648. 71. Fisher CG, DiPaola CP, Ryken TC, et al. A novel classifi-cation system for spinal instability in neoplastic disease: an evidence-based approach and expert consensus from the Spine Oncology Study Group. Spine (Phila Pa 1976). 2010;35(22): E1221-E1229. 72. Louis DN, Perry A, Reifenberger G, et al. The 2016 World Health Organization Classification of Tumors of the Central Nervous System: a summary. Acta Neuropathol. 2016;131(6):803-820. 73. Le Roux PD, Haglund MM, Harris AB. Thoracic disc disease: experience with the transpedicular approach in twenty con-secutive patients. Neurosurgery. 1993;33:58-66. 74. Weinstein JN, Lurie JD, Tosteson TD, et al. Surgical vs nonop-erative treatment for lumbar disk herniation: the Spine Patient Outcomes Research Trial (SPORT) observational cohort. JAMA. 2006;296(20):2451-2459. 75. Delitto A, Piva SR, Moore CG, Fritz JM, Wisniewski SR, Josbeno DA, Fye M, Welch WC. Surgery versus nonsurgical treatment of lumbar spinal stenosis: a randomized trial. Annals of internal medicine. 2015 Apr 7;162(7):465-73. 76. Mulholland RC, Sengupta DK. Rationale, principles, and experimental evaluation of the concept of soft stabilization. Eur Spine J. 2002;11:S198-S205. 77. Dawson D, Hallett M, Wilbourn A. Entrapment Neuropathie. 3rd ed. Baltimore: Lippincott Raven; 1999. 78. Darouiche RO. Spinal epidural abscess. N Engl J Med. 2006;355:2012-2020. 79. Benbadis SR, Heriaud L, Tatum WO, et al. Epilepsy surgery, delays and referral patterns patients controlled? Seizure. 2003;12:167-170. 80. Rausch R, Kraemer S, Pietras CJ, et al. Early and late cogni-tive changes following temporal lobe surgery for epilepsy (see comment). Neurology. 2003;60:951-959. 81. Ben-Menachem E, Manon-Espaillat R, Ristanovic R, et al. Vagus nerve stimulation for treatment of partial seizures. A controlled study of effect on seizures. First International Vagus Nerve Stimulation Study Group. Epilepsia. 1994;35:616-626. 82. Handforth A, DeGiorgio CM, Schachter SC, et al. Vagus nerve stimulation therapy for partial-onset seizures: a randomized active-control trial. Neurology. 1998;51:48-55. 83. Amar AP, Heck CN, Levy ML, et al. An institutional experi-ence with cervical vagus nerve trunk stimulation for medically refractory epilepsy: rationale, technique, and outcome. Neuro-surgery. 1998;1265-1276. 84. Fields JA, Troster AI, Woods SP, et al: Neuropsychologi-cal and quality of life outcomes 12 months after unilateral thalamic stimulation for essential tremor. J Neurol Neurosurg Psychiatry. 2003;74:305-311. 85. Rehncrona S, Johnels B, Widner H, et al. Long-term efficacy of thalamic deep brain stimulation for tremor: double-blind assessments. Mov Disord. 2003;18:163-170. 86. Kleiner-Fisman G, Herzog J, Fisman DN, et al. Subthalamic nucleus deep brain stimulation: summary and meta-analysis of outcomes. Mov Disord. 2006;21:S290-S304. 87. Perozzo P, Rizzone M, Bergamasco B, et al. Deep brain stimulation of the subthalamic nucleus in Parkinsonor: es 12 mocomparison of preand postoperative neuropsychological evaluation. J Neurol Sci. 2001;192:9-15. 88. Weaver FM, Follett K, Stern M, et al. Bilateral deep brain stimulation vs. best medical therapy for patients with advanced Parkinson disease: a randomized controlled trial. JAMA. 2009;301:63-73. 89. Follett KA, Weaver FM, Stern M, et al. Pallidal versus sub-thalamic deep-brain stimulation for ParkinsonWeaver FM, S N Engl J Med. 2010;362(22):2077-2091. 90. Vidailhet M, Vercueil L, Houeto JL, et al. Bilateral deep-brain stimulation of the globus pallidus in primary generalized dys-tonia. N Engl J Med. 2005;352(5):459-467. 91. Goodman WK, Foote KD, Greenberg BD, et al. Deep brain stimulation for intractable obsessive compulsive disorder: pilot study using a blinded, staggered-onset design. Biol Psychiatry. 2010;67:535-542. 92. Lozano AM, Giacobbe P, Hamani C, et al. A multicenter pilot study of subcallosal cingulate area deep brain stimu-lation for treatment-resistant depression. J Neurosurg 2012;116:315-322. 93. Bewernick BH, Kayser S, Sturm V, et al. Long-term effects of nucleus accumbens deep brain stimulation in treatment-resistant depression: evidence for sustained efficacy. Neuro-psychopharmacology 2012;37:1975-1985. 94. Fisher R, Salanova V, Witt T, et al. Electrical stimulation of the anterior nucleus of thalamus for treatment of refractory epilepsy. Epilepsia. 2010;51:899-908. 95. Vassoler FM, Schmidt HD, Gerard ME, et al. Deep brain stimulation of the nucleus accumbens shell attenuates cocaine priming-induced reinstatement of drug seeking in rats. J Neurosci. 2008;28:8735-8739. 96. Halpern CH, Tekriwal A, Santollo J, et al. Amelioration of binge eating by nucleus accumbens shell deep brain stimu-lation in mice involves D2 receptor modulation. J Neurosci. 2013;33(17):7122-7129. 97. Barker FG II, Jannetta PJ, Bissonette DJ, et al. The long-term outcome of microvascular decompression for trigeminal neu-ralgia. N Engl J Med. 1996;334:1077-1083. 98. Kondo A. Microvascular decompression surgery for trigeminal neuralgia. Stereotact Funct Neurosurg. 2001;77:187-189. 99. Bova FJ, Goetsch SJ. Modern linac stereotactic radiosurgery systems have rendered the gamma knife obsolete. Medical Physics. 2001;28:1839-1841. 100. Konigsmaier H, de Pauli-Ferch B, et al. The costs of radio-surgical treatment: comparison between gamma knife and linear accelerator. Acta Neurochirurgica. 1998;140: 1110-1111. 101. Suh JH, Barnett GH, Miller DW, et al. Successful conver-sion from a linear accelerator-based program to a gamma knife radiosurgery program: The Cleveland Clinic experience. Stereot Funct Neurosurg. 1999;72:159-167. 102. Chen CC, Chapman P, Petit J, et al. Proton radiosurgery in neurosurgery. Neurosurg Focus. 2007;23:E5. 103. Gerszten PC, Ozhasoglu C, Burton SA, et al. CyberKnife frameless stereotactic radiosurgery for spinal lesions: clinical experience in 125 cases. Neurosurgery. 2004;55:89-98, discus-sion 98-99.Brunicardi_Ch42_p1827-p1878.indd 187601/03/19 7:17 PM 1877NEUROSURGERYCHAPTER 42 104. Karlsson B, Lax I, Soderman M. Risk for hemorrhage during the 2-year latency period following gamma knife radiosurgery for arteriovenous malformations. Int J Radiat Oncol Biol Phys. 2001;49:1045-1051. 105. Maruyama K, Kawahara N, Shin M, et al. The risk of hemor-rhage after radiosurgery for cerebral arteriovenous malforma-tions. N Engl J Med. 2005;352:146-153. 106. Pan DH, Guo WY, Chung WY, et al. Gamma knife radiosur-gery as a single treatment modality for large cerebral arterio-venous malformations. J Neurosurg. 2000;93:113-119. 107. Regis J, Pellet W, Delsanti C, et al. Functional outcome after gamma knife surgery or microsurgery for vestibular schwan-nomas. J Neurosurg. 2002;97:1091-1100. 108. Shin M, Ueki K, Kurita H, et al. Malignant transformation of a vestibular schwannoma after gamma knife radiosurgery. Lancet. 2002;360:309-310. 109. Elsmore AJ, Mendoza ND. The operative learning curve for vestibular schwannoma excision via the retrosigmoid approach. Br J Neurosurg. 2002;16:448-455. 110. Gerosa M, Nicolato A, Foroni R, et al. Gamma knife radio-surgery for brain metastases: a primary therapeutic option. J Neurosurg. 2002;97:515-524. 111. Pollock BE, Brown PD, Foote RL, et al. Properly selected patients with multiple brain metastases may benefit from aggressive treatment of their intracranial disease. J Neurooncol. 2003;61:73-80.Brunicardi_Ch42_p1827-p1878.indd 187701/03/19 7:17 PM
Brunicardi_Ch42_p1827-p1878.indd 187801/03/19 7:17 PMThis page intentionally left blankOrthopedic SurgeryNabil A. Ebraheim, Bert J. Thomas, Freddie H. Fu, Bart Muller, Dharmesh Vyas, Matt Niesen, Jonathan Pribaz, and Klaus Draenert 43chapterIntroduction 1880Orthopedic Trauma 1881Introduction / 1881Open Fractures / 1881Compartment Syndrome / 1883Treatment of Fractures  and Dislocations 1883Clavicle Fractures / 1883Scapula Fractures / 1883Shoulder Dislocations / 1884Proximal Humerus Fractures / 1884Humeral Shaft Fractures / 1884Distal Humerus Fractures / 1885Elbow Dislocations / 1885Radial Head Fractures / 1886Olecranon Fractures / 1886Forearm Fractures / 1886Distal Radius Fractures / 1886Scaphoid Fractures / 1887Pelvic Fractures / 1887Acetabular Fractures / 1888Hip Dislocations / 1888Hip Fractures / 1888Femoral Shaft Fractures / 1890Distal Femur Fractures / 1890Knee Dislocations / 1890Patella/Extensor Mechanism Injuries / 1891Tibial Plateau Fractures / 1891Tibial Shaft Fractures / 1891Tibial Plafond (Pilon) Fractures / 1892Ankle and Subtalar Dislocations / 1892Ankle Fractures / 1893Maisonneuve Fractures / 1893Calcaneal Fractures / 1893Talus Fractures / 1894Foot Fractures / 1894Sports Medicine 1895Introduction / 1895Shoulder 1895Rotator Cuff / 1895Shoulder Instability / 1896Posterior Dislocation of the Shoulder / 1896Superior Labrum and Biceps Tendon / 1896Impingement Syndromes / 1896The Acromioclavicular Joint / 1897Knee 1897Menisci / 1897Collateral Ligaments / 1898Cruciate Ligaments / 1898Posterolateral Corner / 1899Hip 1899Femoroacetabular Impingement / 1899Spine 1900Spinal Trauma / 1900Occipital Cervical Dislocation / 1900Fractures of C1 (Jefferson Fracture) / 1900Fractures of C2 (Odontoid Fracture) / 1900Hangman’s Fractures of C2 / 1901Compression Fracture of the Cervical Spine / 1901Burst Fractures of the Cervical Spine / 1901Unilateral and Bilateral Facet Dislocation / 1901Clay-Shoveler’s Injury / 1902Fractures of the Thoracic and  Lumbar Spine 1902Thoracic Lumbar Spine Injury / 1902Compression Fracture / 1902Burst Fracture / 1902Seatbelt Injuries (Flexion Distraction Injuries) / 1902Fracture Dislocations of the Spine / 1903Disc Herniation / 1903Cauda Equina Syndrome / 1903Spinal Stenosis / 1903Back Pain and Degenerative Disc Disease / 1904Scoliosis / 1904Idiopathic Scoliosis / 1904Neuromuscular Scoliosis / 1904Joint Reconstruction 1904Introduction to Arthritis / 1904Examination of the Patient / 1904Nonoperative Management and Prevention of Arthritis / 1905Injections / 1905Surgical Management of Arthritis / 1906Computer Navigation, Robotics, and Joint Arthroplasty / 1908Fixation Options in Joint Arthroplasty / 1910Complications in Joint Arthroplasty / 1910Orthopedic Pathology and  Oncology 1910Diagnosis of Malignant Bone Tumors / 1910Osteosarcoma 1911Intramedullary Osteosarcoma / 1911Parosteal Osteosarcoma / 1912Periosteal Osteosarcoma / 1912Paget’s Sarcoma / 1912Radiation-Induced Sarcoma / 1912Ewing’s Sarcoma 1912Cartilage-Forming Tumors 1912Chondrosarcomas / 1912Fibrous Lesions of Bone 1912Desmoplastic Fibroma / 1912Malignant Fibrous Histiocytoma of Bone / 1913Malignant Vascular Tumors / 1913Miscellaneous Tumors 1913Giant Cell Tumor of Bone / 1913Adamantinoma and Osteofibrous Dysplasia / 1913Primary Lymphoma of Bone / 1914Chordoma / 1914Multiple Myeloma / 1914Metastatic Bone Tumors 1914Pediatric Orthopedics 1915Birth Injuries / 1915Skeletal Growth / 1915Pediatric Fractures / 1916Classification of Growth Plate Injuries / 1916Diaphyseal Injuries in a Pediatric Patient / 1916Fractures of the Pediatric Hip / 1916Fractures of the Femoral Shaft / 1916Pediatric Ankle Fractures / 1917Pediatric Elbow Fractures / 1917Brunicardi_Ch43_p1879-p1924.indd 187922/02/19 10:40 AM 1880Key Points1 The main principle of internal fixation for fracture care (most commonly intramedullary nails or plate and screw fixation) is to create a stable construct that will allow the fracture to heal in proper length, alignment, and rotation.2 In open fractures, early administration of intravenous antibiotics is important to avoid infection. An external fixator is used when the wound is grossly contaminated, and definitive treatment of the wound is delayed until the wound is sufficiently clean. Early wound coverage is important.3 Early diagnosis and treatment of compartment syndrome is important in order to prevent irreversible damage to the muscles and the nerves, which is time sensitive. Emergency fasciotomy by releasing the tight fascia is a limb-saving procedure.4 Fractures of the scapula are typically the result of a high-energy trauma with a high incidence of associated injuries that typically involve the ribs and the lungs.5 The shoulder is one of the most commonly dislocated joints, and most dislocations are anterior. Posterior dislo-cations may be missed and are typically associated with seizures or electric shock. Anterior-posterior and axillary views of the shoulder are necessary for the diagnosis.6 Isolated humeral shaft fractures are usually treated conser-vatively. The radial nerve spirals around the humeral shaft and is at risk for injury; therefore, a careful neurovascular exam is important. The patient should be checked for wrist drop.7 Hemorrhage from pelvic trauma can be life-threatening. An important first line of treatment in the emergency department is resuscitation of the patient with fluids, including blood, and the application of a pelvic binder or sheet that is wrapped tightly around the pelvis to control bleeding.8 In spinal injury, spinal stability must be assessed, and the patient should be immobilized until there is further under-standing of the injury. A computed tomography scan is more reliable in assessing spine injury than plain radiographs.9 Spinal cord injuries can be complete or incomplete, and every attempt should be made to avoid further injury. Patients should be triaged to trauma centers since trauma center care is associated with reduced paralysis and improved outcome.10 According to the Centers for Disease Control and Prevention and the National Health Interview Survey, approximately 55 million adults have been diagnosed with some form of arthritis. This number is projected to grow substantially in the future.11 A combination of nonsteroidal anti-inflammatory medica-tions, physiotherapy, and weight loss with the help of a dietary consultation, and physical therapy are typically the first line of treatment for knee osteoarthritis. Weight loss of as little as 11 lbs (5 kg) has been shown to decrease the risk of developing knee osteoarthritis in women by 50%.12 Minimally invasive surgical techniques improve cosmesis and allow for early rehabilitation. However, they may be associated with decreased visualization intraoperatively, associated risks of component malposition, intraoperative fracture, and nerve or vascular injury.Developmental Disease 1917Developmental Dysplasia of the Hip / 1917Treatment of DDH / 1918Legg-Calvé-Perthes Disease / 1918Slipped Capital Femoral Epiphysis / 1918Lower Extremity Rotational Abnormalities / 1918Congenital Talipes Equinovarus (Clubfoot) / 1918Osgood-Schlatter Disease / 1918INTRODUCTIONEvery physician should be familiar with orthopedics and ortho-pedic surgery. Anyone who cares for patients in an outpatient or emergency room setting will find that the majority of presenting complaints involve the musculoskeletal system. A basic under-standing of the principles of care for musculoskeletal conditions is essential for the health care profession.For physicians, the field of orthopedics offers an array of subspecialties with such diversity that it seems that “there is something for everyone.” Trauma specialists have the satis-faction of physically putting complex fractures back together. Sports medicine offers remarkably rapid recovery in athletes who have suffered fibrocartilage and ligament tears with ever-improving arthroscopic techniques and instrumentation. Spine surgeons see remarkable results from their minimally inva-sive microscopic techniques, while also managing massive deformities with new instrumentation and open surgery. Joint reconstruction is one of our most exciting subspecialties, work-ing with orthopedic bioengineers to develop improved designs, biomaterials, and minimally invasive surgical approaches for faster return to function for patients debilitated by arthritis and injury. Musculoskeletal oncology offers the intellectual chal-lenge of arriving at appropriate differential diagnoses as well as the technical challenge of limb salvage and major reconstruc-tive surgery. Pediatric orthopedics is an especially challenging and rewarding subspecialty because of the remarkable ability of children to heal their fractures quickly and remodel their bones. The incredible array of congenital and developmental disorders makes pediatrics a uniquely intellectually challenging field as well. The authors hope that our readers will share our enthusi-asm for orthopedic surgery and all of its subspecialties: trauma, sports, spine, joint replacement, musculoskeletal oncology, foot and ankle, hand, and pediatric orthopedics.Brunicardi_Ch43_p1879-p1924.indd 188022/02/19 10:40 AM 1881ORTHOPEDIC SURGERYCHAPTER 43ORTHOPEDIC TRAUMAIntroductionMusculoskeletal injuries resulting from trauma include frac-tures of bones, damage to joints, and injuries to soft tissues. Long bone fractures can be described as transverse, oblique, spiral, segmental, or comminuted (Fig. 43-1). The goals of treat-ing musculoskeletal injuries are to restore the normal anatomy, stabilize fractures to allow early mobility and minimize com-plications related to multiple system trauma, and to repair or reconstruct these injuries to restore function.Fractures frequently result from high-energy trauma as well as from falls onto an extremity (Fig. 43-2). The majority of fractures can heal well with immobilization, which stabilizes the fracture while new bone forms at the fracture site. Methods of immobilization can vary and depend on the fracture being treated. The most common tool used in orthopedics to treat fractures is immobilization with a splint, cast, or braces, and their proper application is important to successfully treat the injury without causing additional problems. A successful splint contains adequate padding on the underlying skin, particularly over bony prominences, to prevent pressure or burns that can be caused by plaster. Splints, which are not circumferential, are preferred for acute injuries because they allow room for swell-ing that inevitably occurs after a fracture. The splint may later be changed to a cast as the swelling subsides.Fractures that are displaced or angulated require closed reduction to properly realign the bone. This is done using anal-gesia, local or general anesthesia, and often muscle relaxation. Reduction is performed with axial traction and reversal of the mechanism of injury in order to restore length, rotation, and angu-lation. A splint is then applied and can be gently molded to help hold the reduction in place. It is important to obtain X-rays after a closed reduction to verify acceptable alignment of the fracture, and to perform a neurovascular exam to ensure the splint is not too tight or that manipulation did not change the neurovascular status. Careful monitoring with timely clinical and radiological examination is necessary in the outpatient setting.For certain fractures, splint or cast immobilization is inad-equate, and in these instances internal fixation or external fixa-tion is used. A variety of implants can be used to stabilize the fracture such as screws, plates, rods, and external fixators. The main principle of orthopedic implants for fracture care is to cre-ate a stable construct that will allow the fracture to heal in proper length, alignment, and rotation. Screws can be placed across a fracture to create compression at the fracture site, which promotes healing. Plates can be placed on the cortex of bones and held with screws, which creates a long area of fixa-tion to stabilize the fracture. Intramedullary rods are commonly used for long bone fractures, such as the femur and tibia (Fig. 43-3A,B). Usually, the fracture is reamed prior to the insertion of the rod into the intramedullary canal. Screws can then be placed across the cortices of the bone through holes in the rod proximal and distal to the fracture to create a locked construct that further stabilizes the rod. When the fracture is locked proximally and distally, this is called static locking. In situations where patients are severely injured and cannot safely undergo more invasive open surgery, damage control orthope-dics is done by utilizing an external fixator. External fixators are also used when the soft tissues are too swollen or injured to allow for surgical incisions to be safely made. The wrinkle test is helpful in guiding the most suitable time for definitive sur-gery. An external fixation device can be used to temporarily immobilize the fracture, especially if the fracture is open and contaminated. External fixators involve pins placed into bone proximal and distal to the fracture (through healthy tissues), which are then connected by strong rods on the outside of the extremity, creating a stable construct.Open FracturesAn open fracture occurs when the bone breaks through the skin. These typically result from high-energy injuries and are often associated with significant damage to the surrounding soft tissues and contamination of the wound. These injuries are classified into three types according to the Gustillo-Anderson Classification.• Type I injuries are low energy and wounds are usually less than 1 cm.• Type II injuries have a wound length of 2 to 10 cm with mod-erate soft tissue damage and wound contamination.1ABCDEFFigure 43-1. Types of fractures. A. Normal bone. B. Transverse. C. Oblique. D. Spiral. E. Segmental. F. Comminuted.Figure 43-2. Transverse tibia fracture and segmental fibula fracture.Brunicardi_Ch43_p1879-p1924.indd 188122/02/19 10:40 AM 1882SPECIFIC CONSIDERATIONSPART II• Type III injuries are high-energy wounds usually greater than 10 cm in length with extensive muscle devitalization. The wound is highly contaminated with extensive soft tissue damage.These injuries require immediate administration of antibi-otics and irrigation and debridement of the wound. The goal of the treatment is to achieve fracture healing and to prevent wound infections and osteomyelitis. They are frequently associated with injuries to surrounding vessels and nerves, which must be addressed as well. When the wound is contami-nated, an external fixator is initially used (Fig. 43-4A,B). Often, definitive treatment of the fracture is delayed until the wound is 2ABFigure 43-3. A. Transverse femur fracture. B. Intramedullary rod stabilizes femur fracture.ABFigure 43-4. A. Gustillo-Anderson fracture type III open fracture. B. Image of external fixator of the tibia.Brunicardi_Ch43_p1879-p1924.indd 188222/02/19 10:40 AM 1883ORTHOPEDIC SURGERYCHAPTER 43sufficiently cleaned and healthy soft tissue is available to cover the fracture. Early coverage of the wound is important to avoid infection. Usually a large wound in the proximal or middle third of the tibia can be covered using local muscle flaps, while the distal third of the tibia will require a free flap. In general, an increase in Gustillo grade is associated with an increase in infec-tion risk.Compartment SyndromeCompartment syndrome is an orthopedic emergency caused by significant swelling within a compartment of an injured extrem-ity that jeopardizes blood flow and microcirculation to the limb. Increased pressure within the compartment compromises perfu-sion to muscles and nerves and can cause ischemia or necrosis. Patients complain of pain that is greater than expected for the injury or surgery. There may be an increase in analgesic require-ments. Early high index of suspicion is necessary for timely diagnosis and treatment of compartment syndrome. The usual clinical findings are pain, swelling, and pain with passive stretch of the compartment muscles. Numbness, paralysis, and the absence of a pulse are late findings. While the diagnosis is usu-ally based on clinical exam, compartment pressures can be mea-sured with needles placed into the compartment, which is necessary in unconscious patients and those who will not coop-erate with the exam. Compartment pressure within 30 mmHg of the diastolic pressure is diagnostic of compartment syndrome. When compartment syndrome is suspected, emergent fasciot-omy (Fig. 43-5A,B) must be performed in which the overlying tight fascia is released through long incisions. Fasciotomy must be done as soon as possible to prevent damage to muscles and nerves that will result in irreversible necrosis and Volkmann’s ischemic contractures with severe loss of function.TREATMENT OF FRACTURES AND DISLOCATIONSClavicle FracturesFractures of the clavicle are one of the most common fractures in orthopedics. They typically occur following a fall onto the shoulder. The majority of clavicle fractures occur in the middle third of the clavicle. Since the clavicle is subcutaneous, the frac-ture is often evident on inspection. Most clavicle fractures can be treated nonoperatively with a sling, early range of motion exercises, and gradual return to normal activities. Fractures that are significantly displaced and shortened or that penetrate or tent the skin are treated with open reduction and internal fixa-tion, typically with plate and screw fixation.Distal clavicle fractures are less common and may occur with coracoclavicular ligament ruptures. These injuries can be more troublesome and are at risk for nonunion if the bone ends are not in contact. If there is displacement of the fracture and the fracture is proximal to the coracoclavicular ligament, surgical management is often recommended.Acromioclavicular (AC) joint injuries occur from either a fall directly onto the shoulder or onto an outstretched hand and can result in tears of the acromioclavicular and cora-coclavicular ligaments. A step-off, or separation, of the AC joint may be apparent on radiographs. The majority of these injuries can be treated with a sling and gentle range of motion. Although controversial, injuries resulting in severe displacement of the clavicle at the AC joint usually require open reduction and surgical repair, especially in athletes and manual workers.The sternoclavicular (SC) joint is the only articulation between the upper extremity and the axial skeleton. Injuries to this joint are rare. Anterior dislocations occur more frequently, and although closed reduction can be attempted, recurrence of the dislocation is typical. Patients are given a sling and the out-come is usually good, despite the visible bump and swelling. Posterior SC joint dislocations are rare and not grossly visible and can be easily missed. They can be dangerous injuries, result-ing in pulmonary or neurovascular compromise. Therefore, closed or open reduction under general anesthesia is recom-mended with a cardiac surgeon back-up.Scapula FracturesFractures of the scapula often result from significant high-energy trauma (Fig. 43-6) with about 80% associated injuries, 3Compartmentsyndrome ofthe forearmABFigure 43-5. A. Image showing compartment syndrome of the forearm. B. Fasciotomy of the leg. Notice gaping of the wound and bulging of the muscles.Brunicardi_Ch43_p1879-p1924.indd 188322/02/19 10:40 AM 1884SPECIFIC CONSIDERATIONSPART IImost commonly involving the head, ribs, and lungs. Pulmonary injuries occur in over one-third of patients. Most scapula fractures are treated nonoperatively with a sling and early range of motion. Surgery is performed when there is involve-ment of the glenoid with a major articular step-off or if there is a glenoid rim fracture with subluxation of the joint.Shoulder DislocationsThe shoulder is the most commonly dislocated large joint. Most dislocations are anterior. They are often associated with injuries to the anterior inferior glenoid labrum (Bankart lesion), impac-tion fractures of the humeral head (Hill-Sachs lesion) (Fig. 43-7), and rotator cuff tears in the elderly. The axillary nerve is at risk of being injured in shoulder dislocation. If the patient is unable to raise the arm after reduction of shoulder dislocation, then it is most likely due to a rotator cuff tear in the elderly and axillary nerve injury in the young.There is a high recurrence rate that correlates with the age of the patient at the time of dislocation. There is a 90% redislocation rate if the patient is younger than 20 years of age. Posterior dislocations are associated with seizures or electric shock. Adequate radiographs are required to diagnose a shoul-der dislocation, with the axillary view being the most important. The patient’s shoulder is usually locked in internal rotation with limitation of external rotation and axillary view will show the posterior dislocation (Fig. 43-8A,B). If proper X-rays are not performed, then dislocations can be missed and can result in significant disability to the patient. A computed tomography (CT) scan should be performed if an axillary view is unable to be obtained. In general, dislocation of the shoulders can be managed with closed reduction followed by a short period of sling immobilization.Proximal Humerus FracturesProximal humerus fractures occur most frequently in elderly female patients following a fall onto the shoulder, though they can also occur following high-energy trauma in young patients. They have historically been classified by the number of fracture fragments using Neer’s classification (Fig. 43-9), which divides the proximal humerus into four parts: the humeral head, greater tuberosities, lesser tuberosities, and the humeral shaft. Treat-ment is determined by the displacement of the fracture frag-ments, the amount of angulation of the fracture, and the amount of comminution (which means multiple fracture fragments). If there is suspicion of an intra-articular fracture, CT scan is often indicated. The majority of proximal humerus fractures are mini-mally displaced and can be treated with sling immobilization, followed by early shoulder motion and pendulum exercises. Physiotherapy should be started within 2 weeks of the injury to prevent stiffness, especially in the elderly. Displaced fractures and fractures involving the humeral head are at increased risk for osteonecrosis, and therefore surgery is often recommended. If there is adequate bone stock and the fracture can be success-fully reduced, open reduction internal fixation with plate and screw fixation is the treatment of choice. Older patients with osteoporosis, comminuted fractures, head-splitting fractures, and four-part fractures or fracture dislocations are typically treated with a prosthetic replacement of the humeral head or a hemiarthroplasty. Reverse shoulder arthroplasty is gaining popularity in the elderly as well.Humeral Shaft FracturesThe majority of humeral shaft fractures can heal with nonsurgi-cal management if they are within an acceptable degree of angulation. The radial nerve spirals around the humeral shaft and is at risk for injury; therefore, a careful neurovascular exam is important. If you have a patient with a humeral shaft fracture, check the patient for wrist drop (Fig. 43-10). Most radial nerve injuries are neurapraxias, or stretching of the nerve, and function typically returns within 3 to 4 months. A spiral fracture of the distal one-third of the humeral shaft is commonly associated with neurapraxia of the radial nerve, and this fracture is called a Holstein-Lewis fracture. Humeral shaft fractures are typically treated with a coaptation splint or functional bracing, which consists of a plastic clamshell brace with Velcro straps. Criteria for acceptable alignment are less than 20° anterior angulation, less than 30° varus/valgus angulation, and less than 3 cm shortening. Radial nerve palsy is not a contraindication to conservative treatment. Close follow-up with serial radiographs 456Figure 43-6. Scapula fracture. Notice the body and the glenoid are involved.Figure 43-7. Hill-Sachs humeral head impaction fracture and Bankart lesion, which is an avulsion of the anterior inferior labrum.Brunicardi_Ch43_p1879-p1924.indd 188422/02/19 10:40 AM 1885ORTHOPEDIC SURGERYCHAPTER 43is important to verify healing of the fracture, and gentle motion exercises are begun within 1 to 2 weeks. Fractures with signifi-cant angulation are most commonly treated with open reduc-tion and plate fixation, with care to protect the radial nerve as it often lies close to the fracture site. Intramedullary nailing can also be performed, though it carries the risk of shoulder pain from the nail insertion. A plate is usually more stable than a nail and allows early weight-bearing through the humerus. Sponta-neous recovery of radial nerve palsy can occur up to 6 months after injury. The patient should have an EMG to monitor recov-ery of the nerve. In an open fracture of the humeral shaft with radial nerve palsy, the nerve should be explored for the possibil-ity of a significant nerve injury or laceration.Distal Humerus FracturesFractures of the distal humerus result from falls onto the elbow or onto an outstretched arm. Supracondylar fractures occurring above the elbow joint are most common and do not involve the articular surface. Minimally displaced fractures can occasion-ally be treated with a posterior long arm splint, with the elbow typically flexed to 90°. However, fixation is often recommended to allow early range of motion and prevent stiffness. Fractures involving the articular surface are treated with plate fixation, and depending on the fracture pattern they may require more than one (usually anatomically contoured) plate. As with other intra-articular fractures, the goals of treatment are anatomic reduction of the joint surface with stable fixation, restoration of the anatomic alignment of the joint, and early range of motion. Severely comminuted fractures, especially in the elderly, may be treated with a total elbow replacement. Fractures about the elbow are notorious for developing stiffness and therefore early motion of the elbow is paramount to a successful outcome. Range of motion should be started as soon as the patient can tolerate therapy.Elbow DislocationsDislocations of the elbow are common and typically occur posteriorly after a fall on an outstretched hand. A dislocation results in injury to the joint capsule and rupture of the lateral collateral ligament, with possible involvement of the medial collateral ligament, as well as possible fractures of the radial head and coronoid. This combination of injuries is called the “terrible triad,” which is a challenging injury and carries the Figure 43-8. A. Posterior shoulder dislocation showing limitation of external rotation. B. Axillary view sowing posterior dislocation of the shoulder.Figure 43-9. Four-part proximal humeral head fracture.Figure 43-10. Radial nerve palsy due to humeral shaft fracture causing wrist drop.Brunicardi_Ch43_p1879-p1924.indd 188522/02/19 10:40 AM 1886SPECIFIC CONSIDERATIONSPART IIworst prognosis. Simple elbow dislocations should be urgently reduced with the patient under sedation and treated with a short period of immobilization, utilizing a posterior splint. Stiffness of the elbow is a common complication following elbow dislocations and therefore only short-term immobiliza-tion (about 7–10 days) followed by early range of motion is recommended.Dislocations associated with fractures may be treated sur-gically if there is any instability of the elbow joint. The “terrible triad” is an unstable injury comprising of an elbow disloca-tion as well as fractures to the radial head and coronoid, which requires surgery. Surgery includes repair of the torn lateral col-lateral ligament, fixation or replacement of the radial head, and possible fixation of the coronoid, depending on the size of this fracture fragment.Radial Head FracturesMost fractures of the radial head can be treated nonoperatively, simply with a sling for 1 to 2 days followed by motion exercises. Surgery is recommended if there is a displaced fracture, if the fracture blocks pronation or supination of the forearm, if there is an associated dislocation of the elbow, or if the patient has associated wrist pain (Essex-Lopresti fracture). Surgery can be fixation or replacement. If the fracture can be well reduced, it is fixed with 1 or 2 screws. If the radial head is fractured into multiple pieces, the treatment of choice is a radial head replace-ment with a metallic implant. Simple excision of the radial head can also be performed in low demand patients with an isolated radial head fracture; otherwise, it may lead to instability of the elbow and the wrist over time.Olecranon FracturesOlecranon fractures usually occur following a fall directly onto a flexed elbow (Fig. 43-11). Nondisplaced fractures are treated with a splint in 45° to 90° of flexion for a short time followed by range of motion exercises to prevent stiffness. Because the triceps inserts on the olecranon, the pull of the muscle often causes active extension of the elbow and displacement of the fracture, and therefore the olecranon fracture should be fixed surgically. Simple transverse fractures can be fixed with a tension band construct, which consists of wire passing through the ulna, distal to the fracture, and wrapped in a figure-of-8 fashion around two or more pins placed proximally into the olecranon, crossing and stabilizing the fracture. This tension band construct creates a compressive force across the articular aspect of the fracture that will promote healing. Fractures that are comminuted or have large fragments are usually treated with plate and screw fixation. Excision of the olecranon with advancement of the triceps can be done in elderly patients when the fracture involves less than 50% of the joint surface. Because of the subcutaneous location of the olecranon, symp-tomatic hardware is a frequent complication, causing irritation to the patient; it may need to be removed after the fracture has healed. Stiffness of the elbow is another complication seen in a large number of patients.Forearm FracturesForearm fractures are common injuries that result from high-energy trauma or from falls onto an outstretched arm. Both bone forearm fractures generally require surgery with plate and screw fixation. The radius has a bow and rotates around the straight ulna for proper pronation and supination of the forearm, and therefore this anatomic relationship needs to be restored to maintain function. An isolated fracture of the ulna shaft, or a “nightstick fracture,” occurs from a direct blow to the side of the forearm. These can usually be treated in a cast, splint, or brace. Fractures that are angulated or displaced can be treated with open reduction and plate fixation. A Monteggia fracture is a fracture of the proximal third of the ulna associated with a radial head dislocation. The radial head dislocation may be missed. Careful evaluation of the radiograph, especially the relation-ship with the radial head to the capitellum is necessary for the diagnosis of this injury. These fractures are common in children and rare in adults. These injuries require surgery to fix the ulna fracture with plate and screw fixation and to reduce the radial head dislocation. A Galeazzi fracture is a fracture of the distal third radial shaft associated with distal radioulnar joint (DRUJ) injury at the wrist. If the fracture of the radius is less than 7.5 cm from the joint, the distal radioulnar joint is injured in a large number of cases. After the radius is fixed with plate and screw fixation, the DRUJ is assessed for stability and may need wires placed across the joint temporarily.Distal Radius FracturesDistal radius fractures commonly occur in older patients due to a fall or osteoporosis. In younger patients, these fractures usu-ally occur due to high-energy trauma. A Colles fracture is a low energy fracture that is extra-articular and usually dorsally displaced. It has a characteristic appearance of a fork, naming the fracture the “dinner-fork” deformity. A Smith’s fracture is a reverse Colles fracture, usually extra-articular and volarly displaced. A Chauffer’s fracture involves the radial styloid process and may cause occult carpal disruption. A Barton’s fracture can be either volar or dorsal. It is a fracture dislocation of the radiocarpal joint, with an intra-articular volar or dorsal fracture.Every attempt should be made to rule out fractures that extend intra-articularly into the wrist joint or involve the DRUJ. Patients should be evaluated for a median nerve injury and osteoporosis if suspected. Loss of thumb extension from extensor pollicus longus tendon rupture can occur especially in nondisplaced distal radius fractures. Treatment is often a closed Figure 43-11. Displaced olecranon fracture.Brunicardi_Ch43_p1879-p1924.indd 188622/02/19 10:40 AM 1887ORTHOPEDIC SURGERYCHAPTER 43reduction and immobilization. Surgery utilizing a variety of sur-gical techniques is done for unstable fractures as well as those with significant intra-articular involvement.Scaphoid FracturesScaphoid fracture is the most common fracture of the carpal bone. Its diagnosis can be easily missed, and the fracture can lead to nonunion and avascular necrosis. It usually occurs in the waist of the scaphoid but can occur in the proximal or distal pole. Proximal scaphoid fracture will have a higher inci-dence of avascular necrosis due to interruption of the retro-grade blood supply. Tenderness in the anatomic snuffbox after trauma should be considered a scaphoid fracture until proven otherwise. Magnetic resonance imaging (MRI) will be help-ful in early diagnosis if no fracture is visible on an X-ray. A thumb spica cast is used for stable nondisplaced fracture, while reduction and screw fixation of the fracture is usually done for displaced fractures. The dorsal approach is used for proximal fractures, and the volar approach is used for the majority of other fractures.Pelvic FracturesPelvic fractures are indicative of high-energy trauma and are associated with head, chest, abdominal, and urogenital injuries. Hemorrhage from pelvic trauma can be life-threatening and patients can present with hemodynamic instability, requiring significant fluid resuscitation and blood transfusions. The bleed-ing that occurs is often due to injury to the venous plexus in the posterior pelvis or from the fracture itself. It can also be due to a large vessel injury such as the superior gluteal artery at the greater sciatic notch. Immediate resuscitation with fluids and blood is critical. In hemodynamically unstable patients, blood, fresh frozen plasma, and platelets are given in a 1:1:1 ratio. These patients may require surgical exploration or interven-tional radiology embolization to stop the bleeding. An important first-line treatment in the emergency department is the application of a pelvic binder or sheet that is wrapped tightly around the pelvis to help control bleeding. This is important when there is an increase in the volume of the pelvis by the anteroposterior compression mechanism (an open book mechanism). The pelvic binder is clearly the initial management of an unstable open book fracture of the pelvis with bleeding. Traction pins may be applied in the emergency department if there is vertical migration of the hemipelvis. An external fixator may also be placed in the operating room, but it is less fre-quently used. Other associated injuries are bladder and urethral injuries that manifest with bleeding from the urethral meatus or blood in the urinary catheter, and these need to be assessed with a retrograde urethrogram.The pelvis is a ring structure made up of the sacrum and the two innominate bones that are held together by strong liga-ments. Because it is a ring, displacement can only occur if the ring is disrupted in two places. This may occur either from frac-tures of the bones or tears of the ligaments that can cause dis-location. When you see an anterior fracture of the ring, check for a posterior injury (Fig. 43-12). There are three main fracture patterns that occur from trauma to the pelvis. An anteroposterior force to the pelvis causes an “open book” injury pattern in which the pelvis springs open, hinged on the intact posterior ligaments with widening of the pubic symphysis. A lateral compression pattern results from a crush injury that causes fractures to the ilium, sacrum, and pubic rami. Vertical shear injuries are very unstable since they result from disruption of the strong posterior pelvic ligaments and are associated with significant blood loss and visceral injuries. Fractures of the sacrum may be difficult to see on X-ray, and therefore CT scans are often needed to completely visualize the fracture pattern. The sacral nerves pass through foramen in the sacrum, and therefore fractures that are close to the foramen can result in nerve injuries. Fractures that involve the sacral canal have a high incidence of nerve injuries and cauda equina syndrome. Fractures that involve the ala of the sacrum may involve the L5 nerve root. Vertical fractures of the 7ABFigure 43-12. A. Pelvic fracture showing anterior and posterior disruption of the pelvis. B. Image depicting a vertical shear fracture with cephalad migration of the hemi-pelvis.Brunicardi_Ch43_p1879-p1924.indd 188722/02/19 10:40 AM 1888SPECIFIC CONSIDERATIONSPART IIsacrum can be highly unstable even after fixation and may be associated with sacral nerve root injuries.Treatment of pelvic fractures depends on the fracture pat-tern. Stable, minimally displaced fractures such as many lower energy lateral compression fractures can be treated nonopera-tively with protected weight-bearing. Open book injuries in which the pubic symphysis is widened more than 2.5 cm may require an anterior plate, and if the posterior pelvic ligaments are also injured, the patient will need posterior fixation. Pos-terior stabilization is typically performed with screws placed percutaneously through the ilium into the sacrum to stabilize the pelvis posteriorly, and a plate is applied over the pubic symphy-sis for anterior stabilization. Displaced sacral fractures and iliac wing fractures are treated with screws or plates, while pubic rami fractures can usually be managed nonoperatively. While most pelvic fractures are caused by high-energy trauma, elderly patients with osteoporotic bone can also suffer pelvic fractures after a fall, usually fracturing the pubic rami. Since these are stable injuries, they can be managed nonoperatively with pro-tected weight-bearing.Acetabular FracturesThe acetabulum forms the socket of the hip joint, and fractures occur when the femoral head is driven into the acetabulum in the setting of high-energy trauma. Sciatic nerve function should be examined carefully after an acetabulum fracture. It is impor-tant to rule out dislocation of the hip, which should be reduced immediately to prevent avascular necrosis of the femoral head. Usually 45° oblique views, called Judet views, are utilized. CT scans are very important to visualize the fracture pattern. According to Judet and Letournel, there are ten acetabular fracture patterns: five simple and five complex fracture types (Fig. 43-13). These fractures often require surgery in order to obtain anatomic reduction and to minimize the development of degenerative arthritis.Hip DislocationsHip dislocations almost always result from high-energy trauma; they most commonly occur posteriorly and less commonly ante-riorly (Fig. 43-14). They can cause injury to the sciatic nerve, which runs directly posterior to the hip joint. Examine the patient for foot drop and numbness at the top of the foot. Hip dislocation can be simple, or it may be associated with a fracture of the acetabulum or femoral head. Hip dislocations need to be emergently reduced because of the risk of osteonecrosis of the femoral head if the reduction is delayed. Closed reduction is usually successful with adequate sedation or under general anes-thesia. Once reduction is done, a CT scan is ordered to define the extent of the injury. A CT scan will show associated frac-tures, trapped intraarticular fracture fragments, and the congru-ity of the reduction. If the reduction is unsuccessful, or if there is a fracture fragment inside the joint, then an open reduction is indicated. Hip dislocations that are associated with a femoral head fracture are at increased risk for osteonecrosis of the femo-ral head and posttraumatic osteoarthritis. The femoral head frac-ture associated with hip dislocation is called a Pipkin fracture. If the dislocation is associated with posterior wall fractures, the stability of the hip joint should be assessed carefully, even if the fragment is small. This is usually done by an examination of the patient under anesthesia.Hip FracturesHip fractures are an extremely common injury seen in orthope-dics and are associated with significant morbidity and mortal-ity. They most often occur in elderly patients after ground level falls, are much more common in women than men, and occur more commonly in patients with osteoporosis. The three most common fractures in the elderly are those of the wrist, spine, and hip. Patients who suffer hip fractures are at increased risk for many complications, including deep vein thrombosis, pul-monary embolism, pneumonia, deconditioning, pressure sores, and even death. The mortality rate in the first year following a hip fracture is around 25%. One of the most important rea-sons for performing surgery is to prevent these complications because getting patients out of bed and walking as soon as pos-sible diminishes their risk for many of these adverse events. Performing early surgery also decreases the complications in these patients. Therefore, surgery is almost always the treat-ment of choice for hip fractures. The type of surgery performed is determined by the anatomic location of the fracture and the fracture pattern. Surgery should be performed as soon as pos-sible, typically within 24 to 48 hours; however, since many of these patients suffer other comorbidities, they must be properly medically optimized before surgery. The goals of surgery are to minimize pain, restore hip function, and allow early mobi-lization, the importance of which cannot be overemphasized. The functional outcome for patients following a hip fracture is largely based on their level of mobility and independence Figure 43-13. Types of acetabular fractures.Figure 43-14. Posterior and anterior dislocation.Brunicardi_Ch43_p1879-p1924.indd 188822/02/19 10:40 AM 1889ORTHOPEDIC SURGERYCHAPTER 43before their injury. Many patients become less independent, may require assistive devices to help them walk, and some may require a long-term nursing or rehabilitation facility. Hip frac-tures can be femoral neck fractures, intertrochanteric fractures, or subtrochanteric fractures (Fig. 43-15).Femoral Neck Fractures. Femoral neck fractures occur within the capsule of the hip joint. The main blood supply to the femo-ral neck and head comes from the deep branches of the medial femoral circumflex arteries, which run along the femoral neck, and when the fracture is displaced, there is an interruption in the blood supply of the femoral head, which can lead to osteonecro-sis. Femoral neck fractures that are nondisplaced have a low risk of disruption of blood flow and therefore can be treated with in situ internal fixation. Three partially threaded cancellous screws are placed through a small incision over the lateral proximal femur, directed through the femoral neck and into the femoral head. Patients can usually begin protected weight-bearing imme-diately after surgery. Displaced femoral neck fractures will likely disrupt the blood supply and therefore need to be treated with a prosthetic replacement in older adults. Most commonly a hemi-arthroplasty is performed in which the femoral head and neck are replaced with a metal head and neck into the femoral canal. Higher demand patients and those who have osteoarthritis of the hip joint and hip pain before their fracture may receive a total hip replacement, in which the acetabulum is also replaced with a prosthesis, typically a plastic cup inside a metal shell. Patients can begin weight-bearing immediately after surgery. Displaced femoral neck fractures in young patients are the result of a high-energy trauma and are usually treated by reduction with screw fixation. The reduction may be closed or open.Intertrochanteric Hip Fractures. Intertrochanteric hip frac-tures occur between the greater and lesser trochanters of the proximal femur. Because the blood supply to this area is abun-dant, osteonecrosis is uncommon, and therefore these fractures can be treated with reduction and internal fixation. Displaced fractures need to be realigned, and this often involves placing the patient on a fracture table where traction and rotation can be applied to the affected leg to reduce the fracture. There are two devices that can be used. In stable fractures, a sliding hip screw includes a large screw placed from the lateral cortex of the proximal femur across the fracture and into the femoral neck and head, followed by a side plate along the lateral cortex of the femur, which is then fixed to the shaft with screws. A cephalom-edullary nail includes a nail placed down the medullary canal of the femur and a large screw that engages the nail as it is passed from the lateral cortex up into the neck and head. Nails are usually used in unstable fractures and allow protected weight-bearing postoperatively. The reverse oblique intertrochanteric fracture is a specific type of fracture that exits on the lateral cortex (Fig. 43-16). This is best treated with a cephalomedullary Figure 43-15. Types of hip fractures.Figure 43-16. Classic intertrochanteric fracture and reverse oblique fracture. Notice that the fracture line of the reverse oblique fracture exits on the lateral cortex.Brunicardi_Ch43_p1879-p1924.indd 188922/02/19 10:40 AM 1890SPECIFIC CONSIDERATIONSPART IInail; a dynamic hip screw is the wrong device to be used in reverse oblique fractures because it will lead to sliding, shorten-ing, and medial displacement of the fracture.Subtrochanteric Hip Fractures. Subtrochanteric hip frac-tures occur in the proximal femoral shaft just distal to the lesser trochanter in an area of high biomechanical stresses. While they can occur in older adult patients after a fall, they are also seen in high-energy trauma. Because of the forces of muscles attached to the fractured segments, they tend to be significantly displaced (Fig. 43-17) and may be difficult to reduce. They are most often treated with a long cephalomedullary nail that includes a screw distally to lock the nail in place and prevent rotation of the femur. Fixed angle plates or blade plates are sometimes used in the treatment of subtrochanteric fractures. In most cases, pro-tected weight-bearing can begin soon after surgery. Complica-tions usually include malunion and nonunion of the fracture.Bisphosphonate-related subtrochanteric fractures are an example of insufficiency fractures that may be related to the long-term use of bisphosphonates. These fractures have been recently identified. An intramedullary nail is the treatment of choice for this fracture.Femoral Shaft FracturesFractures of the femoral shaft are caused by high-energy trauma and may be associated with other severe injuries. Long bone fractures, such as femoral shaft fractures, put these patients at risk for complications such as thromboembolic events and acute respiratory distress syndrome (ARDS), and therefore it is important to fix these quickly, typically within 24 hours. They are most commonly fixed with an intramedullary nail that can be placed antegrade (from the piriformis fossa or greater tro-chanter down the canal) or retrograde (through an incision into the knee joint and up the canal), with screws placed through proximal and distal holes to lock the nail in place, creating a stable construct to allow weight-bearing. Trauma patients who are hemodynamically unstable or who have other life-threatening injuries are treated temporarily with an external fixator until they can safely undergo surgery. This is called “damage control orthopedics.” The base deficit and lactic acid levels are moni-tored and used as guides to indicate if the patient is adequately resuscitated. When their levels are normal, it means the tissue is adequately oxygenated and the patient can undergo definitive fixation of the femur.Distal Femur FracturesDistal femur fractures are the result of a fall from a height or from high-energy trauma. They can also occur in elderly patients with osteoporotic bone after a fall onto the knee. While nondisplaced fractures in the elderly may be treated nonoper-atively with a hinged knee brace and early motion exercises, most require surgery. These fractures can involve the articu-lar surface of the knee joint, so anatomic reduction of the joint surface is crucial. They are fixed with plates and screws, often utilizing a locking construct. The plate is placed over the lateral, or rarely the medial cortex depending on the fracture pattern. A retrograde intramedullary rod inserted through the knee can also be used, especially in extraarticular fracture patterns. The goal of surgery is to achieve anatomic reduction, stable fixation, and allow early knee range of motion. Intra-articular fractures require the patient to be non–weight-bearing until the frac-ture shows signs of healing. Complications of these fractures include nonunion, malunion, and stiffness of the knee. Be aware of Hoffa fractures, a coronal fractures that usually involve the lateral femoral condyle. They can be missed on X-rays, but they are easily diagnosed by CT scan. It may need a different fixa-tion than that required for the associated supracondylar fracture component.Knee DislocationsDislocation of the knee is a rare but devastating injury that can be limb-threatening. Some dislocations spontaneously reduce and can be underdiagnosed. When the knee dislocates, the anterior cruciate ligament (ACL) and posterior cruciate liga-ment (PCL) are torn, and various degrees of injury occur to the lateral collateral ligament (LCL), medial collateral ligament (MCL), posterolateral corner, joint capsule, and menisci. How-ever, the danger is due to the close proximity of the popliteal artery, which runs directly behind the knee and may kink or sustain a tear of the intimal wall when the knee dislocates. A neurovascular exam is extremely important, focusing on the common peroneal nerve and the vascular status of the extrem-ity, followed by immediate reduction of the knee and repeat neurovascular exam. If the pulses are normal, the ankle brachial index (ABI) should be measured. If the ABI is more than 0.9, then the patient should be monitored with serial examination. If the ABI is less than 0.9, then a CTA or an arterial duplex ultra-sound should be performed. If there is evidence of diminished pulses after reduction, an angiogram must be performed. If the pulses are absent after reduction, immediate surgical explora-tion and/or repair should be done by a vascular surgeon. Pro-phylactic fasciotomy of the leg is usually done. Time is critical to reestablish the circulation of the limb. If ischemia time is more than 8 hours, then there is a very high rate of amputation. With regard to the ligamentous injuries, an external fixator may be initially used to stabilize the unstable knee and protect the reduction. Subsequently, an MRI will identify what structures have been torn. Because a dislocation causes so much damage to the knee, a delayed multiligamentous reconstruction is recom-mended on an elective basis in order to stabilize the knee joint. Figure 43-17. Illustration showing subtrochanteric fracture with the deforming forces of the muscle.Brunicardi_Ch43_p1879-p1924.indd 189022/02/19 10:40 AM 1891ORTHOPEDIC SURGERYCHAPTER 43Stiffness and instability of the knee are common complications after this injury.Patella/Extensor Mechanism InjuriesThe extensor mechanism is comprised of the quadriceps ten-don, the patella, and the patella ligament. This mechanism func-tions to extend the knee. Injuries can result after a fall directly onto the knee or from forcible contraction of the quadriceps. It is important to examine the knee for the ability to actively extend the knee. Quadriceps tendon ruptures, patella fractures, or patella ligament ruptures can result in a loss of active knee extension requiring surgery. Nondisplaced patella fractures with intact active knee extension can be treated nonoperatively with a cast or knee immobilizer, holding the knee in full extension, and weight-bearing is permitted. Displaced or comminuted frac-tures require surgery with tension band wiring and/or screws. Symptomatic hardware is a common complication. Acute osteo-chondral fractures can be managed with internal fixation. Quad-riceps tendon and patella tendon ruptures with loss of active knee extension are treated with suture repair. After surgery, the knee is held in extension, and knee flexion is slowly increased over several weeks using a hinged knee brace.Patella dislocations are common injuries that occur when the femur is forcibly internally rotated on an externally rotated tibia while the foot is planted on the ground. They typically dislocate laterally and often relocate spontaneously. The medial patellofemoral ligament is the primary stabilizer of the patella. Patients present with a significant knee effusion and medial-sided tenderness. During the physical exam, these patients may elicit a positive apprehension test, in which a lateral force to the patella elicits pain and the sensation of an impending dis-location. Dislocated patellas can be reduced by extending the knee and manual reduction and are treated with temporary knee immobilization. Make sure that there is no fracture or loose bod-ies, which would be an indication for surgery. MRIs will show the classic bone bruise and edema involving the medial facet of the patella and the lateral condyle of the femur. There is a high rate of recurrent dislocation with nonoperative treatment, which may require surgical intervention.Tibial Plateau FracturesThe tibial plateau is comprised of the articular surfaces and underlying cancellous bone of the medial and lateral plateaus of the proximal tibia. Fractures of the plateau result from axial loads sustained in falls from a height or high-energy trauma, and they are often associated with injuries to the menisci and cartilage of the knee. Fractures can involve the medial, lat-eral, or both plateaus with significant comminution, angula-tion, and depression, creating a challenging injury to fix. The Schatzker classification is commonly used in tibial plateau fractures (Fig. 43-18).• Type I: Lateral split fracture• Type II: Lateral split-depressed fracture• Type III: Lateral pure depression fracture• Type IV: Medial plateau fracture• Type V: Bicondylar fracture• Type VI: Metaphyseal-diaphyseal disassociationMeniscal tears occur more on the lateral side and tend to be peripheral tears, especially if there is more than 6 mm depres-sion or separation of the joint. Type IV, which is the medial tibial plateau fracture, could be a variant of a knee dislocation. The ankle brachial index (ABI) should be used in this situation and in more complex types of tibial plateau fractures. Clinically, laxity of more than 10° may indicate instability of the fracture; however, the test may be painful and hard to perform. A CT scan is important to visualize the intra-articular involvement of the fracture. Minimally displaced fractures may be treated nonoperatively with strict non–weight-bearing until the fracture heals. Fractures associated with displaced articular fragments require surgery in order to restore the smooth contour of the articular surface. They are treated with plates and screws placed medially, laterally, or both. Stabilization of a posteromedial fragment may require a separate posteromedial approach. Since there is often a depression of the cancellous bone, bone graft or bone substitutes, particularly calcium phosphate which resists compression, may be needed to buttress the articular surface and restore the anatomic alignment of the tibia. Patients are kept strictly non–weight-bearing for several months until the fracture begins to heal, though early range of motion is encouraged to prevent stiffness. Repair of ligament or meniscus injuries may also be indicated at the time of surgery. Knee stiffness and osteoarthritis are common complications of these injuries. The goal of the surgery is to restore joint stability and alignment.Tibial Shaft FracturesTibial shaft fractures are the most common long bone frac-tures and occur following high-energy trauma, direct blows, and severe twisting injuries. Trauma and direct blows to the Figure 43-18. Tibial plateau fracture classification.Brunicardi_Ch43_p1879-p1924.indd 189122/02/19 10:40 AM 1892SPECIFIC CONSIDERATIONSPART IItibia result in transverse or comminuted fracture patterns, while torsional injuries cause spiral fractures. Fractures with minimal angulation can be treated with reduction and casting, followed by transition to a functional brace and slow return to weight-bearing. Such fractures may need to be immobi-lized for several months since these fractures can be slow to heal. Most tibial shaft fractures, especially comminuted and angulated fractures, are treated with an intramedullary nail placed down the tibial canal, with interlocking screws placed proximally and distally. Weight-bearing can begin soon after surgery. Proximal third tibial fractures are challenging and can result in malalignment, usually valgus and apex anterior angulation. Knee pain is common after intramedullary rod placement. Plate and screw fixation can also be used; how-ever, since the tibia is subcutaneous, hardware placed along the shaft can increase the risk of wound complications, mak-ing intramedullary nailing the preferred treatment. Fibula shaft fractures often occur along with tibial shaft fractures, though they usually heal well without surgery. Tibial frac-tures, both closed and open, can be associated with compart-ment syndrome. Patients usually have pain out of proportion with swelling of the leg and pain with passive stretch. Com-partment pressure within 30 mmHg of the diastolic pressure is diagnostic of compartment syndrome.Tibial Plafond (Pilon) FracturesThe tibial plafond is the distal tibial articular surface of the ankle joint. Pilon fractures are typically high-energy injuries that usu-ally result from axial compression. These injuries can cause significant soft tissue injury, severely comminuted intra-articular and metaphyseal fragments (Fig. 43-19A,B), and wound heal-ing problems, making these fractures very difficult to treat. Due to the soft tissue injury, these fractures are initially treated with external fixation until the swelling subsides, which may take several days to weeks. The wrinkle test is helpful in this situation to assess when the soft tissues are amenable to defini-tive fixation. A CT scan is usually obtained after the fracture is stabilized by an external fixator. The CT scan will clearly define the fracture fragments and helps in planning the surgical approach and fixation. Minimal incision techniques and mini-mal fixation are becoming popular in some situations. The main goal of surgery is to restore the articular surface. Fixation of the fibula in order to maintain and establish anatomic length is done in some cases. Bone grafts or bone substitutes may be used to fill the void in the metaphyseal region. A variety of fixation techniques may be used including plates to stabilize the metaphysis to the diaphysis. Patients are kept non–weight-bearing for many months until the fracture heals. Despite best efforts, patients may suffer from ankle pain and stiffness, arthri-tis, wound healing problems, infection, nonunion, and some patients may eventually require ankle fusion. Early fixation of pilon fractures with plates can increase the incidence of wound complications significantly.Ankle and Subtalar DislocationsAnkle Dislocations. The ankle joint is a complex hinge joint comprised of the distal tibial plafond, medial malleolus, and lateral malleolus and their articulation with the talus. Several ligaments also contribute to the stability of the ankle joint, including the deltoid ligament medially, the syndesmotic liga-ments between the tibia and fibula, and the anterior talofibular, posterior talofibular, and calcaneofibular ligaments laterally. Dislocations of the ankle joint result from a severe twisting injury and often occur with fractures. At times, dislocations FibulaTibiaTalusABFigure 43-19. A. Tibial pilon fracture with comminution. B. Pilon fracture and its main fracture fragments.Brunicardi_Ch43_p1879-p1924.indd 189222/02/19 10:40 AM 1893ORTHOPEDIC SURGERYCHAPTER 43can place significant pressure on the overlying skin and can cause neurovascular compromise; therefore, prompt reduction is extremely important followed by splinting.Subtalar Dislocations. Subtalar dislocations can be medial or lateral, depending on the position of the foot. The medial dislocation is more common. Lateral dislocations are less com-mon, can be open, and are more likely to be associated with fractures. Irreducible lateral subtalar dislocations may occur from a trapped tibialis posterior tendon, which will block the reduction. The main complication of subtalar dislocations is subtalar arthritis.Ankle FracturesAnkle fractures are very common and result from a twisting injury to the ankle. The patterns of ankle fractures depend on the direction of force and the position of the foot and ankle at the time of injury. The goals of treating ankle fractures are to restore the anatomy of the ankle joint and to restore the length and rota-tion of the fibula. Initial treatment includes closed reduction and placement of a well-padded splint in order to protect the skin. Swelling can be a significant problem, so elevation of the foot is encouraged. Surgery may be delayed until the skin condition permits. Fractures of the ankle may be:1. Isolated malleolar fractures, usually the lateral malleolus or the medial malleolus.2. Bimalleolar fractures that involve the lateral and medial malleolus. Please note that the deltoid ligament may be in-jured instead of the medial malleolus.3. Trimalleolar fractures that involve the lateral malleolus, medial malleolus, and posterior malleolus.Lateral Malleolus Fractures. Isolated fractures of the lateral malleolus with less than 3 mm displacement and no talar shift may be stable. An external rotation stress radiograph or a grav-ity test is used to assess the competency of the deltoid ligament, with the goal of the test to exclude deltoid injury. If the patient has a deltoid injury, in addition to the fibular fracture, then the patient will need surgery. The fracture will require anatomic reduction in order to restore normal ankle joint congruity. The talus can sublux laterally following lateral malleolus fractures, and even 1 millimeter of talar shift decreases the surface contact between the talus and the tibia by 40%, increasing the risk of developing arthritis. Open reduction and internal fixation of the fibula is usually done with plate and screws.Medial Malleolar Fractures. An isolated fracture of the medial malleolus is usually an avulsion-type injury. Minimally displaced fractures can be treated with a cast or walking boot, while displaced fractures are usually fixed with screws.Bimalleolar Fractures. Fractures to both the medial and lat-eral malleoli usually require surgery. These injuries are more unstable, and the talus will often sublux or completely dislo-cate laterally. They are treated by reducing and fixing both malleoli during surgery. Occasionally, the posterior articular surface of the distal tibia, or posterior malleolus, can be frac-tured as well, resulting in a trimalleolar ankle fracture. Often it is a small fragment and does not need to be fixed; however, if it involves a significant amount of the articular surface, the posterior malleolus should be fixed with screws placed either anteriorly, posteriorly, or with an antiglide plate. In all ankle fractures, especially in ones associated with deltoid rupture, a syndesmotic injury should be considered. After the fixation of the fractures, an intraoperative external rotation stress test will diagnose syndesmotic injury.Syndesmosis Injuries. The syndesmosis is comprised of several ligaments between the distal tibia and fibula that pro-vide stability to the ankle joint by resisting axial, rotational, and translational forces. The syndesmosis can be disrupted at the time of ankle fractures and requires special attention (Fig. 43-20). Widening of the space between the distal tibia and fibula after fixing the fractures is indicative of a syndesmo-sis injury, and an intraoperative external rotation stress radio-graph can be helpful for evaluation. Such injuries are treated with one or two screws placed laterally from the fibula into the tibia, parallel to the ankle joint. Patients are kept non–weight-bearing for several weeks. The screws are often removed after 3 to 6 months, though they can be left in place and are typically asymptomatic.Maisonneuve FracturesA Maisonneuve fracture is a fracture of the proximal fibula associated with fracture of the medial malleolus or rupture of the deltoid ligament. There is always an associated syndesmotic injury (Fig. 43-21). Diagnosis may be difficult, and the injury may be missed. These injuries require surgical treatment with fixation of the syndesmosis by screws from the fibula to the tibia.Calcaneal FracturesCalcaneal fractures usually occur following a fall from a height and are often associated with other injuries, including lum-bar spine fractures. There is a high incidence of compartment Figure 43-20. Ankle fracture with syndesmotic injury (white arrow).Brunicardi_Ch43_p1879-p1924.indd 189322/02/19 10:40 AM 1894SPECIFIC CONSIDERATIONSPART IIsyndrome of the foot associated with calcaneal fractures. These injuries are often intra-articular and can result in collapse of the weight-bearing posterior facet of the calcaneus. The Bohler angle, which is normally between 20° and 40°, would be reduced or even flattened. CT scans are useful to better visualize the fracture pattern. Some fractures can be treated nonoperatively in a well-padded splint with patients being kept non–weight-bearing for up to 12 weeks. Displaced intraarticular fractures can be treated surgically once the swelling subsides and the wrinkle test is positive. Surgery can be done with lag screws or with plate and screw fixation. Despite adequate treatment, calcaneal fractures can be debilitating injuries, leading to significant heel pain and arthritis. The outcome of surgery depends on the com-minution of the fracture and degree of articular involvement. The more fragments seen on a CT scan, the worse the outcome for the patient. Wound complications are a problem for calca-neal fractures with the risk being even higher in diabetics, smok-ers, and in open fractures. Open calcaneal fractures have a high rate of amputation.Talus FracturesFractures of the talus commonly result from forced dorsiflexion of the ankle, causing the talar neck to impact on the anterior distal tibia. The dominant blood supply is the artery of the tarsal canal. The blood supply to the talus can be jeopardized after a displaced fracture and may lead to osteonecrosis (Fig. 43-22), which is an unfortunately common complication following talus fractures. The incidence of osteonecrosis depends on the degree of displacement of the fracture. The Hawkin’s sign is a sub-chondral lucency that is seen on the mortise X-ray at 6 weeks and indicates that there is vascularity of the talus. This indicates that there is no avascular necrosis. Nondisplaced fractures are treated with a cast and have a 15% risk of osteonecrosis, while displaced fractures are often treated surgically with screw fixa-tion. There is a high risk of osteonecrosis, ranging from 30% to 100%. Subtalar arthritis is the most common complication from this injury. Varus malunion that results from inadequate reduc-tion is the most preventable complication. This complication leads to a decreased subtalar range of motion and eversion. With varus malunion, the patient will walk with the foot internally rotated.Foot FracturesThe tarsal bones, including the navicular, the cuboid, and the three cuneiform bones, link the hind foot to the metatarsals and provide mechanical stability to the arch of the foot. Isolated fractures to these bones are rare and are often treated nonopera-tively with a cast or boot. Cuboid fractures are also known as “nutcracker fractures” and may indicate a Lisfranc injury. Stress fractures of the navicular can be occult, and a diagnosis may be challenging to make in a patient that complains of foot pain. An MRI may be needed for diagnosis. Treatment is often a short leg non–weight-bearing cast. The Lisfranc ligament, which con-nects the second metatarsal base to the medial cuneiform, is an important stabilizer of the midfoot. Lisfranc injuries can be seen following torsional forces to the foot or from crush injuries. These injuries can be missed and often require surgery because anatomic reduction is extremely important for a successful outcome. Open reduction and internal fixation is the technique used for Lisfranc fractures. Primary arthrodesis is often used for purely ligamentous injuries. The main complication of Lisfranc injuries is posttraumatic arthritis. Metatarsal fractures similarly result from twisting or crush injuries and most can be treated Figure 43-21. Maisonneuve fracture showing proximal fibular fracture and associated ankle injury with disruption of syndesmosis.Figure 43-22. Displaced talar neck fracture. Notice the interrup-tion of the blood supply in the talus.Brunicardi_Ch43_p1879-p1924.indd 189422/02/19 10:40 AM 1895ORTHOPEDIC SURGERYCHAPTER 43nonoperatively with a hard-soled shoe and weight-bearing as tolerated. The base of the fifth metatarsal, however, warrants close attention. Fifth metatarsal fractures at the metaphyseal-diaphyseal junction (fourth and fifth metatarsal articulation) are called Jones fractures. These fractures can jeopardize blood flow, are at risk for nonunion, and may be associated with cav-ovarus hindfoot. Jones fractures need close follow-up to assess for healing if treated by short-leg cast and non–weight-bearing. In athletes and active young patients, screw fixation is usually used to stabilize the fracture. Injuries to the metatarsal-phalangeal joints and phalangeal fractures can be treated symptomatically or with buddy taping with weight-bearing as tolerated in a hard-soled shoe.SPORTS MEDICINEIntroductionSports medicine deals with the prevention and treatment of inju-ries related to sports and exercise. These injuries encompass various areas in the musculoskeletal system. In recent years, sports-related injuries have increased, and the sports medicine field has been expanding. There are multiple factors leading to this increase in sports-related injuries. They include athletes participating in one sport year-round, more “weekend warriors” participating in sporting activity, and increased expectations for higher performance.The orthopedic subspecialty of sports medicine treats a broad spectrum of patients, ranging from children who have just started participating in their first sports to the specialized care of professional athletes. Medical treatment of athletes, recreational or professional, can be complex as shortand long-term outcomes are influenced by the higher demand that athletes put on their bodies. Additionally, the orthopedic sports medicine specialist does not only treat the patient’s injuries but also has to consider the patient’s attempted return to his or her previous level of activity. “Getting back in the game” is sometimes subject to pressure and competing interests from third parties (e.g., team members, coaches, parents, fans). This can make the athlete’s treatment and the rehabilitation a chal-lenging process.Surgical intervention for ligament and cartilage injuries in sports medicine patients is usually done using arthroscopic techniques. The most frequently injured joints are the shoulder, knee, and hip. Therefore, treatment of common injuries in these joints will be the scope of this section.SHOULDERRotator CuffRotator cuff injuries are among the most common reasons to visit an orthopedic sports specialist. Often, these injuries are associated with forceful or repeated overhead and pulling movements. The rotator cuff provides shoulder movement and glenohumeral joint stability, and injuries can typically lead to pain, weakness, and restricted movement of the arm. Over recent years, improvement of surgical indications, operative techniques, and rehabilitation protocols has led to better out-comes. Studies suggest that arthroscopic techniques are equal or superior to open techniques for most indications. Contro-versies surrounding rotator cuff repair remain and include use of acromioplasty, enhancement of healing with orthobiologics (Fig. 43-23), singlevs. double-row fixation, and the treatment ABrotator cuff teargreater tuberosity/RC attachment siterotator cuff repairCFigure 43-23. Imaging and treatment of rotator cuff tears. A. Magnetic resonance imaging coronal T2 image showing a full-thickness and moderately retracted tear (arrow) of the supraspinatus tendon. B. Arthroscopic image showing the supraspinatus tendon tear as viewed from a posterior portal during the surgery. C. Arthroscopic image showing completion of repair of the supraspinatus tendon tear using suture anchors imbedded in the greater tuberosity of the humerus and attached sutures that capture and reduce the torn tendon to its native insertion site.Brunicardi_Ch43_p1879-p1924.indd 189522/02/19 10:40 AM 1896SPECIFIC CONSIDERATIONSPART IIof massive or large tears. Rehabilitation after surgery plays an important role to restore strength, motion, and function and, ultimately, to return the patient to his or her previous level of activity. The standard rehabilitation protocol is made up of three consecutive stages: immobilization, passive exercise, and active exercise. Immobilization can be established by using a sling, and passive exercises should be initiated by the therapist in the first 4 to 6 weeks after surgery. The therapist moves the arm in different positions to improve range of motion (ROM) while providing support. After 4 to 6 weeks, active exercises can be gradually introduced. At 8 to 12 weeks, muscle strength and improvement of arm control are increased by starting a strength-ening exercise program.Shoulder InstabilityThe most common etiology for shoulder instability is related to trauma, especially shoulder dislocation. After a shoulder has dislocated, it becomes vulnerable to repeat episodes of instability and may develop into a chronic problem. Most of the shoulder’s stability is provided dynamically by the rotator cuff and stati-cally by the shoulder capsule and ligaments. The most com-mon dislocation is in the anterior-inferior direction. Typically, patients with an anterior dislocation present with pain and an externally rotated shoulder. Younger patients are more sus-ceptible to suffer from repeat dislocations than older patients. The position of the humeral head with respect to the glenoid and other bony pathology can be identified with radiographs. Views from different angles should be obtained to thoroughly evaluate the patient; an anterior-posterior (AP) view, a glenoid (axillary) view, and a “Y” view of the shoulder are recom-mended in assessing this injury. Immediate reduction of the glenohumeral joint is paramount to the initial treatment of this injury. Repeat radiographs should be attained to ensure that the humeral head is appropriately positioned. As soft tissue struc-tures are typically damaged in these injuries, an MRI can be obtained to evaluate these structures.Relocation of the shoulder is generally accomplished with the patient in supine position and the arm under gentle traction and slight abduction. Some sedation is helpful as it relaxes the patient’s musculature. Whether or not to immobilize a first-time-dislocated shoulder remains controversial, as does the position of immobilization. Additionally, some surgeons argue that early surgical repair of capsulolabral structures is appropri-ate as the recurrence rate in the young population is high and may lead to more extensive bony involvement and ultimately more invasive open procedures.Prolonged immobilization is not recommended because this will often lead to substantial stiffness in the shoulder and does not appreciably decrease the redislocation rate. Unfor-tunately, many patients experience recurrent dislocations, in which case surgical stabilization of the shoulder should be con-sidered. Arthroscopic stabilization procedures have been the gold standard treatment for the majority of injuries related to shoulder dislocations, typically a tear of the anteroinferior cap-sulolabral complex (Bankart lesion). There are a subset of inju-ries, typically involving large glenoid bony lesions, that require more extensive intervention with a Latarjet procedure or bone grafting. After surgery, the shoulder is temporarily immobi-lized with a sling. When the sling is removed, exercises will be started to rehabilitate the shoulder, improve ROM, and prevent scarring. Strengthening exercises will gradually be added to the rehabilitation plan.Posterior Dislocation of the ShoulderPosterior dislocations of the shoulder are rare and could be missed. This dislocation can occur due to electric shock or sei-zures. Examination of the patient will show limitation in exter-nal rotation of the shoulder. The shoulder will be locked in an internally rotated position. The posterior dislocation could be missed on the AP view of the shoulder, and an axillary view should be obtained to avoid missing the injury.Superior Labrum and Biceps TendonThe labrum is a structure that helps to deepen the shoulder socket and stabilize the glenohumeral joint. Additionally, it serves as an attachment point for many of the shoulder ligaments, as well as the long head of the biceps tendon. A superior labrum ante-rior and posterior (SLAP) lesion may occur in the superior part of the labrum, usually anterior and posterior to the attachment of the biceps tendon, with occasional involvement of the biceps tendon in certain cases. Injuries to the superior labrum can be caused by trauma or by repetitive shoulder motion, such as in throwing athletes. Radiographs are generally obtained to evalu-ate for concomitant bony injuries or osteoarthritic changes. The labrum itself, and other soft tissue, is better visualized with MRI with addition of a gadolinium arthrogram adding sensitivity for labral injury detection (Fig. 43-24). A coronal view MRI will clearly show the condition of the superior labrum.Conservative and operative treatments have had mixed results depending on the patient’s age, activity level, type of tear, and presence of concomitant injuries. If symptoms do not improve with adequate physical therapy and/or nonsteroidal anti-inflammatory drugs (NSAIDs), surgical intervention is usu-ally indicated. Some SLAP injuries involve the biceps tendon, which may require either tenotomy or tenodesis.After surgical repair, the shoulder needs to be immobilized to protect the repair and allow for healing. Usually a sling is used for 4 weeks after surgery. Then a physical therapy program will gradually start improving range of motion and prevent scar formation and stiffness from developing. As healing progresses, exercises to strengthen the shoulder muscles and the rotator cuff will gradually be added to the program typically around 4 to 6 weeks after surgery. Return to early interval throwing can generally be allowed around 3 to 4 months after surgery.Impingement SyndromesAfter minor trauma or repetitive injury, patients may experi-ence pain and discomfort which can be due to irritation of the tissues in the subacromial space. In many cases these shoulder impingement syndromes are caused by simple bursitis or ten-donitis of the long head of the biceps or supraspinatus tendon. Occasionally, impingement syndromes can progress to tears of the supraspinatus tendon, which can be confirmed by MRI or ultrasound.The goal of treatment is to reduce pain and restore func-tion. Initial treatment is generally nonsurgical and involves rest, NSAIDs, and physical therapy. If pain is not adequately relieved, an injection of a local anesthetic and corticosteroid may be helpful, for both therapeutic and diagnostic purposes.If conservative treatment does not relieve pain, surgery is recommended, with the goal to excise the bursa and create more subacromial space. Generally, surgery is performed arthroscopi-cally and encompasses bursectomy and subacromial decompres-sion via acromioplasty. If the rotator cuff (supraspinatus tendon) is also injured, arthroscopic repair is usually indicated to restore Brunicardi_Ch43_p1879-p1924.indd 189622/02/19 10:40 AM 1897ORTHOPEDIC SURGERYCHAPTER 43function and can be accompanied by a bony resection of the inferior portion of the acromion.The Acromioclavicular JointThe acromioclavicular joint is a gliding synovial joint com-prised of the lateral end of the clavicle and medial facet of the acromion, and it has limited mobility. The joint is stabilized by three ligaments: the superior acromioclavicular ligament, the inferior acromioclavicular ligament, and the coracoclavicular ligament. Injuries to these ligaments are commonly sustained by a lateral blow to the shoulder while playing contact sports such as football and ice hockey and may cause displacement of the joint. An acromioclavicular sprain is also referred to as a shoul-der separation. The least severe, types I and II, are typically treated conservatively. Treatment of type III injuries, where the clavicle is displaced up to 100%, is controversial. Some advo-cate for early surgical intervention, while others recommend symptomatic treatment followed by ligament reconstruction if symptoms persist. Types IV to VI, where the coracoclavicular ligaments are completely torn and the clavicle is significantly displaced, are often treated surgically.KNEEThe knee is the largest joint in the human body and is a pivotal hinge joint, which allows flexion and extension as well as some medial and lateral rotation. The knee bears tremendous axial loads as well as torsional and sheer forces, making it vulnerable to both acute injury and the development of osteoarthritis. In sports, the major stabilizing structures such as the ACL and the medial collateral ligament (MCL) are frequently injured. Other common knee injuries involve the menisci, posterolateral corner (PLC), posterior cruciate ligament (PCL), and patellofemoral joint.MenisciThe menisci are crescent-shaped pieces of fibrocartilage that provide joint stability, shock absorption, load distribution, and proprioception to the knee. Sudden meniscal tears often happen during sports, usually during contact or twisting injuries to the knee. Symptoms associated with a meniscus tear include pain, swelling, stiffness, catching, and locking of the knee. Radio-graphs are typically obtained to assess for a concomitant bony injury, the presence of (early) osteoarthritis, and leg alignment abnormalities. However, since menisci are radiolucent and are not seen on radiographs, an MRI is obtained to assess the status of the menisci and the soft tissue surrounding the knee joint (Fig. 43-25). Small tears on the outer edge of the meniscus may not cause symptoms, and provided the knee is stable, nonsurgi-cal treatment may be sufficient.The most commonly performed surgical procedure for meniscus tears is partial (subtotal) meniscectomy. However, it has become increasingly clear over recent years that pres-ervation of the load-distributing function of the meniscus is important in preventing the development of early osteoar-thritis. Research into the use of orthobiologics (e.g., micro-fracture of the notch, fibrin clot) for meniscal repairs has expanded the indications for repair rather than excising the torn fragment, especially if the fragment is large. Tears have been reported in virtually all portions of the meniscus, with radial and longitudinal tears being the most common. Menis-cal root tears are less common, but they are increasingly being recognized as devastating injuries that cause serious alterations of knee contact forces. Surgical techniques are developing to repair the root to restore its function. Meniscus transplantation may be an option for young patients with a largely deficient meniscus.ABLIGHTlabral repairglenoidhumeralheadCFigure 43-24. Imaging and treatment of a shoulder glenoid labrum tear. A. Magnetic resonance imaging axial T1 image showing a tear of the posterior superior labrum (arrow). B. Arthroscopic image with the patient in the lateral decubitus position showing detachment of the torn labrum away from the glenoid. C. Arthroscopic image demonstrating repair of the labrum to its attachment site using anchors in the glenoid and sutures that fixes the labrum to the glenoid.Brunicardi_Ch43_p1879-p1924.indd 189722/02/19 10:41 AM 1898SPECIFIC CONSIDERATIONSPART IIThe paradigm of treatment of torn menisci is shifting thanks to the development of superior surgical techniques, use of orthobiologics, and promising first results with root repair and meniscus transplantations. Nowadays, physicians are well informed on the significance of meniscal preservation when there is potential for healing.Directly after surgery, the knee is immobilized with a brace and weight-bearing is protected to allow the meniscus to heal. When healing is complete, range of motion and strength will need to be regained. Physical therapy is an integral com-ponent of healing and return to play, which usually is allowed between 4 and 6 months after surgery.Collateral LigamentsThe MCL is the most frequently injured knee ligament, which usually occurs after excessive valgus stress of the knee. In more severe injuries, tearing of the meniscus and ACL can also occur, which is known as the “unhappy triad.” This is most often seen in contact sports with a lateral blow to a planted leg, causing a significant valgus force.The MCL has good healing potential, and grade I and II injuries usually improve with bracing and activity modifica-tion. Grade III injuries may also improve with conservative treatment, and often these injuries are initially treated non-operatively. The majority of MCL injuries occur in the mid-substance or at the femoral insertion side. There is a small subset of tibial-sided grade III tears that are associated with worse clinical outcome following conservative treatment, and therefore surgical repair is often recommended. Recon-struction is rare because surgical repair is usually effective in restoring the MCL. LCL injuries are much less common than MCL ligament injuries, but, similarly, most are man-aged conservatively.With return of range of motion and normal gait pattern, patients are functionally progressed towards return to sports. A functional brace during sports is often advised.Cruciate LigamentsThe cruciate ligaments are situated centrally within the intercon-dylar notch of the knee. The biomechanical function of both the ACL and the PCL is complex and three-dimensional, but both play an important role in providing anteroposterior and rota-tional stability of the knee.ACL tears are a common sports injury, especially in sports involving sudden stopping and cutting (e.g., soccer, basketball) or contact (e.g., football). A torn ACL will result in altered knee biomechanics and kinematics and thus can potentially lead to the early development of degenerative changes. Since a torn ACL will not heal on its own, surgical ACL reconstruction is generally the treatment of choice in patients who are young and active. Patients with a more sedentary lifestyle and who experi-ence no persisting or disabling instability in daily life may be effectively treated with conservative management (i.e., bracing and physical therapy).ABCFigure 43-25. Imaging and treatment of a knee lateral and meniscus tear. A. Magnetic resonance imaging sagittal T2 image of the knee showing a displaced bucket-handle lateral meniscus tear (arrow). B. Arthroscopic image showing the remnant rim of the lateral meniscus prior to reduction and fixation of the torn bucket-handle fragment. C. Arthroscopic image after the torn segment is reduced and fixed to the remaining meniscus and the lateral capsule using suture.Brunicardi_Ch43_p1879-p1924.indd 189822/02/19 10:41 AM 1899ORTHOPEDIC SURGERYCHAPTER 43A patient with an ACL tear typically presents with pain and swelling, instability, loss of ROM, joint line tenderness (if there is an associated meniscus injury), and discomfort while walking. The Lachman’s exam is the best clinical test for an ACL tear. Radiographs are obtained to evaluate joint condi-tion and possible associated osseous injuries. To visualize the ACL and other soft tissue in the knee, an MRI should be obtained. Although an MRI is not required to make the diag-nosis, the information it provides is invaluable with regard to objectifying anatomic characteristics by taking measurements, assessing concomitant injuries, and presurgical planning in gen-eral (Fig. 43-26).Reconstruction is performed with use of a tendon-graft that will replace the native ACL. Commonly used graft sources include the patellar, hamstrings, and quadriceps tendons. These tendons can be harvested from the same knee (i.e., autografts) during the same procedure. Alternatively, a cadaver graft (i.e., allograft) can be used. Both have their associated benefits, including the absence of donor site morbidity with an allograft and better healing potential with an autograft. As such, it is important to have a discussion with the patient and provide the necessary information for them to make an informed decision regarding graft type.Injuries of the PCL are less common than other knee ligaments. Frequently seen causes are a bent knee hitting a dashboard in a car accident or falling on a knee that is bent during running. A rupture of the PCL is usually better tolerated than ACL rupture, since many tears (i.e., grades I and II) have the potential to heal on their own and do not result in much knee instability. Most grade I and II injuries are treated non-operatively. Combined PCL/PLC, PCL/MCL, and grade III PCL injuries do present a challenge with regard to appropriate management. Chronic PCL-deficient (grade III) knees have an increased incidence of osteoarthrosis, particularly in the patel-lofemoral and medial knee compartments. Indication for sur-gery is influenced by age, activity level, and the presence of concomitant injuries. Different surgical techniques have been proposed; the most common are the “inlay” technique and the transtibial technique.The goal of cruciate ligament (both ACL and PCL) reconstruction is to restore native knee kinematics, provide the patient with the best potential for a successful outcome, and to prevent the development of long-term complications, such as osteoarthrosis.Posterolateral CornerCritical structures of the posterolateral corner are the LCL, pop-liteus tendon, and popliteofibular ligament. These structures each contribute to the static and dynamic stability of the knee and are commonly seen in combination with other ligamentous injuries, most notably the ACL. It is important to evaluate the PLC after any knee injury as a deficient PLC causes altered knee biomechanics and subsequently increases the stress on sur-rounding stabilizing structures. As such, it has been shown that a deficient PLC is a primary cause of graft failure in cruciate ligament reconstruction.Acute high-grade injuries of the PLC with obvious defi-cient structures require surgical intervention. Since primary repair becomes increasingly difficult as time between injury and surgery increases, a cut-off of 2 to 3 weeks is usually the limit to repair the deficient structures. With more chronic PLC injuries or midsubstance tears, reconstruction is recommended to restore knee stability.HIPFemoroacetabular ImpingementFemoroacetabular impingement (FAI) is a pathologic condi-tion that refers to impingement of the anterior femoral head-neck junction against the anterosuperior acetabular labrum. This is frequently caused by abnormal bony offset at the femoral head-neck junction and is called CAM impingement, which usually affects young males. On the other hand, a Pincer lesion usually occurs due to abnormal acetabular version and excessive anterolateral acetabular bony rim coverage, or a combination of these, which usually occurs in females. Recognition of FAI can be clinically and radiologically dif-ficult. However, familiarity with this disorder is essential AxyzBCDEFigure 43-26. Magnetic resonance imaging of a torn anterior cruciate ligament (ACL). A–C. Proton density sagittal cuts, showing antero-posterior tibial insertion site length measurement “x,” intra-articular ligament length measurement “y,” and ACL inclination angle measure-ment “z.” Oblique (in the same plane as the ACL runs) coronal cuts showing a complete ACL tear with separate images of a PL bundle tear (D) and an anteromedial bundle tear (E).Brunicardi_Ch43_p1879-p1924.indd 189922/02/19 10:41 AM 1900SPECIFIC CONSIDERATIONSPART IIbecause FAI can lead to labral tears, cartilage delamination, and, if untreated, osteoarthritis.Commonly, patients present with anterior groin pain exacerbated by activities involving hip flexion or pain over the greater trochanter, as well as grinding or popping. Patients report pain with flexion and internal rotation, and after pro-longed sitting. On examination, there is a decrease in internal rotation that appears out of proportion to the loss of the other ranges of motion, and flexion can also be limited. The impinge-ment test, elicited by 90° of flexion and adduction and internal rotation of the hip, is almost always positive, signified by pain in the groin region.The imaging findings of FAI can be seen on plain radio-graphs, CT scan, MRI, and magnetic resonance angiography. Some of the abnormalities seen include abnormal lateral femo-ral head/neck offset seen as a lateral femoral neck bump, os acetabuli, synovial herniation pits, acetabular over-coverage, hyaline cartilage abnormalities, and labral tears.Treatment of FAI has traditionally been surgical and has evolved from open surgical treatment with acetabuloplasty, to combined open-arthroscopic–assisted techniques, to all arthroscopic techniques. Hip arthroscopy is becoming increas-ingly popular and is being more frequently applied for this indi-cation. This popularity is largely the result of studies reporting on improvement of functional outcome measures with follow-up of 10 years in some studies and with relatively low compli-cation rates.SPINESpinal TraumaIn spinal injury, spinal stability must be assessed and the patient immobilized until the spine is cleared. CT scan is more reliable in assessing spine injury than plain radiographs. In patients with ankylosing spondylitis, an MRI is the best study to rule out occult fracture and epidural bleeding. When neurologic deficits are present a decompressive procedure may be indi-cated. In spinal cord compression, prompt decompression should be performed. Spinal cord injuries should be triaged to trauma centers since trauma center care is associated with reduced paralysis.Occipital Cervical DislocationMotor vehicle accidents can cause dislocation of the occiput on the condyles of the atlas (C1). Most patients with this injury suffer cervical cord injury and do not survive. Traction on the spine is contraindicated. Treatment consists of stabilization and fusion in situ using a screw plate from the mid cervical spine to the occiput.Fractures of C1 (Jefferson Fracture)Fracture of the C1 ring was described by Jefferson in 1920. The thin anterior and posterior rings of the C1 vertebra fracture with axial loads. C1 fracture causes the lateral masses of C1 to spread, which can be visible on an open-mouth view. A lateral view of the C-spine may show the fracture; however, this injury could be missed due to inadequate visualization of the occipitocervical junction. CT scan is the ideal study for a Jefferson Fracture. The transverse ligament may be ruptured with a Jefferson fracture, and this will render the fracture unstable, which can cause injury to the spinal cord (Fig. 43-27). Jefferson fractures may be associ-ated with other spine fractures. This injury is rarely associated with neurologic injury. The treatment of a Jefferson fracture is based on the integrity of the transverse ligament. The integrity of the transverse ligament is assessed by the amount of C1 lat-eral mass displacement determined by open-mouth radiograph and CT scan. Significantly displaced fractures (less than 7 mm) indicate disruption of the transverse ligament. An increase in the atlanto-dense interval (ADI) may indicate a transverse ligament injury. Normally, the ADI is less than 3 mm, as seen on the lat-eral view. An unstable injury with a rupture of the transverse ligament may need a posterior C1-C2 fusion.Bracing with a cervicothoracic orthosis or a halo ring and vest is the recommended treatment for nondisplaced and mini-mally displaced fractures; significantly displaced unstable frac-tures require more definitive surgical treatment.Fractures of C2 (Odontoid Fracture)Half of normal cervical rotation occurs at the atlantoaxial joint. The odontoid (Dens) is a small bony process which arises from the body of C2, and articulates with the body of C1 (the Atlas). There are three types of odontoid fractures (Fig. 43-28). Type I fractures are the most common and are avulsion fractures off the tip of the dens. Type I fractures occur when there is tension applied to the alar ligaments (which span from the tip of the odontoid to the skull bypassing the C1 vertebra). Type I frac-tures are stable and managed nonoperatively.Type II fractures, at the base of the odontoid, results from lateral loading forces. Operative stabilization in patients with a high risk of fracture nonunion is the preferred treatment since immobilization in a halo vest results in nonunion rates ranging 89Figure 43-27. Jefferson fracture with and without ligamentous injury. Note the increased ADI and the potential compression of the spinal cord (orange color).Brunicardi_Ch43_p1879-p1924.indd 190022/02/19 10:41 AM 1901ORTHOPEDIC SURGERYCHAPTER 43from 20% to 80%. The risk of nonunion includes displacement greater than 5 mm, angulation greater than 10 degrees, age over 50 years, smoking, and delayed diagnosis more than 4 weeks. Nonunion occurs due to interruption of the blood supply. Trans-fixing the odontoid fracture with a screw maintains rotational movement. Posterior fusion of C1 on C2 is another option, but this results in decreased cervical spine rotation; 50% of rotation of the cervical spine comes from C1 and C2 joint.Type III fractures extend into the body of C2, below the origin of the odontoid process. The cancellous bone is rich in blood supply and usually heals well. Type III fractures are gen-erally treated with a halo brace.Hangman’s Fractures of C2Hangman’s Fractures are a bilateral fracture of the pars inter-articularis (Fig. 43-29). The spinal canal is usually widened, and neurological deficits rarely occur (Fig. 43-30). It results from sudden extension forces on the neck. Treatment is simple immobilization in a halo vest. Higher energy injuries causing severe extension forces can dislocate the C2-3 facet complex and damage the C2-3 disc. Significantly displaced Hangman’s fractures are managed by internal fixation and bone grafting between C2 and C3. When the fracture is severely angulated, it may indicate a flexion distraction injury, and traction on the C-spine may exacerbate the injury.Compression Fracture of the Cervical SpineIn C3 to C7 an axial load can cause fracture of the endplate while preserving the posterior cortex of the vertebral body. These fractures generally heal well and are treated nonopera-tively with analgesics and a cervical brace.Burst Fractures of the Cervical SpineBurst Fractures of the cervical spine usually result from axial loads such as in diving and motor vehicle accidents. The injury results in displacement of bony fragments into the canal, injur-ing the spinal cord. Burst fractures are treated surgically by anterior decompression (corpectomy) and reconstruction using a bone graft strut stabilized with a plate and screws.Unilateral and Bilateral Facet DislocationThis injury is usually associated with motor vehicle accidents. A restrained passenger can suffer forced flexion with distrac-tion resulting in dislocation of the facets. The diagnosis can be made on lateral radiographs. Unilateral facet dislocation can be missed on an X-ray. It usually shows less than 25% sublux-ation on an X-ray, and it affects the nerve roots. Bilateral facet dislocation will have more than 50% subluxation on an X-ray and may cause severe spinal cord injury. Treatment consists of closed reduction with axial traction utilizing cranial tongs, grad-uated application of weight, and periodic X-rays. The patient is kept awake for safety concerns. A closed reduction should not be done if the patient is not awake. Facet dislocations could be associated with disc herniation. An MRI is the study of choice to rule out disc herniations and should be done prior to reduc-tion in an unconscious patient or prior to open reduction and/or surgical fixation. When a reduction is obtained, the patient is taken to surgery for fusion, which may be performed anteriorly Figure 43-28. The three types of Odontoid fractures.Figure 43-29. Lateral view shows displaced hangman’s fracture.Figure 43-30. Hangman’s fracture cross-section view shows wid-ening of the canal, and therefore the spinal cord is not affected.Brunicardi_Ch43_p1879-p1924.indd 190122/02/19 10:41 AM 1902SPECIFIC CONSIDERATIONSPART IIor posteriorly. Anterior surgery is necessary if the patient has an associated herniated disc.Clay-Shoveler’s InjuryClay-shoveler’s injury can result from a motor vehicle accident or from shoveling soil or clay. The injury (of C6, C7, T1, and T2) is the result of avulsion fracture of the spinous process by the paraspinal muscle forces (Fig. 43-31). The fracture is treated nonoperatively with analgesics and a soft collar.FRACTURES OF THE THORACIC AND LUMBAR SPINEThoracic Lumbar Spine InjuryThe ribs stabilize fractures of the thoracic spine, making these fractures more stable than similar fractures of the lumbar spine. Neurologic injuries are more common in the thoracic and proxi-mal lumbar spine because of the presence of the spinal cord, which ends at the L2 level, as well as the small spinal canal diameter of the thoracic spine.Compression FractureCompression fractures result from osteoporosis as well as trauma. Compression fractures involve a fracture of the anterior part of the vertebral body without associated posterior cortex fracture. Thoracolumbar compression fractures are treated non-operatively with braces and analgesics.Burst FractureBurst fractures are caused by falls and high-energy automo-bile accidents. The posterior cortex fracture (middle column involvement) differentiates the burst fracture from a compres-sion fracture. The injury may be associated with neurological deficits due to retropulsion of bone into the canal. A vertical lamina fracture may contain an invaginated segment of the dura mater with accompanying nerve root injury and dural tear. Wid-ening of the pedicle in an AP view of the spine will indicate a burst fracture. CT scan will define the bony injury, and an MRI will show compression of the neural elements and any injury to the posterior ligaments.Treatment is nonoperative with an orthoses and mobiliza-tion of the patient if the fracture is stable. Surgery is done for decompression and destabilization of the spine if the patient has neurologic deficits or if the fracture is unstable.Seatbelt Injuries (Flexion Distraction Injuries)A seatbelt injury occurs when there is acute forward flexion of the trunk and anterior (i.e., seatbelt) restraint. The pelvis and upper torso move forward, and failure of the spine under tension begins with the posterior elements. Tearing of the dorsal fascia, the interspinous ligament, dislocation of the facets, and tearing of the discs occurs. Seatbelt injury may be bony or ligamen-tous (Fig. 43-32). The bone of the spinous process, the lamina, the pedicles, and the vertebral body fail in tension (“chance Figure 43-32. Seatbelt injuries (flexion-distraction injuries) can be bony or ligamentous.Figure 43-31. Fracture of the transverse process of C6 or C7.Brunicardi_Ch43_p1879-p1924.indd 190222/02/19 10:41 AM 1903ORTHOPEDIC SURGERYCHAPTER 43fracture”). The bony injury could be stable. Flexion distraction injuries involving the soft tissue, with injury to the posterior spine elements, are usually unstable. This unstable injury will require internal fixation and fusion with bone grafting. This spine injury may be associated with a colon injury, especially in children.Fracture Dislocations of the SpineFracture dislocations of the spine displace the bony elements by translation or rotation, resulting in canal narrowing and nerve injury.Reduction of the displaced bones is the best way to improve the canal dimensions.Patients with fracture dislocations of the spine and par-tial nerve function can recover. Fracture dislocations are treated operatively with surgical stabilization.Disc HerniationDisc herniation, most common between ages of 20 and 50, can occur in the cervical, thoracic, or the lumbar spine, and consists of a tear of the annulus allowing the nucleus pulposus material to extrude through the annulus and enter the canal, pressing on the exiting nerve or the “traversing” nerve roots. In the cervical spine, spinal cord compression can occur.Symptoms of most disc herniations resolve within 8 weeks as the nerve root accommodates and inflammation recedes. The bulk of the extruded nucleus pulposus resorbs over time. When symptoms persist beyond 6 to 8 weeks, surgery with excision of the involved disc and decompression of the nerve roots may be indicated.In cervical disc herniation, an anterior approach to the spine is performed with dissection through a transverse incision on the neck. Dissection is carried between the trachea, esopha-gus medially, and the carotid sheath laterally. The disc is then removed. The disc space is usually filled with bone graft to fuse the vertebrae. A locking screw low profile titanium plate is then attached to the vertebrae.Posterior decompression and laminotomy exposes the pos-terior elements of the spine. A portion of the lamina is removed to allow access to the canal to correct foraminal impingement or to remove lateral disc herniations. While the posterior approach does not require fusion with plates and screws, central disc her-niation cannot be managed through a posterior approach since the spinal cord cannot be safely retracted.In thoracic spine disc herniation, the posterior approach is contraindicated because it may lead to paralysis.For lumbar disc herniation, a midline incision is used, and laminotomy allows visualization of the lateral recess. Retraction of the dura allows visualization of the traversing nerve roots as well as of the disc fragment.Cauda Equina SyndromeCauda equina syndrome is uncommon and occurs from a central disc herniation (Fig. 43-33). This can be a difficult diagnosis to make; however, it is a true emergency, and a delay in diagnosis can lead to permanent impairment. The patient will complain of back pain with bilateral leg pain. Bladder and bowel diffi-culty such as incontinence and frequency, saddle anesthesia, decreased perianal sensation, impotence, diminished rectal tone, and motor deficits. MRI will show a central disc herniation. Treatment is with urgent diagnosis and urgent surgical decom-pression. The results are better if the decompression is done within 48 hours of onset of symptoms. A central disc herniation causing cauda equina should be differentiated from a postero-lateral disc herniation. The posterolateral disc herniation usu-ally affects a nerve root and can be treated conservatively, at least initially. In the case of central disc herniation, it affects the cauda equina (the lumbosacral nerve roots), and this is a surgical emergency. Spontaneous recovery does not occur, and the outcome is catastrophic, including permanent loss of bowel and bladder control as well as the ability to have an erection if treatment is delayed.Spinal StenosisA loss of hydration of the discs causes loss of disc height and bulging of annular tissue and the ligamentum flavum, which effectively narrows the canal (spinal stenosis). Osteophyte for-mation on the facet joints can also cause nerve impingement. Cervical stenosis can cause myelopathic symptoms (hyper-reflexia, problems with fine hand dexterity, balance problems resulting in gait disturbance, weakness, and pain). In patients with low back pain and gait disturbance, obtain an MRI of the cervical spine to rule out cervical myelopathy. Pathology of the lumbo-sacral spine does not cause gait disturbances.Lumbar stenosis causes neurogenic claudication (pro-gressive pain, weakness, and numbness in the legs). The clau-dication symptoms result from standing and walking, which increases lumbar lordosis. Extension of the spine decreases the spinal canal diameter as well as the foramen size and worsens the condition. The symptoms resolve with sitting and bending forward (i.e., over a shopping cart) (Fig. 43-34). Flexion of the spine increases the spinal canal diameter as well as the foramen size and decrease the symptoms. The patient may have a normal neurologic exam, and it is important to study the vascular status of the patient and differentiate between neurologic and vascular claudication. Examine the pulses, prescribe a noninvasive vas-cular study if necessary. In general, walking causes the symp-toms for both conditions, and standing relieves the vascular claudication symptoms. Spinal stenosis is treated with NSAIDs, epidural steroid injections, and physical therapy. Resistant cases may require surgical decompression.Spinal stenosis usually occurs in patients over 50 years of age. With degenerative spondylolisthesis or scoliosis, fusion with instrumentation is usually required to prevent progression of the deformity.Figure 43-33. Image showing central disc herniation affecting the cauda equina and the classic posterolateral disc herniation affecting a nerve root.Brunicardi_Ch43_p1879-p1924.indd 190322/02/19 10:41 AM 1904SPECIFIC CONSIDERATIONSPART IIBack Pain and Degenerative Disc DiseaseBack pain occurs in the majority of adults but is usually self-limited, resolving in 1 to 2 weeks. Chronic unremitting back pain may suggest the possibility of infection, malignancy, or metastatic disease.While radiographs are one option in the management of disabling low back pain, they are ineffective at ruling out malig-nancy, and radiographic findings correlate poorly with symp-toms. Patients with severe degenerative symptoms may have no pain, while others with mild degenerative findings complain of severe pain. The potential for secondary gain and psychiatric problems and the unpredictable results of spine fusion add to the difficulty of diagnosis and choosing a treatment plan.Intervertebral disc replacement prostheses are experimen-tal in the treatment of degenerative disc disease. The potential for loosening, creation of wear debris, and bone loss complicat-ing revision surgery are concerns, as are the proximity of the device to the spinal canal and the great vessels.ScoliosisScoliosis is a lateral curvature of the spine. Lateral bending of the spine is always accompanied by rotational deformity (coupling).In order to measure the severity of scoliosis, lines are drawn along the endplates of the vertebral bodies at either end of the curve, and the angle formed when these lines intersect determines the magnitude of the curve.Scoliotic curves are classified as congenital, degenera-tive, metabolic (mucopolysaccharidoses), neurogenic (cerebral palsy), and myogenic curves (muscular dystrophy). Idiopathic scoliosis is the most common form and represents a spectrum of genetic disease.Adults with scoliosis may present with axial pain and imbalance in posture. Treatment for scoliosis may include anti-inflammatory medications, therapy, and activity modification. In severe cases with objective deformity, surgical correction of the deformity may be indicated.Idiopathic ScoliosisThe majority of idiopathic scoliosis curves become apparent during adolescence and progress during skeletal growth. Ini-tial management consists of observation. Rapidly progressing curves are treated with braces. Brace treatment is recommended for curves between 20 and 40 degrees. For patients with large curves, surgical intervention may be needed using rods with grafting and fusion.Neuromuscular ScoliosisNeurologic conditions such as polio and cerebral palsy can lead to “uncompensated” scoliosis curves where the patient is unable to lean with his upper body to restore balance. Scoliosis correc-tion surgery may be needed to facilitate sitting balance and to avoid skin breakdown caused by pelvic obliquity.JOINT RECONSTRUCTIONIntroduction to ArthritisArthritis refers to a large number of medical conditions, includ-ing osteoarthritis, rheumatoid arthritis, septic arthritis, and post-traumatic arthritis. Each has the potential to lead to loss of articular cartilage lining the joints. According to the CDC and the National Health Interview Survey, approximately 55 million adults (22% of the U.S. population) have been diag-nosed with some form of arthritis. This number is pro-jected to grow to an astounding 67 million adults by 2030 (or 25% of the U.S. population).Arthritis causes pain, loss of range of motion, decreased ability to perform work duties or participate in social functions, and decreased quality of life. The number of individuals suffer-ing from arthritic conditions will continue to rise as the “baby boomer” generation enters old age and the prevalence of obesity rises in the U.S. population, as age and obesity are two major factors in the onset of arthritis.Examination of the PatientA thorough history and physical examination is indicated for all orthopedic patients. Patient history should include loca-tion, quality, severity, timing, and radiation of pain along with any referred pain, associated signs and symptoms, modify-ing factors, or prior treatments, including both conservative and surgical measures. Other details within the history and physical examination are equally important in establishing a diagnosis and successfully developing a treatment plan. If you listen carefully to your patients, they will often tell you their diagnosis.For example, location of “hip pain” can narrow a dif-ferential diagnosis. Patients with activity-related groin pain often are found to have hip arthritis, whereas patients with 10Figure 43-34. Person is seen bending over shopping cart to improve symptoms.Brunicardi_Ch43_p1879-p1924.indd 190422/02/19 10:41 AM 1905ORTHOPEDIC SURGERYCHAPTER 43peritrochanteric pain (lateral hip pain) may be suffering from trochanteric bursitis. The importance of listening and focusing on the patient’s description of location and type of pain cannot be overemphasized.Physical examination should begin by observing the patient’s gait, both with and without assistive devices if pos-sible. This demonstrates the extent of the patient’s functional deficit and the effect of the patient’s pain. Typical gait pat-terns include antalgic gait due to pain, or a “Trendelenburg gait” (Fig. 43-35) where abductor weakness may lead to a poor outcome following total hip arthroplasty. Other aspects of the exam include assessment of leg length discrepancy, joint con-tractures, skin changes, assessment for prior surgical incisions to identify prior treatments or plan future surgical approaches, neurovascular status, and strength, as well as range of motion. These details document functional status and help to formulate a differential diagnosis. Patients with “hip pain” may have lumbar spinal stenosis, radiculopathy, or vascular disease that may play a large role in their presentation. Once an appropriate physi-cal examination is performed, weight-bearing radiographs are needed. Advanced imaging, including CT and MRI, are rarely indicated in the initial workup. Once a diagnosis is made, spe-cific treatment directed towards the patient’s condition can be initiated. The goals of treatment are to improve pain, preserve motion, and maximize patient function, independence, and qual-ity of life.Nonoperative Management and Prevention of ArthritisNonoperative measures to treat arthritis include weight loss, activity modification, rest, physical therapy, NSAIDs, bracing, and assistive devices such a cane or walker. These treatments have the potential to decrease symptoms and improve function and quality of life. For example, holding a cane on the opposite side of the symptomatic extremity reduces the forces across the hip joint and subsequently decreases hip pain (Fig. 43-36). In nearly all cases, it is best to treat patients nonoperatively prior to recommending surgery.Health and exercise can also play a role in the prevention of arthritis. Weight loss of as little as 11 lbs (5 kg) has been shown to decrease the risk of developing knee osteoarthritis in 11women by 50%. Similarly, patients who engage in regu-lar physical activity have a lower incidence of arthritis. However, despite nonoperative treatment, surgical intervention may be required to effectively manage patient symptoms.InjectionsJoint injections are commonly performed into the knee and shoulder. Common injections into the knee include corticoste-roids and hyaluronic-acid gels. Corticosteroid injections can decrease inflammation within the joint. These injections are usually administered in combination with a local anesthetic, such as lidocaine, in order to provide more immediate relief for both diagnostic and therapeutic purposes. If the patient has immediate relief of pain with injection of the joint, this localizes the source of the patient’s pain to the joint and may assist with diagnosis. Diagnostic hip injections are particularly helpful in distinguishing pain resulting from hip versus lumbar spine pathology. Any benefit received is therapeutic for the patient. Hyaluronic acid injections in the knee are frequently used and are commonly referred to as “viscosupplementation.” The viscosity of the synovial fluid is increased by hyaluronic acid, but its role and mechanism are not well defined yet. There is a risk of joint infection, cartilage injury from the needle, hemarthrosis, and failure to receive benefit. Short-term altered glucose metabolism in diabetic patients is common with cor-ticosteroid injections. The efficacy of hyaluronic acid injec-tions has been questioned by recent evidence summarized in the American Academy of Orthopaedic Surgeons’ Clinical Practice Guidelines.Figure 43-35. Trendelenburg Gait resulting from weakness of abductor muscles.Figure 43-36. Holding the cane on the opposite side of the pathol-ogy is beneficial in decreasing arthritis pain in the hip.Brunicardi_Ch43_p1879-p1924.indd 190522/02/19 10:41 AM 1906SPECIFIC CONSIDERATIONSPART IISurgical Management of ArthritisThe most commonly performed procedure for arthritis of a major joint is arthroplasty, or joint replacement. Joint replace-ments, including hip and knee arthroplasty, are considered two of the most successful procedures performed in all of surgery. However, nonarthroplasty options exist and are typically per-formed for certain indications and goals.Osteotomy. Osteotomy is cutting of the bone to change the position of the fragments, thereby improving rotation, align-ment, or angulation. Osteotomy can be performed for both con-genital and acquired deformities that contribute to the patient’s pain or development or progression of disease. Pelvic and femo-ral osteotomy can be utilized in the treatment of developmen-tal dysplasia of the hip. The position of the acetabulum can be altered with pelvic osteotomies in order to provide more appro-priate coverage of the femoral head, which is typically deficient anteriorly and laterally. Femoral osteotomies can be performed to correct version and varus/valgus deformity of the femoral neck. Osteotomies are performed to obtain more normal align-ment and coverage of the femoral head within the acetabulum to prevent or delay future disease.An osteotomy commonly used in the knee is a proxi-mal tibia osteotomy. An adult patient who presents with iso-lated medial compartment knee arthritis and associated varus deformity would be a candidate for a valgus-producing (high tibial) osteotomy. An osteotomy that realigns the knee into slight valgus has the potential to off-load the medial com-partment, slow disease progression, and prevent or delay the need for further procedures (unicompartmental or total knee arthroplasties).Arthrodesis. Arthrodesis is a treatment option for severe arthritis where the overlying articular cartilage is removed and two opposing bones heal together with the use of hardware (internal or temporary external fixation) often supplemented by bone graft. After successful arthrodesis, no motion is possible through the joint and the source of pain is removed. Arthrodesis of large joints, such as the knee, shoulder, or hip, are typically explored as an option in the face of infection, in older adult, low-demand patients or in young, active patients who are con-sidered too young for a joint replacement (out of concern for component wear and the need for early revision). Arthrodesis can also serve as a “last resort” procedure in orthopedics when joint preserving treatments fail due to fracture or infection. Ankle arthrodesis is the primary procedure performed in adult patients with traumatic arthritis of the ankle.Joint Arthroplasty/Joint Replacement. Joint arthroplasty is the most common option for patients suffering from pain associated with arthritis in a joint. The surfaces of the bones are replaced after removing the damaged articular cartilage. The amount of bone and the determination of how to make the bone cuts is made based on preoperative radiographs and templating, cutting guides, anatomic measurements, and soft tissue/ligament balancing. The cut bony surfaces are covered with new compo-nents, usually made of metal, ceramic, or polyethylene. These new components are sized to appropriately match the patient, based on templated preoperative radiographs, intraoperative measurements, and examination for stability, leg length, align-ment, and range of motion.If all compartments or surfaces of the joint are replaced, the arthroplasty is referred to as a total joint arthroplasty. In comparison, if only one surface or compartment of the joint is replaced, it is referred to as hemiarthroplasty (hip, shoulder) or unicompartmental arthroplasty (knee). Total hip and knee arthroplasties are considered among the most successful of all surgical procedures performed in terms of patient outcome and improvement in pain.Hip Arthroplasty Background Hip arthroplasty is utilized for end stage arthri-tis in the hip that has failed a reasonable trial of nonoperative measures (Fig. 43-37). Conventional hip arthroplasty commonly refers to total hip arthroplasty where both the femoral head and acetabulum are replaced or resurfaced, respectively. Finally, hemiarthroplasty describes the replacement of the femoral head and neck with a stemmed femoral component in isolation. The acetabulum is not addressed surgically.History of Hip Arthroplasty The history of hip arthroplasty (hip replacement) may be broken down into “Pre-Charnley” and “Post-Charnley” eras, referring to the significant contri-butions of Sir John Charnley to the evolution of hip arthro-plasty. Prior to Charnley’s contributions, hip arthroplasty consisted of a variety of procedures with highly variable results. Early attempts at relieving hip pain were made with interpositional arthroplasty, where tissue layers, plastic, or metal were placed between the worn articular surfaces. Frac-ture of the interposed material or loosening of components often led to failure.Later attempts introduced stemmed components to improve fixation. One of the earliest femoral components was designed by Austin-Moore. This prosthesis replaced the femoral head and neck with a metal component secured into the femoral shaft with a stem extending down the diaphysis. This prosthesis was utilized in hemiarthroplasty for many years and served as Figure 43-37. Osteoarthritis femoral head. Note erosion of weight-bearing cartilage and peripheral osteophytes.Brunicardi_Ch43_p1879-p1924.indd 190622/02/19 10:41 AM 1907ORTHOPEDIC SURGERYCHAPTER 43a step in the development of total hip arthroplasty with the later addition of the acetabular component.Surgical Approaches to the Hip A variety of approaches to the hip joint have been utilized in joint arthroplasty, includ-ing anterior approach (Smith Petersen), anterolateral approach (Watson-Jones), lateral approach (Hardinge), and posterior approach (Kocher Langenbach). Each approach contains a unique set of advantages and disadvantages. The following is a brief summary of the most common approaches that are utilized in total hip arthroplasty.Anterior approach (Smith Petersen): This approach is an internervous and intermuscular approach. It utilizes the inter-nervous plane between the femoral nerve and superior gluteal nerve. Superficially, the plane between the sartorius (femo-ral nerve) and tensor fasciae lata (superior gluteal nerve) is dissected in the deep layer and the plane between the rectus femoris (femoral nerve) and gluteus medius (superior glu-teal nerve) is dissected. Advantages to this approach include supine positioning, use of intraoperative fluoroscopy for acetabular component positioning, and discontinuation of all ambulatory assistive devices 1 week earlier than other approached. Downsides include difficult preparation and placement of the femoral component with higher rate of femoral fracture/femoral component revision, higher rate of wound complications, and lack of a true extensile approach.Posterior approach (Kocher–Langenbach): The posterior approach is a muscle-splitting approach without an interner-vous plane. After incising the skin and subcutaneous fat, the fascia lata is incised along with the gluteus maximus. The short external rotators are exposed and dissected, includ-ing the piriformis, superior and inferior gemelli, obturator internus and externus, and quadratus femoris. This allows internal rotation of the hip along with flexion and adduction to dislocate the hip. The posterior approach with posterior soft tissue repair has no increased rate of dislocation com-pared to the anterior approach. The posterior approach is extensile and provides excellent exposure of both the femur and acetabulum for complex and revision cases.Lateral approach (Hardinge): While there have been many modifications to the original Hardinge approach, first described in 1982, most involve releasing the anterior one-third of the gluteus medius, underlying minimus, abductor tendon, and vastus lateralis distally in one sleeve off of the greater trochanter. The capsule is then incised to expose the hip joint. Care must be taken to protect the superior gluteal nerve during this exposure, which lies 5 cm proximal to the tip of the greater trochanter.Exposure of the acetabulum is excellent with the modified Hardinge approach, which is extensile. However, access to the posterior column is limited compared to the posterior approach. The increased risk of postoperative Trendelenburg gait, other pathologic gait, and heterotopic ossification compared to all other approaches to the hip have made it far less commonly performed than the posterior approach. Minimally invasive total hip arthroplasty is associated with decreased visualiza-tion intraoperatively and associated risks of component malposition, intraoperative fracture, and nerve or vascular injury. In fact, the only documented benefit of minimally inva-sive techniques appears to be a smaller incision, but with increased soft tissue tension intraoperatively comes the risk of compromised wound healing and periprosthetic joint infection.Bearing Surfaces in Hip Arthroplasty The most common combination of bearing surfaces used in total hip arthroplasty is a metal (generally cobalt chrome) or ceramic prosthetic head, articulating with a polyethylene liner. Metal on metal (MOM) articulations have largely been abandoned in total hip arthro-plasty as they are associated with production of metal ions that deposit in solid organs, pseudotumors that are locally destruc-tive to soft tissue/bone, and risk of early failure (Fig. 43-38). Ceramic on ceramic articulations have the lowest friction of all current bearing combinations. However, ceramic may fracture or squeak in ceramic on ceramic total hip arthroplasties.Alignment of Hip Arthroplasty Components Proper align-ment of hip arthroplasty components is vital to a successful procedure and patient outcome. Surgeons aim for appropriate alignment of components to restore a functional and stable range of motion. This is accomplished with combined version of the femoral and acetabular components, appropriate abduc-tion of the acetabular components, and staying true to Sir John Charnley’s principles: establishing a low friction articulation, 12Figure 43-38. Failed ceramic on metal hip arthroplasty components. Note the metallic staining on the ceramic femoral head.Brunicardi_Ch43_p1879-p1924.indd 190722/02/19 10:41 AM 1908SPECIFIC CONSIDERATIONSPART IImedializing the acetabular component and center of rotation and restoring abductor length and tension with restoration of appropriate length and femoral offset. Inappropriate placement of components can lead to early failure, accelerated component wear, dislocation, need for revision surgery, as well as poor patient outcomes and satisfaction.Knee Arthroplasty Background Knee arthroplasty is indicated for end-stage arthritis that has failed a reasonable trial of nonoperative mea-sures (Figs. 43-39 and 43-40). Knee arthroplasty commonly refers to total knee arthroplasty where the distal femur, tibia, and patella are resurfaced after any remaining articular cartilage and a layer of subchondral bone are resected. A unicompartmental knee arthroplasty consists of replacing one compartment of the knee, most commonly the medial compartment.Surgical Approach to the Knee Total knee arthroplasty is generally accomplished through a medial parapatellar approach. This approach utilizes a longitudinal skin incision extending, on average, 5 cm proximal to the patella to the medial aspect of the tibial tubercle distally. Dissection is carried down to the capsule. To gain access to the joint, an arthrotomy is performed medial to the patella extending proximally along the most medial aspect of the quadriceps tendon and distally just medial to the patellar tendon. This approach provides excellent exposure to all three compartments of the knee after patellar dislocation.Once the joint surfaces are adequately exposed, remain-ing articular cartilage and a thin layer of underlying bone are removed prior to placement of prosthetic components. Bone cuts are made based on preoperative templating, cutting guides, ligament balancing, and anatomic measurements (Figs. 43-41 and 43-42).Bearing Surfaces in Knee Arthroplasty The femoral com-ponent consists of a metal prosthetic cap sized to fit the normal shape of the distal femur. The tibia is cut perpendicular to the anatomic and mechanical axis, and a flat, stemmed, metal tray is placed that serves as a base plate for a polyethylene bearing surface. The patella is usually resurfaced with a polyethylene component.Two types of primary total knee arthroplasty systems exist, including cruciate retaining and posterior stabilized systems. As the name implies, with cruciate retaining systems, the PCL is retained in hopes of preserving more normal knee structures and minimizing bone loss, while in posterior stabilized systems the ligament is sacrificed and the components are designed to accommodate for the loss. These two systems have equivalent results in knee arthroplasty.Alignment and Balancing in Knee Arthroplasty Appropri-ate sizing and positioning of the components and balancing of the size and geometry of bony gaps in flexion and extension are essential for a successful knee arthroplasty. Inappropriate com-ponent position can lead to early wear and failure, instability, pain, and stiffness.Computer Navigation, Robotics, and Joint ArthroplastyComputer-navigated joint arthroplasty has the theoretical ben-efit of more accurate and consistent placement of arthroplasty components through intraoperative feedback to the surgeon regarding component position, planned bone cuts, and align-ment. Disadvantages include increased costs of the technology, prolonged operative times, and risk of infection/fracture at the sites of intraoperative sensor placement within bone. Use of Figure 43-39. Valgus deformity. Osteoarthritis of lateral compart-ment right knee.Figure 43-40. Osteoarthritis of both knees. Note varus alignment of right knee and valgus alignment of left knee (windswept deformity).Brunicardi_Ch43_p1879-p1924.indd 190822/02/19 10:41 AM 1909ORTHOPEDIC SURGERYCHAPTER 43ABFigure 43-41. A. Varus knee with osteoarthritis. B. Right total knee replacement.Figure 43-42. Computer-assisted robotic targeting arm for total knee replacement.Brunicardi_Ch43_p1879-p1924.indd 190922/02/19 10:41 AM 1910SPECIFIC CONSIDERATIONSPART IIcomputer navigation in total joint arthroplasty has been shown to minimize outliers in alignment, but there has been no proven benefit in survival or function secondary to computer-navigated or robotic-assisted joint replacement.Fixation Options in Joint ArthroplastyComponents in hip and knee arthroplasty can be secured with cement or biologic fixation. The cement most commonly used is polymethylmethacrylate (PMMA). PMMA serves as a grout between the component and the bone surface. Components secured without cement are grit blasted or porous coated to allow bony on growth or ingrowth, respectively. Hydroxyapatite can also be utilized on implant surfaces to promote bone ingrowth or ongrowth through osteoconductive properties. A majority of hip joint arthroplasty components are now secured without cement, where initial fixation of components is accomplished through press fit techniques. In knee arthroplasty, cement utilization is generally preferred. In hip replacement patients where biologic fixation is unreliable, such as older adults, osteoporotic or previ-ously irradiated cement may be a better option. With revision total hip arthroplasty, cement fixation of components has been shown to lead to earlier mechanical failure.Osteolysis and Aseptic Loosening. Osteolysis is a term used to describe abnormal resorption of bone. Osteolysis can be caused by underlying infection, metastatic disease, or in case of joint replacement, the production of wear debris. Even with appropriately positioned components, some wear of the bear-ing surfaces is expected over time. However, wear rates as well as the size and amount of wear debris differs with the bearing surface. Friction in ceramic on ceramic articulations is the low-est of all bearing surfaces; however, there is increased risk of component fracture and postoperative “squeaking.” In metal or ceramic on polyethylene articulations, wear debris is produced, and polyethylene particles are phagocytized by local macro-phages. Activated macrophages lead to an osteolytic process and bone resorption. Particulate methylmethacrylate cement debris can also play a role in osteolysis by damaging the polyethylene bearing surface. Osteolysis has been shown to be significantly decreased with the advent and use of highly cross-linked poly-ethylene. Improperly positioned components or patient-related factors such as high impact activities can lead to increased wear. A substantial osteolytic response may occur and lead to compo-nent micromotion and aseptic loosening. Patients who present to clinic with pain following joint arthroplasty and an increas-ing zone of osteolysis in the periprosthetic region frequently need revision surgery (Fig. 43-43). Alternative bearing surfaces continue to be explored in hopes of decreasing component wear, associated osteolysis, and aseptic loosening.Complications in Joint ArthroplastyThe risk of any complication following joint arthroplasty proce-dures falls in the range of 5% to 10%. Risks shared by hip and knee arthroplasties include infection, intraoperative or postop-erative fracture, vascular injury, need for intraoperative or post-operative blood transfusion, nerve injury or nerve palsy (most commonly involving the deep peroneal nerve and loss of ankle dorsiflexion), stress shielding, component fracture or wear, and medical complications, including venous thromboembolic dis-ease (DVT and PE), myocardial infarction, or cerebrovascular accident. Complications unique to total hip arthroplasty include dislocation, leg length discrepancy, and iliopsoas impingement or tendonitis.Dislocation Following Hip Arthroplasty. Dislocation can result from malpositioned components (inadequate com-bined version of the femoral stem and acetabular component; extremes of inclination of the acetabular component), noncom-pliance, cognitive or neuromuscular disorders, compromised soft tissue envelope from revision surgery, fracture, or insuf-ficient restoration of length and/or offset. Comparable disloca-tion rates have been found with anterolateral, lateral, anterior, and posterior with soft tissue repair (approximately 0.5%) approaches. History, physical examination, and radiographs are vital to proper treatment of dislocation. Closed reduction can usually be performed with conscious sedation and gentle traction or manipulation. Rarely, open reduction may be neces-sary. Component position should be assessed in patients with multiple dislocations. Patients with recurrent dislocations and suboptimally positioned components may require component revision. Patients with recurrent dislocations and properly posi-tioned components should be considered for conversion to a device with a larger prosthetic head (dual mobility construct) or a constrained total hip arthroplasty implant that provides improved stability.ORTHOPEDIC PATHOLOGY AND ONCOLOGYDiagnosis of Malignant Bone TumorsHistory. Diagnosis of musculoskeletal tumors begins with a thorough patient history. A history of unremitting pain unre-lated to activity or pain that interferes with sleep suggests malig-nancy. Patient age can help in establishing a differential. Round Figure 43-43. Failed total knee replacement. Note subsided, loose, tibial component.Brunicardi_Ch43_p1879-p1924.indd 191022/02/19 10:41 AM 1911ORTHOPEDIC SURGERYCHAPTER 43blue cell lesions are most likely neuroblastoma in a 5-year-old, Ewing’s sarcoma in a 10-year-old, lymphoma in a 20-year-old, and myeloma in a 60-year-old. Gender also aids in the differen-tial. For instance, giant cell tumor is more common in females, while osteosarcoma is more common in males. Multiple bone involvement may suggest enchondromas (Ollier disease, Maffucci’s syndrome) or osteochondromas (multiple hereditary exostoses).Laboratory Tests. Laboratory tests determine the level of cellular turnover (lactate dehydrogenase [LDH]) or of bone destruction (calcium, alkaline phosphatase). Elevated prostate-specific antigen (PSA) suggests prostate cancer.Imaging. Radiographic studies are critical in the diagnosis of bony tumors. Radiographs can help assess the aggressive-ness of the tumor. Four questions should be addressed when assessing radiographs: (a) Where is the tumor—in which bone (Table 43-1) and in which part of the bone is the lesion? (Table 43-2) (b) What is the tumor doing to the bone (clinical behavior)? (c) What is the bone doing to the tumor (biologic response)? and (d) What is the matrix pattern? Matrix is the acellular interstitial substance produced by tumor cells. Particu-lar attention should be paid to the junction between the tumor and the host bone since this margin can also indicate the aggres-siveness of the tumor. Ewing’s sarcoma has a characteristic “onion skin” periosteal reaction pattern. This reaction pattern also occurs in other tumors and infections.OSTEOSARCOMAThe most common primary malignant bone tumor is osteosar-coma (Fig. 43-44). Osteosarcomas are classified as osteoblas-tic, chondroblastic, fibroblastic, telangiectatic, round cell, or MFH-like, according to the predominant cell type. Most osteo-sarcomas present in patients between 10 and 20 years of age. Secondary osteosarcomas occur in older patients in abnormal bone affected by Paget’s disease, radiation, or bone infarct.Intramedullary OsteosarcomaThis is the most common primary sarcoma of the bone. It usu-ally occurs in the distal femur or the proximal tibia in young people. This condition may also occur at the proximal humerus, proximal femur, or pelvis. It usually presents itself as a high-grade extracompartmental disease. It can metastasize to the bone, which is called a “skip lesion,” but the lung is the primary site of metastases. Long term survival is 75% with adequate treatment. The response to chemotherapy (98% necrosis of the Table 43-1Common locations of bone tumorsFEMURDistal posteriorParosteal osteosarcomaDistal anteriorPeriosteal osteosarcoma, periosteal chondroma or chondrosarcoma, myositis ossificansTIBIAAdamantinoma, chondromyxoid, fibromaHANDS AND FEETEnchondroma, exostosisCalcaneusUnicameral bone cyst, lipoma, chondroblastoma, osteosarcomaSPINEAnteriorMetastatic, myeloma, Paget’s disease, vascular malformation, giant cell tumorPosteriorOsteoid osteoma, osteoblastoma; aneurysmal bone cystPELVISMetastatic, myeloma, chondrosarcoma, giant cell tumor, aneurysmal bone cyst, Paget’s disease, Ewing’s SarcomaSACRUMChordoma (midline), chondrosarcoma, giant cell tumor, aneurysmal bone cyst, lymphomaRIBSMetastatic, myeloma, fibrous dysplasia, chondrosarcomaTable 43-2Tumor location in boneEpiphysisChondroblastoma, clear cell chondrosarcoma, giant cell tumor (GCT), infection, dysplasia epiphysealis hemimelica (DEH)MetaphysisMost common site of involvementDiaphysisF-Fibrous dysplasia, EG-Eosinophilic Granuloma, N-Nonossifying Fibroma, O-Osteoid osteoma, M-Myeloma, A-Adamantinoma, S-Simple Bone Cyst, H-Histiocytosis, I-InfectionFigure 43-44. Osteosarcoma.Brunicardi_Ch43_p1879-p1924.indd 191122/02/19 10:41 AM 1912SPECIFIC CONSIDERATIONSPART IItumor after chemotherapy is a good sign) and the stage of the disease determines the prognosis. Young patients may present with pain and swelling, with X-rays showing plastic lesions in some areas of destruction with periosteal reaction called “Codman’s Triangle.” X-rays may show bone formation with a sunburst appearance. MRI should involve the entire bone to diagnose the skip metastasis. CT scans of the chest are usually done to find primary metastases. Alkaline phosphatase is usu-ally high. Diagnosis is typically confirmed with a biopsy, which is done after staging the tumor. Proper biopsy technique should be employed, which includes longitudinal incisions. As a gen-eral rule, the biopsy should be done by the same surgeon who will provide the definitive treatment for the patient. Treatment of osteosarcoma will be preoperative chemotherapy and wide resection, followed by postoperative chemotherapy.Parosteal OsteosarcomaParosteal osteosarcoma is a low-grade surface osteosarcoma that appears as if it were stuck on the bone, especially in the pos-terior distal femoral metaphysis (80%). The differential diagno-sis includes osteochondroma and myositis ossificans. Treatment consists of wide excision. The prognosis is 95% 5-year survival as it is a low-grade tumor.Periosteal OsteosarcomaPeriosteal osteosarcoma is a high-grade tumor. It occurs on the anterior surface of the distal femur or proximal tibia. The lesion appears chondroblastic on histology. Radiographs show scalloping of the underlying cortex with a “sunburst” periosteal reaction. Treatment is chemotherapy and wide surgical excision. The 5-year survival rate is 80%.Paget’s SarcomaPaget’s sarcoma is a rare complication of Paget’s disease. In Paget’s disease with multiple bone involvement, osteogenic sar-coma, fibrosarcoma, chondrosarcoma, and MFH have occurred, most often in the pelvis, but also in the femur, humerus, spine, and skull. This malignant transformation occurs in less than 1% of patients. The patient will complain of new onset pain and swelling. The physician must have a high index of suspicion in patients with Paget’s who previously had no pain. Imaging may demonstrate osteolytic areas and loss of normal fatty marrow and multifocal lesions. Treatment of Paget’s sarcoma is chemo-therapy and wide surgical excision. The prognosis is poor, and the 5-year survival rate is less than 10%.Radiation-Induced SarcomaThe three criteria for diagnosis of radiation-induced sarcoma are (a) histology different from the original lesion, (b) sarcoma develops in the irradiated field, and (c) a 3to 5-year latent period between radiation and sarcoma development. Radiation for carcinoma of the breast and cervix can result in osteosar-coma, chondrosarcoma, fibrosarcoma, or MFH. Treatment is a combination of chemotherapy and surgery.EWING’S SARCOMAEwing’s sarcoma is the second most common primary bone tumor in patients under 25 years of age. The typical presenta-tion is a tumor in the diaphysis of long bones, especially the femur. It can also be seen in the pelvis, the proximal tibia, and proximal humerus, and it is usually seen in young white males. It has a t(11:22) translocation and positive CD99. The patient may have pain and fever with an elevated sedimentation rate and WBC count; the condition may be confused with an infection. An “onion skin” periosteal reaction may be seen on radiographs. A large soft-tissue extension from the primary bone tumor may be seen, and histology reveals a small, round, blue cell tumor (Fig. 43-45). Diagnosis is confirmed with bone marrow biopsy specimen. Bone scan can identify multiple lesions. Treatment is chemotherapy and surgery or radiation therapy for spine or pelvic lesions.CARTILAGE-FORMING TUMORSChondrosarcomasChondrosarcomas typically occur in male patients over 40 years of age, and they are the third most common primary bone malignancies. Primary chondrosarcomas can form clear cell, mesenchymal, or dedifferentiated neoplastic cartilage. Secondary chondrosarcomas may also develop in preexisting lesions such as exostoses or enchondromas. Pelvis, shoulder, and ribs are common locations. Chondroid or “popcorn” cal-cifications are typical on radiographs. Clear cell chondrosar-coma and mesenchymal chondrosarcoma occur in younger patients (second to fifth decades of life). Clear cell chondro-sarcomas are low-grade lesions that often affect the epiphyses. The dedifferentiated chondrosarcoma is a high-grade chondro-sarcoma with a less than 10% survival rate. It has a biomor-phic histology, with a chondroid component and a high-grade spindle cell component.The treatment of chondrosarcoma is surgical excision, since cells are not chemosensitive or radiosensitive. For high-grade lesions, wide or radical resection is recommended. Pelvic and scapular chondrosarcomas have a high recurrence rate, and adjuvant chemotherapy does not improve survival rates.FIBROUS LESIONS OF BONEDesmoplastic FibromaDesmoplastic fibroma is a rare tumor occurring in the mandible, femur, pelvis, radius, or tibia in young adults. It presents as a painful lesion. Radiographs show a metadiaphyseal “soap bubble” appearance and endosteal scalloping. Histology resembles Figure 43-45. Ewing’s sarcoma.Brunicardi_Ch43_p1879-p1924.indd 191222/02/19 10:41 AM 1913ORTHOPEDIC SURGERYCHAPTER 43desmoid tumors or fibromatosis. Recommended treatment is wide excision to avoid recurrence.Malignant Fibrous Histiocytoma of BoneMFH occurs in the metadiaphysis of long bones after condi-tions like nonossifying fibromas and bone infarcts. It may pres-ent with pain or by a pathologic fracture. Radiographs typically show destructive lesions with soft-tissue extension. Histology resembles osteosarcoma with pleomorphic spindle cells, his-tiocytes, and giant cells, but no neoplastic osteoid formation. Treatment is chemotherapy and wide surgical excision.Malignant Vascular TumorsHemangioendothelioma. Hemangioendothelioma is a malig-nant neoplasm arising from vascular endothelium in long bones and most often occurs in the lower extremity. Radiographs show a metadiaphyseal lytic lesion with a “soap bubble” appearance. Histology reveals eosinophilic cells in a basophilic stroma. Lesions may be multifocal. Treatment consists of curettage for low-grade lesions and wide excision +/radiation therapy for high-grade lesions.Hemangiopericytoma. Hemangiopericytoma is usually a solitary lesion occurring in the soft tissues or the axial skeleton and proximal long bones in middle-aged or older adult males. Histology reveals branching “staghorn” vascular spaces. The tumor cells resemble cells normally seen adjacent to capillaries. Treatment is wide excision.Angiosarcoma of Bone. Angiosarcoma is a soft tissue malig-nancy usually seen in older adult males; chronic vascular stasis is a risk factor. Histology reveals vascular channels with ana-plasia. Treatment is wide excision, or if the tumor is surgically inaccessible, radiation.MISCELLANEOUS TUMORSGiant Cell Tumor of BoneGiant cell tumor is a benign aggressive tumor. Fifty per-cent of these tumors occur around the knee, especially at the distal femur and the proximal tibial. Giant cell tumors may also occur in the distal radius, proximal humerus, and pelvis (especially the sacrum ala) in women 20 to 40 years of age. Presenting complaints include pain and pathologic fracture. Imaging reveals eccentric, epimetaphyseal lytic lesions erod-ing the subchondral bone. Histology reveals multinucleate giant cells and mononuclear stromal cells. An abundance of giant cells in the field can help establish the diagnosis, and the nuclei of giant cells appear the same as the stroma cells (all nuclei look similar) (Fig. 43-46). Giant cell tumors must be differentiated from the Brown tumor of hyperparathy-roidism. While both have giant cells, hyperparathyroidism affects multiple areas, and the serum calcium is not normal. Epiphyseal lesions such as chondroblastoma should also be part of the differential diagnosis. These tumors can occasion-ally metastasize to the chest. Primary malignant giant cell tumor has a poor prognosis. Treatment of giant cell tumors is with curettage and high-speed burr. Recurrence rates are high with simple curettage, and the use of adjuvants such as cryosurgery, phenol, or polymethylmethacrylate bone cement may help decrease recurrence rates. After pathologic fractures, wide excision with reconstruction or amputation may be required.Adamantinoma and Osteofibrous DysplasiaAdamantinomas are low-grade malignant tumors usually seen in the tibia (Fig. 43-47). Adamantinomas are capable of metas-tasizing to the lung. The patient may present with pain and/or bowing of the tibia. X-ray reveals multiple lucent lesions on the cortex of the tibia. Histology reveals a biphasic tumor with nests of epithelial cells and fibrous stroma (see Fig. 43-46). Osteofibrous dysplasia is considered the precursor to ada-mantinoma and should be part of the differential diagnosis. Osteofibrous dysplasia is a benign lesion, usually occurring in children, at the anterior tibia, which is treated with obser-vation. The treatment of adamantinoma is with wide surgical excision.Figure 43-46. Giant cell tumor.Figure 43-47. Typical location of adamantinoma.Brunicardi_Ch43_p1879-p1924.indd 191322/02/19 10:41 AM 1914SPECIFIC CONSIDERATIONSPART IIPrimary Lymphoma of BonePrimary lymphoma accounts for about 5% of all neoplasms of bone. Long bone involvement is more frequent than spine. Lym-phoma of bone typically occurs in males in their forties. Histol-ogy reveals large B cell lymphomas. Treatment is a combination of chemotherapy and radiation. Surgery may be required for stabilization of pathologic fractures.ChordomaChordoma arises from notochordal remnants in the sacrum. It is usually midline in location. These tumors are found in middle-aged to older men and presents with bladder and bowel symptoms due to involvement of the cauda equina. Visual-ization of the lesion may be difficult because of the bowel gas shadow. Diagnosis may be delayed. An MRI shows a destructive extensile midline lesion with a large soft tissue mass. Histology shows epithelioid cells arranged in cords with vacuolated foamy physaliferous cells. These cells are keratin positive. Treatment is surgical excision and muscle flaps and a mesh for reconstruction. Urinary diversion and colostomy may be needed for loss of bladder and bowel control. Local recurrence is common.Multiple MyelomaMyeloma, the most common primary bone malignancy, is a pro-liferative disorder of B cells with plasma cells producing immu-noglobins. These plasma cells have a classic eccentric nucleus giving a “signet ring” appearance (Fig. 43-48). Evidence of monoclonal protein in the serum and/or urine (Bence Jones proteinuria), and hypercalcemia, renal insufficiency, anemia, or bone disease are usually present.Presenting symptoms in myeloma range from bone pain and osteopenia to focal lytic lesions with pathologic fractures and hypercalcemia. Myeloma protein 1-α stimulates osteo-clast formation. Osteoclast activating factors increase recep-tor activator of nuclear factor κB ligand (RANKL) in the bone marrow. RANKL induces osteoclast differentiation and acti-vation. Myeloma cells inhibit osteoblast differentiation and activity. Serum and urine electrophoresis detect the M protein. Workup also includes complete blood cell count, erythrocyte sedimentation rate, calcium levels, renal function assessment, β2-microglobulin levels, and a skeletal survey. X-ray will show multiple punched out lytic lesions. Bone scans may be cold in about 30% of cases. The SPEP, UPEP, and bone marrow biopsy are helpful in diagnosis. Histology will show atypical plasma cells with eccentric nuclei, its appearance resembles a “signet ring (Fig. 43-49).” Plasmacytoma is a solitary tumor with a negative bone marrow biopsy, usually treated with radiation to the lesion. Myeloma is treated with bisphosphonates, chemo-therapy, stem cell transplantation, and radiation therapy. Surgi-cal stabilization and irradiation is done for pathologic fractures or impending fractures. Many patients with myeloma develop a vertebral compression fracture. Kyphoplasty can be useful in providing pain relief. The risks of cement extravasation and related complications are lower with kyphoplasty than with ver-tebroplasty. If there is instability or if there is neural compres-sion, surgical stabilization may be required.METASTATIC BONE TUMORSMetastatic bone tumors are more common than primary bone tumors. Metastatic tumors affect the lung, liver, and bone. Cancers that commonly metastasize to bone are breast, lung, thyroid, kidney, and prostate. In patients older than 40 years of age, metastases and myeloma are the most common causes of destructive lesions in bone. The most common site of involve-ment is the axial skeleton, especially the thoracic spine, and proximal ends of long bones, especially the proximal femur. Lung and renal cell carcinomas can metastasize distal to the knee and elbow. Malignant cells are able to detach from one location and set up a focus at a distant site. The tumor activates osteoclasts and causes destruction of the bone, a mechanism that involves the RANK/RANKL pathway. The patient may present with pain, pathologic fractures, or the manifestation of hypercalcemia. Workup of a patient with a suspected metastatic disease to bone and an unknown primary tumor should include CT of the chest, abdomen, and pelvis. The extent of the disease is evaluated by bone scans (myeloma and thyroid are usually cold in bone scans), mammography, tumor markers, serum, and urine electrophoresis (SPEP and UPEP). A biopsy may be nec-essary to rule out primary bone lesions if the primary site is not identified. Treatment of bone tumors depends on the diagnosis, as metastatic tumors are treated differently than primary bone tumors. Metastatic tumors are usually treated by bisphospho-nates and by surgical stabilization with postoperative radiation if warranted. Primary bone tumors are usually treated by wide excision with chemotherapy in high-grade tumors (chondrosar-coma are treated only with wide excision). Radiation therapy can be used in Ewing’s.Multiple myelomaEccentricnucleusSignet ring appearanceFigure 43-48. Signet ring.Figure 43-49. Multiple Myeloma showing the eccentric nuclei and the signet appearance of cells.Brunicardi_Ch43_p1879-p1924.indd 191422/02/19 10:41 AM 1915ORTHOPEDIC SURGERYCHAPTER 43PEDIATRIC ORTHOPEDICSBirth InjuriesNeonatal Brachial Plexus Palsy. Injury of the brachial plexus during delivery occurs in 2 births in every 1000. Large birth weight, forceps delivery, breech presentation, and pro-longed second stage of labor with shoulder dystocia are risk factors. Brachial plexus injury usually represents a stretch injury on the nerve roots of the upper or lower plexus.Upper plexus injuries (Erb-Duchenne) are lesions mani-fested by weakness of shoulder abductors and external rota-tors as well as the elbow flexors (Fig. 43-50). The hand is not involved. It has a good prognosis, if the biceps function is pres-ent early.In lower plexus injury, the hand is involved, with defor-mity of the fingers. An ipsilateral Horner’s Syndrome consist-ing of ptosis, myosis, anhidrosis, and enophthalmos may occur indicating a preganglionic injury of the T1 cervical sympathetic nerve. This condition has a poor prognosis.Management is therapy and gentle, passive range-of-motion exercises to preserve motion in the shoulder and prevent muscle contractures and joint incongruency in the early neonatal period while awaiting return of neurologic function and motor reinnervation. Early surgical intervention for the brachial plexus is indicated in infants who did not recover elbow flexion by 3 months of age, as they are anticipated to have a poor chance of full recovery.Surgical intervention includes microsurgical repair proce-dures in the form of neurolysis, nerve transfer, or nerve grafts. Later orthopedic reconstruction such as muscle rebalancing procedures may be considered to improve function around the shoulder.Cerebral Palsy. Cerebral palsy results from an injury to the brain, which may be associated with mental impairment. Cere-bral palsy is classified as spastic, athetotic, or ataxic and may present with spasticity, hemiplegia, diplegia, or scoliosis. The typical cerebral palsy patient is hyperreflexic with increased muscle tone and spasm. Treatment includes tendon lengthen-ing procedures, release of contractures, and tendon transfers to maintain motion and function.Figure 43-50. Erb’s point.Reserve zone(resting zone)Proliferative zoneHypertrophic zoneZone ofmaturationZone ofdegenerationWWeaWeWeaWeaWeaWeaWeaWWWWWWWWWWWWWWWkkzkzkzkzkkzkzkzkzkzkkkkkkkk zkkkkkzkkoWeak zoneZone ofprovisionalcalcificationFigure 43-51. Different zones of the growth plate.Hip dislocation or subluxation results from unbalanced muscle forces in many cerebral palsy patients. Early treatment consists of soft tissue releases in the form of adductor tendon releases, iliopsoas releases, and immobilization in an abduction brace.In older children with severe deformity, bony procedures in the form of open reduction and femoral or acetabular osteoto-mies are usually required. Femoral head resection is considered to be a salvage procedure in nonambulatory patients with pain-ful dislocated hips.Knee flexion contractures are treated with hamstring muscle lengthenings and immobilization in knee extension braces.Foot and ankle deformities are treated even in nonambu-latory patients to facilitate shoe wear. The most common foot deformity in cerebral palsy is an equinovalgus foot caused by heel cord contracture and peroneal spasm. Tendon balancing is usually necessary, and bony reconstruction may also be needed in severe cases.Skeletal GrowthInjury, inflammatory disease, and developmental disorders in actively growing bones requires special attention to preserve the growth plates. The pediatric skeleton is incompletely ossi-fied making the diagnosis of an injury difficult, since signifi-cant portions of the skeleton are invisible on radiographs. The epiphysis, generally containing an articular surface, is found at the ends of the long bone. The physis, or growth plate, is found beneath the epiphysis. The physis is divided into spe-cific zones: the reserve zone, the zone of proliferation, and the hypertrophic zone. The hypertrophic zone has three phases: the maturation zone, the degenerative zone, and the zone of calcification (Fig. 43-51).Injury or insult to the growth plate can lead to premature growth arrest or angular deformity of the limb. Surrounding the metaphyseal and diaphyseal bone is the periosteum. This meta-bolically active layer of tissue synthesizes new bone onto the diaphyseal and metaphyseal bone and provides circumferential growth of the bones.Ossification centers in the epiphysis appear in a predict-able order and can help determine “bone age.”Brunicardi_Ch43_p1879-p1924.indd 191522/02/19 10:41 AM 1916SPECIFIC CONSIDERATIONSPART IIPediatric FracturesIn a pediatric patient, the epiphyseal growth plate is unossified and weak and is at risk of fracture. Reduction and stabiliza-tion of epiphyseal fractures is critical to minimize permanent growth disturbances and deformity. Fractures near the growth plate have significant potential to remodel. For example, 80% of the growth of the humerus occurs from the proximal humeral growth plate; therefore, severely displaced proximal humeral fracture can remodel in the younger age group.Classification of Growth Plate InjuriesSalter and Harris described a useful classification for epiphyseal fractures (Fig. 43-52). A Salter-Harris type I injury is a simple transverse fracture through the physis. A Salter-Harris type II fracture contains a component of fracture through the growth plate in continuity with a fracture of the metaphysis. A Salter-Harris type III fracture occurs through the epiphysis and exits through the growth plate, while a Salter-Harris type IV fracture extends through the physis from the metaphysis into the epiphy-sis. A Salter-Harris type V fracture is a crushing injury to the physis. Type III and type IV involve the joint.Treatment of growth plate fracture requires anatomic reduction of the fragments, closed or open. If internal fixation is used, avoid placing the hardware across the growth plate to minimize the chance of injury and premature growth plate clo-sure. When hardware needs to be placed across the physis, it should be limited to smooth K-wires. The most common com-plication is a physeal arrest resulting in leg length discrepancy (LLD) and/or angular deformity. Complete arrest will lead to LLD. Partial arrest will result in angulation in the area of the bar, bridge, and fusion. If less than 50% of the physis is involved and the patient has two years of growth remaining, the bar is usually resected with interposition of fat graft. If the bar (fusion area) is more than 50%, the surgeon will complete the arrest on the same side and will do a contralateral epiphysiodesis on the other extremity.Distal femur physeal fractures are known to have a high rate of leg length discrepancy and angular deformity. The injury will need an anatomical reduction and close follow-up. Parents need to be counseled about the poor prognosis associated with these fractures.Diaphyseal Injuries in a Pediatric PatientLong bone diaphyseal fractures are generally treated closed. Pediatric patients are capable of extensive remodeling so that an angular deformity within the plane of an adjacent joint is often completely remodeled by the growth of the child. Older children do not remodel as well. A 10° angulation in both bones of the forearm in a child over an age of 10 years may cause significant limitation of rotation of the forearm. When internal fixation of a diaphyseal fracture is required, fixation through the physis is avoided.Fractures of the Pediatric HipFractures of the pediatric hip can occur with high-energy trauma, and there is a high rate of avascular necrosis. Pedi-atric patients with hip fractures may be treated with a spica cast. The spica cast includes the abdomen, lower back, pelvis, and lower limb, and derives its name from the resemblance of the plaster wrap over the hip to wheat “spica.” Closed or open reduction and internal fixation is done in fractures with severe displacement. Avascular necrosis is the most common complication after hip fractures. The incidence depends on the age of the patient and the type of the fracture. Children between 3 and 8 years old with very proximal fractures such as transphyseal fractures have the highest incidence of avas-cular necrosis.Fractures of the Femoral ShaftConsider child abuse if a femoral shaft fracture occurs before the walking age. Femoral shaft fractures in a child younger than 6 months are usually treated by a Pavlik harness or spica cast. A child between 6 months and 5 years with an acceptable shortening of the femur is usually treated by an immediate spica cast. The child between 5 years and 11 years is usu-ally treated by surgery. If the fracture is transverse, flexible IM nails may be used, especially if the child weighs less than 100 lbs (45 kg). If the fracture is too proximal or too distal, or if the fracture is comminuted and unstable, a submuscu-lar bridge plate is usually used; alternatively, an external fix-ator may also be used, especially in multiple trauma patients. If the patient is older than 11 years, an interlocking IM rod with a lateral trochanteric entry is used. Insertion of IM rod in younger children can cause avascular necrosis of the femoral head due to interruption of the blood supply. Refracture of the femur is a risk after using an external fixator. Overgrowth of the injured femur with leg length discrepancy can occur in children between 2 and 10 years of age.Figure 43-52. Classification of growth plate injuries.Brunicardi_Ch43_p1879-p1924.indd 191622/02/19 10:41 AM 1917ORTHOPEDIC SURGERYCHAPTER 43Pediatric Ankle FracturesPediatric ankle fractures include several types. Salter-Harris type I and type II usually involve the fibula, and the fracture may not be apparent. The patient may present with pain and swelling. Salter-Harris type III usually involves fracture of the medial malleolus or avulsion of the anterior inferior tibiofibular ligament from the tibia. It is called a Tillaux fracture. Tillaux fractures occur because the lateral part of the ankle is not fused and it is weak. Triplane fractures are complex ankle fractures in older children as a result of partial closure of the growth plate, and they appear as a Salter II in the lateral view and as a Salter III in an AP view (Fig. 43-53). Salter-Harris I and II fractures are usually managed with casting. Salter-Harris III or IV fractures are usually managed by closed or open reduction and internal fixation. Smooth percutaneous pins or screws are utilized, avoiding the physis.Pediatric Elbow FracturesManagement of pediatric elbow fractures is complex. Famil-iarity with the timing of the ossification centers’ appearance aids in diagnosis. Distal humeral physeal separation can occur from child abuse and can be mistaken for an elbow dislocation. A lateral condylar fracture of the elbow is a significant injury, and when it is displaced it will need anatomical surgical reduc-tion. Medial epicondyle fractures of the elbow are usually treated conservatively unless they are severely displaced. It is associated with elbow dislocation in 50% of cases. When the elbow is reduced, the fragment may lodge in the joint itself and must be removed and fixed. In supracondylar fractures of the humerus (Fig. 43-54), the neurovascular status of the extrem-ity must be assessed carefully before, during, and after treat-ment. The anterior interosseous nerve could be injured, and the patient may not be able to make an “OK sign” (Fig. 43-55). The brachial artery may also be injured. Closed reduction, pos-sible open reduction, and percutaneous pinning is usually done for these fractures. The procedure should be done emergently if there is concern about the vascular status of the extremity. Close follow-up for maintenance of reduction and neurovas-cular status is needed.DEVELOPMENTAL DISEASEDevelopmental Dysplasia of the HipDevelopmental dysplasia of the hip (DDH) involves a spectrum of disease that includes dysplasia, subluxation, or dislocation of the hip. Teratologic hip dislocation is a different entity in which the hip is dislocated in utero and irreducible on neonatal examination, usually associated with neuromuscular conditions and genetic syndromes. Developmental dysplasia of the hip is most often seen in firstborn females with a positive family history or with breech birth.Untreated hip dislocations can lead to a dysplastic acetab-ulum, and they should be recognized and treated early. New-borns are examined for hip instability within the first 72 hours HumerusFigure 43-54. Supracondylar fracture of the humerus.Figure 43-55. Unable to make the “OK” sign due to interosseous nerve injury.Figure 43-53. Triplane fracture of the ankle in children.Brunicardi_Ch43_p1879-p1924.indd 191722/02/19 10:42 AM 1918SPECIFIC CONSIDERATIONSPART IIof life. Ortolani’s test consists of gentle elevation and abduction of the femur causing a palpable click in the relocation of a dis-located hip. Barlow’s test is gentle adduction and depression of the femur, which causes a palpable click as the hip slips into a dislocated position. In older infants (older than 3 months), limited abduction of the involved hip is an important finding. Infants with a dislocated or dislocatable hip will have apparent length discrepancies of the femur when the hip is positioned at 90° (Galeazzi test).Since the bones are not ossified at birth, X-ray images of the acetabulum and femoral head are not reliable for diag-nosis. Ultrasound is the imaging modality of choice in the neonatal period and can often demonstrate a dislocated or dislocatable hip.Treatment of DDHThe main goal in the treatment of DDH is to achieve stable concentric reduction of the hip.• Neonate to 6 months: Early treatment with abduction and flexion in a Pavlik harness for 6 to 12 weeks is usually suf-ficient. Avoid severe abduction and flexion in the Pavlik har-ness to avoid the risk of avascular necrosis of the femoral head and femoral nerve palsy.• Children 6 to 18 months: Closed reduction and application of hip spica cast is indicated in this age group and in those children who failed Pavlik harness treatment.• Children older than 18 months: Open reduction and cap-sulorrhaphy is indicated in this age group. A variety of procedures, including femoral shortening and pelvic osteoto-mies, are done in older age groups and in more severe cases. Osteonecrosis of the femoral head is a possible complication of treatment and can result in pain and decreased range of motion.Legg-Calvé-Perthes DiseaseOsteonecrosis of the proximal femoral epiphysis can cause flattening of the femoral head called Legg-Calvé Perthes disease. The age at presentation is between 4 and 8 years of age and occurs more in males, usually affecting one side. Younger age at presentation (less than 6 years old) will have a better prognosis. The patient presents with groin or knee pain, decreased hip motion, and a limp. Treatment includes traction, physical therapy, abduction exercises, and crutches. Restoration of range of motion is important. Femoral and pelvic osteotomies may be needed in extreme cases and in older children.Slipped Capital Femoral EpiphysisChildren ages 10 to 16 years can develop displacement of the epiphysis on the femoral neck with no history of injury. The slippage occurs through the weak zone (hypertrophic zone) of the growth plate. When slippage occurs in young patients, check for endocrine disorders such as hypothyroid-ism, renal osteodystrophy, and growth hormone deficiency. Slipped capital femoral epiphysis (SCFE) is associated with African-American heritage and obesity, and it is more com-mon in boys than in girls. One-quarter of cases are bilateral. In patients with endocrine etiology, the condition is usually bilateral. Patients generally present with groin and anterior thigh pain, and the patient may have antalgic gait and a limp. Patient may present with knee pain that can lead to missing the diagnosis. In pediatric patients with knee pain, the ipsi-lateral hip should be assessed as well.Examination of the patient will show obligatory external rotation with flexion and loss of internal rotation of the hip. Obtain AP and frog leg lateral views of both the hips.Slipped epiphysis is classified as either stable or unstable on the basis of the patient’s ability to bear weight. It is classi-fied as stable if the patient is able to bear weight and the risk of osteonecrosis is less than 10%. It is classified as unstable if the patient is unable to bear weight even with crutches, and the incidence of avascular necrosis is high.Treatment for slipped capital femoral epiphysis patients is percutaneous screw fixation through the femoral neck to engage the epiphysis, causing the growth plate to close. Reduc-tion of the slipped epiphysis is not recommended because of an increased risk of avascular necrosis. One screw is usually adequate to prevent further slip.Lower Extremity Rotational AbnormalitiesIntoeing can result from femoral anteversion, tibial torsion, and metatarsus adductus. Mild degree of intoeing is normal in young children 3 to 5 years of age.Excessive internal rotation of the femur will usually cor-rect by age 8. Severe rotation with functional impairment that does not correct by age 10 or 11 may require rotational femoral osteotomy.Tibial torsion is the most common cause of intoeing in toddlers and could be bilateral. The condition usually resolves without treatment.Metatarsus adductus in infants will also resolve spontane-ously in most cases.Congenital Talipes Equinovarus (Clubfoot)Clubfoot is a congenital disorder, and its etiology is not known. Clubfoot is a common problem associated with con-tractures of the medial tendons of the foot, a tight Achilles tendon, and contractures of the ankle, hindfoot, and midfoot. The foot is usually small, and it is in the equinus, varus, cavus, and adduction position. Talipes equinovarus can be corrected by sequential corrective casting of the foot. The serial manip-ulation and the casting technique is called the Ponseti tech-nique, and it has a high success rate. A successful program of casting may be complete in 1 to 5 months. In patients with severe disease or who initiate treatment after 9 months of age, surgical release of contracted soft tissues may be necessary. The procedure is called posteromedial soft tissue release and tendon lengthening.Osgood-Schlatter DiseaseOsgood-Schlatter disease is a common problem most often seen in athletically active adolescents, especially in sprint-ers and jumpers. It is a traction apophysitis of tibial tubercule (Figs. 43-56 and 43-57). One must know the difference between the epiphysis, apophysis, and physis. This disorder is charac-terized by ossification in the distal patellar tendon at the point of its tibial insertion, and it is thought to result from mechani-cal stress on the tendinous insertion. The disease presents with severe local pain and tenderness in the area of the tibial tubercle. Radiographs may show calcified ossicles within the tendon at its insertion.Brunicardi_Ch43_p1879-p1924.indd 191822/02/19 10:42 AM 1919ORTHOPEDIC SURGERYCHAPTER 43Treatment for the disease is activity restriction and anti-inflammatory drugs. The majority of patients improve with con-servative treatment, and athletic participation can be resumed. Usually, symptoms regress after skeletal maturity or after activ-ity modification. In refractory cases, surgery in the form of ossicle excision is rarely done.BIBLIOGRAPHYEntries highlighted in bright blue are key references.TraumaBhandari M, Devereaux PJ, Tornetta III P, et al. Operative man-agement of displaced femoral neck fractures in elderly patients: an international survey. J Bone Joint Surg Am. 2005;87(9):2122-2130.Bond CD, Shin AY, McBride MT, Dao KD. Percutaneous screw fixation or cast immobilization for nondisplaced scaphoid frac-tures. J Bone Joint Surg Am. 2001;83(4):483-488.Bone LB, Johnson KD, Weigelt J, et al. Early vs. delayed stabiliza-tion of femoral fractures. A prospective randomized study. J Bone Joint Surg Am. 1989;71:336-340.Bottlang M, Krieg JC, Mohr M, Simpson TS, Madey SM. Emergent management of pelvic ring fractures with use of circumferential compression. J Bone Joint Surg Am. 2002;84-A(suppl 2):43-47.Burgess AR, Eastridge BJ, Young JWR, et al. Pelvic ring disrup-tions: Effective classification system and treatment protocols. J Trauma. 1990;30(7):848-856.De Ugarte DA, Morizono K, Elbarbary A, et al. Comparison of multi-lineage cells from human adipose and bone marrow. Cells, Tissue, and Organs. 2003;174:101-109.Dragoo JL, Samimi B, Zhu M, et al. Tissue-engineered cartilage and bone using stem cells from human infrapatellar fat pads. JBJS. 2003;85-B:740-747.Ebraheim N, Cooper J, Siddiqui S. Compartment syndrome book-let. University of Toledo Medical Center. March 1, 2018. Avail-able at: www.utoledo.edu/med/cme/pdf/Compartment%20Syndrome%20Booklet%20and%20Post%20Test%20water marked.pdf. Accessed August 14, 2018.Ebraheim N, Cooper J, Corba L. Synopsis of fractures and dislo-cations. University of Toledo Medical Center. March 1, 2018. Available at: www.utoledo.edu/med/cme/pdf/Synopsis%20of%20Fractures%20and%20Dislocations%20Booklet%20and%20Post%20Test%20Watermarked.pdf. Accessed August 13, 2018.Ebraheim N, Lea J, Cooper J, Corba L. Orthopaedic emergencies booklet. University of Toledo Medical Center. March 1, 2018. Available at: www.utoledo.edu/med/cme/pdf/Orthopedic%20Emergencies%20Booklet%20and%20Post%20Test%20Water marked.pdf. Accessed August 14, 2018.Frankle MA, Herscovici D, DiPasquale TG, Vasey MB, Sanders RW. A comparison of open reduction and internal fixation and primary total elbow arthroplasty in the treatment of intraar-ticular distal humerus fractures in women older than age 65. J Ortho Trauma. 2003;17(7):473-480. Holstein A, Lewis GB. Fractures of the humerus with radial-nerve paralysis. J Bone Joint Surg Am. 1963;45:1382-1388.Lauge-Hansen N. Fractures of the ankle. II. Combined experimental-surgical and experimental-roentgenologic investigations. Arch Surg. 1950;60:957-985.Leslie IJ, Dickson RA. The fractured carpal scaphoid. Natu-ral history and factors influencing outcome. Bone Joint J. 1981;63(2):225-230.Letournel E. Acetabulum fractures: classification and management. Clin Orthop Relat Res. 1980;151:81-106.Lin J. Treatment of humeral shaft fractures with humeral locked nail and comparison with plate fixation. J Trauma. 1998;44(5):859-864.Liporace FA, Adams MR, Capo JT, et al. Distal radius fractures. J Orthop Trauma. 2009;23(10):739-748.McQueen MM, Gaston P, Court-Brown CM. Acute compartment syndrome: who is at risk? J Bone Joint Surg Br. 2000;82(2): 200-203.Figure 43-57. Differences between physis, epiphysis, and apophysis.Figure 43-56. Osgood Schlatter lesion.Brunicardi_Ch43_p1879-p1924.indd 191922/02/19 10:42 AM 1920SPECIFIC CONSIDERATIONSPART IIMoran CG, Wenn RT, Sikand M, Taylor AM. Early mortality after hip fracture: is delay before surgery important? J Bone Joint Surg Am. 2005;87:483-489.Moro JK, Werier J, MacDermid JC, Patterson SD, King GJ. Arthro-plasty with a metal radial head for unreconstructible fractures of the radial head. J Bone Joint Surg Am. 2001;83-A(8):1201-1211.Neer CS. Displaced proximal humeral fractures. J Bone Joint Surg Am. 1970;52(6):1077-1089.Nicoll EA. Fractures of the tibial shaft: a survey of 705 cases. J Bone Joint Surg Br. 1964;46:373-387.Nork SE, Cannada LK. Hip dislocations and femoral head and neck fractures. In: Baumgaertner MR, Tornetta P III, eds. Orthopaedic Knowledge Update: Trauma 3. Rosemont: American Academy of Orthopaedic Surgeons; 2005:365-376.Ring D, Jupiter JB, Zilberfarb J. Posterior dislocation of the elbow with fractures of the radial head and coronoid. J Bone Joint Surg Am. 2002;84:547-551.Ring D, Quintero J, Jupiter JB. Open reduction and internal fixa-tion of fractures of the radial head. J Bone Joint Surg Am. 2002;84-A(10):1811-1815.Roberts CS, Pape HC, Jones AL. Damage control orthopaedics: evolving concepts in the treatment of patients who have sus-tained orthopaedic trauma. Instr Course Lect. 2005;54: 447-462.Ross G, McDevitt ER, Chronister R, Ove PN. Treatment of sim-ple elbow dislocation using immediate motion protocol. Am J Sports Med. 1999;27:308-311.Sanders S, Tejwani N, Egol KA. Traumatic hip dislocation. Bull NYU Hosp Jt Dis. 2010;68(2):91-96.Sarmiento A, Kinman PB, Galvin EG, et al. Functional bracing of fractures of the shaft of the humerus. J Bone Joint Surg Am. 1977;59:596-601.Schatzker J, McBroom R, Bruce DD. The tibial plateau fracture: the Toronto experience 1968-1975. ClinOrthop. 1979;138:94-104.Schemitsch EH, Richards RR. The effect of malunion on functional outcome after plate fixation of fractures of both bones of the forearm in adults. J Bone Joint Surg Am. 1992;74(7):1068-1078.Schmidt AH, Asnis SE, Haidukewych GI, et al. Femoral neck frac-tures. Instr Course Lect. 2005;54:417-445.Schutz M, Ruedi TP. Principles of internal fixation. In: Buchholz C. Rockwood and Green’s Fractures in Adults. Philadelphia: Wolters Kluwer Health; 2014.Shin SSS. Circulatory and vascular changes in the hip following traumatic hip dislocation. ClinOrthop. 1979;140:255-261.Sidor ML, Zuckerman JD, Lyon T, Koval K, Cuomo F, Schoen-berg N. The Neer classification system for proximal humeral fractures. An assessment of interobserver reliabil-ity and intraobserver reproducibility. J Bone Joint Surg Am. 1993;75(12):1745-1750.Tidermark J, Ponzer S, Svensson O, Söderqvist A, et al. Internal fixation compared with total hip replacement for displaced femoral neck fractures in the elderly: a randomised, controlled trial. J Bone Joint Surg Br. 2003;85(3):380-388.Tile MM. Acute pelvic fracture II. Principles of management. J Am Acad Orthop. 1996;4:152-161.Tile MM. Acute pelvic fracture: I. Causation and classification. J Am Acad Orthop. 1996;4:143-151.Wolfe SW. Distal radius fractures. Green’s Operative Hand Surgery. 6th ed. Philadelphia, PA: Churchill Livingstone; 2011:561-638.Yagishita K, Thomas BJ. Use of allograft for large Hill-Sachs lesion associated with anterior glenohumeral dislocation. A case report. Injury. 2002;33:791-794.SportsAllaire R, Muriuki M, Gilbertson L, Harner CD. Biomechani-cal consequences of a tear of the posterior root of the medial meniscus. Similar to total meniscectomy. J Bone Joint Surg Am. 2008;90(9):1922-1931.Araujo P, Van Eck CF, Torabi M, Fu FH. How to optimize the use of MRI in anatomic ACL reconstruction. Knee Surg Sports Traumatol Arthrosc. 2013;21(7):1495-1501.Arnoczky SP, Warren RF, Spivak JM. Meniscal repair using an exogenous fibrin clot. An experimental study in dogs. J Bone Joint Surg Am. 1988;70(8):1209-1217.Baer GS, Harner CD. Clinical outcomes of allograft versus auto-graft in anterior cruciate ligament reconstruction. Clin Sports Med. 2007;26(4):661-681.Brophy RH, Marx RG. The treatment of traumatic anterior insta-bility of the shoulder: nonoperative and surgical treatment. Arthroscopy. 2009;25:298-304.Byers PD, Contepomi CA, Farkas TA. A post mortem study of the hip joint. Including the prevalence of the features of the right side. Ann Rheum Dis. 1970;29(1):15-31.Byrd JWT, Jones KS. Arthroscopic femoroplasty in the manage-ment of cam-type femoroacetabular impingement. Clin Orthop Relat Res. 2009;467:739-746.Byrd JWT, Jones KS. Prospective analysis of hip arthroscopy with 10-year follow-up. Clin Orthop Relat Res. 2010;468: 741-746.Carey JL, Dunn WR, Dahm DL, Zeger SL, Spindler KP. A sys-tematic review of anterior cruciate ligament reconstruction with autograft compared with allograft. J Bone Joint Surg Am. 2009;91(9):2242-2250.Clarke MT, Arora A, Villar RN. Hip arthroscopy: complications in 1054 cases. Clin Orthop Relat Res. 2003;(406):84-88.Fetto JF, Marshall JL. Medial collateral ligament injuries of the knee: a rationale for treatment. Clin Orthop Relat Res. 1978;(132):206-218.Frost A, Zafar MS, Maffulli N. Tenotomy versus tenodesis in the management of pathologic lesions of the tendon of the long head of the biceps brachii. Am J Sports Med. 2009;37(4):828-833.Ganz R, Parvizi J, Beck M, et al. Femoroacetabular impingement: a cause for osteoarthritis of the hip. Clin Orthop Relat Res. 2003;417:112-120.Gartsman GM. Arthroscopic management of rotator cuff disease. J Am Acad Orthop Surg. 1998;6(4):259-266.Harner CD, Mauro CS, Lesniak BP, et al. Biomechanical conse-quences of a tear of the posterior root of the medial meniscus. J Bone Joint Surg Am. 2009;91(suppl 2):257-270.Harner CD, Vogrin TM, Höher J, et al. Biomechanical analysis of a posterior cruciate ligament reconstruction. Deficiency of the posterolateral structures as a cause of graft failure. Am J Sports Med. 2000;28(1):32-39.Hovelius L. The natural history of primary anterior dislocation of the shoulder in the young. J Orthop Sci. 1999;4(4):307-317.Ilizaliturri VM, Orozco-Rodriguez L, Acosta-Rodríguez E, et al. Arthroscopic treatment of cam-type femoroacetabular impinge-ment: preliminary report at 2 years minimum follow-up. J Arthroplasty. 2008;23:226-234.Jakobsen BW, Johannsen HV, Suder P, et al. Primary repair versus conservative treatment of first-time traumatic anterior disloca-tion of the shoulder: a randomized study with 10-year follow-up. Arthroscopy. 2007;23:118-123.Lafosse L, Lejeune E, Bouchard A, et al. The arthroscopic Latar-jet procedure for the treatment of anterior shoulder instability. Arthroscopy. 2007;23(11):1242.e1-e5.LaPrade RF, Resig S, Wentorf F, Lewis JL. The effects of grade III posterolateral knee complex injuries on anterior cruciate liga-ment graft force. A biomechanical analysis. Am J Sports Med. 1999;27(4):469-475.Larson CM, Giveans MR. Arthroscopic management of femoroac-etabular impingement: early outcomes measures. Arthroscopy. 2008;24:540-546.Li H, Tao H, Cho S, et al. Difference in graft maturity of the recon-structed anterior cruciate ligament 2 years postoperatively: a comparison between autografts and allografts in young men Brunicardi_Ch43_p1879-p1924.indd 192022/02/19 10:42 AM 1921ORTHOPEDIC SURGERYCHAPTER 43using clinical and 3.0-T magnetic resonance imaging evalua-tion. Am J Sports Med. 2012;40(7):1519-1526.MacGillivray JD, Stein BES, Park M, et al. Comparison of tibial inlay versus transtibial techniques for isolated posterior cruciate ligament reconstruction: minimum 2-year follow-up. Arthroscopy. 2006;22:320-328.Mohtadi NG, Hollinshead RM, Sasyniuk TM, et al. A randomized clinical trial comparing open to arthroscopic acromioplasty with mini-open rotator cuff repair for full-thickness rotator cuff tears: disease-specific quality of life outcome at an aver-age 2-year follow-up. Am J Sports Med. 2008;36(6):1043-1051.Morse K, Davis AD, Afra R, et al. Arthroscopic versus mini-open rotator cuff repair: a comprehensive review and meta-analysis. Am J Sports Med. 2008;36:1824-1828.Nho SJ, Shindle MK, Sherman SL, et al. Systematic review of arthroscopic rotator cuff repair and mini-open rotator cuff repair. J Bone Joint Surg Am. 2007;89:127-136.Pallis M, Svoboda SJ, Cameron KL, et al. Survival comparison of allograft and autograft anterior cruciate ligament reconstruc-tion at the United States Military Academy. Am J Sports Med. 2012;40(6):1242-1246.Philippon MJ, Briggs KK, Yen YM, et al. Outcomes following hip arthroscopy for femoroacetabular impingement with associ-ated chondrolabral dysfunction: minimum two-year follow-up. J Bone Joint Surg Br. 2009;91:16-23.Ranawat A, Baker CL, Henry S, et al. Posterolateral corner injury of the knee: evaluation and management. J Am Acad Orthop Surg. 2008;16(9):506-518.Rugg CM, Hettrich CM, Ortiz S, Wolf BR; MOON Shoulder Insta-bility Group, Zhang AL. Surgical stabilization for first-time shoulder dislocators: a multicenter analysis. J Shoulder Elbow Surg. 2018;27(4):674-685.Sampson TG. Complications of hip arthroscopy. Clin Sports Med. 2001;20:831-835.Samuelsson K, Andersson D, Karlsson J. Treatment of anterior cru-ciate ligament injuries with special reference to graft type and surgical technique: an assessment of randomized controlled tri-als. Arthroscopy. 2009;25:1139-1174.Sekiya JK, West RV, Groff YJ, et al. Clinical outcomes following isolated lateral meniscal allograft transplantation. Arthroscopy. 2008;22:771-780.Seldes RM, Tan V, Hunt J, et al. Anatomy, histologic features, and vascularity of the adult acetabular labrum. Clin Orthop Relat Res. 2001;382:232-240.Seon JK, Song EK. Reconstruction of isolated posterior cruciate ligament injuries: a clinical comparison of the transtibial and tibial inlay techniques. Arthroscopy. 2006;22:27-32.Silliman JF, Hawkins RJ. Classification and physical diagnosis of instability of the shoulder. Clin Orthop Relat Res. 1993;291:7-19.Simovitch R, Sanders B, Ozbaydar M, et al. Acromioclavicular joint injuries: diagnosis and management. J Am Acad Orthop Surg. 2009;17(4):207-219.Snyder SJ, Karzel RP, Del Pizzo W, Ferkel RD, Friedman MJ. SLAP lesions of the shoulder. Arthroscopy. 1990;6(4):274-279.Swenson TM, Harner CD. Knee ligament and meniscal injuries. Current concepts. Orthop Clin North Am. 1995;26(3):529-546.Tannast M, Siebenrock KA, Anderson SE. Femoroacetabular impingement: radiographic diagnosis—what the radiologist should know. Am J Roentgenol. 2007;188(6):1540-1552.Tashman S, Kolowich P, Collon D, et al. Dynamic function of the ACL-reconstructed knee during running. Clin Orthop Relat Res. 2007;454:66-73.Van Eck CF, Lesniak BP, Schreiber VM, et al. Anatomic singleand double-bundle anterior cruciate ligament reconstruction flow-chart. Arthroscopy. 2010;26:258-268.Verma NN, Dunn W, Adler RS, et al. All-arthroscopic versus mini-open rotator cuff repair: a retrospective review with minimum 2-year follow-up. Arthroscopy. 2006;22:587-594.Weaver JK, Dunn HK. Treatment of acromioclavicular injuries, especially complete acromioclavicular separation. J Bone Joint Surg. 1972;54(6):1187-1194.Wolf RS, Zheng N, Weichel D. Long head biceps tenotomy versus tenodesis: a cadaveric biomechanical analysis. Arthroscopy. 2005;21:182-185.SpineAnderson LD, D’alonzo RT. Fractures of the odontoid process of the axis. J Bone Joint Surg. 1974;56(8):1663-1674.Apuzzo ML, Heiden JS, Weiss MH, Ackerson TT, Harvey JP, Kurze T. Acute fractures of the odontoid process: an analysis of 45 cases. J Neurosurg. 1978 Jan;48(1):85-91.Asher MA, Burton DC. Adolescent idiopathic scoliosis: natural history and long term treatment effects. Scoliosis. 2006;1(1):2.Bailitz J, Starr F, Beecroft M, et al. CT should replace three-view radiographs as the initial screening test in patients at high, moderate, and low risk for blunt cervical spine injury: a prospective comparison. J Trauma. 2009;66(6):1605-1609.Bellabarba C, Mirza SK, West GA, et al. Diagnosis and treatment of craniocervical dislocation in a series of 17 consecutive survivors during an 8-year period. J Neurosurg Spine. 2006;4(6): 429-440.Ben Galim PJ, Sibai T, Hipp JA, et al. Internal decapitation: survival after head to neck dissociation injuries. Spine. 2008;33(16):1744-1749.Bransford RJ, Alton TB, Patel AR, Bellabarba C. Upper cervical spine trauma. J Am Acad Orthop Surg. 2014;22(11):718-729.Ceroni D, Mousny M, Lironi A, Kaelin A. Pediatric seatbelt inju-ries: unusual Chance’s fracture associated with intra-abdominal lesions in a child. Eur Spine J. 2004;13(2):167-171.Deyo RA, Mirza SK, Martin BI, Kreuter W, Goodman DC, Jarvik JG. Trends, major medical complications, and charges associ-ated with surgery for lumbar spinal stenosis in older adults. JAMA. 2010;303(13):1259-1265.Dimar JR, Glassman SD, Raque GH, Zhang YP, Shields CB. The influence of spinal canal narrowing and timing of decompres-sion on neurologic recovery after spinal cord contusion in a rat model. Spine. 1999;24:1623-1633.Elgafy H, Bransford RJ, Chapman JR. Epidural hematoma associ-ated with occult fracture in ankylosing spondylitis patient: a case report and review of the literature. J Spinal Disord Tech. 2011;24(7):469-473.El-Khoury GY, Kathol MH, Daniel WW. Imaging of acute injuries of the cervical spine: value of plain radiography, CT, and MR imaging. AJR Am J Roentgenol. 1995;164(1):43-50.Fehlings MG, Sekhon LH, Tator C. The role and timing of decompression in acute spinal cord injury. Spine. 2001;26: s101-s110.Fehlings MG, Tator CH. An evidence-based review of decompres-sive surgery in acute spinal cord injury: rationale, indications, and timing based on experimental and clinical studies. J Neuro-surg Spine. 1999;91:1-11.Genevay S, Courvoisier DS, Konstantinou K, et al. Clinical classification criteria for neurogenic claudication caused by lumbar spinal stenosis. The N-CLASS criteria. Spine J. 2018;18(6):941-947.Joaquim AF, Patel AA, Schroeder GD, Vaccaro AR. A simplified treatment algorithm for treating thoracic and lumbar spine trauma. J Spinal Cord Med. 2018;7:1-11.Kesterson L, Benzel E, Orrison W, Coleman J. Evaluation and treat-ment of atlas burst fractures (Jefferson fractures). J Neurosurg. 1991;75(2):213-220.Kwon BK, Vaccaro AR, Grauer JN, Fisher CG, Dvorak MF. Subaxial cervical spine trauma. J Am Acad Orthop Surg. 2006;14(2):78-89.Li XF, Dai LY, Lu H, Chen XD. A systematic review of the manage-ment of hangman’s fractures. Eur Spine J. 2006;15(3):257-269.Brunicardi_Ch43_p1879-p1924.indd 192122/02/19 10:42 AM 1922SPECIFIC CONSIDERATIONSPART IIMacias CA, Rosengart MR, Puyana JC, et al. The effects of trauma center care, admission volume, and surgical volume on paralysis after traumatic spinal cord injury. Ann Surg. 2009;249(1):10-17.McAFEE PC, Yuan HA, Lasda NA. The unstable burst fracture. Spine. 1982;7(4):365-373.Negrini S, Aulisa AG, Aulisa L, et al. 2011 SOSORT guidelines: orthopaedic and rehabilitation treatment of idiopathic scoliosis during growth. Scoliosis. 2012;7(1):3.Reid AB, Letts RM, Black GB. Pediatric Chance fractures: associa-tion with intra-abdominal injuries and seatbelt use. J Trauma. 1990;30(4):384-391.Rorabeck CH, Rock MG, Hawkins RJ, Bourne RB. Unilateral facet dislocation of the cervical spine. An analysis of the results of treatment in 26 patients. Spine. 1987;12(1):23-27.Shapiro S. Medical realities of cauda equina syndrome secondary to lumbar disc herniation. Spine. 2000;25(3):348-352.Shields CB, Zhang YP, Shields LB, Han Y, Burke DA, Mayer NW. The therapeutic window for spinal cord decompression in a rat spinal cord injury model. J Neurosurg Spine. 2005;3: 302-307.Spector LR, Madigan L, Rhyne A, Darden B 2nd, Kim D. Cauda equina syndrome. J Am Acad Orthop Surg. 2008;16(8):471-479.Tambe AD, Panikkar SJ, Millner PA, Tsirikos AI. Current concepts in the surgical management of adolescent idiopathic scoliosis. Bone Joint J. 2018;100-B(4):415-424.Weiss HR, Negrini S, Rigo M, et al. Indications for conservative management of scoliosis (guidelines). Scoliosis. 2006;1(1):5.Wolf A, Levi L, Mirvis S, Ragheb J, Huhn S, Rigamonti D, Robinson WL. Operative management of bilateral facet dislocation. J Neurosurg. 1991;75(6):883-890.Joint ReconstructionAbu-Amer Y, Darwech I, Clohisy JC. Aseptic loosening of total joint replacements: mechanisms underlying osteolysis and potential therapies. Arthritis Res Ther. 2007;9(suppl 1):S6.Alazzawi S, Bardakos NV, Hadfield SG, Butt U, Beer ZH, Field RE. Patient-reported complications after elective joint replacement surgery: are they correct? Bone Joint Surg Br. 2012;94(8):1120-1125.American Academy of Orthopaedic Surgeons. Treatment of Osteo-arthritis of the Knee: Evidence-Based Guideline. 2nd ed. May 18, 2013. Available at: www.aaos.org/cc_files/aaosorg/research/guidelines/treatmentofosteoarthritisofthekneeguideline.pdf. Accessed August 14, 2018.Beckenbaugh RD, Ilstrup DM. Total hip arthroplasty. J Bone Joint Surg Am. 1978;60(3):306-313.Berry DJ, Von Knoch M, Schleck CD, Harmsen WS. Effect of fem-oral head diameter and operative approach on risk of disloca-tion after primary total hip arthroplasty. J Bone Joint Surg Am. 2005;87(11):2456-2463.Bergin PF, Doppelt JD, Kephart CJ, et al. Comparison of mini-mally invasive direct anterior vs. posterior total hip arthroplasty. J Bone Joint Surg Am. 2011;93(15):1392-1398.Berstock JR, Blom AW, Beswick AD. A systematic review and meta-analysis of complications following the posterior and lat-eral surgical approaches to total hip arthroplasty. Ann R Coll Surg Engl. 2015;97(1):11-16.Callahan LF, Rao J, Boutaugh M. Arthritis and women’s health: prevalence, impact, and prevention. Am J Prev Med. 1996;12(5):401-409.Chechik O, Khashan M, Lador R, Salai M, Amar E. Surgical approach and prosthesis fixation in hip arthroplasty world wide. Arch Orthop Trauma Surg. 2013;133:1595-1600.Cheng YJ, Hootman JM, Murphy LB, Langmaid GA, Helmick CG. Prevalence of doctor-diagnosed arthritis and arthritis-attribut-able activity limitation—United States, 2007-2009. MMWR. 2010;59(39):1261-1265.Davis CM III, Berry DJ, Harmsen WS. Cemented revision of failed uncemented femoral components of total hip arthroplasty. J Bone Joint Surg Am. 2003;85-A(7):1264-1269.Felson DT, Zhang Y. An update on the epidemiology of knee and hip osteoarthritis with a view to prevention. Arthritis Rheum. 1998;41(8):1343-1355.Furner SE, Hootman JM, Helmick CG, Bolen J, Zack MM. Health-related quality of life of US adults with arthritis: analysis of data from the behavioral risk factor surveillance system, 2003, 2005, and 2007. Arthritis Care Res (Hoboken). 2011;63(6):788-799.Haaker RG, Tiedjen K, Ottersbach A, Rubenthaler F, Stockheim M, Stiehl JB. Comparison of conventional versus computer-navigated acetabular component insertion. J Arthroplasty. 2007;22(2):151-159.Hardinge K. The direct lateral approach to the hip. J Bone Joint Surg Br. 1982;64(1):17-19.Hootman JM, Helmick CG. Projections of U.S. prevalence of arthritis and associated activity limitations. Arthritis Rheum. 2006;54(1):266-229.Hürlimann M, Schiapparelli FF, Rotigliano N, Testa E, Amsler F, Hirschmann MT. Influence of surgical approach on hetero-topic ossification after total hip arthroplasty—is minimal inva-sive better? A case control study. BMC Musculoskelet Disord. 2017;18(1):27.Jewett BA, Collis DK. High complication rate with anterior total hip arthroplasties on a fracture table. Clin Orthop Rel Res. 2010;469(2):503-507.Johnston RC, Brand RA, Crowninshield RD. Reconstruction of the hip. A mathematical approach to determine optimum geometric relationships. J Bone Joint Surg Am. 1979;61:639-652.Jones CW, Jerabek SA. Current role of computer navigation in total knee arthroplasty. J Arthroplasty. 2018;33(7):1989-1993.Kim YH, Park JW, Kim JS. Computer-navigated versus conven-tional total knee arthroplasty: a prospective randomized trial. J Bone Joint Surg Am. 2012;94(22):2017-2024.Kurtz S, Ong K, Lau E, Mowat F, Halpern M. Projections of primary and revision hip and knee arthroplasty in the United States from 2005 to 2030. J Bone Joint Surg Am. 2007;89(4):780-785.Kwon MS, Kuskowski M, Mulhall KJ, Macaulay W, Brown TE, Saleh KJ. Does surgical approach affect total hip arthroplasty dislocation rates? Clin Orthop Relat Res. 2006;447:34-38.Maratt JD, Gagnier JJ, Butler PD, Hallstrom BR, Urquhart AG, Roberts KC. No difference in dislocation seen in anterior vs posterior approach total hip arthroplasty. J Arthroplasty. 2016;31(9):127-130.Meneghini, R. Michael, et al. Direct anterior approach: risk factor for early femoral failure of cementless total hip arthroplasty: a multicenter study. J Bone Joint Surg Am. 2017;99(2):99-105.Miller, Larry E., et al. Does surgical approach affect outcomes in total hip arthroplasty through 90 days of follow-up? A systematic review with meta-analysis. J Arthroplasty. 2018;33(4):1296-1302.Murphy L, Schwartz TA, Helmick CG, et al. Lifetime risk of symptomatic knee osteoarthritis. Arthritis Rheum. 2008;59(9):1207-1213.Pai VS. A modified direct lateral approach in total hip arthroplasty. J Orthop Surg. 2002;10(1):35-39.Penninx BW, Messier SP, Rejeski WJ, et al. Physical exercise and the prevention of disability in activities of daily liv-ing in older persons with osteoarthritis. Arch Intern Med. 2001;161(19):2309-2316.Pivec R, Johnson AJ, Mears SC, et al. Hip arthroplasty. Lancet. 2012;380(9855):1768-1777.Pospischill M, Kranzl A, Attwenger B, Knahr K. Minimally inva-sive compared with traditional transgluteal approach for total hip arthroplasty: a comparative gait analysis. J Bone Joint Surg Am. 2010;92(2):328-337.Brunicardi_Ch43_p1879-p1924.indd 192222/02/19 10:42 AM 1923ORTHOPEDIC SURGERYCHAPTER 43Sassoon A, Nam D, Nunley R, et al. Systematic review of patient-specific instrumentation in total knee arthroplasty: new but not improved. Clin Orthop Relat Res. 2015;473(1):151-158.Shih M, Hootman JM, Kruger J, Helmick CG. Physical activity in men and women with arthritis National Health Interview Survey, 2002. Am J Prev Med. 2006;30(5):385-393.Soong M, Rubash HE, Macaulay W. Dislocation after total hip arthroplasty. Am Acad Orthop Surg. 2004;12:314-321.Taunton MJ, Trousdale RT, Sierra RJ, Kaufman K, Pagnano MW. John Charnley award: Randomized Clinical Trial of Direct Anterior and Miniposterior Approach THA: Which Provides Better Functional Recovery? Clin Orthop Rel Res. 2018;476(2):216-229.Tronzo RG. Surgical approaches to the hip. Surgery of the Hip Joint. New York: Springer; 1984:75-113.Vail T, Callaghan J. Minimal incision total hip arthroplasty. J Am Acad Orthop Surg. 2007;15:707-715.Whatling GM, Dabke HV, Holt CA, Jones L, Madete J, Alderman PM, Roberts P. Objective functional assessment of total hip arthroplasty following two common surgical approaches: the posterior and direct lateral approaches. Proc Inst Mech Eng H. 2008;222(6):897-905.Whiteside LA. Soft tissue balancing: the knee. J Arthroplasty. 2002;17(4):23-27.Orthopedic OncologyAndresen KJ, Sundaram M, Unni KK, Sim FH. Imaging features of low-grade central osteosarcoma of the long bones and pelvis. Skeletal Radiol. 2004;33(7):373-379.Becker N. Epidemiology of multiple myeloma. In: Moehler T, Goldschmidt H, eds. Multiple Myeloma. Berlin: Springer; 2011:25-35.Chakarun CJ, Forrester DM, Gottsegen CJ, Patel DB, White EA, Matcuk Jr GR. Giant cell tumor of bone: review, mim-ics, and new developments in treatment. Radiographics. 2013;33(1):197-211.Coleman RE. Clinical features of metastatic bone disease and risk of skeletal morbidity. Clin Cancer Res. 2006;12(20): 6243s-6249s.Dai X, Ma W, He X, Jha RK. Review of therapeutic strategies for osteosarcoma, chondrosarcoma, and Ewing’s sarcoma. Med Sci Monit. 2011;17(8):RA177-190.Gaspar N, Hawkins DS, Dirksen U, et al. Ewing sarcoma: current management and future approaches through collaboration. J Clin Oncol. 2015;33(27):3036-3046.Giuffrida AY, Burgueno JE, Koniaris LG, Gutierrez JC, Duncan R, Scully SP. Chondrosarcoma in the United States (1973 to 2003): an analysis of 2890 cases from the SEER database. J Bone Joint Surg Am. 2009;91(5):1063-1072.Inwards CY, Wenger D. Parosteal osteosarcoma. In: Tumors and Tumor-Like Lesions of Bone. London: Springer; 2015: 217-226.Jawad MU, Cheung MC, Min ES, Schneiderbauer MM, Koniaris LG, Scully SP. Ewing’s sarcoma demonstrates racial disparities in incidence-related and sex-related differences in outcome: an analysis of 1631 cases from the SEER database, 1973-2005. Cancer. 2009;115(15):3526-3536.Klenke FM, Wenger DE, Inwards CY, Rose PS, Sim FH. Giant cell tumor of bone: risk factors for recurrence. Clin Orthopaed Relat Res. 2011;469(2):591-599.Kyle RA, Rajkumar SV. Criteria for diagnosis, staging, risk strati-fication and response assessment of multiple myeloma. Leukemia. 2009;23(1):3-9.Luetke A, Meyers PA, Lewis I, Juergens H. Osteosarcoma treat-ment–where do we stand? A state of the art review. Cancer Treat Rev. 2014;40(4):523-532.Mankin HJ, Hornicek FJ. Paget’s sarcoma: a historical and outcome review. Clin Orthopaed Relat Res. 2005;438:97-102.Mirabello L, Troisi RJ, Savage SA. Osteosarcoma incidence and survival rates from 1973 to 2004: data from the sur-veillance, epidemiology, and end results program. Cancer. 2009;115(7):1531-1543.Most MJ, Sim FH, Inwards CY. Osteofibrous dysplasia and ada-mantinoma. J Am Acad Orthop Surg. 2010;18(6):358-366.Rougraff BT. Evaluation of the patient with carcinoma of unknown origin metastatic to bone. Clin Orthop Relat Res. 2003;415(suppl):S105-S109.Spychalski JN, Thomas BJ. Treatment and rehabilitation of patho-logic fractures. State of the Art Reviews: Physical Medicine and Rehabilitation. 1995;9(1):77-92.Visuri T, Pukkala E, Paavolainen P, Pulkkinen P, Riska EB. Cancer risk after metal on metal and polyethylene on metal total hip arthroplasty. Clin Orthop Relat Res. 1996; (329 suppl):S280-S289.Walcott BP, Nahed BV, Mohyeldin A, Coumans JV, Kahle KT, Ferreira MJ. Chordoma: current concepts, management, and future directions. Lancet Oncol. 2012;13(2):e69-e76.Pediatric OrthopedicsBoardman MJ, Herman MJ, Buck B, Pizzutillo PD. Hip fractures in children. J Am Acad Orthop Surg. 2009;17(3):162-173.Brown JH, DeLuca SA. Growth plate injuries: Salter-Harris clas-sification. Am Fam Phys. 1992;46(4):1180-1184.Crawford AH, Mehlman CT, Slovek RW. The fate of untreated developmental dislocation of the hip: Longterm follow-up of eleven patients. J Pediatr Orthop. 1999;19(5):641-644; 369(9572):1541-1552.Foad SL, Mehlman CT, Ying J. The epidemiology of neonatal bra-chial plexus palsy in the United States. J Bone Joint Surg Am. 2008;90:1258-1264.Flynn JM, Schwend RM. Management of pediatric femoral shaft fractures. J Am Acad Orthop Surg. 2004;12(5):347-359.Gilbert A, Khouri N, and Carloiz H. Birth palsy of the brachial plexus—surgical exploration and attempted repair in twenty one cases (in French). Rev Chir Orthop Reparatrice Appar Mot. 1980;66:33-42.Herring JA, Tachdjian MO. Tachdjian’s Pediatric Orthopedics. 5th ed. Philadelphia: Saunders/Elsevier; 2014.Jessel RH, Zurakowski D, Zilkens C, Burstein D, Gray ML, Kim YJ. Radiographic and patient factors associated with pre-radiographic osteoarthritis in hip dysplasia. J Bone Joint Surg Am. 2009;91(5):1120-1129.Jowett CR, Morcuende JA, Ramachandran M. Management of con-genital talipes equinovarus using the Ponseti method: a system-atic review. J Bone Joint Surg Br. 2011;93(9):1160-1164.Kim HK. Legg-Calve-Perthes disease. J Am Acad Orthop Surg. 2010;18(11):676-686.Lee SS, Mahar AT, Miesen D, Newton PO. Displaced pediat-ric supracondylar humerus fractures: biomechanical analy-sis of percutaneous pinning techniques. J Pediatr Orthop. 2002;22(4):440-443.Lincoln TL, Suen PW. Common rotational variations in children. J Am Acad Orthop Surg. 2003;11(5):312-320.Loder RT, Aronsson DD, Weinstein SL, Breur GJ, Ganz R, Leunig M. Slipped capital femoral epiphysis. Instr Course Lect. 2008;57:473-498.Mahan ST, Katz JN, Kim YJ. To screen or not to screen? A decision analysis of the utility of screening for developmental dysplasia of the hip. J Bone Joint Surg Am. 2009;91(7):1705-1719.Murray AW, Wilson NI. Changing incidence of slipped capital fem-oral epiphysis: a relationship with obesity? J Bone Joint Surg Br. 2008;90(1):92-94.O’Donnell S. Pediatric ankle fractures. In: The Orthopedic Consult Survival Guide. New York: Springer; 2017:265-269.Palocaren T, Holmes L, Rogers K, Kumar SJ. Outcome of in situ pinning in patients with unstable slipped capital femoral Brunicardi_Ch43_p1879-p1924.indd 192322/02/19 10:42 AM 1924SPECIFIC CONSIDERATIONSPART IITokmakova KP, Stanton RP, Mason DE. Factors influenc-ing the development of osteonecrosis in patients treated for slipped capital femoral epiphysis. J Bone Joint Surg Am. 2003;85(5):798-801.Trousdale RT. Acetabular osteotomy: indications and results. Clin Orthop Relat Res. 2004;429:182-187.Wainwright AM, Auld T, Benson MK, Theologis TN. The clas-sification of congenital talipes equinovarus. Bone Joint J. 2002;84(7):1020-1024.Weiler R, Ingram M, Wolman R. Osgood-Schlatter disease. Br Med J (Online). 2011;1:343.epiphysis: assessment of risk factors associated with avascular necrosis. J Pediatr Orthop. 2010;30(1):31-36.Parsch K, Weller S, Parsch D. Open reduction and smooth Kirschner wire fixation for unstable slipped capital femoral epiphysis. J Pediatr Orthop. 2009;29(1):1-8.Rosenbaum P, Paneth N, Leviton A, et al. A report: the definition and classification of cerebral palsy April 2006. Dev Med Child Neurol Suppl. 2007;109(suppl 109):8-14.Sjöberg I, Erichs K, Bjerre I. Cause and effect of obstetric (neonatal) brachial plexus palsy. Acta Paediatrica. 1988;77(3): 357-364.Stevenson DA, Mineau G, Kerber RA, Viskochil DH, Schaefer C, Roach JW. Familial predisposition to developmental dysplasia of the hip. J Pediatr Orthop. 2009;29(5):463-466.Brunicardi_Ch43_p1879-p1924.indd 192422/02/19 10:42 AM
Surgery of the Hand and WristScott D. Lifchez and Brian H. Cho 44chapterINTRODUCTIONThe highly mobile, functional, and strong hand is a major dis-tinguishing point between humans and the nonhuman primates. The hand is an essential participant for activities of daily living, vocation, and recreational activities. The hand is even adaptable enough to read for the blind and speak for the mute. The under-lying goal of all aspects of hand surgery is to maximize mobil-ity, sensibility, stability, and strength while minimizing pain. These goals are then maximized to the extent possible given the patient’s particular pathology. Hand surgery is a regional specialty.Hand surgeons integrate components of neurologic, ortho-pedic, plastic, and vascular surgery in the care of patients with disorders of the upper extremities.1ANATOMY OF THE HAND AND WRISTIn order to understand any disorder of the hand, one must under-stand the anatomy of the underlying structures. Examina-tion of the hand is based on demonstrating the function or lack thereof of each of these structures.BonesThe hand is highly mobile in space to allow maximum flex-ibility in function. As such, a number of directions particular to the hand are necessary in order to properly describe posi-tion, motion, and so on.1 Palmar (or volar) refers to the anterior surface of the hand in the anatomic position; dorsal refers to the posterior surface in the anatomic position. The hand can rotate at the wrist level; rotation to bring the palm down is called 2Introduction 1925Anatomy of the Hand  and Wrist 1925Bones / 1925Muscles Affecting the Hand and Wrist / 1926Tendons and Pulleys / 1929Vascular / 1929Nerve / 1930Hand Examination 1931Emergency Department/Inpatient Consultation / 1931Hand Imaging 1932Plain X-Rays / 1932Computed Tomography / 1932Ultrasonography / 1932Magnetic Resonance Imaging / 1933Angiography / 1933Trauma 1933Fractures and Dislocations / 1934Tendons / 1935Nerve Injuries / 1936Vascular Injuries / 1936Anesthesia 1936Local Anesthesia / 1936Hand Surgery Under Local Anesthesia / 1938Postoperative Pain Management / 1938Special Considerations 1938Amputations and Replantation / 1938Fingertip Injuries / 1938High-Pressure Injection Injuries / 1939Compartment Syndrome / 1939Complications 1943Nonunion / 1943Stiffness / 1943Neuroma / 1943Regional Pain Syndromes / 1943Nerve Compression 1943Carpal Tunnel Syndrome / 1944Cubital Tunnel Syndrome / 1944Other Sites of Nerve Compression / 1945Degenerative Joint Disease 1945Small Joints (Metacarpophalangeal and Interphalangeal) 1945Wrist / 1945Rheumatoid Arthritis / 1946Dupuytren’s Contracture 1947Infections 1947Cellulitis / 1947Abscess / 1948Collar-Button Abscess / 1948Osteomyelitis / 1949Pyogenic Arthritis / 1949Necrotizing Infections / 1949Infectious Flexor Tenosynovitis / 1950Felon / 1951Paronychia / 1951Tumors 1952Benign Soft Tissue Tumors / 1953Malignant Soft Tissue Tumors— Cutaneous / 1955Malignant Soft Tissue Tumors—Noncutaneous / 1956Benign Bone Tumors / 1956Malignant Bone Tumors / 1957Secondary Metastatic Tumors / 1958Burns 1958Acute Management / 1958Surgical Management / 1959Reconstruction / 1959Special Considerations / 1960Vascular Disease 1960Progressive Thrombotic Disease / 1960Systemic Vasculopathy / 1960Vasospastic Disorders / 1961Congenital Differences 1961Failure of Formation / 1961Failure of Differentiation / 1961Duplication / 1961Overgrowth / 1961Constriction Band Syndrome / 1961Generalized Skeletal Anomalies and Syndromes / 1961Reconstructive Transplantation  of the Upper Extremity 1962Brunicardi_Ch44_p1925-p1966.indd 192520/02/19 2:48 PM 1926pronation, and rotation to bring the palm up is called supina-tion. Because the hand can rotate in space, the terms medial and lateral are avoided. Radial and ulnar are used instead as these terms do not vary with respect to the rotational position of the hand. Abduction and adduction, when used on the hand, refer to movement of the digits away from and toward the middle finger, respectively (Fig. 44-1).The hand is comprised of 19 bones arranged in five rays.2 A ray is defined as a digit (finger or thumb) from the metacarpal base to the tip of the digit (Fig. 44-2A). The rays are numbered 1 to 5, beginning with the thumb. By convention, however, they are referred to by name: thumb, index, middle, ring, and small. There are five metacarpals, comprising the visible palm of the hand. Each digit has a proximal and a distal phalanx, but only the fingers have a middle phalanx as well. The metacarpopha-langeal (MP) joint typically allows 90° of flexion with a small amount of hyperextension. In addition, the fingers can actively abduct (move away from the middle finger) and adduct (move toward the middle finger). The thumb, in contrast, moves prin-cipally in the flexion-extension arc at the MP joint. Although there can be laxity in the radial and ulnar direction, the thumb cannot actively move in these directions at the MP level. The proximal interphalangeal joint (PIP) is the critical joint for finger mobility. Normal motion is 0° to 95° (full extension to flexion). The distal interphalangeal joint (DIP) also moves only in a flexion-extension plane from 0° to 90° on average. The thumb interphalangeal joint (IP) also moves only in a flexion-extension plane. Its normal motion is highly variable between individuals, but averages 0° to 80°.Each of the MP and IP joints has a radial and ulnar col-lateral ligament to support it. The IP joint collateral ligaments are on tension with the joint fully extended. For the fingers, the MP joint collateral ligaments are on tension with the joint bent 90°. Collateral ligaments have a tendency to contract when not placed on tension; this becomes relevant when splinting the hand (see later “Trauma” section on splinting).The wrist consists of eight carpal bones divided into two rows (see Fig. 44-2B).2 The proximal row consists of the scaph-oid, lunate, and triquetrum. The lunate is the principle axis of motion of the hand onto the forearm. It bears approximately 35% of the load of the wrist onto the forearm. The scaphoid is shaped like the keel of a boat and bears 55% of the load of the hand onto the forearm, but it also serves as the principle link between the proximal and distal rows, allowing for motion while maintaining stability. Both the scaphoid and the lunate articulate with the radius. The triquetrum resides ulnar to the lunate. It does not interact with the ulna proximally; rather, it interacts with a cartilage suspended between the ulnar styloid and the distal radius called with triangular fibrocartilage com-plex (TFCC) (see Fig. 44-2B). The remaining 10% of load of the hand onto the forearm is transmitted through the TFCC.3The distal row consists of four bones. The trapezium resides between the scaphoid and the thumb metacarpal. Dis-tally, it has a saddle-shaped surface, which interacts with a reciprocally saddle-shaped base of the thumb metacarpal to allow for high mobility of the thumb carpometacarpal (CMC) joint in radial-ulnar and palmar-dorsal directions and opposition (Fig. 44-1B). The trapezoid rests between the scaphoid and the index finger metacarpal. The capitate, the largest carpal bone and first to ossify in a child, lies between the lunate and the middle finger metacarpal, but it also interacts with the scaph-oid on its proximal radial surface. The index and middle finger CMC joints are highly stable and have minimal mobility. The hamate is the ulnar-most bone in the distal row, sitting between the triquetrum proximally and the ring and small finger metacar-pals distally. The ring and small finger CMC joints are mobile, principally in the flexion-extension direction.The pisiform is a carpal bone only by geography. It is a sesamoid bone within the FCU tendon (see following section). It does not bear load and can be excised, when necessary, without consequence.Muscles Affecting the Hand and WristThe wrist is moved by multiple tendons that originate from the forearm and elbow. The digits of the hand are moved by both intrinsic (originating within the hand) and extrinsic (originating in the forearm) muscles. All of these muscles are innervated by the median, radial, or ulnar nerves (or their branches) (Fig. 44-3).Three muscles flex the wrist, all of which originate from the medial epicondyle of the humerus. The flexor carpi radialis (FCR, median nerve) inserts on the volar base of the index fin-ger metacarpal. The flexor carpi ulnaris (FCU, ulnar nerve) also originates from the proximal ulna and inserts on the volar base of the small finger metacarpal. The palmaris longus (PL) tendon does not insert on a bone; it inserts on the palmar fascia, located deep to the skin in the central proximal palm, and is absent in up to 15% of patients. The FCR also deviates the wrist radially, whereas the FCU deviates the wrist ulnarly.All three wrist extensors are innervated by the radial nerve or its branches. The extensor carpi radialis longus (ECRL) Key Points1 Surgery of the hand is a regional specialty, integrating com-ponents of neurologic, orthopedic, plastic, and vascular surgery.2 Understanding hand anatomy is the key to proper diagnosis of injury, infection, and degenerative disease of the hand.3 After evaluation and/or treatment, patients should be splinted to protect the injured digits and keep the collateral ligaments of the injured joints on tension (metacarpophalangeal joints flexed, interphalangeal joints extended).4 Healing of an injured or diseased structure in the hand is not the endpoint of treatment; the goal of any intervention must be to obtain structure healing, relief of pain, and maximiza-tion of function.5 If a patient managed conservatively for cellulitis does not improve within 24 to 48 hours of appropriate intravenous antibiotics, abscess must be suspected.6 Clinical examination, particularly noting the area of greatest tenderness and/or inflammation, is the most useful diagnos-tic tool for hand infections.Brunicardi_Ch44_p1925-p1966.indd 192620/02/19 2:48 PM 1927SURGERY OF THE HAND AND WRISTCHAPTER 44originates from the distal shaft of the humerus and inserts on the dorsal base of the index finger metacarpal. The extensor carpi radialis brevis (ECRB) originates from the lateral epicondyle of the humerus and inserts on the dorsal base of the middle finger metacarpal. The extensor carpi ulnaris (ECU) also originates from the lateral epicondyle of the humerus and inserts on the dorsal base of the small finger metacarpal. The ECRL deviates the wrist radially, whereas the ECU deviates the wrist ulnarly.The long flexors of the fingers all originate from the medial epicondyle of the humerus. The flexor digitorum super-ficialis (FDS) inserts on the base of the middle phalanx of each finger and primarily flexes the PIP joint. The flexor digitorum profundus (FDP) inserts on the base of the distal phalanx and primarily flexes the DIP joint. The flexor pollicis longus (FPL) originates more distally, from the ulna, radius, and interosseous membrane between them in the forearm. It inserts on the base of the distal phalanx of the thumb and primarily flexes the IP joint. All of these tendons can also flex the more proximal joint(s) in their respective rays. All of these muscles are innervated by the median nerve (or its branches) except the FDP to the ring and small fingers, which are innervated by the ulnar nerve.The extrinsic extensors of the fingers and thumb are all innervated by the posterior interosseous nerve (PIN, branch of the radial nerve). The extensor digitorum communis (EDC) originates from the lateral epicondyle of the humerus and extends the MP joints of the fingers. Unlike most tendons that attach directly into a bone, the EDC tendons do not insert on the dorsal base of the proximal phalanx, but rather into a soft tissue sling called the sagittal hood, which surrounds the proximal phalanx base and pulls up on the volar surface in a ABCDFigure 44-1. Directions of finger, hand, and wrist motion. A. Finger abduction (white arrows) and adduction (black arrows). B. Thumb radial (black arrow) and palmar (white arrow) abduction. C. Thumb and small finger opposition. D. Hand/wrist pronation (black arrow) and supination (white arrow).Brunicardi_Ch44_p1925-p1966.indd 192720/02/19 2:48 PM 1928SPECIFIC CONSIDERATIONSPART IIhammock-like manner. More distally in the dorsal forearm, the extensor indices proprius (EIP) and extensor digiti quinti (EDQ) originate from the ulna, radius, and posterior interosseous mem-brane and insert on the sagittal hood of the index and small fingers, respectively.The thumb has three separate extrinsic extensors. All of these originate from the dorsal ulna in the mid-forearm and are innervated by the PIN. The abductor pollicis longus (APL) inserts on the radial base of the thumb metacarpal to produce some extension, but mostly abduction. The extensor pollicis ECRL/ECRBEPLEDQECUTCL23455432Radial AANUlnarSCHMedian NAPLEPBFPLPFCREIP/EDCFigure 44-3. Cross-section of the wrist at the midcarpal level. The relative geography of the neurologic and tendinous structures can be seen. The transverse carpal ligament (TCL) is the roof of the carpal tunnel, passing volar to the median nerve and long flexor tendons. The TCL is also the floor of the ulnar tunnel, or Guyon’s canal, passing dorsal to the ulnar artery and nerve. The wrist and digital extensor tendons are also seen, distal to their compartments on the distal radius and ulna. Bones: C = capitate; H = hamate; P = pisiform; S = scaphoid. Tendons (flexor digitorum superficialis is volar to flexor digitorum profundus within the carpal tunnel): 2 = index finger; 3 = middle finger; 4 = ring finger; 5 = small finger. A = artery; APL = abductor pollicis longus; ECRB = extensor carpi radialis brevis; ECRL = extensor carpi radialis longus; ECU = extensor carpi ulnaris; EDC = extensor digitorum communis; EDQ = extensor digiti quinti; EIP = extensor indices proprius; EPB = extensor pollicis brevis; EPL = extensor pollicis longus; FCR = flexor carpi radialis; FPL = flexor pollicis longus; N = nerve.ABFigure 44-2. Bony architecture of the hand and wrist. A. Bones of the hand and digits. All rays have metacarpophalangeal (MP) joints. The fingers have proximal and distal interphalangeal joints (PIP and DIP), but the thumb has a single interphalangeal (IP) joint. B. Bones of the wrist. The proximal row consists of the scaphoid, lunate, and capitate. The distal row bones articulate with the metacarpals: the trapezium with the thumb, the trapezoid with the index, the capitate with the middle, and the hamate with the ring and small. The pisiform bone is a sesamoid within the flexor carpi ulnaris tendon. It overlaps the triquetrum and hamate but does not contribute to a carpal row. CMC = carpometacarpal; TFCC = triangular fibrocartilage complex.Brunicardi_Ch44_p1925-p1966.indd 192820/02/19 2:48 PM 1929SURGERY OF THE HAND AND WRISTCHAPTER 44brevis (EPB) inserts on the base of the thumb proximal pha-lanx. The extensor pollicis longus (EPL) inserts on the base of the thumb distal phalanx.The intrinsic muscles of the hand are what allow humans fine, subtle movements of the hand. Microsurgery, typing, and even video gaming would be difficult, if not impossible, without them.The thenar muscles originate from the volar radial surface of the scaphoid and trapezium and the flexor retinaculum. The abductor pollicis brevis (APB) inserts on the radial base of the thumb proximal phalanx and abducts the thumb in a radial and volar direction. The opponens pollicis (OP) inserts on the radial distal aspect of the thumb metacarpal and draws the thumb across the palm toward the small finger. The flexor pollicis bre-vis (FPB) inserts on the base of the thumb proximal phalanx and flexes the thumb MP joint. The APB, OP, and superficial head of the FPB are all innervated by the thenar motor branch of the median nerve.The lumbrical muscles are unique in the body in that they originate from a tendon. Each finger’s lumbrical originates from the FDP tendon in the palm. The lumbrical tendon passes along the radial aspect of the digit to flex the MP and extend the IP joints. The index and middle lumbricals are median nerve inner-vated, and the ring and small finger lumbricals are ulnar nerve innervated.The hypothenar muscles originate from the pisiform, hamate, and flexor retinaculum and insert on the ulnar base of the small finger proximal phalanx. The abductor digiti quinti (ADQ) abducts the small finger. The opponens digiti quinti (ODQ) brings the small finger across the palm in reciprocal motion to the OP. The flexor digiti quinti (FDQ) flexes the small finger metacarpal. All of these muscles are innervated by the ulnar nerve.The interosseous muscles occupy the space between the metacarpal bones. Their tendons insert on the bases of the proxi-mal phalanges. All act to flex the MP joints and extend the IP joints. The three palmar interosseous muscles adduct the fin-gers. The four dorsal interosseous muscles abduct the fingers. The adductor pollicis originates from the middle finger metacar-pal and inserts on the ulnar base of the thumb proximal phalanx. It acts to adduct the thumb. All of these muscles, as well as the deep head of the FPB, are innervated by the ulnar nerve.Tendons and PulleysMultiple pulleys pass over or surround the extrinsic tendons en route to or within the hand. Their purpose is to maintain tendon position near the bone, allowing maximal translation of tendon excursion into joint motion.The most well known of the wrist-level pulleys is the flexor retinaculum, also known as the transverse carpal liga-ment. It attaches to the scaphoid tubercle and trapezium radially and the hook of the hamate bone and pisiform ulnarly. Deep to this ligament, between the scaphoid (radially) and the hamate (ulnarly), pass the FDS, FDP, and FPL tendons as well as the median nerve. This area is also known as the carpal tunnel (see Fig. 44-3).On the dorsum of the wrist, the extensor retinaculum is divided into six compartments. Beginning on the radial aspect of the radius, the first compartment contains the APL and EPB tendons. The second holds the ECRL and ECRB tendons. The EPL passes through the third compartment. The fourth com-partment contains the EIP and EDC tendons, the fifth the EDQ, and the sixth the ECU. The sixth compartment is located on the ulnar aspect of the distal ulna. Although the compartments end at the radiocarpal/ulnocarpal joints, the relative geography of the tendons is preserved over the carpal bones (see Fig. 44-3).In the hand, the pulleys maintain the long flexor tendons in close apposition to the fingers and thumb. There are no extensor pulleys within the hand. Each finger has five annular and three cruciate pulleys (Fig. 44-4). The second and fourth (A2 and A4) pulleys are the critical structures to prevent bowstringing of the finger.3 The remaining pulleys can be divided as needed for sur-gical exposure or to relieve a stricture area.VascularTwo major arteries serve the hand. The radial artery travels under the brachioradialis muscle in the forearm. At the junc-tion of the middle and distal thirds of the forearm, the artery becomes superficial and palpable, passing just radial to the FCR tendon. At the wrist level, the artery splits into two branches. The smaller, superficial branch passes volarly into the palm to contribute to the superficial palmar arch. The larger branch passes dorsally over the scaphoid bone, under the EPL and EPB tendons (known as the anatomic snuffbox) and back volarly between the proximal thumb and index finger metacarpals to form the superficial palmar arch.The ulnar artery travels deep to the FCU muscle in the forearm. When the FCU becomes tendinous, the ulnar artery resides deep and slightly radial to it. At the wrist, the artery travels between the hamate and pisiform bones superficial to the transverse carpal ligament (known as Guyon’s canal) into the palm. The larger, superficial branch forms the superficial A5C3A4C2A3C1A2A1Figure 44-4. Drawing of anteroposterior and lateral view of the pulley system.Brunicardi_Ch44_p1925-p1966.indd 192920/02/19 2:48 PM 1930SPECIFIC CONSIDERATIONSPART IIpalmar arch. The deeper branch contributes to the deep palmar arch (Fig. 44-5A). In 97% of patients, at least one of the deep or superficial palmar arches is intact, allowing for the entire hand to survive on the radial or ulnar artery.5Each digit receives a radial and ulnar digital artery. For the thumb, the radial digital artery may come from the deep palmar arch or the main body of the radial artery. The larger ulnar digi-tal artery comes off the deep arch as either a discrete unit, the princeps pollicis artery, or less frequently as the first common digital artery, which then splits into the radial digital artery to the index finger and the ulnar digital artery to the thumb. The second, third, and fourth digital arteries typically branch off the superficial palmar arch and pass over the similarly named inter-osseous spaces respectively, ultimately dividing into two proper digital arteries each. The ulnar digital artery of the small finger comes off as a separate branch from the superficial arch. Within the finger, the proper digital arteries travel lateral to the bones and tendons, just palmar to the midaxis of the digit, but dorsal to the proper digital nerves (Fig. 44-5B).NerveThree principal nerves serve the forearm, wrist, and hand: the median, radial, and ulnar nerves. The most critical of these from a sensory standpoint is the median nerve. The median nerve begins as a terminal branch of the medial and lateral cords of the brachial plexus. It receives fibers from C5–T1. The palmar cuta-neous branch of the median nerve separates from the main body of the nerve 6 cm proximal to the volar wrist crease and serves the proximal, radial-sided palm. The main body of the median nerve splits into several branches after the carpal tunnel: a radial digital branch to the thumb, an ulnar digital nerve to the thumb, and a radial digital nerve to the index finger (sometimes begin-ning as a single first common digital nerve); the second common digital nerve that branches into the ulnar digital nerve to the index finger and the radial digital nerve to the middle finger; and a third common digital nerve that branches into the ulnar digital nerve to the middle finger and a radial digital nerve to the ring finger. The digital nerves provide volar-sided sensation from the metacarpal head level to the tip of the digit. They also, through their dorsal branches, provide dorsal-sided sensation to the dig-its from the midportion of the middle phalanx distally via dorsal branches. The thenar motor branch of the median nerve most commonly passes through the carpal tunnel and then travels in a recurrent fashion back to the thenar muscles. Less commonly, the nerve passes through or proximal to the transverse carpal ligament en route to its muscles.In the forearm, the median nerve gives motor branches to all of the flexor muscles except the FCU, and the ring and small finger portions of the FDP. Distal median motor fibers (with the exception of those to the thenar muscles) are carried through a large branch called the anterior interosseous nerve.The ulnar nerve is a terminal branch of the medial cord of the brachial plexus. It receives innervation from C8 and T1 roots. The FCU and FDP (ring/small) receive motor fibers from the ulnar nerve. In the distal forearm, 5 cm above the head of the ulna, the nerve gives off a dorsal sensory branch. Once in the hand, the nerve splits into the motor branch and sensory branches. The motor branch curves radially at the hook of the hamate bone to innervate the intrinsic muscles, as described ear-lier. The sensory branches become the ulnar digital nerve to the small finger and the fourth common digital nerve, which splits into the ulnar digital nerve to the ring finger and the radial digi-tal nerve to the small finger. The sensory nerves provide distal dorsal sensation similar to the median nerve branches.The radial nerve is the larger of two terminal branches of the posterior cord of the brachial plexus. It receives fibers from C5–T1 nerve roots. It innervates all of the extensor muscles of the forearm and wrist through the PIN branch except for the ECRL, which is innervated by the main body of the radial nerve in the distal upper arm. There is no ulnar nerve contribution to extension of the wrist, thumb, or finger MP joints. As noted ear-lier, the ulnar innervated intrinsic hand muscles are the principle ABFigure 44-5. Arteries of the hand and finger. A. Relative position of the superficial and deep palmar arches to the bony structures and each other; note the radial artery passes dorsal to the thumb metacarpal base, through the first web space, and anterior to the index metacarpal base as it forms the deep arch. B. The neurovascular bundles lay volar to the midaxis of the digit with the artery dorsal to the nerve; Grayson’s ligament (volar) and Cleland’s ligament (dorsal) connect the bone to the skin surrounding the bundle.Brunicardi_Ch44_p1925-p1966.indd 193020/02/19 2:48 PM 1931SURGERY OF THE HAND AND WRISTCHAPTER 44extensors of the finger IP joints, although the long finger exten-sors (EDC, EIP, EDQ) make a secondary contribution to this function.In the proximal dorsal forearm, the superficial radial nerve (SRN) is the other terminal branch of the radial nerve. It travels deep to the brachioradialis muscle until 6 cm proximal to the radial styloid, where it becomes superficial. The SRN provides sensation to the dorsal hand and the radial three and a half dig-its up to the level of the mid-middle phalanx (where the dorsal branches of the proper digital nerves take over, as described earlier). The dorsal branch of the ulnar nerve provides sensation to the ulnar one and a half digits and dorsal hand in complement to the SRN.HAND EXAMINATIONEmergency Department/Inpatient ConsultationA common scenario in which the hand surgeon will be intro-duced to the patient is in trauma or other acute situations. The patient is evaluated by inspection, palpation, and provocative testing.On inspection, one should first note the position of the hand. The resting hand has a normal cascade of the fingers, with the small finger flexed most and the index finger least (Fig. 44-6). Disturbance of this suggests a tendon or skeletal problem. Also note any gross deformities or wounds and what deeper structures, if any, are visible in such wounds. Observe for abnormal coloration of a portion or all of the hand (this can be confounded by ambient temperature or other injuries), edema, and/or clubbing of the fingertips.Palpation typically begins with the radial and ulnar artery pulses at the wrist level. Pencil Doppler examination can sup-plement this and evaluate distal vessels. A pulsatile signal is normally detectable by pencil Doppler in the pad of the finger at the center of the whorl of creases. Discrepancies between digits should be noted. If all other tests are inconclusive, pricking the involved digit with a 25-gauge needle should produce bright red capillary bleeding. If an attached digit demonstrates inadequate or absent blood flow (warm ischemia), the urgency of complet-ing the evaluation and initiating treatment markedly increases.Sensation must be evaluated prior to any administration of local anesthetic. At a minimum, light and sharp touch sensation should be documented for the radial and ulnar aspects of the tip of each digit. Beware of writing “sensation intact” at the con-clusion of this evaluation. Rather, one should document what was tested (e.g., “light and sharp touch sensation present and symmetric to the tips of all digits of the injured hand”). For a more detailed evaluation of hand sensation, two-point discrimi-nation may be assessed using a bent paperclip or monofilament. In the setting of a sharp injury, sensory deficit implies a lacer-ated structure until proven otherwise. Once sensation has been evaluated and documented, the injured hand can be anesthetized for patient comfort during the remainder of the examination (see below).Ability to flex and extend the wrist and digital joints is typically examined next. At the wrist level, the FCR and FCU tendons should be palpable during flexion. The wrist exten-sors are not as readily palpated due to the extensor retinaculum. Ability to flex the DIP joint (FDP) is tested by blocking the finger at the middle phalanx level. To test the FDS to each finger, hold the remaining three fingers in slight hyperextension and ask the patient to flex the involved digit (Fig. 44-7). This maneuver makes use of the fact that the FDP tendons share a common muscle belly. Placing the remaining fingers in exten-sion prevents the FDP from firing, and allows the FDS, which has a separate muscle belly for each tendon, to fire. Strength in grip, finger abduction, and thumb opposition is tested and compared to the uninjured side. Range of motion for the wrist, MP, and IP joints should be noted and compared to the opposite side.If there is suspicion for closed space infection, the hand should be evaluated for erythema, swelling, fluctuance, and localized tenderness. The dorsum of the hand does not have fascial septae; thus, dorsal infections can spread more widely than palmar ones. The epitrochlear and axillary nodes should be palpated for enlargement and tenderness. Findings for spe-cific infectious processes will be discussed in the “Infections” section.ABFigure 44-6. In the normal resting hand, the fingers assume a slightly flexed posture from the index finger (least) to the small finger (most). A. Anteroposterior view. B. Lateral view.Brunicardi_Ch44_p1925-p1966.indd 193120/02/19 2:48 PM 1932SPECIFIC CONSIDERATIONSPART IIAdditional exam maneuvers and findings, such as those for office consultations, will be discussed with each disease pro-cess covered later in this chapter.HAND IMAGINGPlain X-RaysAlmost every hand evaluation should include plain X-rays of the injured or affected part. A standard, anteroposterior, lateral, and oblique view of the hand or wrist (as appropriate) is rapid, inexpensive, and usually provides sufficient information about the bony structures to achieve a diagnosis in conjunction with the symptoms and findings.6Lucencies within the bone should be noted. Most com-monly, these represent fractures, but they can on occasion rep-resent neoplastic or degenerative processes. Great care should be taken to evaluate the entire X-ray, typically beginning away from the area of the patient’s complaint. Additional injuries can be missed, which might affect the treatment plan selected and eventual outcome.Congruency of adjacent joints should also be noted. The MP and IP joints of the fingers should all be in the same plain on any given view. Incongruency of the joint(s) of one finger implies fracture with rotation. At the wrist level, the proxi-mal and distal edge of the proximal row and proximal edge of the distal row should be smooth arcs, known as Gilula’s arcs (Fig. 44-8A). Disruption of these implies ligamentous injury or possibly dislocation (Fig. 44-8B).7Computed TomographyComputed tomography (CT) scanning of the hand and wrist can provide additional bony information when plain X-rays are insufficient. Comminuted fractures of the distal radius can be better visualized for number and orientation of fragments. Scaphoid fractures can be evaluated for displacement and com-minution preoperatively as well as for the presence of bony bridging postoperatively (Fig. 44-9). Recent studies have sug-gested that in the setting of suspected scaphoid fractures with negative radiographs, the use of CT scans may decrease the healthcare costs and patient morbidity.8 CT scans are also useful for CMC fractures of the hand where overlap on a plain X-ray lateral view may make diagnosis difficult.Unlike the trunk and more proximal extremities, CT scans with contrast are less useful to demonstrate abscess cavities due to the small area of these spaces.UltrasonographyUltrasonography has the advantages of being able to demon-strate soft tissue structures and being available on nights and weekends. Unfortunately, it is also highly operator dependent. In the middle of the night when magnetic resonance imaging (MRI) is not available, ultrasound may be able to demonstrate a Figure 44-7. The examiner holds the untested fingers in full exten-sion, preventing contracture of the flexor digitorum profundus. In this position, the patient is asked to flex the finger, and only the flexor digitorum superficialis will be able to fire.ABFigure 44-8. Gilula’s arcs are seen shown in this normal patient (A) and in a patient with a scaphoid fracture and perilunate dislocation (B).Brunicardi_Ch44_p1925-p1966.indd 193220/02/19 2:48 PM 1933SURGERY OF THE HAND AND WRISTCHAPTER 44Figure 44-9. A. Preoperative images demonstrate a nonunion of a scaphoid fracture sustained 4 years earlier. B. Postoperatively, cross-sectional imaging with a computed tomography scan in the coronal plan demonstrates bone crossing the previous fracture line. This can be difficult to discern on plain X-rays due to overlap of bone fragments.ABlarge deep infection in the hand but is rarely more useful than a thorough clinical examination. Additionally, the use of dynamic ultrasound may be used to evaluate tendon motion and aid in the diagnosis of tendon pathology or injury.9Magnetic Resonance ImagingMRI provides the best noninvasive visualization of the soft tis-sue structures. With contrast, MRI can demonstrate an occult abscess. Unfortunately, it is often not available on an urgent basis for hand issues when this information is often needed. MRI can also demonstrate soft tissue injuries such as cartilage or ligament tears or tendonitis (usually by demonstrating edema in the area in question). It can demonstrate occult fractures that are not sufficiently displaced to be seen on X-ray or CT (again, by demonstrating edema). MRI can also demonstrate vascular disturbance of a bone, as in a patient with avascular necrosis of the scaphoid (Fig. 44-10).AngiographyAngiography of the upper extremity is rarely used. In many cen-ters, MRI and CT angiography provide sufficient resolution of the vascular structures to make traditional angiography unnec-essary. Also, primary vascular disease of the upper extremity is relatively uncommon. In the trauma setting, vascular distur-bance usually mandates exploration and direct visualization of the structures in question, and angiography is thus obviated.For a patient with vascular disease of the upper extrem-ity, angiography of the upper extremity is usually performed through a femoral access much like with the leg. An arterial catheter can be used to deliver thrombolytic drugs to treat a thrombotic process.TRAUMAThe upper extremity–injured patient may have additional inju-ries to other parts of the body. All injured patients should receive an appropriate trauma survey to look for additional injuries.The patient with upper extremity trauma is evaluated as described in the “Hand Examination” section. Sensory exami-nation should be performed early. Once sensory status has been documented, administration of local anesthesia can provide comfort to the patient during the remainder of the evaluation Figure 44-10. T1-weighted magnetic resonance imaging shows perfused bone as white. In this patient, there is the absence of white-ness where the scaphoid should be (dashed circle), consistent with avascular necrosis.Brunicardi_Ch44_p1925-p1966.indd 193320/02/19 2:48 PM 1934SPECIFIC CONSIDERATIONSPART IIand subsequent treatment. Patients with nonclean wounds who received fewer than three prior doses of tetanus toxoid (or more than 5 years since last tetanus vaccination) or have an unknown history of prior doses should receive tetanus immunoglobulin as well as tetanus vaccination.10Fractures and DislocationsFor dislocations and displaced fractures, a visible deformity is often present. Nondisplaced fractures may not show a gross deformity but will have edema and tenderness to palpation at the fracture site. A fracture is described by its displacement, rotation, and angulation. A fracture is also described in terms of comminution and the number and complexity of fracture fragments. Displacement is described as a percentage of the diameter of the bone; rotation is described in degrees of supina-tion or pronation with respect to the rest of the hand; angula-tion is described in degrees. To avoid confusion, it is useful to describe which direction the angle of the fracture points. All injuries should be evaluated for nearby wounds (open) that may introduce bacteria into the fracture site or joint space.Once the initial force on the fracture ceases, the tendons passing beyond the fracture site provide the principal deforming force. Their force is directed proximally and, to a lesser extent, volarly. Based on this, the stability of a fracture can be deter-mined by the orientation of the fracture with respect to the shaft of the bone. Transverse fractures are typically stable. Oblique fractures typically shorten. Spiral fractures typically rotate as they shorten and thus require surgical treatment.Fractures of the tuft of the distal phalanx are common. Catching of a finger in a closing door is a common causative mechanism. These fractures are often nondisplaced and do not require treatment beyond protection of the distal phalanx from additional trauma while the fracture heals.Displaced transverse fractures of the phalanges can usu-ally be reduced with distraction. The distal part is pulled away from the main body of the hand and then pushed in the direc-tion of the proximal shaft of the finger, and then distraction is released. Postreduction X-rays should routinely be performed to document satisfactory reduction. Oblique and spiral frac-tures usually are unstable after reduction. The involved digit(s) should be splinted until appropriate surgical intervention can be performed.Articular fractures of the IP and MP joints are worrisome because they may compromise motion. Chip fractures must be evaluated for instability of the collateral ligaments. If the joint is stable, the patient should initially be splinted for comfort. Motion therapy should be instituted early (ideally within the first week) to prevent stiffness. For larger fractures, the patient should be splinted until surgical treatment can be performed. In surgery, the fracture is typically internally fixated to allow for early motion, again with the goal of preventing stiffness.11,12Dislocations of the PIP joints produce traction on the neurovascular structures but usually do not lacerate them. In general, the patient should not be sent home with a joint that remains dislocated. Most commonly, the distal part is dorsal to the proximal shaft and sits in a hyperextended position. For this patient, the examiner gently applies pressure to the base of the distal part until it passes beyond the head of the proximal phalanx. Once there, the relocated PIP joint is gently flexed, confirming the joint is in fact reduced. The joint is splinted in slight flexion to prevent redislocation. On occasion, the head of the proximal phalanx may pass between the two slips of the FDS tendon. For these patients, the joint may not be reducible in a closed fashion.Angulated fractures of the small finger metacarpal neck (“boxer’s fracture”) are another common injury seen in the ER. Typical history is that the patient struck another individual or rigid object with a hook punch. These are often stable after reduction using the Jahss maneuver (Fig. 44-11).13Fractures of the thumb metacarpal base are often unstable. The Bennett fracture displaces the volar-ulnar base of the bone. The remainder of the articular surface and the shaft typically dislocate dorsoradially and shorten. The thumb often appears grossly shortened, and the proximal shaft of the metacarpal may reside at the level of the trapezium or even the scaphoid on X-ray. In a Rolando fracture, a second fracture line occurs between the remaining articular surface and the shaft. These fractures nearly always require open reduction and internal fixation.Most nondisplaced fractures do not require surgical treat-ment. The scaphoid bone of the wrist is a notable exception to this rule. Due to peculiarities in its vascular supply, particularly vulnerable at its proximal end, nondisplaced scaphoid fractures can fail to unite in up to 20% of patients even with appropriate immobilization. Recent developments in hardware and surgi-cal technique have allowed stabilization of the fracture with minimal surgical exposure. One prospective randomized series of scaphoid wrist fractures demonstrated shortening of time to union by up to 6 weeks in the surgically treated group, but no difference in rate of union.14 Surgery may be useful in the younger, more active patient who would benefit from an earlier return to full activity.Ligament injuries of the wrist can be difficult to recognize. Patients often present late and may not be able to localize their pain. In severe cases, the ligaments of the wrist can rupture to the point of dislocation of the capitate off the lunate or even the lunate off the radius. Mayfield and colleagues classified the progression of this injury into four groups.15 In the most severe group, the lunate dislocates off the radius into the carpal tunnel. In some circumstances, the scaphoid bone may break rather than Figure 44-11. The Jahss maneuver. The surgeon fully flexes the patient’s small finger into the palm and secures it in his distal hand. The proximal hand controls the wrist and places the thumb on the patient’s fracture apex (the most prominent dorsal point). The examiner distracts the fracture, pushes dorsally with the distal hand (up arrow), and resists dorsal motion with the proximal hand (down arrow).Brunicardi_Ch44_p1925-p1966.indd 193420/02/19 2:48 PM 1935SURGERY OF THE HAND AND WRISTCHAPTER 44the scapholunate ligament rupturing. Attention to the congru-ency or disruption of Gilula’s arcs will help the examiner to recognize this injury. For patients with type 4 (most severe) and some with type 3 injury, the examiner should also evaluate for sensory disturbance in the median nerve distribution because this may indicate acute carpal tunnel syndrome and necessitate more urgent intervention. Although the Mayfield pattern of injury is most common, force can also transmit along alternate paths through the carpus.16After reduction of fractures and dislocations (as well as after surgical repair of these and many other injuries), the hand must be splinted in a protected position. For the fingers, MP joints should be splinted 90°, and the IP joints at 0° (called the intrinsic plus position). The wrist is generally splinted at 20° extension because this puts the hand in a more functional posi-tion. This keeps the collateral ligaments on tension and helps prevent secondary contracture. In general, one of three splints should be used for the emergency department (ED) patient (Fig. 44-12). The ulnar gutter splint uses places plaster around the ulnar border of the hand. It is generally appropriate for small finger injuries only. Dorsal plaster splints can be used for injuries of any of the fingers. Plaster is more readily con-toured to the dorsal surface of the hand than the volar surface, particularly in the setting of trauma-associated edema. For thumb injuries, the thumb spica splint is used to keep the thumb radially and palmarly abducted from the hand. Lastly, sugar tong splints include a volar and dorsal slab that includes the elbow in order to prevent supination and pronation. Sugar tong splints are most often used in the setting of acute distal radius or ulna fractures.TendonsInjuries to the flexor and extensor tendons compromise the mobility and strength of the digits. On inspection, injury is nor-mally suspected by loss of the normal cascade of the fingers. The patient should be examined as described earlier to evaluate for which tendon motion is deficient. If the patient is unable to cooperate, extension of the wrist will produce passive flexion of the fingers and also demonstrate a deficit. This is referred to at the tenodesis maneuver.Flexor tendon injuries are described based on zones (Fig. 44-13). Up until 40 years ago, zone 2 injuries were always reconstructed and never repaired primarily due to concern that the bulk of repair within the flexor sheath would prevent tendon glide. The work of Dr. Kleinert and colleagues at the University of Lou-isville changed this “axiom” and established the principle of pri-mary repair and early controlled mobilization postoperatively.17 Flexor tendon injuries should always be repaired in the operat-ing room. Although they do not need to be repaired on the day 3Figure 44-12. Commons splints used for hand injuries/surgeries. A. Ulnar gutter splint. The ring and small fingers are included and maintain an interphalangeal (IP) joint extension and metacarpopha-langeal (MP) joint flexion to 90°. B. Dorsal four-finger splint. As with the ulnar gutter splint, finger MP joints are flexed to 90° with IP joints kept fully extended. C. Thumb spica splint. One easy method to fabricate is to place one slab of plaster radially over the wrist and thumb with a second square of plaster over the thenar eminence, which joins the first. D. Sugar tong splint. This dorsal and volar slab splints immobilizes the wrist and elbow in neutral and 90° positions, respectively.Figure 44-13. The zones of flexor tendon injury. I. Flexor digito-rum superficialis insertion to the flexor digitorum profundus inser-tion. II. Start of the A1 pulley to the flexor digitorum superficialis insertion. III. End of the carpal tunnel to the start of the A1 pulley. IV. Within the carpal tunnel. V. Proximal to the carpal tunnel.Brunicardi_Ch44_p1925-p1966.indd 193520/02/19 2:48 PM 1936SPECIFIC CONSIDERATIONSPART IIof injury, the closer to the day of injury they are repaired, the easier it will be to retrieve the retracted proximal end in surgery. The laceration should be washed out and closed at the skin level only using permanent sutures. The hand should be splinted as described earlier; one notable difference is that the wrist should be splinted at slight flexion (about 20°) to help decrease the retracting force on the proximal cut tendon end.Extensor tendons do not pass through a sheath in the fin-gers. As such, bulkiness of repair is less of a concern. With proper supervision/experience and equipment, primary extensor tendon repair can be performed in the ED.Very distal extensor injuries near the insertion on the dor-sal base of the distal phalanx may not have sufficient distal ten-don to hold a suture. Closed injuries, called mallet fingers, can be treated with extension splinting of the DIP joint for 6 contin-uous weeks. For patients with open injuries, a dermatotenodesis suture is performed. A 2-0 or 3-0 suture is passed through the distal skin, tendon remnant, and proximal tendon as a mattress suture. Using a suture of a different color than the skin clos-ing sutures will help prevent removing the dermatotenodesis suture(s) too soon. The DIP joint is splinted in extension.More proximal injuries are typically repaired with a 3-0 braided permanent suture. Horizontal mattress or figure-of-eight sutures should be used, two per tendon if possible. Great care should be used to ensure matching the appropriate proximal and distal tendon ends. The patient is splinted with IP joints in extension and the wrist in extension per usual. MP joints should be splinted in 45° flexion, sometimes less. Although this posi-tion is not ideal for MP collateral ligaments, it is important for taking tension off of the tendon repairs.Nerve InjuriesIn the setting of a sharp injury, a sensory deficit implies a nerve laceration until proven otherwise. For blunt injuries, even dis-placed fractures and dislocations, nerves are often contused but not lacerated and are managed expectantly. Nerve repairs require appropriate microsurgical equipment and suture; they should not be performed in the ED. As with tendons, nerve injuries do not require immediate exploration. However, earlier exploration will allow for easier identification of structures and less scar tissue to be present. The nerve must be resected back to healthy nerve fascicle prior to repair. Delay between injury and repair can thus make a difference between the ability to repair a nerve primarily or the need to use a graft. The injured hand should be splinted with MPs at 90° and IPs at 0°, as described earlier.Vascular InjuriesVascular injuries have the potential to be limb or digit threaten-ing. A partial laceration of an artery at the wrist level can poten-tially cause exsanguinating hemorrhage. Consultations for these injuries must be evaluated urgently.Initial treatment for an actively bleeding wound should be direct local pressure for no less than 10 continuous minutes. If this is unsuccessful, an upper extremity tourniquet inflated to 100 mmHg above the systolic pressure should be used. One should keep this tourniquet time to less than 2 hours to avoid tissue necrosis. Once bleeding is controlled well enough to evaluate the wound, it may be cautiously explored to evaluate for bleeding points. One must be very cautious if attempting to ligate these to ensure that adjacent structures such as nerves are not included in the ligature.The hand must be evaluated for adequacy of perfusion to the hand as a whole as well as the individual digits. Capillary refill, turgor, Doppler signal, and bleeding to pinprick all pro-vide useful information regarding vascular status. The finger or hand with vascular compromise requires urgent operative explo-ration. Unlike the complete amputation, in which the amputated part can be cold preserved (see later section, “Amputation and Replantation”), devascularization without amputation produces warm ischemia, which is tolerated only for a matter of hours.For the noncritical vascular injury, two treatment options exist. Simple ligation will control hemorrhage. At least one of the palmar arterial arches is intact in 97% of patients, so this will usually not compromise hand perfusion.5 Each digit also has two arterial inflows and can survive on one (see “Amputations and Replantation” section). In the academic hospital setting, however, consideration should be given to repairing all vascular injuries. Instructing a resident in vascular repair in the noncriti-cal setting will produce a more skilled and prepared resident for when a critical vascular injury does arise.ANESTHESIALocal AnesthesiaAnesthetic blockade can be administered at the wrist level, digi-tal level, or with local infiltration as needed. Keep in mind that all local anesthetics are less effective in areas of inflammation.The agents most commonly used are lidocaine and bupiva-caine. Lidocaine has the advantage of rapid onset, whereas bupi-vacaine has the advantage of long duration (average 6–8 hours).18 Although bupivacaine can produce irreversible heart block in high doses, this is rarely an issue with the amounts typically used in the hand. For pediatric patients, the tolerated dose is 2.5 mg/kg. This can be easily remembered by noting that when using 0.25% bupivacaine, 1 mL/kg is acceptable dosing.A commonly held axiom is that epinephrine is unaccept-able to be used in the hand. Several recent large series have dispelled this myth.19 Epinephrine should not be used in the fingertip and not in concentrations higher than 1:100,000 (i.e., what is present in commercially available local anesthetic with epinephrine). Beyond that, its use is acceptable and may be use-ful in an ED where tourniquet control may not be available. Also, because most ED procedures are done under pure local anesthesia, many patients will not tolerate the discomfort of the tourniquet beyond 30 minutes.20 Epinephrine will provide hemostasis and also prolong the effect of the local anesthetic.Studies have reported that the addition of sodium bicar-bonate (NaHCO3) in order to buffer local anesthetic solutions and decrease the pain experienced during the administration of local anesthetic.21 This decrease in pain has been attributed to decreasing the acidity of local anesthetic solutions. In the clinical setting, the mixing of 8.4% sodium bicarbonate with 1% lidocaine with 1:100,000 epinephrine in a 1:9 ratio is ade-quate to provide a decrease in pain during the injection of local anesthetic.22Simple lacerations, particularly on the dorsum of the hand, can be anesthetized with local infiltration. This is performed in the standard fashion.Blocking of the digital nerves at the metacarpal head level is useful for volar injuries distal to this point and for dorsal injuries beyond the midpoint of the middle phalanx (via dor-sal branches of the proper digital nerves). Fingertip injuries are particularly well anesthetized by this technique. A digit can be anesthetized via a flexor sheath approach or via the dorsal web space (Fig. 44-14A,B).Brunicardi_Ch44_p1925-p1966.indd 193620/02/19 2:48 PM 1937SURGERY OF THE HAND AND WRISTCHAPTER 44Figure 44-14. Local anesthesia can be administered at the digital or the wrist level. A. A single injection into the flexor tendon sheath at the metacarpal head level provides complete anesthesia for the digit. B. Alternatively, one can inject from a dorsal approach into the web space on either side. C. The superficial radial nerve is blocked by infiltrating subcutaneously over the distal radius from the radial artery pulse to the distal radioulnar joint. The dorsal sensory branch of the ulnar nerve is blocked in similar fashion over the distal ulna. D. To block the ulnar nerve, insert the needle parallel to the plane of the palm and deep to the flexor carpi ulnaris tendon; aspirate to confirm the needle is not in the adjacent ulnar artery. E. To block the median nerve, insert the needle just ulnar to the palmaris longus tendon into the carpal tunnel. One should feel two points of resistance: one when piercing the skin, the second when piercing the antebrachial fascia.Brunicardi_Ch44_p1925-p1966.indd 193720/02/19 2:48 PM 1938SPECIFIC CONSIDERATIONSPART IIBlocking one or more nerves as they cross the wrist can provide several advantages: anesthesia for multiple injured dig-its, avoiding areas of inflammation where the local anesthetic agent may be less effective, and avoiding injection where the volume of fluid injected may make treatment harder (such as fracture reduction). Four major nerves cross the wrist: the median nerve, SRN, ulnar nerve, and dorsal sensory branch of the ulnar nerve (Fig. 44-14C–E). When blocking the median and ulnar nerves, beware of intraneural injection, which can cause irreversible neural scarring. If the patient complains of severe paresthesias with injection or high resistance is encountered, the needle should be repositioned.Hand Surgery Under Local AnesthesiaWide awake hand surgery is surgery that is performed under sur-geon-administered local anesthesia with field sterility but with-out the use of sedation or a tourniquet. A major benefit of this approach is the reduction of healthcare costs due to the elimination of an anesthesia provider and postoperative monitoring because only local anesthesia is used. Further benefits of sedation-free sur-gery include decreased time spent in the hospital for surgery and the ability of patients to follow instructions during surgery. This advantage is evident during flexor tendon repairs, where intra-operative active movement allows direct visualization of the tendon repair under active movement.23 Perceived weaknesses of sedation-free surgery include patient intraoperative anxiety and fear of pain during the administration of local anesthetic. A study by Davison et al, however, found that patients undergoing carpal tunnel release under wide awake local had no difference in anxiety or pain compared to patients undergoing carpal tunnel release with sedation.24Postoperative Pain ManagementSince the recognition of pain as the fifth vital sign in the early 2000s, the number of opioid prescriptions has risen dramati-cally. Accordingly, over the last decade, the United States has seen an increase the number of deaths due to prescription opi-oid overdose. Deaths due to opioid overdose now exceeds the number of deaths caused by heroin and cocaine combined. As healthcare providers, it is essential that we adequately treat post-operative pain with the minimal amount of narcotics necessary. A recent study by Rodgers et al identified that the majority of patients undergoing elective hand surgery used prescription pain medication for only 2 or fewer days after surgery. Many patients achieved adequate pain control with over-the-counter pain med-ication and were often left with unused opioid analgesics.25Accordingly, there has been increased emphasis on educat-ing prescribers on the recognition of opioid abuse and guide-lines for appropriate opioid prescribing. Approaches such as multimodal pain management and opioid prescription protocols have shown to achieve adequate pain control while also reduc-ing excess opioid prescriptions.26SPECIAL CONSIDERATIONSAmputations and ReplantationAfter replantation was first reported, replantation was attempted for nearly all amputations.27 Over the ensuing decades, more stringent guidelines have been established regarding what should be replanted. Indications for replantation include ampu-tations of the thumb, multiple digit amputations, and amputa-tions in children. Relative contraindications to replantation include crush injuries, injuries to a single digit distal to the PIP joint, and patients who are unable to tolerate a long surgical procedure. As with all guidelines, one should evaluate the par-ticular needs of the injured patient.In preparation for replantation, the amputated part and proximal stump should be appropriately treated. The ampu-tated part should be wrapped in moistened gauze and placed in a sealed plastic bag. This bag should then be placed in an ice water bath. Do not use dry ice, and do not allow the part to contact ice directly; frostbite can occur in the amputated part, which will decrease its chance of survival after replantation. Bleeding should be controlled in the proximal stump by as mini-mal a means necessary, and the stump should be dressed with a nonadherent gauze and bulky dressing.For digital amputations deemed unsalvageable, revision amputation can be performed in the ED if appropriate equip-ment is available. Bony prominences should be smoothed off with a rongeur and/or rasp. Great care must be taken to identify the digital nerves and resect them back as far proximally in the wound as possible; this helps decrease the chance of painful neuroma in the skin closure. Skin may be closed with perma-nent or absorbable sutures; absorbable sutures will spare the patient the discomfort of suture removal several weeks later. For more proximal unsalvageable amputations, revision should be performed in the operating room to maximize vascular and neural control.Prostheses can be made for amputated parts. The more proximal the amputation, the more important to function the prosthesis is likely to be. Although finger-level prostheses are generally considered cosmetic, patients with multiple finger amputations proximal to the DIP have demonstrable functional benefit from their prosthesis as well.28Fingertip InjuriesFingertip injuries are among the most common pathologies seen in an ED. The usual history is that a door closed on the finger (commonly the middle, due to its increased length) or something heavy fell on the finger.Initial evaluation should include: wound(s) including the nail bed, perfusion, sensation, and presence and severity of fractures. For the common scenario, complex lacerations with minimally displaced fracture(s) and no loss of perfusion, the wound is cleansed, sutured, and splinted in the ED. To properly assess the nail bed, the nail plate (hard part of the nail) should be removed. A Freer periosteal elevator is well suited for this purpose. Lacerations are repaired with 6-0 fast gut suture. Great care must be taken when suturing because excessive traction with the needle can further lacerate the tissue. After repair, the nail folds are splinted with the patient’s own nail plate (if avail-able) or with aluminum foil from the suture pack. This is done to prevent scarring from the nail folds down to the nail bed that would further compromise healing of the nail.In some situations, tissue may have been avulsed in the injury and be unavailable for repair. Choice of treatment options depends on the amount and location of tissue loss (Fig. 44-15). Historically, wounds less than 1 cm2 with no exposed bone can be treated with local wound care and secondary intention. Recently, studies have reported that wounds with an average size of 1.75 cm2 have healed well with excellent functional and aesthetic results.29 For larger wounds or wounds or with bone exposed, one must decide if the finger is worth preserving at the current length or if shortening to allow for primary closure is a Brunicardi_Ch44_p1925-p1966.indd 193820/02/19 2:48 PM 1939SURGERY OF THE HAND AND WRISTCHAPTER 44better solution. A useful guideline is the amount of fingernail still present; if greater than 50% is present, local or regional flap coverage may be a good solution.If sufficient local tissue is present, homodigital flaps can be considered. A wide range of antegrade and retrograde homodig-ital flaps can be mobilized to cover the defect. Some carry sen-sation or can receive nerve coaptation to recover sensation over time.30 For the thumb only, the entire volar skin including both neurovascular bundles can be raised and advanced distally up to 1.5 cm2.31 The thumb receives separate vascularity to its dorsal skin from the radial artery. This flap is not appropriate for the fingers. Patients retain full sensibility in the advanced skin and can be mobilized within days of surgery (Fig. 44-16A–C).For wounds too large to cover with homodigital tissue, regional flaps can be considered. The skin from the distal radial thenar eminence can be raised as a random pattern flap (Fig. 44-16D–F). The finger is maintained in flexion for 14 to 21 days until division of the flap pedicle and inset of the flap. Some authors have reported prolonged stiffness in patients over 30 years old, but careful flap design helps minimize this complication.32 Alternatively, the skin from the dorsum of the middle phalanx of an adjacent digit can be raised as a flap to cover the volar P3 (Fig. 44-16G–I). The flap is inset at 14 to 21 days. Long-term studies have shown this flap develops sen-sation over time.33Patients with fingertip injures must be assessed for the possibility of salvage of the injured digit(s) taken within the context of the patient’s recovery needs and goals. The surgeon then matches the available options to the particular patient needs.High-Pressure Injection InjuriesHigh-pressure devices are commonly used for cleaning and applications of liquids such as lubricants and paint. Most commonly, the inexperienced worker accidentally discharges the device into his nondominant hand at the base of the digit. Severity of injury depends on the amount and type of liquid injected; hydrophobic compounds cause greater damage.34These injuries are typically quite innocuous to inspection. They are, however, digit-threatening emergencies. The patient should be informed of the severity of the injury, and explora-tion is ideally performed within 6 hours of injury. Up to 50% of such injuries result in loss of the digit, but early recogni-tion and treatment are associated with increased chance of digit survival.35 Early frank discussion with the patient and initiation of appropriate treatment produce the best results and medicole-gal protection.Compartment SyndromeCompartment syndromes can occur in the forearm and/or the hand. As in other locations, these are potentially limb-threat-ening issues. Principle symptoms are pain in the affected com-partments, tense swelling, tenderness to palpation over the compartment, and pain with passive stretch of the muscles of the compartment.36 Pulse changes are a late finding; normal pulses do not rule out compartment syndrome.There are three compartments in the forearm and four groups of compartments in the hand. The volar forearm is one compartment. On the dorsum of the forearm, there is the dorsal compartment as well as the mobile wad compartment, begin-ning proximally over the lateral epicondyle. In the hand, the thenar and hypothenar eminences each represent a compart-ment. The seven interosseous muscles each behave as a separate compartment.Compartment syndrome can be caused by intrinsic and extrinsic causes. Intrinsic causes include edema and hematoma due to fracture. Extrinsic causes include splints and dressings that are circumferentially too tight and intravenous infiltrations. Infiltrations with hyperosmolar fluids such as X-ray contrast are particularly dangerous, because additional water will be drawn in to neutralize the hyperosmolarity.Measurement of compartment pressures can be a useful adjunct to assessment of the patient. The Stryker pressure mea-surement device or similar device is kept in many operating rooms for this purpose. The needle is inserted into the compart-ment in question, a gentle flush with 0.1 to 0.2 cc of saline clears the measurement chamber, and a reading is obtained. Studies have disagreed about whether the criterion is a measured pres-sure (30–45 mmHg, depending on the series) or within a certain amount of the diastolic blood pressure.37Compartment releases are performed in the operating room under tourniquet control. Release of the volar forearm compartment includes release of the carpal tunnel. As the inci-sion travels distally, it should pass ulnar and then curve back radially just before the carpal tunnel. This avoids a linear inci-sion across a flexion crease and also decreases the chance of injury to the palmar cutaneous branch of the median nerve. One dorsal forearm incision can release the dorsal compartment and the mobile wad. In the hand, the thenar and hypothenar com-partments are released each with a single incision. The interos-seous compartments are released with incisions over the index and ring metacarpal shafts. Dissection then continues radial and ulnar to each of these bones and provides release of all the mus-cle compartments. Any dead muscle is debrided. Incisions are left open and covered with a nonadherent dressing. The wounds are reexplored in 2 to 3 days to assess for muscle viability. Often the incisions can be closed primarily, but a skin graft may be needed for the forearm.Fingertip injuryGreater than 50%nailbed remainingHeal by secondaryintentionSufficient same digittissueVolar V-YNoNoNoNoYesYesYesYesCross-finger flapBilateral V-YMoberg flap(Thumb only)Shorten bone forprimary stumpclosureTissue lossThenar flapWound <1 cm2 andno exposed bonePrimary repairFigure 44-15. Treatment algorithm for management of fingertip injuries. See text for description of flaps.Brunicardi_Ch44_p1925-p1966.indd 193920/02/19 2:48 PM 1940SPECIFIC CONSIDERATIONSPART IIFigure 44-16. Local flaps for digital tip coverage. A–C. For thumb injuries, Moberg described elevation of the entire volar skin with both neurovascular bundles for distal advancement. Sensation to the advanced skin is maintained. D–F. An 8-year-old girl underwent fingertip replantation that did not survive. A thenar flap was transferred to cover the defect. Some authors advise against its use in patients over 30 years old. G–I. In this 45-year-old man, the entire skin of P3 of the long finger was avulsed and unrecoverable. A cross-finger flap was transferred and provides excellent, durable coverage. The border of the flap and surrounding skin is still apparent 4.5 months after surgery.Brunicardi_Ch44_p1925-p1966.indd 194020/02/19 2:49 PM 1941SURGERY OF THE HAND AND WRISTCHAPTER 44Figure 44-16. (Continued)Brunicardi_Ch44_p1925-p1966.indd 194120/02/19 2:49 PM 1942SPECIFIC CONSIDERATIONSPART IIFigure 44-16. (Continued)Brunicardi_Ch44_p1925-p1966.indd 194220/02/19 2:49 PM 1943SURGERY OF THE HAND AND WRISTCHAPTER 44If the examiner feels the patient does not have a compart-ment syndrome, elevation and serial examination are manda-tory. When in doubt, it is safer to release an early compartment syndrome than wait to release and risk muscle necrosis. Pro-gression of compartment syndrome can lead to Volkmann’s ischemic contracture with muscle loss and scarring that may compress nerves and other critical structures. Medicolegally, it is far easier to defend releasing an early compartment syn-drome than delaying treatment until the process has progressed to necrosis and/or deeper scarring.COMPLICATIONSNonunionAny fractured bone has the risk of failing to heal. Fortunately, in the fingers and hand, this is a rare problem. Tuft injuries, where soft tissue interposes between the fracture fragments, have rela-tively higher risk of this problem. The nonunited tuft can be treated with debridement and bone grafting or revision amputa-tion depending on the needs and goals of the patient. Phalan-geal and metacarpal nonunions are also quite rare. They can similarly be treated with debridement of the nonunion, grafting, and rigid fixation.38 More proximally, the scaphoid bone of the wrist has a significant risk of nonunion even if nondisplaced (see Fig. 44-9A). Any patient suspected of a scaphoid injury, namely those with tenderness at the anatomic snuffbox, should be placed in a thumb spica splint and reevaluated within 2 weeks even if initial X-rays show no fracture. Scaphoid nonunions can be quite challenging to repair, and immobilization at the time of injury in a thumb spica splint is essentially always warranted.39StiffnessThe desired outcome of any hand injury is a painless, mobile, functional hand. Multiple factors can contribute to decreased mobility, including complex injuries of soft tissue and bone, noncompliance of the patient with postoperative therapy, and inappropriate splinting. The surgeon performing the initial eval-uation can greatly impact this last factor. The goal of splinting is to keep the collateral ligaments on tension (MPs at 90°, IP joints straight). For severe cases of stiffness, mobilization sur-geries such as tenolysis and capsulotomies can be performed, but these rarely produce normal range of motion.40 Prevention of joint contractures with appropriate splinting and early, pro-tected mobilization is the best option to maximize mobility at the end of healing. Healing of an injured or diseased structure in the hand is not the endpoint of treatment; the goal of any inter-vention must be to obtain structure healing, relief of pain, and maximization of function.NeuromaAny lacerated nerve will form a neuroma. A neuroma consists of a ball of scar and axon sprouts at the end of the injured nerve.41 In unfavorable circumstances, this neuroma can become painful. The SRN is particularly notorious for this problem. By provid-ing proximal axon sprouts a target, nerve repair is an excellent preventive technique. In some circumstances, such as injuries requiring amputation, this is not possible. As mentioned earlier, the surgeon should resect the nerve stump as far proximally in the wound as possible to avoid the nerve stump healing in the cutaneous scar to minimize this risk.For the patient who develops a painful neuroma, nonsurgi-cal treatments are initiated first. The neuroma can be identified by the presence of a Tinel’s sign. Therapy techniques of desen-sitization, ultrasound, and electrical stimulation have all proven useful. Corticosteroid injection to the neuroma has also proven useful in some hands.When these techniques fail, surgery is contemplated. The neuroma can be resected, but a new one will form to replace it. The nerve ending can be buried in muscle or even bone to pre-vent the neuroma from residing in a superficial location where it may be impacted frequently.Regional Pain SyndromesInjuries to the upper extremity can occasionally result in the patient experiencing pain beyond the area of initial injury. Reflex sympathetic dystrophy and sympathetic mediated pain are two terms that have been used in the past to describe this phenomenon. Both are inaccurate, as the sympathetic nervous system is not always involved. Current terminology for this condition is complex regional pain syndrome (CRPS). Type I occurs in the absence of a documented nerve injury; type II occurs in the presence of one.42CRPSs manifest as pain beyond the area of initial inju-ries. There is often associated edema and changes in hair and/or sweat distribution. Comparison to the unaffected side is useful to better appreciate these findings. There are currently no imag-ing studies that can be considered diagnostic for CRPS.43For the patient in whom the diagnosis of CRPS is not clear, no definitive diagnostic study exists. Patients suspected of CRPS should be referred for aggressive hand therapy. Brief trials of oral corticosteroids have been successful in some series. Referral to a pain management specialist including a trial of stel-late ganglion blocks is also frequently employed.NERVE COMPRESSIONNerves conduct signals along their axonal membranes toward their end organs. Sensory axons carry signals from distal to proximal; motor axons from proximal to distal. Myelin from Schwann cells allows faster conduction of signals. Signals jump from the start of one Schwann cell to the end of the cell (a loca-tion called a gap junction) and only require the slower mem-brane depolarization in these locations.Nerve compression creates a mechanical disturbance of the nerve.44 In early disease, the conduction signal is slowed across the area of compression. When compression occurs to a sufficient degree for a sufficient time, individual axons may die. On a nerve conduction study, this manifests as a decrease in amplitude. Muscles receiving motor axons may show electri-cal disturbance on electromyogram (EMG) when sufficiently deprived of their axonal input.Compression of sensory nerves typically produces a com-bination of numbness, paresthesias (pins and needles), and pain. Knowledge of the anatomic distribution of the peripheral nerves can aid in diagnosis. Sensory disturbance outside an area of dis-tribution of a particular nerve (e.g., volar and dorsal radial-sided hand numbness for median nerve) makes compression of that nerve less likely. Diseases that cause systemic neuropathy (e.g., diabetes) can make diagnosis more difficult.Nerve compression can theoretically occur anywhere along a peripheral nerve’s course. The most common sites of nerve compression in the upper extremity are the median nerve at the carpal tunnel, ulnar nerve at the cubital tunnel, and ulnar nerve at Guyon’s canal. Other, less common locations of nerve 4Brunicardi_Ch44_p1925-p1966.indd 194320/02/19 2:49 PM 1944SPECIFIC CONSIDERATIONSPART IIcompression are described as well. In addition, a nerve can become compressed in scar due to a previous trauma.Carpal Tunnel SyndromeThe most common location of upper extremity nerve compres-sion is the median nerve at the carpal tunnel, called carpal tunnel syndrome (CTS). The carpal tunnel is bordered by the scaphoid bone radially, the lunate and capitate bones dorsally, and the hook of the hamate bone ulnarly (see Fig. 44-3). The transverse carpal ligament, also called the flexor retinaculum, is its super-ficial border. The FPL, four FDS, and four FDP tendons pass through the carpal tunnel along with the median nerve. Of these 10 structures, the median nerve is relatively superficial and radial to the other nine.An estimated 53 per 10,000 working adults have evidence of CTS. The National Institute for Occupational Safety and Health website asserts, “There is strong evidence of a positive association between exposure to a combination of risk factors (e.g., force and repetition, force and posture) and CTS.”45 There is disagreement among hand surgeons regarding whether occur-rence of CTS in a patient who does repetitive activities at work represents a work-related injury.Initial evaluation of the patient consists of symptom inven-tory: location and character of the symptoms, sleep disturbance due to symptoms, history of dropping objects, and difficulty manipulating small objects such as buttons, coins, or jewelry clasps.46Physical examination should begin with inspection. Look for evidence of wasting of the thenar muscles. Tinel’s sign should be tested over the median nerve from the volar wrist flexion crease to the proximal palm, although this test has significant interexam-iner variability.47 Applying pressure over the carpal tunnel while flexing the wrist has been shown in one series to have the high-est sensitivity when compared to Phalen’s and Tinel’s signs.48 Strength of the thumb in opposition should also be tested.Early treatment of CTS consists of conservative man-agement. The patient is given a splint to keep the wrist at 20° extension worn at nighttime. Many patients can have years of symptom relief with this management. As a treatment and diag-nostic modality, corticosteroid injection of the carpal tunnel is often employed. Mixing local anesthetic into the solution pro-vides the benefit of early symptom relief (corticosteroids often take 3–7 days to provide noticeable benefit), and report of postin-jection anesthesia in the median nerve distribution confirms the injection went into the correct location. Multiple authors have shown a strong correlation to relief of symptoms with cortico-steroid injection and good response to carpal tunnel release.49When lesser measures fail or are no longer effective, carpal tunnel release is indicated. Open carpal tunnel release is a time-tested procedure with documented long-term relief of symptoms. A direct incision is made over the carpal tun-nel, typically in line with where the ring finger pad touches the proximal palm in flexion. Skin is divided followed by palmar fascia. The carpal tunnel contents are visualized as they exit the carpal tunnel. The transverse carpal ligament is divided with the median nerve visualized and protected at all times. Improve-ment in symptoms is typically noted by the first postoperative visit, although symptom relief may be incomplete for patients with long-standing disease or systemic nerve-affecting diseases such as diabetes.Endoscopic techniques have been devised to address CTS. All involve avoidance of incising the skin directly over the carpal tunnel. In experienced hands, endoscopic carpal tunnel release provides the same relief of CTS with less intense and shorter lasting postoperative pain. After 3 months, however, the results are equivalent to open release.50 In inexperienced hands, there may be a higher risk of injury to the median nerve with the endoscopic techniques; this procedure is not for the occasional carpal tunnel surgeon.Cubital Tunnel SyndromeThe second most common location of upper extremity nerve compression is the ulnar nerve where it passes behind the elbow at the cubital tunnel. The cubital tunnel retinaculum passes between the medial epicondyle of the humerus and the olec-ranon process of the ulna. It stabilizes the ulnar nerve in this location during elbow motion. Over time, or sometimes after trauma, the ulnar nerve can become less stabilized in this area. Motion of the elbow then produces trauma to the nerve as it impacts the retinaculum and medial epicondyle.Cubital tunnel syndrome may produce sensory and motor symptoms.51 The small finger and ulnar half of the ring fin-gers may have numbness, paresthesias, and/or pain. The ulnar nerve also innervates the dorsal surface of the small finger and ulnar side of the ring finger, so numbness in these areas can be explained by cubital tunnel syndrome. The patient may also report weakness in grip due to effects on the FDP tendons to the ring and small fingers and the intrinsic hand muscles. Patients with advanced disease may complain of inability to fully extend the ring and small finger IP joints.Physical examination for cubital tunnel syndrome begins with inspection. Look for wasting in the hypothenar eminence and the interdigital web spaces. When the hand rests flat on the table, the small finger may rest in abduction with respect to the other fingers; this is called Wartenberg’s sign. Tinel’s sign is often present at the cubital tunnel. Elbow flexion and the shoulder internal rotation tests are affective maneuvers to aid in the diagnosis of cubital tunnel syndrome.52 Grip strength and finger abduction strength should be compared to the unaffected side. Froment’s sign can be tested by placing a sheet of paper between the thumb and index finger and instructing the patient to hold on to the paper while the examiner pulls it away without flexing the finger or thumb (this tests the strength of the adduc-tor pollicis and first dorsal interosseous muscles). If the patient must flex the index finger and/or thumb (FDP-index and FPL, both median nerve supplied) to maintain traction on the paper, this is a positive response.Early treatment of cubital tunnel syndrome begins with avoiding maximal flexion of the elbow. Splints are often used for this purpose. Corticosteroid injection is rarely done for this condition; unlike in the carpal tunnel, there is very little space within the tunnel outside of the nerve. Injection in this area runs a risk of intraneural injection, which can cause permanent scar-ring of the nerve and dysfunction.When conservative management fails, surgery has been contemplated. Treatment options include releasing the cubital tunnel retinaculum with or without transposing the nerve ante-rior to the elbow. While some authors advocate anterior trans-position into the flexor-pronator muscle group with the goal of maximizing nerve recovery, recent studies have demonstrated equivalent results between transposition and in situ release of the nerve even in advanced cases. For this reason, the simpler in situ release, either open or endoscopic, is preferred by many surgeons.53Brunicardi_Ch44_p1925-p1966.indd 194420/02/19 2:49 PM 1945SURGERY OF THE HAND AND WRISTCHAPTER 44Other Sites of Nerve CompressionAll nerves crossing the forearm have areas described where compression can occur.51 The median nerve can be compressed as it passes under the pronator teres. The ulnar nerve can be compressed as it passes through Guyon’s canal. The radial nerve, or its posterior interosseous branch, can be compressed as it passes through the radial tunnel (distal to the elbow where the nerve divides and passes under the arch of the supinator muscle). The SRN can be compressed distally in the forearm as it emerges from under the brachioradialis tendon, called Wartenberg’s syndrome. As mentioned previously, any nerve can become compressed in scar at the site of a previous trauma.DEGENERATIVE JOINT DISEASEAs with other joints in the body, the joints of the hand and wrist can develop degenerative changes. Symptoms typically begin in the fifth decade of life. Symptoms consist of joint pain and stiffness and often are exacerbated with changes in the weather. Any of the joints can become involved. As the articular carti-lage wears out, pain typically increases and range of motion decreases. The patient should always be asked to what degree symptoms are impeding activities.Physical findings are documented in serial fashion from the initial visit and subsequent visits. Pain with axial loading of the joint may be present. Decreased range of motion may be a late finding. Instability of the collateral ligaments of the joint is uncommon in the absence of inflammatory arthritis.Plain X-rays are typically sufficient to demonstrate arthri-tis. Initially, the affected joint has a narrower radiolucent space between the bones. As joint degeneration progresses, the joint space further collapses. Bone spurs, loose bodies, and cystic changes in the bone adjacent to the joint all may become appar-ent. X-ray findings do not always correlate with patient symp-toms. Patients with advanced X-ray findings may have minimal symptoms, and vice versa. Treatment is initiated and progressed based on the patient’s symptoms regardless of imaging findings.Initial management begins with rest of the painful joint. Splints are often useful, but may significantly impair the patient in activities and thus are frequently used at nighttime only. Oral nonsteroidal anti-inflammatory medications such as ibuprofen and naproxen are also useful. Patients on anticoagulants and antiplatelet medications may not be able to take these, and some patients simply do not tolerate the gastric irritation side effect even if they take the medication with food.For patients with localized disease affecting only one or a few joints, corticosteroid injection may be contemplated. Nee-dle insertion can be difficult since these joint spaces are quite narrow even before degenerative disease sets in. Also, many corticosteroid injections are suspensions, not solutions; injected corticosteroid will remain in the joint space and can be seen as a white paste if surgery is performed on a joint that has been previously injected.Small Joints (Metacarpophalangeal and Interphalangeal)When conservative measures fail, two principal surgical options exist: arthrodesis and arthroplasty. The surgeon and patient must decide together as to whether conservative measures have failed. Surgery for arthritis, whether arthrodesis or arthroplasty, is performed for the purpose of relieving pain. Arthrodesis, fusion of a joint can be performed with a tension band or axial compression screw techniques.54 Both methods provides excel-lent relief of pain and is durable over time. However, it comes at the price of total loss of motion.Silicone implant arthroplasty has been available for over 40 years.55 Rather than a true replacement of the joint, the silicone implant acts as a spacer between the two bones adja-cent to the joint. This allows for motion without bony contact that would produce pain. Long-term studies have shown that all implants fracture over time, but usually continue to preserve motion and pain relief.56In the past 15 years, resurfacing implant arthroplasties have become available for the small joints of the hand. Multiple different materials have been used to fabricate such implants. These are designed to behave as a true joint resurfacing (as knee and hip arthroplasty implants are) and have shown promising outcomes in shortand intermediate-term studies.56 Neither the silicone nor the resurfacing arthroplasties preserve (or restore) full motion of the MP or PIP joints.WristThe CMC joint of the thumb, also called the basilar joint, is another common location of arthritis pain. Pain in this joint par-ticularly disturbs function because the CMC joint is essential for opposition and cylindrical grasp. Patients will typically com-plain of pain with opening a tight jar or doorknob and strong pinch activities such as knitting. Conservative management is used first, as described earlier. Prefabricated, removable thumb spica splinting can provide excellent relief of symptoms for many patients.Multiple surgical options exist for thumb CMC arthritis. Many resurfacing implants have been used in the past; often they have shown good shortand intermediate-term results and poor long-term results. Resection of the arthritic trapezium provides excellent relief of pain; however, many authors feel that stabi-lization of the thumb metacarpal base is necessary to prevent shortening and instability.57 Some surgeons have demonstrated excellent long-term results from resection of the trapezium without permanent stabilization of the metacarpal base.58 For both of these operations, the thumb base may not be sufficiently stable to withstand heavy labor. For these patients, fusion of the thumb CMC in mild opposition provides excellent pain relief and durability. The patient must be warned preoperatively that he will not be able to lay his hand flat after the surgery. This loss of motion can be problematic when the patient attempts to tuck in clothing or reach into a narrow space.59Degenerative change of the radiocarpal and midcarpal joints is often a consequence of scapholunate ligament injury. Often the initial injury goes untreated, with the patient believ-ing it is merely a “sprain”; the patient is first diagnosed with the initial injury when he presents years later with degenerative changes.Degenerative wrist changes associated with the scaph-olunate ligament follow a predictable pattern over many years, called scapholunate advanced collapse or SLAC wrist.60 Because of this slow progression (Fig. 44-17A), patients can usually be treated with a motion-sparing procedure. If there is truly no arthritic change present, the scapholunate ligament can be reconstructed.If arthritis is limited to the radiocarpal joint, two motion-sparing options are available. The proximal carpal row (scaphoid, lunate, and triquetrum) can be removed (proximal row carpectomy [PRC]). The lunate facet of the radius then Brunicardi_Ch44_p1925-p1966.indd 194520/02/19 2:49 PM 1946SPECIFIC CONSIDERATIONSPART IIarticulates with the base of the capitate, whose articular surface is similar in shape to that of the base of the lunate. Studies have shown maintenance of approximately 68% of the wrist flexion-extension arc and 72% of hand strength compared to the con-tralateral side.61 Alternatively, the scaphoid can be excised, and four-bone fusion (lunate, capitate, hamate, and triquetrum) can be performed. This maintains the full length of the wrist and the lunate in the lunate facet of the radius. Some series have shown better strength but less mobility with this technique, oth-ers have shown equivalent results to the PRC.62 The four-bone fusion does appear to be more durable for younger patients and/or those who perform heavy labor.If the patient presents with pancarpal arthritis or motion-sparing measures have failed to alleviate pain, total wrist fusion is the final surgical option. The distal radius is fused, through the proximal and distal carpal rows to the third metacarpal, typi-cally with a dorsal plate and screws. Multiple long-term studies have shown excellent pain relief and durability; this comes at the cost of total loss of wrist motion. This is surprisingly well tolerated in most patients, especially if the other hand/wrist is unaffected. The only activity of daily living that cannot be done with a fused wrist is personal toileting.Rheumatoid ArthritisRheumatoid arthritis (RA) is an inflammatory arthritis that can affect any joint in the body. Inflamed synovium causes articular cartilage breakdown with pain and decreased range of motion. The goals of hand surgery for the RA patient are relief of pain, improvement of function, slowing progression of disease, and improvement in appearance.63 In addition, swelling of the joint due to the inflammation can cause laxity and even failure of the collateral ligaments supporting the joints. Recent advances in the medical care of RA have made the need for surgical care of these patients far less common than in previous decades.MP joints of the fingers are commonly affected. The base of the proximal phalanx progressively subluxates and eventu-ally dislocates volarly with respect to the metacarpal head. The collateral ligaments, particularly on the radial side, stretch out and cause the ulnar deviation of the fingers characteristic of the rheumatoid hand. In more advanced cases, the joint may not be salvageable (Fig. 44-17B). For these patients, implant arthro-plasty is the mainstay of surgical treatment. Silicone implants have been used for over 40 years with good results.64 The sili-cone implant acts as a spacer between proximal and distal bone, rather than as a true resurfacing arthroplasty. The radial col-lateral ligament must be repaired to appropriate length to cor-rect the preoperative ulnar deviation of the MP joint. Extensor tendon centralization is then performed, as needed, at the end of the procedure.For MP joint and PIP joint disease, fusion is an option. However, since RA usually affects multiple joints, fusion is typically avoided due to impaired function of adjacent joints, which would leave a severe motion deficit to the finger.Failure of the support ligaments of the distal radioulnar joint (DRUJ) leads to the caput ulnae posture of the wrist with the ulnar head prominent dorsally. As this dorsal prominence becomes more advanced, the ulna head, denuded of its cartilage to act as a buffer, erodes into the overlying extensor tendons. Extensor tenosynovitis, followed ultimately by tendon rupture, begins ulnarly and proceeds radially. Rupture of the ECU ten-don may go unnoticed due to the intact ECRL and ECRB ten-dons to extend the wrist. EDQ rupture may go unnoticed if a sufficiently robust EDC tendon to the small finger exists. Once the fourth compartment (EDC) tendons begin to fail, the motion deficit is unable to be ignored by the patient.Surgical solutions must address the tendon ruptures as well as the DRUJ synovitis and instability and ulna head break-down that led to them.65 Excision of the ulna head removes the bony prominence. The DRUJ synovitis must also be resected. Figure 44-17. Arthritis of the hand and wrist. A. This patient injured her scapholunate ligament years prior to presentation. The scapholunate interval is widened (double arrow), and the radioscaphoid joint is degenerated (solid oval), but the radiolunate and lunocapitate joint spaces are well preserved (dashed ovals). B. This patient has had rheumatoid arthritis for decades. The classic volar subluxation of the metacarpophalangeal joints of the fingers (dashed oval) and radial deviation of the fingers are apparent.Brunicardi_Ch44_p1925-p1966.indd 194620/02/19 2:49 PM 1947SURGERY OF THE HAND AND WRISTCHAPTER 44Alternatively, the DRUJ can be fused and the ulna neck resected to create a pseudoarthrosis to allow for rotation. For both pro-cedures, the remaining distal ulna must be stabilized. Multiple techniques have been described using portions of FCU, ECU, wrist capsule, and combinations thereof.The ruptured extensor tendons are typically degenerated over a significant length. Primary repair is almost never pos-sible, and the frequent occurrence of multiple tendon ruptures makes repair with graft less desirable due to the need for mul-tiple graft donors.Strict compliance with postoperative therapy is essential to maximizing the surgical result. Due to the chronic inflam-mation associated with RA, tendon and ligament repairs will be slower to achieve maximal tensile strength. Prolonged night-time splinting, usually for months, helps prevent recurrence of extensor lag. Finally, the disease may progress over time. Reconstructions that were initially adequate may stretch out or fail over time. Medical management is the key to slowing dis-ease progression and maximizing the durability of any surgical reconstruction.DUPUYTREN’S CONTRACTUREIn 1614, a Swiss surgeon named Felix Plater first described con-tracture of multiple fingers due to palpable, cord-like structures on the volar surface of the hand and fingers. The disease state he described would ultimately come to be known as Dupuytren’s contracture. Dupuytren’s name came to be associated with the disease after he performed an open fasciotomy of a contracted cord before a class of medical students in 1831.66The palmar fascia consists of collagen bundles in the palm and fingers. These are primarily longitudinally oriented and reside as a layer between the overlying skin and the underlying tendons and neurovascular structures. There are also connections from this layer to the deep structures below and the skin above. Much is known about the progression of these structures from their normal state (called bands) to their contracted state (called cords), but little is known on how or why this process begins.Increased collagen deposition leads to a palpable nodule in the palm. Over time, there is increased deposition distally into the fingers. This collagen becomes organized and linearly ori-ented. These collagen bundles, with the aid of myofibroblasts, contract down to form the cords, which are the hallmark of the symptomatic patient. Detail of the molecular and cell biology of Dupuytren’s disease is beyond the scope of this chapter but is available in multiple hand surgery texts.67Most nonoperative management techniques will not delay the progression of disease. Corticosteroid injections may soften nodules and decrease the discomfort associated with them but are ineffective against cords. Splinting has similarly been shown not to retard disease progression.Recently, several minimally invasive treatment approaches have been described for the treatment of Dupuytren’s disease.68 Disruption of the cord with a needle is an effective means of releasing contractures, particularly at the MP joint level. Long-term studies have demonstrated more rapid recovery from needle fasciotomy, as the procedure is called, but more durable results with fasciectomy.69 Injectable clostridial collagenase was approved by the U.S. Food and Drug Administration in 2009, and although it has shown good early results, treatment costs remain high.70For patients with advanced disease including contrac-tures of the digits that limit function, surgery is the mainstay of therapy. Although rate of progression should weigh heavily in the decision of whether or not to perform surgery, general guidelines are MP contractures greater than or equal to 30° and/or PIP contractures greater than or equal to 20°.71Surgery consists of an open approach through the skin down to the involved cords. Skin is elevated off of the under-lying cords. Great care must be taken to preserve as much of the subdermal vascular plexus with the elevated skin flaps to minimize postoperative skin necrosis. All nerves, tendons, and blood vessels in the operative field should be identified. Once this is done, the involved cord is resected while keeping the critical deeper structures under direct vision. The skin is then closed, with local flap transpositions as needed, to allow for full extension of the fingers that have been released (Fig. 44-18).Alternative cord resection techniques include removal of the skin over the contracture (dermatofasciectomy). This requires a skin graft to the wound and should only be done if skin cannot be separated from the cords and local tissue cannot be rearranged with local flaps to provide closure of the wound.Complications of surgical treatment of Dupuytren’s dis-ease occur in as many as 24% of cases.72 Problems include digi-tal nerve laceration, digital artery laceration, buttonholing of the skin, hematoma, swelling, and pain, including some patients with CRPS (see earlier section on CRPS). Digital nerve injury can be quite devastating, producing annoying numbness at best or a painful neuroma in worse situations.Hand therapy is typically instituted within a week of sur-gery to begin mobilization of the fingers and edema control. The therapist can also identify any early wound problems because he or she will see the patient more frequently than the surgeon. Extension hand splinting is maintained for 4 to 6 weeks, with nighttime splinting continued for an additional 6 to 8 weeks. After this point, the patient is serially followed for evidence of recurrence or extension of disease.INFECTIONSTrauma is the most common cause of hand infections. Other predisposing factors include diabetes, neuropathies, and immu-nocompromised patients. Proper treatment consists of incision and drainage of any collections followed by debridement, obtain-ing wound cultures, antibiotic therapy, elevation, and immobi-lization. Staphylococcus and Streptococcus are the offending pathogens in about 90% of hand infections. Infections caused by intravenous drug use or human bites and those associated with diabetes will often be polymicrobial, including gram-positive and gram-negative species. Heavily contaminated injuries require anaerobic coverage. Although α-hemolytic Streptococcus and Staphylococcus aureus are the most commonly encountered pathogens in human bites, Eikenella corrodens is isolated in up to one-third of cases and should be considered when choosing antimicrobial therapy. Ziehl-Neelsen staining and cultures at 28°C to 32°C in Lowenstein-Jensen medium must be performed if there is a suspicion for atypical mycobacteria.73CellulitisCellulitis is characterized by a nonpurulent diffuse spreading of inflammation characterized by erythema, warmth, pain, swell-ing, and induration. Skin breakdown is a frequent cause, but Brunicardi_Ch44_p1925-p1966.indd 194720/02/19 2:49 PM 1948SPECIFIC CONSIDERATIONSPART IIFigure 44-18. Dupuytren’s disease. A. This patient has cords affecting the thumb, middle, ring, and small fingers. B. The resected specimens are shown. C. Postoperatively, the patient went on to heal all his incisions and, with the aid of weeks of hand therapy, recover full motion.often no inciting factor is identified. Group A α-hemolytic Streptococcus is the most common offending pathogen and causes a more diffuse spread of infection. S aureus is the second most common offending pathogen and will cause a more local-ized cellulitis. The diagnosis of cellulitis is clinical. Septic arthritis, osteomyelitis, an abscess, a deep-space infection, and necrotizing fasciitis are severe infectious processes that may initially mimic cellulitis. These must be ruled out appropriately before initiating treatment, and serial exams should be con-ducted to ensure proper diagnosis. Treatment of cellulitis con-sists of elevation, splint immobilization, and antibiotics that cover both Streptococcus and Staphylococcus. Intravenous antibiotics are usually initiated for patients with severe comorbidities and those who fail to improve on oral antibiotics after 24 to 48 hours. Failure to improve after 24 hours indicates a need to search for an underlying abscess or other infectious cause.735AbscessAn abscess will present much like cellulitis, but they are two clinically separate entities. The defining difference is an area of fluctuance. Skin-puncturing trauma is the most common cause. S aureus is the most common pathogen, followed by Streptococcus. Treatment consists of incision and drainage with appropriate debridement, wound cultures, wound packing, elevation, immo-bilization, and antibiotics. The packing should be removed in 12 to 24 hours or sooner if there is clinical concern, and warm soapy water soaks with fresh packing should be initiated. Most should be allowed to heal secondarily. Delayed primary clo-sure should only be performed after repeat washouts for larger wounds where complete infection control has been achieved.Collar-Button AbscessThis is a subfascial infection of a web space and is usually caused by skin trauma that becomes infected; it often occurs in Brunicardi_Ch44_p1925-p1966.indd 194820/02/19 2:49 PM 1949SURGERY OF THE HAND AND WRISTCHAPTER 44laborers. The adherence of the palmar web space skin to the pal-mar fascia prevents lateral spread, so the infection courses dor-sally, resulting in both palmar web space tenderness and dorsal web space swelling and tenderness. The adjacent fingers will be held in abduction with pain on adduction (Fig. 44-19). Incision and drainage, often using separate volar and dorsal incisions, is mandatory, and follows the same treatment as for any abscess or deep-space infection.OsteomyelitisOsteomyelitis in the hand usually occurs due to an open fracture with significant soft tissue injury. The presence of infected hard-ware, peripheral vascular disease, diabetes, and alcohol or drug abuse are also predisposing factors. Presentation includes per-sistent or recurrent swelling with pain, erythema, and possible drainage. It will take 2 to 3 weeks for periosteal reaction and osteopenia to be detected on radiographs. Bone scans and MRI Figure 44-19. Collar-Button abscess A. The fingers surround-ing the involved (second) web space rest in greater abduction than the other fingers. B. Dorsal and volar drainage incisions are made, separated by a bridge of intact web skin; a Penrose drain prevents the skin from closing too early.are useful modalities to aid in diagnosis. Erythrocyte sedimenta-tion rate (ESR) and C-reactive protein (CRP) have low specific-ity but are useful for monitoring the progress of treatment, with CRP being more reliable. Treatment consists of antibiotics alone in the early stage as long as there is favorable response. All necrotic bone and soft tissue, if present, must be debrided. Initial intravenous antibiotic therapy should cover S aureus, the most common pathogen, and should then be adjusted according to bone cultures. Antibiotic therapy is continued for 4 to 6 weeks once the patient clinically improves and there is no further need for debridement. For osteomyelitis in the setting of an acute fracture with internal fixation in place, the hardware should be left in place as long as it is stable and the fracture has not yet healed. If the hardware is unstable, it must be replaced. An external fixation device may be useful in this setting. If osteo-myelitis occurs in a healed fracture, all hardware and necrotic bone and soft tissue must be removed.74Pyogenic ArthritisInfection of a joint will progress quickly to severe cartilage and bony destruction if not addressed quickly. Direct trauma and local spread of an infection are the most common causes. Hema-togenous spread occurs most commonly in patients who are immunocompromised. S aureus is the most common pathogen, followed by Streptococcus species. Neisseria gonorrhoeae is the most common cause of atraumatic septic arthritis in an adult less than 30 years of age. Presentation includes exacerbation of pain with any joint movement, severe pain on axial load, swell-ing, erythema, and tenderness. Radiographs may show a foreign body or fracture, with widened joint space early in the process and decreased joint space late in the process due to destruc-tion. Joint aspiration with cell count, Gram stain, and culture is used to secure the diagnosis. Treatment of nongonococcal septic arthritis includes open arthrotomy, irrigation, debridement, and packing the joint or leaving a drain in place. Intravenous antibi-otics are continued until there is clinical improvement, followed by 2 to 4 weeks of additional oral or intravenous antibiotics. Gonococcal septic arthritis is usually treated nonoperatively. Intravenous ceftriaxone is first-line therapy. Joint aspiration may be used to obtain cultures and decrease joint pressure.75Necrotizing InfectionsNecrotizing soft tissue infections occur when the immune system is unable to contain an infection, leading to extensive spread with death of all involved tissues. This is different from an abscess, which forms when a functioning immune system is able to “wall off” the infectious focus. Necrotizing infections can result in loss of limb or life, even with prompt medical care.Bacteria spread along the fascial layer, resulting in the death of soft tissues, which is in part due to the extensive blood vessel thrombosis that occurs. An inciting event is not always identified. Immunocompromised patients and those who abuse drugs or alcohol are at greater risk, with intravenous drug users having the highest increased risk. The infection can by monoor polymicrobial, with group A β-hemolytic Streptococcus being the most common pathogen, followed by α-hemolytic Streptococcus, S aureus, and anaerobes. Prompt clinical diag-nosis and treatment are the most important factors for salvag-ing limbs and saving life. Patients will present with pain out of proportion with findings. Appearance of skin may range from normal to erythematous or maroon with edema, induration, and blistering. Crepitus may occur if a gas-forming organism Brunicardi_Ch44_p1925-p1966.indd 194920/02/19 2:49 PM 1950SPECIFIC CONSIDERATIONSPART IIis involved. “Dirty dishwater fluid” may be encountered as a scant grayish fluid, but often there is little to no discharge. There may be no appreciable leukocytosis. The infection can progress rapidly and can lead to septic shock and disseminated intravas-cular coagulation. Radiographs may reveal gas formation, but they must not delay emergent debridement once the diagnosis is suspected. Intravenous antibiotics should be started imme-diately to cover gram-positive, gram-negative, and anaerobic bacteria. Patients will require multiple debridements, and the spread of infection is normally wider than expected based on initial assessment.73Necrotizing myositis, or myonecrosis, is usually caused by Clostridium perfringens due to heavily contaminated wounds. Unlike necrotizing fasciitis, muscle is universally involved and found to be necrotic. Treatment includes emergent debride-ment of all necrotic tissue along with empirical intravenous antibiotics.Wet gangrene is most common in diabetics with renal failure and an arteriovenous shunt. It is usually polymicrobial. Patients will present with a necrotic digit that is purulent and very malodorous, with rapidly evolving pain, swelling, skin discoloration, and systemic collapse. Emergent treatment is the same as for other necrotizing infections, and amputation of the involved digit or extremity must often be performed.Infectious Flexor TenosynovitisFlexor tenosynovitis (FTS) is a severe pathophysiologic state causing disruption of normal flexor tendon function in the hand. A variety of etiologies are responsible for this process. Most acute cases of FTS are due to purulent infection. FTS also can occur secondary to chronic inflammation as a result of diabetes, RA, crystalline deposition, overuse syndromes, amyloidosis, psoriatic arthritis, systemic lupus erythematosus, and sarcoidosis.The primary mechanism of infectious FTS usually is penetrating trauma. Most infections are caused by skin flora, including both Staphylococcus and Streptococcus species. Bac-teria involved vary by etiology of the infection: bite wounds (Pasteurella multocida—cat, E corrodens—human); diabetic patients (Bacteroides, Fusobacterium, Haemophilus species, gram-negative organisms); hematogenous spread (Mycobacte-rium tuberculosis, N gonorrhoeae); or water-related punctures (Vibrio vulnificus, Mycobacterium marinum). Infection in any of the fingers may spread proximally into the wrist, carpal tun-nel, and forearm, also known as Parona’s space.76Suppurative FTS has the ability to rapidly destroy a finger’s functional capacity and is considered a surgical emer-gency. Suppurative FTS results from bacteria multiplying in the closed space of the flexor tendon sheath and culture-rich synovial fluid medium causing migration of inflammatory cells and subsequent swelling. The inflammatory reaction within the closed tendon sheath quickly erodes the paratenon, leading to adhesions and scarring, as well as increase in pressures within the tendon sheath that may lead to ischemia. The ultimate con-sequences are tendon necrosis, disruption of the tendon sheath, and digital contracture.Patients with infectious FTS present with pain, redness, and fever (Fig. 44-20). Physical examination reveals Kanavel’s “cardinal” signs of flexor tendon sheath infection: finger held in slight flexion, fusiform swelling, tenderness along the flexor ten-don sheath, and pain over the flexor sheath with passive exten-sion of the digit.77 Kanavel’s signs may be absent in patients who are immunocompromised, have early manifestations of Figure 44-20. Suppurative flexor tenosynovitis of the ring finger. A. The finger demonstrates fusiform swelling and flexed posture. B. Proximal exposure for drainage. C. Distal drainage incision.Brunicardi_Ch44_p1925-p1966.indd 195020/02/19 2:49 PM 1951SURGERY OF THE HAND AND WRISTCHAPTER 44infection, have recently received antibiotics, or have a chronic, indolent infection.If a patient presents with suspected infectious FTS, empiric intravenous antibiotics should be initiated. Prompt medical ther-apy in early cases may prevent the need for surgical drainage. For healthy individuals, empiric antibiotic therapy should cover Staphylococcus and Streptococcus. For immunocompromised patients (including diabetics) or infections associated with bite wounds, empiric treatment should include coverage of gram-negative organisms as well.78Adjuncts to antibiotics include splint immobilization (intrinsic plus position preferred) and elevation until infec-tion is under control. Hand rehabilitation (i.e., range-of-motion exercises and edema control) should be initiated once pain and inflammation are under control.If medical treatment alone is attempted, then initial inpa-tient observation is indicated. Surgical intervention is necessary if no obvious improvement has occurred within 12 to 24 hours.Several surgical approaches can be used to drain infectious FTS. The method used is based on the extent of the infection. Michon developed a classification scheme that can be use-ful in guiding surgical treatment (Table 44-1).79 Figure 44-20 (B and C) demonstrates drainage of a stage II FTS. A Brunner incision allows better initial exposure but may yield difficul-ties with tendon coverage if skin necrosis occurs. A 16-gauge catheter or 5-French pediatric feeding tube then is inserted into the tendon sheath through the proximal incision. The sheath is copiously irrigated with normal saline. Avoid excessive fluid extravasation into the soft tissue because the resulting increase in tissue pressure can lead to necrosis of the digit. The catheter is removed after irrigation. The incisions are left open. Some surgeons prefer a continuous irrigation technique for a period of 24 to 48 hours. The catheter is sewn in place, and a small drain is placed at the distal incision site. Continuous or intermittent irrigation every 2 to 4 hours with sterile saline can then be per-formed through the indwelling catheter.After surgery, an intrinsic plus splint is applied, the hand is elevated, and the appropriate empiric antibiotic coverage is instituted while awaiting culture results. The hand is reexamined the following day. Whirlpool therapy and range of motion are begun. Drains are removed before discharge from the hospital. The wounds are left open to heal by secondary intention. In severe cases, repeat irrigation and operative debridement may be required.Antibiotic therapy is guided by culture results as well as clinical improvement. Once there is no further need for debride-ment, a 7to 14-day course of oral antibiotics is generally prescribed. Consultation with an infectious disease specialist should be considered early in order to maximize efficiency and efficacy of therapy.FelonA felon is a subcutaneous abscess of the fingertip and is most commonly caused by penetrating trauma. S aureus is the most common pathogen. The fingertip contains multiple septa con-necting the distal phalanx to the skin. These septa are poorly compliant, and presence of an abscess will increase pressure and lead to severe pain and tissue death. Patients will experience erythema, swelling, and tenderness of the volar digital pad. Oral antibiotics may resolve the infection if diagnosed very early, but incision and drainage is indicated when fluctuance is identified. A digital block should be performed, followed by a longitudi-nal incision over the point of maximal fluctuance (Fig. 44-21). Transverse and lateral incisions should be avoided, and the incision should never extend across the distal phalangeal joint crease. Deep incision should not be performed as this may cause seeding of bacteria into the flexor tendon sheath. The wound is irrigated and packed, with warm soapy water soaks and packing changes initiated within 24 hours and performed two to three times daily until secondarily healed. Antibiotic coverage should cover for Staphylococcus and Streptococcus species.73ParonychiaParonychia is an infection beneath the nail fold. The nail plate can be viewed as an invagination into the dorsal skin extend-ing down to the distal phalanx periosteum. Predisposing factors include anything that causes nail trauma, such as manicures, artificial nails, or nail biting. The infection may spread around Table 44-1Michon’s stages of suppurative flexor tenosynovitis and appropriate treatmentSTAGEFINDINGSTREATMENTIIncreased fluid in sheath, mainly a serous exudateCatheter irrigationIIPurulent fluid, granulomatous synoviumMinimal invasive drainage ± indwelling catheter irrigationIIINecrosis of the tendon, pulleys, or tendon sheathExtensive open debridement and possible amputationBAFigure 44-21. Felon. A. Lateral view of the digit showing fluctu-ance between the skin of the pad and the underlying distal phalanx bone. B. The authors prefer to drain felons with a longitudinal inci-sion (dashed line) directly over the area of maximal fluctuance.Brunicardi_Ch44_p1925-p1966.indd 195120/02/19 2:49 PM 1952SPECIFIC CONSIDERATIONSPART IIthe nail plate from one side to the other, or it may extend into the pulp and result in a felon. An acute paronychia is usually caused by S aureus or Streptococcal species. Patients report pain, ery-thema, swelling, and possibly purulent drainage involving the periungual tissue. Treatment consists of warm water soaks and oral antibiotics if diagnosed early. If purulence or fluctu-ance is present, then a freer elevator or 18-gauge needle can be passed along the involved nail fold to decompress the collection (Fig. 44-22). If the infection involves the eponychial fold, a small proximally based flap of eponychium is created by using a scalpel, followed by irrigation and packing. The nail plate must be removed if the infection extends beneath the nail plate. Packing is kept in place for 24 to 48 hours, followed by warm water soaks and local wound care. Usually, the wound cannot be repacked once the dressing is removed.73A chronic paronychia is most commonly caused by Can-dida species and is most often found in patients who perform jobs involving the submersion of their hands in water or other moist environments. These develop into thickened nails with callus-like formation along the nail folds and may occasion-ally become red and inflamed. They do not respond to antibi-otic treatment, and nail plate removal with marsupialization of the skin proximal to the eponychial fold will allow the wound to heal secondarily. The environmental factors leading to the chronic paronychia must also be corrected in order for treatment to be successful.All hand infections other than cellulitis will require surgi-cal management. Clinical examination, particularly noting the area of greatest tenderness and/or inflammation, is the single most useful diagnostic tool to localize any puru-lence requiring drainage. Specific recommendations for differ-entiating among the possible locations of hand infection are included in the diagnostic algorithm shown in Fig. 44-23.TUMORSTumors of the hand and upper extremity can be classified as benign soft tissue tumors; malignant soft tissue tumors (subclas-sified into cutaneous and noncutaneous malignancies); benign bony tumors; malignant bony tumors; and secondary metastatic tumors. Initial investigation for any mass starts with a complete 6ABAFigure 44-22. Paronychia. A. Fluctuance in the nail fold is the hallmark of this infection. B. The authors prefer to drain a paro-nychia using the bevel of an 18-gauge needle inserted between the nail fold and the nail plate at the location of maximal fluctuance.NondiagnosticFractureForeign bodyCellulitisadmit, IV Abxserial examSite of fluctuanceEntire fingerseYoNPyogenic FTSKanavel’ssigns presentMRI if nofluctuanceSubcutaneousabscessThenarabscessMidpalmabscessHypothenarabscessDistalLoss ofpalmarconcavityRadial toIF MCUlnar toSF MCWeb spaceabscessPalmPain withaxial loadingof jointPyogenic vs.crystallinearthritisConsiderarthrocentesisNo improvementin 48 hoursHand inflammationPlain X-raysPartial fingerDorsalCenteredon jointBetweendigitsLocalized fluctuanceFigure 44-23. Diagnostic algorithm. Diagnostic workup for a patient with hand inflammation to evaluate for infection. See text for details about particular infectious diagnoses. Abx = antibiotics; FTS = flexor tenosynovitis; IF MC = index finger metacarpal; MRI = magnetic resonance imaging; SF MC = small finger metacarpal.Brunicardi_Ch44_p1925-p1966.indd 195220/02/19 2:49 PM 1953SURGERY OF THE HAND AND WRISTCHAPTER 44history and physical exam. Hand and/or wrist X-rays should be obtained in every patient presenting with a mass unless clearly not indicated (e.g., a superficial skin lesion with no aggressive/malignant features). The workup proceeds in an orderly fashion until a diagnosis is obtained. Once a benign diagnosis is secured (by strong clinical suspicion in an experienced hand surgeon, radiographic evidence, or tissue biopsy), further workup is not needed; this may occur at any point in the workup of a mass.Most hand masses are benign and can be readily diagnosed without advanced imaging or tissue biopsy. When necessary, additional workup may include baseline laboratory studies, CT and/or MRI of the involved region, and a bone scan or positron emission tomography (PET) scan. Staging of a malignant tumor may occur before biopsy if a malignancy is strongly suspected, or it may occur after formal biopsy. Staging includes a chest X-ray and CT with intravenous contrast of the chest, abdomen, and pelvis to detect possible metastasis. Biopsy of the mass is always the last step of a workup and should occur only after all other available information has been gathered. Any mass that is over 5 cm in size, is rapidly increasing in size (as judged by an experienced surgeon or oncologist), is symptomatic or painful, or has an aggressive clinical or radiographic appearance war-rants workup and biopsy to rule out malignancy.CT scans are useful for detecting bony tumor extension across planes and identifying tumors of small bones, such as the carpal bones. MRI is useful for evaluating soft tissue tumor involvement (e.g., which muscle compartments are involved) as well as intramedullary lesions. Most soft tissue tumors will appear dark on T1-weighted images and bright on T2-weighted images. Hematomas, hemangiomas, lipomas, liposarcomas, and adipose tissue will appear bright on T1-weighted images and dark on T2-weighted images. Scintigraphy uses methylene diphosphonate attached to technetium-99m. This complex will attach to hydroxyapatite. Immediate uptake is seen in areas of increased vascularity, such as infection, trauma, and neoplasia. Increased uptake 2 to 3 hours later is seen in “pooled” areas where new bone formation has occurred. This modality is useful for detecting areas of tumor invasion or metastases not other-wise seen on prior CT, MRI, or radiographs.Biopsy is reserved for masses that cannot be diagnosed as benign based on prior clinical and radiographic exams. Needle biopsy is not reliable for primary diagnosis, but it can be use-ful for recurrent or metastatic disease. Open excisional (if mass is less than 5 cm in size) or incisional (if mass is greater than 5 cm in size) biopsy is the most common biopsy method. Proper surgical oncologic technique is strictly adhered to in order to prevent tumor spread into uninvolved tissues or compartments. This includes making all incisions longitudinally using sharp dissection and meticulous hemostasis; carrying the incision directly down to the tumor with no development of tissue planes (i.e., making a straight-line path from skin to tumor); incising through the fewest number of muscle compartments; and avoid-ing critical neurovascular structures. The CT or MRI images will help determine the best surgical approach for biopsy or resection in order to avoid uninvolved compartments and criti-cal structures.80Benign Soft Tissue TumorsGanglion Cyst. This is the most common soft tissue tumor of the hand and wrist, comprising 50% to 70% of all soft tis-sue tumors in this region. They can occur at any age but are most common in the second to fourth decades with a slight predilection toward females. Patients may report a slowgrowing soft mass that may fluctuate in size and can sometimes be associated with mild pain. Compressive neuropathies may be seen if they occur in Guyon’s canal or the carpal tunnel, but they are uncommon. There are no reports of malignant degeneration. History and physical exam are usually sufficient to establish a diagnosis. Occurrence by location is as follows: 60% to 70% occur on the dorsal wrist between the third and fourth exten-sor compartments and are connected by a stalk to the scaph-olunate ligament (Fig. 44-24); 18% to 20% occur on the volar wrist; and 10% to 12% occur in the digits as volar retinacular or flexor tendon sheath cysts. The cyst transilluminates. There is always a stalk that communicates with the underlying joint or tendon sheath. The cyst wall is composed of compressed col-lagen fibers with no epithelial or synovial cells present. Clear viscous mucin fills the cyst and is composed of glucosamine, albumin, globulin, and hyaluronic acid. The etiology is unclear. The most accepted theory currently is Angelides’ who proposed that repeated stress of a joint, ligament, or tendon sheath causes an increase of mucin-producing cells and subsequent mucin pro-duction. The increased mucin production dissects superficially and coalesces into a cyst. The successful treatment of dorsal ganglion cysts by excising only the stalk supports this theory.80Treatment consists of observation if asymptomatic. If symptoms exist or the patient desires removal for cosmetic appearance, aspiration of the cyst may be performed with a Figure 44-24. Dorsal wrist ganglion cyst. These typically occur between the third and fourth dorsal extensor compartments and have a stalk connecting the base of the cyst to the scapholunate ligament.Brunicardi_Ch44_p1925-p1966.indd 195320/02/19 2:49 PM 1954SPECIFIC CONSIDERATIONSPART IIsuccessful cure rate ranging from 15% to 89%. The benefit of injected steroids is inconclusive. Aspiration of a volar wrist ganglion cyst can be dangerous due to the potential of injur-ing neurovascular structures. Open excision and arthroscopic excision of the cyst stalk are surgical options for cysts that are not amendable to aspiration. A recent meta-analysis reported recurrence rates after either needle aspiration, open excision, and arthroscopic excision as 59%, 21%, and 6%, respectively.81Mucous Cyst. A mucous cyst is a ganglion cyst of the DIP joint. They occur most commonly in the fifth to seventh decades, and the underlying cause is associated osteoarthritis of the DIP joint. They are slow growing and usually occur on one side of the ter-minal extensor tendon between the DIP joint and the eponych-ium. The earliest clinical sign is often longitudinal grooving of the involved nail plate followed by a small enlarging mass and then attenuation of overlying skin. X-rays will show signs of osteoarthritis within the DIP joint. Heberden nodes (osteophytes within the DIP joint) are often seen on X-ray.Possible treatment includes observation, aspiration, or excision. If the cyst is not draining and the overlying skin is intact, the patient may be offered reassurance. A draining cyst poses risk of DIP joint infection due to the tract communicating with the DIP joint and should be excised. If the cyst is symp-tomatic, painful, or the patient desires removal for cosmetic pur-poses, excision should be performed. Any osteophytes in the DIP joint must be removed to reduce recurrence. Aspiration is an option for treatment, but this poses the risk of DIP joint infec-tion through seeding of bacteria into the joint or by the devel-opment of a draining sinus tract. It is generally not performed.Giant Cell Tumor of the Tendon Sheath. Also known as a xanthosarcoma, fibrous xanthoma, localized nodular synovitis, sclerosing hemangioma, or pigmented villonodular tenosynovi-tis, giant cell tumor of the tendon sheath is the second most com-mon soft tissue mass of the hand and wrist. It is a benign lesion with no clear pathogenesis. The tumor is a growth of polyclonal cells with no risk of malignant transformation. Despite the simi-larity in name, it is not histopathologically related to giant cell tumor of the bone.82Giant cell tumor of the tendon sheath occurs as a firm slow-growing painless mass over months to years and will often feel bumpy or nodular, which is a distinguishing characteristic helpful for diagnosis. It has a predilection for occurring in close proximity to joints along flexor surfaces of the wrist, hands, and digits (especially the PIP joints of the radial digits) and occurs most commonly between the second and fifth decades (Fig. 44-25A). These tumors do not transilluminate. Direct extension into joints and ligaments can make complete exci-sion difficult. Gross appearance of the tumor will show a wellcircumscribed nodular firm mass with a deep brown color due to the large amount of hemosiderin content, which is easily detected on histologic staining (Fig. 44-25B). Multinucleated giant cells and hemosiderin-laden macrophages are characteristic.80This tumor is not visible on radiographs. Approximately 20% will show extrinsic cortical erosion on X-ray. This is a risk factor for recurrence, and removal of the cortical shell should be considered. MRI is useful for delineating involvement with tendons, ligaments, and joints.The standard treatment is marginal excision. These tumors will often grow next to or around neurovascular bundles, and an Allen’s test should always be performed preoperatively to con-firm adequate blood supply by both ulnar and radial arteries as Figure 44-25. Giant cell tumor of tendon sheath. A. The mass pro-duces lobulated enlargement of the external finger. B. The excised giant cell tumor has a multilobulated, tan-brown appearance.ABwell as dual blood supply to an involved digit via the ulnar and radial proper digital arteries. It is important to completely excise the stalk because this will greatly reduce tumor recurrence even in the setting of residual tumor. If tumor is suspected to have extended into the joint, the joint must be opened and all tumor removed. Despite this being a benign lesion, local recurrence is varies widely from 4% to 44%. Some variants can mimic more aggressive processes, and malignancy must be considered if aggressive features are identified, such as direct bony invasion.82Lipoma. Lipomas of the hand and wrist may occur in multiple anatomic locations, including subcutaneous tissues; intramus-cularly (especially thenar or hypothenar muscles); deep spaces; carpal tunnel or Guyon’s canal; and rarely bone or nerve. They typically present as a painless, slow-growing, soft, and mobile mass over a period of months to years. Painful findings sug-gest close approximation to a neurovascular structure or, less commonly, a malignant lesion such as liposarcoma. Lipomas do not transilluminate. They resemble mature fat histologically. X-rays typically reveal no abnormality. MRI is a helpful imag-ing modality to evaluate a lipoma and will show signal charac-teristics that are suggestive of adipose tissue.80Asymptomatic lesions with no aggressive findings may be observed. Marginal excision is recommended for symptomatic, painful, or enlarging lipomas or those that cause dysfunction. MRI is recommended for deep lipomas to evaluate proxim-ity or involvement of critical structures, followed by marginal excision if MRI findings are consistent with a lipoma. If MRI findings are not consistent with a lipoma, incisional biopsy is warranted. Recurrence after marginal excision is rare.80Brunicardi_Ch44_p1925-p1966.indd 195420/02/19 2:50 PM 1955SURGERY OF THE HAND AND WRISTCHAPTER 44Schwannoma. A schwannoma, also known as a neurilem-moma, is a type of benign peripheral nerve sheath tumor. It is the most common benign peripheral nerve sheath tumor of the upper extremity.83 The majority occur as single solitary masses. Patients with neurofibromatosis type 1 (NF1) or 2 (NF2) may develop multiple schwannomas involving large peripheral nerve trunks or bilateral acoustic schwannomas, respectively. These tumors arise from the Schwann cell and occur most often in the middle decades of life. They grow as painless, slow-growing, firm, round, well-encapsulated masses with a predilection toward flexor surfaces of the forearm and palm (given their presence of large nerves). Schwannomas grow from the peripheral nerve sheath and are usually connected by a pedicled stalk. The tumor is well demar-cated and can be readily separated from the nerve fascicles (Fig. 44-26). Unlike neurofibromas, they do not grow within the nerve. Paresthesias or other neurologic findings may occur, but they are usually absent, as is the Tinel’s sign. Findings such as pain, paresthesias, or numbness should raise concern for a tumor causing a compressive neuropathy or a tumor that is malignant.83Histologic exam reveals Antoni type A palisades of spindle cells with large oval nuclei with interlacing fascicles. Less cellular regions appear as Antoni type B areas. Mutations of the schwanomin gene on chromosome 22 are found in 50% of sporadic cases and 100% of acoustic schwannomas in patients with NF2.84Surgical treatment is reserved for symptomatic tumors and those that require biopsy to rule out a malignant process. An MRI should be obtained prior to surgery to confirm that the tumor is not located within the nerve (i.e., a neurofibroma) and that it is consistent with a schwannoma. Operative treatment involves excisional biopsy. If the tumor is adherent to adjacent soft tissue or not encapsulated, incisional biopsy is performed and excision is delayed pending pathology results. Malignant degeneration is exceedingly rare.83Malignant Soft Tissue Tumors—CutaneousSquamous Cell Carcinoma. Squamous cell carcinoma (SCC) is the most common primary malignant tumor of the hand, accounting for 75% to 90% of all malignancies of the hand. Eleven percent of all cutaneous SCC occurs in the hand.85 It is the most common malignancy of the nail bed. Risk factors include sun exposure, radiation exposure, chronic ulcers, immu-nosuppression, xeroderma pigmentosa, and actinic keratosis. Marjolin’s ulcers represent malignant degeneration of old burn or traumatic wounds into an SCC and are a more aggressive type. Transplant patients on immunosuppression have a fourfold increased risk, and patients with xeroderma pigmentosa have a 65 to 200–fold increased risk of developing an SCC.86 They often develop as small, firm nodules or plaques with indistinct margins and surface irregularities ranging from smooth to ver-ruciform or ulcerated (Fig. 44-27). They are locally invasive, with 2% to 5% lymph node involvement. Metastasis rates of up to 20% have been reported in radiation or burn wounds. Stan-dard treatment is excision with 0.5to 1.0-cm margins. Other treatment options include curettage and electrodessication, cryotherapy, and radiotherapy.85Basal Cell Carcinoma. Basal cell carcinoma (BCC) is the sec-ond most common primary malignancy of the hand, accounting for 3% to 12%; 2% to 3% of all BCCs occur on the hand. Risk fac-tors are similar for SCC and include chronic sun exposure, light complexion, immunosuppression, inorganic arsenic exposure, and Gorlin’s syndrome. Presentation includes a small, well-defined nodule with a translucent, pearly border and overlying telangi-ectasias (Fig. 44-28). Metastasis is very rare. Standard treatment is excision with 5-mm margins. Other treatment options include curettage and electrodessication, cryotherapy, and radiotherapy.Melanoma. Melanoma accounts for approximately 4% of skin cancers and is responsible of 80% of all deaths from skin cancer. Approximately 2% of all cutaneous melanomas occur in the hand.87 Risk factors include sun exposure (especially blis-tering sunburns as a child), dysplastic nevi, light complexion, family history of melanoma, immunosuppression, and congenital Figure 44-26. Schwannomas grow as a firm, round, well-encapsulated mass within the epineurium of a peripheral nerve. Schwannomas are able to be separated from the nerve fascicles relatively easily because they do not infiltrate between them (unlike neurofibromas).Figure 44-27. Squamous cell carcinoma involving the nail fold and nail bed. Note the wart-like and ulcerated appearance.Brunicardi_Ch44_p1925-p1966.indd 195520/02/19 2:50 PM 1956SPECIFIC CONSIDERATIONSPART IInevi. Pigmented lesions with irregular borders, color changes, increase in growth, or change in shape are suggestive of mela-noma. Breslow thickness is the most important factor in predicting survival for a primary melanoma. Melanoma in situ lesions should be surgically excised with 0.5 cm margins. For lesions up to 1 mm in thickness, 1-cm margins should be used. Two centimeter mar-gins should be used for lesions over 1 mm in thickness.88 Sentinel lymph node biopsy is done for lesions over 1 mm in thickness or for any lesion that is over 0.76 mm in thickness and exhibits ulcer-ation or high mitotic rate.89 Any clinically palpable lymph node requires a formal lymph node dissection of the involved basin, as do sentinel lymph nodes positive for melanoma. Lymph node dis-section has not been shown to offer any long-term survival ben-efit, but the information gained from sentinel lymph node biopsy (or lymph node dissection) does offer valuable staging informa-tion that is important for prognosis. For cases of subungual mela-nomas, DIP amputation is the current standard of care. A recent study reported similar recurrence and survival rates when com-paring patients treated with either DIP amputations or wide local excision; however, there was insufficient evidence to conclude if one treatment was superior to another.90Malignant Soft Tissue Tumors—NoncutaneousPrimary soft tissue sarcomas of the upper extremity are very rare. Approximately 12,000 new cases of sarcomas are diag-nosed each year and of those, only 15% occur in upper extremity.80 Statistical inference is limited due to the rare occur-rence of these tumors, but mortality rate is very high despite the aggressive treatments. Fewer than 5% of soft tissue sarcomas of the upper extremity will develop lymph node metastasis. Cutaneous malignancies must be considered in the differential diagnosis for any patient with palpable lymph nodes in the setting of any upper extremity mass. Any lesion of the upper extremity that is over 5 cm in diameter, rapidly enlarges, or is painful should be considered malignant until proven otherwise.91Treatment for soft tissue sarcomas can range from pallia-tive debulking to attempted curative resection. Many muscles of the upper extremity and their compartments cross joints (e.g., forearm flexors). Any malignancy within a compartment mandates complete resection of that compartment, and there-fore, amputations must often be performed at levels much more proximal than the level of the actual tumor. Many soft tissue sarcomas are not responsive to radiation or chemotherapy, and use of these adjuvant treatments must be decided upon after discussion with medical and radiation oncologists in a multi-disciplinary team. Several studies have shown higher mortality rates in patients who undergo initial tumor biopsy of sarcomas at institutions from which they do not ultimately receive treatment. These studies recommend biopsy be performed at the institution at which definitive treatment will be provided.92 Institutions best suited for such treatment should have pathologists familiar with soft tissue sarcomas, medical and radiation oncologists, surgical oncologists, and a multidisciplinary tumor board.An in-depth review of each type of soft tissue sarcoma is beyond the scope of this chapter. Epithelioid sarcoma is the most common primary soft tissue sarcoma of the upper extremity and usually presents as a benign-like slow-growing mass during the third or fourth decades. It has a propensity for the forearm, palm, and digits. Spread to lymph nodes has been reported. It typically spreads along fascial planes.80 Synovial sarcoma is argued by some to be the most common primary soft tissue sarcoma of the hand and wrist, but the paucity of case reports is inconclusive. It is a high-grade malignancy that is painless and slow-growing and usually occurs adjacent to, but not involving, joints. It is most common in the second to fifth decades of life. Tumor size (greater than 5 cm) is positively correlated with mortality. Other sarcomas include malignant fibrous histiocytoma, liposarcoma, fibrosarcoma, dermatofibrosarcoma protuberans, and malignant peripheral nerve sheath tumors, and more information can be found in further selected reading.93 The majority of metastases to the hand involve secondary bone tumors and are discussed later in the section, “Secondary Metastatic Tumors.”Benign Bone TumorsPrimary benign bone tumors of the hand and wrist make up a total of 7% of all primary benign bone tumors in the body. Benign tumors of cartilage origin comprise 79% of all primary benign bone tumors of the hand and wrist.94Enchondroma. This is the most common primary benign bone tumor of the hand and wrist and is of cartilage origin. Up to 90% of all bone tumors in the hand and wrist are enchondromas, with 35% to 54% of all enchondromas occurring in the hand and wrist. They are often found incidentally on X-rays taken for other reasons (e.g., hand trauma). They are usually solitary and favor the diaphysis of small tubular bones and are most com-mon in the second and third decades of life. The most common location is in the proximal phalanges, followed by the metacar-pals and then middle phalanges. Enchondroma has never been reported in the trapezoid. Presentation is usually asymptomatic, but pain may occur if there is a pathologic fracture or impending fracture. The etiology is believed to be from a fragment of carti-lage from the central physis. Histology shows well-differentiated hyaline cartilage with lamellar bone and calcification.94Figure 44-28. Basal cell carcinoma of the dorsal hand with sur-rounding telangiectasia.Brunicardi_Ch44_p1925-p1966.indd 195620/02/19 2:50 PM 1957SURGERY OF THE HAND AND WRISTCHAPTER 44Figure 44-29. Enchondroma. A. X-ray of the phalanx demon-strates a well-defined central lucency. Surrounding cortex may thin or thicken. Thinning of the cortex contributes to risk of pathologic fracture. B. Intraoperative fluoroscopy after curettage of the tumor. A radiopaque ribbon is used to occupy the defect to help ensure that there is no tumor (similarly radiolucent to the defect after curettage) left behind prior to bone grafting.BATwo variants of enchondroma include Ollier’s disease (multiple enchondromatosis) and Maffucci’s syndrome (multi-ple enchondromatosis associated with multiple soft tissue hem-angiomas). Malignant transformation is very rare in the solitary form, but there is a 25% incidence by age 40 in Ollier’s patients and a 100% life-time incidence in Maffucci’s patients. When malignant transformation does occur, it is almost uniformly a chondrosarcoma with pain and rapid growth.95Diagnosis is usually made based on history, physical exam, and X-rays. There is a well-defined, multilobulated cen-tral lucency in the metaphysis or diaphysis that can expand caus-ing cortical thinning or, sometimes, thickening (Fig. 44-29A). Further imaging is seldom needed, but a CT would be the study of choice.Observation is indicated for asymptomatic enchondromas with no risk of impending fracture, followed by annual X-rays for 2 years. If a pathologic fracture is found, it is treated with immobilization until fracture union and then surgically treated. If there is any uncertainty as to whether it is an enchondroma, incisional biopsy is indicated, and definitive treatment is postponed pending final pathology. Symptomatic lesions and those with impending fracture are treated surgically. Surgical treatment consists of an open incisional biopsy and confirmation by frozen section that it is well-differentiated hyaline cartilage. Curettage and high-speed burring are used to ablate the tumor. Intraoperative fluoroscopy is used to confirm complete ablation (Fig. 44-29B). The defect is then packed with bone graft or bone substitute. Recurrence ranges from 2% to 15%. X-rays should be obtained serially after surgery.94Periosteal Chondroma. Periosteal chondromas are benign bone tumors of cartilage origin that arise most commonly within or adjacent to periosteum at the metaphyseal-diaphyseal junc-tion in phalanges. They occur usually in the second or third decade as solitary lesions with pain, swelling, deformity, and possible pathologic fracture. X-rays reveal a subperiosteal lytic, unilobular lesion with erosion into adjacent cortex. There is often a rim of sclerosis. Histologically, they appear as aggres-sive cartilage with atypia, and it can be difficult to differentiate these from chondrosarcomas.94Diagnosis involves X-rays with incisional biopsy to con-firm the benign diagnosis and avoid unnecessary amputation. Treatment includes en bloc resection of periosteum and cortico-cancellous bone. Recurrence is less than 4%.Osteoid Osteoma. This is a tumor of bone origin. Approxi-mately 5% to 15% of all osteoid osteomas occur in the hand and wrist and are most often found in the proximal phalanx or car-pus. They usually occur in the second or third decade and pres-ent with a deep, dull ache that is classically worse at night and relieved by nonsteroidal anti-inflammatory drugs (NSAIDs). X-rays reveal a central lucency that is usually less than 1 cm in diameter surrounded by reactive sclerosis. Bone scan or CT is helpful to secure the diagnosis.96Treatment consists of NSAID therapy only, and resolu-tion occurs at an average of 33 months. If the patient does not wish to undergo prolonged discomfort with conservative ther-apy, curettage or percutaneous ablation of the nucleus may be performed.96Giant Cell Tumor of Bone. Giant cell tumors of bone make up only 4% to 5% of all benign bone tumors in the body, and only 12% of these occur in the hand or wrist. Although its name is similar to that of “giant cell tumor of tendon sheath,” they are two separate tumors and do not share the same clinical or histo-pathologic characteristics. Approximately 2% occur in the hand and 10% occur in the distal radius; those within the distal radius are more aggressive. They usually occur in the fourth decade with pain and swelling and possibly pathologic fracture.97Giant cell tumor of the bone is unique in that it is benign on histology but does have metastatic potential and can cause death. It should be considered a low-grade malignancy.97 Workup includes a CT of the chest and total-body scintigra-phy to evaluate for metastases and multifocal lesions and MRI to evaluate the extent of local tissue involvement. The recom-mended treatment consists of surgical resection of the involved phalanges or metacarpals and wide excision of entire carpal rows. Treatment with curettage and adjuvant treatments only results in a high rate of recurrence. Local and systemic surveil-lance must be done for at least 10 years because metastasis has been reported to occur as late as 10 years postoperatively.97,98Malignant Bone TumorsMalignant primary and secondary bone tumors of the hand, like soft tissue malignancies, are exceedingly rare. An in-depth Brunicardi_Ch44_p1925-p1966.indd 195720/02/19 2:50 PM 1958SPECIFIC CONSIDERATIONSPART IIreview is beyond the scope of this chapter. The same principles for soft tissue sarcomas of the upper extremity apply here with regard to evaluation, biopsy, and treatment.Chondrosarcoma comprises 41% of all primary malignant bone tumors of the hand and wrist but only 1.5% of all chon-drosarcomas overall. It is most likely to occur from malignant degeneration from a preexisting lesion, with enchondromatosis and osteochondromatosis being the most common. It usually presents as a slow-growing, painless mass in the fourth to sixth decades and can be difficult to differentiate from its benign counterparts. X-ray reveals endosteal erosion, cortical expan-sion, cortical destruction, and calcification. Metastasis has never been reported for chondrosarcomas of the hand. Chondrosarco-mas are not responsive to chemotherapy or radiation.99Osteosarcoma of the hand is exceedingly rare; only 0.18% of osteosarcomas occur in the hand. It usually presents as a painful swelling with pathologic fracture in the fifth to eighth decades of life. Radiation exposure is believed to be a possible risk factor. X-ray findings vary widely, with 90% of tumors occurring at a metaphyseal location. Findings include an osteo-blastic or osteolytic lesion, cortical breakthrough with soft tissue extension, a “sunburst” pattern radially, or periosteal elevation (Codman’s triangle). The presence or absence of metastasis is the most important prognostic factor, with a 5-year survival of 70% in the absence of metastases and a 5-year survival of 10% if present. Preoperative chemotherapy is usually given, but radi-ation therapy plays no role.100Secondary Metastatic TumorsMetastases to the hand or wrist are rare, with only 0.1% of skel-etal metastases occurring in the hand. The majority of metas-tases to the hand are bone lesions, but soft tissue metastases have been reported. The most common primary site is the lung (40%), followed by the kidney (13%) and the breast (11%). Approximately 16% will have no known diagnosis of cancer.101 The most common sites are the distal phalanges, followed by the proximal and middle phalanges, metacarpals, and carpus. Patients will present with pain, swelling, and erythema. Dif-ferential diagnosis includes felon, gout, osteomyelitis, trauma, RA, or skin cancer. Treatment of a hand or wrist metastatic lesion must not interfere with treatment of the primary cancer. Treatment is usually palliative (simple excision or amputa-tion). The average life expectancy for these patients is less than 6 months.101BURNSThe palm of the hand makes up approximately 1% of the total body surface area. A burn involving the entire hand and digits is unlikely to cause life-threatening injury or shock, but seem-ingly small burns to the hand may cause severe permanent loss of function if not treated appropriately. Burns to the hand can cause serious shortand long-term disability. All burns to the hand are considered severe injuries that warrant transfer to a dedicated burn center for specialized treatment. This manage-ment will include a multidisciplinary team consisting of hand surgeons, burn surgeons, burn-specialized nurses, occupational therapists, case managers, and social workers.Superficial burns involve damage to the epidermis only and present with erythema, no blistering, and full sensation with blanching of skin. These will heal without scarring. Super-ficial partial-thickness burns involve damage to the papillary dermis; all skin appendages are preserved, and therefore, these readily reepithelialize with minimal to no scarring. Superficial partial-thickness burns are sensate and present with pain, ery-thema, blistering, and blanching of skin. Topical dressings are the mainstay of treatment. Deep partial-thickness burns involve damage to the reticular dermis with damage to skin appendages, as well as the dermal plexus blood vessels and nerves. These have decreased sensation and no cap refill and appear pale or white. Blistering may be present. Damage to the skin append-ages and blood supply in the dermal plexus precludes spontane-ous healing without scar. Excision with skin grafting is needed. Third-degree burns involve full-thickness damage through the dermis and are insensate with no blistering. They appear dry, leathery, and even charred.Acute ManagementAdvanced trauma life support guidelines should be followed. After primary survey, circulation to the hand should be assessed. Palpation and Doppler ultrasound should be used to evaluate blood flow within the radial and ulnar arteries, the pal-mar arches, and digital blood flow at the radial and ulnar aspect of each volar digital pad. A sensorimotor exam should be per-formed. Objective evidence of inadequate perfusion (i.e., deteri-orating clinical exam with changes in or loss of pulse or Doppler signal) indicates the need for escharotomy, especially in the set-ting of circumferential burns. Escharotomy may be performed at bedside with scalpel or electrocautery under local anesthesia or intravenous sedation. In the forearm, axially oriented midra-dial and midulnar incisions are made for the entire extent of the burn. Escharotomy should proceed as distally as necessary into the wrist and hand to restore perfusion. Digital escharotomies are made via a midaxial (the middle of the longitudinal axis on sagittal view) incision over the radial aspects of the thumb and small finger and the ulnar aspects of the index, middle, and ring fingers.102 These locations for digital escharotomies avoid pain-ful scars on the heavy-contact surfaces of each respective digit. After primary survey, vascular, and sensorimotor exams are complete, careful documentation should be made of all burns. This is best done with a Lund and Browder chart and includes location, surface area, and initial depth of burn.The burns should be dressed as soon as examination is complete. Gauze moistened with normal saline is a good initial dressing because it is easy, readily available, and will not leave ointment or cream on the wounds, which can hinder frequent examinations in the initial period. It is critical that no dressing is wrapped in a circumferential manner around any body part. Edema and swelling can lead to extremity ischemia if a circum-ferential dressing is in place. It is important to maintain body temperature above 37°C, especially in burn patients who have lost thermoregulatory function of the skin and now have moist dressings in place. The hands should be elevated above heart level to decrease edema formation, which can hinder motion and lead to late scar contracture. The hand should be splinted in the intrinsic plus position with the MPs flexed to 90° (placing MP collateral ligaments under tension), the IPs in straight extension (prevents volar plate adhesion), and the wrist in approximately 15° of extension.103 In rare cases, Kirschner wires or heavy steel wires/pins are needed to keep a joint in proper position. These are placed percutaneously through the involved joint and serve as a temporary joint stabilizer.After the primary and secondary surveys are complete, the wound should be evaluated again. Devitalized tissue should be Brunicardi_Ch44_p1925-p1966.indd 195820/02/19 2:50 PM 1959SURGERY OF THE HAND AND WRISTCHAPTER 44debrided. Wounds should be cleansed twice daily, typically with normal saline. Second-degree superficial burns may be dressed with Xeroform gauze and bacitracin. Silver sulfadiazine cream is another option for any secondor third-degree wound. It cov-ers gram-positive and gram-negative microbes, but it does not penetrate eschar. It should be applied at least one-sixteenth of an inch thick. Sulfamylon can be used in conjunction with silver sulfadiazine or alone. It deeply penetrates eschar and tissues and has good gram-positive coverage.Surgical ManagementAny burn wound will eventually heal with proper wound care. However, this may involve unacceptable scarring, deformity, contractures, pain, and unstable wounds that are prone to breakdown. The goal is to restore preinjury function as much as possible with a wound that is durable, supple, nonpainful, and allows the patient to return to society as an active member. Local wound care is the ideal treatment for wounds that can heal completely within 14 days while not sacrificing function. For deep partial-thickness or full-thickness burns, early surgical excision and skin grafting is necessary.103Considerable controversy surrounds the need, timing, and method of grafting burns. Careful consideration must be given to the patient’s overall status, their preinjury state, and the type of work and recreational activities they enjoyed in order to have a better understanding of which issues should be addressed. Tangential excision of the wounds should be performed under tourniquet to minimize blood loss and is carried down to viable tissue. Avoid excising through fascia (epimysium) overlying muscles or exposing tendons, bone, joint capsules, or neurovascular structures. Tissues capable of receiv-ing a skin graft include well-vascularized fat, muscle, perineu-rium, paratenon, perichondrium, and periosteum. Exposure of deep structures without an adequately graftable bed mandates further coverage before skin grafting can occur (discussed later in “Reconstruction”).Once there is an adequate bed, grafting is the next step. If there is any doubt as to whether the wound bed can support a skin graft, a temporary dressing such as Allograft (human cadaver skin) should be placed and the patient reexamined fre-quently for signs of granulation tissue and wound bed viability. It can remain in place for up to 14 days before rejection and can serve as a way of “testing” if a wound is ready to receive a skin graft. Skin grafts to the dorsum of the hand are typi-cally split-thickness sheet grafts (not meshed), as sheet grafts have a superior aesthetic appearance. Skin grafts to the palmar aspects of the hand should be full-thickness in order to provide the dermal durability needed for daily functions. Skin grafts are secured with staples, sutures, fibrin glue, or even skin glue. It is important to bolster every skin graft. This prevents shearing loss and also keeps the skin graft in contact with the wound bed, preventing fluid collections that can lead to graft loss. A bol-ster may consist of a tie-over bolster and a splint or a negativepressure dressing. The hand should be splinted in intrinsic plus for 7 days after skin grafting. Once the graft is adherent, hand therapy should begin, consisting of active and passive range-of-motion exercises and modalities.103ReconstructionReconstruction of burn wounds can begin as early as the acute setting and continue into the subacute and late stages. Burns may initially be superficial but later convert to deep burns (especially with grease, oil, and alkali burns) due to infection, tissue desiccation, or continued trauma, or they may be deep from the outset of injury. Debridement or excision of burns may result in exposure of viable muscle, bone, tendon, cartilage, joints, and neurovascular structures, as well as loss of fascial layers that are required for overlying soft tissue to glide during movement. Simply skin grafting these exposed structures will result in unstable wounds that are prone to chronic breakdown. Soft tissue contractures will develop as the skin grafts adhere to the structures, effectively anchoring them in static position. This is especially true for tendons, where gliding capability is paramount for function. Flap coverage is required in these situ-ations. The reversed radial forearm flap is a local flap and is often the first choice for flap coverage of the hand. If the zone of injury or size of defect precludes its use, other skin and fat flaps, including the free lateral arm, free anterolateral thigh, or even free parascapular flaps, may be useful, provided the patient can tolerate a free tissue transfer (see Chapter 45) operation (Fig. 44-30). The digits may also be buried subcutaneously in the lower abdominal skin or groin crease. Vascular ingrowth from the digits into the abdominal or groin skin occurs over 2 to 3 weeks, allowing division of the flap(s) and achieving full-thickness coverage of the wounds.104An acellular dermal regenerative substitute (e.g., Integra) may be used for wounds that have exposed structures and require more durability than is offered by a skin graft such as full-thickness loss overlying the extensor tendons of the wrist and hand.105 Dermal substitute is a good option for wounds that are not extensive enough to warrant a flap and for patients who are poor candidates for an extensive surgery. Integra is com-posed of acellular cross-linked bovine tendon collagen and gly-cosaminoglycan with an overlying silicone sheet. It is applied much like a skin graft. After incorporation in 14 to 21 days, it is capable of accepting a skin graft (after removing the silicone sheet). Conceptually, it works by replacing the lost dermis and adds durability to a wound bed. It may be reapplied multiple times to the same area if thicker neodermis is desired. Although cultured autologous keratinocytes have been used, they are expensive, time-consuming, and do not provide prompt or durable coverage.Web space contractures are the most common deformity resulting after hand burns. They may occur late despite the best efforts. In the normal web space, the leading edge of the volar Figure 44-30. Free anterolateral thigh flap reconstruction of a large dorsal hand wound. Once wound coverage is stable, this flap will need to be surgically revised to achieve proper contour.Brunicardi_Ch44_p1925-p1966.indd 195920/02/19 2:50 PM 1960SPECIFIC CONSIDERATIONSPART IIaspect of the web is distal to the dorsal aspect. This is reversed in web space contractures and limits digit abduction. Local modified Z-plasty (double-opposing Z-plasty) is the preferred treatment (Fig. 44-31).Special ConsiderationsChemical burns pose a risk to healthcare providers and should be considered hazardous material. They must also be removed from the patient or continued burn injury will occur. A complete discussion of all chemicals causing burns is beyond the scope of this chapter. Hydrofluoric acid produces a slow onset of severe pain and continues to penetrate deeper structures. It avidly binds tissue and circulating calcium and can lead to hypocalcemia and cardiac arrest. The wound should be irrigated copiously with water followed by topical or intra-arterial injection of calcium gluconate. Chromic acid burns should be treated with immediate lavage, phosphate buffer soaks and immediate surgical excision. Cement can result in chemical burns and should be treated with immediate irrigation and topical antibacterial ointments. Alka-line and acid burns require copious irrigation with water, with alkali burns often requiring hours of irrigation. Phenol burns should be irrigated with dilute polyethylene glycol wash fol-lowed by high-flow water lavage.106VASCULAR DISEASEVascular disease encompasses a broad spectrum of disorders leading to compromised perfusion to the hand and digits and may potentially cause ischemia and necrosis. Chronic vascular disorders tend to develop slowly and are typically seen in older patients. This includes progressive thrombosis, aneurysms, sys-temic vasculopathy, and vasospastic disorders. Disorders unique or common to the hand are discussed in the following sections.Progressive Thrombotic DiseaseHypothenar hammer syndrome involves occlusion of the ulnar artery at the wrist and is the most common occlusive vascular disorder of the upper extremity. The etiology is believed to be chronic trauma to the ulnar artery as it exits Guyon’s canal. The classic example is a construction worker who frequently uses heavy equipment, such as jackhammers, that cause prolonged vibration and repetitive impact on the ulnar aspect of the palm. This causes periadventitial arterial damage that results in scar-ring and eventual compression, as well as medial and intimal damage.107 The artery then becomes weakened and prone to aneurysm and/or thrombosis. If a thrombus forms, it may embo-lize, producing digital ischemia. Symptoms may be chronic or acute and include pain, numbness and tingling, weakness of grip, discoloration of the fingers, and even gangrene or ulcers of the fingertips.If acute in onset, proximal occlusions may be extracted with a balloon catheter or, sometimes, under direct vision via an arteriotomy. Very distal embolism may require infusion of thrombolytics to dissolve clots and allow reperfusion. Large-vessel acute embolism and reperfusion may result in edema and compartment syndrome, requiring fasciotomy. A high index of suspicion must be maintained.For the more common scenario of chronic, progres-sive occlusion, the involved segment of ulnar artery should be resected. There is disagreement in the literature regarding whether simple ligation and excision is sufficient for patients with sufficient distal flow or if all patients should undergo vas-cular reconstruction.108 The authors’ personal preference is to reconstruct all patients.Systemic VasculopathyBuerger’s disease (thromboangiitis obliterans) is an inflamma-tory occlusive disease affecting small and medium-sized arter-ies and veins. It is strongly influenced by smoking and will often resolve upon smoking cessation. The disease is classified into acute, intermediate, and chronic, depending on histologic progression of the disease. Migratory phlebitis occurs distal to the elbow, resulting in ischemia, rest pain, and ulceration and necrosis of the digits. It can continue to cause more proximal ischemia and ultimately lead to loss of the hands. Treatment must start with smoking cessation. Failure to stop smoking will make any surgical intervention unsuccessful. Arteriography is useful to determine arterial flow and whether bypass is possible. ABFigure 44-31. Z-plasty release of web space contracture. A. First web space burn contracture. B. Immediate postoperative result.Brunicardi_Ch44_p1925-p1966.indd 196020/02/19 2:50 PM 1961SURGERY OF THE HAND AND WRISTCHAPTER 44If direct bypass is not possible, alternatives include arteriali-zation of the venous system by connecting the dorsal venous network to the brachial artery or possible free microvascular omental transfer beneath the dorsal forearm or hand for indirect revascularization.109Vasospastic DisordersRaynaud’s syndrome results from excessive sympathetic ner-vous system stimulation. Perfusion is diminished and fingers often become cyanotic. Although the onset of the symptoms is benign, chronic episodes can result in atrophic changes and painful ulceration or gangrene of the digits. Raynaud’s disease occurs without another associated disease. This disease predom-inately affects young women and is often bilateral. The vascular system is structurally intact without any obstructions. There is no ulceration, gangrene, or digit loss. In contrast, Raynaud’s phenomenon is associated with an underlying connective tissue disorder, such as scleroderma. Arterial stenosis is present due to disease changes in blood vessels as a result of the specific medical disorder.110Scleroderma is an autoimmune connective tissue disorder resulting in fibrosis and abnormal collagen deposition in tissue. Many organs can be affected, with the skin most commonly and noticeably involved. In this disease, blood vessels are injured by intimal fibrosis leading to microvascular disease. The ves-sels become subject to Raynaud’s phenomenon, and patients develop painful, ulcerated, and sometimes necrotic digits.109,110Sympathectomy can provide pain relief and healing of ulcers for patients with scleroderma and Raynaud’s phenom-enon. In this procedure, adventitia is stripped from the radial artery, ulnar artery, superficial palmar arch, and digital arter-ies in various combinations based on the affected digits being treated. The decrease in sympathetic tone allows for vasodila-tion and increased blood flow. If the patient notes significant distal pain relief and/or previously ischemic tissue improves in color after a test administration of local anesthetic, sympathec-tomy may provide the same results in a long-term fashion.111 Recently, several studies have investigated the use of botulinum toxin on improving digital perfusion in patients with Raynaud’s. Reports have shown improved objective measurements of hand function 8-12 weeks after injection.112CONGENITAL DIFFERENCESCongenital differences in a newborn can be particularly dis-abling as the child learns to interact with the environment by using the hands. The degree of anomaly can range from minor, such as a digital disproportion, to severe, such as total absence of a forearm bone. In recent years, increasing knowledge of the molecular basis of embryonic limb development has sig-nificantly enhanced the understanding of congenital differences. Congenital hand differences have an incidence of 1:1500 births. The two most common differences encountered are syndactyly and polydactyly.113There are numerous classification systems for hand dif-ferences. The Swanson classification, adopted by the American Society for Surgery of the Hand, delineates seven groups orga-nized based on anatomic parts affected by types of embryonic failures.114,115Failure of FormationThe failure of the formation of parts is a group of congenital differences that forms as a result of a transverse or longitudinal arrest of development. Conditions in this group include radial club hand, a deformity that involves some or all of the tissues on the radial side of the forearm and hand, and ulnar club hand, which involves underdevelopment or absence of the ulnar-sided bones.Failure of DifferentiationThe failure of the differentiation of parts comprises conditions where the tissues of the hand fail to separate during embryo-genesis. Syndactyly, in which two or more fingers are fused together, is the most common congenital hand deformity and occurs in 7 out of every 10,000 live births. There is a famil-ial tendency to develop this deformity. This deformity often involves both hands, and males are more often affected than females. Syndactyly is classified as either simple (soft tissue only) or complex (bone and/or cartilage also involved), and complete (full length of the digits) or incomplete (less than the full length).Surgical release of syndactyly requires the use of local flaps to create a floor for the interdigital web space and to partially surface the adjacent sides of the separated digits (Fig. 44-32). Residual defects along the sides of the separated fingers are covered with full-thickness skin grafts. Surgery usu-ally is performed at 6 to 12 months of age.DuplicationDuplication of digits is also known as polydactyly. Radial polydactyly is usually manifests as thumb duplication. Wassel described a classification system for thumb duplications based on the level of bifurcation.116 When two thumbs are present in the same hand, they are rarely both normal in size, alignment, and mobility. In the most common form of thumb duplication, a single broad metacarpal supports two proximal phalanges, each of which supports a distal phalanx. Optimal reconstruction requires merging of elements of both component digits. Usually the ulnar thumb is maintained. If the duplication occurs at the MP joint, the radial collateral ligament is preserved with the metacarpal and attached to the proximal phalanx of the retained ulnar thumb. Surgery is usually performed at 6 to 12 months of age. Ulnar-sided polydactyly may often be treated by simple excision of the extra digit.OvergrowthOvergrowth of digits is also known as macrodactyly, which causes an abnormally large digit. In this situation, the hand and the forearm also may be involved. In this rare condition, all parts of a digit are affected; however, in most cases, only one digit is involved, and it is usually the index finger. This condition is more commonly seen in males. Surgical treatment of this condi-tion is complex, and the outcomes may be less than desirable. Sometimes, amputation of the enlarged digit provides the best functional result.Constriction Band SyndromeUnderdeveloped fingers or thumbs are associated with many congenital hand deformities. Surgical treatment is not always required to correct these deformities. Underdeveloped fingers may include the following: small digits (brachydactyly), miss-ing muscles, underdeveloped or missing bones, or absence of a digit.Generalized Skeletal Anomalies and SyndromesThis is a rare and complex group of unclassified problems.Brunicardi_Ch44_p1925-p1966.indd 196120/02/19 2:50 PM 1962SPECIFIC CONSIDERATIONSPART IIRECONSTRUCTIVE TRANSPLANTATION OF THE UPPER EXTREMITYHand transplantation was first performed in humans in the late 1990s both in Louisville, Kentucky, and Lyon, France.117 The treating surgeons were able to successfully remove an upper extremity from a brain-dead donor, attach it to an upper extrem-ity amputee, and have the tissue survive. In the subsequent 15 years, many additional centers have achieved technical suc-cess with upper extremity transplantation as well.The technical considerations of hand transplantation have proven to be only the beginning of challenges in bring-ing this treatment option to the general public. Replantation of an amputated limb was first reported by Malt in 1962.118 In a limb replantation, there is a zone of injury, and cold preser-vation of the amputated part does not begin immediately. In a limb transplant, the harvest can be done as proximally as neces-sary to ensure that only healthy tissue is present on both sides of the repair and to obviate the need for limb shortening, and cold preservation of the amputated part can begin immediately after harvest.A major concern regarding the use of limb transplanta-tion is the immunosuppression medications required to prevent rejection of the transplanted limb. Unlike organ transplantation, which provides a critical organ without which the recipient could not survive or would require chronic mechanical support (e.g., hemodialysis), the absence of one or even multiple limbs does not represent an immediate threat to a patient’s survival. Multiple studies have documented the nephrotoxic and other side effects of tacrolimus (FK 506), the principle antirejection agent used in transplant immunomodulation protocols.119,120Due to these concerns, much research has been directed at minimizing the amount of antirejection medication as well as promoting tolerance or even chimerism. Donor bone mar-row transplantation to the limb transplant recipient has been shown to be beneficial toward this purpose and is part of the limb transplant protocol in some centers.121,122 Recent research with donor bone marrow infusions has shown that lower lev-els of immunosuppressive drugs may be possible, as well as fewer immunosuppressive agents.121 Further research is needed in order to determine the efficacy and utility of donor bone mar-row transfusions and how they impact transplant recipients in the short and long term.The final challenge in consideration of a patient for limb transplantation is selection of an appropriate candidate. There are multiple patient factors that need to be considered to deter-mine if a patient is an appropriate candidate for hand transplan-tation. These include medical concerns, such as immunologic issues (both antibodies and the presence of occult neoplasms or indolent viruses such as cytomegalovirus), hematologic issues including coagulopathies, and anatomic issues such as quality of skin envelope and amputation level of the bone and neuro-muscular structures. Psychological and social factors must also be considered related to the recipient’s ability to comply with postoperative medication and therapy protocols as well as to cope with a continuous visible presence of a limb originating from another person.123The promise of upper limb transplantation as a recon-structive technique remains high. Both civilian and military amputees stand to receive a marked functional benefit from this treatment. With the number of transplants performed worldwide ABCFigure 44-32. Syndactyly. A. Hand of a 1-year-old patient with complex syndactyly between the long and ring fingers. Complex syndactyly refers to fingers joined by bone or cartilaginous union, usually in a side-to-side fashion at the distal phalanges. B. Antero-posterior radiograph. C. The syndactyly is divided with interdigitat-ing full-thickness flaps, a dorsal trapezoidal-shaped flap to resurface the floor of the web space, and full-thickness skin grafts. Note the skin grafts on the ulnar and radial sides of the new web space.Brunicardi_Ch44_p1925-p1966.indd 196220/02/19 2:50 PM 1963SURGERY OF THE HAND AND WRISTCHAPTER 44approaching 100 as well as decades of animal research, under-standing of how best to use this technique from functional, patient safety, and cost-effectiveness standpoints continues to grow.REFERENCESEntries highlighted in bright blue are key references. 1. American Society for Surgery of the Hand. The Hand: Examination and Diagnosis. 3rd ed. New York: Churchill Livingstone; 1990:5-13. 2. Moore KL. The Upper Limb. Clinically Oriented Anatomy. Baltimore: Williams & Wilkins; 1992:501-635. 3. Schuind F, Cooney WP, Linscheid RL, An KN, Chao EY. Force and pressure transmission through the normal wrist. A theoretical two-dimensional study in the posteroanterior plane. J Biomech. 1995;28(5):587-601. 4. Gordon JA, Stone L, Gordon L. Surface markers for locating the pulleys and flexor tendon anatomy in the palm and fingers with reference to minimally invasive incisions. J Hand Surg Am. 2012;37:913-918. 5. Dumanian GA, Segalman K, Buehner JW, Koontz CL, Hendrickson MF, Wilgis EF. Analysis of digital pulse-volume recordings with radial and ulnar artery compression. Plast Reconstr Surg. 1998;102:1993-1998. 6. Green DP. General principles. In: Green DP, Hotchkiss RN, Pedersen WC, Wolfe SW, eds. Green’s Operative Hand Sur-gery. 5th ed. Philadelphia: Churchill Livingstone; 2005:3-24. 7. Gilula LA. Carpal injuries: analytic approach and case exer-cises. AJR Am J Roentgenol. 1979;133:503-517. 8. Karl JW, Swart E, Strauch RJ. Diagnosis of occult scaphoid fractures: a cost-effectiveness analysis. J Bone Joint Surg Am. 2015;97(22):1860-1868. 9. Dezfuli B, Taljanovic MS, Melville DM, Krupinski EA, Sheppard JE. Accuracy of high-resolution ultrasonography in the detection of extensor tendon lacerations. Ann Plast Surg. 2016;76(2):187-192. 10. Kretsinger K, Broder KR, Cortese MM, et al. Preventing teta-nus, diphtheria, and pertussis among adults: use of tetanus tox-oid, reduced diphtheria toxoid and acellular pertussis vaccine recommendations of the Advisory Committee on Immuni-zation Practices (ACIP) and recommendation of ACIP, sup-ported by the Healthcare Infection Control Practices Advisory Committee (HICPAC), for use of Tdap among health-care personnel. MMWR Recomm Rep. 2006;55(Rr-17):1-37. 11. Hastings H 2nd, Carroll C 4th. Treatment of closed articu-lar fractures of the metacarpophalangeal and interphalangeal joints. Hand Clin. 1988;4:203-227. 12. Liodaki E, Xing SG, Mailaender P, Stang F. Management of difficult intra-articular fractures or fracture dislocations of the proximal interphalangeal joint. J Hand Surg Eur Vol. 2015;40(1):16-23. 13. Jahss SA. Fractures of the metacarpals: a new method of reduction and immobilization. J Bone Joint Surg. 1938;20(1):178-186. 14. Bond CD. Percutaneous screw fixation or cast immobilization for nondisplaced scaphoid fractures. J Bone Joint Surg Am. 2001;83-a(4):483-488. 15. Mayfield JK, Johnson RP, Kilcoyne RF. The ligaments of the human wrist and their functional significance. Anat Rec. 1976;186(3):417-428. 16. Apostolides JG, Lifchez SD, Christy MR. Complex and rare fracture patterns in perilunate dislocations. Hand (N Y). 2011;6(3):287-294. 17. Kleinert HE, Kutz JE, Atasoy E, Stormo A. Primary repair of flexor tendons. Orthop Clin North Am. 1973;4(4): 865-876. This key manuscript changed the “axiom” and established that zone two flexor tendon injuries could be immediately repaired primarly. 18. Vinycomb TI, Sahhar LJ. Comparison of local anesthetics for digital nerve blocks: a systematic review. J Hand Surg Am. 2010;39(4):744-751.e5. 19. Lalonde D, Bell M, Benoit P, Sparkes G, Denkler K, Chang P. A multicenter prospective study of 3110 consecutive cases of elective epinephrine use in the fingers and hand: the Dalhousie Project clinical phase. J Hand Surg Am. 2005;30:1061-1067. This large case series supports that the use of lidocaine with epinephrine is safe to use in the hand. 20. Yousif NJ, Grunert BK, Forte RA, Matloub HS, Sanger JR. A comparison of upper arm and forearm tourniquet tolerance. J Hand Surg Br. 1993;18:639-641. 21. Lee HJ, Cho YJ, Gong HS, Rhee SH, Park HS, Baek GH. The effect of buffered lidocaine in local anesthesia: a pro-spective, randomized, double-blind study. J Hand Surg Am. 2013;38(5):971-975. 22. Best CA, Best AA, Best TJ, Hamilton DA. Buffered lidocaine and bupivacaine mixture—the ideal local anesthetic solution? Plast Surg (Oakv). 2015;23(2):87-90. 23. Higgins A, Lalonde DH, Bell M, McKee D, Lalonde JF. Avoiding flexor tendon repair rupture with intraoperative total active movement examination. Plast Reconstr Surg. 2010; 126(3):941-945. 24. Davison PG, Cobb T, Lalonde DH. The patient’s perspective on carpal tunnel surgery related to the type of anesthesia: a prospective cohort study. Hand (N Y). 2013;8(1):47-53. 25. Rodgers J, Cunningham K, Fitzgerald K, Finnerty E. Opioid consumption following outpatient upper extremity surgery. J Hand Surg Am. 2012;37(4):645-650. 26. Stanek JJ, Renslow MA, Kalliainen LK. The effect of an educational program on opioid prescription patterns in hand surgery: a quality improvement program. J Hand Surg Am. 2015;40(2):341-346. 27. Komatsu S, Tamai S. Successful replantation of a com-pletely cut-off thumb: case report. Plast Reconstr Surg. 1968;42:374-377. 28. Lifchez SD, Marchant-Hanson J, Matloub HS, Sanger JR, Dzwierzynski WW, Nguyen HH. Functional improvement with digital prosthesis use after multiple digit amputations. J Hand Surg Am. 2005;30:790-794. 29. Weichman KE, Wilson SC, Samra F, Reavey P, Sharma S, Haddock NT. Treatment and outcomes of fingertip injuries at a large metropolitan public hospital. Plast Reconstr Surg. 2013;131(1):107-112. 30. Bickel KD, Dosanjh A. Fingertip reconstruction. J Hand Surg Am. 2008;33(8):1417-1419. 31. Moberg E. The treatment of mutilating injuries of the upper limb. Surg Clin North Am. 1964;44:1107-1113. 32. Melone CP, Jr, Beasley RW, Carstens JH, Jr. The thenar flap—an analysis of its use in 150 cases. J Hand Surg Am. 1982;7(3):291-297. 33. Johnson RK, Iverson RE. Cross-finger pedicle flaps in the hand. J Bone Joint Surg Am. 1971;53(5):913-919. 34. Cannon TA. High-pressure injection injuries of the hand. Orthop Clin North Am. 2016;47(3):617-624. 35. Bekler H, Gokce A, Beyzadeoglu T, Parmaksizoglu F. The sur-gical treatment and outcomes of high-pressure injection inju-ries of the hand. J Hand Surg Eur Vol. 2007;32(4):394-399. 36. Kalyani BS et al. Compartment syndrome of the forearm: a systematic review. J Hand Surg Am. 2011;36(3):535-543. 37. Staudt JM, Smeulders MJ, van der Horst CM. Normal com-partment pressures of the lower leg in children. J Bone Joint Surg Br. 2008;90(2):215-219. 38. Al-Qattan MM, Abou Al-Shaar H, Al Mugaren FM. Non-union without avascular necrosis of finger phalangeal neck Brunicardi_Ch44_p1925-p1966.indd 196320/02/19 2:50 PM 1964SPECIFIC CONSIDERATIONSPART IIfractures in children: report of 4 cases. J Hand Surg Am. 2014;39(8):1529-1534. 39. Munk B, Larsen CF. Bone grafting the scaphoid nonunion: a systematic review of 147 publications including 5,246 cases of scaphoid nonunion. Acta Orthop Scand. 2004;75(5):618-629. 40. Curtis RM. Capsulectomy of the interphalangeal joints of the fingers. J Bone Joint Surg Am. 1954;36-a(6):1219-1232. 41. Brogan DM, Kakar S. Management of neuromas of the upper extremity. Hand Clin. 2013;29(3):409-420. 42. Zimmerman RM, Astifidis RP, Katz RD. Modalities for complex regional pain syndrome. J Hand Surg Am. 2015;40(7):1469-1472. 43. Schurmann M, Zaspel J, Löhr P, et al. Imaging in early post-traumatic complex regional pain syndrome: a comparison of diagnostic methods. Clin J Pain. 2007;23(5):449-457. 44. Mackinnon SE. Pathophysiology of nerve compression. Hand Clin. 2002;18(2):231-241. 45. US Department of Health and Human Services. Hand/wrist musculoskeletal disorders (carpal tunnel syndrome, hand/wrist tendonitis, and hand-arm vibration syndrome): evidence for work-relatedness. Available at: https://www.cdc.gov/niosh/docs/97-141/pdfs/97-141.pdf. Accessed August 16, 2018. 46. American Academy of Orthopedic Surgeons. Management of Carpal Tunnel Syndrome Evidence-Based Clinical Practice Guideline. Available at: https://www.aaos.org/uploadedFiles/PreProduction/Quality/Guidelines_and_Reviews/guidelines/CTS%20CPG_2.29.16.pdf. Accessed August 16, 2018. 47. Lifchez SD, Means KR, Jr, Dunn RE, Williams EH, Dellon AL. Intraand inter-examiner variability in performing Tinel’s test. J Hand Surg Am. 2010;35(2):212-216. 48. Williams TM, Mackinnon SE, Novak CB, McCabe S, Kelly L. Verification of the pressure provocative test in carpal tunnel syndrome. Ann Plast Surg. 1992;29(1):8-11. 49. Marshall S, Tardif G, Ashworth N. Local corticosteroid injec-tion for carpal tunnel syndrome. Cochrane Database Syst Rev. 2007(2):Cd001554. 50. Trumble TE, Diao E, Abrams RA, Gilbert-Anderson MM. Single-portal endoscopic carpal tunnel release compared with open release : a prospective, randomized trial. J Bone Joint Surg Am. 2002;84-a(7):1107-1115. Carpal tunnel release is one of the most common procedures performed by hand sur-geons. This study by Trumble highlights that although patients undergoing endoscopic carpal tunnel release have less pain in the immediate postoperative period, clinical outcomes after 3 months show no difference compared to traditional open approaches. 51. Mackinnon SE, Novak CB. Compression neuropathies. In: Wolfe SW, Hotchkiss RN, Kozin SH, Cohen MS, eds. Green’s Operative Hand Surgery. 7th ed. Amsterdam: Elsevier; 2016:921-958. This chapter does well to explain the mechanism, pathophysiology, and treatment for compression neuropathies in the upper extremity. 52. Ochi K, Horiuchi Y, Tanabe A, Morita K, Takeda K, Ninomiya K. Comparison of shoulder internal rotation test with the elbow flexion test in the diagnosis of cubital tunnel syndrome. J Hand Surg Am. 2011;36(5):782-787. 53. Goldfarb CA, Sutter MM, Martens EJ, Manske PR. Incidence of re-operation and subjective outcome following in situ decompression of the ulnar nerve at the cubital tunnel. J Hand Surg Eur Vol. 2009;34:379-383. 54. Kocak E, Carruthers KH, Kobus RJ. Distal interphalangeal joint arthrodesis with the Herbert headless compression screw: outcomes and complications in 64 consecutively treated joints. Hand (N Y). 2011;6(1):56-59. 55. Swanson AB. Implant resection arthroplasty of the proximal interphalangeal joint. Orthop Clin North Am. 1973;4:1007-1029. 56. Adkinson JM, Chung KC. Advances in small joint arthroplasty of the hand. Plast Reconstr Surg. 2014;134(6):1260-1268. 57. Naram A, Lyons K, Rothkopf DM, et al. Increased complica-tions in trapeziectomy with ligament reconstruction and ten-don interposition compared with trapeziectomy alone. Hand (N Y). 2016;11(1):78-82. 58. Gray KV, Meals RA. Hematoma and distraction arthroplasty for thumb basal joint osteoarthritis: minimum 6.5-year follow-up evaluation. J Hand Surg Am. 2007;32(1):23-29. 59. Kenniston JA, Bozentka DJ. Treatment of advanced carpo-metacarpal joint disease: arthrodesis. Hand Clin. 2008;24(3): 285-294, vi-vii. 60. Watson HK, Ballet FL. The SLAC wrist: scapholunate advanced collapse pattern of degenerative arthritis. J Hand Surg Am. 1984;9(3):358-365. 61. Wall LB, Didonna ML, Kiefhaber TR, Stern PJ. Proximal row carpectomy: minimum 20-year follow-up. J Hand Surg Am. 2013;38(8):1498-1504. 62. Goldfarb CA, Stern PJ, Kiefhaber TR. Palmar midcarpal instability: the results of treatment with 4-corner arthrodesis. J Hand Surg Am. 2004;29(2):258-263. 63. Chung KC, Pushman AG. Current concepts in the man-agement of the rheumatoid hand. J Hand Surg Am. 2011;36(4):736-747; quiz 747. Surgical treatment for rheu-matoid arthritis of the hand has decreased due to the advances in medical management. This article serves as thorough review for hand surgeons on the treatment of rheumatoid hand. 64. Swanson AB. Silicone rubber implants for replacement of arthritis or destroyed joints in the hand. Surg Clin North Am. 1968;48(5):1113-1127. 65. Fujita S, Masada K, Takeuchi E, Yasuda M, Komatsubara Y, Hashimoto H. Modified Sauve-Kapandji procedure for disorders of the distal radioulnar joint in patients with rheu-matoid arthritis. Surgical technique. J Bone Joint Surg Am. 2006;88(Suppl 1 Pt 1):24-28. 66. Elliot D, Ragoowansi R. Dupuytren’s disease secondary to acute injury, infection or operation distal to the elbow in the ipsilateral upper limb—a historical review. J Hand Surg Br. 2005;30(2):148-156. 67. Eaton C. Dupuytren disease. In: Wolfe SW, Hotchkiss RN, Kozin SH, Cohen MS, eds. Green’s Operative Hand Surgery. 7th ed. Amsterdam: Elsevier; 2016. 68. Murphy A, Lalonde DH, Eaton C, et al. Minimally inva-sive options in Dupuytren’s contracture: aponeurotomy, enzymes, stretching, and fat grafting. Plast Reconstr Surg. 2014;134(5):822e-829e. 69. van Rijssen AL, ter Linden H, Werker PM. Five-year results of a randomized clinical trial on treatment in Dupuytren’s disease: percutaneous needle fasciotomy versus limited fas-ciectomy. Plast Reconstr Surg. 2012;129:469-477. Although percutaneous needle fasciotomy is less invasive than limited fasciectomy, this study showed that fasciectomy provided more durable and lasting results. 70. Hurst LC, Badalamente MA, Hentz VR, et al. Injectable colla-genase clostridium histolyticum for Dupuytren’s contracture. N Engl J Med. 2009;361:968-979. 71. Saar JD, Grothaus PC. Dupuytren’s disease: an overview. Plast Reconstr Surg. 2000;106:125-134. 72. Crean SM, Gerber RA, Le Graverand MP, Boyd DM, Cappelleri JC. The efficacy and safety of fasciectomy and fas-ciotomy for Dupuytren’s contracture in European patients: a structured review of published studies. J Hand Surg Eur Vol. 2011;36:396-407. 73. McDonald LS, Bavaro MF, Hofmeister EP, Kroonen LT. Hand infections. J Hand Surg Am. 2011;36(8):1403-1412.Brunicardi_Ch44_p1925-p1966.indd 196420/02/19 2:50 PM 1965SURGERY OF THE HAND AND WRISTCHAPTER 44 74. Honda H, McDonald JR. Current recommendations in the management of osteomyelitis of the hand and wrist. J Hand Surg Am. 2009;34(6):1135-1136. 75. Murray PM. Septic arthritis of the hand and wrist. Hand Clin. 1998;14(4):579-587, viii. 76. Boles SD, Schmidt CC. Pyogenic flexor tenosynovitis. Hand Clin. 1998;14(4):567-578. 77. Kanavel AB. The treatment of acute suppurative tenosynovi-tis—discussion of technique. In: Infections of the Hand; A Guide to the Surgical Treatment of Acute and Chronic Sup-purative Processes in the Fingers, Hand, and Forearm. 5th ed. Philadelphia: Lea and Febiger; 1925:985. 78. Giladi AM, Malay S, Chung KC. A systematic review of the management of acute pyogenic flexor tenosynovitis. J Hand Surg Eur Vol. 2015;40(7):720-728. 79. Michon J. Phlegmon of the tendon sheaths (in French). Ann Chir. 1974;28(4):277-280. 80. Athanasian E. Bone and soft tissue tumors. In: Wolfe SW, Hotchkiss RN, Kozin SH, Cohen MS, eds. Green’s Operative Hand Surgery. 7th ed. Amsterdam: Elsevier; 2016. 81. Head L, Gencarelli JR, Allen M. Wrist ganglion treatment: systematic review and meta-analysis. J Hand Surg Am. 2015;40(3):546-553.e8. 82. Lanzinger WD, Bindra R. Giant cell tumor of the tendon sheath. J Hand Surg Am. 2013;38(1):154-157; quiz 157. 83. Phalen GS. Neurilemomas of the forearm and hand. Clin Orthop. 1976;114:219-222. 84. Lekanne Deprez RH, Bianchi AB, Groen NA, et al. Fre-quent NF2 gene transcript mutations in sporadic menin-giomas and vestibular schwannomas. Am J Hum Genet. 1994;54:1022-1029. 85. TerKonda SP, Perdikis G. Non-melanotic skin tumors of the upper extremity. Hand Clin. 2004;20:293-301. 86. Webber T, Wolf JM. Squamous cell carcinoma of the hand in solid organ transplant patients. J Hand Surg Am. 2014;39(3):567-570. 87. English C, Hammert WC. Cutaneous malignancies of the upper extremity. J Hand Surg Am. 2012;37(2):367-377. 88. Coit DG, Thompson JA, Andtbacka R, et al. Melanoma, version 2.2016. J Natl Compr Canc Netw. 2016;14(4): 450-473. 89. Dummer RA, Hauschild A, Lindenblatt N, et al. Cutane-ous malignant melanoma: ESMO clinical recommenda-tions for diagnosis, treatment and follow-up. Ann Oncol. 2009;20(Suppl 4):129-131. 90. Cochran AM. Subungual melanoma: a review of current treat-ment. Plast Reconstr Surg. 2014;134(2):259-273. 91. Mahajan A. The contemporary role of the use of radiation therapy in the management of sarcoma. Surg Oncol Clin N Am. 2000;9(3):503-524, ix. 92. Mankin HJ, Mankin CJ, Simon MA. The hazards of the biopsy, revisited. Members of the Musculoskeletal Tumor Society. J Bone Joint Surg Am. 1996;78(5):656-663. 93. Murray PM. Soft tissue sarcoma of the upper extremity. Hand Clin. 2004;20(3):325-333, vii. The subject of soft tissue sarcomas is very broad and specific. This article by Murray provides a concise and accurate summary of soft tissue sarco-mas of the upper extremity. 94. Unni KK, Dahlin DC. Dahlin’s Bone Tumors: General Aspects and Data on 11,087 Cases. 5th ed. Philadelphia: Lippincott-Raven; 1996. 95. Henderson M, Neumeister MW, Bueno RA, Jr. Hand tumors: II. Benign and malignant bone tumors of the hand. Plast Reconstr Surg. 2014;133(6):814e-821e. 96. Marcuzzi A, Acciaro AL, Landi A. Osteoid osteoma of the hand and wrist. J Hand Surg Br. 2002;27(5):440-443. 97. Maloney WJ, Vaughan LM, Jones HH, Ross J, Nagel DA. Benign metastasizing giant-cell tumor of bone. Report of three cases and review of the literature. Clin Orthop Relat Res. 1989(243):208-215. 98. Oliveira VC, van der Heijden L, van der Geest IC, et al. Giant cell tumours of the small bones of the hands and feet: long-term results of 30 patients and a systematic literature review. Bone Joint J. 2013;95-b(6):838-845. 99. Ogose A, Unni KK, Swee RG, et al. Chondrosarcoma of small bones of the hands and feet. Cancer. 1997;80:50-59. 100. Okada K, Wold LE, Beabout JW, et al. Osteosarcoma of the hand: a clinicopathologic study of 12 cases. Cancer. 1993;72:719-725. 101. Amadio PC, Lombardi RM. Metastatic tumors of the hand. J Hand Surg Am. 1987;12:311-316. 102. Sheridan RL. Acute hand burns in children: management and long-term outcome based on a 10-year experience with 698 injured hands. Ann Surg. 1999;229:558-564. 103. Pan BS, Vu AT, Yakuboff KP. Management of the acutely burned hand. J Hand Surg Am. 2015;40(7):1477-1484; quiz 1485. 104. Herndon D. Total Burn Care. 2nd ed. London: WB Saunders; 2002. 105. Haslik W, Kamolz LP, Nathschläger G, et al. First experi-ences with the collagen-elastin matrix Matriderm as a der-mal substitute in severe burn injuries of the hand. Burns. 2007;33:364-368. 106. Robinson EP, Chhabra AB. Hand chemical burns. J Hand Surg Am. 2015;40(3):605-612; quiz 613. 107. Conn J Jr, Bergan JJ, Bell JL. Hypothenar hammer syndrome: posttraumatic digital ischemia. Surgery. 1970;68(6):1122-1128. 108. Lifchez SD, Higgins JP. Long-term results of surgical treat-ment for hypothenar hammer syndrome. Plast Reconstr Surg. 2009;124(1):210-216. 109. Michelotti BM, Rizzo M, Moran SL. Connective tissue disor-ders associated with vasculitis and vaso-occlusive disease of the hand. Hand Clin. 2015;31(1):63-73. 110. Hotchkiss R, Marks T. Management of acute and chronic vas-cular conditions of the hand. Curr Rev Musculoskelet Med. 2014;7(1):47-52. 111. Ruch DS, Holden M, Smith BP, et al. Periarterial sympathec-tomy in scleroderma patients: intermediate-term follow-up. J Hand Surg Am. 2002;27:258-264. 112. Uppal L, Dhaliwal K, Butler PE. A prospective study of the use of botulinum toxin injections in the treatment of Raynaud’s syndrome associated with scleroderma. J Hand Surg Eur Vol. 2014;39(8):876-880. 113. Ekblom AG, Laurell T, Arner M. Epidemiology of congenital upper limb anomalies in 562 children born in 1997 to 2007: a total population study from Stockholm, Sweden. J Hand Surg Am. 2010;35(11):1742-1754. 114. Swanson AB. A classification for congenital limb malfor-mations. J Hand Surg Am. 1976;1:8-22. Swanson developed the seven key categories for the organization of congenital limb malformations later adopted by the American Society for Surgery of the Hand. 115. Bates SJ, Hansen SL, Jones NF. Reconstruction of congeni-tal differences of the hand. Plast Reconstr Surg. 2009;124 (1 Suppl):128e-143e. 116. Wassel HD. The results of surgery for polydactyly of the thumb. A review. Clin Orthop Relat Res. 1969;64: 175-193. 117. Lee WP, Mathes DW. Hand transplantation: pertinent data and future outlook. J Hand Surg Am. 1999;24:906-913. 118. Malt RA, McKhann CF. Replantation of severed arms. JAMA. 1964;189:716.Brunicardi_Ch44_p1925-p1966.indd 196520/02/19 2:50 PM 1966SPECIFIC CONSIDERATIONSPART II 119. Starzl TE, Fung J, Jordan M, et al. Kidney transplantation under FK 506. JAMA. 1990;264:63-67. 120. Gorantla VS, Brandacher G, Schneeberger S, et al. Favoring the risk-benefit balance for upper extremity transplantation: the Pittsburgh Protocol. Hand Clin. 2011;27:511-520. 121. Schneeberger S, Gorantla VS, Brandacher G, et al. Upperex-tremity transplantation using a cell-based protocol to mini-mize immunosuppression. Ann Surg. 2013;257:345-351. 122. Brandacher G, Lee WP, Schneeberger S. Minimizing immu-nosuppression in hand transplantation. Expert Rev Clin Immu-nol. 2012;8(7):673-683; quiz 684. 123. Shores JT. Recipient screening and selection: who is the right candidate for hand transplantation. Hand Clin. 2011;27:539-543.Brunicardi_Ch44_p1925-p1966.indd 196620/02/19 2:50 PM
Plastic and Reconstructive SurgeryRajiv Y. Chandawarkar, Michael J. Miller, Brian C. Kellogg, Steven A. Schulz, Ian L. Valerio, and Richard E. Kirschner 45chapterINTRODUCTIONPlastic and reconstructive surgery is a unique subspecialty of surgery that consists of a set of techniques intended to mod-ify the amount, position, quality, or organization of tissues in order to restore function and appearance. The name of the field is derived from the Greek word plastikos, which means “to mold.” An object is considered plastic if its shape can be modi-fied without destruction. In this sense, all human tissues have some degree of plasticity. They can be nondestructively modi-fied if the surgeon adheres to certain principles. Understanding and applying these principles to solve clinical problems is the essence of plastic and reconstructive surgery. Although informal references to this type of surgery can be found in the modern literature as early as the 17th century, American surgeon John Staige Davis published the first textbook dedicated to the field in 1919, entitled Plastic Surgery—Its Principles and Practice. He coined the term that we have used to refer to the specialty ever since. Science has always evolved in a nonlinear fashion: seminal discoveries in different parts of the world have all col-lectively fueled progress and addressed an unmet need. The evolution of plastic and reconstructive surgery has followed the same path: the Edwin Smith Papyrus1 (Egypt, 1600 b.c.) (Fig. 45-1) described facial reconstruction; the Shushruta Samhita (India, 1500 b.c.) (Fig. 45-2) described nasal reconstruction; and Aulus Cornelius Celsus (Rome, 1 a.d.) described opera-tions for facial reconstruction. The underlying impetus for this evolution is the common unmet need for restoring defects, be they congenital, traumatic, or functional.This strong thread of advances in reconstructive surgery continues even today. What does seem under-recognized is that the clinical practice of plastic and reconstructive surgery touches on every other area of surgery. Enhanced reconstructive capabilities strengthen all other specialties significantly, such as the ability to safely perform radical cancer operations, sal-vage traumatic limbs, or extend the reach of neonatal medicine by congenital reconstruction. Each surgical specialty encoun-ters problems that might be addressed by some form of tissue repair, modification, rearrangement, transfer, or replacement. Since its inception, plastic surgeons have routinely responded to the medical needs of the society and helped restore form and function. One of the most powerful examples of this response is the advances that occurred as a result of World Wars I and II. Walter Yeo, a sailor injured at the Battle of Jutland, is assumed to have received plastic surgery in 1917. The photograph shows him before (Fig. 45-3, left) and after (right) receiving a flap surgery performed by Gillies.The Gulf war and the conflicts in the Middle East have prompted several revolutionary reconstructive surgical advances in limb salvage, microsurgery, supermicrosurgery, hand, face, and abdominal wall transplantation. Plastic surgeons have also targeted muscle reinnervation, tissue engineering, and regenera-tive medicine.When society calls, plastic surgeons rise to the challenge and create novel methods to address its needs. For example, neurosurgeons at times must replace or stabilize bone in the cranium or spine, and healthy soft tissue coverage is essen-tial for optimal healing. Head and neck surgeons face tissue replacement problems in order to restore normal function and appearance after major tumor ablation. Thoracic surgeons must manage bronchopleural fistulae, esophageal defects, or loss of chest wall integrity after trauma or tumor resection. Cardiolo-gists and cardiac surgeons at times face complicated wound Introduction 1967Purpose 1969General Principles 1969Skin Incisions / 1969Incision Repair / 1970Wound Healing / 1971Phases of Wound Healing / 1971Reconstructive Surgery 1974Reconstructive Strategies  and Methods 1974Skin Grafts and Skin Substitutes / 1975Pediatric Plastic Surgery 1981Congenital Craniofacial Anomalies / 1981Reconstructive Surgery  in Adults 2001Maxillofacial injuries and Fractures / 2002Mandible Fractures / 2002Frontal Sinus Fractures / 2003Orbital Fractures / 2004Zygomaticomaxillary Complex Fractures / 2004Nasoorbitalethmoid and Panfacial Fractures / 2005Posttraumatic Extremity Reconstruction / 2005Oncologic Reconstructive Surgery / 2008Breast Reconstruction / 2009Oncoplastic Breast Reconstruction / 2009Implant-based Reconstruction / 2009Tissue Flaps and Breast Implants / 2010Autologous Tissue Reconstruction / 2010Accessory Procedures / 2011Trunk and Abdominal Reconstruction / 2011Pelvic Reconstruction / 2012Other Clinical Circumstances / 2012Aesthetic Surgery and Medicine 2016Aesthetic Surgery of the Face / 2017Aesthetic Surgery of the Breast / 2018Aesthetic Surgery of the Body / 2018Suction Lipectomy / 2022Autologous Fat Grafting / 2024Brunicardi_Ch45_p1967-p2026.indd 196701/03/19 6:26 PM 1968Figure 45-1. The Edwin Smith papyrus (Egypt, 1600 b.c.).Figure 45-2. Statue of Shushruta, considered the “founding father of surgery” in India.Key Points1 It is critical to understand the physiologic basis and ratio-nale of wound healing in order to further assimilate surgi-cal and nonsurgical care of wounds and methods of wound care.2 Understanding the reconstructive choices in tissue repair cases is critical for any surgeon. The principles of soft tis-sue and skin repair are important for the reconstruction of defects, whether in a trauma situation of after excision of lesions.3 Children with cleft and craniofacial differences have com-plex medical, surgical, and social needs. Coordinated, interdisciplinary team care is crucial to success.4 Robin sequence, characterized by micrognathia, glossop-tosis, and airway obstruction, can be managed with prone positioning, tongue-lip adhesion, mandibular distraction osteogenesis, or tracheostomy.5 The first-line treatment for high-risk hemangiomas is oral propranolol, which can induce rapid involution and has a more favorable side effect profile than systemic steroids.6 The coordination of care for patients in a trauma depart-ment is an important part of a surgeon’s role, whether that role be as a trauma emergency department surgeon or a surgeon in practice.7 The careful evaluation of a patient in a polytrauma involves a thorough assessment of internal and soft tissue injuries, planning of care, and the appropriate triage of reconstructive procedures. As a leader in a trauma bay of the trauma service, the surgeon typically assumes a cap-tain’s role in decision-making.8 Principles of oncologic reconstruction have evolved sig-nificantly, and a deeper understanding of these reconstruc-tive choices is essential for a surgeon who is often the first point of contact for cancer patients and responsible for making critical referrals.9 The combined work of general surgeons and reconstruc-tive plastic surgeons has revolutionized the care of abdom-inal wall defects, including ventral hernias, repair after tumor ablation, and bariatric surgery.10 Any critical care unit or a medical surgical team that takes care of debilitated patients needs a detailed understanding of pressure sores, including their etiology and the recon-structive options that are available to these patients.infections, sternal osteomyelitis, or failure of soft tissue cov-erage that leads to exposure and contamination of implanted devices such as left ventricular assist devices or cardiac pace-makers. Orthopedic surgeons managing segmental bone defects in the extremities at times require replacement by surgical transfer of vascularized bone segments rather than conventional bone grafts or alloplastic substitutes. Urologists, colorectal sur-geons, and gynecologists who commonly perform surgery in the perineum encounter nonhealing wounds or fistulae. All of these problems may be managed or potentially prevented by judicious application of tissue methods developed and practiced by plastic and reconstructive surgeons.Plastic and reconstructive surgery is field characterized by innovation, and it has yielded important contributions to other surgical specialties. These include notable advances in hand and upper extremity surgery, craniofacial surgery, peripheral nerve surgery, and reconstructive microsurgery. Entirely new fields of have emerged from plastic surgery research. Joseph E. Murray, a Boston plastic surgeon, and his team performed the first renal transplantation procedures and laid the foundation for modern organ transplantation, an achievement for which he was awarded the Nobel Prize in Medicine in 1990 (Fig. 45-4). This spirit of innovation continues with ongoing active research by plastic surgeons in composite tissue allotransplantation, tis-sue engineering, biomaterials, cell transplantation, regenerative medicine, computer-assisted surgical planning, medical appli-cation of three-dimensional manufacturing methods, infection control, and outcomes research. Plastic and reconstructive sur-gery is a vibrant field that brings tremendous value to people’s health and quality of life through life-changing reconstructive, restorative, and transformative surgeries.Brunicardi_Ch45_p1967-p2026.indd 196801/03/19 6:26 PM 1969PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-3. Walter Yeo, a sailor injured at the Battle of Jutland in 1917.Figure 45-4. Joseph E. Murray, MD, awarded the Nobel Prize in Medicine in 1990.PURPOSEThe purpose of this chapter is to inform about the general prin-ciples of plastic and reconstructive surgery, which apply to all areas of surgery, and to provide current examples of practice. Studying this chapter will help the reader to understand (a) the principles of plastic surgery that translate into other surgi-cal specialties; (b) the kind of clinical problems that may be addressed using plastic surgery techniques; and (c) the types of research found in plastic and reconstructive surgery. It will make clearer the nature of the field and its role in the multidis-ciplinary care environment of modern healthcare.GENERAL PRINCIPLESGeneral principles of plastic surgery relate to technical aspects of incision planning and wound repair. These principles apply to all surgical disciplines. As such, every surgeon can benefit from learning and applying them. Previously, tremendous emphasis was placed on simply understanding the nature of skin, which is completely justified; however, over the past few years plastic surgical focus has expanded to include the entire integument. Muscles, fascia, fat, skeletal framework, nerves, vascular net-works, and their dynamic interactions have become far more important factors that are choreographed in most reconstructive processes.Skin IncisionsFrom a surgical viewpoint, the skin is a multilayered tissue formed by dermis and epidermis. It is the largest organ in the human body and exists in a state of dynamic equilibrium from the balance of tension created by external and internal factors. Externally, skin and underlying subcutaneous tissue are acted on by gravity and clothing. Internal factors include skin elasticity, which is simply the ability to stretch and return to prestretch architecture upon removal of the stretch. The dermis is com-posed of different types of collagen and elastic protein fibers (elastin), and epidermis, composed primarily of cells anchored together in various stages of maturation. The skin serves impor-tant functions of thermoregulation, affording tactile sensation, and protection from foreign materials and microorganisms. Areas of skin exposed to view in normal clothing play a sig-nificant role in personal appearance and social interaction. As a result, even favorable scars from surgical incisions can have an undesirable effect on personal appearance. Thoughtful place-ment and performance of a surgical incision will minimize the risk of adverse consequences that can result in shortand long-term morbidity.Human skin exists in a resting state of tension caused by gravity and its conformation over underlying structures between sites that are tethered by subcutaneous fibrous tissue, which secure the deep surface of the dermis to underlying points of fixation. When the skin is incised linearly, the wound edges separate in a predicable fashion forming an ellipse with the long axis perpendicular to the lines of greatest tension. These tension lines are often called “Langer’s lines,” after Carl Langer, a 19th century anatomist from Vienna who first described them based on studies in fresh cadavers (Fig. 45-5). Later, Borges described relaxed skin tension lines, which follow furrows formed when the skin is relaxed and are produced by pinching the skin. Inci-sions placed parallel to these lines often heal with less conspicu-ous scar because the skin often has natural wrinkles following these lines and there is less tension perpendicular to the orien-tation of the wound1 (Fig. 45-6). Based on these principles,2 a recommended pattern for incisions can be made (Fig. 45-7).Using the proper technique for creating and repairing skin incisions ensures uncomplicated wound healing with few distorting surface scars. The epidermis and superficial dermis should be incised sharply with a scalpel. The incision is then continued through the deep dermis and subdermal plexus of blood vessels with electrocautery. This technique helps to mini-mize collateral tissue injury along the wound margins to facili-tate prompt and reliable healing. It is essential to maintain the orientation of the scalpel or electrocautery blade perpendicular to the surface of the skin in order to facilitate accurate reap-proximation during wound closure. As the incision is deepened through the subcutaneous tissue to expose underlying structures, it is important to avoid creating multiple pathways through the tissue, which can create focal areas of devitalized tissue that form a nidus of infection or lead to delayed wound healing. The Brunicardi_Ch45_p1967-p2026.indd 196901/03/19 6:26 PM 1970SPECIFIC CONSIDERATIONSPART IIFigure 45-5. “Langer’s lines,” named after Carl Langer, a 19th century anatomist from Vienna.Figure 45-6. Lines of relaxed skin tension.Figure 45-7. Planning of incisions based on lines of skin tension.surgeon should extend the incision through the subcutaneous fat by tracing the same line each time with the scalpel or electrocau-tery in order to reach the deeper structures.Traumatic wounds do not permit the same careful plan-ning that is possible with incisions made in undamaged skin. Nevertheless, optimum repair of traumatic lacerations involves similar principles applicable in nontraumatic circumstances. The surgeon must remove as much traumatized tissue as pos-sible from the wound edges, converting the uncontrolled trau-matic wound into a controlled surgical wound. All devitalized tissue is excised. The same principles of making incisions perpendicular to the skin surface and avoiding creating mul-tiple pathways through the subcutaneous tissues apply. In this process, an attempt can be made to reorient the wound into a more favorable direction. A variety of methods are available to perform this reorientation, and they often involve creating small local flaps of undamaged tissue using geometric tissue rearrangements. These techniques will be considered later in this chapter. Following these principles increases the likelihood of uncomplicated wound healing and reduces the need for later treatment of unfavorable scars. However, there are situations in which the direction of the incision has been preestablished, as in acute lacerations, burns, or old contracted and distorting scars. In these circumstances, the principles of proper incision placement can be combined with simple surgical techniques to reorient the scar and lessen the deformity.When making an incision in an area of previous scar-ring, such as in a scar revision or a reoperation, it is preferable to completely excise the scar when making the skin incision and not simply make the incision through the old scar. Closing scarred wound edges increases the likelihood of delayed wound healing, infections, and unfavorable new scars. It only takes a few moments to make the skin incision outside of the area of scarring through unscarred skin. Once the skin incisions on each side of the previous scar reach into the subcutaneous tissue, then the surface scar can be removed completely at the subder-mal level. This approach ensures that the final repair relies on undamaged tissues, thus facilitating uncomplicated healing and lowering the risk of an unfavorable scar.Incision RepairA well-performed skin incision sets the stage for an accurate repair that minimizes the risk of unfavorable scarring. An unfa-vorable scar is characterized by excessive amount of collagen Brunicardi_Ch45_p1967-p2026.indd 197001/03/19 6:26 PM 1971PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45deposition,4 leading to hypertrophic scarring or keloid formation (Fig. 45-8). The difference between them is that a hypertrophic scar stops growing 6 months after the injury, whereas a keloid continues to grow, even growing well beyond its borders. Accu-rate approximation and stabilization of the skin edges helps to minimize the amount of collagen deposition required for skin healing. The most important layer to approximate is the dermis because this layer contains the healing elements such as blood supply and cellular elements that create the extracellular matrix necessary for healing. Optimal wound closure involves placing deep dermal sutures followed by superficial sutures that incorpo-rated the upper layers of the dermis and epidermis. Absorbable deep dermal sutures have the advantage of disappearing over time; however, they can promote prolonged inflammation dur-ing this process. Nonabsorbable sutures minimize inflammation and might be indicated in individuals who are particularly prone to scar formation. A step-off between each side of the wound should be avoided because an uneven surface on each side of the wound can cause a shadow that accentuates the presence of the scar. Stability between the two wound edges is important because motion between the two sides of the wound prolongs the inflammatory phase of healing and requires additional col-lagen to be deposited. The timing of suture removal depends on the type of suture placed in the superficial closure. Sutures placed at the surface that go deep into the dermis can leave addi-tional scarring at the entry and exit points of the suture mate-rial in addition to the incisional scar. Sutures like this should be removed within the first week. If the superficial sutures are placed more shallowly in the dermis, there is a reduced tendency to form additional scarring. A subcuticular suture may be used instead of simple sutures. This type of technique avoids the risk of additional scarring along the wound edge; however, it can be more difficult to accurately reapproximate the skin edges with-out a step-off between the two sides.Wound HealingIn the United States, nonhealing wounds affect about 3 to 6 mil-lion people, with persons 65 years and older accounting for 85% of these events. The annual cost of this problem is estimated to be as high as $25 billion for hospital admissions, antibiotics, and local wound care.3Normal wound healing is achieved through four highly choreographed, overlapping biophysiologic phases: hemostasis, inflammation, proliferation, and tissue remodeling or resolu-tion. Each phase initiates a cascading set of processes critical to the desired result of a healed wound.1Figure 45-8. Hypertrophic scar (left) and keloid (right).Figure 45-9. Phases of wound healing.Hypertrophic ScarKeloidBlood clotBlood vesselScabFibroblastFibroblastsproliferatingFreshlyhealedepidermisFreshlyhealeddermisMacrophageSubcutaneousfatBleedingInflammatoryProliferativeRemodelingSeveral factors impede wound healing and need to be understood so that they can be mitigated. Successful mitiga-tion of these adverse factors requires precise, least-traumatic surgical technique that incorporates new methods of prevention and treatment of infection and an understanding of the role of microbial behavior, including the formation of biofilm. Because chronic diseases such as diabetes, vascular insufficiency, and obesity are on the rise, there must be a better understanding of chronic versus acute wounds and how comorbid conditions affect wound healing. Lastly, the impact of age, gender, and nutrition becomes more important as the population of aging patients increases.Phases of Wound HealingThere are different processes that characterize healing in sev-eral types of tissue, such as skin, muscle, or bone, and there is a strong underlying mechanism that is best understood in terms of a simple skin injury. The process of wound healing is com-prised of four integrated processes that overlap: (a) bleeding and hemostasis, (b) inflammation, (c) proliferation, and (d) tissue modeling or resolution (Fig. 45-9).These processes occur in sequence over a 1-year duration, but they also significantly overlap and work in terms of a “con-tinuum of processes” rather than discrete “stop-and-go” phases. As shown in Fig. 45-9, each phase is characterized by several Brunicardi_Ch45_p1967-p2026.indd 197101/03/19 6:26 PM 1972SPECIFIC CONSIDERATIONSPART IIwell-defined processes that are dominated by cellular as well as noncellular elements, such as platelets, macrophages, and cyto-kines, that act in concert.Hemostasis. This phase of healing occurs immediately after tissue injury. The most important cells that play a role in the hemostatic process are platelets that degranulate and result in the formation of a clot. The extracellular matrix that supports the tissue framework and otherwise acts as a barrier is now open to the vascular compartment, resulting in the release of several factors into the wound. In addition, the release of proteins— otherwise stored within the extracellular matrix—and the presi-dent cells act as further stimulants that start the hemostatic pro-cess. Inflammatory plasma proteins and leukocytes also migrate into the wound. On the cellular level, the plasma membrane of each platelet contains several receptors for collagen (glycopro-tein 1A and 2A). Once these receptors are activated, glycolated granules holding multiple factors that activate hemostasis and inflammation are disrupted, releasing bioactive factors that stimulate platelet aggregation, vasoconstriction, and the subse-quent activation of the clotting cascade. As these initial platelet activation factors are released, there is a subsequent push that influences angiogenesis inflammation. These systemic immune response platelet-derived factors include biologically active proteins, such as PDGF, TGF-β, and VEGF, as well as other cytokines, such as PF4 and CD40L.In addition to the release of these factors, the binding of selected proteins within the already developed fibroblasts and the combination of two elements within the extracellular matrix create a chemotactic gradient that activates cell recruitment, cell migration, and cell differentiation and promotes tissue repair. This has been demonstrated clinically in several instances, including orthopedic surgery, cardiac surgery, and certain types of skin repair, where autologous platelet transfusions have shown to accelerate the healing process.The subsequent fate of the platelet plug is determined by the amount of circulating fibrinogen. The vascular system interacts with the sympathetic nervous system by eliciting vasoconstriction from the actions of cytokines, prostaglandins, and catecholamines. There is also an alteration of capillary permeability caused by histaminic responses and the mediation of VEGF, which is released from micelles and the damaged endothelium. This highly interactive process results in decreasing blood loss while simultaneously delivering bioactive proteins and cells into the wound environment that kick start the inflammatory process.Inflammation. This is the second phase of wound healing and arguably overlaps the hemostatic face. Polymorphonuclear leu-kocytes (PMNs) and macrophages appear in the wound right after platelets, and their primary role is mainly to act as scav-engers. They clear the wound environment of debris, foreign material, bacteria, dead tissue cells and any other devitalized issues that would otherwise impede the healing process. Both macrophages and PMNs aid in phagocytosis and the secretion of free articles that kill bacteria and reduce the bioburden. Cel-lular migration into the wound is highly controlled by bioactive agents within the wound and within the vascular compart-ment. These include cytokines, integrins, selection, and other collagen-derived substances that act in concert. Through anti-body activation, polymorphonuclear cells also interact with the humoral system to facilitate the key functions of cell activation, recruitment, and proliferation, as well as migration from the intravascular compartment to the extracellular matrix. Within 48 hours of tissue injury, PMNs and macrophages are recruited to the wound in very large numbers, heralding the inflamma-tory response. As described in other chapters in this text, macro-phages possess a very large repertoire of functions, all of which are geared towards removing the nonviable elements in the wound and recruiting other cell types into the wound that facili-tate angiogenesis, fibroblast function, and subsequent repair. A summary of various macrophage-related functions is broadly classified into 7 major categories:1. Phagocytosis2. Release of reactive oxygen species that result in cellular kill-ing specifically related towards bacterial lysis3. Release of nitric oxide that is deadly to several otherwise antibody-resistant bacteria4. Cytokine release of interleukins (IL1, IL2, IL4, and IL12)5. Angiogenesis via VEGF that promotes capillary budding6. Recruitment of other cells into the wound that continue the healing process7. Different homeostatic roles of macrophages and Langerhans cells, including wound repair, follicle regeneration, salt bal-ance, and cancer regression and progression in the skinInterestingly, the inflammatory phase determines the dif-ference between chronic and acute wounds. Uncomplicated wounds heal within 4 to 6 weeks. If they continue to remain nonhealing beyond this time, they are termed chronic. Several local and systemic factors affect the inflammatory phase of wound healing directly. These include pressure, tissue hypoxia, infection, tissue contamination, desiccation, and maceration. Systemic factors include age, stress, and comorbid conditions such as diabetes, vascular insufficiency, immunocompromise, malnourishment, obesity, and smoking. The common thread, however, in all nonhealing chronic wounds is the persistence of proinflammatory conditions. These specific tissue deficits result in a chronic cycle of chronically migrating inflammatory cells (PMNs, macrophages) that scavenge early healing tissue, degrade the newly formed matrix proteins, and then cyclically recover only to restart the inflammatory phase. This cycle leads to a chronically unstable wound that is unable to progress to the next phases of healing: cell proliferation, tissue remodeling, and resolution.Biofilm One of the recent discoveries in the area of biofilm is an important microbial factor that impedes healing by affecting inflammatory processes in the wound-healing continuum. Biofilm comprises a colony of microorganisms enveloped with a matrix of extracellular polymers also known as extracellular polymeric substance (EPS) (Fig. 45-10). EPS affects chronic and acute dermal wounds. Its life cycle and effects on the bacterial colonies it protects are shown in Figs. 45-11 and 45-12. These include antibiotic resistance; latency (the ability to enter into latent states during inhospitable conditions); increasing species diversity; and quorum sensing (bacteria in the biofilm engage in a type of decision-making process in which behavior is coordinated through a “chemical” vocabulary).Proliferation. This phase is arguably the first step towards restoration of tissue continuity. It is characterized by the pro-duction of extracellular matrix by the fibroblast, the most prominent cell type in the proliferative phase. Fibroblasts are Brunicardi_Ch45_p1967-p2026.indd 197201/03/19 6:26 PM 1973PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-10. Slough that also comprises biofilm.Figure 45-11. The lifecycle of biofilm.Figure 45-12. Biofilm is a barrier to wound healing.V. choleraebiofilmPhytoplanktonMetabolicallyactive cellMetabolicallyquiescent cellPlanktonic V. choleraeMSHA pilusAquatic environmentFlagellumDetritusZooplanktonSmall intestineTCPSheddingIngestionReleaseTCPbundlingMucusHuman hostStoolthe architects of wound healing and appear in the wound right at the end of the inflammatory phase. Collectively, fibroblasts support several major functions that lead to tissue repair, includ-ing the formation of collagen and the structural creation of the extracellular matrix. The formation of fibrin and fibronectin that is precipitated from the blood clot results in the formation of a provisional extracellular matrix that serves as a scaffold. Typically, this matrix can be compared to the framework of a building without any walls or windows. The protein scaf-fold serves as a solid framework that subsequently hosts cells including human macrophages and fibroblasts. Simultane-ous VEGF-derived angiogenesis promotes the formation of small vascular loops, known as capillary buds, that proliferate within the fibroblast matrix. Paradoxically, the major activat-ing factor responsible for the formation of capillary buds is low oxygen tension. Poor oxygenation of the tissues increases Brunicardi_Ch45_p1967-p2026.indd 197301/03/19 6:26 PM 1974SPECIFIC CONSIDERATIONSPART IIthe expression of hypoxia inducible factor (HIF) by endothe-lial cells. Specific DNA sequences of cells that regulate angio-genesis are turned on by HIF. This paradoxical negative loop is directly related to a low oxygen tension within the tissues. Subsequent release of the epidermal growth factor EGF and the transforming growth factor TGF-α by several cell types, including macrophages, platelets, and keratinocytes, strengthen the newly formed extracellular matrix. Once a robust scaffold is built, the epidermal cells from the edges of the wound on all sides migrate towards the center of the wound. This process is facilitated by several factors, including angiogenesis, neovas-cularization, and the release of fibroblast growth factor TGF-β and epidermal growth factor. The formation of the extracellular matrix is the key process that leads to subsequent reepithelial-ization. The extracellular matrix is primarily made of collagen. The different types of collagen that occur more predominantly in different types of tissues characterize the type of healing that occurs. Specifically, type I is present in scar tissues. After the formation of collagen, the fibers are now attached to form a provisional fibrin matrix. After a variety of complicated signal-ing that includes the transcription and processing of collagen messenger RNA, the collagen gets attached to hydroxylation of protein and lysine. The hydroxyproline in the collagen is responsible for the stable helical confirmation that is critical for the formation of a robust strong scar. It then transforms itself into a classical triple helical structure that is subsequently modified through glycosylation. It is important to realize that increased collagen stability is directly related to the degree of hydroxylation of the collagen and that fragile forms of colla-gen (which result in a fragile scar) are largely due to increases in nonhydroxylated collagen forms. Certain diseases including scurvy (vitamin C deficiency) or other diseases that are pre-dominantly anaerobic in their nature can cause the formation of week nonhydroxylated collagen, which is fragile and can easily undergo denaturation and lysis.The next step is the cleavage of the procollagen N and C terminal peptides. A very important extracellular enzyme called lysyl oxidase is responsible for the strengthening of collagen by the formation of strong, stable cross-linkages. Microscopic examination of stable mature scars reveals that strong cross-linkages present in the intramolecular and the intermolecular compartments directly correlate with strength and stability. Epi-dermal cells migrate over the scaffold, and after the epithelial bridge is completed, enzymes are released to dissolve the attach-ment at the base of the overlying scab that falls off.Contraction is one of the key end phases of proliferation. Typically, contraction starts approximately 7 days from tissue injury, when the fibroblasts differentiate into myofibroblasts. Myofibroblasts are similar to smooth muscle cells, have the same amount of actin (responsible for mobility), and are responsible for contraction it peaks at around 10 days post injury but can continue for several weeks. Myofibroblasts attach to the extra cellular matrix (ECM) at the wound edges and to each other as well as to the wound edges via desmosomes and the fibronexus, through which actin in the myofibroblast is linked across the cell membrane to molecules in the extracellular matrix like fibro-nectin and collagen. This in turn facilitates the myofibroblasts to pull the ECM when they contract, thus reducing the wound size. Wounds contract at the rate of 0.75 mm to 1 mm daily. The formation of a strong, contracted, cross-linked collagen scar with reepithelization heralds the end of the proliferative phase. Contraction usually does not occur symmetrically; instead, most wounds have an “axis of contraction” that allows for greater organization and alignment of cells with collagen.Remodeling/Maturation. The remodeling phase is also termed the maturation phase. It is primarily characterized by the remodeling of collagen through a balance between collagen for-mation and collagen lysis that results in the formation of a strong scar. Biochemically, the collagen is remodeled from type III to type I and is also accompanied by complete reepithelialization of the wound. The lysis of collagen is mediated by collagenases that are secreted by various cells—fibroblasts, neutrophils, and macrophages—each of which can cleave the collagen molecule at different but specific locations on all three chains and break it down to characteristic three-quarter and one-quarter pieces. These collagen fragments undergo further denaturation and digestion by other proteases. There is significant remodeling of the collagen during this process. It is aligned along tension lines, and significant reabsorption of water from the collagen fibers result in a denser alignment and stronger cross-linking. The remodeling phase establishes a new equilibrium with the forma-tion of an organized scar. Several molecules, including TGF-β, which induces intracellular signaling of SMAD proteins, play an important role in the remodeling phase. Using SM 80 knockout mice and transgenic animals, a critical role of the SMAD path-way in the formation of scar has been delineated. This process is also facilitated by apoptosis and programmatic cell death, which helps to former a thinner scar that is stronger and more cosmeti-cally appealing. This phase begins 3 weeks after the injury and continues for over 1 year. One must realize that despite the best cross-linking, scar tissue is weaker than injured skin and regains only 80% of its uninjured tensile strength. As it matures fur-ther, it becomes less red and less vascular because the reduced biologic activity within the scar renders the vascular capillaries redundant and they apoptose.RECONSTRUCTIVE SURGERYReconstructive surgery restores normal anatomy and function using plastic surgery methods of tissue repair, rearrangement, and replacement. Tissues can be missing or damaged as a con-sequence of trauma, cancer, degeneration, congenital abnor-malities, and aging. The primary adverse consequence of lost or impaired tissue is functional disability, which includes physical, psychologic, or social dysfunction. The clinical objective is to reestablish normal anatomy, function, and appearance in order to restore the patient as closely as possible to normal health. The most useful techniques transfer and modify tissues in the form of tissue grafts and surgical flaps.RECONSTRUCTIVE STRATEGIES AND METHODSThe main aim of wound healing is to achieve a closed wound. Ordinarily, wounds heal via three main mechanisms:1. Primary intention: This type of healing occurs in a clean wound without any apparent tissue loss. Mostly seen in surgical incisions that have been approximated (primary closure), healing by primary intention can only be imple-mented when the closure of the wound is precise and there is minimal disruption to the local tissue or the epithelial basement membrane. Typically, this wound seals off within 24 hours. Healing is faster than healing by secondary inten-tion, and there is the least amount of scarring.2Brunicardi_Ch45_p1967-p2026.indd 197401/03/19 6:26 PM 1975PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 452. Secondary intention: Tissue loss following major trauma results in the formation of granulation tissue, which results in a broader scar (see earlier section, “Phases of Wound Healing”).3. Tertiary intention (delayed primary closure or second-ary suture): The wound is initially cleaned, debrided, and observed, typically 4 or 5 days before closure. Examples of this type of healing include healing through the use of tissue grafts, including skin grafts and substitutes.Skin Grafts and Skin SubstitutesSkin grafting methods date back millennia to ancient India, where they were used to resurface nasal defects. They were introduced in the modern era by Guiseppe Baronio, an Italian physician who studied skin grafting techniques in sheep and published his work entitled Degli Innesti Animali (On Grafting in Animals) in 1804.4It is important to know the basic anatomic structure of skin in order to understand the principles of skin grafting. Skin is comprised of the epidermis, the dermis, specialized sensory nerve endings, and various skin appendages that lubricate and protect the skin as well as contribute to functions such as ther-moregulation. The epidermis is a layer of cells that affords pri-mary barrier function. It begins with a layer of cells called the basal layer. These are cuboidal-shaped cells that multiply and differentiate into flattened, keratinized squamous cells, which progressively migrate from the basal layers until they are finally released from the surface in a process known as desquamation. The junction between the dermis and the epidermis is composed of projections from the dermis into the epidermis, which are called dermal papillae. This feature secures the epidermis to the dermis by resisting sheer forces transmitted from the skin surface, helping to prevent separation of the epidermis from the dermis. The dermis contains sebaceous glands, whereas sweat glands and hair follicles are actually located below the dermis in the subcutaneous tissue and traverse the dermis and epithe-lium to reach the body surface. The dermal thickness and con-centration of skin appendages vary widely from one location to another on the body. The blood supply to the skin occurs in a variety of patterns that form the basis for transferring tissue-containing skin, which will be discussed later in this chapter. Regardless of the pattern, there is a network of vessels just below the dermis called the subdermal plexus that supplies the skin immediately above and is important in thermoregulation. Finally, terminal vessels and capillaries fill the dermis and pen-etrate the dermal papillae to perfuse the cellular elements of the dermis and epidermis.Skin grafting methods include split-thickness skin grafts (STSG), full-thickness skin grafts (FTSG), and composite tissue grafts. Each has its advantages and disadvantages, and select-ing the best technique for a given circumstance depends on the reconstructive requirements, the quality of the recipient wound bed, and the availability of donor site tissue.Split-Thickness Grafts. An STSG is the simplest method of tissue transfer. The name is derived from how these grafts are harvested by cutting through (i.e., splitting) the dermis at various levels. Thin STSGs are harvested through the superficial levels of the dermis. Thick grafts are harvested through deeper layers and include a larger amount of dermal tissue. The impor-tant characteristics of STSGs are determined by the thickness of dermis present in the graft. Thin grafts undergo less primary contraction after harvest because they contain fewer elements of the dermal extracellular matrix such as elastic fibers. Thick grafts undergo greater amounts of primary contraction. This is important to remember when harvesting the graft because it is necessary to obtain sufficient tissue in order to restore the defect. On the other hand, thin grafts allow the wound to undergo a greater amount of contraction in a process traditionally referred to secondary contraction of the graft. This becomes important if the wound is adjacent to a mobile structure such as the oral commissure, which might be distorted as healing progresses. Thin grafts also have improved chances of complete engraft-ment, or “taking,” as they contain mostly epidermis, which has low metabolic demands, in contrast to thicker grafts that contain more dermis with greater metabolic needs.A variety of techniques have been described to maximize the surface area that can be covered by harvested skin amount while minimizing the size of the donor site.5 One approach is to process the harvested skin into micrografts using devices spe-cially designed for this purpose in the operating room. Another method is fractional skin harvesting, which involves harvesting a large number of full-thickness skin tissue columns that are then seeded onto the wound surface. The traditional method, however, is to mesh the graft. Meshed grafts usually also have enhanced reliability of engraftment because the fenestrations allow for egress of wound fluid and excellent contour match-ing of the wound bed by the graft. The fenestrations in meshed grafts must epithelialize by secondary intention from the sur-rounding graft skin. The major drawbacks of meshed grafts are poor cosmetic appearance and high rates of secondary contrac-tion. Meshing ratios used usually range from 1:1.5 to 1:6, with higher ratios associated with magnified drawbacks related to meshing. For any case, a decision to mesh the graft must be balanced against the disadvantages. Other differences between thin and thick STSGs include final durability, pigmentation, and tendency to desiccation of the final result. The distinguishing characteristics of skin grafts types based on thickness are sum-marized in Fig. 45-13.STSG donor sites heal by regeneration from dermal and epidermal elements remaining in the harvest site. Recesses between dermal papillae projecting into the dermis are lined by basal cells. These cells migrate across the wound surface and Figure 45-13A. Skin grafts categorized based on thickness.ThinIntermediateSplit skinThickFull thicknessskinABrunicardi_Ch45_p1967-p2026.indd 197501/03/19 6:26 PM 1976SPECIFIC CONSIDERATIONSPART IIDermal content1° contraction2° contractionEngraftmentDurabilityPigmentationResist desiccationRecipient bedAppearanceSTSG(thin) ++++++++++++++++++++++++++++++++++++++++++++++++++++++STSG(thick)FTSGBFigure 45-13B. Characteristics of skin grafts.reepithelialize it. During this process, the donor site must be kept moist and free of bacterial contamination. Depending on the thickness of the graft, uncomplicated donor site epitheliali-zation typically is complete in 2 weeks. In most cases, it should be protected from mechanical shear and drying until the new skin matures with epidermal and dermal thickening and reac-tivation of sebaceous and sweat glands. Part of managing the donor site includes minimizing pain. Some recommended treat-ments include (a) subcutaneous anesthetic injection of adren-aline-lidocaine; (b) ice application; (c) topical agents such as lidocaine and bupivacaine; and (d) hydrocolloidand polyure-thane-based wound dressings accompanied with fibrin sealant.6 Maintaining air-tight coverage using transparent adhesive film dressing can protect the donor site during reepithelialization and minimize pain.Full-Thickness Grafts. By definition, full-thickness skin grafts include the epidermis and the complete dermis. When harvesting and preparing this type of skin graft, the surgeon must carefully remove any retained subcutaneous tissue from the deep surface of the dermis in order to maximize the poten-tial for engraftment. Full-thickness grafts are associated with the greatest amount of primary contraction, the least amount of secondary contraction, the highest durability, and ultimately the best cosmetic appearance. As a result, they are frequently used in reconstructing superficial wounds of the face and the hands. These grafts require clean, well-vascularized recipient beds free of bacterial colonization, previous irradiation, or fibrous wound tissue. They also work poorly in wounds associated with previ-ous radiation treatments in cancer patients. The harvest site for an FTSG must be closed primarily because no skin elements remain in the area of harvest.Skin Substitutes. Skin substitutes are typically types of extra-cellular matrices that are often acellular in nature and are either human-derived (allografts), animal-derived (xenografts), tissue engineered, or a combination of the three.7 These substitutes most often are employed to replace lost dermal and/or epider-mal skin layers resulting from burns, trauma, and other super-ficial injuries to the outer skin layers. While a complete review of all of these commercially available materials is beyond the scope of this chapter, the benefits and applications of these use-ful adjuncts is growing, and they been have shown to play an important role in current as well as future reconstructive, regen-erative, and restorative measures for tissue and skin replace-ment. Essentially, they act similarly to grafts as they rely on revascularization and autologous cell repopulation of the con-struct in order to “take” and become part of the lost anatomic structure they are acting to restore.Graft Take. Skin graft healing, or “take,” occurs in three phases: imbibition, inosculation, and revascularization. Plas-matic imbibition takes place during the first 24 to 48 hours after placement of the graft onto the defect. During this time, the graft is held in place by a thin film of fibrin, and the cellular elements survive by diffusion of oxygen and substrate from plasma pres-ent in the open wound. After 48 hours, a fine vascular network forms from capillaries and small blood vessels in the wound bed and advances through the fibrin layer toward the graft. These new vascular buds encounter open, cut end vessels on the deep surface of the dermis of the graft and line up, forming loose anastomoses that begin to allow blood flow and the transfer of some nutrients and oxygen. This phase is called inosculation and is the period during which the graft is most at risk for fail-ure. If the tenuous alignment of vessels between the wound bed and the graft are disrupted, then the final phase of healing will not occur. Events that can cause graft failure at this time include mechanical shear, formation of a seroma or hematoma, or bac-terial contamination. The final phase of engraftment is called revascularization. During this phase, firmer vascular anastomo-ses are formed as the vessels heal, and the graft becomes per-fused from the wound bed. Signs of perfusion, such as improved coloration and evidence of capillary refill, confirm engraftment and graft take. In most circumstances, these phases are complete by 4 to 5 days after graft placement. The dressing used after placing the skin graft is a critical part of success. It must prevent desiccation and shear stress from disrupting the graft, especially during the critical period of inosculation. Tie-over bolster dress-ings are a traditional method. Topical negative pressure wound dressings have been demonstrated to increase quantity and qual-ity of split-thickness skin graft take compared to traditional bol-ster dressings. The benefits are particularly evident in wounds with irregular surface contours in areas that might be difficult to avoid motion.8After skin graft take, the graft remains subject to late fail-ure due to mechanical shear, desiccation, or bacterial infection. Depending on the location and clinical setting, the graft should continue to be protected using dressings, topical moisturizing creams, or antibacterial medications as indicated until stable healing obtains in up to 2 weeks.Composite Grafts. Composite grafts contain other types of tissue besides skin. Additional elements must have low met-abolic requirements in order to survive the time required for revascularization. Composite grafts might include subcutane-ous fat, cartilage, perichondrium, and small amounts of muscle. Indications for composite grafts are limited to small areas with specialized tissue requirements such as nasal reconstruction. For example, excision of a skin cancer involving the nasal lobule may create a composite defect that involves internal nasal lin-ing, supporting nasal cartilage, and external skin. The ear is a good donor site for a composite graft of tissue with a good color match for the face and small amounts of tissue configured natu-rally to simulate the contours of the nose. For example, harvest of tissue from the root of the helix of the ear causes a relatively inconspicuous donor site. The donor site for composite tissue grafts must be repaired with primary closure.Surgical Flaps. A surgical flap is a unit of tissue harvested from a donor site and transferred to another location for Brunicardi_Ch45_p1967-p2026.indd 197601/03/19 6:26 PM 1977PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45reconstructive purposes. The term “flap” is derived from tech-niques of adjacent skin tissue transfers fashioned as flaps of skin that were elevated and folded into the defect. The distinguishing feature of a surgical flap is having a blood supply independent of the injured area. A graft must go through the phases of heal-ing described previously as it derives a new blood supply from the wound bed. A flap is brought to the wound with its own blood supply. This allows restoring tissue in areas of poor blood supply or with tissue requirements greater than what can be sup-ported through a period of diffusion only.There are a tremendous variety of surgical flaps that can be created depending on the individual patient’s reconstructive needs and available tissues. The challenge of reconstructive sur-gery is to design an appropriate flap to restore the defect with a minimal amount of morbidity related to the flap donor site. The different kinds of flaps can be broadly classified by three distinct characteristics: (a) the types of tissue contained, (b) the proximity to the defect, and (c) the pattern of blood supply.The first way to classify different types of surgical flaps is by what tissue they contain. Nearly any type of vascularized tissue can be transferred as a surgical flap. One of the most com-mon is a cutaneous flap, which contains skin and subcutaneous tissue. Another versatile type is a muscle flap, which contains only muscle. Musculocutaneous flaps contain a portion of mus-cle along with the overlying skin and all the intervening tissues. An osseous flap contains a segment of bone, and an osteocuta-neous flap includes skin as well as the bone. Flaps can also be designed to include fascia and peripheral nerves. Visceral flaps contain segments of jejunum, stomach, colon, or the greater omentum. The choice of flap depends upon the reconstructive needs and availability of tissue.The second way to classify surgical flaps is by their prox-imity to the defect. The location and distance between the flap donor site and the defect usually dictate the method required to transfer the tissue with preservation of the blood supply. Local flaps have a donor site located immediately adjacent to the defect.9 Regional flaps are harvested from the same anatomic region as the defect. Distant flaps are harvested and trans-ferred from outside the anatomic region of the defect. Dur-ing the transfer of all of these flaps, the blood supply remains attached to the source anatomic region. The tissue transmitting the blood supply is called the flap pedicle. When the blood supply is not divided during the transfer, it is referred to as a pedicled flap. If the distance between the donor site and the defect exceeds the length of the pedicle, the vessels can Figure 45-14. Limberg flap.be divided and then reattached to uninjured vessels within or adjacent to the defect after the tissue is placed there. This technique is called a free tissue transfer, and flaps transferred in this fashion are called free flaps because for some period of time during the procedure the tissue of the flap is completely separated, or free, of the patient. The diameter of the blood vessels that supply common surgical flaps is usually less than 5 mm. Repairing blood vessels of this caliber is considered microvascular surgery, and techniques for doing this are part of reconstructive microsurgery.The third and perhaps most important way to classify dif-ferent surgical flaps is by the pattern of their blood supply.10 Using this criterion, flaps are traditionally divided into random pattern flaps, axial pattern flaps, musculocutaneous flaps, fas-ciocutaneous flaps, direct cutaneous flaps, perforator flaps, and free flaps. These designations are based on how vessels reach from the deeper, usually named, arteries and veins to the super-ficial tissues and skin. These are described in greater detail in the following section.Random Pattern Flaps. The simplest flap designs are random pattern flaps, so named because the blood supply is based on unnamed vessels in the attached base of the flap that perfuse through the subdermal plexus.11 Random flaps are typically used to reconstruct relatively small, full-thickness defects, and they are designed following geometric principles of skin rearrange-ment with a traditional length-to-width ratio of 3:1. Exceptions to this principle regarding reliable dimensions abound, however, because of the variability in the patterns of perfusion and the density of the subdermal plexus in different regions of the body.Random pattern flaps can be further subdivided based on the geometry of the transfer. Examples of this are transposition flaps, advancement flaps, and interpolated flaps. A transposition flap is fashioned adjacent to an area needing reconstruction and rotated into the defect. Large transposition flaps can require a skin graft to close the donor site. To avoid this problem, spe-cialized types of transposition flaps have been devised. One that is particularly useful is called a Z-plasty. In this technique, two flaps are rotated, each into the donor site of the other, to rearrange the tissues in a way that redirects the lines of tension and lengthens the central limb. Another is the rhomboid (Lim-berg) flap (Fig. 45-14). In this technique, a skin flap is precisely designed with opposing 60° and 120° angles at the corners of a rhomboid designed immediately adjacent to the defect. This design can be modified to allow the flap to rotate into the defect Area withmaximum laxityABCD120°60°Brunicardi_Ch45_p1967-p2026.indd 197701/03/19 6:26 PM 1978SPECIFIC CONSIDERATIONSPART IIwith primary closure of the donor site with minimal distortion of the surrounding tissues as shown in the case of a gluteal repair (Fig. 45-15A–B, by complex closure; Fig. 45-15C–E, by modi-fied Limberg flap). Modifications on the angle, including the Dufourmental modification, cause the parametric configuration to be optimized based on the defect12 (Fig. 45-16). Rotational flaps are a type of transposition that is semicircular in design, allowing the tissue to be rotated and permitting primary closure. Advancement flaps differ from transposition flaps because the tissue is moved forward from the donor site along the flap’s long axis rather than being rotated about a point. Two common vari-ants include the rectangular advancement flap (Fig. 45-17) and the V-Y advancement flap (Fig. 45-18). Finally, interpolation flaps rotate about a pivot point but are used to transfer tissue ABCDEFigure 45-15. Reconstruction of a gluteal defect using complex closure and reconstruction of a gluteal defect using a modified Limberg flap.Brunicardi_Ch45_p1967-p2026.indd 197801/03/19 6:26 PM 1979PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-16. Dufourmental modification.Figure 45-17. Rectangular advancement flap.Figure 45-18. V-Y flap closure.BABYXZCADEF˜1˜2°Advancement flapABCDinto a nonadjacent area with an intervening portion of undam-aged tissue between the donor site and the defect (Fig. 45-19).Axial Pattern Flaps. Historically, surgeons made an increas-ing variety of surgical flaps to address a greater assortment of reconstructive problems. In the process, they noticed that some of these flaps routinely violated the strict limitations of accepted length-to-width ratio. Further investigation demon-strated that these flaps had significant arteries running parallel to the long axis of the flap. These flaps became known as axial pattern flaps.12 The earliest example of this type of flap is the deltopectoral flap, originally described in 1971 by Bakamjian (Fig. 45-20A,B). This flap is based on cutaneous vessels perfo-rating from inside the chest from the internal mammary artery and vein. After entering the subcutaneous tissues, they travel obliquely from the sternal border toward the deltoid area of the arm. Long flaps can be designed based on these vessels, which can reach into the head and neck to provide thin tissue from the upper chest to restore defects, especially after tumor ablation. Other important and useful axial pattern flaps are the groin flap and the posterior thigh flap.Musculocutaneous Flaps. The vascular pattern of musculo-cutaneous flaps arises from major vessels that primarily supply a muscle and then secondarily supply the skin through multiple small vessels traversing between the superficial surface of the muscle and the subdermal plexus. The discovery of this pat-tern of cutaneous blood supply was a major breakthrough in reconstructive surgery because it made it possible to transfer units of tissue much larger than was possible with random or axial pattern flaps, enabling plastic surgeons to restore a greater range of deformities. Mathes and Nahai classified individual muscles into five types (I–V) according to the number and dom-inance of the vascular pedicles supplying each13 (Table 45-1). There may be advantages to including muscle in a surgical flap besides ensuring adequate blood supply to the overlying skin. The classic example is breast reconstruction using a latissimus dorsi myocutaneous flap (Fig. 45-21A–C). Here, the latissimus muscle is harvested pedicled on the thoracodorsal vessels and transposed anteriorly onto the chest wall. Muscle is a highly vascularized tissue that is bulky and deformable. It can help to repair visible surface contour deformities by increasing the pro-jection of tissue in the defect to reach the level of the surround-ing undamaged tissues. It can also easily contour to fill spaces in a complicated wound surface, thus helping to prevent small fluid collections in recesses, which can be a harbor bacteria and become a nidus of infection. It is also possible to provide func-tional restoration using musculocutaneous flaps by coapting the motor nerve of the muscle in the flap to a corresponding motor nerve in the defect. This method can be used to restore motor function in patients with motor loss in the extremities or face.Fasciocutaneous Flaps. Rather than having a blood supply primarily from underlying muscle, the skin and subcutaneous tissues of some anatomic regions are supplied from vessels communicating with the underlying superficial or deep fascia. Such flaps are referred to as fasciocutaneous flaps. The artery and vein of the flap pedicle passes between rather than through muscles, form a plexus of vessels within the fascia, and then send multiple small vessels to the subdermal plexus to perfuse the skin. There are clinical circumstances when a fasciocutane-ous flap might have advantages over a musculocutaneous flap. Fasciocutaneous flaps are usually thinner compared to muscu-locutaneous flaps. They also do not create a functional loss of muscle in the donor site. Mathes and Nahai classified fasciocu-taneous flaps into types A, B, and C (Table 45-2) based on how the vascular pedicle reaches the fascia from the major vessels deep to the fascia and muscles. Sural perforator fasciocutaneous flaps (Fig. 45-22A–D) are a modern example of reconstructing lower extremity defects that would be difficult to reconstruct without microvascular surgery.Direct Cutaneous Flaps. Some surgical flaps have a vascu-lar pedicle that reaches directly to the superficial tissues and subdermal plexus without passing through a muscle or fascia plexus. These are called direct cutaneous flaps.Perforator Flaps. The final kind of surgical flap classified by the pattern of blood supply is the perforator propeller flap.14,15 The geometric measurements that are critical to its success are summarized in Fig. 45-23. Reconstructive procedures based Brunicardi_Ch45_p1967-p2026.indd 197901/03/19 6:27 PM 1980SPECIFIC CONSIDERATIONSPART IIFigure 45-19. Forehead flap for nasal reconstruction.ADBECFon these flaps are the result of complementary advances in our understanding of cutaneous blood supply and improved surgical techniques.Ian Taylor and a team of investigators from Melbourne, Australia, discovered that the blood supply to all portions of the skin was organized into discreet units, which they called angiosomes18. Analogous to dermatomes that describe the patterns of cutaneous sensation supplied by single sensory nerves, the cutaneous perfusion is organized into angiosomes supplied by a single arteries. These arteries arise from source blood vessels located deep to other structures like muscle and fascia and penetrate through as perforating vessels. Often the artery is accompanied by two venae commitantes, but in many regions an additional venous drainage system is present in the superficial planes. The territories of adjacent angiosomes over-lap similarly to how dermatomes overlap. An angiosome is defined by the limits of an artery’s terminal branching. At the borders, these arterioles form anastomoses with the neighbor-ing angiosome. The vessels that pass between these anatomic angiosomes are called choke vessels. In life, these may open or close in response to physiologic changes in order to increase or decrease, respectively, an artery’s dynamic angiosome momen-tarily. Accordingly, at any given time point, the dynamic angio-some of an artery may be approximated by the volume of tissue stained by an intravascular administration of fluorescein into that artery (indicating the reach of blood flow from that artery into tissues). The potential angiosome of an artery is the vol-ume of tissue that can be included in a flap that has undergone conditioning (see the following section). Both the dynamic and potential angiosomes extend beyond the anatomic angiosome of an artery. Although the angiosome concept provides some guidance to the size and volume limits of a flap harvest, there remains no quantifiable method to predict safe flap harvest lim-its with precision.Brunicardi_Ch45_p1967-p2026.indd 198001/03/19 6:27 PM 1981PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-20A, B. Deltopectoral flap for cheek reconstruction.Table 45-1Mathes-Nahai classification of muscular flapsCLASSIFICATIONVASCULAR SUPPLYEXAMPLEType IOne vascular pedicleGastrocnemiusType IIDominant and minor pedicles (the flap cannot survive based only on the minor pedicles)GracilisType IIITwo dominant pediclesRectus abdominisType IVSegmental pediclesSartoriusType VOne dominant pedicle with secondary segmental pedicles (the flap can survive based only on the secondary pedicles)Pectoralis majorALimit of areatubed ondeep aspectSkinGraftsBTissue Expansion. Tissue expansion is a technique that increases the amount of tissue in a surgical flap by first plac-ing an inflatable device into the tissue beneath the planned flap and gradually expanding the tissue by regular inflation. Staged reconstruction using tissue expansion can significantly increase the amount of local, well-matched tissue for transfer while decreasing donor site morbidity. The most common method of skin expansion involves the placement of an inflatable silicon elastomer similar to a balloon with a filling port that is gener-ally positioned in an easily accessible location beneath the skin. After wound healing, the device is gradually inflated by serial injections of sterile saline solution into the filling port. The process can require several weeks, depending on the amount of expansion and compliance of the tissues. When expansion is complete, the expander is removed, and the resulting expanded tissue is transferred into the defect.The process of expanding flaps confers physiologic bene-fits that increase the reliability of the flap tissue. Histologically, expanded skin demonstrates thickened dermis with enhanced vasculature and diminished subcutaneous fat. Studies have shown that the increased amount of skin is the result of actual generation of new tissue. Also, the blood supply to an expanded flap is improved because of the period of delay associated with expansion process and the capsule formed around the device is highly vascular and contributes to the quality of blood supply.16The disadvantages of tissue expansion have to do with pos-sible complications, which include infection, hematoma, seroma, expander extrusion, implant failure, skin necrosis, pain, and peripheral nerve injury. Furthermore, an inflated expander is vis-ible, and the temporary deformity may cause patients distress.Tissue expansion has found particular usefulness in man-aging giant congenital nevi, secondary reconstruction of exten-sive burn scars, scalp reconstruction, and breast reconstruction. Expanders are available in a multitude of shapes and sizes, depending on the reconstructive needs. The technique permits reconstruction with tissue of similar color, texture, and thick-ness, with minimal donor site morbidity.PEDIATRIC PLASTIC SURGERYCongenital Craniofacial AnomaliesIn 1981, Whitaker et al introduced a simple classification sys-tem to help conceptualize the vast array of congenital pathology involving the craniofacial region.17 Based on anatomy, etiology, and current treatment principles, most cra-niofacial anomalies can be classified into one of four categories: clefts, synostoses, atrophy-hypoplasia, or hypertrophy-hyper-plasia-neoplasia (Table 45-3).Clefts. Arguably, no operation in plastic surgery is more demanding of reconstructive principle and aesthetic intuition 3Brunicardi_Ch45_p1967-p2026.indd 198101/03/19 6:27 PM 1982SPECIFIC CONSIDERATIONSPART IIFigure 45-21. Breast reconstruction (right side) with a latissimus flap.B Preop, right mastectomy and left previous implant reconstructionC Postoperative: bilateral latissimus flap with implantSkin usedfor flapLatissimusdorsimuscleClosedincisionImplantundermusclesLatissimusdorsi flapin placeATable 45-2Nahai-Mathes classification of fasciocutaneous flapsCLASSIFICATIONVASCULAR SUPPLYEXAMPLEType ADirect cutaneous vessel that penetrates the fasciaTemporoparietal fascial flapType BSeptocutaneous vessel that penetrates the fasciaRadial artery forearm flapType CMusculocutaneous vessel that penetrates the fasciaTransverse rectus abdominis myocutaneous flapthan a cleft lip repair. Orofacial clefting is the most common birth defect in the world. Cleft lip, with or without cleft palate (CL/P), occurs spontaneously among Caucasian populations in approximately 1 out of every 1000 births. It is over twice as common (1 in 450) among Asians and Native Americans and half as common (1 in 2000) in African Americans. There is a predilection among males, who are twice as likely to be affected as females. Left-sided cleft lip is twice as common as right and nine times as common as bilateral. Of patients born with CL/P, 29% have associated anomalies, which can range from minor physical differences to major organ involvement. While a fam-ily history of CL/P remains the strongest known predictive factor, other extrinsic risk factors include maternal smoking or early exposure to the anticonvulsant drug phenytoin.18Epidemiologically, isolated cleft palate (CP) appears to be distinctly different from CL/P. CP occurs in 1 of every 2000 live births. It is twice as common in females, and it demonstrates no racial or ethnic preponderance. Nearly half of patients with iso-lated CP have a diagnosable syndrome and additional congeni-tal anomalies. Evaluation by a geneticist is therefore indicated in all babies born with isolated CP. Like CL/P, isolated CP is multifactorial. Known environmental risk factors include mater-nal smoking or alcohol consumption, folate deficiency, use of steroids or anticonvulsant medications, or retinoid (vitamin A) excess.Some familial patterns of orofacial clefting have been linked to specific genetic mutations. Van der Woude syndrome, an autosomal dominant form of CL/P associated with lower lip pits, is caused by an IRF6 gene mutation (Fig. 45-24).23 Stick-ler syndrome should be suspected in patients with isolated CP, Brunicardi_Ch45_p1967-p2026.indd 198201/03/19 6:27 PM 1983PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-22. Reconstruction of a lateral malleolar defect using a reverse sural perforator flap.Figure 45-23. Geometric considerations for a propeller flap.ABCDABaDefectPerforatorbc+CDwith associated eye defects, sensorineural hearing loss, and joint abnormalities. This constellation of findings is due to an autosomal dominant mutation in a procollagen gene. Stickler is also the most common syndrome associated with Pierre Robin sequence (micrognathia, glossoptosis, and respiratory distress).19 These examples help emphasize the importance of early genetic workup for patients in whom a syndrome is suspected.Embryology of the Lip and Palate The “primary palate,” which includes the nostril sill, upper lip, alveolus, and hard pal-ate anterior to the incisive foramen, forms from fusion between the medial nasal and maxillary prominences during weeks 4 through 7 of gestation.20,24 Development of the hard palate pos-terior to the incisive foramen and the soft palate, which are col-lectively known as the “secondary palate,” occurs during weeks Brunicardi_Ch45_p1967-p2026.indd 198301/03/19 6:27 PM 1984SPECIFIC CONSIDERATIONSPART IIFigure 45-24. Van der Woude syndrome.Table 45-3Classification of craniofacial anomalies211. Clefts2. Synostoses3. Atrophy–hypoplasia4. Hypertrophy–hyperplasia–neoplasia6 through 12 of gestation. The lateral palatine processes initially hang vertically on either side of the developing tongue. Around week 8, these palatal shelves rotate into a horizontal orientation, bringing their free edges into close proximity with the nasal septum. Midline fusion then commences, proceeding posteriorly from the incisive foramen (Fig. 45-25).23Normal and Cleft Anatomy There are several key defining characteristics of the lip that make its surgical repair so chal-lenging. On the surface, the philtrum of the upper lip is com-prised of paired philtral columns and a central philtral dimple. The white roll passes along the vermilion-cutaneous junction, peaking at the base of the philtral columns and dipping centrally to form Cupid’s bow. Deep to the surface, the paired orbicularis oris muscles originate lateral to the oral commissures and encir-cle the mouth, decussating in the midline and sending off dermal insertions to the philtrum. This intrinsic muscle of the lip pro-vides oral competence and assists with speech production and facial expression. Continuity of the orbicularis oris muscle is disrupted in babies born with a cleft lip. Aberrant muscle inser-tion into the piriform aperture laterally and the anterior nasal spine medially contributes to the hallmark appearance of cleft lip and nasal deformity (Fig. 45-26).20,25Clefts of the lip can be described as unilateral or bilateral and microform, incomplete, or complete. Microform cleft lip is the most minor variant and may manifest as subtly as a small notch in the vermilion. An incomplete cleft lip, by definition, requires an intact nasal sill. The term can otherwise be applied to a wide spectrum of anomaly, ranging from a partial cleft of the lip alone (Fig. 45-27A) to a near-complete cleft of the entire primary palate. A complete cleft lip involves all structures of the primary palate in their entirety, extending through the nasal sill and opening into the anterior nasal floor (Fig. 45-27B).20,26The normal palate functions primarily as a speech organ, but it is also intimately involved in feeding, swallowing, and breathing. The soft palate, or velum, together with lateral and posterior pharyngeal walls, can be conceptualized as a valve that regulates the passage of air through the nasopharynx. The paired levator veli palatini muscles descend from the cranial base and decussate in the midline to form a sling within the soft palate. This sling acts to elevate the velum against the posterior pharyngeal wall, effectively closing the velopharyngeal port. In patients with cleft palate, the levator muscles are unable to cross the midline. Instead, they run parallel to the cleft margin and insert aberrantly into the posterior edge of the hard palate (Fig. 45-28A,B). Air is allowed to leak through the nose dur-ing attempts to suck or speak. This inability to build negative or positive intraoral pressure makes either task difficult, if not impossible. The tensor veli palatini muscles, which normally function to vent and drain the Eustachian tubes, are also dis-rupted in cleft anatomy. Eustachian tube dysfunction predis-poses patients to frequent bouts of otitis media, which can lead to permanent hearing loss if left untreated.20The most clinically useful system to describe cleft pal-ate morphology is the Veau classification. A Veau I cleft is midline and limited to the soft palate alone, whereas a Veau II cleft may extend further anteriorly to involve the midline of the posterior hard palate (the “secondary palate”). A Veau III cleft is a complete unilateral cleft of primary and secondary pal-ates, in which the cleft extends through the lip, the alveolus, the entire length of the nasal floor on the cleft side, and the midline of the soft palate. Veau IV clefts are bilateral complete clefts of the primary palate that converge at the incisive foramen and continue posteriorly through the entire secondary palate (Fig. 45-29A,B). Not included in the Veau classification is the submucous cleft palate, which occurs when there is clefting of the soft palate musculature beneath intact mucosa. Submucous cleft palate classically presents as the triad of a bifid uvula, a midline translucency called the “zona Pellucida” and a palpable notch of the posterior hard palate.21Presurgical Infant Orthopedics Current literature suggests aesthetic outcomes in patients with complete unilateral or bilateral clefts may be improved by reestablishing more nor-mal skeletal, cartilaginous, and soft tissue relationships prior to definitive lip repair. Presurgical infant orthopedics (PSIO) can help to narrow wide clefts and align dental arches in prepara-tion for surgery. Some methods of PSIO, such as nasoalveolar molding (NAM), provide the added benefits of elongating the columella and improving nasal tip asymmetry.22 The most com-mon barrier to PSIO implementation is its imposition on fami-lies, who must be willing and able to keep frequent follow-up appointments for appliance adjustment. An excellent alternative to PSIO is a lip adhesion procedure, in which a complete cleft is surgically converted to an incomplete cleft. This preliminary stage of lip repair restores soft tissue continuity at the nasal sill, which helps to realign the underlying dental arches and reap-proximate the soft tissues. In addition, the nasal deformity can be improved, both by repositioning of the cleft side alar base and placement of nasal conformers.23Cleft Lip Repair Although cleft lip surgery can be traced to antiq-uity, it was not until the first half of the 20th century that sur-geons began to realize the inadequacy of a straight-line repair. In 1955, Ralph Millard pioneered his “rotation-advancement” tech-nique, which was the first to address upper lip length deficiency while preserving intricate philtral anatomy (Fig. 45-29C).24 The back-cut is designed high on the medial lip element just beneath the columella, enabling a downward rotation and leveling of Cupid’s bow, while the lateral lip element is advanced into the Brunicardi_Ch45_p1967-p2026.indd 198401/03/19 6:27 PM 1985PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-25. Facial prominences and their contributions to facial development. Cleft lip results from failure of fusion between maxillary and medial nasal (a component of frontonasal) prominences.ACDEBrotation defect. Although other techniques exist, most lip repairs performed today are minor modifications of Millard’s original rotation-advancement principle.20Bilateral cleft lip presents an even greater set of challenges to the reconstructive surgeon. With no overlying orbicularis oris muscle, an unrestrained premaxilla rotates anteriorly, com-pletely displacing the incisor-bearing portion of the alveolus from the maxillary dental arch. Orbicularis continuity must be restored over an often protuberant premaxilla. The surgeon must carefully recreate the appearance of a symmetrical philtrum and median labial tubercle. Prototypical markings for bilateral cleft lip repair are demonstrated in Fig. 45-30A,B.20Any surgical approach to bilateral cleft lip repair would be incomplete without addressing the nasal stigmata, which include a short or absent columella, a poorly defined and underprojected nasal tip, and malpositioned lower lateral cartilages.25 Primary nasoplasty at the time of lip repair has become an increasingly common practice. Nasal skin and soft tissue are dissected free from the underlying cartilaginous framework, allowing for suture manipulation of lower lateral cartilages to improve tip symmetry, support, and projection.20Cleft Palate Repair The primary goal of palatoplasty is to enable normal speech development. A successful palate repair is one that results in a robust, layered reconstruction of the cleft and restoration of functional velar anatomy. The two most com-mon techniques employed for soft palate repair are intravelar veloplasty (IVV) and Furlow double-opposing Z-plasty. Para-mount to each technique is the complete release of aberrant levator muscle insertions from the posterior edge of the hard palate. This maneuver untethers the velum anteriorly, enabling maximal levator muscle excursion in the superior and posterior directions postoperatively.21Brunicardi_Ch45_p1967-p2026.indd 198501/03/19 6:27 PM 1986SPECIFIC CONSIDERATIONSPART IIFigure 45-27. Variations in unilateral cleft lip morphology. Left unilateral incomplete cleft lip.Figure 45-26. Hallmarks of unilateral cleft lip deformity include depression of the nasal tip and flaring of the alar base on the cleft side, deviation of the caudal septum and columella toward the non-cleft side, and deficient lip height (short philtral column) on the cleft side with cephalad rotation of the cleft side of cupid’s bow.ABIntravelar veloplasty requires meticulous dissection of the levator muscles with retropositioning and reconstruction of the sling mechanism in the posterior aspect of the soft palate. A Furlow double-opposing Z-plasty involves cleverly designed mirror image Z-plasties on the oral and nasal sides of the soft palate where the central limb of each Z-plasty is the cleft. The posteriorly based flap of mucosa on each surface of the palate incorporates the underlying levator muscle. Transposition of these flaps across the cleft lengthens the palate and, in a man-ner similar to IVV, corrects levator malposition. Lateral relax-ing incisions can be utilized to relieve tension on the closure, if necessary (Fig. 45-31A–C).21,31 In experienced hands, both techniques have demonstrated excellent speech outcomes and low fistula rates. However, direct comparison between the two methods has been difficult due to ongoing evolution of the IVV technique and wide variability in the extent of dissection between performing surgeons.26Clefts involving the hard palate (Veau II–IV) often require additional maneuvers for reconstruction. Wide undermining of the nasal floor mucosa in the subperiosteal plane facilitates the nasal-side repair. As palatal mucoperiosteum is thicker and less pliable, the oral-side closure generally requires the use of relax-ing incisions along the lingual side of the alveolar ridge. Addi-tional medialization of the palatal soft tissue can be obtained by increasing isolation of the greater palatine neurovascular pedicle, which emerges from its foramen near the posterolateral aspect of the hard palate. Narrow Veau II clefts may be closed on the oral side by medialization of bilateral bipedicled muco-periosteal flaps (von Langenbeck palatoplasty), while wider clefts may require detachment of one or both flaps anteriorly for additional medialization (Bardach two-flap palatoplasty). Lateral relaxing incisions are left open, and typically heal by secondary intention within two weeks (Fig. 45-32).21,27Complications of palate repair include oronasal fistula, velopharyngeal dysfunction, obstructive sleep apnea, and mid-face growth deficiency. Reported fistula rates vary widely in the literature, but increased incidence has been correlated with less experienced surgeons, wider clefts, and bilateral clefts.21,22 Few oronasal fistulae are amenable to closure with simple local tissue rearrangement. More commonly, a complete reelevation of palatal mucosa is required in order to obtain a tension-free layered closure. In the case of large or recurrent fistulae, there may be insufficient tissue available locally, and recruitment of regional healthy tissue from the buccal mucosa or tongue may be necessary.32Velopharyngeal dysfunction (VPD) is caused by incom-plete closure of the velopharyngeal port, which results in air leaking through the nose during speech. Approximately 20% of patients develop VPD after primary palatoplasty. After insuring complete release and proper orientation of levator muscles, a posterior pharyngeal flap or a sphincter pharyngoplasty may be required to decrease the size of the velopharyngeal gap, allowing Brunicardi_Ch45_p1967-p2026.indd 198601/03/19 6:27 PM 1987PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-28. Left unilateral complete cleft lip.AponeurosisAHamulusTensor muscleLevator muscleUvulus muscleAponeurosisBHamulusTensor muscleAccessory muscleLevator muscleFigure 45-29. A. Normal anatomy: the levator veli palatini muscle forms a muscular sling in the posterior aspect of the soft palate. B. Cleft anatomy: the levator veli palatini muscles turn anteriorly, run along the cleft margin, and insert aberrantly into the posterior edge of the hard palate. C. Rotation-advancement markings and repair for a unilateral complete cleft lip.ABCnasal air escape during speech.21 These operations carry a risk of obstructive sleep apnea, so preoperative polysomnography is indicated to rule out significant sleep-disordered breathing at baseline.Timeline for Repair The longstanding debate regarding opti-mal timing for lip and palate repair is ongoing. Central to this controversy is the impact of early surgical intervention on speech outcomes and midface growth. Current evidence sug-gests earlier palate repair is better for speech but more detri-mental to midface growth.21 Cleft care algorithms represent a compromise. Most experts perform lip repair between 3 and 6 months of age.33,34 Palate repair should be completed prior to the onset of speech development, usually around 10 to 12 months of age. The alveolar cleft is often repaired secondarily with a can-cellous bone graft from the iliac crest. This operation provides bony support for the permanent teeth that will erupt adjacent to the cleft, and it is usually performed around 7 to 9 years of age. Orthognathic surgery and secondary rhinoplasty, if necessary, are delayed until skeletal maturity. The treatment timeline used at Nationwide Children’s Hospital can be seen in Fig. 45-33.Brunicardi_Ch45_p1967-p2026.indd 198701/03/19 6:28 PM 1988SPECIFIC CONSIDERATIONSPART IIABFigure 45-30. A. Bilateral cleft lip repair diagram. B. Bilateral cleft lip repair.ABCFigure 45-31. Furlow double opposing Z-plasty. A. Oral side markings. B. Nasal side markings. Note that the levator veli pala-tini muscle remains attached to the posteriorly based flap on each surface. C. Flap transposition and closure. The levator veli pala-tini muscle bundles, being attached to the posteriorly based flaps, are reoriented transversely and retrodisplaced as a result of flap transposition.Brunicardi_Ch45_p1967-p2026.indd 198801/03/19 6:28 PM 1989PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-34. The Tessier classification of craniofacial clefts. Numbered lines designate soft tissue manifestations (above) of the underlying skeletal clefts (below).Lip adhesion(1–2 months)Lip and primarynose repair(3–6 months)Orthognathicsurgery*(skeletal maturity)Definitiverhinoplasty*(after jaw surgery)Palate repair(10–12 months)Lip or noserevision*(> 6 years)VPD surgery*(4–7 years)Alveolar bonegrafting(7–11 years)Figure 45-32. Traditional von Langenbeck palatal repair with bilateral bipedicled mucoperiosteal flap.Figure 45-33. The treatment timeline used at Nationwide Children’s Hospital.The Importance of Team in Cleft Care Children born with CL/P require expertise of medical professionals from many different disciplines. In addition to experienced craniofacial surgeons, cleft teams typically consist of otolaryngologists, pediatricians, speech pathologists, feeding specialists, pediatric dentists, orthodontists, geneticists, psychologists, nurses, and social workers. Each member is an integral part of the team and absolutely essential for the delivery of comprehensive cleft care.21Atypical Craniofacial Clefts Beyond the familiar scope of clefts confined to the lip and palate, there exist myriad forms of clefting that may affect the craniofacial skeleton. Sound epide-miologic studies of these atypical craniofacial clefts have been precluded by their extreme rarity, but rough estimates place them on the order of 100 times less common than CL/P. As a result, definitive causality has not been established. With the exception of some well-defined syndromes that include atypical craniofacial clefts, genetics does not appear to play a significant part in their pathogenesis. Some extrinsic factors that have been implicated include radiation, prenatal infections, early gesta-tional exposure to teratogenic drugs or chemicals, and amniotic bands. Metabolic derangements and vascular disturbances have also been hypothesized to play a role.27While CL/P can be logically explained as an embryologic failure of fusion between facial processes, the location of the atypical craniofacial clefts is not well-accounted for by this theory. In the 1960s, Weston and Johnston used animal mod-els to demonstrate the vast contributions of neural crest cells to mesynchymal development of the face. They postulated that failure of these cells to penetrate into the developing face could lead to breakdown of the surrounding epithelia and result in atypical craniofacial clefts. The last 30 years has seen contin-ued refinement of this theory. Most recent evidence suggests that neural crest cells form developmental rests or ossification centers within the well-known facial processes. An abnormal number or impaired differentiation of these ossification centers may better explain the locations of clefts that seem to follow no known embryologic fusion plane.33In 1974, Paul Tessier published detailed anatomic obser-vations of a large series of children with atypical craniofacial clefts. He introduced a simple numbering system to classify these clefts based strictly on involved anatomy.28 Clefts were assigned numbers 0 to 14 as they radiate around the orbit. Num-bers 0 to 7 describe facial clefts, while 8 to 14 described cranial clefts. Fig. 45-34 illustrates the paths of soft tissue clefts (above) and their corresponding skeletal clefts (below).33,35A number 0 facial cleft and its number 14 cranial extension are midline clefts, which may be characterized by tissue defi-ciency or excess. Holoprosencephaly, a term used to describe a 10234568910111213141413121110987665432130334301122347Brunicardi_Ch45_p1967-p2026.indd 198901/03/19 6:28 PM 1990SPECIFIC CONSIDERATIONSPART IIfailed cleavage of the prosencephalon into two separate cere-bral hemispheres, presents as a midline tissue deficiency that causes variable degrees of hypotelorism and upper lip and nasal deformity. Mildly affected patients may have near-normal intel-ligence, while severely affected cases are incompatible with life. Representing the opposite end of the spectrum, patients with median cleft face dysmorphism typically present with a median clefts of the lip and/or premaxilla midline tissue excess, hypertelorism, bifid cranium, and a normal underlying CNS (Fig. 45-35A,B).33Tessier clefts 1, 2, and 3 originate at the cupids bow. All proceed cephalad through the piriform aperture and affect the nose. While number 1 and 2 clefts spare the orbit, number 3 clefts create continuity between the orbit, maxillary sinus, nasal and oral cavities. Clefts 4, 5, and 6 begin lateral to cupids bow, spare the nose, and pass cephalad to affect the orbit and lower eyelid. The number 7 cleft, otherwise known as craniofacial microsomia, extends transversely along a line from the oral com-missure to the auricular tragus. Underlying skeletal clefts can involve the mandible, maxilla, orbit, and cranium. Tessier clefts 8 through 10 continue to radiate laterally and superiorly around the orbit. Cranial extensions are numbered such that the sum of the facial cleft and its corresponding cranial extension is always 14. For example, the number 1 facial cleft continues as the number 13 cranial cleft, and the number 5 facial cleft continues as the number 9 cranial cleft.33,35 Clefts can be unilateral or bilateral and ABFigure 45-35. Tessier 0-14 clefts. A. Holoprosencephaly. Note the midline tissue deficiency, hypotelorism, and the rudimentary nose known as a “proboscis.” The degree of facial deformity in patients with holoprosencephaly typically reflects the degree to which the underlying CNS is affected. B. Median cleft face dysmorphism. Note the marked midline tissue excess and hypertelorism. Although this patient exhibits an obvious encephalocele, CNS function is usually normal.may occur in any combination. The constellation of bilateral Tes-sier clefts 6, 7, and 8 has been well-described within the context of Treacher Collins syndrome, in which patients exhibit malar hypoplasia, lower eyelid colobomas, and downward-slanting palpebral fissures (Fig. 45-36A–C).33Treatment of atypical craniofacial clefts varies widely with each unique patient. Classical approaches to surgical man-agement involved excision of atrophic soft tissue along cleft margins with reconstruction by local tissue rearrangement, with or without underlying bone grafting. Unfortunately, this meth-odology gives little consideration to the aesthetic units of the face, and the resulting scars often cause postoperative deformi-ties of their own. Ortiz-Monasterio and Taylor proposed a new treatment philosophy based on the following tenants:1. Restoration of the craniofacial skeleton2. Reconstruction with skin and soft tissue with like color and texture3. Generous use of tissue expanders4. Aesthetic unit and subunit reconstruction5. Scar location at limits of aesthetic subunits6. Symmetrical repositioning of key facial landmarksFig. 45-37 demonstrates the dramatic improvement in aes-thetic outcome that is attainable when abiding by this treatment philosophy.29Brunicardi_Ch45_p1967-p2026.indd 199001/03/19 6:28 PM 1991PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45ABCFigure 45-36. A child with Treacher Collins syndrome and the hallmark combination of Tessier clefts 6, 7, and 8. Note the downward-slanting palpebral fissures and profound malar hypoplasia due to complete absence of zygomas.Barring immediate danger to vital structures such as the eye, the timing of reconstruction can be determined on a case-by-case basis. Soft tissue clefts can be excised and closed by classical measures within the first year of life. However, bony reconstruction should be delayed until at least 5 to 6 years of age to minimize iatrogenic impairment of facial growth. Serial tissue expansion of the cheek prior to this time may be necessary to excise unfavorable scars and reorient them along aesthetic subunit boundaries. Preoperative imaging, such as computed tomography (CT) or magnetic resonance imaging (MRI), is necessary to fully characterize the defects and plan the opera-tion. Additional preoperative workup should include anesthe-sia evaluation and labs, as these operations can be lengthy and accompanied by significant blood loss. Preparedness for blood transfusion is imperative.33,34Craniofacial clefts are typically approached through a combination of bicoronal and oral vestibular incisions. Various osteotomies have been described to reposition components of Brunicardi_Ch45_p1967-p2026.indd 199101/03/19 6:28 PM 1992SPECIFIC CONSIDERATIONSPART IIFigure 45-37. (left) Eight-year-old girl with significant deformity from local tissue rearrangement to reconstruct a right Tessier no. 4 cleft. (center) Schematic depicting current scars with a solid line and proper scars with a dotted line. (right) Same patient after serial tissue expan-sion and relocation of scars along borders of aesthetic units.the craniofacial skeleton, such as the orbits, maxilla, and man-dible. These may be used in conjunction with bone grafts from the calvarium, ribs or iliac crest, and fixation can be achieved with standard techniques using bioresorbable plates or sutures.33Craniosynostosis. The term “craniosynostosis” refers to pre-mature fusion of one or more calvarial sutures. It occurs in up to 1 out of every 2000 live births, and single-suture, nonsyndromic patients account for 85% of cases. Of these, isolated sagittal cra-niosynostosis is the most common form, while lamdoidal is the least common. Normal suture maintenance is driven by underly-ing brain growth and a complex biochemical interplay between the suture and the underlying dura mater.30 Multiple genes have been implicated in the development of craniosynostosis, the most notable of which being FGFR and TWIST. Fifty percent of these present as de novo mutations, and most exhibit an autoso-mal dominant inheritance pattern. Environmental associations, such as maternal smoking, have been postulated, but definitive causality has not been proven.31According to Virchow’s law, patients with craniosynosto-sis exhibit a predictable pattern of deformity that results from an arrest of cranial growth perpendicular to the prematurely fused suture, with a compensatory increase in growth parallel to the affected suture (Fig. 45-38). Isolated sagittal craniosynostosis, Patent suturesFused midline sutureFigure 45-38. (left) Patent sutures permit normal cranial growth in all directions. (right) Craniosynostosis results in restricted cranial growth across the synostotic suture with a compensatory increased growth parallel to the synostotic suture (Virchow’s law).for example, results in restricted cranial growth in the transverse direction and a compensatory increase in the anterior-posterior diameter of the head with frontal and/or occipital bossing. This head shape is commonly referred to as “scaphocephaly.” Fig. 45-39 depicts various other isolated craniosynostoses and the patterns of deformity that ensue.36All patients with craniosynostosis should be screened for intracranial hypertension. It has been estimated that up to 17% of patients with single-suture involvement may develop elevated intracranial pressure (ICP). This risk approaches 50% in patients with multisuture craniosynostosis.36 Signs and symptoms of increased ICP may include headache, inconsolability, nausea, vomiting, lethargy, sleep apnea, developmental delay, bulging fontanelles, hydrocephalus, papilledema, or loss of vision.36,38 Facial dysmorphism and a strong family history should raise suspicion for syndromic etiology, as seen in Apert, Crouzon, Pfeiffer, and Saethre-Chotzen syndromes, among others.Diagnosis of craniosynostosis begins with physical exam. A recent prospective multicenter study suggests 98% accu-racy of diagnosis based upon physical exam findings alone. Palpable ridges may be present on the cranium but are not pathognomonic for craniosynostosis. The much more reliable physical exam finding involves recognition of the distinct pat-terns of cranial growth that result from premature fusion of one or more sutures. Dysmorphic facies, suspicion for multisuture involvement, or any degree of uncertainty in the diagnosis can be clarified with adjunctive imaging. While skull plain films can provide useful information, 3D computed tomography has emerged as the new gold standard imaging modality for diag-nosing craniosynostosis.37The goals of treatment for craniosynostosis are to achieve a more normalized head shape and to treat or prevent nega-tive impacts on development that may result from increased ICP.37 In general, two approaches exist: (a) strip craniectomy procedures and (b) remodeling procedures. Simply put, strip craniectomy procedures remove the synostotic suture in order to disinhibit cranial growth across the affected suture. Adjunc-tive techniques, such as cranial spring or distractor placement versus postoperative helmet therapy are frequently combined with strip craniectomies to improve aesthetic outcomes. Many surgeons who perform these procedures will do so as early as Brunicardi_Ch45_p1967-p2026.indd 199201/03/19 6:28 PM 1993PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45NormocephalyScaphocephalyTrigonocephaly AnteriorplagiocephalyBrachycephalyPosteriorplagiocephalyFigure 45-39. Patterns of single-suture cranio-synostosis. Scaphocephaly results from sagittal synostosis. Trigonocephaly results from metopic synostosis. Anterior plagiocephaly results from unilateral coronal synostosis. Brachycephaly results from bilateral coronal synostosis. Posterior plagiocephaly results from unilateral lambdoidal synostosis.6 to 12 weeks of life to take advantage of early rapid brain growth, which helps drive cranial expansion after release of the synostotic suture. In addition, younger patients have a better capacity to heal the resulting cranial defects due to the high osteogeneticity of the underlying dura, which decreases substan-tially with age.37 Remodeling procedures go further to normalize head shape by complete removal, rearrangement, and replace-ment of abnormal areas of the calvarium. Given the limited efficacy of the aforementioned strip craniectomy techniques in patients older than 6 months of age, cranial vault remodeling is generally accepted as the definitive treatment for craniosynos-tosis in this age group.36Advantages of strip craniectomy procedures include shorter operative times, less blood loss, and shorter hospital stays, while disadvantages include an inability to treat complex deformities from multisuture involvement, inability to treat areas of compensatory increased cranial growth, and the neces-sity for secondary hardware removal procedures. Remodeling procedures offer a more definitive correction of head shape in a single surgical procedure at the cost of increased operative times, higher rate of blood transfusions, and increased length of hospital stays.37The complexity of patients with syndromic craniosynosto-ses, such as Crouzon or Apert syndrome, mandates multidisci-plinary care from an experienced team of subspecialists. These patients may present with urgent airway obstruction, danger-ously elevated ICP, and/or vision-threatening globe protrusion (Fig. 45-40A–C).23 Early surgical interventions, such as strip craniectomy or posterior cranial vault distraction, are designed to increase cranial volume and therefore decrease ICP. Although optimal timing of definitive reconstruction is debatable, results of cranial vault remodeling and midface advancement surgeries appear more stable and demonstrate less relapse when delayed.32 Hearing, speech, and feeding difficulties are common among patients with syndromic craniosynostoses. As always, the psy-chosocial implications of such profound facial differences make social workers and psychologists indispensable members of the team.23Atrophy and Hypoplasia. Two conditions that exemplify the atrophy and hypoplasia class of craniofacial anomalies are progressive hemifacial atrophy and Robin sequence. Progres-sive hemifacial atrophy, otherwise known as Parry-Romberg syndrome, is a rare, acquired, idiopathic atrophy of the skin, subcutaneous tissue, muscle, and occasionally bone affecting one side of the face (Fig. 45-41). With a typical onset during the first or second decade of life, this self-limiting condition progresses with an indolent course for 2 to 10 years before sta-bilizing, or “burning out.” The pathogenesis of Parry-Romberg syndrome is not well understood. Autoimmune processes such as scleroderma, chronic neurotropic viral infections, trigeminal neuritis, intracerebral vascular malformations, and increased sympathetic nerve activity have all been postulated to play a role. After progression of atrophy ceases, the mainstay of treat-ment is volume and contour restoration with autologous fat grafting. More severe cases may require microvascular transfer of free tissue, such as the parascapular fasciocutaneous flap.33Robin sequence is defined as the triad of micrognathia, glossoptosis, and airway obstruction (Fig. 45-42).23 Cleft palate is present in up to 90% of affected patients, though it is not an obligatory component of the diagnosis. The cause of this condi-tion is not known, but many believe mandibular hypoplasia to be the inciting event. According to this theory, micrognathia (small jaw) prevents forward migration of the tongue during gestational development. Glossoptosis results, where the tongue remains flipped dorsally into an obstructive position within the oropharyngeal airway. The first step in management is prone positioning, which utilizes gravity to bring the mandible and tongue base forward and alleviate the upper airway obstruction. More severely affected babies may require emergent endotra-cheal intubation at the time of delivery in order to secure the airway.34A diagnosable syndrome can be expected in over 50% of patients born with Robin sequence. Stickler syndrome (congeni-tal ocular, orofacial, auditory, and articular anomalies), which is the leading cause of childhood blindness due to retinal detach-ment, is the most commonly associated syndrome. For this reason, ophthalmology and genetics evaluations are indicated in all patients with Robin sequence. Additionally, a thorough airway evaluation by an otolaryngologist is necessary to con-firm obstruction at the level of the tongue base and to rule out intrinsic airway anomalies or obstruction at lower levels of the respiratory tract.41Babies who are mildly affected can often be managed nonsurgically with prone positioning alone. Close monitoring is required because obstructive symptoms do not always fol-low a linear course to resolution. High caloric expenditure on Brunicardi_Ch45_p1967-p2026.indd 199301/03/19 6:28 PM 1994SPECIFIC CONSIDERATIONSPART IIABCFigure 45-40. A and B. Frontal and lateral views of a young girl affected by Crouzon syndrome. Brachycephaly is appreciable on the lateral view, which results from bicoronal craniosynostosis. This patient also exhibits exorbitism and significant midface hyposplasia. C. A patient with Crouzon syndrome whose severe exorbitism has led to exposure keratitis.Brunicardi_Ch45_p1967-p2026.indd 199401/03/19 6:29 PM 1995PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-41. Child with progressive hemifacial atrophy, other-wise known as Parry-Romberg syndrome.Figure 45-42. An infant with Robin sequence. Marked microgna-thia and glossoptosis cause respiratory distress due to upper airway obstruction at the level of the tongue base. Note the presence of sternal retraction during inspiration.increased work of breathing, in combination with reflux and feeding difficulties that are ubiquitous in this population, may manifest as poor weight gain over time. Persistent failure to thrive indicates a failure of conservative management.41Robin sequence patients with single-level obstruction at the tongue base who have failed conservative measures should be considered for surgical airway management.41 Tongue-lip adhesion (TLA) is designed to bring the tongue base forward and out of the airway by temporarily sewing the under-surface of the tongue to the mucosal surface of the lower lip. Adhesions are typically reversed within the first year of life as significant mandibular growth and improved muscle tone of the tongue result in a stable airway.35Another option to treat upper airway obstruction in patients with Robin sequence is mandibular distraction osteogenesis (MDO). In this procedure, osteotomies are made in bilateral mandibular rami, and distractor devices are applied that enable a gradual (1–2 mm/day) lengthening of the mandible. As the mandible is brought forward, the tongue base follows, result-ing in enlargement of the oropharyngeal airway. Specific risks include injury to tooth buds, inferior alveolar or marginal man-dibular nerves, and disruption of mandibular growth potential.41In Robin sequence, patients who fail or are not candidates for less invasive surgical maneuvers, tracheostomy remains the definitive option for airway control. Figure 45-43 represents an algorithm for management of children with Robin sequence proposed on the basis that TLA is less invasive and does not preclude subsequent MDO in the event of failure.42 However, 4one option has not been proven to be significantly better than the other, and many surgeons prefer MDO as a first-line intervention.Hypertrophy, Hyperplasia, and Neoplasia. Numerous hypertrophic, hyperplastic, or neoplastic processes can affect the craniofacial region. The presence of certain vascular anomalies in the face can result in hypertrophy of surrounding bone or soft tissue.19 Patients with neurofibromatosis-1 may similarly present with hemifacial hypertrophy related to the presence of an underlying plexiform neurofibroma.36 Fibrous dysplasia is a focal error in osteoblast differentiation that leads to replacement of normal bone with a disorganized mass of bony trabeculae and fibrous tissue. Seventy percent of lesions are monostotic, and MandibulardistractionosteogenesisLaryngotrachealanomaly?Treat anomaly +/– tracheostomyPronepositioningObservationTongue-lip adhesionObservationFigure 45-43. Algorithm for management of children with Robin sequence.Brunicardi_Ch45_p1967-p2026.indd 199501/03/19 6:29 PM 1996SPECIFIC CONSIDERATIONSPART IIthe remaining 30% are polyostotic. In the craniofacial region, fibrous dysplasia typically presents in childhood with pain and progressive asymmetry. Patients with McCune-Albright syn-drome have polyostotic fibrous dysplasia, café au lait spots, and hyperfunctioning endocrinopathies, which classically manifest as precocious puberty. Lesions have a distinct “ground glass” appearance on CT scan. Small, monostotic fibrous dysplasia lesions can occasionally be resected completely and recon-structed with bone grafts. More commonly, surgical debulking and contouring is the treatment of choice.37Vascular Anomalies. Vascular anomalies affect approxi-mately 5.5% of the population. They can be broadly categorized as either tumors or malformations.38 Vascular tumors are char-acterized histologically by endothelial cell proliferation, with or without luminal structure. In contrast, vascular malformations are collections of abnormally developed vessels without signifi-cant endothelial cell turnover.39Hemangiomas Hemangiomas are the most common vascular tumor in children, presenting in up to 20% of premature infants. Females are four times as likely to be affected as males, and darker-skinned individuals are rarely affected. These benign tumors are believed to be collections of primitive blood vessels formed from angioblasts. Hemangiomas can occur anywhere throughout the body, with the liver being the most common extracutaneous site.46The natural history of hemangiomas is highly predict-able depending on the timing of presentation and early clinical course. Infantile hemangiomas appear shortly after birth, usu-ally between 2 weeks and 2 months of life. Cutaneous infantile hemangiomas may initially resemble a red scratch or bruise, while subcutaneous or visceral lesions go unnoticed. Rapid growth ensues over the next 9 to 12 months (“the proliferative phase”). During this time, cutaneous lesions become bright red and tense, while subcutaneous lesions may present as deep soft tissue masses with a bluish/purplish hue. After plateau of the proliferative phase, infantile hemangiomas reliably undergo a slow regression (“involution”), which is usually complete by 4 years of age. History alone can help differentiate a congenital hemangioma, which is fully formed at birth, from an infantile one. Congenital hemangiomas may exhibit rapidly involuting (RICH), noninvoluting (NICH), or partially involuting (PICH) clinical courses. History and physical is often sufficient to diagnose a hemangioma. Doppler ultrasound has become the imaging modality of choice, while MRI is typically reserved to confirm the diagnosis in cases of uncertainty.40Most hemangiomas can be observed and allowed to invo-lute spontaneously. High-risk lesions that may require early intervention include ulcerated and bleeding hemangiomas; periocular hemangiomas, which can occlude the visual axis and lead to blindness; hemangiomas in the beard distribution, which place the patient at risk for upper airway obstruction (Fig. 45-44); and posterior midline lumbosacral hemangiomas, which may indicate underlying spinal dysraphism and cause cord compression. Patients with three or more hemangiomas should be screened by ultrasound for involvement of abdomi-nal viscera, as large hepatic lesions may lead to high-output heart failure. Large segmental hemangiomas in the cranial nerve V distribution (Fig. 45-45) should raise suspicion for PHACES association (Posterior fossa malformations, Heman-giomas, Arterial anomalies, Cardiac defects, Eye anomalies, Sternal defects).46 The LUMBAR association (Lower body Figure 45-44. Hemangiomas in the beard distribution.hemangiomas, Urogenital anomalies, Myelopathy, Bony defor-mities, Anorectal/Arterial malformations, Renal anomalies) should be considered in patients with large infantile hemangio-mas of the lumbosacral region or lower extremities.41Oral propranolol therapy has emerged as the first-line treatment for complicated or high-risk infantile hemangio-mas. When administered during the proliferative phase, this nonselective beta adrenergic receptor blocker causes rapid invo-lution of the hemangioma. Several randomized, controlled trials have demonstrated oral propranolol to cause a greater decrease in lesion size compared to placebo and steroid therapy.42 In addition, many clinicians believe the side effect profile of pro-pranolol (hypoglycemia, sleep disturbances, hypotension, bra-dycardia, bronchospasm) to be more favorable than that of systemic steroids.43While hemangioma involution may result in no visible sequelae, up to 50% of patients are left with a residual fibrofatty mass with atrophic, hypopigmented and/or telangiectatic over-lying skin (Fig. 45-46A,B). If the residual deformity is troubling to the patient, surgical excision may be indicated.46Vascular Malformations Vascular malformations are collec-tions of abnormally formed vessels that demonstrate minimal endothelial cell turnover. They are present at birth and grow slowly in proportion with the patient. Vascular malformations are classified on the basis of anatomic origin of the abnormal vessels: capillary malformations (CM), venous malformations (VM), lymphatic malformations (LM), and arteriovenous mal-formations (AVM). These classes can be further categorized into “slow-flow” or “fast-flow” lesions (Table 45-4).46Capillary malformations, formerly known as “port wine stains,” present at birth as flat, pink patches of skin. They typi-cally darken with age and may develop a thickened or “cob-blestoned” appearance. CMs may be found anywhere on the body, and overgrowth of underlying soft tissue or bone can occur. History and physical is sufficient to diagnose isolated CMs, but syndromic associations do exist that would warrant 5Brunicardi_Ch45_p1967-p2026.indd 199601/03/19 6:29 PM 1997PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-45. Large segmental hemangiomas in the cranial nerve V distribution.Figure 45-46. Twenty-year-old female with a capillary malformations of the right cheek. A. Before and (B) after pulsed-dye laser treatment.ABTable 45-4Classification of vascular malformationsSLOW FLOWFAST FLOWCapillary malformationsVenous malformationsLymphatic malformationsArteriovenous malformationsfurther work-up.46 Sturge-Weber syndrome often presents with CMs in the V1/V2 nerve distributions of the face and may be accompanied by vascular malformations of the underlying lep-tomeninges or globe. Patients are at high risk for seizure, stroke, and glaucoma, for which pharmacologic prophylaxis may be indicated.44 The mainstay of treatment of CMs is pulsed-dye laser therapy (Fig. 45-47A, pre procedure; Fig. 45-47B post pro-cedure). Other surgical interventions, if necessary, are aimed at addressing soft tissue or bony overgrowth.46Venous malformations are lobulated collections of dilated veins that typically involve skin, mucosa, or subcutaneous tis-sue, although 50% demonstrate deeper involvement. Lesions may or may not be noted at the time of birth. VMs generally grow in proportion to the patient but may undergo accelerated growth during puberty or pregnancy. Swelling of the mass may occur with dependent positioning or Valsalva maneuvers, such as crying. On exam, superficial VMs are soft, compressible masses with a bluish hue. Firm, tender nodules may be present, which represent calcifications known as phleboliths. Deeper, intramuscular VMs may present with pain or increased extrem-ity circumference, while lesions of the GI tract may simply pres-ent with bleeding. MRI with contrast is the imaging modality of choice, although ultrasound can be used in infants and young children to avoid sedation. Observation is indicated for asymp-tomatic lesions. Compression of involved extremities helps alleviate pain and swelling and prevent thrombosis and phlebo-lith formation. Due to the high risk of recurrence after surgi-cal excision, the first line of treatment for symptomatic VMs is sclerotherapy. Surgery is reserved for small, well-localized lesions amenable to complete resection; extremity lesions near major peripheral nerves; or residual deformities after sclero-therapy (Fig. 45-48A, before laser; Fig. 45-48B, after laser; and Fig. 45-48C, after limited resection).46Brunicardi_Ch45_p1967-p2026.indd 199701/03/19 6:29 PM 1998SPECIFIC CONSIDERATIONSPART IIABABCFigure 45-47. A. A 3-year-old patient with an involuting hem-angioma of the right cheek. B. The same patient at 8 years of age showing minimal sequelae after completion of involution.Figure 45-48. A 5-year-old boy with venous malformation of the lower lip. A. Initial presentation. B. After three sclerotherapy treat-ments. C. Six weeks after surgical debulking of residual fibrotic tissue.Brunicardi_Ch45_p1967-p2026.indd 199801/03/19 6:29 PM 1999PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-49. A. Lymphatic malformation of the neck. B. After sclerotherapy with significant skin excess. C. Seven months after resection of excess skin.Lymphatic malformations, previously referred to as “cys-tic hygromas,” are collections of abnormal lymph channels that may cross multiple tissue planes and cause swelling, pain, bleeding, or bony overgrowth. LMs are classified as macrocys-tic, microcystic or combined. Large, macrocystic lesions can alter form and impair function locally through mass effect. Cuta-neous components of LMs present as vesicles that may bleed or become infected. While superficial lesions can be diagnosed by history and physical exam alone, deeper lesions require MRI ABCto confirm the diagnosis and assess the extent of the disease. Asymptomatic LMs can be observed. Sclerotherapy is the treat-ment of choice for all macrocysts. Symptomatic microcystic LMs have been treated with oral sirolimus, and draining cutane-ous vesicles have been successfully ablated with CO2 laser ther-apy. Recurrence after surgery is common; therefore, excision is reserved for severely symptomatic lesions no longer amenable to sclerotherapy or small, well-localized lesions where excision can be curative (Fig. 45-49A–C).46Brunicardi_Ch45_p1967-p2026.indd 199901/03/19 6:30 PM 2000SPECIFIC CONSIDERATIONSPART IIArteriovenous malformations are abnormal vascular con-nections between arteries and veins without intervening capil-lary beds. AVMs involving the skin appear pink and are warm to the touch. A palpable pulse or thrill may be present from the fast-flow shunting of blood from arterial to venous circu-lation. Lack of local capillaries can cause a painful, ischemic ulceration of the skin. Patients with large AVMs are at risk for development of congestive heart failure. Doppler ultrasound is the imaging modality of choice, but MRI is often obtained to provide additional information on the extent of the lesion. Observation is appropriate for asymptomatic AVMs. For symp-tomatic AVMs, embolization is frequently employed 24 to 72 hours prior to excision to minimize operative blood loss. Excision or embolization alone is rarely curative and highly likely to recur. Indications for surgery include small, well-localized AVMs; focal deformities that result from an AVM; or symptomatic AVMs not amenable to embolization.46When multiple types of vascular malformations cohabi-tate, they are collectively referred to as combined malforma-tions. Patients with Klippel-Trenaunay syndrome demonstrate a combined capillary, venous, and lymphatic malformation of an extremity resulting in bony and/or soft tissue overgrowth (Fig. 45-50).45Figure 45-50. A patient with Klippel-Trenaunay syndrome involv-ing the right lower extremity. The combined capillary, venous, and lymphatic malformations result in generalized overgrowth of the extremity.Table 45-5Classification of CMN’sPROJECTED ADULT DIAMETERCMN CLASSIFICATION<1.5 cmSmall≥1.5 cm and <11 cmMedium≥11 cm and ≤20 cmLarge>20 cmGiantCongenital Melanocytic Nevi. Congenital melanocytic nevi (CMN) are hyperpigmented lesions present at birth that result from ectopic rests of melanocytes within the skin. They can be distinguished histologically from acquired nevi by their exten-sion into the deep dermis, subcutaneous tissue, or muscle.46 Depending on their size and location, CMNs may cause severe disfigurement and accompanying psychologic distress. Classi-fication is based on projected diameter of the largest dimension on the fully-grown adult (Table 45-5)47. While CMNs are gener-ally common (1% incidence), only 1 in 20,000 children are born with a giant lesion. At birth, CMNs often appear flat, brown and hairless. They grow in proportion with the patient and may develop color variegation, verrucous thickening, hypertrichosis, erosions, or ulcerations over time. CMNs carry an estimated 0.7% to 2.9% lifetime risk of melanoma, with the majority of cases presenting before puberty. Patients with giant CMNs, multiple satellite lesions, or trunk lesions appear to be at higher risk for malignancy. Melanomas can develop within the CMN itself, but they may also present as primary cancers at distant, extra-cutaneous sites, such as the GI tract or the central nervous system. Patients with CMNs require regular skin surveillance by a dermatologist. A biopsy is indicated for concerning changes in color or shape, nodularity, or ulceration. If melanoma is diag-nosed, management should proceed in accordance with standard melanoma treatment guidelines.55CMNs with multiple (>20) satellite lesions or midline CMNs over the trunk or calvaria should raise suspicion for neu-rocutaneous melanosis, a condition resulting from melanoblast proliferation in the central nervous system (CNS). In addition to the risk of CNS melanoma, patients with neurocutaneous melanosis may suffer from developmental delay, seizures, intracranial hemorrhages, hydrocephalus, cranial nerve palsies, or tethered spinal cord. High-risk patients should be evaluated by MRI between 4 and 6 months of age. While asymptomatic patients may be followed with serial MRI, patients with symp-tomatic neurocutaneous melanosis often succumb to their dis-ease within 2 to 3 years of diagnosis.54The goals in surgical management of CMN are (a) to decrease cancer risk, (b) to reduce symptoms, (c) to improve appearance, (d) to improve psychosocial health, and (e) to maintain function.54 It is important to note that the risk of mela-noma is not eliminated even with complete excision of a CMN. Indeed, a definitive cancer risk reduction from surgical excision of CMNs has yet to be proven. Management paradigms have therefore shifted from complete excision and reconstruction to maximal excision and reconstruction without compromis-ing function or aesthetic outcome.55 From serial excisions or skin grafting, to tissue expansion or free tissue transfer, plastic surgeons have drawn from the entire armamentarium in meet-ing the substantial reconstructive challenges posed by giant CMNs. Treatment plans must be grounded in principle: “tissue Brunicardi_Ch45_p1967-p2026.indd 200001/03/19 6:30 PM 2001PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45losses should be replaced in kind,” and “reconstruct by units.”48 Figure 45-51A–C shows an infant with a giant CMN of the pos-terior trunk and right flank preoperatively; at end of the first round of tissue expansion; and at the culmination of three rounds of tissue expansion, excision, and closure by local tissue rearrangement.49Figure 45-51. A. An infant with a giant CMN of the posterior trunk and right flank. B. Tissues expanders were placed under adjacent normal skin in preparation for first-stage excision. C. The same patient at 11 years of age after three rounds of tissue expansion and excision.ABCRECONSTRUCTIVE SURGERY IN ADULTSReconstructive surgery applies techniques that modify tissues in order to restore a normal function and appearance in a patient with congenital or acquired deformities. The most common causes of acquired deformities are traumatic injuries and cancer.Brunicardi_Ch45_p1967-p2026.indd 200101/03/19 6:30 PM 2002SPECIFIC CONSIDERATIONSPART IIWe will focus first on trauma. Although any anatomic region can be subjected to injuries that might require reconstruc-tive surgery, traumatic fractures, and soft tissue damage in the head and neck and extremities are most common. The manner in which these reconstructive steps are conducted is criti-cal. Reconstructive surgery involves the coordination of many specialties and must occur according to a particular time-line, involving complex system-based practice.Maxillofacial Injuries and FracturesManagement of maxillofacial injuries typically occurs in the context of multiple trauma. Concomitant injuries beyond the face are the rule rather than the exception. The first phase of care is activation of the advanced trauma life support proto-cols. The most common life-threatening considerations in the facial trauma patient are airway maintenance, control of bleed-ing, identification and treatment of aspiration, assessment for closed head injuries, and identification of other injuries. Once the patient’s condition has been stabilized and life-threatening injuries managed, attention is directed to diagnosis and manage-ment of craniofacial injuries.Physical examination of the face focuses first on assess-ment of soft tissue injuries as manifested by surface contusions and lacerations. Part of this process is intranasal and intraoral examination. Associated injuries to the underlying facial skel-eton are determined by observation, palpation, and digital bone examination through open lacerations. Signs of a facial frac-ture include contour abnormalities, irregularities of normally smooth contours such as the orbital rims or inferior border of the mandible, instability, tenderness, ecchymosis, facial asym-metry, or displacement of facial landmarks. Traditional plain radiographs have largely been replaced by high-resolution CT, which is widely available at emergency centers that typically receive these patients. Reformatting raw scans into coronal, sag-ittal, and 3D views is a valuable method to elucidate and plan treatment for complex injuries.The facial skeleton can be divided into the upper third, middle third, and lower third. The upper third is comprised bounded inferiorly by the superior orbital rim and is formed by the frontal bone. The middle third is the most complex and is formed primarily by the maxilla, nasal bones, and zygoma. The lower third is inferior to the oral cavity and is formed by the mandible. The functional structure of the midface may be understood as a system of buttresses formed by the frontal, maxillary, zygomatic, and sphenoid bones. These buttresses are oriented vertically and horizontally and distribute forces applied to the bones in order to maintain their shape and position with-out fracturing. There are three paired vertical buttresses called the nasomaxillary, zygomaticomaxillary, and pterygomaxillary buttresses. The horizontal buttresses of the midface pass through the superior and inferior orbital rims and hard palate. A guiding principle of facial facture management is to restore the integrity of these buttresses.Mandible FracturesMandibular fractures are common injuries that may lead to permanent disability if not diagnosed and properly treated. The mandibular angle, ramus, coronoid process, and condyle are points of attachment for the muscles of mastication, including the masseter, temporalis, lateral pterygoid, and medial pterygoid muscles (Fig. 45-52). Fractures are frequently multiple. Altera-tions in dental occlusion usually accompany mandible fractures. Malocclusion is caused by forces exerted on the mandible of the 6CoronoidprocessRamusAngleBodySymphysisCondyleFigure 45-52. Mandibular anatomy.many muscles of mastication on the fracture segments. Den-tal occlusion is perhaps the most important basic relationship to understand about fracture of the midface and mandible. The Angle classification system describes the relationship of the maxillary teeth to the mandibular teeth. Class I is normal occlu-sion, with the mesial buccal cusp of the first maxillary molar fitting into the intercuspal groove of the mandibular first molar. Class II malocclusion is characterized by anterior (mesial) posi-tioning, and class III malocclusion is posterior (distal) posi-tioning of the maxillary teeth with respect to the mandibular teeth (Fig. 45-53). These occlusal relationships guide clinical management.The goals of surgical treatment include restoration of den-tal occlusion, fracture reduction and stable fixation, and soft Figure 45-53. Angle classification. Class I: The mesial buccal cusp of the maxillary first molar fits into the intercuspal groove of the mandibular first molar. Class II: The mesial buccal cusp of the maxillary first molar is mesial to the intercuspal groove of the mandibular first molar. Class III: The mesial buccal cusp of the maxillary first molar is distal to the intercuspal groove of the man-dibular first molar.IIIIIIBrunicardi_Ch45_p1967-p2026.indd 200201/03/19 6:30 PM 2003PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45tissue repair. Nonsurgical treatment may be used in situations in which there is minimal displacement, preservation of the pretraumatic occlusive relationship, normal range of motion, and no significant soft tissue injury. Operative repair involves first establishing and stabilizing dental occlusion and holding in place with maxillomandibular fixation to stabilize the relation-ships between the mandible and maxilla. The simplest method for this is to apply arch bars to the maxillary and mandibular teeth then use secure them together using interdental wires. Alternatives are sometimes indicated (e.g., screws placed into the bone of the maxilla and mandible that serve as posts for spanning the maxilla and mandible with wires), especially for patients with poor dentition. Once the dental relationships are established, then the fractures can then be reduced and fixed using wire or plates and screws that are specially designed for this purpose. The fracture is surgically exposed using multiple incisions, depending on the location of the fracture and condi-tion of the soft tissues. The fracture is visualized and manually reduced. Fixation may be accomplished using traditional inter-fragment wires, but plating systems are generally superior. The mandibular plating approach follows two schools of thought: rigid fixation as espoused by the Association for Osteosynthe-sis/Association for the Study of Internal Fixation and less rigid but functionally stable fixation (Champy technique). Regardless of the approach, it is important to release maxillomandibular fixation and begin range of motion as soon as possible to pre-vent temporomandibular joint ankylosis. Fractures immediately inferior to the mandibular condyles, called subcondylar frac-tures, are unique in that there is ordinarily minimal displace-ment because the fragments are less subject to displacement from muscle forces and there is little bone available across the ClosedOpenYesYesNoNoAnteriortable onlyAnterior andposteriortables ObservationAnterior ORIFAnterior ORIFAnterior ORIFCranialization of sinusObliteration of NF ductbone grafting orificefat/fascial grafting orificeflap coverage of cavityremoval of posterior tableburring of mucosa-----ExplorationEstablish DiagnosisPhysical examCT scanDepressed?CSF leak ordisplacedposterior wall?Figure 45-54. Algorithm for the treatment of frontal sinus fracture. CSF = cerebrospinal fluid; CT = computed tomography; NF = nasofrontal; ORIF = open reduction, internal fixation.fracture line to permit fixation. These are most often treated with maxillomandibular fixation alone.Important considerations in postoperative management are release from maxillary-mandibular fixation and resumption of range of motion as soon as possible to minimize the risk of tem-poromandibular joint ankylosis. Complications to be avoided include infection, nonunion, malunion, malocclusion, facial nerve injury, mental nerve injury, and dental fractures.Frontal Sinus FracturesThe frontal sinus is located in the upper third of the face. It is actually a paired structure ordinarily fused in the midline imme-diately superior to the orbital rims. It has an anterior bony table that defines the contour of the forehead and a posterior table that separates the sinus cavity from the underlying dura of the intra-cranial frontal fossa. The anterior table is a relatively weak and subject to fracture when it sustains a direct forceful blow, mak-ing frontal sinus fractures relatively common in facial trauma. Each sinus drains through the medial floor into its frontonasal duct, which empties into the middle meatus within the nose.Treatment of a frontal sinus fracture depends on the frac-ture characteristics as shown in the algorithm (Fig. 45-54). The diagnosis is established by physical examination and confirmed by CT scan. Closed fractures that are not depressed and caus-ing a visible deformity may be observed. Depressed or open fractures must be explored. Fractures that involve only the anterior table are reduced and fixed using interosseous wires or miniature plates and screws. Fractures of the posterior table without disruption of the dura evidenced by leaking cerebro-spinal fluid can be treated in similar fashion. When the dura is disrupted, excising the bone and mucosa or the posterior table Brunicardi_Ch45_p1967-p2026.indd 200301/03/19 6:30 PM 2004SPECIFIC CONSIDERATIONSPART IIand obliterating the nasofrontal duct with a local graft or flap converts with frontal sinus into the anterior frontal fossa of the cranial vault, “cranializing” it.Orbital FracturesTreatment of all orbital injuries begins with a careful examina-tion of the globe, which often is best completed by a specialist to assess visual acuity and ocular mobility and to rule out globe injury. Fractures may involve the orbital roof, the orbital floor, or the lateral or medial walls (Fig. 45-55). The most common fracture involves the floor because this is the weakest bone. This type of fracture is referred to as an orbital a “blow-out” frac-ture because the cause is usually direct impact to the globe that results in a sudden increase in intraorbital pressure with failure of the orbital floor. The typical history is either a direct blow Figure 45-55. Facial bone anatomy.FrontalTemporalSphenoidZygomaMaxillaSphenoidFrontalZygomaMaxillaTemporalABduring an altercation or a sports-related event with a small ball directly striking the orbit. Because the medial floor and inferior medial wall are made of the thinnest bone, fractures occur most frequently at these locations. These injuries may be treated with observation only if they are isolated and small without signs of displacement or limitation of mobility of the globe. However, surgical treatment is generally indicated for large fractures or ones associated with enophthalmos (retrusion of the globe), which suggests increased intraorbital volume and restriction of upward gaze on the injured side, with entrapment of inferior orbital tissues or double vision (diplopia) persisting greater than 2 weeks.28 There are a variety of options for surgical exposure of the orbital floor, including the transconjunctival, subciliary, and lower blepharoplasty incisions. All provide good access for accurate diagnosis and treatment, which involves reducing orbital contents and repairing the floor with either autologous bone or synthetic materials. Late complications include per-sistent diplopia, enophthalmos, or displacement of the lower eyelid ciliary margin inferiorly (ectropion) or rolling inward (entropion). Entropion causes the eyelashes to brush constantly against the cornea and is very uncomfortable. Each of these sequelae has procedures for repair should they occur.Orbital floor fractures can be associated with fractures of the lateral or inferior orbital rim. These are typically a compo-nent of facial fractures that extend beyond the orbit involving the zygomatic and maxillary bones and are discussed in more detail in the next section.It is important to be aware of two adverse associated con-ditions seen at times in patients with orbital fractures. The first is superior orbital fissure syndrome. Cranial nerves III (oculo-motor nerve), IV (trochlear nerve), and VI (abducens nerve), and the first division of cranial nerve V (VI, trigeminal nerve) pass into the orbit from the base of the skull and into the orbit through the superior orbital fissure. Direct fractures of the pos-terior orbit or localized swelling caused by a fracture nearby can cause compression of these nerves. Symptoms include eyelid ptosis, protrusion of the globe (proptosis), paralysis of the extra-ocular muscles, and anesthesia supraorbital and trochlear nerve distributions. The second condition to remember is orbital apex syndrome. This is the most severe circumstance in which supe-rior orbital fissure syndrome is combined with signs of optic nerve (cranial nerve II) compression manifested visual changes ranging up to complete blindness. This is a medical emergency that requires immediate treatment to prevent permanent loss of function.Zygomaticomaxillary Complex FracturesThe zygoma defines the lateral contour of the middle third of the face and forms the lateral and inferior borders of the orbit. It articulates with the sphenoid bone in the lateral orbit, the maxilla medially and inferiorly, the frontal bone superiorly, and the temporal bone laterally. It forms the anterior portion of the zygomatic arch, articulating with the zygomatic projection of the temporal bone. The temporalis muscle, a major muscle of mastication, passes beneath the zygomatic arch and inserts on the coronoid process of the mandible.Fractures of the zygomatic bone may involve the zygo-matic arch alone or any of its other portions and bony relation-ships. Isolated arch fractures manifest as a flattened, wide facial appearance with edema and ecchymosis. Typically, they are also associated with pain or limited mobility of the mandible. Nondisplaced fractures may be treated without surgery, but Brunicardi_Ch45_p1967-p2026.indd 200401/03/19 6:30 PM 2005PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45displaced or comminuted fractures should be reduced and stabi-lized. This can be accomplished using an indirect approach from above the hairline in the temporal scalp, the so-called “Gilles approach,” or directly through a coronal incision in severe fractures.A common fracture pattern is called the zygomaticomaxil-lary complex (ZMC) fracture. This involves the zygomatic arch, the inferior orbital rim, the zygomaticomaxillary buttress, the lateral orbital wall, and the zygomaticofrontal buttress. Muscle forces acting on the fracture segment tend to rotate it laterally and inferiorly, thereby expanding the orbital volume, limiting mandibular excursion, creating an inferior cant to the palpebral fissure, and flattening the malar eminence. ZMC fractures are almost always accompanied on physical examination by altered sensation in the infraorbital nerve distribution and a subconjunc-tival hematoma.Treatment of displaced ZMC fractures is surgical. Each fracture site is exposed through incisions strategically placed to gain access but minimize disfiguring facial scars afterwards. These include an incision in the upper eyelid, exposing the zygomaticofrontal buttress and lateral orbital wall; a subtarsal or transconjunctival incision in the lower eyelid, exposing the orbital floor and infraorbital rim; and a maxillary gingivobuc-cal sulcus incision, exposing the zygomaticomaxillary buttress. Severe fractures involving the arch require wide exposure through a coronal incision.Nasoorbitalethmoid and Panfacial FracturesNasoorbitalethmoid (NOE) fractures are defined anatomically by a combination of injuries that involve the medial orbits, the nasal bones, the nasal processes of the frontal bone, and the frontal processes of the maxilla. If improperly treated, these injuries cause severe disfigurement and functional deficits from nasal airway collapse, medial orbital disruption, displacement of medial canthus of the eyelids, and nasolacrimal apparatus dysfunction. Telecanthus is abnormally wide separation of the medical canthus of the eyelids and is produced by a splaying apart of the nasomaxillary buttresses to which the medial can-thal ligaments are attached. NOE fractures require surgical man-agement with open reduction and internal fixation. At times, the thin bones are so comminuted that they are not salvageable and must be replaced or augmented using autologous bone grafts or synthetic materials. Each fragment is carefully identified, returned to a normal anatomic position, and fixed in place using plates and screws or interosseous wiring all bone fragments meticulously, potentially with primary bone grafting, to restore their normal configuration. The key to the successful repair of NOE fractures is to carefully reestablish the nasomaxillary buttress and to restore the normal points of attachment of the medial canthal ligaments.NOE fractures are typically caused by such extreme forces that they are frequently associated with intracranial injuries and multiple other facial bone fractures in a presentation referred to as a panfacial fracture. These may involve any combination of the fractures described previously. The challenge of these injuries is to reestablish normal relationships of key anatomic landmarks. A combination of salvable bone fragments, autolo-gous bone grafting, and synthetic materials accomplishes this.Posttraumatic Extremity ReconstructionThe primary goal in posttraumatic extremity reconstruction is to maximize function. When structural integrity, motor function, and sensation can be reasonably preserved, then extremity salvage may be attempted. Otherwise, severe injuries require amputation best performed following reconstructive surgery principals that set the stage for maximizing function with pros-thetics and minimizing chronic pain and risk of tissue break-down. Microvascular surgical techniques are an essential part of extremity trauma surgery, allowing replantation of amputated parts or transfer of vascularized bone and soft tissue when tis-sue in zone of injury cannot be salvaged. Soft tissue techniques combined with advances in bone fixation and regeneration with distraction have proven tremendous benefit for patients with severe limb-threatening extremity trauma. Current state-of-the-art techniques require multidisciplinary cooperation between orthopedic, vascular, and plastic surgeons as presented in the algorithm (Fig. 45-56). Reconstructive techniques include the use of vascularized bone, bone distraction techniques, external fixation, nerve grafts and transfers, composite tissue flaps, and functioning muscle transfers tailored to the given defect. The future promises further advances with routine application of vascularized composite allografts, engineered tissue replace-ments, and computer animated prosthetics controlled intuitively by patients via sensors that are placed on the amputation stump and able to detect impulses transmitted through undamaged peripheral nerves remaining in the extremity.Common causes of high-energy lower extremity trauma include road traffic accidents, falls from a height, direct blows, sports injuries, and gunshots. As with maxillofacial trauma, the first phase of care is activation of the advanced trauma life support protocols. The most common life-threatening consider-ations are airway maintenance, control of bleeding, and identi-fication of other injuries. Once the patient’s condition has been stabilized and life-threatening injuries managed, attention is directed to diagnosis and management of the extremity. Tetanus vaccine and antibiotics should be provided as soon as possible for open wounds.Systematic evaluation of the traumatized extremity helps to ensure no important findings are missed. Physical examina-tion to assess the neurovascular status, soft tissue condi-tion, and location of bone fractures forms the foundation of ordering imaging studies to provide details of bone and vas-cular injuries. Evidence of absent pulses is an indication to con-sider Doppler ultrasound examination followed by angiography to detail the exact nature of the injury. The blood supply must be immediately restored to devascularized extremities. Crush injuries might be associated with compartment syndrome, in which tissue pressure due to swelling in the constricted facial compartments exceeds capillary perfusion pressure and causes nerve and muscle ischemia. In the early stages of compartment syndrome, findings include pain on passive stretch of the com-partment’s musculature in a pale, pulseless extremity without evidence of direct vascular injury. Neurologic changes consist-ing of paresthesias followed by motor paralysis are late signs. Once recognized, decompressive fasciotomies must be per-formed as soon as possible to prevent permanent tissue loss. Compartment syndrome can be a late event after fracture reduc-tion and fixation (either internal or external), so the extremity must be reevaluated regularly in the early postoperative period. This is especially true in situations where there has been a period of ischemia prior to successful revascularization.Several scoring systems for extremity trauma severity have been suggested to aid in treatment planning. Open fractures can be classified according to a system devised by Gustilo and 7Brunicardi_Ch45_p1967-p2026.indd 200501/03/19 6:30 PM 2006SPECIFIC CONSIDERATIONSPART IIReconstructableKnee functionalAdequate soft tissueDirty woundDirty woundClean woundFoot availableFoot not availableClean woundInadequate soft tissueKnee irreparableUnreconstructableTraumaticbelow kneeinjuryAmputationLimbreconstruction/replantationDelayedclosurePrimaryclosureFoot filetfree flapParascapularfree flapImmediatefree flapDelayedfree flapPrimaryreconstructionBelow kneesalvageBelow kneesalvageAbove kneeamputationFigure 45-56. Algorithm of posttraumatic extremity reconstruction.colleagues. Grades I and II are open fractures with minimal soft tissue disruption. Grade III injuries most often require consider-ation of soft tissue reconstruction. Grade IIIA are open fractures with severe soft tissue injury but adequate soft tissues to repair. Grade IIIB involves a loss of soft tissue that will require some technique for tissue replacement. Grade IIIC involves a vascular injury requiring reconstruction. For the most severe injuries, the most important decision is whether to attempt extremity salvage or proceed with amputation. Patients with extensive fracture comminution, bone or soft tissue loss, wound contamination, and devascularization have a poor prognosis. Extremity salvage requires multiple operations and a prolonged period of rehabili-tation and physical therapy. The loss of plantar sensation histori-cally favored below-knee amputation, but this is no longer an absolute recommendation. A final decision to attempt salvage must be made within the context of comorbidities, socioeco-nomic considerations, patient motivation, and overall rehabilita-tive potential.The first step in surgical management is complete debride-ment of all devitalized tissue. Early one-stage wound coverage and bony reconstruction is generally advocated and should be performed jointly by extremity trauma orthopedic and plastic surgical teams.50 It is acceptable for reconstruction to be deferred briefly if the adequacy of debridement is certain. Negative pres-sure wound therapy is useful between debridement and defini-tive reconstruction to control the wound drainage and prevent bacterial contamination. When there is segmental bone loss, it is advisable to achieve soft tissue closure prior to performing osse-ous reconstruction. Preparation for later restoration of the bone requires steps to prevent the soft tissue from collapsing into the space where bone is needed. A common technique for this is to fill the space with antibiotic-impregnated beads or an antibiotic spacer at the time of soft tissue restoration until definitive bony reconstruction is possible. An external fixation may be needed, if there is segmental bone loss (Fig. 45-57A,B).The sequence for reconstruction is meticulous debride-ment of nonviable tissue, fracture reduction and stabilization, vascular repair if necessary, and finally restoration of the soft tissue coverage. A multidisciplinary team of specialists works together to perform these procedures in order to obtain the best outcomes. Orthopedic and plastic surgeons perform wound debridement. Orthopedic surgeons then reduce and stabilize the fractures. Vascular surgeons reconstruct damage major vessels. Finally, plastic and reconstructive surgeons perform soft tissue coverage. Ideally, each operating team completes their part of the procedure sequentially during the same anesthetic.Choices for soft tissue coverage of open fractures include split-thickness skin grafts, temporary skin substitutes fol-lowed later by skin grafting, local rotation flaps, or free tissue transfers. Selecting the most appropriate option depends on the quality of the local tissues and location of the soft tissue defect relative to the underlying fracture and fixation hard-ware. The guiding principle is to be certain that the source of tissue transferred into the defect is outside of the zone of injury. When flaps are selected, either fasciocutaneous or muscular flaps may be indicated depending on tissue avail-ability, wound bed contours, and surgeon preferences. Uneven wound surface contours are more reliably obliterated with a Brunicardi_Ch45_p1967-p2026.indd 200601/03/19 6:30 PM 2007PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-57A, B. An external fixation for segmental bone loss.Figure 45-58. A. Defect ulnar side of the forearm, with an external fixator. B. Propeller flap. C. Flap is inset. D. Six weeks post operation.ABpliable muscle flap. Fasciocutaneous flaps may provide more durable coverage in areas subject to abrasion or pressure from footwear, for example, on the foot or around the ankle. Some defects can be covered with flaps containing both skin and muscle if indicated. Ideal coverage for weight-bearing areas should be able to resist pressure and shear and provide sensa-tion. Split-thickness skin grafts are reasonable for coverage of exposed healthy muscle or soft tissue. Local flaps may be used to cover smaller defects as long as uninjured tissue is located nearby. These may be designed as traditional random or axial ABCDflaps, but the most advanced techniques are based on under-lying perforators that allow extremely versatile flap designs customized to the defect. These flaps are designed with a per-forating vessel at the base near to the defect and a long axis extending an equal distance opposite. The flap is elevated and rotated into the defect in a motion reminiscent of an airplane propeller, which gives rise to the designation “propeller flap” for this kind of reconstruction (Fig. 45-58A, defect ulnar side of the forearm, with an external fixator; Fig. 45-58B, propel-ler flap; Fig. 45-58C, flap is inset; Fig. 45-58D, 6 weeks after Brunicardi_Ch45_p1967-p2026.indd 200701/03/19 6:31 PM 2008SPECIFIC CONSIDERATIONSPART IIthe operation). The advantages of this technique are that it does not impair muscle function and it can often complete a complex reconstruction without the need for microvascular surgery.When requirements exceed the potential for skin grafts or local flaps, tissue must be transferred from distant sites. The reconstructive choices differ based on the anatomic location of the defect and the extent of damage. This is often the case for major injuries in the middle or lower third of the leg where bones are covered with thin soft tissue and less donor tissue is available. A traditional method is to obtain tissue by creating a pedicled flap from the opposite, uninjured extremity. Cross-leg flaps remain effective, but indications are limited to circum-stances where microsurgery is not possible or in young children who are less prone to risks associated with prolonged immobi-lization necessary for these flaps, such as joint stiffness or deep vein thrombosis. Free tissue transfer is the preferred alternative. The general principles of reconstructive microsurgery in lower extremity trauma are to select recipient vessels outside of the zone of injury, select donor tissue suitable for the defect with minimal risk of donor site morbidity, and ensure there is bone stability before reconstruction using either internal or external fixation. For example, a latissimus dorsi muscle flap provides a large amount of tissue for reconstruction, but loss of the latis-simus function can make it more difficult for the patient to use crutches for ambulation during rehabilitation. Muscle or fascio-cutaneous flaps each have a role in selected circumstances.51 Bone can also be added to help fracture repair.52 Free flaps can also be designed as “flow-through” flaps, which reconstruct missing segments of major vessels and provide soft tissue or bone coverage.53After wound healing, proper physical and/or occupational therapy and rehabilitation is essential for the best long-term out-comes. This often requires many months of consistent retrain-ing and conditioning in order to return to the functional status enjoyed by the patient before injury. Properly fitted orthotic appliances and footwear provide essential protection against pressure-related complications and can improve function. Late complications such as osteomyelitis may appear, evidenced by signs of infection months or even years after reconstruction. Very often this is caused by inadequate debridement at the time of initial surgery.Tumor locationPrimaryreconstructive optionSecondaryreconstructive optionLower-extremity bone sarcomacomposite resectionDistal femur/proximal tibiaPedicled gastrocnemius ±soleusDistally-based pedicledALT; anterior bipedicledfasciocutaneous flap; pedicledsural artery flap; free flapMid/distal tibiaPrimary closurePedicled gastrocneumius± soleus; propeller,keystone flaps; free flapProximal/mid-femurPrimary closurePedicled ALT;Pedicled rectusabdominis; free flapWhen limb salvage either is not possible or is not in the best interest of the patient, amputation is indicated. Maxi-mizing limb length, providing durable soft tissue coverage, and managing peripheral nerves to avoid chronic pain help to ensure good functional recovery using extremity prosthet-ics. Ideally, local tissues are used; however, when they are unavailable or inadequate, the amputated part can be a use-ful source of skin grafts or tissues for microvascular free transfers to the stump, which preserves length and avoids a more proximal amputation. Transected nerves from ampu-tation procedures can be managed using a technique called targeted muscle reinnervation (TMR). TMR surgery takes the transected peripheral nerves resulting from the amputation procedure, and a nerve transfer is then performed to freshly deinnervated motor nerves within the residual limb or stump. By performing these nerve transfers, the sensory and mixed-motor sensory nerves typically transected during amputation are given fresh motor nerves to rapidly reinnervate, which can directly aid in bioprosthetic function and improve pain control. The improvement in pain is a result of reducing phantom limb pain and symptomatic neuroma formation. This technique has shown to be a major advance over traditional traction neurec-tomy techniques, which often contribute to increased phan-tom and residual limb pain rates and a much higher chance of symptomatic neuroma formation compared to TMR.54Oncologic Reconstructive SurgeryOncology-related reconstructive surgery has broad applica-tions in specialty of plastic and reconstructive surgery. Solid tumors necessarily destroy normal tissues, and surgical treat-ment involves excising the tumor with a margin of uninvolved normal tissue, which adds to the extent of tissue loss. As is illustrated in the case of a lower extremity sarcoma, recon-structive strategies are meticulously designed as an algorithm for effective functional and cosmetic restoration (Fig. 45-59) . Chemotherapy and radiation have side effects and com-plications that can cause tissue loss, leading to functional and cosmetic deformities that can be improved with recon-structive surgery. The goal of comprehensive cancer treatment is to restore the patient to full health, which includes normal function and appearance.8Figure 45-59. Algorithm for effective functional and cosmetic restoration after resection of a lower extremity sarcoma.Brunicardi_Ch45_p1967-p2026.indd 200801/03/19 6:31 PM 2009PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Reconstructive surgery in the context of oncology has sev-eral distinctive aspects compared to the larger field of recon-structive surgery in general. The procedure must be highly reliable in order to avoid surgical complications that might interfere with adjuvant therapies.Breast ReconstructionBreast cancer is the most common malignancy besides skin can-cer in women and the second leading cause of cancer-related death for women in the United States. Breast reconstruction is an important part of comprehensive cancer treatment. A number of studies have shown that breast reconstruction, both imme-diate and delayed, does not impede standard oncologic treat-ment, does not delay detection of recurrent cancer, and does not change the overall mortality associated with the disease.46-48Preoperative counseling of the breast cancer patient regarding reconstruction options should include discussion of the timing and technique of reconstruction. It is important to ensure that the patient has realistic expectations of outcome and an understanding of the number of procedures that might be necessary to perform in order to obtain the best outcome. The plastic surgeon and surgical oncologist must maintain close communication to achieve optimal results.Delayed breast reconstruction occurs any time after the mastectomy is performed, usually 3 to 6 months after the opera-tion, depending on the patient’s circumstances and reasons for not electing immediate reconstruction. Although good out-comes can be obtained, it is more difficult to achieve a result that is similar to the preoperative breast shape and size because of established scarring of the chest wall. Nevertheless, it is a good option for patients who are undecided or not candidates for immediate reconstruction because of advanced disease or comorbidities.Immediate reconstruction is defined as initiation of the breast reconstructive process at the time of the ablative sur-gery. Patients are considered candidates for immediate recon-struction who are in general good health and have stage I or stage II disease determined primarily by the size and location of the tumor. There are selected exceptions, such as when an extensive resection requires chest wall coverage. Breast recon-struction might be performed in these cases, but it is really incidental to achieving chest wall coverage. Disadvantages of immediate reconstruction include the potential delay of adju-vant therapy in the event of postoperative complications. Also, if there is uncertainty regarding the need to adjuvant radiation therapy, decision-making regarding immediate reconstruction is a challenge. Breast reconstructions by all techniques are adversely affected by radiation therapy, and many surgeons feel reconstruction should be delayed until at least 6 months after treatment.Once the patient chooses to have immediate reconstruction, she must select a reconstructive technique. In patients selected for breast conservation, oncoplastic tissue rearrangement can be performed to minimize adverse effects of lumpectomy on breast appearance. For patients electing total mastectomy there are essentially three options: (a) tissue expansion followed by breast implant placement, (b) combined tissue flaps with breast implants, and (c) autologous tissue flaps only. After examining the patient, the surgeon then should describe those methods for which the patient is a satisfactory candidate. The patient should then be encouraged to choose based on her goals and an under-standing of the advantages and disadvantages of each technique.Oncoplastic Breast ReconstructionBreast conservation therapy (BCT) consists of excision of the breast tumor with a surrounding margin of normal tissue com-bined with postoperative whole-breast irradiation. Although the overall survival for properly selected patients is shown to be comparable to total mastectomy and reconstruction, the breast can often be distorted and unnatural appearing after treatment. The area of the lumpectomy may create a depression with con-tour deformity, and contraction of the lumpectomy space over time can distract the nipple out of alignment and create an asym-metry with the contralateral breast. This is especially true for women with small breasts in whom a high percentage of breast volume is removed with the lumpectomy.Oncoplastic surgery refers to the set of techniques devel-oped to lessen breast deformity from a partial mastectomy. One of the most common methods of minimizing adverse effects on breast appearance of is to rearrange the skin, parenchyma, and nipple location of the breast at the time of tumor extirpation using surgical techniques developed for breast aesthetic surgery. This procedure involves elevating the skin from the underlying glandular tissue, mobilizing the nipple on a vascular pedicle, and preserving as much of the vascularized glandular tissue as possible. After lumpectomy, the tissue is rearranged to shift glandular tissue into the defect and redrape the skin and nipple onto the new breast mound. After healing and completion of radiotherapy, a contralateral conventional mastopexy or breast reduction can be performed on the contralateral side to achieve symmetry.Implant-Based ReconstructionImmediate breast reconstruction based entirely on the use of implanted devices is initially the most expedient technique. Sometimes it is possible to place a full-size implant at the time of mastectomy when the breasts are small (volume <400 cc) and the patient is a young nonsmoker with good chest wall muscula-ture. In most patients, however, a period of tissue expansion is required. The tissue expander is inserted beneath the pectoralis major and serratus anterior muscles at the time of the mastec-tomy and partially inflated. Alternatively, the tissue expander can be placed only under the pectoralis major muscle or even completely on top of the chest wall muscles then covered with acellular dermal matrix directly beneath the mastectomy skin flaps. Total muscle coverage is the traditional approach, but these alternatives may be suitable only for well-selected patients. Expansion usually requires 6 to 8 weeks to complete, and an implant exchange is performed typically 3 months later. The advantages of this technique are that it involves minimum additional surgery at the time of the mastectomy, has a recovery period essentially the same of that of the mastectomy alone, and creates no additional scarring. The disadvantages of this technique are the length of time necessary to complete the entire reconstruction (up to 1 year), the requirement for a minimum of two operative procedures, and a less predictable cosmetic result due to complete reliance on devices. Also, the patient awak-ens from surgery without a full-size breast and during the time of expansion must accept a breast of abnormal size and shape. Although the final shape of the breast may be satisfactory, it may lack a natural consistency due to the superficial placement of the device, especially when saline-filled implants are used. Finally, breast implants may develop late complications such as capsular contracture, infection, or extrusion. This method is ideal for a slender, small-breasted woman with minimal ptosis Brunicardi_Ch45_p1967-p2026.indd 200901/03/19 6:31 PM 2010SPECIFIC CONSIDERATIONSPART IIwho wish to avoid additional scarring and time for convales-cence. It may also be suitable for women undergoing bilateral reconstruction because symmetry is more easily achieved if both breasts are restored using the same technique. Women who elect this type of immediate reconstruction must understand that breast implants do not have an unlimited service life and that additional surgery will be likely be required to replace the breast implant at some time in the future.Tissue Flaps and Breast ImplantsThe latissimus dorsi musculocutaneous flap is the most com-mon transfer used in combination with breast implants. Other flaps may also be used, depending on patient preference and tissue availability. The principal advantage in using a tissue flap is immediate replacement of missing skin and soft tissue. In cases where there is already adequate breast skin, then a muscle only may be transferred to provide suitable implant coverage. The implant allows the final breast volume to be accurately reproduced to match the contralateral breast or, in bilateral reconstruction, adjust the breast size according to the patient’s desires. The advantages of this technique are that the implant is protected by abundant tissue, a period of tissue expansion is avoided, and the full benefit of preserving the breast skin is realized to achieve a natural-appearing breast. The disadvantage of this technique compared to implants alone is that it results in additional scarring and requires a longer period of recovery. For many patients, this approach represents an acceptable com-promise between implant-only reconstruction and autologous tissue reconstruction, incorporating some of the advantages and disadvantages of each.Autologous Tissue ReconstructionImmediate reconstruction using only autologous tissue is the most elaborate method of breast reconstruction but consis-tently yields the most durable, natural-appearing results. Breast implants cannot match the ability of the autologous tissue to conform to the breast skin and envelop and simulate natural breast parenchyma. The most useful flap is the transverse rec-tus abdominis musculocutaneous (TRAM) flap, although other ABPreoperativePostoperativeImmediate right DIEP FlapFigure 45-60. A. Preoperation right breast cancer. B. After mastectomy and immediate reconstruction with a DIEP flap.donor areas are also possibilities in selected cases. Autologous reconstruction is usually the best option in patients who require adjuvant radiation therapy.55The TRAM flap may be transferred to the chest using a variety of methods, depending on the circumstances of the individual patient. As a pedicled flap, it is transferred based on the superior epigastric vessels and tunneled beneath the skin to reach the mastectomy defect. As a free flap, it is based on the inferior epigastric vessels that are revascularized by micro-vascular anastomosis to vessels on the chest wall nearby the mastectomy defect. Often the microvascular technique using the deep inferior epigastric perforator (DIEP) flap is preferred because there is less risk of partial flap loss or localized areas of fat necrosis due to a more reliable blood supply (Fig. 45-60A, before operation on right breast; Fig. 45-60B, after mastectomy and immediate reconstruction with a DIEP flap). In immediate reconstruction with an axillary dissection, the axillary vessels are completely exposed and free of scar following the lymph node dissection in patients without previous surgery and radiation. In women being treated for recurrence with previous axillary sur-gery, the axillary vessels are less reliable, and plans should be made for the possibility of using the internal mammary vessels. The internal mammary vessels have become the most common recipient vessels for free tissue transfer in breast reconstruction in the contemporary era of sentinel lymph node biopsy that is used as a technique to perform axillary lymph node dissection in a more limited number of patients. Regardless of the technique used to transfer the tissue, the donor site is closed in a similar manner as an abdominoplasty, by repairing the abdominal wall and advancing the upper abdominal skin downward. The umbi-licus is preserved on its vascular stalk brought to the surface through a small incision immediately above its location on the abdominal wall (Fig. 45-61A,B). Other donor sites including the buttock may be used in transferring the skin and fat supplied by the inferior gluteal artery perforator (IGAP) or the superior gluteal perforator as the main blood supply.The advantages of using this technique are complete res-toration of the breast mound in a single stage, avoidance of Brunicardi_Ch45_p1967-p2026.indd 201001/03/19 6:31 PM 2011PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-61A, B. Preand postoperative images following IGAP flap.Figure 45-62A, B. Preand postoperative images following IGAP flap, nipple reconstruction, and tattooing.ABPreoperativePostoperativeDelayed right IGAP Flappotential problems associated with breast implants, and con-sistently superior cosmetic results. The disadvantages are the magnitude of the operation, additional scarring, risks of devel-opment of abdominal bulges, and a longer period of convales-cence. Although the initial cost is greater, over the long term the total cost appears to be less because of less need for second-ary procedures to exchange implants, achieve suitable cosmetic appearance, or care for implant-related problems. This is the best operation for patients who want the most natural breast res-toration possible and who are less concerned about the amount of surgery, scarring, and recovery period.Accessory ProceduresAfter complete healing of the breast mound from the initial stages of reconstruction, refinements and accessory procedures may be performed at a later time to optimize the natural appear-ance of the reconstructed breast. These may include soft tissue ABBefore nipple reconstructionPostoperativeBilateral IGAP Flapmodifications of the breast mound revision, repositioning or the breast implant, scar revisions, autologous fat grafting, and nip-ple-areola complex reconstruction. A variety of methods have been described for nipple reconstruction. They are all based on local tissue rearrangements or skin grafts to create a projecting piece of skin and subcutaneous tissue that simulates the natural nipple (Fig. 45-62A,B). The pigmentation of the areola may be simulated with tattooing of colored pigments selected to match the normal coloration of the patient’s original anatomy.Trunk and Abdominal ReconstructionIn the torso, as in most areas of the body, the location and size of the defect and the properties of the deficient tissue determine choice of reconstructive method. A distinction is made between partial-thickness and full-thickness defects when deciding between grafts, flaps, synthetic materials, or a combina-tion of techniques. Unlike the head and the lower leg, the trunk 9Brunicardi_Ch45_p1967-p2026.indd 201101/03/19 6:31 PM 2012SPECIFIC CONSIDERATIONSPART IIharbors a relative wealth of regional transposable axial pattern flaps that allow sturdy reconstruction, only rarely requiring dis-tant free tissue transfer. Indeed, the trunk serves as the body’s arsenal, providing its most robust flaps to rebuild its largest defects.The chest wall is a rigid framework designed to resist both the negative pressure associated with respiration and the positive pressure from coughing and from transmitted intra-abdominal forces. Furthermore, it protects the heart, lungs, and great vessels from external trauma. Reconstructions of chest wall defects must restore these functions. When a full-thick-ness defect of the chest wall involves more than four, this is usually an indication for the need for rigid chest wall recon-struction usually using synthetic meshes made of polypropyl-ene, polyethylene, or polytetrafluoroethylene, which may be reinforced with polymethylmethacrylate acrylic. In contami-nated wounds, biologic materials are preferred, such as acel-lular dermal matrix allografts. For soft tissue restoration, the pectoralis major muscle is commonly used as a pedicled flap for coverage of the sternum, upper chest, and neck. It may be mobilized and transferred on a vascular pedicle based on the pectoral branch of the thoracoacromial artery or a vascular supply based on perforators from the internal mammary ves-sels. Either flap design is useful in covering the sternum after dehiscence or infection occurring as a complication of median sternotomy or with sternal resection for tumor extirpation. For the lower third of the sternum, a rectus abdominis muscle flap based on the superior epigastric vessels or the deep inferior epigastric vessels is useful. If based on the inferior blood sup-ply, it must be transferred as a free flap with recipient vessels outside of the zone in injury. The latissimus dorsi musculocu-taneous flap is useful for chest wall reconstructions in places other than the anterior midline. Similar to the pectoralis major muscle, it may be transferred on either a single blood supply that is based on the thoracodorsal vessels from the subscapular system or on vessels perforating from deeper source vessels near to the posterior midline. The serratus anterior muscle can be included on the same vascular pedicle to further increase its surface area. Finally, the trapezius muscle flap, based on the transverse cervical vessels, is generally used as a pedicled flap to cover the upper midback, base of neck, and shoulder. The superior portion of the muscle along with the acromial attach-ment and spinal accessory nerve must be preserved to maintain normal shoulder elevation function.The abdominal wall also protects the internal vital organs from trauma, but with layers of strong torso-supporting mus-cles and fascia rather than with osseous structures. The goals of reconstruction are restoration of structural integrity, prevention of visceral herniation, and provision of dynamic muscular sup-port. Although abdominal wall defects may occur in association with oncologic tumor resections, the most common etiology is fascial dehiscence after laparotomy. When a reconstruction plan is being formulated, careful physical examination and review of the medical history will help prevent selection of an otherwise sound strategy that, because of previous incisions and trauma, is destined for failure.Superficial defects of the abdominal skin and subcutane-ous tissue are usually easily controlled with skin grafts, local advancement flaps, or tissue expansion. Defects of the under-lying musculofascial structures are more difficult to manage. The abdominal wall fascia requires a minimal-tension closure to avoid dehiscence, recurrent incisional hernia formation, or abdominal compartment syndrome. Prosthetic meshes are frequently used to replace the fascia in clean wounds and in operations that create myofascial defects. When the wound is contaminated, as in infected mesh reconstructions, enterocuta-neous fistulas, or viscus perforations, prosthetic mesh is avoided because of the risk of infection. The technique of component separation procedure has proven beneficial for closing large midline defects with autologous tissue and avoiding prosthetic materials. This procedure involves advancement of bilateral flaps composed of the anterior rectus fascia rectus and oblique muscles after lateral release. Midline defects measuring up to 10 cm superiorly, 18 cm centrally, and 8 cm inferiorly can be closed using this method.Techniques based on rearranging and reinforcing abdomi-nal wall elements might be inadequate for extremely large or full-thickness abdominal wall defects. For these defects, regional flaps or free flaps are required. Pedicled flaps from the thigh are useful, such as the tensor fasciae latae pedicled flap, based on the ascending branch of the lateral circumflex femoral vessels, or the anterolateral thigh flap, based on the descending branch of the lateral circumflex vessels. Bilateral flaps might be required.Pelvic ReconstructionAnother important area for consideration of reconstructive surgical procedures is in the perineum.56 The perineal region is part of the specialized part of the trunk that supports the pelvic outlet lying between the pubic symphysis, the coccyx, the inferior rami of the pubis, and the ischial tuberosities. Sup-port is provided by the urogenital diaphragm, the deep and superficial fasciae, and the skin. Specialized anatomic struc-tures pass through the perineum. Posteriorly is the anus, and anteriorly are the genitalia and urethra. Treatment of tumors involving this area often require a combination of surgery and radiation. The resulting loss of tissue and healing impairment coupled with the nonyielding nature of the bony pelvic outlet can result in unique reconstructive requirements that often are best addressed with tissue transfer. The reconstruction must achieve wound healing and restore support to the pelvic con-tents, accommodate urinary and bowel function, and finally restore the penis in men and the vagina and vulva in women. Local flaps, regional flaps, or free tissue transfer all have pos-sible application depending on the extent of the resection and local tissue compromise.Other Clinical CircumstancesBesides trauma and cancer, other etiologies can cause functional and cosmetic deformities due to tissue impairment for which reconstructive surgery has value. These include pressure sores, diabetic foot ulcers, and lymphedema.Pressure Sores. A pressure ulcer is defined as tissue injury caused by physical pressure applied to the tissues from an exter-nal source at a magnitude that exceeds capillary perfusion pres-sure. Prolonged tissue ischemia leads to local tissue necrosis. Pressure ulcers tend to occur in people debilitated by advanced age, chronic illness, poor nutrition, prolonged immobilization, motor paralysis, or inadequate sensation. Spinal cord injury patients are especially prone to developing pressure sores. Pres-sure sores can also occur in healthy individuals who undergo prolonged surgical operations and parts of the body support-ing the weight of the patient on the operating table (e.g., the occiput, the sacral prominence, the heels of the feet) are improp-erly padded.57Brunicardi_Ch45_p1967-p2026.indd 201201/03/19 6:31 PM 2013PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Pressure sores are an important contributor to morbidity in patients suffering from limited mobility. Most can be prevented by diligent nursing care in an attentive, cooperative patient. Preventing pressure ulcers requires recognition of susceptible and utilizing appropriate measures to reduce pres-sure on areas of the body at risk. This involves frequent position changes while sitting or supine and the use of pressure-reducing medical equipment such as low-air-loss mattresses and seat cushions and heel protectors. Malnourishment, poor glucose control in diabetics, poor skin hygiene, urinary or bowel incon-tinence, muscle spasms, and joint contractures all increase the risk of pressure sore formation. Mitigating these factors is essential before embarking on a complex reconstructive treat-ment plan. Successful reconstruction also requires a cooperative and motivated patient with good social support.Surgical treatment of pressure ulcers is based on wound depth. The staging system is summarized in Fig. 45-63.58 Stage I and II ulcers are treated nonsurgically with local wound care and interventions to relieve pressure on the affected area. Patients with stage III or IV ulcers should be evaluated for surgery. Important features for preoperative assessment include the extent of soft tissue infection, the presence of con-taminated fluid collection or abscess, osteomyelitis, and com-munication with deep spaces (e.g., joint space, urethra, colon, or spinal canal). Laboratory blood tests and imaging studies help establish whether soft tissue or bone infection is present. Plain radiographs are usually adequate to rule out osteomyeli-tis; CT and MRI are helpful when plain films are equivocal. Necrotic tissue and abscesses should be surgically debrided without delay to prevent or treat systemic sepsis. Bone must also be excised if it appears involved, as evidenced by poor bleeding, softness, or frank purulence. Patients with high spinal cord injuries at or above the level of the fifth thoracic vertebra may experience sudden extreme elevation of blood pressure, an 10Stage 1Observable pressure related alteration of intact skin whose indicators as compared to the adjacent or opposite area of the body may include changes in one or more of the following: skin temperature (warmth or coolness), tissue consistency (firm or boggy feel), and/or sensation (pain, itching). The ulcer appears as a defined area of persistent redness in lightly pigmented skin, whereas in darker skin tones the ulcer may appear with persistent red, blue of purple hues.Stage 2Partial thickness skin loss involving epidermis and/or dermis. The ulcer is superficial and presents clinically as an abrasion, blister, or shallow crater.Stage 3Full thickness skin loss involving damage or necrosis of subcutaneous tissue that may extend down to but not through underlaying fascia. The ulcer presents clinically as a deep crater with or without undermining of adjacent tissue.Stage 4Full thickness skin loss with extensive destruction, tissue necrosis or damage to muscle, bone, or supporting structures (for example, tendon or joint capsule). Undermining and sinus tracts may also be associated with Stage 4 pressure ulcers.ABCD Figure 45-63. The staging system for pressure sores.autonomic-mediated event called hyperreflexia. This condition must be immediately recognized and treated to prevent intra-cranial and retinal hemorrhage, seizures, cardiac irregularities, and death.After adequate debridement, the pressure ulcer can be treated nonsurgically in patients who have shallow wounds with healthy surrounding tissues capable of healing secondarily with offloading pressure. Nonsurgical treatment is also best in patients for whom surgery is contraindicated because of previ-ous surgery or comorbidities. For surgical candidates, primary closure is rarely performed because an inadequate amount of quality surrounding tissue prevents closure without tension, making the repair predisposed to failure. Split-thickness skin grafting can be useful for shallow ulcers with well-vascularized wound beds on which shear forces and pressure can be avoided after repair, a rare circumstance in most patients with pressure ulcers.The mainstay of surgical treatment is tissue transfer fol-lowing several guiding principles. Local muscle or musculocu-taneous flaps are suitable for areas of heavy contamination and complex wound surface contours. Durability requires the ability to consistently off-load of the area of reconstruction postopera-tively. Fasciocutaneous flaps afford more durable reconstruc-tion when off-loading is not possible. The anatomic location is an important determinant of flap choice. Once a donor site is selected, a flap of adequate size is designed and transferred in a way that avoids suture lines in the area under pressure. Large flaps also permit readvancement if the patient experiences a recurrent ulcer in the same area. Sacral pressure sores may be managed with fasciocutaneous or musculocutaneous flaps based on the gluteal vessels. Ischial pressure sores may be man-aged with gluteal flaps or flaps transferred from the posterior thigh, such as the posterior thigh flap based on the descend-ing branch of the inferior gluteal artery. Trochanteric ulcers Brunicardi_Ch45_p1967-p2026.indd 201301/03/19 6:31 PM 2014SPECIFIC CONSIDERATIONSPART IIFigure 45-64. Flap reconstruction of pressure ulcers. Top row: Preoperative and 1-month postoperative photos of a stage IV sacral decubitus ulcer treated with a myocutaneous gluteus maximus flap. Bottom row: Preoperative and 1-month postoperative photos of a stage IV trochan-teric ulcer treated with a myocutaneous V-Y tensor fasciae latae flap.may be managed with musculocutaneous flaps based on the tensor fasciae latae, rectus femoris, or vastus lateralis muscles (Fig. 45-64). The obligatory loss of motor function associated with using these flaps adds no additional functional impairment in patients already paralyzed as a result of strokes or spinal cord injuries.Proper postoperative care after flap reconstruction of pressure ulcers is critical for success. Low-pressure, air fluid-ized beds help to off-load the affected area and prevent new areas of involvement during the first 7 to 10 days of healing. Other important measures are adequate nutritional support and medications to prevent muscle spasms. Careful coordination with patient care providers is planned preoperatively in order to avoid gaps in care that can lead to early recurrent ulceration. Care of the pressure ulcer patient is a labor-intensive process that requires attention to detail by the surgeon, nurses, thera-pists, caseworkers, and family.Diabetic Foot Ulceration. The pathophysiology of primary diabetic lower limb complications has three main components: (a) peripheral neuropathy (motor, sensory, and autonomic), (b) peripheral vascular disease, and (c) immunodeficiency. Altered foot biomechanics and gait caused by painless col-lapse of ligamentous support, foot joints, and foot arches change weight-bearing patterns. Blunted pain allows cutane-ous ulceration to begin. With breakdown of the skin barrier function, polymicrobial infections become established. Bac-terial invasion is often fostered by poor blood supply due to peripheral vascular disease coupled with microangiopathy. Finally, local host defenses may be less effective in resisting bacteria because of poor blood supply and impaired cellular function. Cutaneous ulcerations may progress painlessly to involve deeper soft tissues and bone. The ultimate endpoint of this process is such severe tissue damage that extremity amputation is the only treatment remaining. More than 60% of nontraumatic lower extremity amputations occur in diabetics. The age-adjusted lower extremity amputation rate in diabet-ics (5.0 per 1000 diabetics) was approximately 28 times that of people without diabetes (0.2 per 1000 people).59 Improved patient education and medical management, early detection of foot problems, and prompt intervention play important roles in improving the chances of limb preservation.60The best approach to managing diabetic patients with lower extremity wounds is to involve a multidisciplinary team composed of a plastic and reconstructive surgeon, a vascular surgeon, an orthopedic surgeon, a podiatrist, an endocrinolo-gist specializing in diabetes, a nutritionist, and a physical or Brunicardi_Ch45_p1967-p2026.indd 201401/03/19 6:31 PM 2015PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45occupational therapist. This brings together the greatest level of expertise to manage bone and soft tissue issues as well as the underlying disease and medical comorbidities. Treatment begins with rigorous control of blood glucose levels and a thor-ough assessment of comorbidities. In addition to careful detail-ing of the extent of the wound and the tissues involved, physical examination documents sensory deficits and vascular status. Plain radiographs, MRI, bone scintigraphy, and angiography or duplex Doppler ultrasound imaging may be indicated. A patient with significant vascular disease may be a candidate for lower extremity endovascular revascularization or open bypass.61 Nerve conduction studies may diagnose surgically reversible neuropathies at compressive sites and aid in decisions about whether to perform sensory nerve transfers to restore plantar sensibility.60 Antibiotic and fungal therapies should be guided by tissue culture results.Surgical management starts with debridement of devital-ized tissues. Methods of wound closure are dictated by the extent and location of the remaining defect. Negative pressure wound dressings may be appropriate for superficial defects in an effort to allow secondary healing or as a temporizing measure until definitive wound closure can be achieved. Skin grafts might be indicated at times but cannot be expected to provide durable cov-erage in weight-bearing or high-shear areas. Local and regional flaps can be considered if the extremity is free of significant occlusive peripheral vascular or combined with vascular bypass. Microvascular free tissue transfers are appropriate when defects are large or when local flaps are not available. Combination lower extremity bypass and free flap coverage has proved benefi-cial for the treatment of the diabetic foot in terms of healing and reduction of disease progression (Table 45-6). Consultation with a podiatrist or an orthopedic surgeon who specializes in foot and ankle problems can be considered to improve foot biomechanics and manage bony prominences that act as pressure points on the soft tissue to reduce the risk of recurrent ulceration. Proper foot-wear (including orthotic devices and off-loading shoe inserts), hygiene, and toenail and skin care are essential.60Lymphedema. Lymphedema is the abnormal accumulation of protein-rich fluid in the interstitial spaces of the tissues. It is a complex disorder with both congenital and acquired causes. No universally effective remedy has been devised, but a variety of treatment methods including reconstructive surgery have been effective in carefully selected patients.It is important to be familiar with the fundamentals of lymph physiology in order to understand the rationale for the various forms of lymphedema treatment. Lymph fluid is formed at the capillary level where there is a net outflow of fluid and serum proteins from the intravascular space into the intersti-tium. In the average adult, this amounts to approximately 3 liters of fluid daily. Open-ended lymph capillaries collect this fluid where the lymphatic endothelial cells form loose intercellular connections that freely allow fluid to enter. From here, the net-work of specialized vascular structures gathers the extravasated fluid and transports it back into central circulation. The system is a high-volume transport mechanism that clears proteins and lipids from the interstitial space primarily by means of differ-ential pressure gradients. Lymph fluid enters the lymph vessels driven by colloid and solute concentration gradients at the capil-lary level. Flow is sustained in the larger vessels through direct contractility of the lymph vessel walls and by indirect compres-sion from surrounding skeletal muscle activity. Throughout the system, one-way valves prevent reverse flow. The lymphatic vessels course throughout the body alongside the venous sys-tem, into which they eventually drain via the major thoracic and cervical ducts at the base of the neck.Under normal conditions, there is a balance between fluid formation and lymph transport capacity. With congenital hypo-plasia or acquired obstruction, there is a reduction in transport capacity resulting in accumulation of fluid and protein in the interstitium. Localized fluid stagnation, hypertension, and valvu-lar incompetence further degrade transport capacity and acceler-ate lymph fluid accumulation edema. Dissolved and suspended serum proteins, cellular debris, and waste products of metabolism elicit an inflammatory response with associated with fibrovas-cular proliferation and collagen deposition leading to firm, non-pitting swelling characteristic of chronic, long-standing edema. Lymphoscintigraphy can help detail the lymphatic anatomy and quantify lymphatic flow. MRI can provide additional informa-tion about the larger caliber lymphatic vessels, possibly helping to identify specific points of obstruction.Primary lymphedema is caused by congenital hypopla-sia and is classified clinically based on the age of the affected individual when swelling first appears. Lymphedema present at birth is an autosomal dominant disorder sometimes referred to as Milroy’s disease. Lymphedema praecox occurs near the time of puberty but can appear up to age 35. This form tends to occur in females and usually affects the lower extremity. It accounts for more than 90% of cases. Finally, lymphedema tarda appears after the age of 35 years and is relatively rare.Secondary lymphedema is the acquired form of the dis-order and is more common than congenital causes. Worldwide the most common etiology is parasitic infestation with filarial, a highly specialized nematode transmitted by blood-eating insects Table 45-6Some reconstructive options for the diabetic footAREA OF DEFECTRECONSTRUCTIVE OPTIONSForefootV-Y advancementToe island flapSingle toe amputationLisfranc’s amputationMidfootV-Y advancementToe island flapMedial plantar artery flapFree tissue transferTransmetatarsal amputationHindfootLateral calcaneal artery flapReversed sural artery flapMedial plantar artery flap ± flexor digitorum brevisAbductor hallucis muscle flapAbductor digiti minimi muscle flapFree tissue transferSyme’s amputationFoot dorsumSupramalleolar flapReversed sural artery flapThinner free flaps (e.g., temporoparietal fascia, radial forearm, groin, thinned anterolateral thigh flaps)Brunicardi_Ch45_p1967-p2026.indd 201501/03/19 6:31 PM 2016SPECIFIC CONSIDERATIONSPART IIFigure 45-65. Algorithm for lymphedema management.YesNoYesNoYesNoSymptomatic LymphedemaAmenable to physiologic lymphatic procedures?Suitable lymphatic vessels on MRL or ICGL for LVA?Secondary to surgery and/or XRT?LVA ±VLNTLiposuction ±excisionLVAonlyVLNTonlyConsider furtherLVA or VLNTInadequate response?Secondary to surgery and/or XRT?Severe functional impairment?Excess soft tissue? Skin changes?Yes• Responsive to nonsurgical therapy, but symptoms plateaued or worsening• Significant pitting edemaNo• Minimal or no improvement with nonsurgical therapy• Minimal to absent pitting edemafound mostly in developing countries. In nonaffected areas of the world, the most common cause of secondary lymphedema is regional lymphatic vessel destruction associated with can-cer treatment. It often occurs in the upper extremity of women treated with surgery and radiation therapy for breast cancer. In the lower extremities, it is associated with neoplasms treated with inguinal or retroperitoneal lymph node dissection.The goal of lymphedema treatment is to minimize func-tional and cosmetic disability caused by chronic enlargement and to prevent infection of the involved extremity. The foun-dations of management are patient education and nonsurgical interventions, which include limb elevation, external compres-sive garments and devices, and manual lymphatic massage, sometimes referred to as complex decongestive physiother-apy. The patient must use protective gloves or garments when engaged in activities that might cause minor skin injury, such as gardening, smoking cigarettes, and cooking. Interstitial lymph fluid is prone to infection. When signs of infection appear, prompt treatment that often includes hospitalization with intravenous antibiotics is essential to prevent severe infection and further destruction of remaining lymphatic sys-tem and worsening of lymphedema.When nonsurgical methods fail, surgery can be consid-ered as a treatment option. Surgical operations for lymphedema are either ablative, designed to remove excess lymphedematous tissues, or reconstructive, intended to restore lymph function and improve transport capacity. These choices are presented in Fig. 45-65. Ablative procedures range from minimally invasive measures such as suction lipectomy to complete excision of skin and subcutaneous tissue down to muscle fascia with split-thickness skin grafting. Contemporary reconstructive procedures establish new connections between the venous and lymphatic systems somewhere proximal to the point of obstruction. A variety of methods have been described, including lympholymphatic, lym-phovenous, lymph node venous anastomoses, and vascularized lymph node transfer. Each of these procedures can yield suc-cess, and it has become clear that patient selection is perhaps the most important aspect of surgical care because the patient must be matched to the procedure most likely to yield improved con-trol of swelling and prevent infection. Reconstructive surgery is not generally a cure for the condition, but rather it is intended to ease management challenges and reduce the risks of infection. After surgery, continued use of nonsurgical techniques is still required for optimal results.AESTHETIC SURGERY AND MEDICINEAesthetic, or cosmetic, surgery is an important part of the spe-cialty of plastic surgery. The American Medical Association defines cosmetic surgery as “surgery performed to reshape normal structures of the body to improve the patient’s appear-ance and self-esteem.” It is a natural extension of surgical tech-niques for tissue modification traditionally developed for other reasons. Because aesthetic surgery primarily relates to personal appearance and attractiveness and not a particular disease pro-cess, there has been a tendency to dismiss the health value of Brunicardi_Ch45_p1967-p2026.indd 201601/03/19 6:31 PM 2017PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45aesthetic surgery. Nevertheless, personal appearance plays an important role in psychosocial health. Physical attractiveness plays a role in the marketplace with well-documented influence on employment opportunities, advancement, and earnings.62 The multibillion industry of products and services designed to opti-mize appearance, which spans a wide spectrum between simple cosmetics to elaborate surgical procedures, bears testament to the perceived value by the general population.Important work demonstrates a link between aesthetic sur-gery and psychosocial health. Surgery performed on the face,63 nose,64 ears,65 breast,66 and body67 can positively affect quality of life on multiple scales. There is a clear association between one’s personal appearance and success in the marketplace. As the primary benefits of aesthetic surgery are related to the psy-chosocial outcomes, it is important to assess the state of psycho-logical health prior to offering aesthetic surgery. A variety of preoperative psychological comorbidities can adversely affect outcomes, most notably a syndrome known as body dysmor-phic disorder,68 present in individuals who manifest a preoccu-pation with one or more perceived defects or flaws in physical appearance that are not observable or appear slight to others.69 Performing a surgical procedure to modify personal appearance in such an individual is associated with a high risk of a poor outcome.It is important for all surgeons to have an appreciation of the methods of patient evaluation, surgical techniques, and typical outcomes that might be anticipated in aesthetic sur-gery. Patients seek aesthetic surgery when they are unable to achieve a personal standard of physical appearance without sur-gical modification of various body parts that most affect their appearance. This is especially true for features that are visible in public and strong determinants of appearance, such as the face, breasts, abdomen, and buttocks. The etiology of undesir-able characteristics of form or skin quality can be familial or acquired through natural processes of aging, injury, cancer, or degeneration. Unwanted changes in appearance that result from these processes may still fall within the range of normal appearance yet fall short of the patient’s personal aesthetic ideal. Patient assessment requires an understanding of personal and cultural ideals of appearance. The surgeon must be knowledge-able about the various surgical and nonsurgical techniques that might be considered to address the patient’s concerns.In practical terms, there are both reconstructive and cos-metic elements to almost every plastic surgery case, and the def-inition of “normal” structure is sometimes very subjective and difficult to quantify. Nevertheless, there are patients for whom it is a priority to make surgical changes to their bodies in the clear absence of a functional deformity. Aesthetic surgery patients present a unique challenge to the plastic surgeon because the most important outcome parameter is not truly appearance, but patient satisfaction. Optimally, a good cosmetic outcome will be associated with a high level of patient satisfaction. For this to be the case, the plastic surgeon must do a careful analysis of the patient’s motivations for wanting surgery, along with the patient’s goals and expectations. The surgeon must make a rea-sonable assessment that the improvements that can be achieved through surgery will meet the patient’s expectations. The sur-geon must appropriately counsel the patient about the magni-tude of the recovery process, the exact location of scars, and potential complications. If complications do occur, the surgeon must manage these in a manner that preserves a positive doctor-patient relationship.Figure 45-66. Incisions for cervicofacial rhytidectomy.Aesthetic Surgery of the FaceA thorough evaluation of the patient who presents for facial aes-thetic surgery begins with acquiring a clear understanding of the patient’s primary concern regarding appearance. Examination focuses on that region but takes into consideration overall facial appearance that might be contributing to the patient’s concerns but of which the patient is unaware. The skin quality is care-fully assessed as well as the location, symmetry, and position of each critical feature of facial appearance such as scalp hairline, forehead length, eyebrow shape and position, eyelid configu-ration, nasal proportions, and shape of the lips. Overall facial proportions are assessed, such as the prominence of the orbital rims and malar areas, the chin projection, and contours along the margin of the mandible. An appropriately performed facelift can yield an aesthetically pleasing result (Fig. 45-66).A variety of procedures have been described for modify-ing facial appearance. Nonsurgical interventions topical treat-ments of the skin surface include chemical and laser facial peels. Injections of biocompatible materials made of processed biologic proteins (e.g., collagen, hyaluronic acid) or synthetic materials such as polymethylmethacrylate can modify the depth of facial wrinkles and fullness of facial structures such as the lips. Appearance can also be modified using neuromodulators to block facial muscle function to reduce undesirable move-ments of facial landmarks or deepening of facial wrinkles. Sur-gical interventions may be employed when the structure and position of facial features require modifications greater than what may be achieved with nonsurgical procedures. Browlift operations raise the position of the eyebrows (Fig. 45-67). Blepharoplasty is a set of procedures that modify the shape and position of the upper and lower eyelids. Facelift modifies the configuration and amount of facial skin and subcutaneous Brunicardi_Ch45_p1967-p2026.indd 201701/03/19 6:31 PM 2018SPECIFIC CONSIDERATIONSPART IIstructures to correct features such as deep nasolabial folds, skin redundancy along the inferior border of the mandible, and loss of definition of neck contours. Rhinoplasty involves a complex set of procedures to modify the size, shape, and airway function of the nose (Fig. 45-68).Aesthetic Surgery of the BreastSurgery to modify the shape, volume, and nipple position of the breast are among the most common aesthetic procedures. Figure 45-67. Facelift. A. Preoperative appearance. B. Postopera-tive appearance.ABBreast reduction surgery reduces the amount of both skin and breast tissue volume and modifies the position of the nipple on the breast mound (Fig. 45-69). The most common indication is to treat symptoms of large breasts known as macromastia, which is associated with a symptomatic triad of upper back pain, bra strap grooving, and skin rashes under the fold of the breasts. Unilateral breast reduction is often performed to achieve breast symmetry after contralateral postmastectomy breast reconstruc-tion. As with all breast surgery, achieving a natural and cos-metically acceptable appearance is essential to a satisfactory outcome. Mastopexy techniques share many aspects with breast reduction except that breast volume is preserved and only the amount of skin and location of the nipple are modified. Funda-mental to the success of the procedure is the establishment of symmetric and proper nipple position. Nipple ptosis is graded by the nipple position relative to the inframammary fold.Many patients seek surgical intervention to increase breast size in a procedure known as augmentation mammoplasty (Fig. 45-70). Breast volume is increased by insertion of a syn-thetic implant specifically designed for this purpose. Modern breast implants are manufactured from various formulations of silicone polymers. The implant shell, which is on contact with the tissues, is always made from silicone elastomer. The filling material can be either silicone or saline, depending on the patient and surgeon preference. As with any surgical proce-dure that involves implanting synthetic materials, the surgeon must fully understand the nature of the materials and be able to inform the patient of all known risks and benefits.The pervasive risk of breast cancer among women man-dates careful consideration of the impact of any breast surgery on cancer screening, diagnosis, and treatment. Preoperative breast cancer screening consistent with current American Can-cer Society guidelines should be performed for all patients undergoing elective breast reshaping surgery. After breast augmentation surgery, routine screening mammograms are no longer considered adequate. Patients with breast implants must have diagnostic mammograms where a radiologist studies the images at the time of the study to ensure they completely visual-ize the breast tissue.Gynecomastia is a condition of excess breast tissue in males. It can be caused by a wide range of medical disorders, including liver dysfunction, endocrine abnormalities, genetic syndromes (e.g., Klinefelter’s syndrome), renal disease, tes-ticular tumors, adrenal or pituitary adenomas, secreting lung carcinomas, and male breast cancer. Pharmacologic agents associated with the potential side effect of breast enlargement include marijuana use, digoxin, spironolactone, cimetidine, the-ophylline, diazepam, and reserpine. Although all of these pos-sible causes must be considered in any patient presenting with gynecomastia, the majority of patients have idiopathic enlarge-ment of the breast parenchyma, often occurring in teenagers. Surgical correction of this condition as often indicated.Aesthetic Surgery of the BodyAesthetic surgery may be applied to the torso and extremities. The most common circumstance is following massive weight loss, typically as a result of bariatric surgery. Morbid obesity stretches the skin and supporting ligaments that tether it to the underlying fascial framework. Decreasing the amount of sub-cutaneous fat often results in significant skin laxity that creates body contour deformities. Improvement can be achieved only through skin excision. Therefore, all body-contouring surgery Brunicardi_Ch45_p1967-p2026.indd 201801/03/19 6:31 PM 2019PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45ANaso-frontal angleNaso-labial angleTip-columellar angleLower lateral cartilageUpper lateral cartilageBCFigure 45-68. A. Rhinoplasty anatomy. B. Preoperative appear-ance. C. Postoperative appearance.Brunicardi_Ch45_p1967-p2026.indd 201901/03/19 6:31 PM 2020SPECIFIC CONSIDERATIONSPART IIFigure 45-69. Inferior pedicle reduction mammaplasty.De-epithelializedareaExcised arearepresents a trade of excess skin for scar, and this must be emphasized during patient consultation. The patient willing to accept scars in exchange for improved contour is likely to be satisfied with the procedures. With the increased number of bar-iatric surgery procedures over the past decade, body-contouring surgery has become very popular and is emerging as a new sub-specialty of plastic surgery.Excess skin and subcutaneous tissue on the anterior abdominal wall creates a redundancy that can hang over the pubic area called an abdominal wall pannus. It can cause dif-ficulty dressing and maintaining proper personal hygiene. A panniculectomy is a procedure that removes the redundant skin and subcutaneous tissue of the pannus. If additional contouring of the abdominal wall is performed, the procedure is known as abdominoplasty. During this procedure, not only is the pannus excised but the maximum amount of skin is excised to tighten the abdominal wall. Optimum contouring typically requires tightening of the underlying abdominal wall by suturing the midline and transposing the umbilicus as the upper abdominal skin is advanced inferiorly. At times additional skin must be excised transversely, requiring a concurrent vertical incision to remove skin in two vectors (Fig. 45-71). Possible complications include skin necrosis, persistent paresthesias of the abdominal wall, seroma, and wound separation. Necrosis of the umbili-cus may complicate preservation of that structure if the stalk is excessively long or an umbilical hernia is repaired. Adding a Brunicardi_Ch45_p1967-p2026.indd 202001/03/19 6:32 PM 2021PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45Figure 45-70. Placement of breast implant. A. Subglandular. B. Subpectoral.Figure 45-69. (Continued)ImplantBAPectoralis majormusclevertical resection increases the incidence of skin necrosis, espe-cially at the confluence of scars in the lower abdomen.Brachioplasty, or arm lift, excises excess skin and subcu-taneous tissue from the arms. It results in improved contour but leaves a visible longitudinal scar on the medial aspect of the arm. Therefore, it is reserved for patients with excessive skin in that region. The patient willing to accept the scar can be happy with the results. Complications include distal seroma and wound separation. Paresthesias in the upper arm and forearm may occur secondary to injury of sensory nerves passing through the resec-tion area, though this rarely affects function. Incisions that cross the axilla must be designed to avoid axillary contractures that limit shoulder mobility.Thigh and buttock lifts treat loose skin on the thighs and buttocks. A variety of methods have been described, and applica-tion requires proper patient selection in order to obtain the best outcome. The lateral thighs can be lifted simultaneously during abdominoplasty with one scar along the belt line. If the lift is continued on the posterior torso, a buttocks lift can be performed as well. This procedure is referred to as a circumferential lower body lift. Contouring the medial thighs typically requires an inci-sion in the groin crease. Firmly anchoring the deep thigh fascia to Colles’ fascia is essential to help prevent spreading of the labia. In cases of severe excess skin on the inner thighs, a long verti-cal incision is necessary. Complications of thigh and buttock lift include seroma, wound separation, skin necrosis, and change in the shape of the genital region (with possible sexual dysfunction).Brunicardi_Ch45_p1967-p2026.indd 202101/03/19 6:32 PM 2022SPECIFIC CONSIDERATIONSPART IIABFigure 45-71. A. Preoperative photo of 35-year-old woman after gastric bypass and massive weight loss. B. Patient 12 months after a fleurde-lis abdominoplasty.Suction LipectomyLiposuction is a technique that involves the removal of adipose tissue through minimal incisions using a hollow suction can-nula system. The key consideration in determining acceptable candidates for this body contouring technique directly relies on the patient’s inherent skin elasticity, which provides the sought-after retraction of skin over the lipoaspirated adipose depot to improve area contour. Thus, assessment of skin tone is a vital part of the preoperative patient evaluation. If there is excessive skin laxity in the body area to be treated, it may worsen after liposuction and contribute to contour irregularities, voids, and abnormal appearance.This technique can be highly effective in the correctly chosen patient as the access port sites provide minimally vis-ible scars and can remove significant amounts of fatty tissue to improve contour. However, it is worth mentioning that liposuc-tion is not considered a weight-loss treatment; rather, it is a tool for addressing unwanted and troublesome adipose depots. Typi-cally, the best candidates for liposuction are individuals who are close to their goal weight and have focal adipose deposits that are resistant to diet and exercise (Fig. 45-72). The suction cannula system removes adipose tissue by avulsing fat into the small holes located within the cannula tip. As the cannula is repeatedly passed throughout the adipose planes to remove the fat, one can often visualize and feel the reduction in the fat depot area treated. In general, larger-diameter cannulas remove adi-pose tissue at a faster rate yet carry a higher risk of causing contour irregularities such as grooving and/or uneven removal of fat. Newer liposuction technologies employing ultrasonic or laser probes to heat and emulsify fat via cavitation before suc-tion are gaining increasing application because they also aid in better tightening of the overlying skin envelope. However, use of these technologies also increases the chance and incidence of tissue damage and injury from the heat of the cannula and can cause burn injury to skin and underlying structures.A major advance in the field of liposuction involves appli-cation of tumescent local anesthesia. This method involves the infiltration of very dilute lidocaine and epinephrine (lidocaine 0.05% and epinephrine 1:1,000,000) in large volumes through-out the subcutaneous tissues prior to suction removal of fatty tissue. Tumescent volumes can range from one to three times the anticipated aspirate volume. The dilute lidocaine provides sufficient anesthesia to allow the liposuction to be performed without additional agents in some instances. However, in cases where large volumes of fat are to be removed or in cases where multiple sites are to be addressed, then sedation and/or general anesthesia is often preferred. With tumescent anesthesia, the absorption of the dilute lidocaine from the subcutaneous tissue is very slow, with peak plasma concentrations occurring approx-imately 10 hours after the procedure. Therefore, the standard lidocaine dosing limit of 7 mg/kg may be safely exceeded. Cur-rent recommendations suggest a limit of 35 mg/kg of lidocaine with tumescent anesthesia. A very important component of the tumescent anesthetic solution is diluted epinephrine, which has proved to limit blood loss during the procedure.Safety issues are paramount for liposuction because of potential fluid shifts postoperatively and hypothermia. If ≥5000 mL of aspirate is to be removed, the procedure should be Brunicardi_Ch45_p1967-p2026.indd 202201/03/19 6:32 PM 2023PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45ABCFigure 45-72. A and B. Preoperative photos of a 22-year-old woman with focal adipose deposits on the trunk and extremities. C. Patient 3 months after surgery.Brunicardi_Ch45_p1967-p2026.indd 202301/03/19 6:32 PM 2024SPECIFIC CONSIDERATIONSPART IIperformed in an accredited acute care hospital facility. After the procedure, vital signs and urinary output should be monitored overnight in an appropriate facility by qualified and competent staff familiar with perioperative care of the liposuction patient.Autologous Fat GraftingThe concept of reinjecting fat tissue harvested by liposuction has been put into practice for decades. Key to the technique is a pro-cessing step in which the sterilely collected fat is separated from the aqueous (primarily tumescent fluid) and free lipid fractions. This can be done by centrifugation and/or filtering. Ideally, the prepared adipose grafts are then injected into the tissues using specially designed blunt-tipped cannulas that provide for micro-graft injection. Small aliquots of fat grafts are injected with each cannula pass to deposit the grafts within the vascularized tissues of the recipient bed. Autologous fat grafting has gained increased interest and has been applied to various areas of aesthetic and reconstructive surgery. Specific applications include fat grafting to augment areas where fat atrophy is commonplace (aging of the face or hands), to enhance breast aesthetics and/or other breast reconstruction techniques, gluteal augmentation, or to address contour deformities or irregularities caused by iatrogenic, trau-matic, oncologic, or congenital processes.REFERENCESEntries highlighted in bright blue are key references. 1. Martin, Andrew J. (2005-07-27). “Academy Papyrus to be Exhibited at the Metropolitan Museum of Art” (Press release). The New York Academy of Medicine. Archived from the origi-nal on November 27, 2010. 2. Borges AF, Alexander JE. Relaxed skin tension lines, Z-plasties on scars, and fusiform excision of lesions. Br J Plast Surg. 1962;15:242-254. 3. Wilhelmi BJ, Blackwell SJ, Phillips LG. Langer’s lines: to use or not to use. Plast Reconstr Surg. 1999;104:208-214. 4. Staylor A. Wound care devices: growth amid uncertainty. Med Tech Insight. 2009;11(1):32-47. 5. Baronio G. On Grafting in Animals. Boston: Boston Medical Library; 1985. This is a modern publication of the classic 18th century work by Guiseppi Baronio who studied skin grafting in animals. Baronio’s work represents the first preclinical animal study of a surgical procedure. The logo of the most important professional organization dedicated to plastic surgery research, the Plastic Surgery Research Council, is based on Baronio’s illustration of a sheep with multiple grafted areas of skin on the back. 6. Singh M, Nuutila K, Kruse C, Robson MC, Caterson E, Eriksson E. Challenging the conventional therapy: emerging skin graft techniques for wound healing. Plast Reconstruct Surg. 2015;136(4):524e-530e. 7. Sinha S, Schreiner AJ, Biernaskie J, Nickerson D, Gabriel VA. Treating pain on skin graft donor sites: review and clini-cal recommendations. J Trauma Acute Care Surg. 2017;83(5): 954-964. 8. Kagan RJ, Peck MD, Ahrenholz DH, et al. Surgical manage-ment of the burn wound and use of skin substitutes: an expert panel white paper. J Burn Care Res. 2013;34(2):e60-e79. A variety of skin substitutes are available for repairing areas of skin loss from injuries such as deep partial-thickness or full-thickness burns. This article provides a nice summary of con-temporary options. 9. Azzopardi EA, Boyce DE, Dickson WA, et al. Application of topical negative pressure (vacuum-assisted closure) to split-thickness skin grafts: a structured evidence-based review. Ann Plast Surg. 2013;70(1):23-29. 10. Maciel-Miranda A, Morris SF, Hallock GG. Local flaps, including pedicled perforator flaps: anatomy, technique, and applications. Plast Reconstruct Surg. 2013;131(6): 896e-911e. 11. Kunert P. Structure and construction: the system of skin flaps. Ann Plast Surg. 1991;27(6):509-516; discussion 517-518. 12. McGregor IA, Morgan G. Axial and random pattern flaps. Br J Plastic Surg. 1973;26(3):202-213. 13. Rajabi A, Dolovich AT, Johnston JD. From the rhombic transpo-sition flap toward Z-plasty: an optimized design using the finite element method. J Biomech. 2015;48(13):3672-3678. 14. Bakamjian VY, Long M, Rigg B. Experience with the medially based deltopectoral flap in reconstructive surgery of the head and neck. Br J Plast Surg. 1971;24(2):174-183. 16. Geddes CR, Morris SF, Neligan PC. Perforator flaps: evo-lution, classification, and applications. Ann Plast Surg. 2003;50(1):90-99. 17. Sinna R, Boloorchi A, Mahajan AL, Qassemyar Q, Robbe M. What should define a “perforator flap”? Plast Reconstr Surg. 2010;126(6):2258-2263. 18. Taylor GI, Palmer JH. The vascular territories (angiosomes) of the body: experimental study and clinical applications. Br J Plast Surg. 1987;40(2):113-141. This is the classic article studying blood supply to the skin that introduced the angiosome concept and transformed our under-standing of the anatomic basis of surgical flap design. The blood supply was shown to be a continuous three-dimensional network of vessels in all tissue layers. The anatomical territory of a source artery corresponded in both the skin and deep tissues and gave rise to the angiosome concept. 19. Buchanan PJ, Kung TA, Cederna PS. Evidence-based medicine: wound closure. Plast Reconstr Surg. 2014;134(6):1391-1404. This is an excellent summary of the basic principles of wound healing. It explains the physiologic basis and rationale for vari-ous wound care methods, including dressings, negative pressure wound therapy, skin and dermal substitutes, and tissue expan-sion. This is basic knowledge that is important for all surgeons to understand. 20. Whitaker LA, Pashayan H, Reichman J. A proposed new classification of craniofacial anomalies. Cleft Palate J. 1981;18(3):161-176. 21. Monson LA, Kirschner RE, Losee JE. Primary repair of cleft lip and nasal deformity. Plast Reconstr Surg. 2013;132(6): 1040e-1053e. 22. Fattah AY. Craniofacial syndromes: genetics, embryology, and clinical relevance. In: Bentz ML, Bauer BS, Zuker RM, eds. Principles & Practice of Pediatric Plastic Surgery. Boca Raton: CRC Press; 2016:393-452. 23. Hoffman WY, Fisher DM. Unilateral cleft lip repair. In: Bentz ML, Bauer BS, Zuker RM, eds. Principles & Practice of Pediatric Plastic Surgery. Boca Raton: CRC Press; 2016: 453-478. 24. van Aalst JA, Kolappa KK, Sadove M. MOC-PSSM CME article: nonsyndromic cleft palate. Plast Reconstr Surg. 2008; 121(1 suppl):1-14. 25. Garfinkle JS, Grayson BH. Nasoalveolar molding and columella elongation in preparation for the primary repair of unilateral and bilateral cleft lip and palate. In: Losee JE, ed. Craniofacial, Head and Neck Surgery and Pediatric Plastic Surgery. Philadel-phia: Elsevier; 2013:1223-1251. 26. Kirschner REA, Losee JE. Lip adhesion. In: Losee J, Kirschner RE, eds. Comprehensive Cleft Care. Boca Raton, FL: CRC Press; 2016:781-792. This is the definitive textbook on pediatric plastic surgery that covers each aspect in depth. 27. Hoffman WY. Cleft palate. In: Losee JE, ed. Craniofacial, Head and Neck Surgery and Pediatric Plastic Surgery. Philadelphia: Elsevier; 2013:568-583.Brunicardi_Ch45_p1967-p2026.indd 202401/03/19 6:32 PM 2025PLASTIC AND RECONSTRUCTIVE SURGERYCHAPTER 45 28. Moe KS, Murr AH, Wester ST. Orbital Fractures. Facial Plast Surg Clin North Am. 2018 May;26(2):237-251. doi: 10.1016/j.fsc.2017.12.007. Review. PubMed PMID: 29636153. 29. Fattah AY. Craniofacial syndromes: genetics, embryology, and clinical relevance. In: Bentz ML, Bauer BS, Zuker RM, eds. Principles & Practice of Pediatric Plastic Surgery. Boca Raton: CRC Press; 2016:393-452. 30. Patel PK, Kawamoto HK, Jr. Atypical craniofacial clefts. In: Bentz ML, Bauer BS, Zuker RM, eds. Principles & Prac-tice of Pediatric Plastic Surgery. Boca Raton: CRC Press; 2016:663-723. 31. Tessier P. Anatomical classification facial, cranio-facial and latero-facial clefts. J Maxillofac Surg. 1976;4(2):69-92. 32. Monasterio FO, Taylor JA. Major craniofacial clefts: case series and treatment philosophy. Plast Reconstr Surg. 2008;122(2):534-543. 33. Forrest CR, Nguyen PD, Smith DM. Craniosynostosis. In: Bentz ML, Bauer BS, Zuker RM, eds. Principles & Practice of Pedi-atric Plastic Surgery. Boca Raton: CRC Press; 2016:595-647. 34. Fearon JA. Evidence-based medicine: craniosynostosis. Plast Reconstr Surg. 2014;133(5):1261-1275. 35. Persing JA. MOC-PS(SM) CME article: management consider-ations in the treatment of craniosynostosis. Plast Reconstr Surg. 2008;121(4 suppl):1-11. 36. Taylor JA, Bartlett SP. What’s new in syndromic craniosynosto-sis surgery? Plast Reconstr Surg. 2017;140(1):82e-93e. 37. Vaienti L, Soresina M, Menozzi A. Parascapular free flap and fat grafts: combined surgical methods in morphological resto-ration of hemifacial progressive atrophy. Plast Reconstr Surg. 2005;116(3):699-711. 38. Evans KN, Sie KC, Hopper RA, Glass RP, Hing AV, Cunning-ham ML. Robin sequence: from diagnosis to development of an effective management plan. Pediatrics. 2011;127(5):936-948. 39. Kirschner RE, Low DW, Randall P, et al. Surgical airway man-agement in Pierre Robin sequence: is there a role for tongue-lip adhesion? Cleft Palate Craniofac J. 2003;40(1):13-18. 40. Overdiek A, Feifel H, Schaper J, Mayatepek E, Rosenbaum T. Diagnostic delay of NF1 in hemifacial hypertrophy due to plexiform neurofibromas. Brain Dev. 2006;28(5):275-280. 41. Ricalde P, Magliocca KR, Lee JS. Craniofacial fibrous dyspla-sia. Oral Maxillofac Surg Clin North Am. 2012;24(3):427-441. 42. Mulliken JB, Glowacki J. Hemangiomas and vascular malfor-mations in infants and children: a classification based on endo-thelial characteristics. Plast Reconstr Surg. 1982;69(3):412-422. 43. Greene AK, Phillips JH. Vascular anomalies. In: Bentz ML, Bauer BS, Zuker RM, eds. Principles & Practice of Pediatric Plastic Surgery. Boca Raton: CRC Press; 2016:199-230. 44. Biswas A, Pan X, Meyer M, et al. Urinary excretion of microRNA-126 is a biomarker for hemangioma proliferation. Plast Reconstr Surg. 2017;139(6):1277e-1284e. 45. Iacobas I, Burrows PE, Frieden IJ, et al. LUMBAR: association between cutaneous infantile hemangiomas of the lower body and regional congenital anomalies. J Pediatr. 2010;157(5): 795-801.e1-e7. 46. Taylor CW, Horgan K, Dodwell D. Oncological aspects of breast reconstruction. Breast. 2005 Apr;14(2):118-30. Review. PubMed PMID: 15767181. 47. Nicholas Zdenkowski, Butow P, Tesson S, Boyle F. A system-atic review of decision aids for patients making a decision about treatment for early breast cancer. Breast. 2016 Apr;26:31-45. doi: 10.1016/j.breast.2015.12.007. Epub 2016 Jan 8. Review. PubMed PMID: 27017240. 48. Cho BC, McCready DR. Oncologic principles in breast recon-struction. Clin Plast Surg. 2007 Jan;34(1):1-13; abstract v. Review. PubMed PMID: 17307067. 49. Jacob AG, Driscoll DJ, Shaughnessy WJ, Stanson AW, Clay RP, Gloviczki P. Klippel-Trenaunay syndrome: spectrum and man-agement. Mayo Clin Proc. 1998;73(1):28-36. 50. Arneja JS, Gosain AK. Giant congenital melanocytic nevi. Plast Reconstr Surg. 2009;124(1 suppl):1e-13e. 51. Arad E, Zuker RM. The shifting paradigm in the management of giant congenital melanocytic nevi: review and clinical appli-cations. Plast Reconstr Surg. 2014;133(2):367-376. 52. Millard DR. Principlization of Plastic Surgery. 1st ed. Boston/Toronto: Little, Brown; 1986. 53. Corcoran J, Bauer BS. Cutaneous lesions. In: Bentz ML, Bauer BS, Zuker RM, eds. Principles & Practice of Pediatric Plastic Surgery. Boca Raton: CRC Press; 2016:453-478. 54. Bosse MJ et al. An analysis of outcomes of reconstruction or amputation after leg-threatening injuries. N Engl J Med. 2002;347(24):1924-1931. 55. Gustilo RB, Merkow RL, Templeman D. The management of open fractures. J Bone Joint Surg. 1990;72(2):299-304. 56. Crowley DJ, Kanakaris NK, Giannoudis PV. Debridement and wound closure of open fractures: the impact of the time factor on infection rates. Injury. 2007;38(8):879-889. 57. Cho EH, Shammas RL, Carney MJ, et al. Muscle versus fascio-cutaneous free flaps in lower extremity traumatic reconstruc-tion: a multicenter outcomes analysis. Plast Reconstr Surg. 2018;141(1):191-199. 58. Yazar S, Lin CH, Wei FC. One-stage reconstruction of compos-ite bone and soft-tissue defects in traumatic lower extremities. Plast Reconstr Surg. 2004;114(6):1457-1466. 59. Gurney JK(1), Stanley J(2), York S(3), Rosenbaum D(4), Sar-fati D(2). Risk of lower limb amputation in a national preva-lent cohort of patients with diabetes. Diabetologia. 2018 Mar;61(3):626-635. doi: 10.1007/s00125-017-4488-8. Epub 2017 Nov 3. 60. Wukich DK, Raspovic KM. What Role Does Function Play in Deciding on Limb Salvage versus Amputation in Patients With Diabetes? Plast Reconstr Surg. 2016 Sep;138(3 Suppl):188S-95S. doi: 10.1097/PRS.0000000000002713. Review. PubMed PMID: 27556759. 61. Nelson JA, Disa JJ. Breast reconstruction and radiation therapy: an update. Plast Reconstr Surg. 2017;140:60S-68S. Radiation therapy has an adverse effect on all forms of breast reconstruction. The need for radiation therapy affects the opti-mal timing and technique for breast reconstructive surgery. It is helpful for all surgeons caring for breast cancer patients to have an understanding of the issues involved, and this paper provides an excellent summary of the issues surrounding breast reconstruction and radiation therapy. 62. Weichman KE, Matros E, Disa JJ. Reconstruction of peripelvic oncologic defects. Plast Reconstr Surg. 2017;140(4):601e-612e. General surgeons often encounter problems in the perineum. This article offers an excellent summary of how to manage surgical problems in this region. It provides a review of anat-omy, the types of problems encountered, and appropriate local, regional, or free-flap options based on the location of the defect and donor-site characteristics. 63. Cushing CA, Phillips LG. Evidence-based medicine: pres-sure sores. Plast Reconstr Surg. 2013;132(6):1720-1732. Pressure sores are a common problem affecting surgical patients of all types, and it is important for all surgeons to understand how to prevent and treat them. This paper provides an excellent overview of the problem, with emphasis on risk factors, patho-physiology, classification, and treatment options. Most impor-tantly, it reviews steps for the prevention of pressure sores.64. Edsberg LE, Black JM, Goldberg M, McNichol L, Moore L, Sieggreen M. Revised National Pressure Ulcer Advisory Panel pressure injury staging system: revised pressure injury staging system. J Wound Ostomy Continence Nurs. 2016;43(6):585-597. 65. Centers for Disease Control and Prevention. 2017 National Diabetes Statistics Report, 2017. Available at: https://www.cdc.gov/diabetes/data/statistics/statistics-report.html. Accessed January 20, 2019.Brunicardi_Ch45_p1967-p2026.indd 202501/03/19 6:32 PM 2026SPECIFIC CONSIDERATIONSPART II 66. Clemens MW, Attinger CE, Colen LB. Foot reconstruction. In: Mathes SJ, ed. Plastic Surgery. 2nd ed. Philadelphia: Elsevier; 2006:1403. 67. Hinchliffe RJ, Andros G, Apelqvist J, et al. A systematic review of the effectiveness of revascularization of the ulcerated foot in patients with diabetes and peripheral arterial disease. Diabetes Metab Res Rev. 2012;28(suppl 1):179-217. 68. Johnson SK, Podratz KE, Dipboye RL, Gibbons E. Physi-cal attractiveness biases in ratings of employment suitability: tracking down the “beauty is beastly” effect. J Soc Psychol. 2010;150(3):301-318. 69. Jacono A, Chastant RP, Dibelius G. Association of patient self-esteem with perceived outcome after face-lift surgery. JAMA Facial Plast Surg. 2016;18(1):42-46. 70. Schwitzer JA, Sher SR, Fan KL, Scott AM, Gamble L, Baker SB. Assessing patient-reported satisfaction with appearance and quality of life following rhinoplasty using the FACE-Q appraisal scales. Plast Reconstr Surg. 2015;135(5):830e-837e. 71. Papadopulos NA, Niehaus R, Keller E, et al. The psychologic and psychosocial impact of otoplasty on children and adults. J Craniofac Surg. 2015;26(8):2309-2314. 72. McGrath MH. The psychological safety of breast implant sur-gery. Plast Reconstr Surg. 2007;120(7 suppl 1):103S-109S. 73. Papadopulos NA, Staffler V, Mirceva V, et al. Does abdomino-plasty have a positive influence on quality of life, self-esteem, and emotional stability? Plast Reconstr Surg. 2012;129(6):957e-962e. 74. Shridharani SM, Magarakis M, Manson PN, Rodriguez ED. Psychology of plastic and reconstructive surgery: a systematic clinical review. Plast Reconstr Surg. 2010;126(6):2243-2251. 75. American Psychiatric Association. Diagnostic and Statistical Manual of Mental Disorders. 5th ed. Arlington, VA: American Psychiatric Association; 2013.Brunicardi_Ch45_p1967-p2026.indd 202601/03/19 6:32 PM
Anesthesia for Surgical PatientsJunaid Nizamuddin and Michael O’Connor 46chapterBRIEF HISTORY OF ANESTHESIAThe discovery of anesthesia is one of the seminal American con-tributions to the world. Along with infection control and blood transfusion, anesthesia has enabled surgery to occupy its fundamental place in medicine. Before the advent of anes-thesia in the 1840s, many substances and methods had been tried in the search for pain relief and better operating conditions. Patients were typically restrained by several attendants, and only the most stoic could tolerate the screams heard in the oper-ating theater.BeginningsHorace Wells (1815–1848), a dentist, first pursued using nitrous oxide for the relief of pain in surgical procedures in 1844.1 After experimenting on himself, Wells attempted to demonstrate the analgesic effects of nitrous oxide for a dental procedure at Harvard Medical School in 1845. The public demonstration was a failure, at least partially, due to improper administration of the gas. Wells never recovered from his humiliating experience and eventually committed suicide. However, he does hold a place in history as the first person to recognize and use the only anesthetic from the 1800s that is still in use today—nitrous oxide.Ether DayWilliam Morton (1819–1868) was a dentist and partner of Horace Wells. After taking a course in anesthesia from Wells, Morton left the partnership in Hartford, Connecticut, and established himself in Boston. He continued his interest in anesthesia, but using diethyl ether instead of nitrous oxide. Ether proved a good choice. He practiced the administration of ether on a 11dog and then used it when extracting teeth from patients in his office. On October 16, 1846, Morton gave the first pub-lic demonstration of ether as an anesthetic for Johns Collins Warren, a distinguished surgeon and one of the founders of Massachusetts General Hospital. In attendance in the surgi-cal amphitheater were several surgeons, medical students, and a newspaper reporter. After induction of anesthesia, Warren successfully removed a vascular mass from the patient’s neck with no ill effects (Fig. 46-1). The description of this public demonstration of ether was published in the Boston Medical and Surgical Journal (now The New England Journal of Medicine).2 The stature of Warren lent considerable credence to the advent of surgical anesthesia. The news spread rapidly, and surgeons around the world were quick to adopt this new invention. Massachusetts General Hospital has restored and preserved the original amphi-theater where the demonstration took place, now called the Ether Dome. The description of the public demonstration of ether was voted as the most important article published in the history of The New England Journal of Medicine in its first 200 years.3The Modern EraAnesthesia has developed rapidly over the past century. Inhaled anesthetics, initially discovered fortuitously by observation, have been synthetically produced and remain the mainstay of anesthetic maintenance. The advent of the hollow syringe and needle and discovery of rapidly acting of intravenous anesthet-ics allowed for rapid induction of anesthesia. Development of endotracheal intubation and mechanical ventilation revolution-ized the delivery of inhaled anesthetics. The discovery of local anesthetics led to the development of peripheral nerve blocks Brief History of Anesthesia 2027Beginnings / 2027Ether Day / 2027The Modern Era / 2027Basic Pharmacology 2028Pharmacokinetics and Pharmacodynamics / 2028Administration, Distribution, Metabolism, and Elimination / 2029Pharmacodynamics / 2029Potency, Efficacy, Lethal Dose, and Therapeutic Index / 2029Anesthetic Agents 2029Inhaled Anesthetics / 2029Local Anesthetics / 2031Neuromuscular Blockers / 2031Anesthetic Monitoring 2032Perioperative Evaluation and  Preparation 2033ASA Physical Status Assessment / 2034Airway Evaluation / 2034Cardiovascular Disease / 2034Pulmonary Disease / 2035Renal Disease / 2036Hepatic Disease / 2036Endocrine Disease / 2036Preoperative Fasting / 2036Patients With Advanced Directives / 2036Risk Estimation / 2036Intraoperative Management 2036General Anesthesia / 2036Monitored Anesthesia Care / 2039Regional Anesthesia/Acute Pain / 2039Recovery And Complications 2039The Postanesthesia Care Unit / 2039Enhanced Recovery After Surgery Pathways / 2039Acute Postoperative Pain / 2039Malignant Hyperthermia / 2040Cardiovascular Complications / 2040Respiratory Failure / 2040Neurologic and Psychiatric Complications / 2040Conclusion 2040Brunicardi_Ch46_p2027-p2044.indd 202701/03/19 11:03 AM 2028Figure 46-1. Robert Cutler Hinckley, The First Operation with Ether. (Reproduced with permission from Boston Medical Library in the Francis A. Countway Library of Medicine, Boston, Massachusetts.)Key Points1 The discovery of anesthesia was one of the most important advances and has enabled surgery to occupy its fundamental place in medicine.2 Advances in anesthetic monitoring have made the admin-istration of anesthesia safer than ever. Types of cardiovas-cular monitors include arterial catheters, central venous and pulmonary artery catheters, and transesophageal echocardiography.3 A detailed preoperative evaluation should be performed on each patient when circumstances allow, with special atten-tion devoted to functional status. The American College of Cardiology/American Heart Association guidelines for pre-operative evaluation can guide workup.4 The American Society of Anesthesiologists has developed specific guidelines for preoperative fasting to mitigate the risk of aspiration of gastric contents; individual patients may need more stringent preoperative fasting periods and/or rapid sequence inductions.5 The American Society of Anesthesiologists has developed an algorithm for management of the difficult airway. Nota-bly, in patients in whom both intubation and ventilation are impossible, the algorithm calls for placement of a laryngeal mask airway as the next step.and spinal anesthesia. Concurrently, physiologic monitoring techniques have advanced to make the administration of anes-thesia safer than ever.Initially, anesthesia was given by medical students, nurses, and dentists, but eventually became a physician specialty of medicine of its own. The American Board of Anesthesiology was formed in 1938. Over the past 50 years, anesthesiology has increasingly specialized and also spread outside the operating room into critical care, pain management, and perioperative medicine.BASIC PHARMACOLOGYPharmacokinetics and PharmacodynamicsPharmacodynamics is the study of what a drug does to the body; pharmacokinetics is the study of what the body does to a drug. Brunicardi_Ch46_p2027-p2044.indd 202801/03/19 11:04 AM 2029ANESTHESIA FOR SURGICAL PATIENTSCHAPTER 46The conduct of anesthesia is predicated upon the pharmacody-namics and pharmacokinetics of the drugs used.4Administration, Distribution, Metabolism, and EliminationAdministration of a drug affects its pharmacokinetics, as there will be different rates of drug entry into the circulation. For example, medications administered via the oral route are subject to first-pass effect of the portal circulation; this can be bypassed with the IV, nasal, or sublingual route. Other routes of drug administration include transdermal, intramuscular, subcutaneous, or inhalation.Distribution is the delivery of a drug from the systemic circulation to the tissues. Once a drug has entered the systemic circulation, the rate at which it will enter the tissues depends on the blood flow into that tissue, as well as the molecular size of the drug, lipid solubility, capillary permeability, polarity, plasma protein and tissue binding, and volume of distribution, the fluid volume in which the drug distributes. The distribution or redis-tribution of drugs can play a critical role in shaping their clinical use. For instance, clinically, the effect of propofol is terminated by its redistribution into fatty tissues and not metabolism of the drug.Metabolism is the permanent breakdown of original compounds into smaller metabolites. Drug elimination varies widely; some drugs are excreted unchanged by the body, some decompose via plasma enzymes, and some are degraded in the liver. Many drugs rely on multiple pathways for metabolism and elimination (i.e., metabolized by liver enzymes and then excreted by the kidney).Context-sensitive half time is the time required for blood concentrations of a drug to decrease by 50% after its discontinu-ation, which is determined by the interaction of the duration of administration, distribution and accumulation, and metabolism and excretion. Fig. 46-2 illustrates the context sensitive half-time for commonly used anesthetics and opioids.4PharmacodynamicsPharmacodynamics, or how the plasma concentration of a drug translates into its effect on the body, depends on biologic vari-ability, receptor physiology, and clinical evaluations of the actual drug. An agonist is a drug that causes a response (acti-vates a receptor). A full agonist produces the full receptor/tissue response, and a partial agonist elicits less than the maximum response induced by a full agonist. An antagonist is a drug that blocks agonist mediated responses. An additive effect means that a second drug acts with the first drug and will produce an effect that is equal to the algebraic summation of both drugs. A synergistic effect means that two drugs interact to produce an effect that is greater than expected from the two drugs’ alge-braic summation. Tolerance, desensitization, or tachyphylaxis occurs when a larger than expected dose is required to produce a response. Tolerance usually results from chronic drug exposure, either through enzyme induction (e.g., alcohol) or depletion of neurotransmitters (e.g., cocaine).4Potency, Efficacy, Lethal Dose, and Therapeutic IndexThe potency of a drug is the dose required to produce a given effect, such as pain relief or a change in heart rate. The aver-age sensitivity to a particular drug can be expressed through the calculation of the effective dose; ED50 would have the desired effect in 50% of the general population. The efficacy of any therapeutic agent is its power to produce a desired effect. Two drugs may have the same efficacy but different potencies. Dose-response curves show the relationship between the dose of a drug administered (or the resulting plasma concentration) and the pharmacologic effect of the drug. The lethal dose (LD50) of a drug produces death in 50% of animals to which it is given, and the toxic dose (TD50) is the dose that elicits a toxicity in 50% of humans to which it is given. The ratio of the toxic dose and effective dose, TD50/ED50, is the therapeutic index. A drug with a high therapeutic index is safer than a drug with a low or narrow therapeutic index.4ANESTHETIC AGENTSInhaled AnestheticsInhaled anesthetics have greatly advanced since the original dem-onstration with ether. Modern agents provide faster induction and emergence and provide all of the major characteristics of general anesthesia: unconsciousness, analgesia, and muscle relaxation.Minimum alveolar concentration (MAC) is a measure of anesthetic potency. It is the ED50 of an inhaled agent (i.e., the dose required to prevent movement in response to skin incision in 50% of patients). The higher the MAC, the less potent an agent is. Advantages and disadvantages of inhaled anesthetics are shown in Table 46-1.5Nitrous Oxide. Nitrous oxide has a low solubility and is a weak anesthetic agent, but it has the most rapid onset and offset. Because 600500400300Duration of infusion (min)2001000020406080100120140Time required for plasmalevels to drop by 50% (min)AEtomidateMidazolamPropofolSufentanilFentanylRemifentanil600500400300Duration of infusion (min)2001000020406080100120140Time required for plasmalevels to drop by 50% (min)BFigure 46-2. Context-sensitive half time for commonly used anesthetics (A) and opioids (B). The vertical axis represents the half-time, or the time required for plasma concentrations of the drug to drop by 50%. The horizontal axis represents the duration of a continuous infusion. (Reproduced with permission from Longnecker DE, Mackey SC, Newman MF, et al: Anesthesiology, 3rd ed. New York, NY: McGraw-Hill Education; 2018.)Brunicardi_Ch46_p2027-p2044.indd 202901/03/19 11:04 AM 2030SPECIFIC CONSIDERATIONSPART IITable 46-1Advantages and disadvantages of inhaled anestheticsANESTHETICADVANTAGESDISADVANTAGESNitrous OxideNo odor, taste, or pungencyRapid uptake and eliminationAnalgesic effectMinimal cardiovascular depressionMinimal biotransformationInexpensiveAirspace expansionIncreased nausea and vomitingInhibits methionine synthaseEnvironmental pollutantSupports combustionIsofluraneGood muscle relaxationBronchodilationStable heart rateInexpensiveSlow uptake and eliminationSevoflurane Rapid uptake and eliminationNot pungentBreakdown to compound A in circuitMore expensive than isofluraneDesflurane  Rapid uptake and eliminationVery low biotransformationAirway irritantRequires electric/heated vaporizerExpensiveData from Longnecker DE, Brown DL, Newman MF, et al: Anesthesiology, 2nd ed. New York, NY: McGraw-Hill Ediucation; 2012.its MAC is 104%, it must be combined with other agents to pro-vide general anesthesia. A recent randomized controlled trial demonstrated that use of 70% nitrous oxide, given as part of a general anesthetic, did not increase the risk of death or major adverse cardiovascular events.6 Nitrous oxide has been shown to increase the rate of postoperative nausea and vomiting (PONV).Volatile Agents. The volatile inhaled anesthetics are gener-ally more soluble in blood than nitrous oxide, are more potent, and thus require lower inspired concentrations. Currently, iso-flurane, sevoflurane, and desflurane are the agents that are most commonly used. Older agents, including halothane, which was associated with hepatotoxicity, are no longer widely used.Isoflurane is the most inexpensive and widely available of the agents currently used. Sevoflurane has relatively rapid uptake and elimination. It is also not pungent and is therefore commonly used for inhalational induction. Desflurane has the most rapid uptake and elimination of the three most commonly used volatile agents. It is also the most expensive, requires a heated-electric vaporizer, and is an airway irritant. All of the volatile inhalational agents as well as the depolarizing neu-romuscular blocker succinylcholine are triggering agents for malignant hyperthermia.5Intravenous Agents. Intravenous agents are used to produce unconsciousness, analgesia, muscle relaxation, and/or amnesia. They include barbiturates, propofol, benzodiazepines, ketamine, etomidate, opioids, and nonopioid analgesics.7Barbiturates Barbiturates used in anesthesia include thio-pental and methohexital. These drugs act as agonists at the γ-aminobutyric acid (GABA) receptor, which inhibit excitatory synaptic transmission. Clinically, they produce a rapid, smooth induction of general anesthesia and wear off quickly. They cause hypotension and myocardial depression in a dose-dependent manner. Barbiturates are seldom used in modern anesthesia, with the exception of methohexital, which is still commonly used dur-ing electroconvulsive therapy.Propofol Propofol is an alkylated phenol that inhibits synaptic transmission through its effects at the GABA receptor. It has a short duration, rapid recovery, and low incidence of nausea and vomiting. Consequently, it is the induction agent of choice. Propofol causes hypotension in a dose-dependent manner, and it should be used cautiously in patients with cardiac disease or hypovolemia. Continuous infusion of propofol is commonly used for sedation in the intensive care unit setting. Continuous infusions of propofol are also used for moderate-to-deep seda-tion for many procedures and are also commonly incorporated into total intravenous anesthetics (TIVA), most commonly for neurosurgical procedures. Propofol is an irritant and frequently causes pain on injection. Propofol also has anticonvulsant properties.Benzodiazepines Benzodiazepines are most commonly used to reduce anxiety and produce amnesia. Midazolam, which has a rapid onset and relatively short duration of action, is by far the most commonly used benzodiazepine in anesthesia. Lorazepam and diazepam are still sometimes used as anxiolytics or amnes-tics. Benzodiazepines act as agonists at the GABAA receptor. They produce sedation, vasodilation, and respiratory depres-sion in a dose-dependent manner. They should be used with caution when given with opioids because a synergistic reaction causing respiratory depression is common. Oral midazolam is commonly used for anxiolysis in children. Benzodiazepines are excellent anticonvulsants and only rarely cause allergic reac-tions. Benzodiazepines should be administered cautiously in older adult patients due to the heightened risk of delayed awak-ening and postoperative delirium.Etomidate Etomidate is an imidazole derivative used for IV induction. Its rapid and almost complete hydrolysis to inactive metabolites results in rapid offset. Like the IV agents mentioned earlier, etomidate acts on the GABA receptor. Etomidate has little direct effect on cardiac output and heart rate; induction doses thus cause less reduction in blood pressure than seen with propofol. Etomidate is associated with pain on injection. Nota-bly, etomidate causes adrenal suppression,8,9 although whether a single dose of etomidate given at induction causes clinically relevant adrenal suppression remains controversial.10-13Dexmedetomidine Dexmedetomidine is an IV α2-adrenergic agonist, administered as a continuous infusion, and has both sedative and analgesic properties. It is useful for sedation in an intensive care unit setting and as an adjunct to general anes-thesia, especially as part of a total intravenous anesthetic. Side effects include hypotension and bradycardia in a dose-dependent manner. It does not cause respiratory depression at commonly used doses and is thus particularly useful for procedural seda-tion for patients at high risk of respiratory complications. It is synergistic with opiates and thus can be used to facilitate an opiate-sparing anesthetic.14,15Ketamine Ketamine differs from the aforementioned IV agents in that it produces analgesia as well as amnesia. Its principal Brunicardi_Ch46_p2027-p2044.indd 203001/03/19 11:04 AM 2031ANESTHESIA FOR SURGICAL PATIENTSCHAPTER 46action is on the N-methyl-d-aspartate (NMDA) receptor. It is a dissociative anesthetic, producing a cataleptic gaze with nystag-mus. Patients may experience delirium and hallucinations while regaining consciousness. The addition of benzodiazepines has been shown to reduce the incidence of these side effects. Ket-amine typically increases heart rate and blood pressure, which may cause myocardial ischemia in patients with coronary dis-ease. Ketamine is often used in acutely hypovolemic patients to maintain blood pressure via sympathetic stimulation. Impor-tantly, ketamine is a direct myocardial depressant in patients who are catecholamine depleted, and it can produce profound hypotension and low cardiac output in such patients. Ketamine is a bronchodilator and is sometimes used as an induction agent in asthmatic patients. It can increase intracranial pressure and intraocular pressure, and thus its use in patients with trauma to the head and neck is controversial. Ketamine can be admin-istered intramuscularly to induce anesthesia in patients who would not tolerate an inhalational induction or IV placement, such as patients with developmental delay.Opioid Analgesics The commonly used opioids—morphine, codeine, hydromorphone, meperidine, and the fentanyl-based compounds—act on µ-receptors in the brain and spinal cord. The main side effects of opioids are euphoria, sedation, con-stipation, and respiratory depression, which also are mediated by µ-receptors in a dose-dependent fashion. Although opioids have differing potencies required for effective analgesia, equi-analgesic doses of opioids result in equal degrees of respiratory depression. Thus, there is no completely safe opioid analgesic, and no reason to suppose that one opioid is safer than another. The synthetic opioid fentanyl and its analogues sufentanil, alfentanil, and remifentanil are used in the operating room. They differ pharmacokinetically in their lipid solubility, tissue binding, and elimination profiles and thus have differing poten-cies and durations of action. Fentanyl, which is highly lipid-soluble, accumulates in tissues and exhibits a steep increase in its context-sensitive half-time with infusions. Remifentanil is remarkable in that it undergoes rapid hydrolysis that is unaf-fected by sex, age, weight, or renal or hepatic function, even after prolonged infusion. Alfentanil and sufentanil are seldom used, having largely been replaced by remifentanil in the mod-ern era. Morphine and meperidine have active metabolites that are renally excreted and thus should be used with caution or avoided in patients with renal insufficiency.Naloxone, an opioid antagonist, can be used to rapidly reverse the effects of opioids, and is commonly used to rescue patients from opioid-associated respiratory depression. Nalox-one is poorly absorbed orally and is also often combined with oral opioids to prevent abuse by injection use of the combined drug. Methylnaltrexone and alvimopan are both peripheral opi-oid antagonists and can reverse the opioid side effect of consti-pation without affecting analgesia.16,17Nonopioid Analgesics Ketorolac is a parenteral nonsteroidal anti-inflammatory drug (NSAID) that produces analgesia by reducing prostaglandin formation via inhibition of the enzyme cyclooxygenase (COX). Intraoperative use of ketorolac reduces postoperative need for opioids. Ketorolac along with other NSAIDs can cause major side effects, including bleeding, plate-let dysfunction, and acute kidney injury and should be used cau-tiously in elderly patients or patients with renal insufficiency.Acetaminophen is an analgesic drug and antipyretic; its site of action is in the central nervous system. Use of acetaminophen has been shown to reduce opioid requirements postoperatively. Long available in an orally administered form as well as a rec-tal suppository, an intravenous formulation of acetaminophen is now available which has become widely used in the postopera-tive setting.18Lidocaine is a local anesthetic commonly used for local infiltration, nerve blocks, or epidural infusions. Recently, intra-venous infusions of lidocaine have been shown to be beneficial in the perioperative period. A large meta-analysis of 42 trials with 2800 patients showed that intravenous lidocaine infusions modestly reduced postoperative pain, reduced opioid require-ments, and shortened time to recovery of bowel function for patients undergoing abdominal surgery.19Local AnestheticsLocal anesthetics act on sodium channels to block transmission of neural impulses. They are divided into two groups based on their chemical structure: the amides and the esters. In general, the amides are metabolized in the liver, and the esters are metabo-lized by plasma cholinesterases, which yield metabolites with slightly higher allergic potential than the amides. Amides include lidocaine, bupivacaine, mepivicaine, prilocaine, and ropivicaine. Lidocaine has a fairly rapid onset and is shorter acting. Ropivic-aine and bupivacaine have a slower onset and are longer lasting. All three are commonly used for local infiltration and regional nerve blocks. Amides are 95% metabolized in the liver, with a minority excreted unchanged in the kidneys. Prilocaine and mepivicaine are seldom used in anesthesia at present. Esters include cocaine, procaine, chloroprocaine, tetracaine, and ben-zocaine. Esters are hydrolyzed in the blood by plasma esterases.When used in large quantities over a short period of time, local anesthetic levels can rise in the blood and cause central nervous system (CNS) toxicity and cardiovascular toxicity. Symptoms of CNS toxicity include restlessness, tinnitus, and slurred speech and can progress to seizures and coma. Car-diovascular toxicity may manifest as hypotension, conduction abnormalities leading to heart block, and ventricular arrhyth-mias, and it may lead to cardiac arrest. The type of local anes-thetic used affects the risk of developing toxicity; bupivicaine is most often associated with cardiovascular toxicity. Other risk factors for local anesthetic systemic toxicity include cumulative dose, site of injection, and preexisting renal, hepatic, or cardiac disease in the patient.20 In addition to treating symptomatology, local anesthetic systemic toxicity can be treated with intrave-nous administration of lipid emulsion.21Neuromuscular BlockersWhile general anesthetics provide muscle relaxation, they usu-ally do so at a much deeper anesthetic depth than required for amnesia and hypnosis. For this reason, neuromuscular blockers are commonly administered to attain adequate relaxation at lev-els of anesthesia sufficient to produce hypnosis, amnesia, and analgesia. Neuromuscular blockers block conduction at the neu-romuscular junction of skeletal muscle.22The two categories of neuromuscular blockers in use are depolarizing and nondepolarizing blockers. Character-istics of neuromuscular blockers currently used are summa-rized in Table 46-2. Succinylcholine is the only depolarizing agent used currently. It binds to acetylcholine receptors on the postjunctional membrane in the neuromuscular junction and causes depolarization of muscle fibers. The rapid onset (less than 60 seconds) and rapid offset (5–8 minutes) of succinyl-choline make it ideal for management of the airway in certain Brunicardi_Ch46_p2027-p2044.indd 203101/03/19 11:04 AM 2032SPECIFIC CONSIDERATIONSPART IITable 46-2Commonly used neuromuscular blockersAGENTTYPEINTUBATING DOSECONSIDERATIONSSuccinylcholineDepolarizer1 mg/kgCan cause severe hyperkalemiaContraindicated in burns, denervating conditionsExcessive or prolonged use can lead to phase II blockRocuroniumNondepolarizer0.6 mg/kg1.2 mg/kg for RSIPrimarily hepatic metabolismCan be reversed with suggamadex or acetylcholinesterase inhibitorVecuroniumNondepolarizer0.1 mg/kgPrimarily hepatic metabolismCan be reversed with suggamadex or acetylcholinesterase inhibitorCisatracuriumNondepolarizer0.1 mg/kgHoffman degradationCan be reversed with an acetylcholinesterase inhibitorRSI = rapid sequence inductionsituations.23 Succinylcholine has several adverse effects includ-ing transient hyperkalemia, which can be severe or even fatal for patients with burns and denervating injuries. Succinylcholine can cause bradycardia, which can be severe in children. It is also associated with transient increases in intracranial and intraocular pressure. The depolarization caused by succinylcholine causes skeletal muscles to fasciculate, which in turn, can result in post-operative myalgias. Succinylcholine is a known trigger of malig-nant hyperthermia in susceptible individuals. Succinylcholine is broken down by psuedocholinesterase; patients who are homo-zygous for pseudocholinestrase deficiency will have prolonged neuromuscular blockade, typically lasting for several hours.There are several nondepolarizing neuromuscular block-ing agents in clinical use. Long-acting agents including pan-curonium are no longer widely used. Intermediate-duration neuromuscular blockers include the steroid-based drugs vecuronium and rocuronium, which are metabolized by the liver as well as by the kidney, and the benzylisoquinolone drugs atra-curium and cisatracurium, which undergo breakdown in plasma known as Hofmann elimination. All nondepolarizers reversibly bind to the postsynaptic terminal in the neuromuscular junc-tion and prevent acetylcholine from depolarizing the muscle. Muscle blockade occurs without fasciculation and without the subsequent side effects seen with succinylcholine. Neuromus-cular blockade with nondepolarizing drugs is typically reversed. Failure to adequately reverse neuromuscular blockade is associ-ated with an increased risk of perioperative respiratory failure and death. Reversal agents include acetylcholinesterase inhibi-tors including neostigmine, edrophonium, or pyridostigmine that are given concurrently with muscarinic-anticholinergics, almost always atropine or glycopyrrolate. Recently, suggama-dex, a chelating agent, has been approved for use as a reversal agent for reversal of neuromuscular blockade by the steroid paralytics rocuronium and vecuronium. When given at a very high dose, suggamadex can even rapidly reverse the effect of an intubating dose of a steroid neuromuscular blocker.ANESTHETIC MONITORINGOver the past several decades, advancement in anesthetic moni-toring has made administration of anesthesia safer than ever. The goal of anesthetic monitoring is to continuously moni-tor the patients’ cardiovascular status, pulmonary status, respiratory physiology, anesthetic depth, concentration of gases administered, and temperature. The American Society of Anesthesiology (ASA) has established standards for basic intra-operative monitoring that are listed in Table 46-3. Types of anesthetic monitoring are listed in Table 46-4.Cardiovascular monitoring includes continuous ECG monitoring as well as blood pressure monitoring, which is to be measured and recorded at least every 5 minutes. Blood pressure monitoring can be done using noninvasive blood pressure cuff measurements or invasively using an arterial catheter. Other car-diovascular monitors include monitoring of central venous pres-sure, pulmonary artery pressure, and cardiac output. In high-risk 22Table 46-3American Society of Anesthesiologists standards for basic intraoperative monitoringStandardsStandard 1: Qualified anesthesia personnel shall be present in the room throughout the conduct of all general anesthetics and regional and monitored anesthesia care.Standard 2: Oxygenation, ventilation, circulation, and temperature shall be continually evaluated Oxygenation  Inspired gas oxygen analyzer  Pulse oximetry  Monitoring of patient clinical status Ventilation  Auscultation  Observation of the patient  Observation of reservoir bag  End-tidal carbon dioxide analysis Circulation  Continuous electrocardiogram display  Heart rate and blood pressure recorded at least every  5 minutes  Evaluation of circulation: auscultation of heart sounds,  palpation of pulse, pulse oximetry, blood pressure monitoring with noninvasive means or intra-arterial catheter pressure measurement Temperature  Core and/or skin temperatureReproduced with permission from Longnecker DE, Mackey SC, Newman MF, et al: Anesthesiology, 3rd ed. New York, NY: McGraw-Hill Education; 2018.Brunicardi_Ch46_p2027-p2044.indd 203201/03/19 11:04 AM 2033ANESTHESIA FOR SURGICAL PATIENTSCHAPTER 46Table 46-4Types of anesthesia monitors and their propertiesTYPE OF MONITORWHAT IS MEASUREDINVASIVENESSPOTENTIAL FOR COMPLICATIONSPhysical examinationHeart sounds, breath sounds, pulse, color, mental status, etcNoninvasive–Pulse oximetryArterial oxygen saturationNoninvasive–Arterial catheterBlood pressure, acid/base statusInvasive++Noninvasive blood pressure measurementBlood pressureNoninvasive+/–ElectrocardiographyCardiac rhythm, rate, ST segmentsNoninvasive–CapnographyVentilatory, circulatory statusNoninvasive–Electroenceophalogram, bispectral index, etcBrain function, depth of anesthesiaNoninvasive+/–Temperature probeBody temperatureNoninvasive to invasive+/–Central venous pressure, pulmonary artery pressureCardiac function, volume statusInvasive+++Transesophageal echocardiogramCardiac function, volume statusInvasive+++Adapted with permission from Longnecker DE, Mackey SC, Newman MF, et al: Anesthesiology, 3rd ed. New York, NY: McGraw-Hill Education; 2018.anesthetics such as liver transplantation and cardiac surgery, transesophageal echocardiography (TEE) is employed to moni-tor myocardial function and volume status. Intraoperative TEE can also be used to guide surgeons when performing complex cardiac surgeries, including cardiac valve replacements.Monitoring of oxygenation and ventilation includes use of continuous pulse oximetry, monitoring of exhaled end-tidal carbon dioxide (ETCO2), and monitoring of fraction of inspired oxygen. End tidal CO2 monitoring also provides important infor-mation about systemic perfusion. During cardiac arrest, there is no delivery of CO2 to the lungs, and the end-tidal CO2 is thus very low or zero; a sudden spike in end tidal CO2 during cardio-pulmonary resuscitation correlates with return of spontaneous circulation.24 Modern ventilators also measure peak and plateau inspiratory airway pressure and minute ventilation. Adequacy of oxygenation and ventilation can also be confirmed by arterial blood gas analysis.Temperature monitoring is performed using a temperature probe, usually inserted in the esophagus or nasopharynx. Core body temperature can be measured with temperature sensing Foley catheters. Temperature can also be measured at the skin.Several monitors exist that measure depth of anesthesia, including the bispectral index (BIS) monitor and the SedLine monitor. While these monitors were designed to prevent aware-ness under anesthesia, a multicenter trial of over 6000 patients showed that titrating anesthetic concentration to the BIS moni-tor was not superior to titrating anesthetic depth to end-tidal anesthetic concentration with goal MAC greater than 0.7.25Peripheral nerve stimulators should be used to moni-tor depth of neuromuscular blockade. A train-of-four monitor delivers four successive stimuli over 2 seconds. Presence of four twitches without fade with a ratio of the height of the first twitch to the height of the fourth twitch at least 0.9 suggests adequate reversal of neuromuscular blockade.26 The presence of one or two twitches (absence of the last two or three) is generally suffi-cient for the relaxation required for almost any kind of abdomi-nal or thoracic operation.PERIOPERATIVE EVALUATION AND PREPARATIONThe ASA has adopted basic standards for the evaluation of patients before surgery. These standards require the anesthe-siologist to evaluate the medical status of the patient, develop a plan of anesthetic care, and discuss this plan with the patient and/or the patient’s legal guardian.A preoperative evaluation includes an appropriately detailed medical history, current drug therapy, appropriate physical examination, and review of laboratory and specific testing results. Based on these findings, the anesthesiologist may conclude that a patient is not in optimal medical condition to undergo elective surgery. These findings and opinions are then discussed with the patient’s primary physician or surgeon, and the surgery may be delayed (or cancelled) until the patient’s medical condition is further evaluated and optimized.The medical history obtained at the preoperative visit should include the patient’s previous exposure and experi-ence with anesthesia, as well as any family history of problems with anesthesia. History of atopy is an important aspect of this evaluation in that it may predispose patients to form antibodies against antigens that may be represented by agents administered during the perioperative period. Concurrent medications should be fully evaluated when circumstances allow, and adverse inter-actions with agents administered during the perioperative period need to be considered. A review of the function of major organ systems should also be performed. The physical examination is targeted primarily at the central nervous system, cardiovascular system, lungs, and airway.Laboratory testing should be based on the patient’s con-dition and the proposed procedure. Otherwise healthy patients usually do not need laboratory testing for minor procedures. Preoperative testing may be necessitated by findings on physi-cal examination; for example, an electrocardiogram should be obtained if an irregular heart rhythm is noted, and an echo-cardiogram may be indicated if a new murmur is observed on Brunicardi_Ch46_p2027-p2044.indd 203301/03/19 11:04 AM 2034SPECIFIC CONSIDERATIONSPART IIauscultation. Chest imaging or pulmonary function testing may be indicated if abnormalities are noted on pulmonary examina-tion and may be pertinent to the administration of the anesthetic or the recovery from anesthesia and surgery. Urine pregnancy testing is typically performed on the day of surgery in women of childbearing age.ASA Physical Status AssessmentThe ASA classification system is a scale used to risk-stratify patients for anesthesia and surgery. The scale, ranging from physical status I to VI, is shown in Table 46-5. Patients under-going emergent surgery are denoted by an “E”; for example, an otherwise healthy patient undergoing an appendectomy for appendicitis would be classified as ASA IE. Mortality has shown to increase with increasing ASA physical status, and it has been shown to be higher for patients undergoing emergency surgery.27Airway EvaluationAirway examination can identify most patients in whom management of the airway and conventional endotracheal CLASS 1: Soft palate, fauces, uvula, pillarsCLASS 2: Soft palate, fauces, portion of uvulaCLASS 3: Soft palate, base of uvulaCLASS 4: Hard palate onlyMALLAMPATI CLASSIFICATIONCLASS 1CLASS 2CLASS 3CLASS 4Figure 46-3. The Mallampati classification.Table 46-5American Society of Anesthesiologists physical status classificationASA PHYSICAL STATUSDESCRIPTIONIA healthy patient without systemic diseaseIIA patient with mild systemic diseaseIIIA patient with severe systemic diseaseIVA patient with severe systemic disease that is a constant threat to lifeVA moribund patient not expected to survive without the operationVIA declared brain-dead patient whose organs are being removed for donationData from American Society of Anesthesiologists: ASA Physical Status Classification System Developed. ASA House of Delegates/Executive Committee. Amended: October 15, 2014.intubation may be difficult. It is vitally important to recognize such patients before administering medications that induce apnea. The Mallampati classification (Fig. 46-3) is based on the structures visualized with maximal mouth opening and tongue protrusion in the sitting position.28 Patients with higher Mallampati classification, in combination with other airway abnormalities, can be difficult to intubate. Other predictors of difficult intubation include short neck, immobility of the neck,29 a large overbite, a small mandible, or the inability to shift the lower incisors in front of the upper incisors. The thyromental distance, the distance from the thyroid cartilage to the tip of the chin should be greater than 6 cm; thyromental distance of less than 6 cm has been associated with difficult intubation.30 Obesity is also a risk factor for difficult intubation, and neck circumference has been identified as a risk factor for both dif-ficult intubation as well as difficult mask ventilation.31Cardiovascular DiseaseCardiac risk is widely regarded as the most important risk associated with anesthesia and surgery, and it has been the focus of an enormous amount of scholarship over the past four decades. The revised cardiac risk index incorporates six patient and surgical factors to assess a patient’s risk of major adverse cardiac events in the perioperative period: history of ischemic heart disease, congestive heart failure, cerebrovascular dis-ease, diabetes requiring insulin, chronic kidney disease with baseline creatinine greater than 2, and whether the surgery is in a high-risk area, namely major vascular, intraperitoneal, or intrathoracic. In 2014, the American College of Cardiology and the American Heart Association published guidelines for perioperative workup and management of patients with cardio-vascular disease; a simplified version is seen in Fig. 46-4 . Notably, this guideline stresses the importance of func-tional status in determining need for further evaluation; patients with good functional status can typically proceed to surgery without additional evaluation. Functional capacity is measured in metabolic equivalents (METs), with patients unable to attain 4 METs considered to have poor functional status. Activities representing 4 METs including walking up a flight of stairs, climbing a hill, or walking on level ground at 3 to 4 miles per hour.3233Brunicardi_Ch46_p2027-p2044.indd 203401/03/19 11:04 AM 2035ANESTHESIA FOR SURGICAL PATIENTSCHAPTER 46These recent guidelines have minimized the role of routine screening. Preoperative electrocardiograms and stress testing are unnecessary for asymptomatic patients undergoing low-risk surgery.Special attention is required for patients with coronary stents. Elective surgery should be delayed a stent has been inserted, which allows time for it to stabilize and the risk of in-stent thrombosis to decrease. The ACC/AHA guidelines rec-ommend delaying elective surgery for 30 days after bare metal stent placement and for 1 year after drug eluting stent place-ment. Dual antiplatelet therapy should be continued for urgent or emergent procedures that take place before the minimum recommended waiting period.32 For semi-elective surgeries in patients with drug-eluting stents, where the risk of delaying sur-gery is greater than the risk of in-stent thrombosis, ACC/AHA guidelines recommend surgery be delayed for 180 days.Current recommendation is that β-blockers and statins should be continued in patients who are on them chronically. β-Blockers may be started in the perioperative period for patients with multiple RCRI risk factors or who are at intermediate or high risk for myocardial ischemia. If started in the perioperative period, β-blockers should be started long enough before sur-gery to ascertain their safety, and not on the day of surgery.32,33 Recent large randomized trials have demonstrated excess risk of mortality and stroke simultaneously with decreased risk of myocardial events in moderateand high-risk patients who are newly treated with β-blockers in the periprocedural setting.34,35Implanted cardiac devices including pacemakers and implantable cardioverter-defibrillators also have important peri-operative implications. A 2011 ASA practice advisory stressed the importance of determining whether electromagnetic interfer-ence is likely to occur during the planned procedure, determin-ing the current function and necessity of the implanted device, determining whether reprogramming or temporary disabling of the device is advantageous, having alternative therapy available for the time that the device is unavailable, and restoring device function in the postoperative period.36Pulmonary DiseaseChronic pulmonary disease is an increasingly recognized cause of morbidity and mortality in surgical patients. For patients with asthma or chronic obstructive pulmonary disease, exercise toler-ance and the frequency and severity of exacerbations should be evaluated. A focused history, including prior admissions and intubations for exacerbations, should be obtained. Treatment with bronchodilators in the perioperative setting is appropri-ate, although there is no literature to either guide this care or to document a benefit from it. Most inhaled anesthetics act as bronchodilators.37 Desflurane can be an airway irritant, and it is often avoided in patients with reactive airway disease.The incidence of obstructive sleep apnea (OSA) has risen with the incidence of obesity. In 2014 the ASA published guide-lines for perioperative management of patients with OSA. These guidelines highlight the importance of identifying patients with obstructive sleep apnea during preoperative evaluation and obtaining a sleep study if appropriate. They also highlight the importance of the development of protocols by anesthesiologists and surgeons to manage OSA in the perioperative setting. There is consensus that these patients should not be extubated until they are completely awake, and that they should be treated with ACC/AHA algorithm of cardiac evaluation for noncardiac surgeryProceed to surgery with medical riskreduction and perioperative surveillancePostpone surgery until stabilized or correctedNo clinicalpredictorsProceed with surgeryProceed with surgery˜1 clinicalpredictorsIntermediate riskor vascular surgeryProceed with surgeryProceed to surgery with heart ratecontrol or consider noninvasive testingif it will change managementEmergency surgeryActive cardiac conditions• Unstable coronary syndromes (unstable or severe angina, recent MI)• Decompensated heart failure (HF; new onset, NYHA class IV)• Significant arrhythmias (Mobitz ll or third-degree heart block, supraventricular tachycardia or atrial fibrillation with rapid ventricular rate (>100), symptomatic ventricular arrhythmia or bradycardia, new ventricular tachycardia)• Severe valvular disease (severe aortic or mitral stenosis)Step 1Step 2Low-risk surgery (risk <1%)• Superficial or endoscopic• Cataract, breast• Ambulatory surgeryStep 3Functional capacityGood; ≥4 METS (can walk flight of stairs without symptoms)Step 4Clinical predictors• Ischemic heart disease• Compensated or prior HF• Cerebrovascular disease (stroke, TIA)• Diabetes mellitus• Renal insufficiencyStep 5Figure 46-4. Simplified cardiac evaluation for noncardiac surgery. (Data from Eagle KA, Berger PB, Calkins H, et al: ACC/AHA guideline update for perioperative cardiovascular evaluation for noncardiac surgery–executive summary: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Committee to Update the 1996 Guidelines on Perioperative Cardiovascular Evaluation for Noncardiac Surgery), J Am Coll Cardiol. 2002 Feb 6;39(3):542-553.)Brunicardi_Ch46_p2027-p2044.indd 203501/03/19 11:04 AM 2036SPECIFIC CONSIDERATIONSPART IInoninvasive positive pressure ventilation in the postoperative period as indicated.38Renal DiseaseManagement of anesthesia in patients with chronic renal insuf-ficiency requires close attention to perioperative fluid man-agement and acid-base and electrolyte homeostasis. Doses of opioids and neuromuscular agents are typically reduced and dosing intervals increased to compensate for decreased renal excretion. Cisatracurium is often chosen as the muscle relax-ant in patients with severe renal insufficiency because its elimi-nation is unchanged by renal failure. Sugammadex, a reversal agent for steroid-based neuromuscular blockers, is not currently recommended for use in patients with advanced chronic kidney disease or end-stage renal disease.Hepatic DiseaseHepatic dysfunction has many causes, and it can compel significant changes in anesthetic care. First, anesthetic agents metabolized in the liver can accumulate in these patients and may have a longer duration of effect. To mitigate this, short-acting agents are strongly preferred in these patients. Hypoalbuminemia can paradoxically increase the free plasma levels of drugs, which can also exagger-ate their effects. In patients with substantial ascites, high intra-abdominal pressure may increase the risk of passive gastric reflux, and thus many such patients are managed as if they have a full stomach, regardless of how long they have been NPO. In patients with significant hepatocellular dysfunction and/or portal hyperten-sion, the combination of thrombocytopenia and coagulation factor deficiency not only increase the risk of bleeding associated with surgery, they also are relative or absolute contraindications to a variety of anesthetic techniques, such as subarachnoid blocks and epidural anesthesia. Presence of esophageal varices increases the risk of gastric tubes and transesophageal echocardiography.Endocrine DiseasePerioperative management of the diabetic patient can be espe-cially challenging. A hemoglobin A1c level should be obtained if a recent level is not available, as an increased A1c level is asso-ciated with an increase in perioperative complications including wound infections.39-41 Several institutions have implemented pro-tocols for glucose management for diabetic patients undergoing surgery, although recommendations differ on appropriate target glucose levels.39,42,43 Perhaps the most important thing for a prac-titioner to know and remember is that the difference between type 1 and type 2 diabetes is important, and that these two differ-ent diseases require different approaches to their management. In general, patients with type 2 diabetes have a lower risk of becom-ing hypoglycemic, tend to have higher blood sugars at baseline, and tolerate higher levels of serum glucose without significant acute hazard. Patients with type 1 diabetes, who are deficient in insulin production and thus require insulin administration to pre-vent ketosis, are far more likely to become hypoglycemic when subjected to stress, and they are also at risk for developing keto-acidosis with hyperglycemia. Patients with type 1 diabetes merit more careful monitoring of their blood sugars in the periopera-tive setting than patients with type 2 diabetes.44-47Preoperative FastingThe ASA has developed specific guidelines for preoperative fasting to mitigate the risk of aspiration of gastric contents. Table 46-6 shows guidelines for preoperative food and fluid intake for elective procedures. Individual patients may need lengthier fasting times than the guidelines indicate. Notably, a rapid sequence induction and intubation should be considered in patients who are at higher risk for aspiration such as those with very symptomatic gastroesophageal reflux, achala-sia, gastroparesis, or dysmotility, regardless of fasting status.48Patients With Advanced DirectivesPatients with do not resuscitate (DNR) and/or do not intu-bate (DNI) orders present a unique challenge. Patients or their power-of-attorney may choose to rescind these directives in the perioperative period, maintain them as originally ordered, or modify them to allow for a limited resuscitation. Both the ASA and the American College of Surgeons recommend that preoperative discussions with the patient and their family clarify the patient’s wishes, and both societies emphasize that policies that mandate uniform enforcement or disregarding of all DNR orders take away patients’ right to self-determination.49,50Risk EstimationSeveral risk calculators have been developed to estimate peri-operative morbidity and mortality. The American College of Surgeons National Surgical Quality Improvement Program (NSQIP) surgical risk calculator allows for estimation of risk of eight different adverse outcomes, including mortality.51 The Society of Thoracic Surgeons risk calculator estimates risk of morbidity and mortality after cardiac surgical procedures.52 While such risk estimators can provide widely differing esti-mates or may be inaccurate in certain situations,53 they are still invaluable aids for discussions with patients and their families about high-risk surgery.INTRAOPERATIVE MANAGEMENTGeneral AnesthesiaGeneral anesthesia remains the cornerstone of anesthesia prac-tice; many surgical procedures cannot be done under regional techniques or monitored anesthesia care with sedation.The induction of general anesthesia can precipitate cata-strophic anesthetic complications. Many different techniques can be used to induce general anesthesia, each with significant advantages and disadvantages.Intravenous induction, used primarily in adults, quickly produces unconsciousness, and depending on the agent used, apnea as well. Propofol, the most common induction agent currently used, can cause hypotension due to its myocardial depressing and vasodilatory properties. Hypertension and 4Table 46-6Guidelines for food and fluid intake before elective surgeryTIME BEFORE SURGERYFOOD OR FLUID INTAKEUp to 8 hoursFood and fluids as desiredUp to 6 hoursaLight meal, infant formulaUp to 4 hoursBreast milkUp to 2 hoursClear liquids onlyaLight meal refers to a limited amount of easily digestible food, such as toast or crackers. Individual patients may need lengthier fasting times than these guidelines indicate.Adapted with permission from Longnecker DE, Mackey SC, Newman MF, et al: Anesthesiology, 3rd ed. New York, NY: McGraw-Hill Education; 2018.Brunicardi_Ch46_p2027-p2044.indd 203601/03/19 11:04 AM 2037ANESTHESIA FOR SURGICAL PATIENTSCHAPTER 46tachycardia commonly occur during laryngoscopy or other sig-nificant airway stimulation.The goal of a rapid sequence induction (RSI) is to achieve secure protection of the airway with a cuffed endotracheal tube without ever mask ventilating a patient. It is intended to prevent vomiting and aspiration, and it is routinely employed in patients at heightened risk for aspiration. There are no randomized con-trolled trials that demonstrate any kind of outcome benefit of rapid sequence induction in such patients, but it is nevertheless routinely employed for this purpose in the United States.Pediatric patients are often not amenable to preoperative IV catheter placement. Hence, inhalation induction of anesthe-sia is commonly used in children, with IV placement occur-ring after induction. Even among children, however, patients at heightened risk for aspiration or with a full stomach may be best managed with preoperative IV placement and an IV induction. Patients with developmental delay may not be amenable to pre-operative IV placement or inhalational induction of anesthesia. In such patients, intramuscular administration of an agent such as ketamine is often required to induce anesthesia.Airway Management. Most anesthesiologists prefer to secure the airway of a patient undergoing general anesthesia, and this is usually accomplished immediately after anesthesia has been induced. The airway may be managed in several ways, includ-ing by face mask, with a laryngeal mask airway (LMA), or, most definitively, by endotracheal intubation with a cuffed endotracheal tube. Nasal and oral airways can help establish a patent airway in a patient being ventilated with a mask by creat-ing an air passage behind the tongue.The LMA is a cuffed supraglottic oral airway that is inserted through the oropharynx and ideally positioned just above the glottis opening. It is passed blindly, and the inflated cuff creates a seal around the laryngeal inlet. An LMA does not protect against aspiration and should generally not be used in patients with a high risk of aspiration.Tracheal intubation requires a skilled operator and proper equipment. In most elective anesthetics, attempts to intubate the trachea are facilitated by the administration of muscle relaxants in a patient who is already under a general anesthetic. Intubation is typically performed under direct visualization with a laryn-goscope, watching the endotracheal tube pass through the vocal cords into the trachea. To obtain a direct line of sight, the patient is placed in the sniffing position. The neck is flexed at the lower cervical spine and extended at the atlanto-occipital joint. This flexion and extension are amplified during laryngoscopy. Laryn-goscope blades can be curved (Macintosh) or straight (Miller) blades. Laryngoscopic views are typically reported in a classi-fication system developed by Cormack and Lehane (Fig. 46-5).Management of the Difficult Airway. Some patients have physical characteristics or a history suggestive of difficulty in placing an endotracheal tube. A short neck, limited neck mobil-ity, small interincisor distance, short thyromental distance, and high Mallampati classes may all represent a challenge to Figure 46-5. Laryngoscopic views obtained per Cormack and Lehane.Figure 46-6. Video laryngoscopy with the GlideScope.endotracheal intubation. Several tools have been developed to assist in management of the difficult airway.The Glidescope, a video laryngoscope, allows for visualiza-tion of the larynx on a video screen (Fig. 46-6). Having more of a bend than a standard curved Macintosh blade, it can be advanta-geous for visualizing and intubating the trachea in patients with large tongues or relatively anterior glottis openings. Placement of the endotracheal tube once the larynx has been visualized can still be challenging. A recent study of ICU patients requiring intubation showed that video laryngoscopy did not improve first-pass orotracheal intubation success rate and was associated with higher rates of severe life-threatening complications.54The intubating laryngeal mask airway (ILMA) is an advanced form of LMA designed to maintain a patent airway and facilitate tracheal intubation. The ILMA can be placed in anticipated or unexpectedly difficult airways as an airway res-cue device and as a guide for intubating the trachea. The device itself is substantially more rigid than other laryngeal mask airways, and includes a handle which the operator can use to displace the opening of the device. A specially manufactured endotracheal tube can be passed blindly through the ILMA into the larynx, or the ILMA can be used as a conduit for a flex-ible fiberoptic scope. Experience with airway management in general and the use of this device in particular is essential for its effective use in emergency situations; operators with little experience will enjoy little success with this device.The flexible fiberoptic intubation bronchoscope is the gold standard for difficult intubation. It is indicated in difficult or compromised airways where neck extension is not desirable or in cases with risk of dental damage. The flexible bronchoscope allows excellent visualization of the airway and glottic open-ing. This technique can be used for oral and nasal intubation, for awake or asleep intubation, and for intubation in the awake, spontaneously ventilating patient whose airway has been treated with topical local anesthetic.The ASA has developed an algorithm for management of the difficult airway (Fig. 46-7).55 Notably, in patients in whom Brunicardi_Ch46_p2027-p2044.indd 203701/03/19 11:04 AM 2038SPECIFIC CONSIDERATIONSPART IIFigure 46-7. ASA difficult airway algorithm. (Reproduced with permission from Apfelbaum JL, Hagberg CA, Caplan RA, et al: Practice guidelines for management of the difficult airway: an updated report by the American Society of Anesthesiologists Task Force on Management of the Difficult Airway, Anesthesiology. 2013 Feb;118(2):251-270.)Brunicardi_Ch46_p2027-p2044.indd 203801/03/19 11:04 AM 2039ANESTHESIA FOR SURGICAL PATIENTSCHAPTER 46both intubation and ventilation are impossible, the algorithm calls for placement of an LMA with ventilation attempted through the LMA.Monitored Anesthesia CareMonitored anesthesia care (MAC) is when a patient under-goes a procedure under local anesthesia under the care of an anesthesiologist who can provide sedation as indicated. Seda-tion is administered to a level that allows the patient to main-tain airway reflexes and breath spontaneously. Advantages of MAC anesthesia include reduced invasiveness, as the airway is not manipulated, and faster recovery. ASA standard moni-tors must be used, including capnography, which allows for rapid detection of apnea or hypoventilation. In some instances, most commonly for gastroenterology procedures, patients are administered an intravenous anesthetic that is often classified as a MAC, even though the patient is so deeply anesthetized that they have no significant response to significant airway stimula-tion; the airway is monitored by the anesthesia provider and secured if necessary.Regional Anesthesia/Acute PainRegional anesthesia allows for selective blockade and is an excellent anesthetic option for several different types of pro-cedures. Regional anesthesia can also provide excellent post-operative pain control. Regional techniques include neuraxial blockade, including spinal and epidural anesthetics, peripheral nerve blocks, and truncal blocks.Spinal anesthetics (also referred to as subarachnoid blocks) can be used for lower extremity, lower abdominal, pelvic, and urologic and gynecologic procedures. A small caliber needle (typically 25-gauge or smaller) is inserted into the intrathecal space in the cauda aquina and below the conus medularis, and a small volume of local anesthetic is injected. Duration and level of the block in the spinal cord is affected by the anesthetic used, the dose employed, and baricity of solution injected. Complica-tions can include hypotension, bradycardia, postdural puncture headache, injury to local structures or nerves, and hematoma formation. The American Society of Regional Anesthesia pub-lishes guidelines regarding safe intervals to perform neuraxial anesthetics after the administration of anticoagulant and anti-platelet agents.An epidural catheter can be used as a primary anesthetic for a procedure, or it can be placed preoperatively and used in conjunction with a general anesthetic for postoperative pain control. Epidural catheters can be placed in the thoracic or lumbar spine and can remain in place for days after surgery. A dilute local anesthetic and/or opioid is administered through the catheter to provide analgesia. Complications of epidural anesthesia are similar to that of spinal anesthesia. In addition to improved pain control, benefits of epidural anesthesia include reduced pulmonary complications56 and decreased duration of postoperative ileus.57Peripheral nerve blockade can also be used to provide sur-gical anesthesia as well as postoperative analgesia, particularly for surgeries of the upper or lower extremities. The nerve or plexus of interest is located with ultrasound and/or peripheral nerve stimulator, and local anesthetic is injected around the nerve. Single-shot nerve blocks allow for surgical anesthesia and immediate postoperative analgesia and can last for several hours. Flexible catheters can also be placed in proximity to nerves to allow for continuous infusion and blockade that can continue for several days. Complications of peripheral nerve blocks include injury to nerves or nearby structures and local anesthetic systemic toxicity.Recently, truncal blocks have become more commonly and widely used for the treatment of postoperative pain. Trun-cal blocks include the transversus abdominis plane (TAP) block, the rectus sheath block, the pectoral nerve block, and the serra-tus anterior plane block. These truncal blocks are usually done under ultrasound guidance with local anesthetic injected in the appropriate plane. Truncal blocks are typically performed as part of a multimodal approach to postoperative pain. Limited evidence suggests that use of truncal blocks decreases postop-erative opioid requirements.58,59RECOVERY AND COMPLICATIONSThe Postanesthesia Care UnitThe advent of the modern postanesthesia care unit represents a major advance in the safety of perioperative care, as the close monitoring that occurs there can prevent or expedite the man-agement of a variety of serious complications. Ventilation, oxygenation, hemodynamics, temperature, nausea, and pain are closely monitored in the PACU, with close attention also given to urine output, ongoing bleeding, and drainage. To be dis-charge eligible, patients should have returned to their baseline mental status, be oxygenating and ventilating adequately, have adequate pain control, and have stable vital signs. There are multiple scoring systems that can be used assess suitability for discharge from PACU.60-62 Postoperative hemorrhage, hyper-tension or hypotension, myocardial ischemia, arrhythmias, and altered mental status commonly manifest in the postoperative care unit. Postoperative nausea and vomiting (PONV) occurs in 20% to 30% of surgical cases,63 and it is a common cause of increased PACU length of stay and increased cost of PACU stay.64 For this reason, many or most patients undergoing gen-eral anesthesia receive prophylactic antiemetics.Enhanced Recovery After Surgery PathwaysEnhanced recovery after surgery (ERAS) pathways are multi-modal perioperative care pathways designed to hasten recovery after elective surgery. These pathways may include preoperative education and counseling, preoperative optimization, limiting preoperative bowel preparation, limiting preoperative fasting, providing multimodal analgesia (including regional anesthesia) as appropriate, minimizing intraoperative fluid administration, and early mobilization. ERAS pathways have been shown to reduce duration of hospitalization and reduce cost of periopera-tive care.65-67Acute Postoperative PainThe management of postoperative pain has changed dra-matically in the modern era, with multimodal approaches and regional techniques reducing the use of opiates. Regardless, opioids remain the mainstay of intraoperative and postoperative analgesia, especially for larger and more invasive procedures. Patients with chronic pain or opiate tolerance can present a unique challenge in the perioperative period, and they can ben-efit from regional and multimodal approaches. Such patients may benefit from early involvement of an acute pain medicine specialist.For the past decade, pain has been described as the fifth vital sign, and physicians have been strongly encouraged to 5Brunicardi_Ch46_p2027-p2044.indd 203901/03/19 11:04 AM 2040SPECIFIC CONSIDERATIONSPART IIaggressively treat pain in their patients. Generally speaking, physicians sought to accomplish this goal through the more liberal use of opiates. Opioid prescription has thus soared in recent years. Some studies suggest that 3% to 7% of surgical patients prescribed opioids in the postoperative period continue to use them for a prolonged period after surgery,68,69 suggesting that opioid abuse often begins in the postoperative period. The U.S. Centers for Disease Control and Prevention has recently declared that prescription drug abuse is an epidemic.70 Physi-cians and surgeons will have to continue to seek the fine line between adequate pain control and prescribing patterns that enable dependence.Malignant HyperthermiaMalignant hyperthermia (MH) is a hereditary, life-threatening, hypermetabolic disorder, developing during or after receiving general anesthesia. The clinical incidence of MH ranges from 1:10000 to 1:250,000.71 A genetic predisposition and expo-sure to one or more triggering agents are necessary to evoke MH. Triggering agents include all volatile anesthetics (e.g., isoflurane, sevoflurane, and desflurane) and the depolarizing neuromuscular blocker succinylcholine. Volatile anesthetics and/or succinylcholine cause a rise in the myoplasmic cal-cium concentration in susceptible patients, causing persistent muscle contraction, the production of large quantities of car-bon dioxide and lactic acid, and a relentless increase in body temperature.MH is often an autosomal dominant disorder associated with several gene loci, predominantly the ryanodine receptor gene RYR1. MH can be diagnosed with the caffeine-contracture halothane test, which requires a muscle biopsy. Genetic testing can be helpful after an episode of MH. There is no simple, reli-able blood screening test yet available for diagnosis.The classic MH crisis entails a hypermetabolic state with tachycardia and increased end-tidal CO2. Relentless muscle con-traction causes respiratory and metabolic acidosis, as well as rhabdomyolysis, arrhythmias, hyperkalemia, and even sudden cardiac arrest. Hyperthermia typically occurs after the episode is well under way. Treatment must be aggressive and begin as soon as a case of MH is suspected. Volatile anesthetics should be stopped immediately and dantrolene given at an initial dose of 2.5 mg/kg intravenously. The national MH hotline should be contacted for help in managing any patient with MH. Patients should be monitored in the intensive care setting for possible recrudescence of MH.Cardiovascular ComplicationsHemodynamic perturbations are a common in the periopera-tive period. Arrhythmias may begin before, during, and after an anesthetic, and are particularly common after cardiothoracic and esophageal surgery. Hypotension may be due to anemia, hypovolemia, myocardial ischemia or dysfunction, or other less common events such as pulmonary embolism and ana-phylactic reactions. Hypertension is also common, particularly when antihypertensive regimens are altered in the perioperative period.Respiratory FailureRespiratory insufficiency and failure occur frequently in the postoperative period. Respiratory depression can occur as a con-sequence of residual neuromuscular blockade, residual inhaled anesthetics, or opioids. Mechanical airway obstruction can be ameliorated by rescue maneuvers, or insertion of an oral or nasal airway. It is imperative to evaluate and treat anesthesia-related causes of respiratory insufficiency. The opioid antagonist nalox-one can be given for opioid related respiratory insufficiency, and an additional reversal agent can be given for residual neuromus-cular weakness. Respiratory failure can reasonably be managed with noninvasive positive pressure ventilation in many cases72; patients who fail this or are unlikely to benefit from it should be intubated. High-flow nasal cannula is increasingly being used for postextubation respiratory failure,73 and several studies have demonstrated its benefit in postoperative patients.74-77Neurologic and Psychiatric ComplicationsPerioperative neurologic and psychiatric complications include stroke, both ischemic and hemorrhagic, postoperative delirium, and postoperative cognitive dysfunction. Treatment of periop-erative stroke may be difficult as initiation of anticoagulation or thrombolysis may not be safe after surgery. Postoperative delirium is common and transient. Treatment includes reorienta-tion, treatment of pain, workup for metabolic, hemodynamic, or respiratory perturbations, and consideration of the side effects of the anesthetics and analgesics administered. Antipsychotics such as haloperidol can be useful in the treatment of postopera-tive delirium.78 Postoperative cognitive dysfunction (POCD) is a decline in cognitive function that may last days or may persist for months. Risk factors for persistent POCD include advanced age, history of prior stroke, and lower educational level.79 POCD rates among older adult patients have been shown to be as high as 40% at hospital discharge and 12% 3 months after surgery. Notably, a causal link has not been established between administration of anesthesia and development of POCD, sug-gesting that it may be the physiologic stress of the perioperative experience that may lead to a decline in cognitive function in such patients.80CONCLUSIONThe practice of anesthesia has improved dramatically over the past century. Advances in training, pharmacology, anesthesia equipment, and monitoring have not only made anesthesia dra-matically safer but have also allowed ever sicker patients to benefit from surgery.REFERENCESEntries highlighted in bright blue are key references. 1. Haridas RP. Horace wells’ demonstration of nitrous oxide in Boston. Anesthesiology. 2013;119:1014-1022. 2. Bigelow HJ. insensibility during surgical operations produced by inhalation. Boston Med Surg J. 1846;35:309-317. This arti-cle, published in the predecessor to the New England Journal of Medicine, described the first public demonstration of ether at the Massachusetts General Hospital. 3. Buckley K. The most important article in NEJM history. 2012. Available at: https://blogs.nejm.org/now/index.php/explore-the-history-of-medical-discoveries/2012/01/26/. Accessed August 20, 2018. 4. Kim TK OS, Johnson KB. Basic Principles of pharmacology. In: Miller RD, Eriksson LI, Fleisher LA, Wiener-Kronish JP, Cohen N, Young WL, eds. Miller’s Anesthesia. 8th ed. Philadelphia: Elsevier; 2015:590-613. 5. Forman SA, Benkwitz C. Pharmacology of inhalational anesthetics. In: Longnecker DE, Brown DL, Newman MF, Zapol WM, eds. Anesthesiology. New York: McGraw-Hill; 2012:596-616.Brunicardi_Ch46_p2027-p2044.indd 204001/03/19 11:04 AM 2041ANESTHESIA FOR SURGICAL PATIENTSCHAPTER 46 6. Myles PS, Leslie K, Chan MT, et al. The safety of addition of nitrous oxide to general anaesthesia in at-risk patients hav-ing major non-cardiac surgery (ENIGMA-II): a randomised, single-blind trial. Lancet (London, England). 2014;384: 1446-1454. This randomized, controlled trial demonstrated the safety of a largely nitrous-oxide based general anesthetic technique. 7. Dershwitz M RC. Pharmacology of intravenous anesthetics. In: Longnecker DE, Brown DL, Newman MF, Zapol WM, eds. Anesthesiology. New York: McGraw-Hill; 2012:687-702. 8. Wagner RL, White PF, Kan PB, et al. Inhibition of adrenal steroidogenesis by the anesthetic etomidate. N Engl J Med. 1984;310:1415-1421. 9. Annane D, Sebille V, Charpentier C, et al. Effect of treat-ment with low doses of hydrocortisone and fludrocortisone on mortality in patients with septic shock. JAMA. 2002;288: 862-871. 10. McPhee LC, Badawi O, Fraser GL, et al. Single-dose etomidate is not associated with increased mortality in ICU patients with sepsis: analysis of a large electronic ICU database. Crit Care Med. 2013;41:774-783. 11. Absalom A, Pledger D, Kong A. Adrenocortical function in critically ill patients 24 h after a single dose of etomidate. Anaesthesia. 1999;54:861-867. 12. Hohl CM, Kelly-Smith CH, Yeung TC, et al. The effect of a bolus dose of etomidate on cortisol levels, mortality, and health services utilization: a systematic review. Ann Emerg Med. 2010;56:105-113.e105. 13. Mozanski M, Tomaszewski D, Rybicki Z, et al. Etomidate, but not thiopental, decreases serum cortisol concentration in mor-bidly obese patients. A randomized controlled trial. Anaesthe-siol Intensive Ther. 2016;48:7-12. 14. Su S, Ren C, Zhang H, et al. The Opioid-sparing effect of perioperative dexmedetomidine plus sufentanil infusion dur-ing neurosurgery: a retrospective study. Front Pharmacol. 2016;7:407. 15. Jessen Lundorf L, Korvenius Nedergaard H, Moller AM. Peri-operative dexmedetomidine for acute pain after abdominal sur-gery in adults. Cochrane Database Syst Rev. 2016;2:Cd010358. 16. Rosow CE, Dershwitz M. Pharmacology of opioid anesthetics. In: Longnecker DE, Brown DL, Newman MF, Zapol WM, eds. Anesthesiology. New York: McGraw-Hill; 2012:703-724. 17. Kraft M, MacLaren R, Du W, et al. Alvimopan (Entereg) for the management of postoperative ileus in patients undergoing bowel resection. Pharm Therapeut. 2010;35:44-49. 18. Chen L MJ, Mao J. Nonopioid pain medications, In: Miller RD, Eriksson LI, Fleisher LA, Wiener-Kronish JP, Cohen N, Young WL, eds. Miller’s Anesthesia. 8th ed. Philadelphia: Elsevier; 2015:915-918. 19. Weibel S, Jokinen J, Pace NL, et al.. Efficacy and safety of intravenous lidocaine for postoperative analgesia and recovery after surgery: a systematic review with trial sequential analysis. Br J Anaesth. 2016;116:770-783. 20. Christie LE, Picard J, Weinberg GL. Local anaesthetic systemic toxicity. BJA Educ. 2015;15:136-142. 21. Heavner JE. Pharmacology of local anesthetics. In: Longnecker DE, Brown DL, Newman MF, Zapol WM, eds. Anesthesiology. New York: McGraw-Hill; 2012:767-782. 22. Naguib M, Lien C, Meistelman C. Pharmacology of neuromus-cular blocking drugs. In: Miller RD, Eriksson LI, Fleisher LA, Wiener-Kronish JP, Cohen N, Young WL, eds. Miller’s Anes-thesia. 8th ed. Philadelphia: Elsevier; 2015:958-994. 23. Naguib M, Samarkandi AH, El-Din ME, et al. The dose of succinylcholine required for excellent endotracheal intubating conditions. Anesth Analg. 2006;102:151-155. 24. Kodali BS, Urman RD. Capnography during cardiopulmonary resuscitation: current evidence and future directions. J Emerg Trauma Shock. 2014;7:332-340. This article reviews the impor-tance of capnography during cardiopulmonary resuscitation. 25. Avidan MS, Jacobsohn E, Glick D, et al. Prevention of intraoperative awareness in a high-risk surgical population. N Engl J Med. 2011;365:591-600. This landmark study dem-onstrated no reduction of intraoperative awareness rates with use of the bispectral index monitor over monitoring anesthetic gas concentration. 26. Lien CA, Kopman AF. Current recommendations for monitor-ing depth of neuromuscular blockade. Curr Opin Anaesthesiol. 2014;27:616-622. 27. Hopkins TJ, Raghunathan K, Barbeito A, et al. Associations between ASA physical status and postoperative mortality at 48 h: a contemporary dataset analysis compared to a historical cohort. Perioper Med (London, England). 2016;5:29. 28. Mallampati SR, Gatt SP, Gugino LD, et al. A clinical sign to predict difficult tracheal intubation: a prospective study. Can Anaesth Soc J. 1985;32:429-434. Dr. Mallampati’s land-mark study set the standard for preoperative airway exami-nation, and the classification system described assists with prediction of difficult intubation. 29. Crosby ET. Airway management in adults after cervical spine trauma. Anesthesiology. 2006;104:1293-1318. 30. Shiga T, Wajima Z, Inoue T, et al. Predicting difficult intuba-tion in apparently normal patients: a meta-analysis of bedside screening test performance. Anesthesiology. 2005;103:429-437. 31. Riad W, Vaez MN, Raveendran R, et al. Neck circumference as a predictor of difficult intubation and difficult mask ventilation in morbidly obese patients: a prospective observational study. Eur J Anaesthesiol. 2016;33:244-249. 32. Fleisher LA, Fleischmann KE, Auerbach AD, et al. 2014 ACC/AHA guideline on perioperative cardiovascular evaluation and management of patients undergoing noncardiac surgery: executive summary: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines. Circulation. 2014;130:2215-2245. The ACC/AHA guidelines have set the standard for preoperative cardiovascular evaluation and management for patients undergoing noncardiac surgery. 33. London MJ, Hur K, Schwartz GG, et al. Association of peri-operative beta-blockade with mortality and cardiovascu-lar morbidity following major noncardiac surgery. JAMA. 2013;309:1704-1713. 34. Blessberger H, Kammler J, Domanovits H, et al. Periopera-tive beta-blockers for preventing surgery-related mortality and morbidity. Cochrane Database Syst Rev. 2014;Cd004476. 35. Devereaux PJ, Yang H, Yusuf S, et al. Effects of extended-release metoprolol succinate in patients undergoing non-cardiac surgery (POISE trial): a randomised controlled trial. Lancet (London, England). 2008;371:1839-1847. 36. American Society of Anesthesiologists. Practice advisory for the perioperative management of patients with cardiac implantable electronic devices: pacemakers and implantable cardioverter-defibrillators: an updated report by the American Society of Anesthesiologists task force on perioperative management of patients with cardiac implantable electronic devices. Anesthesiology. 2011;114:247-261. 37. Mutlu GM, Factor P, Schwartz DE, et al. Severe status asthmat-icus: management with permissive hypercapnia and inhalation anesthesia. Crit Care Med. 2002;30:477-480. 38. American Society of Anesthesiologists. Practice guidelines for the perioperative management of patients with obstructive sleep apnea: an updated report by the American Society of Anesthesi-ologists task force on perioperative management of patients with obstructive sleep apnea. Anesthesiology. 2014;120:268-286. 39. Stryker LS, Abdel MP, Morrey ME, et al. Elevated postop-erative blood glucose and preoperative hemoglobin A1C are Brunicardi_Ch46_p2027-p2044.indd 204101/03/19 11:04 AM 2042SPECIFIC CONSIDERATIONSPART IIassociated with increased wound complications following total joint arthroplasty. J Bone Joint Surg. 2013;95:808-814, s801-s802. 40. Alserius T, Anderson RE, Hammar N, et al. Elevated glycosyl-ated haemoglobin (HbA1c) is a risk marker in coronary artery bypass surgery. Scand Cardiovasc J. 2008;42:392-398. 41. Halkos ME, Puskas JD, Lattouf OM, et al. Elevated preopera-tive hemoglobin A1c level is predictive of adverse events after coronary artery bypass surgery. J Thorac Cardiovasc Surg. 2008;136:631-640. 42. Dhatariya K, Levy N, Kilvert A, et al. NHS Diabetes guideline for the perioperative management of the adult patient with dia-betes. Diabet Med. 2012;29:420-433. 43. Joshi GP, Chung F, Vann MA, et al. Society for Ambulatory Anesthesia consensus statement on perioperative blood glucose management in diabetic patients undergoing ambulatory sur-gery. Anesth Analg. 2010;111:1378-1387. 44. Sudhakaran S, Surani SR. Guidelines for perioperative manage-ment of the diabetic patient. Surg Res Pract. 2015;2015:284063. 45. Sebranek JJ, Lugli AK, Coursin DB. Glycaemic control in the perioperative period. Br J Anaesth. 2013;111(suppl 1):i18-i34. 46. Duncan AE. Hyperglycemia and perioperative glucose man-agement. Curr Pharm Des. 2012;18:6195-6203. 47. Lipshutz AKM, Gropper MA. Perioperative glycemic control: an evidence-based review. Anesthesiology. 2009;110:408-421. 48. American Society of Anesthesiologists. Practice guidelines for preoperative fasting and the use of pharmacologic agents to reduce the risk of pulmonary aspiration: application to healthy patients undergoing elective procedures: an updated report by the American Society of Anesthesiologists com-mittee on standards and practice parameters. Anesthesiology. 2011;114:495-511. 49. American College of Surgeons. Statement on advance direc-tives by patients: “do not resuscitate” in the operating room. Bull Am Coll Surg. 2014;99:42-43. 50. American Society of Anesthesiologists. Ethical guidelines for the anesthesia care of patients with do-not-resuscitate orders or other directives that limit treatment. Available at: https://www .asahq.org/resources/ethics-and-professionalism. Accessed August 20, 2018. 51. Bilimoria KY, Liu Y, Paruch JL, et al. Development and evalu-ation of the universal ACS NSQIP surgical risk calculator: a decision aid and informed consent tool for patients and sur-geons. J Am Coll Surg. 2013;217:833-842.e831-833. 52. Prins C, De Villiers Jonker I, Smit FE, et al. Cardiac surgery risk-stratification models. Cardiovasc J Africa. 2012;23:160-164. 53. Johnson C, Campwala I, Gupta S. Examining the validity of the ACS-NSQIP Risk Calculator in plastic surgery: lack of input specificity, outcome variability and imprecise risk calculations. J Invest Med. 2017;65:722-725. 54. Lascarrou JB, Boisrame-Helms J, Bailly A, et al. Video laryngoscopy vs direct laryngoscopy on successful first-pass orotracheal intubation among ICU patients: a randomized clinical trial. JAMA. 2017;317:483-493. This recent study showed no difference in rates of successful first-pass intubation between direct laryngoscopy and video laryngoscopy. 55. Apfelbaum JL, Hagberg CA, Caplan RA, et al. Prac-tice guidelines for management of the difficult airwayan updated report by the American Society of Anesthesiologists task force on management of the difficult airway. Anesthesi-ology. 2013;118:251-270. The ASA Difficult Airway Algorithm, last updated in 2013, provides guidelines for management of patients with expected or unexpected difficult airways. 56. Popping DM, Elia N, Marret E, et al. Protective effects of epi-dural analgesia on pulmonary complications after abdominal and thoracic surgery: a meta-analysis. Arch Surg. (Chicago, IL 1960). 2008;143:990-999; discussion 1000. 57. Manion SC, Brennan TJ. Thoracic epidural analgesia and acute pain management. Anesthesiology. 2011;115:181-188. 58. Bashandy GMN, Elkholy AHH. Reducing postoperative opioid consumption by adding an ultrasound-guided rectus sheath block to multimodal analgesia for abdominal cancer surgery with midline incision. Anesthesiol Pain Med. 2014; 4:e18263. 59. Ris F, Findlay JM, Hompes R, et al. Addition of transversus abdominis plane block to patient controlled analgesia for lapa-roscopic high anterior resection improves analgesia, reduces opioid requirement and expedites recovery of bowel function. Ann R Coll Surg Engl. 2014;96:579-585. 60. Palumbo P, Tellan G, Perotti B, et al. Modified PADSS (post anaesthetic discharge scoring system) for monitoring outpa-tients discharge. Ann Ital Chir. 2013;84:661-665. 61. Phillips NM, Street M, Kent B, et al. Post-anaesthetic discharge scoring criteria: key findings from a systematic review. Int J Evid Based Healthc. 2013;11:275-284. 62. Phillips NM, Haesler E, Street M, et al. Post-anaesthetic dis-charge scoring criteria: a systematic review. JBI Libr Syst Rev. 2011;9:1679-1713. 63. Watcha MF, White PF. Postoperative nausea and vomit-ing. Its etiology, treatment, and prevention. Anesthesiology. 1992;77:162-184. 64. Habib AS, Chen YT, Taguchi A, et al. Postoperative nausea and vomiting following inpatient surgeries in a teaching hospital: a retrospective database analysis. Curr Med Res Opin. 2006;22: 1093-1099. 65. Eskicioglu C, Forbes SS, Aarts MA, et al. Enhanced recovery after surgery (ERAS) programs for patients having colorectal surgery: a meta-analysis of randomized trials. J Gastrointest Surg. 2009;13:2321-2329. 66. Sammour T, Zargar-Shoshtari K, Bhat A, et al. A programme of enhanced recovery after surgery (ERAS) is a cost-effective intervention in elective colonic surgery. N Z Med J. 2010; 123:61-70. 67. Reurings JC, Spanjersberg WR, Oostvogel HJ, et al. A prospec-tive cohort study to investigate cost-minimisation, of Traditional open, open fAst track recovery and laParoscopic fASt track mul-timodal management, for surgical patients with colon carcinomas (TAPAS study). BMC Surg. 2010;10:18. 68. Carroll I, Barelka P, Wang CK, et al. A pilot cohort study of the determinants of longitudinal opioid use after surgery. Anesth Analg. 2012;115:694-702. 69. Clarke H, Soneji N, Ko DT, et al. Rates and risk factors for pro-longed opioid use after major surgery: population based cohort study. BMJ. 2014;348:g1251. 70. CDC grand rounds: prescription drug overdoses—a U.S. epi-demic. MMWR Morb Mortal Wkly Rep. 2012;61:10-13. 71. Rosenberg H, Pollock N, Schiemann A, et al. Malignant hyper-thermia: a review. Orphanet J Rare Dis. 2015;10:93. 72. Jaber S, Lescot T, Futier E, et al. Effect of noninvasive ventila-tion on tracheal reintubation among patients with hypoxemic respiratory failure following abdominal surgery: a randomized clinical trial. JAMA. 2016;315:1345-1353. 73. Hernandez G, Vaquero C, Gonzalez P, et al. Effect of postextu-bation high-flow nasal cannula vs conventional oxygen therapy on reintubation in low-risk patients: a randomized clinical trial. JAMA. 2016;315:1354-1361. 74. Corley A, Bull T, Spooner AJ, et al. Direct extubation onto high-flow nasal cannulae post-cardiac surgery versus standard treatment in patients with a BMI >/=30: a randomised con-trolled trial. Intensive Care Med. 2015;41:887-894. 75. Ansari BM, Hogan MP, Collier TJ, et al. A randomized con-trolled trial of high-flow nasal oxygen (optiflow) as part of an enhanced recovery program after lung resection surgery. Ann Thorac Surg. 2016;101:459-464.Brunicardi_Ch46_p2027-p2044.indd 204201/03/19 11:04 AM 2043ANESTHESIA FOR SURGICAL PATIENTSCHAPTER 46 76. Parke R, McGuinness S, Dixon R, et al. Open-label, phase II study of routine high-flow nasal oxygen therapy in cardiac sur-gical patients. Br J Anaesth. 2013;111:925-931. 77. Stephan F, Barrucand B, Petit P, et al. High-flow nasal oxygen vs noninvasive positive airway pressure in hypoxemic patients after cardiothoracic surgery: a randomized clinical trial. JAMA. 2015;313:2331-2339. 78. Vijayakumar B, Elango P, Ganessan R. Post-operative delirium in elderly patients. Indian J Anaesth. 2014;58:251-256. 79. Monk TG, Weldon BC, Garvan CW, et al. Predictors of cogni-tive dysfunction after major noncardiac surgery. Anesthesiology. 2008;108:18-30. 80. Crosby G, Culley DJ, Hyman BT. Preoperative cognitive assessment of the elderly surgical patient: a call for action. Anesthesiology. 2011;114:1265-1268.Brunicardi_Ch46_p2027-p2044.indd 204301/03/19 11:04 AM
Brunicardi_Ch46_p2027-p2044.indd 204401/03/19 11:04 AMThis page intentionally left blankSurgical Considerations in Older AdultsAnne M. Suskind and Emily Finlayson 47chapterINTRODUCTIONAs the population ages, an increasing number of older adults will develop surgical diseases. The segment of the U.S. popu-lation age 65 and older is expected to double by 2050. Older adults present unique challenges in surgical management and decision-making. The accumulation of comorbid conditions and physiologic vulnerability that occurs with age put older adults at high risk for major morbidity and mortality after sur-gery. It is essential that surgeons approach this population with a new set of skills and knowledge to provide optimal care for this vulnerable population. A comprehensive understanding of the unique vulnerabilities of older adults—geriatric syndromes and risk factors—are required to accurately estimate surgical risk, inform surgical decision-making, and guide perioperative management. In this chapter, we will (a) discuss the physiologic conditions that are common in older adults that are essential for surgical risk assessment of older adults considering surgery, (b) describe best practices in perioperative care in the older adult, and (c) discuss special considerations and common pitfalls for surgical conditions that are common in the older adult.GERIATRIC SYNDROMESApproximately one-third of older individuals undergoing vascu-lar and urologic surgery suffer from geriatric syndromes.1,2 This term is used to describe clinical conditions that do not fit into discrete disease categories but that can substantially negatively impact quality of life and result in disability. Geriat-ric syndromes often involve multiple underlying factors and organ systems (i.e., multiple causation of a unified manifesta-tion3) and include frailty, falls, delirium, malnutrition, dizziness, syncope, urinary incontinence, and pressure ulcers among oth-ers. These syndromes can be present before surgery and/or 1develop as a result of surgery and hospitalization.1,2 Further-more, close attention to both the presence and development of geriatric syndromes among surgical candidates is important and often overlooked, making caring for older surgical patients unique compared to their younger and healthier counterparts.FrailtyFrailty is among the most widely studied geriatric syndrome in the surgical literature. Frail older individuals are at high risk for adverse events in the face of stressors such as surgery. They are more likely to experience surgical complications, delayed recovery, falls, and to develop functional impairment. Frailty is also associated with a higher risk of death. It Is believed that frailty is a chronic, progressive condition that represents a spec-trum; less frail individuals may be responsive to strategies or interventions to ameliorate its clinical manifestations, while more frail individuals may demonstrate an irreversible predeath condition with limited life expectancy.4Frailty has been shown to be independently predictive of poor postoperative outcomes. Makary et al studied 594 older patients presenting for elective surgery at a university hospital and demonstrated that frail individuals were at increased risk of postoperative complications (OR 2.54; 95% CI 1.12–5.77), lon-ger length of stay (incidence rate ratio 1.69; 95% CI 1.28–2.23), and discharge to a skilled or assisted living facility after previ-ously living at home (OR 20.48; 95% CI 5.54-75.68).5 Similar findings have been echoed throughout the surgical literature inclusive of vascular, colorectal, cardiac, urologic, and other types of procedures.6-11Definitions of frailty fall into two broad models; a pheno-typic model and a deficits accumulation model. The phenotypic model was originally described by Linda Fried using data from the Cardiovascular Health Study, which is an observational study of community-dwelling men and women age 65 years and Introduction 2045Geriatric Syndromes 2045Frailty / 2045Falls / 2047Delirium / 2047Preoperative Assessment 2047Best Practices: Preoperative Assessment / 2048Frailty Assessment / 2049Cognitive and Behavioral Assessment / 2049Medical Assessment / 2050Nutritional Assessment / 2051Psychosocial Considerations / 2052Medication Review / 2052Patient Counseling / 2052Preoperative Preparation 2052Patient Goals, Preferences, and Advance Directives / 2052Preoperative Fasting / 2053Antibiotic Prophylaxis and Venous Thromboembolism Prevention / 2053Surgical Prehabilitation / 2053Palliative Care Services for Older Surgical Patients / 2053Special Considerations 2054Functional Recovery / 2054Cancer Surgery / 2055Emergency Surgery / 2055Cardiovascular Surgery / 2055Valve Replacement / 2055Endovascular Aortic Surgery / 2056Palliative Surgery / 2056Summary 2056Brunicardi_Ch47_p2045-p2060.indd 204528/02/19 2:08 PM 2046Table 47-1Criteria used to define frailty• Weight loss: “In the last year, have you lost more than 10 pounds unintentionally (i.e., not due to dieting or exercise)?” If yes, then frail for weight loss criterion. At follow-up, weight loss was calculated as: (Weight in previous year – current measured weight)/(weight in previous year) = K. If K ≥0.05 and the subject does not report that he/she was trying to lose weight (i.e., unintentional weight loss of at least 5% of previous year’s body weight), then frail for weight loss = Yes.• Exhaustion: Using the CES-D Depression Scale, the following two statements are read. (a) I felt that everything I did was an effort; (b) I could not get going. The question is asked “How often in the last week did you feel this way?” 0 = rarely or none of the time (<1 day), 1 = some or a little of the time (1–2 days), 2 = a moderate amount of the time (3–4 days), or 3 = most of the time. Subjects answering “2” or “3” to either of these questions are categorized as frail by the exhaustion criterion.• Physical Activity: Based on the short version of the Minnesota Leisure Time Activity questionnaire, asking about walking, chores (moderately strenuous), mowing the lawn, raking, gardening, hiking, jogging, biking, exercise cycling, dancing, aerobics, bowling, golf, singles tennis, doubles tennis, racquetball, calisthenics, swimming. Kcals per week expended are calculated using standardized algorithm. This variable is stratified by gender. Men: Those with Kcal of physical activity per week <383 are frail. Women: Those with Kcals per week <270 are frail.• Walk Time, stratified by gender and height (gender-specific cutoff a medium height). Men Height ≤173 cm Height >173 cmCutoff for time to walk 15 feet criterion for frailty≥7 seconds≥6 seconds Women Height ≤159 cm Height >159 cm≥7 seconds≥6 seconds• Grip Strength, stratified by gender and body mass index (BMI) quartiles: Men BMI ≤24 BMI 24.1–26 BMI 26.1–28 BMI >28Cutoff for grip strength (Kg) criterion for frailty≤29≤30≤30≤32 Women BMI ≤23 BMI 23.1–26 BMI 26.1–29 BMI >29≤17≤17.3≤18≤21Reproduced with permission from Fried LP, Tangen CM, Walston J, et al. Frailty in older adults: evidence for a phenotype, J Gerontol A Biol Sci Med Sci. 2001 Mar;56(3):M146-M156.older. Individuals in this cohort underwent baseline evaluations and had 4 to 7 years of follow-up with annual examinations and surveillance for the following outcomes: incident disease, hos-pitalization, falls, disability, and mortality. Based on observa-tions in these individuals over time, the following criteria were identified to define frailty: weight loss, exhaustion, physical activity, walk time, and grip strength (Table 47-1). The pres-ence of one or two of these factors is associated with intermedi-ate risk for poor outcomes, i.e., a “prefrail” phenotype, and the presence of three or more of these factors is associated with high risk for poor outcomes, i.e., a “frail” phenotype.12 This study additionally demonstrated that frailty is strongly associated Key Points1 Frailty, dementia, and functional impairment are significant contributors to morbidity and mortality after surgery. Assess-ment of these risk factors is essential in an older population.2 Geriatric perioperative pathways are effective in preventing delirium, a morbid and costly postoperative complication that is associated with cognitive decline.3 Population-based data demonstrate that mortality after emer-gency surgery and high-risk cancer surgery is substantially higher in older adults that in a younger population.4 Impaired cardiac function is responsible for more than half of the postoperative deaths in older adult patients, so careful attention must be paid to intravascular volume status in the perioperative period.5 Many frail elders experience significant and sustained func-tional decline after surgery.6 Older adults with acute abdominal pathology—appendicitis, cholecystitis—often do not have fever, elevated white blood cell count, or physical findings of peritonitis.Brunicardi_Ch47_p2045-p2060.indd 204628/02/19 2:08 PM 2047SURGICAL CONSIDERATIONS IN OLDER ADULTSCHAPTER 47with several major chronic diseases, including cardiovascular disease, pulmonary disease, and diabetes; however, not all frail individuals demonstrated these associations. The same is true for disability. While there is some overlap between frailty and disability, not all frail individuals are disabled. These findings suggest that while there may be overlap between these three constructs in some individuals, frailty is a distinct process from both comorbidity and disability.12Alternatively, the deficit accumulation model, developed by Rockwood et al, suggests that frailty is defined by discrete failures of redundant physiologic systems. The more deficits that occur, the more likely it is that adverse outcomes will result. Using data from the Canadian Study of Health and Aging, a longitudinal study of individuals age 65 and older, the authors developed a frailty index represented by the cumulative pro-portion of 92 accumulated deficits, which include symptoms, signs, functional impairments, and laboratory abnormalities. They demonstrated that deficits accumulated at a rate of 3% per year in their cohort, represented a gamma distribution, and increased with chronological age; they proposed that this model be used as a proxy for aging and mortality.13While these models are helpful to conceptualize frailty, no one model is all inclusive, and each may have applicability in different settings. For example, the frailty phenotype does not include items on cognition or mood and may not be easily appli-cable to the busy clinical setting.14 The deficits accumulation model is ideal for use in large databases, such as the American College of Surgeons National Surgical Quality Improvement Project (ACS-NSQIP),15 and may be helpful for research and public health and policy purposes, but it is not practical for clini-cal care. Measurement of frailty in the clinical setting will be discussed later in this chapter.While frailty is often defined as a geriatric syndrome, it is also plausible that other geriatric syndromes (i.e., urinary incontinence, falls, pressure ulcers, delirium, and functional decline) may demonstrate shared risk factors that lead to frailty. In turn, frailty may also cause more risk factors and more geriat-ric syndromes.16 Regardless of the association and directionality between frailty and other geriatric syndromes, identification of each is essential in the preoperative setting in order to help risk stratify and potentially to mitigate risk for patients considering surgical intervention.FallsOlder adults are at markedly increased risk of falls, and one in three adults age 65 and older report falling in the last year. The incidence of falls increases with age, and close to 60% of individuals who have fallen in the last year will fall again within the following year. Falls are associated with subsequent declines in functional status, greater likelihood of nursing home placement, increased use of medical services, and development of a fear of falling. Approx-imately half of older individuals who fall are unable to get up, resulting in a “long lie,” which is further associated with lasting functional declines.17 In fact, falls can be so detrimental to older individuals that the Joint Commission (United States) established fall prevention as one of its national safety goals in 2015.18Causes of falls can be multifactorial, as with other geri-atric syndromes. Factors include age-related declines, chronic disease, medications, environmental factors, changing positions, routine activities, risk-taking behaviors, acute illness, or situ-ational hazards such as the unfamiliar setting of hospitals and long-term care facilities.17It has been shown that preoperative falls are associated with poor postoperative outcomes among patients undergoing elective surgery. One study looking at 7982 such patients found that a preoperative history of one, two, or three or more falls predicted postoperative falls at 30 days (adjusted OR 2.3, 3.6, 5.5, respectively) and 1 year (adjusted OR 2.3, 3.4, 6.9, respec-tively), in addition to predicting a decline in functional status at 30 days (adjusted OR 1.2, 2.4, 2.4, respectively) and 1 year (adjusted OR 1.3, 1.5, 3.2, respectively) and in-hospital compli-cations (adjusted OR 1.2, 1.3, 2.0, respectively).18 Furthermore, preoperative falls are a major predictor of poor postoperative outcomes and may be a valuable preoperative assessment tool as part of routine preoperative care.DeliriumDelirium is a disorder of attention and awareness that develops acutely and tends to fluctuate, as defined by the new Diagnos-tic and Statistical Manual of Mental Disorders, Fifth Edition (DSM-5) criteria. Delirium is so common among older adults that up to one third of patients age 70 and older admitted to the hospital experiences delirium, half of which have delirium on admission and the other half of which develop delirium dur-ing the hospitalization itself.19 Rates of delirium among older patients undergoing surgery ranges from 4% to 5% in cataract and urologic procedures to 50% to 60% in infrarenal AAA repair or hip fracture surgery.20 Patients who develop postopera-tive delirium have a twoto threefold increased risk of mortality within the first year after surgery.21Preoperative assessment should focus on the identifi-cation of risk factors for delirium including age 70 years or older, cognitive impairment, limited physical function, history of alcohol abuse, abnormal serum sodium, potassium or glu-cose, intrathoracic surgery, and AAA surgery. Preoperative assessment and documentation of mental status is imperative in order to establish a baseline for postoperative comparison. Intraoperative blood loss is another risk factor for postopera-tive delirium, and patients with a postoperative hematocrit less than 30% are at increased risk, irrespective of baseline risk fac-tors. Postoperatively, undertreatment of pain is an important risk factor for delirium. Management of fluid, electrolyte and metabolic abnormalities, optimization of blood loss replace-ment, maintenance of circadian rhythms, and cautious prescrip-tion of medication and pain management are among the most important methods by which to minimize the risk of postop-erative delirium among surgical patients.20 Furthermore, many commonly used medications may induce delirium and should be avoided. They include drugs with anticholinergic properties, corticosteroids, merperidine, and sedative hypnotics. Finally, postoperative care bundles have been shown to successfully reduce the incidence of delirium. These strategies include sensory enhancement (glasses, hearing aids), early mobility, cognitive orientation and therapeutic activities, and sleep proto-cols. Treatment of postoperative delirium should focus on treat-able etiologies (Fig. 47-1), and pharmacologic treatment should be reserved for patients who are at risk of harming themselves or others.PREOPERATIVE ASSESSMENTPreoperative assessment in older adults is more complex than in younger individuals, as there are many unique characteris-tics that require consideration. The purpose of the assessment Brunicardi_Ch47_p2045-p2060.indd 204728/02/19 2:08 PM 2048SPECIFIC CONSIDERATIONSPART IIFigure 47-1. Useful algorithm to determine preoperative management of the acutely delirious patient.is not to “clear” the patient for surgery but rather to minimize risks and optimize good outcomes. The ACS NSQIP and the American Geriatrics Society (AGS) published best practice guidelines to help optimize this process. Preoperative planning should be pro-active, commencing at the time of surgical decision-making, if not sooner. To this end, the ACS NSQIP/AGS produced best practice guidelines and a preoperative management checklist to provide a framework for thinking about critical issues in this patient population (Table 47-2).22 In addition to these issues, they emphasize the importance of planning analgesia strategies, making efforts to minimize opioid use and to prevent functional and cognitive decline, obtaining multidisciplinary consultation early and early involvement of allied health staff (i.e., physical or occupational therapy), and anticipating home health needs that may be required at discharge.23Best Practices: Preoperative AssessmentFunctional Assessment. As previously discussed, poor phys-ical function prior to surgery is associated with higher risk of major postoperative complications, increased need for intensive WORKUPPhysical exam• Check surgical wound• Check for tubes/lines/drains• Urinalysis• CBC, BMP• May consider: TSH, NH3, LFT, EtoH/tox• Blood/sputum/urine cultures-Vital signs, pulse ox, pain assessmentMedication reviewLaboratory evaluation:---Chest XRSubstance abuse history--PHARMACOLOGIC MANAGEMENT:ONLY FOR AGITATED DELIRIUM AND PATIENT SAFETYAgent of choice: Low dose Haloperidol0.5 mg PO: 1–2 hours for effect, may redose in 60 m0.5 mg IM/IV: 20–40 min to take effect, may redosein 30 mMost patients respond to total of 1–2 mgCheck 12 lead EKG, hold if QTc >500----Use benzos only if there is a concern for withdrawalDIFFERENTIAL DIAGNOSIS DRUG!!! Electrolytes, environment change Lack of drugs (withdrawal), lack of sleep Infection, idiopathic Restraints, reduced sensory input (vision/hearing) Intracranial (CVA, bleed, post-ictal, meningitis) Urinary retention, or fecal impaction Metabolic, includes PE/MI, uremia, ammonia, thyroidDELIRIUMAlways check the medication list – there is acumulative effect burden, any new medicationor recent dose change is suspectAlgorithm for the acutelydelirious patient.For prevention in at risk patientsplease refer to opposite side.Why are they delirious?Common Delirium Inducing MedicationsRisk FactorsPrecipitating Factors, in aaddition to SURGERYPhysical restraintsMalnutrition3 medication classes addedBladder catheterUncontrolled pain-----PREVENTION/CONSERVATIVE MANAGEMENTSensory enhancement: Hearing aids, glasses at bedsideMobilizationCognitive orientation and stimulationSleep enhancementMedication reviewNormalize environment• Get rid of tethers• Keep room calm and quiet• Encourage family/caregiver involvement------Address/remove precipitating factors or agentsIf MB consider hospitalist consult--Are they a danger tothemselves or others?Age >65Cognitive impairmentComorbidity burdenPoor functional statusHearing/vision impairmentDepression------Anticholinergics: Tricyclics, antihistamines,H2-blockers, antimuscarinics, antispasmodics,promethazine, olanzapine, paroxetineCorticosteroids: methylprednisone, prednisoneMeperidineSedative hypnotics: benzos, zolpidem----Nu-DESC Screen: ScoreEach item scored 0–2• Disorientation• Inappropriate behavior• Inappropriate communication• Illusions/hallucinations• Psychomotor retardationIs your patient acutely delirious?Yes?Differential and workupBrunicardi_Ch47_p2045-p2060.indd 204828/02/19 2:08 PM 2049SURGICAL CONSIDERATIONS IN OLDER ADULTSCHAPTER 47Table 47-2Immediate preoperative management checklist from the ACS NSQIP/AGS1. Confirm and document patient goals and treatment preferences, including advance directives2. Confirm and document patient’s health care proxy or surrogate decision-maker3. In patients with existing advance directives, discuss new risks associated with the surgical procedure and an approach for potentially life-threatening problems consistent with the patient’s values and preferences4. Consider shortened fluid fast (clear liquids up to two hours before anesthesia)5. Adhere to existing best practices regarding antibiotic and venous thromboembolism prophylaxis6. Ensure nonessential medications have been stopped and essential medications have been takenAdapted with permission from Mohanty S, Rosenthal RA, Russell MM, et al: Optimal Perioperative Management of the Geriatric Patient: A Best Practices Guideline from the American College of Surgeons NSQIP and the American Geriatrics Society, J Am Coll Surg. 2016 May;222(5):930-947.rehabilitation services, increased rates of discharge to a skilled or assisted nursing facility, and higher mortality.24-26 Assessment of physical function and performance status in the preoperative setting are recommended by the ACS NSQIP/AGS best practice guidelines.22 There are several methods by which to measure physical function. Overall functional status may be ascertained by assessing the ability of an individual to perform activities of daily living (ADLs) and instrumental ADLs. ADLs include dressing, bathing, toileting, transferring, continence, and eating independently.25 Instrumental ADLs measure an individual’s ability to live independently and include the ability to perform the following tasks: shopping, laundry, mode of transportation, ability to handle finances, responsibility for won medications, food preparation, and housekeeping.27In addition to assessment of ADLs and instrumental ADLs, the surgeon should also assess for deficits in vision, hearing, and swallowing, inquire about history of falls in the past year, evaluate for limitations in gait and mobility, and determine risk for falls, which can be performed via the timed up and go test (TUGT). This test measures gait and mobility impairment and is associated with increased risk for falls in ambulatory individu-als. All that is required to perform this test are a chair, a mark 10 feet in front of the chair, and a stopwatch. Individuals are instructed to do the following while being timed:1. Stand up from the chair (without using arm rests, if possible)2. Walk to the mark (10 feet in front of them)3. Turn4. Walk back to the chair5. Sit down in the chairA time of ≥15 seconds indicates high risk of falls and should prompt referral to physical therapy for further assessment.In a prospective cohort of individuals age 65 and older undergoing surgery, the TUGT times were stratified into three groups that strongly correlated with varying risk for postop-erative complications and 1-year mortality. These groups were “slow” (≥15 seconds), “intermediate” (11–14 seconds), and “fast” (≤10 seconds). Postoperative complications and 1-year mortality in the slow group were significantly higher com-pared to those in the fast group, 52% to 77% versus 11% to 13% for complications, and 31% compared to 3% for mortality, respectively.9Frailty AssessmentAs stated earlier, frailty is an important consideration in preop-erative planning for older individuals. Measurement of frailty can take several forms. One method is to apply the operational definition put forth by Fried (see Table 47-1), which has been applied to surgical patients and shown to be an independent pre-dictor of postoperative adverse events, increased length of stay, and higher likelihood of discharge to a skilled or assisted living facility.5The frailty phenotype, however, may be cumbersome to apply in the busy clinical setting. To this end, Robinson proposed alternative definitions and methods for frailty mea-surement. One such method includes the following criteria: cog-nitive impairment (Mini-Cog score of ≤3), poor nutrition (serum albumin ≤3), history of falls (≥1 fall in the past 6 months), and low hematocrit (<35%).26 A second definition includes func-tional impairment (TUGT ≥15 seconds and dependence in any ADL) and comorbidity (Charlson index score ≥3).28Cognitive and Behavioral AssessmentPreoperative cognitive impairment is strongly linked to postop-erative delirium, worse surgical outcomes, longer hospital stays, increased risk of functional decline, and even mor-tality. History and cognitive assessment are important to con-sider early on in all surgical candidates age 65 years and older in the preoperative setting. The Mini-Cog, consisting of the three-item recall and clock draw tests, can be used to complete this assessment (Table 47-3). If possible, someone who knows the patient well (such as a spouse or family member) should be interviewed about the presence and evolution of any cognitive decline in the patient. If decline is present, the patient should be referred to a primary care physician, geriatrician, or mental health specialist for further evaluation. Documentation of pre-operative cognitive status will further assist in the identification of any postoperative cognitive dysfunction.22 Risk factors for postoperative delirium should also be assessed in the preopera-tive period and are detailed in Table 47-4.In addition to measuring cognitive status, assessing the patient’s decision-making capacity is also important to deter-mine the patient’s ability to provide informed surgical consent. It is helpful to ask the patient to describe, in his/her own words, the important features of the discussion, the condition and indi-cations for surgery, and the risks, benefits, and alternatives to surgery. There are four legally-relevant criteria for decision-making capacity22:1. The patient can clearly indicate his/her treatment choice.2. The patient understands the relevant information communi-cated by the physician.3. The patient acknowledges his/her medical condition, treat-ment options, and likely outcomes.4. The patient can engage in a rational discussion about the treatment options.Depression should also be screened for in the preoperative setting, as up to 11% of the population age 71 years and older in the United States suffer from this condition.29 Risk factors 2Brunicardi_Ch47_p2045-p2060.indd 204928/02/19 2:08 PM 2050SPECIFIC CONSIDERATIONSPART IITable 47-4Risk factors for postoperative deliriumCognitive and behavioral disorders:• Cognitive impairment and dementia• Untreated or inadequately controlled pain• Depression• Alcohol use• Sleep deprivationDisease or illness related:• Severe illness or comorbidities• Renal insufficiency• Anemia• HypoxiaMetabolic:• Poor nutrition• Dehydration• Electrolyte abnormalitiesFunctional impairments:• Poor functional status• Immobilization• Hearing or vision impairmentOther:• Older age ≥70 years• Polypharmacy and use of psychotropic medications (benzodiazepines, anticholinergics, and antihistamines)• Risk of urinary retention or constipation, presence of urinary catheterReproduced with permission from Chow WB, Rosenthal RA, Merkow RP, et al. Optimal preoperative assessment of the geriatric surgical patient: a best practices guideline from the American College of Surgeons National Surgical Quality Improvement Program and the American Geriatrics Society, J Am Coll Surg. 2012 Oct;215(4):453-466.Table 47-3Cognitive assessment: three-item recall and clock draw1. Get the patient’s attention and say:  “I am going to say three words that I want you to remember now and later.  These words are banana, sunrise, chair.  Please say them for me now.” Give the patient three tries to repeat the words. If unable after three tries, go to next item.2. Say all of the following phrases in the order indicated:  “Please draw a clock in the space below. Start by drawing a large circle. Put all the numbers in the circle and set the hands to show 11:10 (10 past 11).” If the subject has not finished clock drawing in 3 minutes, discontinue and ask for recall items.3. Say: “What were the three words I asked you to remember?”Scoring:• 3 item recall (0-3 points): 1 point for each correct word• Clock draw (0-2 points): 0 points for abnormal clock; 2 points for normal clock A normal clock has all of the following elements:  1. All numbers 1-12, each only once, are present in the correct order and direction (clockwise) inside the circle.  2. Two hands are present, one pointing to 11 and one pointing to 2.  3. Any clock missing any of these elements is scored abnormal. refusal to draw a clock is scored abnormalTotal score of 0, 1, or 2 suggests possible impairmentTotal score of 3, 4, or 5 suggests no impairmentReproduced with permission from Borson S, Scanlan J, Brush M, et al. The mini-cog: a cognitive ‘vital signs’ measure for dementia screening in multi-lingual elderly, Int J Geriatr Psychiatry. 2000 Nov;15(11):1021-1027.for depression in older adults include female gender, disability, bereavement, and sleep disturbance. Poor health status, cogni-tive impairment, living alone, and new medical illness may also contribute to depression.30The Patient Health Questionnaire-2 (PHQ-2) can be used to screen for depression via the following two questions31:1. In the past 12 months, have you ever had a time when you felt sad, blue, depressed, or down for most of the time for at least two weeks?2. In the past 12 months, have you ever had a time, lasting at least two weeks, when you didn’t care about the tings things that you usually care about or when you didn’t enjoy the things that you usually enjoy?If a patient answers yes to either question, further revalu-ation with a primary care physician, geriatrician, or psychiatrist is recommended.Screening for alcohol and substance abuse is also recom-mended, as alcohol use is common among older adults. Up to 13% of men and 8% of women ≥65 years consume at least 2 drinks per day and 14.5% of men and 3.3% of women con-sume 5 or more drinks per day.32 Alcohol and substance abuse are associated with increased rates of postoperative mortality and complications including pneumonia, sepsis, wound infec-tion and disruption, and prolonged length of stay.33,34 The ACS NSQIP/AGS recommend screening for alcohol and substance abuse among older individuals with the modified CAGE ques-tionnaire in combination with prescribing daily multivitamins. including folic acid and high dose (100 mg) oral or parenteral thiamine to patients who drink alcohol.22,35Medical AssessmentA thorough medical assessment should be performed in all older operative candidates and should include a cardiac evaluation, pulmonary evaluation, nutritional assessment, and medication evaluation and management where appropriate.Cardiac adverse events are the most common cause of serious perioperative morbidity and mortality among patients undergoing noncardiac operations and occur more commonly in older adults.36,37 For these reasons, cardiac evalu-ation may be helpful to identify older patients with higher risk for cardiac complications who may be candidates for periopera-tive optimization. This evaluation should follow the American College of Cardiology and the American Heart Association (ACC/AHA) algorithm for cardiac evaluation and care. This is a step-wise approach that incorporates the following factors: (a) urgency of surgery (whether the procedure is an emergency); the (b) presence of active major cardiac risk factors (i.e., unsta-ble coronary syndromes, decompensated heart failure, signifi-cant arrhythmias or severe valvular disease) that would necessitate referral to a cardiologist; (c) if risk factors for stable coronary artery disease are present, then calculation of risk for major adverse cardiac events using the ACS NSQIP calculator 3Brunicardi_Ch47_p2045-p2060.indd 205028/02/19 2:08 PM 2051SURGICAL CONSIDERATIONS IN OLDER ADULTSCHAPTER 47is recommended; (d) if the patient is at low risk for major car-diac events (<1%) then no further testing is needed; (e) if the patient is at elevated risk of major cardiac events, then determi-nation of functional capacity with an objective measure or scale may be helpful; (f) if functional capacity is poor, then additional testing such as pharmacological stress testing, may be helpful; and finally (g) if testing does not impact care, then one should proceed to surgery or consider alternative treatment strategies.38 Routine electrocardiograms are not indicated in older patients undergoing low-risk surgery in the absence of other risk factors.39-41The combined effect of depletion of intravascular volume, age-related impairment of response to catecholamines, and increased myocardial relaxation time adversely affects the cardiac function of an older adult patient under stress in the perioperative period. Aging has been demonstrated to cause a decrease in cardiac output by approximately 1% per year. Older individuals fail to augment heart rate to the same extent as younger individuals. More importantly, the ability to increase cardiac output with aging is dependent on ventricular dilatation, which is determined by preload. Therefore, careful attention must be paid to volume status in the perioperative period. Over one half of all postoperative deaths in older adult patients and 11% of postoperative complications are a result of impaired car-diac function under physiologic stress. Incomplete emptying of the ventricle at end systole and subsequent reduction in ejection fraction is characteristic of the aging heart. Reduced distensibil-ity, in addition to acute stressors, leads to impaired coronary perfusion and cardiac ischemia.An important predictor of surgical outcomes and cardiac complications in the older adult is congestive heart failure (CHF). CHF is present in approximately 10% of patients older than 65 years and is the leading cause of postoperative morbid-ity and mortality. This prevalence will likely increase as per-cutaneous interventions and medical therapy prolongs survival from myocardial ischemia and acute myocardial infarction. Therefore, identifying correctable and uncorrectable cardiovas-cular disease is critical before elective surgical interventions.Common pulmonary postoperative complications in older adults include atelectasis, pneumonia, and prolonged mechanical ventilation.42 These complications can contribute significantly to overall morbidity and mortality among older adults, affecting up to 15% of individuals ≥70 years in the postoperative setting.22,43 Risk factors for postoperative pulmonary complications include both patient and procedure-related factors. Patient-related fac-tors include age >60, chronic obstructive pulmonary disease (COPD), American Society of Anesthesiologists (ASA) class II or greater, functional dependence, congestive heart failure, obstructive sleep apnea, pulmonary hypertension, current ciga-rette use, impaired sensorium, preoperative sepsis, weight loss >10% in 6 months, serum albumin <3.5 mg/dL, and blood urea nitrogen (BUN) ≥7.5 mmol/L (≥1.5 mg/dL). Surgical related fac-tors include prolonged operation of greater than 3 hours, surgi-cal site, emergency operation, general anesthesia, perioperative transfusion, and residual neuromuscular blockade after an opera-tion. Of note, obesity, well-controlled asthma, and diabetes are not risk factors for postoperative pulmonary complications. It is recommended that patients with COPD and asthma that is not well controlled undergo preoperative optimization of pulmonary function and other general recommendations include smoking cessation, preoperative intensive inspiratory muscle training, and selective chest radiograph and pulmonary function testing.22In general, the use of routine preoperative screening com-bined with the high cost of unnecessary testing dispute the use of a routine battery of preoperative screening tests in all patients. Instead, it is preferable to perform selected tests in high-risk patients based on history, physical exam, known comorbidities, and the type of procedure being planned.22Nutritional AssessmentNutritional status should also be performed in older adults prior to surgery, as poor nutrition is potentially modifiable and related to increased risk of postoperative complications. The most com-mon adverse events related to poor nutritional status are infec-tious complications (i.e., surgical site infections, pneumonia, urinary tract infections), wound complications (i.e., dehiscence and anastomotic leaks), and increased length of stay. The ACS NSQIP/AGS best practice guidelines recommend the following to screen for poor nutritional status:1. Document height and weight and calculate body mass index (BMI). A BMI <18.5 kg/m2 places an individual at risk and should prompt referral for full nutritional assessment.2. Measure baseline serum albumin and prealbumin levels. Serum albumin <3.0 g/dL (with no evidence of hepatic or renal dysfunction) should prompt referral for full nutritional assessment.3. Inquire about unintentional weight loss in the last year. Unintentional weight loss >10% to 15% in the past 6 months is associated with severe nutritional risk and should prompt assessment by a dietician.22The American Society for Parenteral and Enteral Nutrition (ASPEN) argues that measurement of serum albumin and pre-albumin reflect the severity of the inflammatory response rather than true poor nutritional status. Instead, they favor a more indi-vidualized approach whereby the presence of any of the follow-ing six factors would classify an individual with malnutrition:1. Insufficient energy intake. Severe malnutrition in the context of chronic illness is defined as <75% of estimated energy requirement for ≥1 month.2. Weight loss. Severe malnutrition in the context of chronic illness is defined as >5% weight loss in 1 month, >7.5% weight loss in 3 months, >10% weight loss in 6 months, and >20% weight loss in 1 year.3. Loss of muscle mass. Severe malnutrition is defined as severe muscle wasting of the temples, clavicles, shoulders, interosseous muscles, scapula, thigh, and calf.4. Loss of subcutaneous fat. Severe malnutrition is defined as loss of subcutaneous fat (e.g., orbital, triceps, fat overlying the ribs).5. Localized or generalized fluid accumulation that may sometimes mask weight loss. This can be demonstrated by fluid accumulation evident on exam (e.g., extremities, vulvar/scrotal edema, or ascites).6. Diminished functional status as measured by hand grip strength. Measurements for grip strength are based on nor-mative standards supplied by the manufacturer of the mea-surement device.44Regardless of the method used to measure nutritional sta-tus, attention to the diagnosis and management of malnutrition in the perioperative setting is imperative to optimize postopera-tive outcomes.4Brunicardi_Ch47_p2045-p2060.indd 205128/02/19 2:08 PM 2052SPECIFIC CONSIDERATIONSPART IIPsychosocial ConsiderationsAnxiety, depression, substance abuse, and social isolation are common, underdiagnosed conditions in older adults. Careful screening can identify these potential barriers to recovery, safe discharge after surgery, and maintenance of independence.Medication ReviewCareful review and documentation of the patient’s complete med-ication history is important in the preoperative setting. The review should include the use of nonprescription agents, including over-the-counter, nonsteroidal anti-inflammatory drugs (NSAIDs), vitamins, eye drops, topical agents, and herbal products.Additionally, it is important to discontinue medications that should be avoided prior to surgery in order to minimize potential adverse events and interactions. These include dis-continuation of all nonessential medications that are associated with increased surgical risk and medications with potential for drug interactions with anesthesia. Herbal medication should be stopped at least 7 days prior to surgery, and the Beers criteria should be reviewed. Medications with potential for withdrawal (e.g., selective serotonin reuptake inhibitor [SSRIs], tricyclic antidepressants, benzodiazepines, antipsychotics, monoamine oxidase inhibitors [MAOIs], β-blockers, clonidine, statins, and corticosteroids) in addition to angiotensin-converting enzyme inhibitors and angiotensin II receptor blockers should be con-tinued unless hypertension is well controlled. Medications that are associated with increased risk for postoperative delirium should also be avoided and replaced with safer medications. For example, benzodiazepines should be stopped or reduced, where possible. Pain should be adequately controlled and meperi-dine should be avoided for pain management. Caution should be used when prescribing antihistamine H1 antagonists (such as diphenhydramine/Benadryl) and medications with antihista-mine effects. Of note, there is no increased risk associated with neuroleptics (antipsychotics) and digoxin and no conclusive evi-dence against using H2 agonists, tricyclic antidepressants, anti-Parkinson medications, steroids, NSAIDs, and antimuscarinics in the perioperative setting.Certain medications, such as β-blockers or statins, may be beneficial to start preoperatively in order to reduce risk of perioperative adverse events such as cardiac complications and stroke. There are ACC/AHA guidelines to support the use of perioperative β-blockers in patients who are already taking them, particularly those with independent cardiac indications such as arrhythmia or history of myocardial infarction and in patients who are undergoing intermediate risk or vascular surgery with no known coronary artery disease or with multiple clinical risk factors for ischemic heart disease. Statins should be started as soon as possible prior to surgery in patients who have known vascular disease, elevated low-density lipoprotein cholesterol, or ischemia on thallium testing. They may also be considered in patients undergoing vascular and intermediate-risk surgery.Additionally, medications doses should be adjusted based on renal function. Older patients are at greater risk for renal impairment and chronic kidney disease; furthermore, adjustment of medications that are renally cleared is an important consider-ation. Glomerular filtration rate (GFR), rather than creatinine, is the best overall measure of renal function due to the fact that the ratio of GFR to creatinine decreases with increasing age.22Finally, medication use is very common among the older population, and older individuals should be monitored for polypharmacy and potential adverse interactions. This is of real concern since 40% of individuals age 65 years and older are taking five or more medications prescribed by more than one doctor.45 Additionally, 68% of older adults use over-the-counter medications, dietary supplements, or both concurrently with prescription medications.46 Of note, polypharmacy has been associated with increased risk of cognitive impairment, morbidity, and mortality, and the risk of adverse drug reactions increases with a greater number of medications.45,47Patient CounselingDetermination of the patient’s preferences and expectations prior to surgery is an essential component to preoperative assessment and decision making. One study demonstrated that agreement between patients and their surrogates (primary care providers and close family members) was poor, despite patients predicting that their physicians (90%) and family members (87%) would accurately represent their wishes. Instead, they found that per-cent of agreement ranged from 59% to 88%, suggesting that sub-stituted judgement may not be a good proxy for an individual patient’s wishes.48 Another study looked at older patients with limited life expectancy due to cancer, congestive heart failure, or chronic obstructive pulmonary disease and found that 99% of patients would undergo a low-burden treatment to restore current health (with the alternative being death), but that 74% and 89% would forgo treatment if it resulted in severe functional or cognitive impairment, respectively.49 Furthermore, it is imperative that the surgeon have a substantive discussion with the patient prior to sur-gery to determine their preferences and expectations and that fam-ily members and potential decision-making surrogates be involved. The ACS NSQIP/AGS Guidelines recommend that the following four points be included in these conversations:1. Ensure that the patient has an advance directive and desig-nated health care proxy.2. Discuss treatment goals and plans with the patient to ensure that the physician understands the patient’s preferences and expectations. This should be documented in the medical record.3. The surgeon should describe the expected postoperative course and possible complications, including the potential for functional decline and need for rehabilitation or nursing home care, if relevant.4. The physician should determine the patient’s family and social support systems. If support is insufficient, then a referral to a social worker should be considered.22The American College of Surgeons has created a checklist for the optimal preoperative assessment of the geriatric surgical patient (see Table 47-2).PREOPERATIVE PREPARATIONIn the immediate preoperative period, careful planning is essen-tial to optimize the care of the frail older patient.Patient Goals, Preferences, and Advance DirectivesIt is important that surgeons have a good understanding of patients’ goals and wishes surrounding their medical care, par-ticularly towards the end of life. This should be established in the clinic setting prior to surgery and should be confirmed Brunicardi_Ch47_p2045-p2060.indd 205228/02/19 2:08 PM 2053SURGICAL CONSIDERATIONS IN OLDER ADULTSCHAPTER 47and documented throughout the process. Additionally, patients should be encouraged to designate a health care proxy to help with this process, should they be unable to make their own med-ical decisions. The healthcare team should also consider early palliative care consultation in individuals with poor prognoses who are electing to undergo surgery, particularly if they have a life expectancy of less than 6 months.Preoperative FastingHistorically, preoperative fasting began at midnight the night before elective surgery, whereby, patients were not permitted to have any oral intake of either liquids or solids. However, more recent literature suggests that there may be no clear benefit to extended periods of fasting greater than 6 hours.50 Based on the American Society of Anesthesiologists 2011 practice guidelines for all adults, fasting should take the form of stopping clear liq-uids at least 2 hours before elective procedures, stopping light food intake and/or nonhuman milk 6 hours before elective pro-cedures and stopping fried, fatty foods and meat at least 8 hours before elective procedures. Of note, patients with comorbidities or diseases that can affect gastric emptying (i.e., diabetes, hiatal hernia) may require additional periods of fasting.Antibiotic Prophylaxis and Venous Thromboembolism PreventionAntibiotic prophylaxis for older adults should comply with standard guidelines put forth by The Society for Healthcare Epidemiology of America/Surgical Infection Society/American Society of Health-System Pharmacists/Infectious Disease Society. Older adults who receive appropriate preoperative antibiotics demonstrate a mortality benefit at 60 days.51,52 Appropriate antibiotics should be administered within 60 minutes prior to surgical incision.Older adults are at higher risk for venous thromboem-bolism (VTE), making VTE risk stratification among this population essential. Older individuals undergoing orthopedic procedures (i.e., total hip or knee arthroplasty) or who have suffered a hip fracture should be treated with low molecular weight heparin (LMWH) (starting either 13 hours or more pre-operatively or 12 hours or more postoperatively) for a minimum of 10 to 14 days and up to 35 days. Older adults undergoing nonorthopedic surgery (i.e., general, abdominopelvic, bariatric, vascular plastic/reconstructive, and thoracic surgery) should have LMWH or low-dose unfractionated heparin (LDUH) and mechanical prophylaxis with intermittent pneumatic compres-sion (IPC). Older adults undergoing craniotomy/spinal surgery or cardiac surgery should have IPC. Finally, older individuals who experienced major trauma and spinal cord injury should use LDUH/LMWH and IPC if not contraindicated.23Surgical PrehabilitationOne purpose of the preoperative assessment is to identify potentially modifiable risk factors in order to optimize surgi-cal outcomes. Several prehabilitation programs have emerged in order to help meet this need and have demonstrated prom-ising results. One of the first of such programs was referred to as the Proactive Care of Older People undergoing surgery (POPS) study in the United Kingdom’s National Health Service (NHS). This project was designed to decrease complications leading to increased hospital length of stay among at-risk older adults undergoing elective surgery. The authors performed a structured geriatric team intervention to identify at-risk patients and to then facilitate coordinated multidisciplinary care in the form of daily inpatient rounds, weekly multidisciplinary meet-ings, and biweekly ward rounds led by a POPS consultant/clini-cal nurse specialist. Outcomes in surgical patients undergoing the POPS intervention were compared to those among patients not undergoing the intervention. The POPS group had fewer postoperative complications, including lower rates of pneumo-nia (4% vs. 20%, P = 0.008) and delirium (4% vs. 19%, P = 0.028), better pain control (2% vs. 30%, P <0.001), lower rates of delayed mobilization (9% vs. 28%, P = 0.-12) and lower rates of inappropriate catheter use (7% vs. 37%, P = 0.046). They also demonstrated a reduction in hospital length of stay by 4.5 days.53The Michigan Surgical Home and Optimization Program (MSHOP) is another example of a successful prehabilitation program. This is a structured, home-based preoperative train-ing program that targets physical, nutritional, and psychological interventions. The intervention included the following four com-ponents: (a) a home-based walking program with daily remind-ers and feedback; (b) incentive spirometry instructions starting one week prior to surgery; (c) education on nutrition, stress management, and care planning; and (d) resources for smoking cessation, when appropriate. Eighty-two percent of individu-als enrolled in the study were actively engaged in the program. Compared to individuals who did not undergo the intervention, patients enrolled in the trial demonstrated a 31% reduction in hospital length of stay and a 28% reduction in cost.64 Collec-tively, the POPS study and the MSHOP studies are illustrative of the notion that attention to preand perioperative assessment in the older population result in improved postoperative out-comes that benefit the patient, hospital, and health care system.Palliative Care Services for Older Surgical PatientsAmong seriously ill individuals, palliative care services have the potential to increase quality of life, improve symptoms and patient satisfaction, and reduce caregiver burden.55-57 The role of palliative care in older surgical patients is not as well under-stood, and it is not widely understood in the surgical population.58 Over a decade ago, the American College of Surgeons Pallia-tive Care Workgroup identified core competencies of surgical palliative care.59 The two key elements of palliative care—pain management and communication skills—are essential. For sur-geons who frequently care for individuals at high risk of mor-bidity and mortality, there are six additional core competency domains: patient care, medical knowledge, practice-based learn-ing, interpersonal skills, communication skills, and profession-alism (Table 47-5).Emerging data suggests that surgical patients benefit from the addition of palliative care principles and services. An interventional trial evaluating a decision-making interven-tion considering procedures that included information about health status and prognosis increased the likelihood of choosing less aggressive treatment options among patients with frailty (OR 3.41, 95% CI 1.39–8.39) or dementia (OR 1.66, 95% CI 1.06–2.64).60 In a study of preoperative care consultation in frail older adults, Ernst et al found that preoperative palliative care consultations were associated with reduced mortality.61 Several studies have found that postoperative palliative care improves symptoms, including uncertainly, symptom distress, and depres-sion, and improves quality of life.62-63Brunicardi_Ch47_p2045-p2060.indd 205328/02/19 2:08 PM 2054SPECIFIC CONSIDERATIONSPART IITable 47-5Core Competencies in surgical palliative careDOMAINCOMPETENCYPatient Care      Possess the capacity to guide the transition from curative and palliative goals of treatment to palliative goals alone based on patient information and preferences, scientific and outcomes evidence, and sound clinical judgmentPerform an assessment and gather essential clinical information about symptoms, pain, and sufferingPerform palliative procedures competently and with sound judgment to meet patient goals of care at the end of lifeProvide management of pain and other symptoms to alleviate sufferingCommunicate effectively and compassionately bad news and poor prognosesConduct a patient and family meeting regarding advance directives and end-of-life decisionsExercise sound clinical judgment and skill in the withdrawal and withholding of life supportMedical knowledge     Acute and chronic pain managementNon-pain symptom managementEthical and legal basis for advance directives, informed consent, withdrawal and withholding of life support, and futilityGrief and bereavement in surgical illnessQuality of life outcomes and prognosticationRole of spirituality at the end of lifeInterpersonal and communication skillsSurgeons must be competent and compassionate communicators with patients, families, and other health care providers. They should be effective in communicating bad news and prognosis and in redefining hope in the context of cultural diversity. The interdisciplinary nature of palliative care requires that the surgeon is skilled as both a leader and a member of an interdisciplinary team and maintains collegial relationships with other health care providers.ProfessionalismSurgeons must maintain professional commitment to ethical and empathic care, which is patient focused, with equal attention to relief of suffering along with curative therapy. Respect and compassion for cultural diversity, gender, and disability is particularly important around rituals and bereavement at the end of life. Maintenance of ethical standards in the withholding and withdrawal of life support is essential.Systems-based practiceSurgeons must be aware and informed of the multiple components of the health care system that provide palliative and end-of-life care. Surgeons should be knowledgeable and willing to refer patients to hospice, palliative care consultation, pain management, pastoral care, social services, etc., and to understand resource utilization and reimbursement issues involved.Data from Mohanty S, Rosenthal RA, Russell MM, et al: Optimal Perioperative Management of the Geriatric Patient: A Best Practices Guideline from the American College of Surgeons NSQIP and the American Geriatrics Society, J Am Coll Surg. 2016 May;222(5):930-947.SPECIAL CONSIDERATIONSFunctional RecoveryIn the past decade, there has been increasing attention to the examination of functional outcomes after major surgery in the geriatric population. In a large prospective cohort study of patients age 60 years and older undergoing abdominal surgery, Lawrence et al found that older adults required several months to fully return to basic activities of daily living (ADLs) and up to 6 months to become independent in more complex instrumental activities of daily living (IADLs).65 Older adults are frequently discharged to postacute facilities even when they are functional dependent at baseline and have an uncomplicated postoperative course.66Among frail older adults, functional decline after surgery is often substantial and sustained. Studies examining functional outcomes after surgery among nursing home residents have demonstrated that the majority of nursing home residents who undergo surgery do not return to baseline levels of function post-operatively.67-68 Among residents who underwent colectomy for cancer, 53% were dead after 1 year and over half of 1-year survi-vors experienced functional decline.68 For residents who undergo lower extremity bypass, half die within a year of surgery.67 At 1 year, 13% of the initial vascular surgery cohort was ambulatory, and 18% had maintained or improved their baseline functional status—calling into question the efficacy of this procedure in the nursing home. A study of hip fracture repair in nursing home resi-dents found that over a third of residents died and over half of resi-dents had died or experienced functional decline within 180 days after fracture. Residents with multiple comorbidities and advanced cognitive impairment and those who did not undergo surgical cor-rection of the fracture experienced the worst outcomes.5Brunicardi_Ch47_p2045-p2060.indd 205428/02/19 2:08 PM 2055SURGICAL CONSIDERATIONS IN OLDER ADULTSCHAPTER 47Cancer SurgeryApproximately 50% of cancer diagnoses are currently made in patients age 70 years or older.69 It is predicted that the increase in the older adult population will account for up to a 50% increase in the number of patients undergoing oncologic procedures by the year 2020. The increased life expectancy of the geriatric patient coupled with the increasing incidence of cancer with advancing age will lead to an increased prevalence of malignant disease requiring surgical intervention. This is an area of great interest given that randomized clinical trials to determine the out-comes of older adult patients undergoing curative resections, as well as neoadjuvant and adjuvant therapy, are lacking. In addi-tion, older adult patients are rarely included in clinical trials; therefore, treatment decisions are often based on individual sur-geon experience and nongeriatric data, and they may be flawed by inherent biases regarding the outcome of complete oncologic resections in older adult patients. Surgeons may also be reluctant to expose older patients to the toxic effects of chemotherapy and radiation without proven efficacy in this geriatric population. This highlights the need for research targeting the specific needs of older adult patients with malignancy to aid in the development of specific treatment guidelines for various cancers within this age cohort.Numerous studies have documented increased risk of post-operative morbidity and mortality in older adults with cancer. Evaluation of a national surgical registry found that older adults undergoing major gastrointestinal surgery have substan-tially higher risks of complications and death than individuals younger than 65 years.70 The impact of age on risk was present across all operations but had most impact in liver and rectal surgery. Surgeons are challenged to decide whether major sur-gery is justified in older adult patients, especially those with limited life expectancy. Effectiveness of oncologic surgery in older adult patients depends on whether a cure can be achieved safely without compromise to functional status or quality of life. Postoperative life expectancy should be improved by surgery, or, at the very least, not diminished.Emergency SurgeryEmergent surgery caries exceptionally high risk for older adult patients. In an analysis of patients age 90 years and older, 90-day mortality after emergency gastrointestinal procedures was 54%.71 In a large cohort of patients undergoing endovas-cular repair for ruptured aortic aneurysm, 30-day mortality was 35% after primary aortic repair and 52% after open conversion of endovascular aortic repair.72Frail institutionalized elders are at substantial risk for poor surgical outcomes after emergent surgery. In an analysis of over 70,000 nursing home residents who underwent emer-gent abdominal operations (surgery for bleeding ulcer, chole-cystectomy, appendectomy, and colectomy), operative mortality was twoto threefold higher than among matched community-dwelling elders.73 In addition, invasive life-sustaining interven-tions after surgery were significantly higher in the nursing home population than among noninstitutionalized Medicare enrollees, ranging from 18% vs. 5%, respectively, after cholecystectomy to 55% vs. 43%, respectively, after ulcer surgery. The combined effects of poor nutrition, decreased cogni-tion, and immune impairments due to nutritional or phar-macologic factors create a treacherous circumstance for older adult patients with poorly defined symptoms or who pres-ent with more advanced disease. In acute abdominal conditions, such as acute appendicitis and acute cholecystitis, one-third of older adult patients will lack an elevated white blood cell count, one-third will lack fever, and one-third will lack physical find-ings of localized peritonitis.74 These deficits contribute to a threefold higher rate of perforated appendicitis and of gangrene of the gallbladder in older adult patients compared to young patients. An “unimpressive” physical exam in an older adult patient with acute onset of abdominal symptoms should never be taken as a sign of the absence of surgical disease.Cardiovascular SurgeryWith advances in cardiopulmonary bypass technique, myocar-dial protection, and improved perioperative care, coronary artery bypass grafting (CABG) and valve replacement operations have become safer in older patients. When considering cardiovascular surgery in elders, it is essential to consider that advanced age is not the strongest predictor of poorer outcomes or increased mor-tality compared in older patients. It has been demonstrated that emergency operations, preoperative New York Heart Association (NYHA) functional class 3 or greater, and chronic renal failure are the strongest independent predictors of increased operative mortality.75 In one study, preoperative renal dysfunction, cere-brovascular disease, valve surgery, and catastrophic state were independent predictors of increased mortality in older adult patients.76 Older adult patients with non–dialysis-dependent renal dysfunction had a 60% chance of death during a 5-year follow-up period compared to 25% in older adult patients with-out a history of renal dysfunction. Similarly, the presence of cerebrovascular disease resulted in a two-fold increase in mor-tality among older adult patients.76 Even patients who were 80 years of age or more did not have any significant increase in surgical risk and within this population, and the 4-year actuarial survival was 70.5% with an event-free survival of 60.6%.There has been an increase in definitive operative interven-tion to older patients with operable coronary artery disease. The Society of Thoracic Surgeons reports that perioperative mortality rates range from 1.6% in patients 51 to 60 years of age to 7.7% in those 81 to 90 years of age.77 Older patients are more likely to have significant three-vessel disease accompanied by poor ejec-tion fraction, left ventricular hypertrophy, significant valvular disease, and previous history of myocardial infarction than are younger patients.77 Older patients also are more likely to be clas-sified as NYHA functional class 3 or higher and are more likely to present on an emergent basis, in part because of reluctance to provide elective surgical intervention because of presumptive poorer outcome. Despite the increased risk of morbidity and mortality compared to younger patients, older adult patients, including those >80 years old, can undergo CABG with accept-able mortality risk. The overall mortality rate is approximately 7% to 12% for older adult patients, including those in whom CABG is performed under emergency conditions. The mortality rate decreases to approximately 2.8% when CABG is performed electively with careful preoperative evaluation.78Valve ReplacementAs the population ages, the incidence of senile calcific aortic stenosis and referral for aortic valve replacement are increas-ing. The operative mortality from aortic valve replacement is estimated to be between 3% and 10%, with an average of approximately 7.7%.76 If aortic stenosis is allowed to progress without operative intervention, CHF will ensue. The average survival of these patients is approximately 1.5 to 2 years. If a patient is deemed fit for operative intervention, age should not 6Brunicardi_Ch47_p2045-p2060.indd 205528/02/19 2:08 PM 2056SPECIFIC CONSIDERATIONSPART IIbe a deterrent, especially considering the potential to increase life expectancy. It has been recommended that the carefully selected, minimally symptomatic octogenarian with aortic ste-nosis should be considered a low-risk patient and be expected to experience an uneventful operative course and expedient recov-ery. More importantly, if elective procedures are delayed until symptoms or left ventricular dysfunction develop, patients may suffer from unnecessary increased operative risk and mortality.75 Early intervention results in a demonstrable improvement in quality of life in these patients, with many improving their NYHA functional classification.Older patients are candidates for mitral valve surgery when ischemic regurgitation is present. Surgery for mitral valve disease carries a higher morbidity and mortality risk than for aortic intervention, with an estimated mortality rate as high as 20%.77 Left ventricular function usually is compromised in patients requiring intervention, leading to a poorer outcome in these patients. The surgical outcome for mitral valve proce-dures depends on the extent of the disease, age of the patient, presence of pulmonary hypertension, and extent of coronary artery disease. The presence of comorbid conditions combined with the emergent nature of surgery in a large percentage of older patients further worsens the outcome. Therefore, a deci-sion regarding management of mitral valve disease should be individualized to each patient. Another concern regarding older patients who are candidates for valve disease surgery is the additional need for coronary revascularization—an important contributor to morbidity and mortality from surgical interven-tion. To mitigate risk, an older patient with multiple comorbid conditions in need of a combined procedure should only have critically stenosed vessels bypassed.79 Neurologic complications from valve surgery are particularly common in older patients. It has been estimated that approximately 30% of patients >70 years old who undergo valve procedures develop either transient or permanent neurologic dysfunction.22 This often is a result of embolism from debris dislodged from the valve during the procedure or from a formed thrombus in the right atrium.An important consideration in valve replacement proce-dures in older patients is the type of prosthesis to be used. Older patients are at increased risk from bleeding-associated anticoagu-lation complications. This risk is especially significant in patients who have experienced falls and minor trauma that have resulted in intracranial hemorrhage. To avoid the lifelong requirement for anticoagulants, bioprosthetic valves should be used in place of mechanical valves whenever possible.79 Although the biopros-thetic valves are not as durable as mechanical valves, studies demonstrate excellent structural integrity 10 years post proce-dure, making it an appropriate choice in older patients.Transcatheter aortic valve implantation/replacement (TAVI/TAVR) is increasingly being used to treat aortic stenosis. Initially, this technique was reserved for individuals with high surgical risk. A systematic review of transcatheter aortic valve implantation versus surgical aortic valve replacement revealed that, compared to surgical repair, the transcatheter approach may have similar or better early and midterm outcomes, including among lowto intermediate-risk patients.80 Furthermore, there is increasing evidence that suggests TAVI results in acceptable long-term results in the older adult population.81,82Endovascular Aortic SurgeryWith increasing use of screening abdominal CT scans and ultrasounds for evaluation of various abdominal complaints, abdominal aortic aneurysms (AAA) are being identified with greater frequency, The percentage of AAA rises from about 1% at age 55 to 60 years to approximately 10% in patients 80 years of age or older.83 Historically, very old patients were deemed poor operative candidates for the traditional open repair given the frequent presence of comorbid conditions and limited car-diopulmonary reserve to tolerate a major operation or the many hours of required operative time and general anesthesia. The dissemination of endovascular techniques for repair of AAA, however, has shifted the risk-benefit ratio for operative inter-vention, allowing greater life expectancy for the elective repair of this potentially life-threatening condition with the benefits of a minimally invasive approach.Multiple studies have demonstrated that endovascular aortic repair (EVAR) is feasible and efficacious in older adult patients, including those previously considered unfit for open repair. EVAR is a minimally invasive technique in which a pros-thetic graft is introduced into the aortic lumen via the common femoral artery to exclude the aortic aneurysm sac. EVAR sig-nificantly reduces operative and anesthesia times, blood loss, intensive care needs, length of stays, and major postoperative morbidity associated with open AAA repair. This procedure also can be done using epidural anesthesia for high-risk candi-dates who may tolerate general anesthesia poorly (Fig. 47-2).Careful consideration of the life expectancy and the risk of rupture dictate the necessity for intervention. EVAR remains a viable option in older adult patients. Nonoperative management is justified in frail older adult patients with multiple comorbidi-ties and reduced life expectancy whose operative risks outweigh the risk of rupture and in those who are unlikely to survive long enough to benefit from the repair.Palliative SurgeryPalliative surgery is defined as surgical intervention targeted to alleviate a patient’s symptoms, thus improving the patient’s quality of life despite minimal impact on the patient’s survival.54 With an increasing number of older patients presenting with advanced disease, surgeons must be familiar with the concept of palliation to control symptoms. This concept focuses on pro-viding the maximal benefit to the patient using the least-invasive intervention. Ideally, this intervention leads to symptom relief and preservation of the quality of life in terminal disease states by alleviating symptoms such as intractable vomiting and severe pain. The success of palliative surgery is a careful bal-ance between achieving symptom relief without the develop-ment of new symptoms from the intervention itself. A recent meta-analysis of outcomes after palliative surgery for malignant bowel obstruction from peritoneal carcinomatosis revealed that although palliative surgery can benefit some patients, many patients experience serious complications, incomplete resolu-tion of symptoms, and substantial hospitalization relative to the patient’s remaining survival time.84 It is essential to provide patients with realistic information about expected outcomes after palliative surgery to ensure that this surgical intervention is in line with their care preferences. The core competencies for surgical palliative care are shown in Table 47-5.SUMMARYMajor surgery in older adults requires careful consideration. In addition to chronic medical conditions, many elders have geriat-ric syndromes that put them at high risk for increased morbidity, Brunicardi_Ch47_p2045-p2060.indd 205628/02/19 2:08 PM 2057SURGICAL CONSIDERATIONS IN OLDER ADULTSCHAPTER 47Figure 47-2. Endovascular repair of abdominal aortic aneurysms (AAAs) has gained favor for suitable older adult patients to prevent rupture. Through minimal groin incisions, this 82-year-old patient underwent repair of an AAA and right iliac artery aneurysm and was discharged on post-op day 2.mortality, and poor functional recovery after surgery. Screen-ing for and optimization of multiple domains of vulnerability is essential to improve outcomes in this vulnerable population. Furthermore, the incorporation of palliative care principles into the surgical care of frail elders will improve patient-centered decision-making, symptom management, and quality of life.REFERENCESEntries highlighted in bright blue are key references. 1. McRae PJ, Peel NM, Walker PJ, de Looze JW, Mudge AM. Geri-atric syndromes in individuals admitted to vascular and urology surgical units. J Am Geriatr Soc. 2014;62(6):1105-1109. 2. McRae PJ, Walker PJ, Peel NM, et al. Frailty and geriatric syndromes in vascular surgical ward patients. Ann Vasc Surg. 2016;35:9-18. 3. Flacker JM. What is a geriatric syndrome anyway? J Am Geri-atr Soc. 2003;51(4):574-576. 4. Fried LP. Frailty. In: Medina-Walpole A, Pacala JT, Potter JF, eds. Geriatric Review Syllabus. 9th ed. New York: American Geriatrics Society; 2016. 5. Makary MA, Segev DL, Pronovost PJ, et al. Frailty as a pre-dictor of surgical outcomes in older patients. J Am Coll Surg. 2010;210(6):901-908. 6. Suskind AM, Jin C, Cooperberg MR, et al. Preoperative frailty is associated with discharge to skilled or assisted living facili-ties after urologic procedures of varying complexity. Urology. 2016;97:25-32. 7. Suskind AM, Walter LC, Jin C, et al. Impact of frailty on compli-cations in patients undergoing common urological procedures: a study from the American College of Surgeons National Surgical Quality Improvement database. BJU Int. 2016;117(5):836-842. 8. Robinson TN, Wu DS, Pointer L, Dunn CL, Cleveland JC Jr, Moss M. Simple frailty score predicts postoperative complica-tions across surgical specialties. Am J Surg. 2013;206(4):544-550. 9. Robinson TN, Wu DS, Sauaia A, et al. Slower walking speed forecasts increased postoperative morbidity and 1-year mortal-ity across surgical specialties. Ann Surg. 2013;258(4):582-588; discussion 588-590. 10. Revenig LM, Canter DJ, Kim S, et al. Report of a simplified frailty score predictive of short-term postoperative morbidity and mortality. J Am Coll Surg. 2015;220(5):904-911 e901. 11. Revenig LM, Canter DJ, Master VA, et al. A prospective study examining the association between preoperative frailty and postoperative complications in patients undergoing minimally invasive surgery. J Endourol. 2014;28(4):476-480. 12. Fried LP, Tangen CM, Walston J, et al. Frailty in older adults: evidence for a phenotype. J Gerontol A Biol Sci Med Sci. 2001;56(3):M146-M156. 13. Mitnitski AB, Mogilner AJ, Rockwood K. Accumulation of def-icits as a proxy measure of aging. Sci World J. 2001;1:323-336. 14. Sternberg SA, Wershof Schwartz A, Karunananthan S, Bergman H, Mark Clarfield A. The identification of frailty: a systematic literature review. J Am Geriatr Soc. 2011;59(11):2129-2138. 15. Velanovich V, Antoine H, Swartz A, Peters D, Rubinfeld I. Accumulating deficits model of frailty and postoperative mor-tality and morbidity: its application to a national database. J Surgical Res. 2013;183(1):104-110. 16. Inouye SK, Studenski S, Tinetti ME, Kuchel GA. Geriatric syndromes: clinical, research, and policy implications of a core geriatric concept. J Am Geriatr Soc. 2007;55(5):780-791. 17. Berry SD, Kiel DP. Falls. In: Medina-Walpole A, Pacala JT, Potter JF, eds. Geriatric Review Syllabus. 9th ed. New York: American Geriatrics Society; 2016. 18. Kronzer VL, Jerry MR, Ben Abdallah A, et al. Preoperative falls predict postoperative falls, functional decline, and surgical complications. EBioMedicine. 2016;12:302-308.Brunicardi_Ch47_p2045-p2060.indd 205728/02/19 2:08 PM 2058SPECIFIC CONSIDERATIONSPART II 19. Marcantonio ER. Delirium. In: Medina-Walpole A, Pacala JT, Potter JF, eds. Geriatric Review Syllabus. 9th ed. New York: American Geriatrics Society; 2016. 20. Christmas C, Pacala JT. Perioperative care. In: Medina-Walpole A, Pacala JT, Potter CT, eds. Geriatric Review Syllabus. 9th ed. New York: American Geriatrics Society; 2016. 21. McCusker J, Cole M, Abrahamowicz M, Primeau F, Belzile E. Delirium predicts 12-month mortality. Arch Int Med. 2002;162(4):457-463. 22. Chow WB, Rosenthal RA, Merkow RP, et al. Optimal preop-erative assessment of the Surgeons National Surgical Qual-ity Improvement Program and the American Geriatrics Society. J Am Coll Surg. 2012;215(4):453-466. 23. Mohanty S, Rosenthal RA, Russell MM, Neuman MD, Ko CY, Esnaola NF. Optimal Perioperative Management of the Geriatric Patient: A Best Practices Guideline from the American College of Surgeons NSQIP and the American Geriatrics Society. J Am Coll Surg. 2016;222(5):930-947. 24. Stefan M, Iglesia Lino L, Fernandez G. Medical consultation and best practices for preoperative evaluation of older adult patients. Hosp Pract. 2011;39(1):41-51. 25. Shelkey M, Wallace M. Katz index of independence in activities of daily living (ADL). Director. 2000;8(2):72-73. 26. Robinson TN, Eiseman B, Wallace JI, et al. Redefining geri-atric preoperative assessment using frailty, disability and co-morbidity. Ann Surg. 2009;250(3):449-455. 27. Graf C. The Lawton instrumental activities of daily liv-ing (IADL) scale. http://ConsultGeri/try-this/issue-23.pdf, January 14, 2016. 28. Robinson TN, Wallace JI, Wu DS, et al. Accumulated frailty characteristics predict postoperative discharge institutionaliza-tion in the geriatric patient. J Am Coll Surg. 2011;213(1):37-42; discussion 42-34. 29. Steffens DC, Fisher GG, Langa KM, Potter GG, Plassman BL. Prevalence of depression among older Americans: the Aging, Demographics and Memory Study. Int Psychogeriatr. 2009;21(5):879-888. 30. Cole MG, Dendukuri N. Risk factors for depression among older adult community subjects: a systematic review and meta-analysis. Am J Psychiatry. 2003;160(6):1147-1156. 31. Li C, Friedman B, Conwell Y, Fiscella K. Validity of the Patient Health Questionnaire 2 (PHQ-2) in identifying major depres-sion in older people. J Am Geriatr Soc. 2007;55(4):596-602. 32. Blazer DG, Wu LT. The epidemiology of at-risk and binge drinking among middle-aged and older adult community adults: National Survey on Drug Use and Health. Am J Psychiatry. 2009;166(10):1162-1169. 33. Nath B, Li Y, Carroll JE, Szabo G, Tseng JF, Shah SA. Alcohol exposure as a risk factor for adverse outcomes in elective sur-gery. J Gastrointest Surg. 2010;14(11):1732-1741. 34. Tonnesen H, Kehlet H. Preoperative alcoholism and postopera-tive morbidity. Br J Surg. 1999;86(7):869-874. 35. National Institute on Alcohol Abuse and Alcoholism. CAGE Questionnaire. 2002. Available at: https://pubs.niaaa.nih.gov/publications/aa65/aa65.htm. Accessed August 21, 2018. 36. Gal J, Bogar L, Acsady G, Kertai MD. Cardiac risk reduction in non-cardiac surgery: the role of anaesthesia and monitoring techniques. Eur J Anaesthesiol. 2006;23(8):641-648. 37. Puig-Barbera J, Marquez-Calderon S, Vila-Sanchez M. Car-diac complications of major elective non-cardiac surgery: incidence and risk factors (in Spanish). Rev Esp Cardiol. 2006;59(4):329-337. 38. Fleisher LA, Fleischmann KE, Auerbach AD, et al. 2014 ACC/AHA guideline on perioperative cardiovascular evalu-ation and management of patients undergoing noncardiac surgery: executive summary: a report of the American College of Cardiology/American Heart Association Task Force on practice guidelines. Developed in collaboration with the American College of Surgeons, American Society of Anesthesiologists, American Society of Echocardiography, American Society of Nuclear Cardiology, Heart Rhythm Society, Society for Cardiovascular Angiography and Interventions, Society of Cardiovascular Anesthesiologists, and Society of Vascular Medicine Endorsed by the Society of Hospital Medicine. J Nucl Cardiol. 2015;22(1):162-215. 39. Ansaloni L, Catena F, Chattat R, et al. Risk factors and inci-dence of postoperative delirium in older adult patients after elective and emergency surgery. Br J Surg. 2010;97(2):273-280. 40. Landesberg G, Beattie WS, Mosseri M, Jaffe AS, Alpert JS. Perioperative myocardial infarction. Circulation. 2009;119(22):2936-2944. 41. Smetana GW, Macpherson DS. The case against routine preop-erative laboratory testing. Med Clin North Am. 2003;87(1):7-40. 42. Smetana GW, Cohn SL, Lawrence VA. Update in perioperative medicine. Ann Intern Med. 2004;140(6):452-461. 43. Johnson RG, Arozullah AM, Neumayer L, Henderson WG, Hosokawa P, Khuri SF. Multivariable predictors of postop-erative respiratory failure after general and vascular surgery: results from the patient safety in surgery study. J Am Coll Surg. 2007;204(6):1188-1198. 44. White JV, Guenter P, Jensen G, et al. Consensus statement: Academy of Nutrition and Dietetics and American Society for Parenteral and Enteral Nutrition: characteristics recom-mended for the identification and documentation of adult malnutrition (undernutrition). JPEN J Parenter Enteral Nutr. 2012;36(3):275-283. 45. Barnett SR. Polypharmacy and perioperative medications in the older adult. Anesthesiol Clin. 2009;27(3):377-389. 46. Qato DM, Alexander GC, Conti RM, Johnson M, Schumm P, Lindau ST. Use of prescription and over-the-counter medications and dietary supplements among older adults in the United States. JAMA. 2008;300(24):2867-2878. 47. Hajjar ER, Cafiero AC, Hanlon JT. Polypharmacy in older adult patients. Am J Geriatr Pharmacother. 2007;5(4):345-351. 48. Seckler AB, Meier DE, Mulvihill M, Paris BE. Substituted judgment: how accurate are proxy predictions? Ann Intern Med. 1991;115(2):92-98. 49. Fried TR, Bradley EH, Towle VR, Allore H. Understanding the treatment preferences of seriously ill patients. N Engl J Med. 2002;346(14):1061-1066. 50. American Society of Anesthesiologists C. Practice guidelines for preoperative fasting and the use of pharmacologic agents to reduce the risk of pulmonary aspiration: application to healthy patients undergoing elective procedures: an updated report by the American Society of Anesthesiologists Com-mittee on Standards and Practice Parameters. Anesthesiology. 2011;114(3):495-511. 51. Classen DC, Evans RS, Pestotnik SL, Horn SD, Menlove RL, Burke JP. The timing of prophylactic administration of antibi-otics and the risk of surgical-wound infection. N Engl J Med. 1992;326(5):281-286. 52. Silber JH, Rosenbaum PR, Trudeau ME, et al. Preopera-tive antibiotics and mortality in the older adult. Ann Surg. 2005;242(1):107-114. 53. Harari D, Hopper A, Dhesi J, Babic-Illman G, Lockwood L, Martin F. Proactive care of older people undergoing surgery (‘POPS’): designing, embedding, evaluating, and funding a comprehensive geriatric assessment service for older elective surgical patients. Age Ageing. 2007;36(2):190-196. 54. Englesbe MJ, Grenda DR, Sullivan JA, et al. The Michigan Surgical Home and Optimization Program is a scalable model to improve care and reduce costs. Surgery. 2017;161(6): 1659-1666. 55. Temel JS, Greer JA, Muzikansky A, et al. Early palliative care for patients with metastatic non-small-cell lung cancer. N Eng J Med. 2010;363(8):733-742.Brunicardi_Ch47_p2045-p2060.indd 205828/02/19 2:08 PM 2059SURGICAL CONSIDERATIONS IN OLDER ADULTSCHAPTER 47 56. Kavialieratos D, Corbelli J, Zhang D, et al. Association between palliative care and patient and caregiver outcomes. A systematic review and meta-analysis. JAMA. 2016;316(20):2104-2114. 57. Zimmermann C, Swami N, Krzyzanowska M, et al. Early palliative care for patients with advanced cancer: a clusterrandomised controlled trial. Lancet. 2014;383(9930): 1721-1730. 58. Olmsted CL, Johnson AM, Kaboli P, et al. Use of pal-liative care and hospice among surgical and medical spe-cialties in the Veterans Health Administration. JAMA Surg. 2014;149(11):1169-1175. 59. Surgeons Palliative Care Workgroup. Office of Promoting Excellence in End-of-Life Care: Surgeon’s Palliative Care Work-group report from the field. J Am Coll Surg. 2003;197(4):661-686. 60. Moorhouse P, Mallery LH. Palliative and therapeutic harmoni-zation: a model for appropriate decision-making in frail older adults. J Am Geriatr Soc. 2012;60(12):2326-2332. 61. Ernst KF, Hall DE, Schmid KK, et al. Surgical palliative care consultations over time in relationship to systemwide frailty screening. JAMA Surg. 2014;149(11):1121-1126. 62. McCorkle R, Dowd M, Ercolano E, et al. Effects of a nursing intervention on quality of life outcomes in post-surgical women with gynecological cancers. Psychooncology. 2009;18(1):62-70. 63. McCorkle R, Strumpf NE, Nuamah IF, et al. A specialized home care intervention improves survival among older post-surgical cancer patients. J Am Geriatr Soc. 2000;48(12):1707-1713. 64. Englesbe MJ, Grenda DR, Sullivan JA, et al. The Michigan Sur-gical Home and Optimization Program is a scalable model to improve care and reduce costs. Surgery. 2017;161(6):1659-1666. 65. Lawrence VA, Hazuda HP, Cornell JE, et al. Functional inde-pendence after major abdominal surgery in the older adult. J Am Coll Surg. 2004;199(5):762-772. 66. Balentine CJ, Naik AD, Berger DH, et al. Postacute care after major abdominal surgery in older adult patients: intersection of age, functional status, and postoperative complications. JAMA Surg. 2016;151(8):759-766. 67. Oresanya L, Zhao S, Gan S, et al. Functional outcomes after lower extremity revascularization in nursing home residents: a national cohort study. JAMA Intern Med. 2015;175(6):951-957. 68. Finlayson E, Zhaao S, Boscardin WJ, et al. Functional status after colon cancer surgery in older adult nursing home residents. J Am Geriatr Soc. 2012;60(5):967-673. 69. Pasetto LM, Lise M, Monfardini S. Preoperative assessment of older adult cancer patient. Crit Rev Oncol Hematol. 2007;64:10. 70. Yeo HL, O’Mahoney PR, Lachs M, et al. Surgical oncol-ogy outcomes in the aging US population. J Surg Res. 2016;205(1):11-18. 71. Sudlow A, Tuffaha H, Strearns AT, et al. Outcomes of surgery in patients aged >=90 years in the general surgical setting. Ann R Coll Surg Engl. 2018;24:1-6. 72. Scali ST, Runge SJ, Feezor RJ, et al. Outcomes after endovas-cular aneurysm repair conversion and primary aortic repair for urgent and emergency indications in the Society for Vascular Surgery Quality Initiative. J Vasc Surg. 2016;64(2):338-347. 73. Finlayson E, Wang L, Landefeld CS, et al. Major abdominal surgery in nursing home residents: a national study. Ann Surg. 2011;254(6):921-926. 74. Zenilman ME. Surgery in the older adult. Curr Probl Surg. 1998;35:99-179. 75. Cerillo AG, Kodami AA, Solinas M, et al. Aortic valve surgery in the older adult patient: a retrospective review. Interact Car-diovasc Thorac Surg. 2007;6:308-313. 76. Srinivasan AK, Oo AY, Grayson AD, et al. Mid-term survival after cardiac surgery in older adult patients: analysis of predic-tors for increased mortality. Interact Cardiovasc Thorac Surg. 2004;3:289-293. 77. Davis EA, Gardner TJ, Gillinov AM, et al. Valvular disease in the older adult: influence on surgical results. Ann Thorac Surg. 1993;55:333-337. 78. Richmond TS, Kaunder D, Strumpf N, et al. Characteristics and outcomes of serious traumatic injury in older adults. J Am Geri-atr Soc. 2002;50:215-222. 79. Aziz S, Grover FL. Cardiovascular surgery in the older adult. Cardiol Clin. 1999;17:213-231. 80. Garguilo G, Sannino A, Capodanno D, et al. Transcatheter aortic valve implantation versus surgical aortic valve replace-ment: a systematic review and meta-analysis. Ann Intern Med. 2016;165(50):334-344. 81. Chakos A, Wilson-Smith A, Arora S, et al. Long term outcomes of transcatheter aortic valve implantation (TAVI): a systematic review of 5-year survival and beyond. Ann Cardiothorac Surg. 2017;6(5):432-443. 82. D’Onofrio A, Facchin M, Besola L, et al. Intermediate clini-cal and hemodynamic outcomes after transcatheter aortic valve implantation. Ann Thorac Surg. 2016;101:881-8; discussion 888. 83. Biebl M, Lau LL, Hakaim AG, et al. Midterm outcomes of endo-vascular abdominal aortic aneurysm repair in octogenarians: a single institution’s experience. J Vasc Surg. 2004;40:435-442. 84. Olson P, Pinkerton C, Brasel KJ, et al. Palliative surgery for malignant bowel obstruction from carcinomatosis: a system-atic review. JAMA Surg. 2014;149(4):383-392.Brunicardi_Ch47_p2045-p2060.indd 205928/02/19 2:08 PM
Brunicardi_Ch47_p2045-p2060.indd 206028/02/19 2:08 PMThis page intentionally left blankEthics, Palliative Care, and Care at the End of LifeDaniel E. Hall, Eliza W. Beal, Peter A. Angelos, Geoffrey P. Dunn, Daniel B. Hinshaw, and Timothy M. Pawlik48chapterDedicated to the advancement of surgery along its scientific and moral side. June 10, 1926, dedication on the Murphy Auditorium, the first home of the American College of SurgeonsWHY ETHICS MATTEREthical concerns involve not only the interests of patients but also the interests of surgeons and society. Surgeons choose among the options available to them because they have particu-lar opinions regarding what would be good (or bad) for their patients. Aristotle described practical wisdom (Greek: phronesis) as the capacity to choose the best option from among several imperfect alternatives (Fig. 48-1).1 Frequently, surgeons are confronted with clinical or interpersonal situations in which there is incomplete information, uncertain outcomes, and/or complex personal and familial relationships. The capacity to choose wisely in such circumstances is the challenge of surgi-cal practice.DEFINITIONS AND OVERVIEWBiomedical ethics is the system of analysis and deliberation dedicated to guiding surgeons toward the “good” in the prac-tice of surgery. One of the most influential ethical “systems” in the field of biomedical ethics is the principalist approach as articulated by Beauchamp and Childress.2 In this approach to ethical issues, moral dilemmas are deliberated using four guiding principles: autonomy, beneficence, nonmaleficence, and justice.2The principle of autonomy respects the capacity of indi-viduals to choose their own destiny, and it implies that indi-viduals have a right to make those choices. It also implies an obligation for physicians to permit patients to make autonomous choices about their medical care. Beneficence requires that proposed actions aim at and achieve something good whereas nonmaleficence aims at avoiding concrete harm: primum non nocere.* Justice requires fairness where both the benefits and burdens of a particular action are distributed equitably.The history of medical ethics has its origins in antiquity. The Hippocratic Oath along with other professional codes has guided the actions of physicians for thousands of years. However, the growing technical powers of modern medicine raise new questions that were inconceivable in previous gen-erations. Life support, dialysis, and modern drugs, as well as organ and cellular transplantation, have engendered new moral and ethical questions. As such, the ethical challenges faced by the surgeon have become more complex and require greater attention.The case-based paradigm for bioethics is used when the clinical team encounters a situation in which two or more val-ues or principles come into apparent conflict. The first step is to clarify the relevant principles (e.g., autonomy, beneficence, nonmaleficence, and justice) and values at stake (e.g., self-determination, quality of life). After identifying the principles and values that are affecting the situation, a proposed course of action is considered given the circumstances.Much of the discourse in bioethics adopts this “principal-ist” approach in which the relevant principles are identified, weighed, and balanced, and then applied to formulate a course of action. This approach to bioethics is a powerful technique for thinking through moral problems because the four princi-ples help identify what is at stake in any proposed course of action. However, the principles themselves do not resolve ethi-cal dilemmas. Working together, patients and surgeons must use wise judgment to choose the best course of action for the specific case.Why Ethics Matter 2061Definitions and Overview 2061Specific Issues in Surgical Ethics 2062Informed Consent / 2062The Boundaries of Autonomy: Advance Directives and Powers of Attorney / 2064Withdrawing and Withholding Life-Sustaining Therapies / 2065Living Donor Liver Transplantation / 2066Palliative Care 2066General Principles of Palliative Care / 2066Concepts of Suffering, Pain, Health, and Healing / 2067Effective Communication and Negotiating the Goals of Care / 2067Care at the End of Life 2068The Syndrome of Imminent Demise / 2068Common Symptoms at the End of Life and Their Management / 2068Pronouncing Death / 2072Aid in Dying / 2072Professional Ethics: Conflict of  Interest, Research, and Clinical Ethics 2072Conflict of Interest / 2072Research Ethics / 2072Special Concerns in Surgical Research / 2072Surgical Innovation / 2073The Ethics of Authorship / 2073Clinical Ethics: Disclosure of Errors / 2074*“First do no harm.”Brunicardi_Ch48_p2061-p2076.indd 206119/02/19 1:49 PM 2062Figure 48-1. Bust of Aristotle. Marble, Roman copy after a Greek bronze original by Lysippos from 330 b.c. (From http://en.wikipedia.org/wiki/File:Aristotle_Altemps_Inv8575.jpg: Ludovisi Collection, Accession number Inv. 8575, Palazzo Altemps, Location Ground Floor, Branch of the National Roman Museum. Photographer/-source Jastrow [2006] from Wikipedia.)Choosing wisely requires the virtue of practical wisdom first described by Aristotle (see Fig. 48-1). Along with the other cardinal virtues of courage, justice and temperance, practical wisdom is a central component of virtue ethics which comple-ment principalist ethics by guiding choices toward the best options for treatment. Practical wisdom cannot be learned from books and is developed only through experience. The appren-ticeship model of surgical residency fosters the development of practical wisdom through experience. More than teaching merely technical mastery, surgical residency is also moral training. In fact, the sociologist Charles Bosk argues that the “postgraduate training of surgeons is above all things an ethical training.”3SPECIFIC ISSUES IN SURGICAL ETHICSInformed ConsentAlthough a relatively recent development, the doctrine of informed consent is one of the most widely established tenets of modern biomedical ethics. During the nineteenth and early twentieth centuries, most physicians practiced a form of benign paternalism whereby patients were rarely involved in the deci-sion-making process regarding their medical care, relying instead on the beneficence of the physician. Consensus among the wider public eventually changed such that surgeons are now expected to have an open discussion about diagnosis and treatment with the patient to obtain informed consent. In the United States, the legal doctrine of simple consent dates from the 1914 decision in Schloendorff vs. The Society of New York Hospital regarding a case in which a surgeon removed a diseased uterus after the patient had consented to an examination under anesthesia, but with the express stipulation that no operative excision should be performed. The physician argued that his decision was justified by the beneficent obligation to avoid the risks of a second anes-thetic. However, Justice Benjamin Cardozo stated:Every human being of adult years and sound mind has a right to determine what shall be done with his body; and a surgeon who performs an operation without his patient’s consent commits an assault, for which he is liable in damages . . . except in cases of emergency, where the patient is unconscious, and where it is neces-sary to operate before consent can be obtained.4Having established that patients have the right to deter-mine what happens to their bodies, it took some time for the modern concept of informed consent to emerge from the ini-tial doctrine of simple consent. The initial approach appealed to a professional practice standard whereby physicians were obligated to disclose to patients the kind of information that experienced surgeons customarily disclosed.5 However, this dis-closure was not always adequate for patient needs. In the 1972 Key Points1 The physician should document that the patient or surrogate has the capacity to make a medical decision.2 Sufficient details regarding diagnosis and treatment options should be disclosed to the patient so that the patient can pro-vide informed consent.3 Living wills are written to anticipate treatment options and choices in the event that a patient is rendered incompetent by a terminal illness.4 The durable power of attorney for healthcare identifies sur-rogate decision makers and invests them with the authority to make healthcare decisions on behalf of patients in the event that they are unable to speak for themselves.5 Surgeons should encourage their patients to complete a liv-ing will and clearly identify their surrogates early in the course of treatment.6 Earlier referrals and wider use of palliative and hospice care may help more patients achieve their goals at the end of life.7 Seven requirements for the ethical conduct of clinical research studies have been articulated: value, scientific validity, fair subject selection, favorable risk-benefit ratio, independent review, informed consent, and respect for enrolled subjects.8 Individuals working together on research endeavors should have clear discussions early in the planning process about authorship, and those discussions should be continued throughout the project or study.9 Disclosure of error is consistent with recent ethical advances in medicine toward more transparency, openness with patients, and the involvement of patients in their care.Brunicardi_Ch48_p2061-p2076.indd 206219/02/19 1:49 PM 2063ETHICS, PALLIATIVE CARE, AND CARE AT THE END OF LIFECHAPTER 48Patient establishes selfas decision-makerNoYesEngage patientdirectly in informedconsent process andin all aspects of careIdentify patient’s culturalidentity and, if possible,explicit preferences formaking decisions,including degree of familyinvolvementMaintain heightenedawareness of patient-family or patient-surrogate interactionsMake sure family orother surrogate is willingparticipant in informedconsent processContinuously reassessfor signs that patient isunhappy with current role ininformed consent processSecure private discussionwith patient and remindpatient of right toinformed consent processMake sure patient hasnot deferred decision-making involuntarilyFigure 48-2. Algorithm for navigating the process of informed consent. (Modified with permission from Childers R, Lipsett A, Pawlik T. Informed consent and the surgeon, J Am Coll Surg. 2009 Apr;208(4):627-634.)landmark case, Canterbury vs. Spence, the court rejected the professional practice standard in favor of the reasonable person standard whereby physicians are obliged to disclose to patients all information regarding diagnosis, treatment options, and risks that a “reasonable patient” would want to know in a similar situation. Rather than relying on the practices or consensus of the medical community, the reasonable person standard empow-ers the public (reasonable persons) to determine how much information should be disclosed by physicians to ensure that consent is truly informed. The court did recognize, however, that there are practical limits on the amount of information that can be communicated or assimilated.5 Subsequent litigation has revolved around what reasonable people expect to be disclosed in the consent process to include the nature and frequency of potential complications, the prognostic life expectancy,6 and the surgeon-specific success rates.4 Despite the litigious environ-ment of medical practice, it is difficult to prosecute a case of inadequate informed consent so long as the clinician has made a concerted and documented effort to involve the patient in the decision-making process.Adequate informed consent entails at least four basic ele-ments: (a) the physician documents that the patient or surrogate has the capacity to make a medical decision; (b) the sur-geon discloses to the patient details regarding the diagno-sis and treatment options sufficiently for the patient to make an informed choice; (c) the patient demonstrates understanding of the disclosed information before (d) authoriz-ing freely a specific treatment plan without undue influence (Fig. 48-2). These goals are aimed at respecting each patient’s prerogative for autonomous self-determination. To accomplish these goals, the surgeon needs to engage in a discussion about the causes and nature of the patient’s disease, the risks and ben-efits of available treatment options, as well as details regarding what patients can expect after an operative intervention includ-ing possible outcomes and complications.7-14Certain clinical settings make obtaining informed consent challenging. For example, obtaining consent for emergency surgery can be difficult, as the clinical team is forced to make decisions with incomplete information. Emergency consent requires the surgeon to consider if and how possible interven-tions might save a patient’s life, and if successful, what kind of disability might be anticipated. Surgical emergencies are one of the few instances where the limits of patient autonomy are freely acknowledged, and surgeons are empowered by law and ethics to act promptly in the best interests of their patients according to the surgeon’s judgment. Most applicable medi-cal laws require physicians to provide the standard of care to incapacitated patients, even if it entails invasive procedures without the explicit consent of the patient or surrogate. If at all possible, surgeons should seek the permission of their patients to provide treatment, but when emergency medical conditions render patients unable to grant that permission, and when delay is likely to have grave consequences, surgeons are legally and ethically justified in providing whatever surgical treatment the surgeon judges necessary to preserve life and restore health.4 This justification is based on the social consensus that most people would want their lives and health protected in this way, and this consensus is manifest in the medical profession’s gen-eral orientation to preserve life. It may be that subsequent care may be withdrawn or withheld when the clinical prognosis is clearer, but in the context of initial resuscitation of injured patients, incomplete information makes clear judgments about the patient’s ultimate prognosis or outcome impossible.The pediatric population also presents unique challenges for the process of consent. For many reasons, children and ado-lescents cannot participate in the process of giving informed 1122Brunicardi_Ch48_p2061-p2076.indd 206319/02/19 1:49 PM 2064SPECIFIC CONSIDERATIONSPART IIconsent in the same way as adults. Depending on their age, children may lack the cognitive and emotional maturity to participate fully in the process. In addition, depending on the child’s age, their specific circumstances, as well as the local jurisdiction, children may not have legal standing to fully par-ticipate on their own independent of their parents. The use of parents or guardians as surrogate decision makers only partially addresses the ethical responsibility of the surgeon to involve the child in the informed consent process. The surgeon should strive to augment the role of the decision makers by involving the child in the process. Specifically, children should receive age-appropriate information about their clinical situation and therapeutic options delivered in an appropriate setting and tone so that the surgeon can solicit the child’s “assent” for treatment. In this manner, while the parents or surrogate decision makers formally give the informed consent, the child remains an inte-gral part of the process.Certain religious practices can present additional chal-lenges when treating minor children whose parents disallow medically indicated blood transfusions; however, case law has made clear the precedent that parents, regardless of their held beliefs, may not place their minor children at mortal risk. In such a circumstance, the physician should seek counsel from the hospital medicolegal team, as well as from the institutional ethics team. Legal precedent has, in general, established that the hospital or physician can proceed with providing all necessary care for the child.Obtaining “consent” for organ donation deserves spe-cific mention.15 Historically, discussion of organ donation with families of potential donors was performed by transplant professionals, who were introduced to families by intensivists after brain death had been confirmed and the family had been informed of the fact of death. In other instances, consent might be obtained by intensivists caring for the donor, as they were assumed to know the patient’s family and could facilitate the process. However, issues of moral “neutrality” as part of end-of-life care in the intensive care unit have caused a shift in how obtaining “consent” for organ donation is handled. Responsibility for obtaining consent from the donor family is now vested in trained “designated requestors” (or “organ procurement coordinators”)16 or by “independent” intensivists who do not have a therapeutic clinical relationship with the potential donor.17 In this way, the donor family can be allowed to make the decision regarding donation in a “neutral” environment without erosion of the therapeutic relationship with the treating physician or perceived undue pressure from the transplant team.The process of informed consent also can be limited by the capacity of patients to assimilate information in the context of their illness. For example, despite the best efforts of surgeons, evidence suggests that patients rarely retain much of what is dis-closed in the consent conversation, and they may not remember discussing details of the procedure that become relevant when postoperative complications arise.18 It is important to recognize that the doctrine of informed consent places the most emphasis on the principle of autonomy precisely in those clinical situa-tions when, because of their severe illness or impending death, patients are often divested of their autonomy.The Boundaries of Autonomy: Advance Directives and Powers of AttorneySevere illness and impending death can often render patients incapable of exercising their autonomy regarding medical decisions. One approach to these difficult situations is to make decisions in the “best interests” of patients, but because such decisions require value judgments about which thoughtful peo-ple frequently disagree, ethicists, lawyers, and legislators have sought a more reliable solution. Advance directives of various forms have been developed to carry forward into the future the autonomous choices of competent adults regarding healthcare decisions. Furthermore, the courts often accept “informal” advance directives in the form of sworn testimony about state-ments the patient made at some time previous to their illness. When a formal document expressing the patient’s advance directives fails to exist, surgeons should consider the comments patients and families make when asked about their wishes in the setting of debilitating illness.Living wills are written to anticipate treatment options and choices in the event that a patient is incapacitated by a terminal illness. In the living will, the patient indicates which treatments she wishes to permit or prohibit in the setting of terminal illness. The possible treatments addressed often include mechanical ventilation, cardiopulmonary resuscitation, artificial nutri-tion, dialysis, antibiotics, or transfusion of blood products. Unfor-tunately, living wills are often too vague to offer concrete guidance in complex clinical situations, and the language (“termi-nal illness,” “artificial nutrition”) can be interpreted in many ways. Furthermore, by limiting the directive only to “terminal” conditions, it does not provide guidance for common clinical sce-narios like advanced dementia, delirium, or persistent vegetative states where the patient is unable to make decisions, but is not “terminally” ill. Perhaps even more problematic is the evidence that demonstrates that healthy patients cannot reliably predict their preferences when they are actually sick. This phenomenon is called “affective forecasting” and applies to many situations. For example, the general public estimates the health-related qual-ity of life (HRQoL) score of patients on dialysis at 0.39, although dialysis patients themselves rate their HRQoL at 0.56.19 Similarly, patients with colostomies rated their HRQoL at 0.92, compared to a score of 0.80 given by the general public for patients with colostomies.19 For these and other reasons, living wills are often unable to provide the extent of assistance they promise.20An alternative to living wills is the durable power of attor-ney for healthcare in which patients identify surrogate decision makers and invest them with the authority to make healthcare decisions on their behalf in the event that they are unable to speak for themselves. Proponents of this approach hope that the surrogate will be able to make decisions that reflect the choices that the patients themselves would make if they were able. Unfortunately, several studies demonstrate that surrogates are not much better than chance at predicting the choices patients make when the patient is able to state a preference. For example, a recent meta-analysis found that surrogates predicted patients’ treatment preferences with only 68% accuracy.21 These data reveal a flaw in the guiding principle of surrogate decision making: Surrogates do not necessarily have privileged insight into the autonomous preferences of patients. However, the dura-ble power of attorney at least allows patients to choose the person who will eventually make prudential decisions on their behalf and in their best interests; therefore, respecting the judgment of the surrogate is a way of respecting the self-determination of the incapacitated patient.22There is continuing enthusiasm for a wider use of advance directives. In fact, the 1991 Patient Self Determination Act requires all U.S. healthcare facilities to (a) inform patients of 334Brunicardi_Ch48_p2061-p2076.indd 206419/02/19 1:49 PM 2065ETHICS, PALLIATIVE CARE, AND CARE AT THE END OF LIFECHAPTER 48their rights to have advance directives, and (b) to document those advance directives in the chart at the time any patient is admitted to the healthcare facility.4 However, only a minority of patients in U.S. hospitals have advance directives despite concerted efforts to teach the public of their benefits and pro-vide resources to help patients prepare and maintain them. For example, the ambitious SUPPORT trial used specially trained nurses to promote communication between physicians, patients, and their surrogates to improve the care and decision making of critically ill patients. Despite this concerted effort, the interven-tion demonstrated “no significant change in the timing of do not resuscitate (DNR) orders, in physician-patient agreement about DNR orders, in the number of undesirable days (patients’ experiences), in the prevalence of pain, or in the resources consumed.”23Some of the reluctance around physician–patient agree-ment about DNR orders may reflect patient and family anxiety that DNR orders equate to “do not treat.” Patients and families should be assured, when appropriate, that declarations of DNR/do not intubate will not necessarily result in a change in ongoing routine clinical care. The issue of temporarily rescinding DNR/do not intubate orders around the time of an operative procedure may also need to be addressed with the family.Patients should be encouraged to clearly identify their sur-rogates, both formally and informally, early in the course of treatment and before any major elective operation. Often, around the time of surgery or at the end of life, there are limits to patient autonomy in medical decision-making. Seeking an advance directive or surrogate decision maker requires time that is not always available when the clinical situation deterio-rates. As such, these issues should be clarified as early as pos-sible in the patient–physician relationship.Withdrawing and Withholding Life-Sustaining TherapiesThe implementation of various forms of life support technol-ogy raise a number of legal and ethical concerns about when it is permissible to withdraw or withhold available therapeu-tic technology. There is general consensus among ethicists that there are no philosophic differences between withdrawing (stopping) or withholding (not starting) treatments that are no longer beneficial.24 However, the right to refuse, withdraw, and withhold beneficial treatments was not established before the landmark case of Karen Ann Quinlan. In 1975, Quinlan lapsed into a persistent vegetative state requiring ventilator support. After several months without clinical improvement, Quinlan’s parents asked the hospital to withdraw ventilator support. The hospital refused, fearing prosecution for euthanasia. The case was appealed to the New Jersey Supreme Court where the justices ruled that it was permissible to withdraw ventilator support.25 This case established a now commonly recognized right to with-draw “extraordinary” life-saving technology if it is no longer desired by the patient or the patient’s surrogate.The difference between “ordinary” and “extraordinary” care, and whether there is an ethical difference in withhold-ing or withdrawing “ordinary” vs. “extraordinary” care, has been an area of much contention. The 1983 Nancy Cruzan case highlighted this issue. In this case, Cruzan had suffered severe injuries in an automobile crash that rendered her in a persistent vegetative state. Cruzan’s family asked that her tube feeds be withheld, but the hospital refused. The case was appealed to the U.S. Supreme Court, which ruled that the tube feeding could be withheld if her parents demonstrated “clear and convincing evidence” that the incapacitated patient would have rejected the treatment.26 In this ruling, the court essentially ruled that there was no legal distinction between “ordinary” vs. “extraor-dinary” life-sustaining therapies.27 In allowing the feeding tube to be removed, the court accepted the principle that a competent person (even through a surrogate decision maker) has the right to decline treatment under the Fourteenth Amendment of the U.S. Constitution. The court noted, however, that there has to be clear and convincing evidence of the patient’s wishes (con-sistent with the principle of autonomy) and that the burdens of the medical intervention should outweigh its benefits (consistent with the principles of beneficence and nonmaleficence).In deliberating the issue of withdrawing vs. withholding life-sustaining therapies, the principle of “double effect” is often mentioned. According to the principle of “double effect,” a treatment (e.g., opioid administration in the terminally ill) that is intended to help and not harm the patient (i.e., relieve pain) is ethically acceptable even if an unintended consequence (side effect) of its administration is to shorten the life of the patient (e.g., by respiratory depression). Under the principle of double effect, a physician may withhold or withdraw a life-sustaining therapy if the surgeon’s intent is to relieve suffering, not to has-ten death. The classic formulation of double effect has four ele-ments (Fig. 48-3).Withholding or withdrawing of life-sustaining therapy is ethically justified under the principle of double effect if the phy-sician’s intent is to relieve suffering, not to kill the patient. Thus, in managing the distress of the dying, there is a fundamental eth-ical difference between titrating medications rapidly to achieve relief of distress and administering a very large bolus with the 55Double effectConditionsActionGood effectBad effectGood effectBad effectActIntrinsic moral wrongAgentIntendsGood effectBad effect1234ActBad effectGood effectFigure 48-3. The four elements of the double effect principle: (1) The good effect is produced directly by the action and not by the bad effect. (2) The person must intend only the good effect, even though the bad effect may be foreseen. (3) The act itself must not be intrinsically wrong, or needs to be at least neutral. (4) The good effect is sufficiently desirable to compensate for allowing the bad effect.Brunicardi_Ch48_p2061-p2076.indd 206519/02/19 1:49 PM 2066SPECIFIC CONSIDERATIONSPART IIintent of causing apnea. It is important to note, however, that although the use of opioids for pain relief in advanced illness is frequently cited as the classic example of the double effect rule, opioids can be used safely without significant risk. In fact, if administered appropriately, in the vast majority of instances the rule of double effect need not be invoked when administering opioids for symptom relief in advanced illness.28In accepting the ethical equivalence of withholding and withdrawing of life-sustaining therapy, surgeons can make dif-ficult treatment decisions in the face of prognostic uncertainty.24 In light of this, some important principles to consider when con-sidering withdrawal of life-sustaining therapy include: (a) Any and all treatments can be withdrawn. If circumstances justify withdrawal of one therapy (e.g., IV pressors, antibiotics), they may also justify withdrawal of others; (b) Be aware of the sym-bolic value of continuing some therapies (e.g., nutrition, hydra-tion) even though their role in palliation is questionable; (c) Before withdrawing life-sustaining therapy, ask the patient and family if a spiritual advisor (e.g., pastor, imam, rabbi, or priest) should be called; and (d) Consider requesting an ethics consult.Although the clinical setting may seem limited, a range of options usually exists with respect to withdrawing or with-holding treatment, allowing for an incremental approach, for example (a) continuing the current regimen without adding new interventions or tests; (b) continuing the current regimen but withdrawing elements when they are no longer beneficial; and (c) withdrawing and withholding all treatments that are not tar-geted to relieve symptoms and maximize patient comfort.34The surgeon might consider discussing the clinical situ-ation with the patient or proxy decision maker, identify the various therapeutic options, and delineate the reasons why with-holding or withdrawing life-sustaining therapy would be in the patient’s best interest. If the patient (or designated proxy deci-sion maker) does not agree with withholding or withdrawing life-sustaining therapy, the surgeon should consider involving consultants who have participated in the patient’s care, experts in palliative or end-of-life care or recommend a second medical opinion. If the second opinion corroborates that life-sustaining therapy should be withheld or withdrawn but the patient/family continues to disagree, the surgeon should consider assistance from institutional resources such as the ethics committee and hospital administration. Although the surgeon is not ethically obligated to provide treatment that he or she believes is futile, the surgeon is responsible for continued care of the patient, which may involve transferring the patient to a surgeon who is willing to provide the requested intervention.24Living Donor Liver TransplantationOne unique ethical issue that deserves special mention is that of living donor liver transplantation. Living donor kidney transplantation has been practiced for almost 50 years and has become a routine part of clinical care, but living donor liver transplantation was first performed in the late 1980s with par-ent-to-child grafts and in the late 1990s for adult-to-adult grafts. These procedures are unique in that there are two patients, one with a diseased organ who requires intervention to be made well and one who is healthy and is being made unwell, albeit usu-ally temporarily, during the intervention. Performing an ethi-cal analysis of this situation requires considering both risks and benefits to each of the patients individually.For the recipient, the benefits of receiving a living donor organ as opposed to a deceased donor organ are many: first, there is reduced risk of death on the waitlist, and second, there is a potential for improved post-transplant outcomes due to improved matching between relatives and the absence of hemo-dynamic instability often present before organ procurement in a deceased donor.30 Furthermore, the use of living donor organs is supported by the principal of utility, maximizing efficient use of organs.32The benefit to the organ donor is in fulfillment of an altru-istic ideal and satisfaction associated with having extended the recipient’s life, while the risks are those associated with partial hepatectomy, a procedure that is not without risks including postoperative complications and mortality, the risk of which is estimated to be 0.15%.29 The ethical concern in this case is hav-ing possibly violated the principle of nonmaleficence.This particular ethical issue emphasizes the importance of truly informed consent. The donor should be provided with information on local complication and mortality rates and allowed sufficient time to consider the risks and benefits with-out pressure from healthcare workers.30 Furthermore, experi-enced centers have recommended that living donors have access to sufficient resources and strong support from an institutions’ ethics committee, given substantial pressure exerted by the criti-cal illness of a family member.31PALLIATIVE CAREGeneral Principles of Palliative CarePalliative care is a coordinated, interdisciplinary effort that aims to relieve suffering and improve quality of life for patients and their families in the context of serious illness.33 It is offered simultaneously with all other appropriate medical treatment, and its indication is not limited to situations associated with a poor prognosis for survival. Palliative care strives to achieve more than symptom control, but it should not be confused with noncurative treatment.The World Health Organization defines palliative care as “an approach that improves the quality of life of patients and their families facing the problems associated with life-threat-ening illness, through the prevention and relief of suffering by means of early identification and impeccable assessment and treatment of pain and other problems, physical, psychosocial, and spiritual.”34 Palliative care is both a philosophy of care and an organized, highly structured system for delivering care.Palliative care includes the entire spectrum of intervention for the relief of symptoms and the promotion of quality of life. No specific therapy, including surgical intervention, is excluded from consideration. Therefore, surgeons have valuable contri-butions to make to palliative care. In fact, the term palliative care was coined in 1975 by Canadian surgeon, Balfour Mount. Furthermore, surgical palliative care can be defined as the treat-ment of suffering and the promotion of quality of life for seri-ously or terminally ill patients under the care of surgeons.36 The standard of palliative treatment lies in the agreement between patient and physician that the expected outcome is relief from distressing symptoms, lessening of pain, and improvement of quality of life. The decision to intervene is based on the treat-ment’s ability to meet the stated goals, rather than its impact on the underlying disease.The fundamental elements of palliative care consist of pain and nonpain symptom management, communication among patients, their families, and care providers, and conti-nuity of care across health systems and through the trajectory Brunicardi_Ch48_p2061-p2076.indd 206619/02/19 1:49 PM 2067ETHICS, PALLIATIVE CARE, AND CARE AT THE END OF LIFECHAPTER 48of illness. Additional features of system-based palliative care are team-based planning that includes patient and family; close attention to spiritual matters; and psychosocial support for patients, their families, and care providers, including bereave-ment support.Indications for palliative care consultation in surgical practice include: (a) patients with conditions that are progres-sive and life-limiting, especially if characterized by burdensome symptoms, functional decline, and progressive cognitive defi-cits; (b) assistance in clarification or reorientation of patient/family goals of care; (c) assistance in resolution of ethical dilemmas; (d) situations in which a patient/surrogate declines further invasive or curative treatments with stated preference for comfort measures only; (e) patients who are expected to die imminently or shortly after hospital discharge; and (f) provision of bereavement support for patient care staff, particularly after loss of a colleague under care36 (Table 48-1). Although all patients, regardless of prognosis, may benefit from the services of a palliative care physician, hospice care is a specific form of palliative care intended for patients who have an estimated prognosis of 6 months or less to live. Hospice care is covered under Medicare Part A, and benefits may be continued beyond the original 6 months of estimated survival if physicians certify that life expectancy remains limited to 6 months or less. Although most Americans indicate a preference to die at home, nearly 75% die in an institutional setting. Earlier referral and wider use of the hospice benefit may help more patients achieve their goal of dying at home.Concepts of Suffering, Pain, Health, and HealingPalliative care specifically addresses the individual patient’s experience of suffering due to illness. Indeed, the philosophi-cal origins of palliative care began with attention to suffering and the existential questions suffering engenders. More than mere technologic evolution in the management of symptoms, the early proponents of palliative care sought a revolution in the moral foundations of medicine that challenged the assumptions that so often seemed to result in futile invasive intervention, and identified many of the problems that were subsequently taken up by medical ethicists. This reorientation of the goals of medical care from a focus on disease and its management to the patient’s experience of illness focuses attention on the purpose of medicine and the meaning of health and healing.Over the past half century, several concepts and theo-ries about the nature of pain, suffering, and health have been proposed in service of the evolving conceptual framework of palliative care. For example, while considering the differences between disease-oriented and illness-oriented approaches to the care of seriously ill patients, psychiatrist Arthur Kleinman wrote, “There is a moral core to healing in all societies. [Healing] is the central purpose of medicine . . . the purpose of medicine is both control of disease processes and care for the illness experience. Nowhere is this clearer than in the relationship of the chronically ill to their medical system: For them, the control of disease is by definition limited; care for the life problems created by the disorder is the chief issue.”33The relief of pain has been the clinical foundation for hospice and palliative care. Pain is defined by the International Association for the Study of Pain as “an unpleasant sensory and emotional experience associated with actual or potential tissue damage, or described in terms of such damage.”38 For purposes of interdisciplinary palliative care, Saunders’s concept of “total pain”37 is a more useful definition and is frequently used as the basis for palliative assessments. Total pain is the sum total of four principal domains of pain: physical, psychologic, social or socioeconomic, and spiritual. Each of these contributes to, but is not synonymous with, suffering.Effective Communication and Negotiating the Goals of CareChanging the goals of care from cure to palliation near the end of life can be both emotionally and clinically challenging. It depends on determination of a clear prognosis and can be aided by effective communication. Unfortunately, prognostication can be notoriously difficult and inaccurate in advanced illness, and Christakis has argued that, to a large degree, physicians have abdicated their traditional responsibility to provide clear prognosis regarding incurable disease and approaching death.40 However, there are validated tools for prognosis in critical ill-ness (APACHE, MODS, etc.), and with most advanced diseases, functional status is the most powerful predictor of survival. For example, patients with advanced metastatic cancer who are rest-ing or sleeping for 50% or more of normal waking hours and require some assistance with activities of daily living (ADL) have a projected survival of weeks, and patients who are essen-tially bedfast and dependent for ADL have a projected survival of days to a week or two at best. Table 48-2 shows a simple prognostic tool to aid clinicians in recognizing patients nearing the end of life.Alternatively, the Karnofsky Performance Scale is a scale of functional status ranging from 100 (high level of function) to 0 (death). It is commonly used in palliative care to roughly assess a patient’s anticipated needs as well as prognosis. The Palliative Performance Scale41 is a validated42 expansion of the Karnofsky Performance Scale that includes five palliative-focused domains, including ambulation, activity level, self-care, intake, and level of consciousness, in addition to evidence of disease. The Missoula-Vitas Quality of Life Index is a 25-question scale specifically for palliative care and hospice patients that scores symptoms, function, interpersonal relationships, well-being, and spirituality. Updates and Spanish versions are available.39Regardless of the prognostic tool used, the prognosis should be conveyed to the patient and family. If done well, communication and negotiation with patients and families about advanced terminal illnesses can potentially avoid great 66Table 48-1Indications for palliative care consultationPatients with conditions that are progressive and life-limiting, especially if characterized by burdensome symptoms, functional decline, and progressive cognitive deficitsAssistance in clarification or reorientation of patient/family goals of careAssistance in resolution of ethical dilemmasSituations in which patient/surrogate declines further invasive or curative treatments with stated preference for comfort measures onlyPatients who are expected to die imminently or shortly after hospital dischargeProvision of bereavement support for patient care staff, particularly after loss of a colleague under careBrunicardi_Ch48_p2061-p2076.indd 206719/02/19 1:49 PM 2068SPECIFIC CONSIDERATIONSPART IITable 48-2Simple prognostication tool in advanced illness (especially cancer)FUNCTIONAL LEVELPERFORMANCE STATUS (ECOG)PROGNOSISAble to perform all basic ADLs independently and some IADLs2MonthsResting/sleeping up to 50% or more of waking hours and requiring some assistance with basic ADLs3Weeks to a few monthsDependent for basic ADLs and bed-to-chair existence4Days to a few weeks at mostThese observations apply to patients with advanced, progressive, incurable illnesses (e.g., metastatic cancer refractory to treatment).Basic ADL = activities of daily living (e.g., transferring, toileting, bathing, dressing, and feeding oneself); IADL = instrumental activities of daily living (e.g., more complex activities such as meal preparation, performing household chores, balancing a checkbook, shopping, etc.); ECOG = Eastern Cooperative Oncology Group functional (performance) status.Table 48-3Communicating unfavorable news: important principles• Setting: Find a quiet, private place to meet. Sit down close to the patient.• Listen: Clarify the patient’s and/or the family’s understanding of the situation.• “Warning shot”: Prepare patient and family and obtain their permission to communicate bad news (e.g., “I’m afraid I have bad news.”).• Silence: Pause after giving bad news. Allow patient/family to absorb/react to the news.• Encourage: Convey hope that is realistic and appropriate to the circumstances (e.g., patient will not be abandoned; symptoms will be controlled).psychologic harm and help make a difficult transition easier. To communicate effectively and compassionately, it is helpful to pursue an organized process similar to the structured history and physical central to the evaluation of any patient. One such structured approach to delivering unfavorable news proposes six steps that can be easily learned by clinicians: (a) getting started by selection of the appropriate setting, introductions, and seating; (b) determining what the patient or family knows; (c) determining what the patient or family wants to know; (d) giving the information; (e) expressing empathy; and (f) establishing expectations, planning, and aftercare (Table 48-3).43 Success with this approach to breaking bad news is critically depen-dent upon the clinician’s ability to empathically respond to the patient’s (and family’s) reaction to the news.44 The empathic response does not require the surgeon to share the same emo-tions of the patient, but it does require the surgeon to identify the patient’s emotion and accurately reflect that awareness back to the patient. Such effective communication may be facilitated by involving other members of the healthcare team who have developed relationships with the patient and their family. Patient assessment in these conversations should give the highest prior-ity to identifying and responding to the most immediate source of distress. Relieving a pressing symptom is prerequisite for a more thorough search for other potential sources of suffering, and the assessment process itself can be therapeutic if conducted in a respectful and gentle manner.CARE AT THE END OF LIFEThe process of dying and the care of a patient at the time of death is a distinct clinical entity that demands specific skills from physicians. The issues specific to dying and the available tools for compassionate care at the end of life are addressed in this section.The Syndrome of Imminent Demise34,45In a patient who has progressed to the terminal stage of an advanced illness (e.g., cancer), a number of signs provide evi-dence of imminent death. As terminally ill patients progress toward death, they become increasingly bedbound, requiring assistance for all basic ADL. There is a steady decrease in desire and requests for food and fluids. More distressing to the dying patient is a progressively dry mouth that may be confused by the treating team as thirst. It is often exacerbated by anticholinergic medications, mouth breathing, and supplemental oxygen (O2) administered without humidification.With progressive debility, fatigue, and weight loss, it is common for terminally ill patients to experience increasing dif-ficulty swallowing. This may result in aspiration episodes and an inability to swallow tablets, requiring alternative routes for medication administration (e.g., IV, SC, PR, sublingual, buccal, or transdermal). In addition to the increased risk of aspiration, patients near death develop great difficulty clearing oropharyn-geal and upper airway secretions, leading to noisy breathing or the so-called “death rattle.” As death approaches, the respiratory pattern may change to increasingly frequent periods of apnea often following a Cheyne-Stokes pattern of rapid, progressively longer breaths leading up to an apneic period. As circulatory instability develops near death, patients may exhibit cool and mottled extremities. Periods of confusion are often accompanied by decreasing urine output and episodes of fecal and urinary incontinence.A number of cognitive changes occur as death approaches. Patients who are in the last days of life may demonstrate some signs of confusion or delirium. Agitated delirium is a promi-nent feature of a difficult death. Other cognitive changes that may be seen include a decreased interest in social interactions, increased somnolence, reduced attention span, disorientation to time (often with altered sleep-wake cycles), and an altered dream life, including vivid “waking dreams” or visual halluci-nations. Reduced hearing and visual acuity may be an issue for some patients; however, patients who appear comatose may still be aware of their surroundings. Severely cachectic patients may lose the ability to keep their eyes closed during sleep because of loss of the retro-orbital fat pad.Common Symptoms at the End of Life and Their Management34,45,46The three most common, major symptoms that threaten the comfort of dying patients in their last days are respiratory Brunicardi_Ch48_p2061-p2076.indd 206819/02/19 1:49 PM 2069ETHICS, PALLIATIVE CARE, AND CARE AT THE END OF LIFECHAPTER 48Table 48-4Principles of pharmacotherapy in palliative care• Believe patient report of symptoms.• Modify pathologic process when possible and appropriate.• In terminally ill patients, avoid medications not directly linked to symptom control.• Use a multidisciplinary approach.• Consider nonpharmacologic approaches whenever possible.• Engage participation of clinical pharmacist in treatment plan.• Select drugs that can multitask (i.e., use haloperidol for agitated delirium and nausea).• For pain, use adjuvant medications when possible (see Table 48-7).• When using opioids, spare when possible (adjuvant medication, local or regional anesthetics, surgical interventions, etc.).• Avoid fixed combination drugs.• Avoid excessive cost.• Select agents with minimum side effects.• Anticipate and prophylax against side effects.• For older adult patients, the hypoproteinemic, the azotemic: “Start low and go slow.”• Oral route whenever possible and practical.• No intramuscular injections.• Scheduled dosing, not as needed, for persistent symptoms.• Stepwise approach. (See the World Health Organization Analgesic Ladder for pain, Table 48-5.)• Reassess continuously and titrate to effect.• Use equianalgesic doses when changing opioids (see Table 48-5).• Assess the patient’s and family’s comprehension of management plan.Table 48-5The World Health Organization’s three-step ladder for control of cancer pain30Step 1: mild pain (visual analogue scale, 1–3) Nonopioid ± adjuvant medicationStep 2: moderate pain (visual analogue scale, 4–6) Opioid for mild to moderate pain and nonopioid ± an adjuvantStep 3: severe pain (visual analogue scale, 7–10) Opioid for moderate to severe pain ± nonopioid ± an adjuvantThe primary treatment of dyspnea (air hunger) in the dying is opioids, which should be cautiously titrated to increase com-fort and reduce tachypnea to a range of 15 to 20 breaths per minute. Air movement across the face generated by a fan can sometimes be quite helpful. If this is not effective, empirical use of supplemental O2 by nasal cannula (2–3 L/min) may bring some subjective relief, independent of observable changes in pulse oximetry. Supplemental O2 should be humidified to avoid exacerbation of dry mouth. Typical starting doses of an immedi-ate release opioid for breathlessness should be one-half to two-thirds of a starting dose of the same agent for cancer pain. For patients already on opioids for pain, a 25% to 50% increment in the dose of the current immediate release agent for breakthrough pain often will be effective in relieving breathlessness in addi-tion to breakthrough pain.The availability and variety of drugs should not prevent consideration of nonpharmacologic therapy. Massage therapy, music therapy, art therapy, guided imagery, hypnosis, physi-cal therapy, pet therapy, and others play a constructive role not only for the relief of symptoms but also for promoting a sense of hope through improving function, aesthetic pleasure, and social connectedness. Talents and capacities neglected during the treatment and progression of disease can be recovered even in the most advanced stages of illness.Pain is often less of a problem in the last days of life because the reduced activity level is associated with lower inci-dent pain. This, combined with lower renal clearance of opioids, may result in greater potency of the prescribed agents. Severe pain crises are fortunately rare, but when they are inadequately addressed, can cause great and lasting distress (complicated grief) for loved ones who witness the final hours or days of agony. Such situations may require continuous administration of parenteral opioids. As death approaches and patients become less verbal, it is important to assess pain frequently, including the use of close observation for nonverbal signs of distress (e.g., grimacing, increased respiratory rate). Adequate dosing of opi-oid analgesics may require alternate route(s) of administration other than oral as patients become more somnolent or develop swallowing difficulties. Opioids should not be stopped abruptly, even if the patient becomes nonresponsive, because sudden withdrawal can cause severe distress.49,50Cognitive failure at the end of life is manifested in most patients by increasing somnolence and delirium. Gradually increasing somnolence can be accompanied by periods of dis-orientation and mild confusion, and it may respond to the reas-suring presence of loved ones and caregivers with minimal need for medications. A more distressing form of delirium also can distress, pain, and cognitive failure. General principles that are applicable to symptom management in the last days of life include (a) anticipating symptoms before they develop; (b) minimizing technologic interventions (usually manage symp-toms with medications); and (c) planning alternative routes for medications in case the oral route fails. It may be possible to cautiously reduce the dose of opioids and other medications as renal clearance decreases near the end of life, but it is important to remember that increased somnolence and decreasing respira-tions are prominent features of the dying process independent of medication side effects. Sudden cessation of opioid analgesics near the end of life could precipitate withdrawal symptoms, and therefore medications should not be stopped for increasing som-nolence or slowed respirations.The principles of pharmacotherapy for pain and non-pain symptoms in the palliative care setting are outlined in Table 48-4. The World Health Organization,35 the United States Agency for Healthcare Policy and Research,47 the Academy of Hospice and Palliative Medicine,48 and many other agencies have endorsed a “step ladder” approach to cancer pain man-agement that can predictably result in satisfactory pain control in most patients (Table 48-5). More refractory pain problems require additional expertise, and occasionally, more invasive approaches (Tables 48-6 and 48-7).Brunicardi_Ch48_p2061-p2076.indd 206919/02/19 1:49 PM 2070SPECIFIC CONSIDERATIONSPART IITable 48-6Analgesics for persistent painDRUGINITIAL DOSING (ADULT, >60 kg)COMMENTSMild persistent pain, visual analogue scale (VAS) 1–3 Acetaminophen (Tylenol)325–650 mg PO four times a day Maximum = 3200 mg/24 hUse <2400 mg if other potentially hepatotoxic drugs taken. Acetaminophen contained in concurrent nonprescription medications can easily exceed maximum daily allowable dose. Aspirin600–1500 mg PO four times a dayGastric bleeding, platelet dysfunction Choline magnesium trisalicylate (Trilisate)750–1500 mg PO twice a dayUseful for avoiding platelet dysfunction Ibuprofen (Advil, Motrin)200–400 mg PO four times a day Maximum = 3200 mg/24 hGastropathy, nephropathy, decreased platelet aggregation Naproxen (Naprosyn)250 mg PO twice a day Maximum = 1300 mg/24 hAvailable as a transcutaneous gelModerate persistent pain, VAS 4–6 Hydrocodone (Vicodin, Lortab)5–7.5 mg PO every 4 hoursMost prescribed drug in the United StatesAcetaminophen in compounded drug limits use to moderate pain Oxycodone5 mg PO every 4 hoursSold as single agent or compounded with aspirin or acetaminophenSlow release form available (Oxycontin)Severe persistent pain, VAS 7–10 Morphine10 mg PO every 2–4 hours 2–4 mg IV, SC every 1–2 hoursStandard drug for comparison to alternative opioids. Avoid or caution when giving to older adults, patients with diminished glomerular filtration rate, or liver disease. Slow release PO form available (MS Contin). Hydromorphone1–3 mg PO, PR every 4 hours 1 mg IV, SC every 1–2 hoursSuppository form availableOral dose forms limited to 4 mg maximum Fentanyl, transdermal12 μg/h patch every 72 hoursNot for acute pain management. Do not use on opioid-naive patients. Absorption unpredictable in cachectic patients. MethadoneConsultation with pain management, clinical pharmacists, or palliative care/hospice services skilled in methadone use is recommended for those inexperienced in prescribing methadone.Not a first-line agent, although very effective, especially for pain with a neuropathic componentVery inexpensiveCan be given PO, IV, SC, PR, sublingually, and vaginallyIts long half-life makes dosing more difficult than alternative opioids and close monitoring is required when initiating.Numerous medications, alcohol, and cigarette smoking can alter its serum levels.Physicians who write methadone prescriptions for pain should specify this indication. Methadone use for drug withdrawal treatment requires special licensure.Risk factors for NSAID-induced nephropathy include: advanced age, decreased glomerular filtration rate, congestive heart failure, hypovolemia, pressors, hepatic dysfunction, concomitant nephrotoxic agents. Dose reduction and hydration reduce risk.Opioids compounded with aspirin or acetaminophen are limited to treatment of moderate persistent pain because of dose-limiting toxicities of acetaminophen and aspirin.Slow-release preparations of morphine and oxycodone may be given rectally.Timed-release tablets or patches should never be crushed or cut.Opioid analgesics are the agents of choice for severe cancer-related pain. Sedation is a common side effect when initiating opioid therapy. Tolerance to this usually develops within a few days. If sedation persists beyond a few days, a stimulant (methylphenidate 2.5–5 mg PO twice a day) can be given.Initiate bowel stimulant prophylaxis for constipation when prescribing opioids unless contraindicated.Adjuvant or coanalgesic agents are drugs that enhance analgesic efficacy of opioids, treat concurrent symptoms that exacerbate pain, or provide independent analgesia for specific types of pain (e.g., a tricyclic antidepressant for treatment of neuropathic pain). Coanalgesics can be initiated for persistent pain at any visual analogue scale level. Gabapentin is commonly used as an initial agent for neuropathic pain.No place for meperidine (Demerol), propoxyphene (Darvon, Darvocet, or mixed agonist-antagonist agents [Stadol, Talwin]) in management of persistent pain.Always consider alternative approaches (axial analgesia, operative approaches, etc.) when managing severe persistent pain.Note: These are not recommendations for specific patients. The interand intraindividual variability to opioids requires individualizing dosing and titration to effect.Adapted with permission from Cameron JL: Current Surgical Therapy, 9th ed. Philadelphia, PA: Elsevier; 2008.Brunicardi_Ch48_p2061-p2076.indd 207019/02/19 1:49 PM 2071ETHICS, PALLIATIVE CARE, AND CARE AT THE END OF LIFECHAPTER 48Table 48-7Examples of adjuvant medications for treatment of neuropathic, visceral, and bone painaDRUG CLASSINITIAL DOSING (ADULT, >60 kg)COMMENTSTricyclic antidepressants Best for continuous burning or tingling  pain and allodynia Efficacy for pain not due to  antidepressant effectAmitriptyline 10–25 mg PO before bedNortriptyline 10–25 mg PO one per daySedating properties may be useful for relief of other concurrent symptoms. Side effects may precede benefit. Avoid in older adult patients due to anticholinergic side effects. Dose generally less than that required  for antidepressant effectDoxepin 10–25 mg PO before bedLess anticholinergic effect Dose titrated up every few days until  effect. Pain may respond to alternative antidepressants if no response to initial agent.Imipramine 10–25 mg PO one per day Anticonvulsants For shooting, stabbing painGabapentin 100–1200 mg PO three times a day. Titrate up rapidly as needed. Max: 3600 mg daily in divided dosesCommonly used first-line agent. Generally well tolerated. Does not require blood level monitoring. Carbamazepine 200 mg PO every 12 hoursPregabalin starting dose 25–50 mg PO three times a dayEffective. Well studied. Requires blood monitoring.Does not require blood monitoring. Valproic acid 250 mg PO three times a day Local anesthetics Systemic use requires monitoring.  Nebulized local anesthetics (lidocaine, bupivacaine) can be used for severe, refractory cough.Lidocaine transdermal patch 5%. Apply to painful areas. Max: 3 simultaneous patches over 12 hours (each patch contains 700 mg lidocaine).Lidocaine/prilocaine topical. Apply to painful areas.Systemic toxicity can result from applying more than recommended number per unit time and in patients with liver failure. Effective for postherpetic neuralgia.MiscellaneousBisphosphonates (pamidronate, zoledronic acid)For bone pain and reduced incidence of skeletal complications secondary to malignancy—best results in myeloma and breast cancer. Contraindicated in renal failure. Calcitonin nasal sprayRefractory bone pain DexamethasoneFor bone pain, acute nerve compression, visceral pain secondary to tumor infiltration or luminal obstruction by reducing inflammatory component of tumor Radionuclides (Sr-89)For malignant bone pain secondary to osteoclastic activity. 4–6 wk delay in benefit. Requires adequate bone marrow reserve. For prognosis of more than 3 mo. OctreotideReduces GI secretions that contribute to visceral painaRecommendations are based on experience of practitioners of hospice and palliative medicine and in some instances do not reflect current clinical trials.Brunicardi_Ch48_p2061-p2076.indd 207119/02/19 1:49 PM 2072SPECIFIC CONSIDERATIONSPART IIdevelop, manifested by increasing agitation that may require the use of neuroleptic medications. Increasing amounts of opioids and/or benzodiazepines may exacerbate the delirium (especially in the elderly).Pronouncing Death51If the body is hypothermic or has been hypothermic, such as a drowning victim pulled from the water in the winter, the phy-sician should not declare death until warming attempts have been made. In the hospital, hospice, or home setting, the dec-laration of death becomes part of the medical or legal record of the event. There are a number of physical signs of death a physician should look for in confirming the patient’s demise: complete lack of responsiveness to verbal or tactile stimuli, absence of heart beat and respirations, fixed pupils, skin color change to a waxen hue as blood settles, gradual poikilothermia, and sphincter relaxation with loss of urine and feces. For deaths in the home with patients who have been enrolled in hospice, the hospice nurse on call should be contacted immediately. In some states, deaths at home may require a brief police investiga-tion and report. For deaths in the hospital, the family must be notified (in person, if possible). A coroner or medical examiner may need to be contacted under specific circumstances (e.g., deaths in the operating room), but most deaths do not require their services. The pronouncing physician will need to complete a death certificate according to local regulations. Survivors may also be approached, if appropriate, regarding potential autopsy and organ donation. Finally, it is important to accommodate religious rituals that may be important to the dying patient or the family. Bereavement is the experience of loss by death of a person to whom one is attached. Mourning is the process of adapting to such a loss in the thoughts, feelings, and behaviors that one experiences after the loss.52 Although grief and mourn-ing are accentuated in the immediate period around death, it is important to note that patients and families may have begun the process of bereavement well before the time of death as patients and families grieve incremental losses of independence, vitality, and control. In addition to the surviving loved ones, it is impor-tant to acknowledge that caregivers also experience grief for the loss of their patients.53,54Aid in DyingFive European countries, Canada, and six U.S. states have legal-ized physician-assisted suicide, medical assistance in dying, or aid-in-dying, in some form, ranging from hospital-based pro-grams to provision of fatal doses of medications for home self-administration.55-57 Medical assistance in dying is a complex ethical and legal issues with divergent opinions among the pub-lic and healthcare providers.58,59 While aid-in-dying laws passed in the United States vary somewhat, these laws essentially all allow physicians to prescribe a lethal dose of medication to men-tally, competent, terminally ill adult patients for the purpose of achieving the end of life.60,61 Key areas of ethical consideration in this area include the benefit and harm of death; the relation-ship between passive euthanasia, active euthanasia, withholding treatment, and withdrawing treatment; the morality of physician and nursing participation in deliberately causing death; and the management of conscientious objection.60,62 Although surgeons outside of the critical care arena may only infrequently be asked to participate in aid-in-dying, it is important to be familiar with local legislation so that appropriate information can be provided to patients who request it.PROFESSIONAL ETHICS: CONFLICT OF INTEREST, RESEARCH, AND CLINICAL ETHICSConflict of InterestConflicts of interest for surgeons can arise in many situations in which the potential benefits or gains to be realized by the surgeon are, or are perceived to be, in conflict with the respon-sibility to put the patient’s interests before the surgeon’s own. Conflicts of interest for the surgeon can involve actual or per-ceived situations in which the individual stands to gain mon-etarily by his or her role as a physician or investigator. In the academic community, monetary gain may not be the primary factor. Instead, motivators such as power, tenure, or authorship on a publication may serve as potential sources of conflict of interest. For example, the accrual of subjects in research studies or patients in surgical series may ensure surgeons better author-ship or more financial gains. The dual-role of the surgeon-scien-tist therefore needs to be considered because the duty as surgeon can conflict with the role of scientist or clinical researcher.Research EthicsOver the last three decades in the United States, the ethical requirements for the conduct of human subject research have been formalized and widely accepted. Although detailed informed consent is a necessary condition for the conduct of ethically good human subject research, other factors also deter-mine whether research is designed and conducted ethically. Emanuel and colleagues63 described seven requirements for all clinical research studies to be ethically sound: (a) value—enhancement(s) of health or knowledge must be derived from the research; (b) scientific validity—the research must be methodologically rigorous; (c) fair subject selection—scientific objectives, not vulnerability or privilege, and the potential for and distribution of risks and benefits, should deter-mine communities selected as study sites and the inclusion cri-teria for individual subjects; (d) favorable risk-benefit ratio—within the context of standard clinical practice and the research protocol, risks must be minimized, potential benefits enhanced, and the potential benefits to individuals and knowl-edge gained for society must outweigh the risks; (e) independent review—unaffiliated individuals must review the research and approve, amend, or terminate it; (f) informed consent—individuals should be informed about the research and pro-vide their voluntary consent; and (g) respect for enrolled subjects—subjects should have their privacy protected, the opportunity to withdraw, and their well-being monitored.63Special Concerns in Surgical ResearchA significant issue for clinical surgical research is that many surgical studies are retrospective in nature and are not com-monly undertaken in a prospective, double-blind, randomized fashion. For a randomized trial to be undertaken, the researchers should be in a state of equipoise—that is, there must be a state of genuine uncertainty on the part of the clinical investigator or the expert medical community regarding the comparative thera-peutic merits of each arm in a trial.64 To randomize subjects to receive two different treatments, a researcher must believe that the existing data are not sufficient to conclude that one treat-ment strategy is better than another. In designing surgical trials, surgeons usually have biases that one treatment is better than another and often have difficulty maintaining the state of equi-poise. As such, it is frequently difficult to demonstrate that a 77Brunicardi_Ch48_p2061-p2076.indd 207219/02/19 1:49 PM 2073ETHICS, PALLIATIVE CARE, AND CARE AT THE END OF LIFECHAPTER 48Table 48-8ICMJE criteria for authorshipAccording to ICMJE best practices recommendations, authors should fulfill each of the following four criteria67:1. Substantial contributions to the conception or design of the work; or the acquisition, analysis, or interpretation of data for the work2. Drafting the work or revising it critically for important intellectual content3. Final approval of the version to be published4. Agreement to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolvedContributors who do not fulfill all four criteria should be named in the manuscript in the acknowledgment section.Adapted with permission from Cameron JL: Current Surgical Therapy, 9th ed. Philadelphia, PA: Elsevier; 2008.randomized trial is necessary or feasible, and treatment options that question the validity of clinical tenets are difficult to accept. Meakins has suggested that a slightly different hierarchy of evi-dence applies to evidence-based surgery.65A second major issue for surgical trials is whether it is ethically acceptable to have a placebo-controlled surgical trial. Some commentators have argued that sham surgery is always wrong because, unlike a placebo medication that is harmless, every surgical procedure carries some risk.66 Others have argued that sham operations are essential to the design of a valid ran-domized clinical trial because, without a sham operation, it is not possible to know if the surgical intervention is the cause of improvement in patient symptoms or whether the improve-ment is due to the effect of having surgery.67,68 Most surgeons readily agree that designing an appropriately low-risk sham sur-gical procedure would create problems for the surgeon-patient relationship in that the surgeon would need to keep the sham a secret.69 In this sense, a sham surgical arm of a trial is very different from a placebo medication in that there cannot be blinding of the surgeon as to which procedure was undertaken. As a result, to have a sham surgery arm in a clinical trial, the interactions between the surgeon and the subject must be lim-ited, and the surgeon performing the procedure should not be the researcher who follows the subject during the trial. Despite difficulties with designing a surgical trial in which the surgeon could ethically perform a sham operation, there are specific cir-cumstances that allow for placebo operations to be conducted, so long as certain criteria are met and are analyzed on a case by case basis.70,71Surgical InnovationAn important issue is whether surgical innovation should be treated as research or as standard of care. Throughout history, many advances in surgical techniques and technologies have resulted from innovations of individual surgeons crafted dur-ing the course of challenging operations—such innovations and technologies have served to move the field of surgery forward.72 In the Korean and Vietnam wars, military guidelines for treat-ment of vascular injuries recommended ligation and amputation rather than interposition grafting of vascular injuries. Individual surgeons chose to ignore those guidelines and subsequently demonstrated the value of the reconstructive techniques that ultimately became the standard of care. It is debated whether modifications to an accepted surgical technique in an individual patient based on their circumstances and within the skill and judg-ment of an individual surgeon should require the same type of prior approval that enrollment in a clinical trial would warrant.73 However, if a surgeon decides to use a new technique on sev-eral occasions and to study the outcomes, Institutional Review Board approval and all other ethical requirements for research are necessary. These situations require strict oversight as well as explicit consent by the patient.74 In particular, when developing new and innovative techniques, the surgeon should work in close consultation with his or her senior colleagues, including the chairperson of the department. Frequently, more senior individuals can provide sage ethical advice regarding what constitutes minor innovative changes in a technique vs. true novel research.Compared to the formalized process for new drug approval by the Food and Drug Administration, the process for a surgeon developing an innovative operation can be relatively unregu-lated and unsupervised.The Ethics of AuthorshipAuthorship specifies who is responsible for published research. It confers both recognition for academic achievement as well as responsibility for the academic integrity of the published con-tent. Authorship is the stock in trade of productivity for aca-demic surgeons, and it plays a significant role in promotion and tenure. It can also be commodified in the form of intellectual property and patents in which the author and the author’s insti-tution have vested interests. Yet it can also become a liability if a given piece of work becomes embroiled in accusations of plagiarism, data fabrication, or other academic misconduct.In the past, criteria for authorship were unspecified: Those submitting manuscripts simply listed the authors with little or no need to substantiate their contribution to the work. Unfortu-nately, this informal process led to confusion and even abuse. For example, there has been a long tradition of awarding author-ship to the investigator who supervised or obtained funding for research, regardless of that person’s specific contribution to the manuscript. However, current recommendations specify that supervision and funding, by themselves, are insufficient criteria for authorship, and thus such individuals should only be included as authors if they make direct contributions to the work.75,76 A more disturbing example is the practice of “ghost writing” by which senior investigators publish industry-written research under their own name to bolster their productivity while providing a luster of academic integrity to industry.To address these conflicts of interest and to provide guid-ance to investigators, the International Committee of Medical Journal Editors (ICMJE) provides recommendations on criteria for authorship so that individuals who contributed to the intel-lectual content of a work get appropriate credit and that all those listed as authors take responsibility and are accountable for the published work. The ICMJE recommendations for authorship can be found in Table 48-8.75 Furthermore, the ICMJE recom-mends that each author should be able to identify the contribu-tion that each other author made to the work and be confident regarding the integrity of their co-authors. The ICMJE also recommends that individuals who do not meet these criteria be acknowledged in the manuscript, providing appropriate pro-cedures for such acknowledgement. Additionally, the ICMJE Brunicardi_Ch48_p2061-p2076.indd 207319/02/19 1:49 PM 2074SPECIFIC CONSIDERATIONSPART IIspecifically excludes certain types of contributions including acquisition of funding, general supervision of a research group, administrative support, writing assistance, technical editing, language editing, and proofreading.75Many journals have adopted these criteria, operational-izing them at the time of submission by having each author specify his or her contributions. These contributions are then disclosed in the published manuscript to further specify how credit and responsibility is shared.77 This approach has been shown to provide valuable information and has proved feasible in several journals, including The Lancet.78As research becomes increasingly interdisciplinary with ever-expanding teams of contributors, it can be difficult to determine which contributions warrant full authorship rather than simple acknowledgement. Individuals working together on research endeavors should have clear discussions early in the planning process about authorship, and those discus-sions should be continued throughout the project or study.Clinical Ethics: Disclosure of ErrorsDisclosure of error—either in medical or research matters—is important, but often difficult (see Chapter 12). Errors of judg-ment, errors in technique, and system errors are responsible for most errors that result in complications and deaths. Hospitals are evaluated based on the number of complications and deaths that occur in surgical patients, and surgeons traditionally review their complications and deaths in a formal exercise known as the mortality and morbidity conference, or M&M. The exercise places importance on the attending surgeon’s responsibility for errors made, whether he or she made them themselves, and the value of the exercise is related to the effect of “peer pressure”— the entire department knows about the case—on reducing repeated occurrences of such an error. Although a time-honored ritual in surgery, the M&M conference is nonetheless a poor method for analyzing causes of error and for developing methods to prevent them. Moreover, the proceedings of the M&M con-ference are protected from disclosure by the privilege of “peer review,” and the details are thus rarely shared with patients or those outside the department.A report from the United States Institute of Medicine titled “To Err Is Human” highlighted the large number of medi-cal errors that occur and encouraged efforts to prevent patient harm.79 Medical errors are generally considered to be “prevent-able adverse medical events.”80 Medical errors occur with some frequency, and the question is what and how should patients be informed that a medical error has occurred.81Disclosure of error is consistent with the ethical virtue of candor (e.g., transparency and openness) and the ethical prin-ciple of respect for persons by involving patients in their care. In contrast, failing to disclose errors to patients under-mines public trust in medicine and potentially compro-mises adequate treatment of the consequences of errors and effective intervention to prevent future errors. In addition, fail-ure to self-disclose medical errors can be construed as a breach of professional ethics, as it is a failure to act in the patient’s best interests. Information regarding a medical error may be needed so that patients can make independent and well-informed deci-sions about future aspects of their care. The principles of auton-omy and justice dictate that surgeons need to respect individuals by being fair in providing accurate information about all aspects of their care—even when an error has occurred.Disclosing one’s own errors is therefore part of the ethi-cal standard of honesty and putting the patient’s interests above one’s own. Disclosing the errors of others is more complicated and may require careful consideration and consultation. Sur-geons sometimes discover that a prior operation has included an apparent error; an injured bile duct or a stenotic anastomosis may lead to the condition for which the surgeon is now treating the patient. Declaring a finding as an “error” may be inaccurate, however, and a nonjudgmental assessment of the situation is usually advisable. When clear evidence of a mistake is at hand, the surgeon’s responsibility is defined by his or her obligation to act as the patient’s agent.REFERENCESEntries highlighted in bright blue are key references. 1. Aristotle. Nichomachean Ethics, Book VI. In Ackrill J, ed. A New Aristotle Reader. Princeton, NJ: Princeton University Press; 1987:416. 2. Beauchamp TL, Childress JF. Principles of Biomedical Ethics, 3rd ed. New York: Oxford University Press; 1989. 3. Bosk C. Forgive and Remember, 2nd ed. Chicago, University of Chicago Press, 2003 (1979). 4. McCullough LB, Jones JW, Brody BA, eds. Surgical Ethics. New York: Oxford University Press; 1998. 5. Faden RR, Beauchamp TL. A History and Theory of Informed Consent. New York: Oxford University Press; 1986. 6. Bernat JL, Peterson LM. Patient-centered informed consent in surgical practice. Arch Surg. 2006;141:86-92. 7. Schneider CE. The Practice of Autonomy: Patients, Doctors, and Medical Decisions. New York: Oxford University Press; 1998. 8. Robb A, Etchells E, Cusimano MD, et al. A randomized trial of teaching bioethics to surgical residents. Am J Surg. 2005;189:453-457. 9. Steinemann S, Furoy D, Yost F, et al. Marriage of professional and technical tasks: a strategy to improve obtaining informed consent. Am J Surg. 2006;191:696-700. 10. Guadagnoli E, Soumerai SB, Gurwitz JH, et al. Improving dis-cussion of surgical treatment options for patients with breast cancer: local medical opinion leaders versus audit and perfor-mance feedback. Breast Cancer Res Treat. 2000;61:171-175. 11. Braddock CH III, Edwards KA, Hasenberg NM, et al. Informed decision making in outpatient practice: time to get back to basics. JAMA. 1999;282:2313-2320. 12. Leeper-Majors K, Veale JR, Westbrook TS, et al. The effect of standardized patient feedback in teaching surgical resi-dents informed consent: results of a pilot study. Curr Surg. 2003;60:615-622. 13. Courtney MJ. Information about surgery: what does the public want to know? ANZ J Surg. 2001;71:24-26. 14. Newton-Howes PA, Dobbs B, Frizelle F. Informed con-sent: what do patients want to know? N Z Med J. 1998;111: 340-342. 15. Streat S. Clinical review: moral assumptions and the pro-cess of organ donation in the intensive care unit. Crit Care. 2004;8:382-388. 16. Williams MA, Lipsett PA, Rushton CH, et al. The physician’s role in discussing organ donation with families. Crit Care Med. 2003;31:1568-1573. 17. Pearson IY, Zurynski Y. A survey of personal and professional attitudes of intensivists to organ donation and transplantation. Anaesth Intensive Care. 1995;23:68-74. 18. Sulmasy DP, Lehmann LS, Levine DM, et al. Patients’ percep-tions of the quality of informed consent for common medical procedures. J Clin Ethics. 1994;5:189-194. 19. Ubel PA, Loewenstein G, Jepson C. Whose quality of life? A commentary exploring discrepancies between health state 8899Brunicardi_Ch48_p2061-p2076.indd 207419/02/19 1:49 PM 2075ETHICS, PALLIATIVE CARE, AND CARE AT THE END OF LIFECHAPTER 48evaluations of patients and the general public. Qual Life Res. 2003;12:599-607. 20. Schneider CE. After autonomy. Wake Forest Law Review. 2006;41:411. 21. Shalowitz DI, Garrett-Mayer E, Wendler D. The accuracy of surrogate decision makers: a systematic review. Arch Intern Med. 2006;166(5): 493-497. 22. Sulmasy DP, Hughes MT, Thompson RE, et al. How would terminally ill patients have others make decisions for them in the event of decisional incapacity? A longitudinal study. J Am Geriatr Soc. 2007;55:1981-1988. 23. SUPPORT Principle Investigators. A controlled trial to improve care for seriously ill hospitalized patients. The study to under-stand prognoses and preferences for outcomes and risks of treatments (SUPPORT). The SUPPORT Principal Investigators. JAMA. 1995;274:1591-1598. 24. Pawlik TM. Withholding and withdrawing life-sustain-ing treatment: a surgeon’s perspective. J Am Coll Surg. 2006;202:990-994. 25. In re Quinlan. 355 A2d 647 (JN). Vol 429 US 9221976. 26. Cruzan vs. Director, Missouri Dept of Health, 497(1990). 27. Annas GJ. Nancy Cruzan and the right to die. N Engl J Med. 1990;323:670-673. 28. Sykes N, Thorns A. The use of opioids and sedatives at the end of life. Lancet Oncol. 2003;4:312-318. 29. Trotter JF, Adam R, Lo CM, Kenison J. Documented deaths of hepatic lobe donors for living donor liver transplantation. Liver Transpl. 2006;12(10):1485-1488. 30. Singer PA, Siegler M, Whitington PF, et al. Ethics of liver transplantation with living donors. N Engl J Med. 1989;321(9):620-622. 31. Fournier V, Foureur N, Rari E. The ethics of living donation for liver transplant: beyond donor autonomy. Med Healthcare Philos. 2013;16(1):45-54. 32. Shapiro RS, Adams M. Ethical issues surrounding adult-to-adult living donor liver transplantation. Liver Transpl. 2000; 6(6 suppl 2):S77-S80. 33. Kleinman A. The Illness Narratives. Suffering, Healing & the Human Condition. New York: Basic Books; 1988. 34. Nelson KA, Walsh D, Behrens C, et al. The dying cancer patient. Semin Oncol. 2000;27:84. 35. WHO. Definition of palliative care, 2008. World Health Orga-nization. Available at: http://www.who.int/cancer/palliative/definition/en/. Accessed August 29, 2018. 36. Dunn G. Surgical palliative care. In: Mosby, ed. Current Surgical Therapy, 9th ed. Philadelphia: Elsevier; 2008. 37. Saunders C. The challenge of terminal care. In: Symington T, Carter R, eds. Scientific Foundations of Oncology. London: Heineman; 1976:673. 38. International Association for the Study of Pain, Subcommittee on Taxonomy. Part II. Pain Terms: a current list with definitions and notes on usage. Pain. 1979;6:249. 39. Byock IR, Merriman MP. Measuring quality of life for patients with terminal illness: the Missoula-VITAS quality of life index. Palliat Med. 1998;12:231-244. 40. Christakis NA, Lamont EB. Extent and determinants of error in doctors’ prognoses in terminally ill patients: prospective cohort study. BMJ. 2000;320:469-472. 41. Anderson F, Downing GM, Hill J, et al. Palliative performance scale (PPS): a new tool. J Palliat Care. 1996;12:5-11. 42. Morita T, Tsunoda J, Inoue S, et al. Validity of the palliative performance scale from a survival perspective. J Pain Symptom Manage. 1999;18:2-3. 43. Buckman R. How to Break Bad News. A Guide for Healthcare Professionals. Baltimore: Johns Hopkins University Press; 1992. 44. Kubler-Ross E. On Death and Dying. London: Routledge; 1973. 45. Twycross R, Lichter I. The terminal phase. In: Doyle D, Hanks G, MacDonald N, eds. Oxford Textbook of Palliative Medicine. New York: Oxford University Press; 1998:977. 46. Hinshaw DB. Spiritual issues in surgical palliative care. Surg Clin North Am. 2005;85:257-272. 47. Jacox A, Carr D, Payne R, et al. Management of cancer pain. AHCPR Publication No. 94-052: Clinical Practice Guideline No. 9. Rockville: US Department of Health and Human Services, Public Health Service; 1994. 48. Storey P, Knight C. UNIPAC Three: Assessment and Treat-ment of Pain in the Terminally Ill. 2nd ed. New York: Mary Ann Liebert Inc; 2003. 49. Rubenfeld GD, Crawford SW. Principles and practice of with-drawing life-sustaining treatment in the ICU. In: Curtis JR, Rubenfeld GD, eds. Managing Death in the Intensive Care Unit. New York: Oxford University Press; 2001. 50. Rousseau P. Existential distress and palliative sedation. Anesth Analg. 2005;101:611-612, 51. The EPEC-O Project, Educating Physicians in End-of-Life Care-Oncology: Module 6: Last Hours of Living. Bethesda: National Cancer Institute; 2007. 52. Worden J. Bereavement Care. Philadelphia: Lippincott Williams and Wilkins; 2002. 53. Bishop JP, Rosemann PW, Schmidt FW. Fides ancilla medici-nae: on the ersatz liturgy of death in biopsychosociospiritual medicine. Heythrop J. 2008;49:20. 54. Schroeder-Sheker T. Transitus: A Blessed Death in the Modern World. Mt. Angel: St. Dunstan’s Press; 2001. 55. Li M, Watt S, Escaf M, et al. Medical assistance in dying—implementing a hospital-based program in Canada. N Engl J Med. 2017;376(21):2082-2088. 56. Emanuel EJ, Onwuteaka-Philipsen BD, Urwin JW, Cohen J. Attitudes and practices of euthanasia and physician-assisted suicide in the United States, Canada, and Europe. JAMA. 2016;316:79-90. 57. Trice Loggers E, Starks H, Shannon-Dudley M, Back AL, Appelbaum FR, Stewart FM. Implementing a Death with Dignity program at a comprehensive cancer center. N Engl J Med. 2013;368:1417-1424. 58. Rhee JY, Callaghan KA, Stahl A, et al. Physician-assisted sui-cide and euthanasia is incompatible with medicine: a response from medical students. Crit Care Med. 2017;45(6):e626-e627. doi: 10.1097/CCM.0000000000002354. 59. Vogelstein E. Evaluating the American Nurses Associa-tion’s arguments against nurse participation in assisted suicide. Nurs Ethics. 2017;969733017694619. doi: 10.1177/0969733017694619. 60. Sharpe JT. Is there a significant moral distinction between active and passive euthanasia? Critique. 2011;5:11-16. 61. Buchbinder M. Aid-in-dying laws and the physician’s duty to inform. J Med Ethics. 2017;43(10):666-669. doi: 10.1136/medethics-2016-103936. 62. Goligher EC, Ely EW, Sulmasy DP, et al. Physician-assisted suicide and euthanasia in the ICU: a dialogue on core ethi-cal issues. Crit Care Med. 2017;45(2):149-155. doi: 10.1097/CCM.0000000000001818. 63. Emmanuel EJ, Wendler D, Grady C. What makes clinical research ethical? JAMA. 2000;283:2701-2711. 64. Freedman B. Equipoise and the ethics of clinical research. N Engl J Med. 1987;317:141-145. 65. Meakins J. Innovation in surgery. The rules of evidence. Am J Surg. 2002;183:399-405. 66. Lefering R, Neugebauer E. Problems of randomized controlled trials in surgery. Paper presented at: Nonrandomized Compara-tive Clinical Studies. Heidelberg, 1997. 67. Flum DR. Interpreting surgical trials with subjective out-comes: avoiding UnSPORTsmanlike conduct. JAMA. 2006;296:2483-2485.Brunicardi_Ch48_p2061-p2076.indd 207519/02/19 1:49 PM 2076SPECIFIC CONSIDERATIONSPART II 68. Moseley JB, O’Malley K, Petersen NJ, et al. A controlled trial of arthroscopic surgery for osteoarthritis of the knee. N Engl J Med. 2002;347:81. Summary for patients in: J Fam Pract. 2002;51:813. 69. Angelos PA. Sham surgery in research: a surgeon’s view. Am J Bioeth. 2003;3:65-66. 70. Miller FG. Sham surgery: an ethical analysis. Sci Eng Ethics. 2004;10:157-166. 71. Angelos P. Sham surgery in clinical trials. JAMA. 2007;297:1545-1546, author reply 1546. 72. Riskin DJ, Longaker MT, Gertner M, et al. Innovation in sur-gery: a historical perspective. Ann Surg. 2006;244:686-693. 73. Biffl WL, Spain DA, Reitsma AM, et al. Responsible develop-ment and application of surgical innovations: a position state-ment of the Society of University Surgeons. J Am Coll Surg. 2008;206(6):1204-1209. 74. McKneally MF, Daar AS. Introducing new technologies: pro-tecting subjects of surgical innovation and research. World J Surg. 2003;27:930-934. 75. International Committee of Medical Journal Editors. Defin-ing the role of authors and contributors. Available at: http://www.icmje.org/recommendations/browse/roles-and-respon-sibilities/defining-the-role-of-authors-and-contributors.html> Accessed August 29, 2018. 76. Eggert LD. Best practices for allocating appropriate credit and responsibility to authors of multi-authored articles. Front Psychol. 2011;2:196. 77. Rennie D, Yank V, Emanuel L. When authorship fails. A proposal to make contributors accountable. JAMA. 1997;278(7):579-585. 78. Yank V, Rennie D. Disclosure of researcher contributions: a study of original research articles in The Lancet. Ann Intern Med. 1999;130(8):661-670. 79. Kohn LT, Corrigan JM, Donaldson MS. To Err Is Human: Building a Safer Health System. Washington: National Academy Press; 2000. 80. Brennan TA, Leape LL, Laird NM, et al. Incidence of adverse events and negligence in hospitalized patients. Results of the Harvard Medical Practice Study I. N Engl J Med. 1991;324:370-376. 81. Hebert PC, Levin AV, Robertson G. Bioethics for clinicians: 23. Disclosure of medical error. CMAJ. 2001;164:509-513.Brunicardi_Ch48_p2061-p2076.indd 207619/02/19 1:49 PM
Global SurgeryKatherine E. Smiley, Haile T. Debas, Catherine R. deVries, and Raymond R. Price 49chapterINTRODUCTIONModern surgery can save lives, help expand economies, and offer hope to individuals and communities. Prior to the accep-tance and availability of aseptic technique to prevent or decrease infections, and improved anesthesia for controlling pain, sur-gery as a specialty was held in very low esteem by medical doc-tors and the general public. Over the last 100 years, surgery has developed into a highly regarded discipline that not only pro-vides opportunities for curing certain diseases but also fulfills a special role in preventing and mitigating disability.Yet, surgery is currently unavailable to most people world-wide. The vast majority—90%—of the world’s population receives only 10% of the surgical care delivered. Said another way, 90% of surgical resources are consumed by the most privi-leged 10% of the world’s population. More than 5 billion people lack access to safe, timely, and affordable surgical care.1 Very few surgical procedures occur in countries spending less than U.S. $100 per person on health care per year compared to coun-tries spending greater than U.S. $1000 per person (Fig. 49-1).2Examples of disparities abound. In many countries, including the wealthiest, islands of poverty coexist within cities replete with material resources. Tertiary level hospitals operate within eyesight of slums whose inhabitants have no access to even basic care. Most of the people without access—people in rural areas and in countries with poor infrastructure—are the very people most at risk for death or disability due to lack of surgical care. Often the poor accept and endure many painful and potentially correctable fatal conditions as a fact of life.3-6 Care for trauma and obstetrical emergencies is considered a basic surgical need but is absent in many rural regions. Other chronic conditions—often equally debilitating—progress to death or serious disability due to lack of available, safe surgery and anesthesia.Many factors contribute to the disparity in access to surgi-cal care. Poverty, a primary risk factor for all types of diseases, is a major obstacle hindering access to surgery. Healthcare pro-fessionals, including surgeons, migrate from areas of need due to a lack of infrastructure (hospitals, roadways, and stable elec-trical sources), limited supplies and equipment, lack of human resources, few opportunities for professional development, and concerns for personal safety. Until recently, there has been a significant lack of information regarding the burden of surgical disease and surgery’s positive impact on communities. Current research substantiates that investment in surgical care improves economies and is an integral and necessary component of global health.7,8Disparities in care and outcomes are multidimensional, and no simple solution exists to improve access to appro-priate and affordable surgical care. Yet, five major forces are reshaping priorities and strategies leading the charge for the globalization of surgical care.1. The epidemiologic transition of diseases from primarily in-fectious to more chronic conditions2. The mobile nature of the world’s populations, allowing peo-ple to move freely between more isolated areas of the world, leading to a more integrated global community3. Ubiquitous information access exponentially enabling wide-spread participation in understanding and designing innova-tive opportunities for high-quality surgical care4. A revolution for equity and human rights where the world’s poor are demanding benefits to surgical care similar to those found in high-income countries (HICs)5. Recognition of the cost-effectiveness of surgical care and its potential to build economies, demonstrating the value of in-cluding surgery in global health strategies9-12The greatest burden of disease occurs in areas where human resources—physicians, nurses, pharmacists, and other healthcare workers—are scarce (Fig. 49-2).13 The proportion of physicians is low both in high-population areas and in areas where the population is growing most rapidly (Fig. 49-3).14,15 Fully trained surgeons and anesthesiologists comprise only a small proportion of the total number of the Human Resources in Health (HRH), and efforts to meet the 12Introduction 2077Defining Global Surgery 2079Global Surgery Ecosystem / 2079Human Resources / 2081Burden of Surgical Disease / 2081Strategies for Development 2086Essential Surgery: Current and Evolving Concepts / 2086Outreach and Engagement / 2087International Organizations / 2088Global Surgery and Public Health / 2091Cancer Initiatives / 2098Integrating Value into Global Surgery / 2102Advanced Surgical Care for Resource-Poor Areas / 2102Academic Global Surgery / 2103Ethics / 2105Innovation in Global Surgery / 2106The Future for Global Surgery 2106Brunicardi_Ch49_p2077-p2112.indd 207713/02/19 5:53 PM 2078surgical needs are now embracing a multifaceted approach, including advanced care practitioners. The Lancet Commission on Global Surgery estimates that an additional 143 million sur-gical procedures are needed each year in LMICs to prevent death and disability caused by lack of care.16The potential benefits of surgical care for economic pro-ductivity are astounding. Considering that the annual eco-nomic loss from road traffic injuries alone exceeds U.S. $500 billion globally, a panel of expert economists at the Copenhagen Consensus of 2012, including four Nobel prize lau-reates, prioritized strengthening surgical capacity as the eighth most cost-effective investment for addressing the world’s most pressing problems. The Consensus reconvened in 2015, syn-chronizing their recommendations to the United Nations’ Sus-tainable Development Goals, and reaffirmed that surgery-related initiatives (i.e., circumcision and skilled obstetrical support), offer the best “value-for-money” in terms of alleviating world poverty.17-19 The Lancet Commission on Global Surgery, a research and advisory working group with contributors from 110 nations, echoed these sentiments. Surgery should be viewed as an investment rather than a cost.16,20Much of the economic modeling and strengthening of political will related to surgical and anesthesia care has been carried out by collaborative groups and consortia including aca-demic, nongovernmental, and other organizations. The efforts of these groups truly coalesced in 2015, when several major consensus statements from governmental organizations, such as the World Bank and the World Health Assembly, recognized the importance of surgery in public health for the first time. 3$100$101-400$401-1000> $100012,00010,00080006000400020000Number of procedures/100,000 populationUS dollars/person healthcare/yearFigure 49-1. Worldwide distribution of surgical procedures. (Data from Weiser TG, Regenbogen SE, Thompson KD, et al. An estima-tion of the global volume of surgery: a modelling strategy based on available data, Lancet. 2008 Jul 12;372(9633):139-144.)Key Points1 There are five major forces reshaping priorities and strate-gies for the globalization of surgical care:a. The epidemiologic transition of diseasesb. The mobile nature of the world’s populationsc. Ubiquitous information accessd. A revolution for equity and human rightse. Recognition of the cost-effectiveness of surgical care for treatment and prevention of disease2 The burden of disease is greatest in areas where human resources—physicians, nurses, pharmacists, and other healthcare workers—are the least.3 Surgery should be viewed as an investment rather than a cost.4 The key components of the global surgery ecosystem include technology, education, community, healthcare, business, and multidisciplinary engagement between a variety of disciplines.5 Understanding and addressing the necessary communica-tion, energy, and transportation technologies along with the underlying cultural context represent the foundation critical to implementing sustainable infrastructure for appropriate surgical care.6 There has been a significant shift from communicable, maternal, neonatal, and nutritional causes of disease to noncommunicable causes, many of which require surgi-cal care.7 Patients and their communities in lowand middle-income countries (LMICs) bear a much greater share of the burden of cancer than high-income countries (HICs).8 Globally, trauma has become a leading cause of death and disability; 90% of trauma deaths occur in LMICs.9 Essential surgical services should be integrated into com-prehensive health care delivery, with the potential to avert 1.5 million deaths per year in LMICs.10 Surgery is gaining an increasingly recognized role for improving public health, having a role in prevention as well as treatment.11 The cost-effectiveness of surgical care has been demon-strated, and its value as a public health investment is increasingly understood by policymakers.12 Developing capabilities for surgical care has the ability to promote system-strengthening in resource-poor countries and to mitigate migration of health professionals at all levels.13 Academic global surgery provides a unique environment to study health systems, identify solutions and implement them collaboratively, fulfilling many institutions’ mis-sions to strengthen multidisciplinary training, advocacy, and research.14 Surgical innovations that bring value by balancing cost with quality designed for challenging energy environ-ments will foster equity in surgical care for LMICs.Brunicardi_Ch49_p2077-p2112.indd 207813/02/19 5:53 PM 2079GLOBAL SURGERYCHAPTER 49The third edition of World Bank’s Disease Control Priorities (DCP3) and the World Health Assembly’s Resolution 68.15 both specifically discuss the vital nature of surgical care as part of any health system.7,21 Such resolutions represent a sea change in terms of how the global policy community views surgical care for LMICs and, indeed, the entire world.This chapter examines the ongoing need to expand and strengthen surgical care globally, explores some of the signifi-cant challenges of global surgery, and presents potential guid-ing concepts along with examples of successful strategies for sustainable surgical development.DEFINING GLOBAL SURGERYGlobal Surgery EcosystemTo understand how surgery fits into healthcare systems and to understand its unique needs, it is helpful to consider global surgery as an ecosystem. The emerging field of global surgery considers surgical care to be a fundamental component of global health. As a system with both local and international scope, global surgery encompasses not just the medical and technical aspects of surgical care, but also the societal and environmental context in which surgery is per-formed. Global surgery also refers to a worldwide lens through which we view challenges collaboratively; thus, global sur-geons may focus on resource-limited areas where needs are profound, but the ultimate goal should be to make surgical care equitable, accessible, and affordable for every human being.22 Surgery as an ecosystem considers the diverse but interrelated systems that must be functional for quality surgical care to be delivered. Only part of these systems falls within the tradi-tional training of surgeons. Yet, modern surgical care requires these systems to work in a coordinated fashion to support three priorities critical for expanding surgery globally—accessibility, affordability, and innovation (Fig. 49-4). Global surgery is a way to consider a “systems-based practice” beyond a single hospital or community, for the benefit of people worldwide. Many interrelated components of this surgical ecosystem orig-inate outside the hospital.Disparities in surgical care have geographical, socioeco-nomic, and cultural components. Most people who live in major cities in the northern and western hemispheres take for granted a functioning energy grid. The development of energy beyond major cities has enabled wealthier communities to imagine, and indeed, to expect healthcare to be available at all times and affordable. Yet, a lack of reliable energy sources is a major limiting factor. Communication and transportation technologies, for example, the mobile phone and air and ground travel, have dramatically progressed in highand middle-income countries but are still rudimentary in poor countries. Many of the current disparities in health care, particularly surgical care, are due to the lack of penetration of these technologies. Under-standing and addressing the necessary communication, energy, and transportation deficits as well as the underlying cultural nuances are necessary to support the sustainable development of surgical care.Electricity is necessary for all modern surgery. Anesthe-sia monitoring, operating room lighting, cautery, suction, and patient warming devices all require sources of electricity that are stable, without huge electrical surges. Only in the last 50 years or so could stable electricity be expected in most wealthy cities. However, in rural areas of even wealthy countries, electricity remains unpredictable (Fig. 49-5).23In poorer countries, the cost and availability of electric-ity is frequently the limiting factor for more advanced diagnos-tic and therapeutic technology—from laboratories that require refrigeration to radiology in all of its various branches. Modern design for surgical devices has, for the most part, not taken into account the wide range of energy environments where surgery is practiced. Fragile instruments and monitors that cannot survive the rigors of the real working environment limit the types of surgery that can be provided.4535302520151050Percent of global disease burdenPercent of global workforceAmericasEuropeWesternPacificSouth-EastAsiaAfricaEasternMediterranean* Even with grants and loans from abroad.054045303520251015Africa suffers from 24% of the global burden of disease but has access to only 3% of health workers and less than 1% of the world's financial resources.*Figure 49-2. Distribution of healthcare workers by burden of disease in WHO regions. (Reproduced with permission from Intermountain Healthcare.)Brunicardi_Ch49_p2077-p2112.indd 207913/02/19 5:53 PM 2080SPECIFIC CONSIDERATIONSPART IIComponents of the Global Surgery Ecosystem. Improve-ments in energy, transportation, and communication are criti-cal to support the growth of surgical care.9 Building capacity for surgical care requires interaction between the various com-ponents that create a functioning, sustainable system. When surgeons think of surgery, they usually think in terms of science and hands-on technical expertise. However, global surgery requires a broader understanding of systems in other disciplines. Surgeons must work collaboratively with engineers and busi-ness leaders to develop technology that can function in lower 0–1717–3434–50Physicians (per 10,000 population)2005–201050–67200,000,000–600,000,0000–200,000,000600,000,000–1,400,000,000Population20120.48%–1.96%1.96%–3.45%3.45%–4.93%Population growth rate2012–1.01%– –0.48%Figure 49-3. Number of physicians, world populations, and world population growth rates. (Reproduced with permission from World Health Organization, 2018 (Density of Physicians [total number per 1000 population]); 2013 World Population Data Sheet Interactive Map; World Bank, population growth (annual %) map.)Brunicardi_Ch49_p2077-p2112.indd 208013/02/19 5:53 PM 2081GLOBAL SURGERYCHAPTER 49resource environments. These innovations can provide a source of economic growth for the community, which in turn supports better health care (Fig. 49-6).No sustainable surgical system in the modern age can function without specialists in bioengineering, sterile process, supply chain, hospital safety, and waste management. These often unappreciated colleagues make possible the daily practice of surgery. Similarly, specialists in anesthesia, nursing, and the diagnostic specialties of radiology, pathology, and laboratory services are fundamental to a fully functional surgical service.Human ResourcesPrimary care physicians, nurses, midwives, or advanced care practitioners (ACPs) provide much of the basic surgical and anesthetic care in LMICs. Where regulations allow, “task sharing,” or training ACPs to deliver surgery and anesthesia services previously allowed only under the purview of fully trained specialists, can provide expanded access to care.24-26 Non-MD practitioners, known as assistant medical officers (AMOs) or “tecnicos de cirurgia” in Mozambique, often have extensive operative experience, including obstetrical care, and are the pri-mary surgical providers in some regions.27-29 Task sharing with ACPs also occurs in the United States and other countries where they fill a need otherwise unmet by specialists even in major tertiary care centers.30 However, concerns about the quality of care, lack of adequate supervision, and the effect on prestige and professional development for specialists and ACPs, continue to be topics for debate.31,32Migration of practitioners to economically and culturally favorable locales is universal and not restricted to low-resource countries.33,34 However, the net impact on poor countries is greater. In a 2004 study, more than 23% of U.S. physicians received their medical training from other countries; of these 64% were from low-income countries.35 Using 2013 data, another study showed annual emigration rates of sub-Saharan physicians to the United States are increasing, despite a World Health Organization Global Code of Practice in 2010 aimed at LMIC workforce retention.36 Investments in training greater numbers of doctors in these countries, including surgical spe-cialists, have been only partially successful in meeting demand in poor countries. Until economic conditions improve or oppor-tunities for professional development increase, and incentives enticing migration of health care workers to high-income countries abate, it is unlikely that the most skilled practitio-ners will remain in resource-poor areas beyond their immediate obligations.37-41Burden of Surgical DiseaseEpidemiologic Transition of Disease. The population on Earth currently stands at more than 7 billion. While the rate of growth has slowed in recent years, projections estimate that AccessibilityAffordabilityInnovationGLOBALSURGERYFigure 49-4. Global surgery priorities. (Reproduced with permission from University of Utah Center for Global Surgery and Intermountain Healthcare.)Figure 49-5. Map of world electrification. (Reproduced with permission from NASA, Visible Earth, Available at: http://visibleearth.nasa.gov/view.php?id=79765.)Brunicardi_Ch49_p2077-p2112.indd 208113/02/19 5:53 PM 2082SPECIFIC CONSIDERATIONSPART IIthe population will continue to grow to 9 billion by 2050.42 Population characteristics are changing rapidly. According to United Nations’ estimates, the entire world is aging even in low-income countries, and by 2050, 2 billion people will be over the age of 60. Currently, Asia is home to 55% of the world’s population over the age of 60.43 Just before the year 2020, the percentage of the world’s population over age 65 years is predicted to surpass the percentage of children under age 5 years, on an unprecedented reversal of trajectories for both age demographics. While this represents a victory for infectious disease control, the dramatic increase in longevity will present new challenges in terms of treating noncommu-nicable disease in the older adult population.44 At the same time, Sub-Saharan Africa’s population is experiencing a much different trend: a current “baby boom” will lead the region to quadruple its population, from 960 million to 4 billion, by the year 2100.45Until recently, infectious diseases dominated public health strategy. Now with major scourges like polio isolated to rela-tively small regions of the world, and HIV and malaria decreas-ing in their relative impact worldwide, chronic diseases and their complications, as well as the effects of aging, are gaining dominance in health care needs. Many of these chronic diseases are best approached by surgery.The lack of metrics and paucity of data identifying the unmet burden of surgical need in many countries have been obstacles facing global surgery initiatives. The 2010 Global Burden of Disease Study was the first worldwide comprehensive burden of disease evaluation since the initial 1990 epidemiologic study. Using the disability-adjusted life year (DALY), a metric that captures both premature mortality and the prevalence and severity of illnesses, disease burdens were calculated for 291 causes in 21 regions of the world (including 187 countries) for 1990, 2005, and 2010 to enable identification of significant trends over time.46 While the global DALYs remained stable from 1990 to 2010, the study identified a significant shift from communicable, maternal, neonatal, and nutritional causes of disease to noncommuni-cable causes (Fig. 49-7).47In 2015, the previous estimate by the second edition of Disease Control Priorities in 2006 of an 11% global surgical dis-ease burden was updated to 30%, obtained from provider-based survey data from the Lancet Commission.1,10 Using country-wide population surveys (the Surgeons OverSeas Assessment of Surgical Need Survey [SOSAS]) in Sierra Leone, Rwanda, and Nepal, the overall presence of surgically treatable condi-tions was 11.2%, with 25.6% of deaths potentially avoidable had surgical care been available. Applying these percentages to the 48 low-income countries, as defined by the World Bank, suggests that there are 288.2 million people currently living with surgically treatable conditions; providing improved access to surgical care could prevent 5.6 million deaths per year.48-50 Untreated acute and chronic surgical conditions represent a sig-nificant unmet burden of disease that has major impact on the economies of these nations.7,16,51Cancer. Patients and their communities in LMICs bear a much greater share of the burden of cancer than HICs. The dramatic increase in the proportion of reported cancer cases in LMICs is a result of population growth, aging populations, and decreased mortality from infectious diseases. In 1970, only 15% of newly reported cancer cases worldwide were from the developing world; by 2008, this proportion rose dramatically to 58% and is expected to grow to 70% by 2030.52 Since 2013, the second leading cause of death world-wide has been cancer, and an estimated 20% of all global surgery is now cancer-related.53 Previously thought to be a 67ElectricityLaundrySupply chainKnowledgeCultureHealthcareFamily supportGeographyPatientRoad/travel infrastructurePre-hospital careSpiritualityExpectationsLaboratory servicesHospital safetyAdministrationBusinessHealthcarePublic healthInsurersRegulatory agenciesTechnologyPublic policyEducationSURGICALECOSYSTEMBioengineeringWaste managementSterile processingAnesthesiologyRadiologyNursingPharmacyPathologyRESOURCESCOMMUNITYMULTIDISCIPLINARY ENGAGEMENTSURGICAL CARE INFRASTRUCTUREValue-driven outcomesPatient-centered careFigure 49-6. The global surgery ecosystem requires broad integration of many fields in a multidisciplinary context. (Reproduced with permission from Intermountain Healthcare.)Brunicardi_Ch49_p2077-p2112.indd 208213/02/19 5:53 PM 2083GLOBAL SURGERYCHAPTER 49disease almost exclusive to high-income countries, nearly two-thirds of the 7.6 million cancer deaths worldwide occur in LMICs. Mortality from cancer correlates inversely with a country’s economy for certain treatable cancers, including breast, testicular, and cervical cancer—LMICs have higher case fatality rates than HICs (Fig. 49-8).52,54For example, breast cancer case fatality rates illustrate the great disparity in outcomes between regions. Case fatality rates in East Africa reach an unacceptable 59% compared to 19% in the United States.54 In LMICs, patients have very lim-ited access to screening. They present for care with much later stages of cancer. In Haiti, after the great earthquake in 2010, with its initial onslaught of orthopedic injuries, many aid orga-nizations found themselves faced with the unmet underlying burden of disease, including late-stage breast cancer and other tumors (Fig. 49-9). The DCP3 has devoted an entire chapter to cancer screening in LMICs, emphasizing the importance of proper infrastructure for screening and treatment, as well as considering cost-effectiveness and ethical concerns related to screening and subsequent treatment of detected cancers.55 The number and quality of training programs in surgical oncology is also inversely related to a country’s income, leaving LMICs with few adequately trained providers. Collaborative training programs between HIC and LMIC centers, as well as tele-teaching and mobile consultation, may address this shortage in a relatively low-cost, high-impact way.56Trauma. Trauma has become a leading cause of death (5.8 million people per year) and disability around the world; 90% of trauma deaths occur in LMICs.57 Approximately 32% more people die as a result of injuries than from malaria, tuberculosis, and HIV/AIDS combined, representing 10% of the world’s deaths (Fig. 49-10).58,59 The major causes of death from injuries are road traffic accidents (RTAs), suicides, homicides, falls, drownings, and burns; in every category except burns, almost twice as many men die compared to women.60847354354101119902010% Worldwide DALYsCommunicable, maternal, neonatal, nutritionalNoncommunicableInjuriesFigure 49-7. Shift in disease burden 1990–2010. (Reproduced with permission from Intermountain Healthcare.)ThyroidHighHigh-middleLow-middleLow0.80.60.40.20.0Ratio of mortality to incidenceIncome classBreastCervicalTesticularProstateColorectalFigure 49-8. Ratio of mortality to incidence by solid tumor type and country income (2008). (Reproduced with permission from Intermountain Healthcare.)Brunicardi_Ch49_p2077-p2112.indd 208313/02/19 5:53 PM 2084SPECIFIC CONSIDERATIONSPART IIOver 1.25 million people die from RTAs, causing LMICs to lose 3% of their GDP; 50 million more people incur nonfatal injuries, many with resulting lifelong disabilities.61 Globally, RTAs are the main cause of death for young people between the ages of 15 and 29. Forty-nine percent of all traffic deaths are among pedestrians, cyclists, and motorcycles.62 In the United States, a patient presenting with an injury in a rural community has a higher mortality than those from an urban setting.63 This disparity is much more pronounced in eco-nomically disadvantaged societies, where seriously injured patients from road traffic accidents are twice as likely to die compared to similarly injured patients in a high-income set-ting (Fig. 49-11).58,64 Additionally, death is much more likely to occur in the prehospital settings for injured patients from low-income countries. The lack of integrated communication and emergency transportation systems contribute to prehospital risk, while the lack of infrastructure, supplies, and personnel contribute to inhospital mortality.The number of deaths from RTAs has remained the same between 2007 and 2013. The predicted increase in mortality from RTAs, expected from the increase in population and global motorization, did not materialize, suggesting that interventions to improve global road safety (i.e., The Decade of Action for Road Safety 2011–2020) may be having some success in pre-venting deaths from RTAs.62Burns. The World Health Organization estimates that 265,000 people die of burn injuries each year, mostly (95%) from LMICs; the vast majority never present for medical care.65 Scalds and electrical burns represent another significant source of death and disability. Women and children in LMICs are most likely to be burned in domestic kitchens; men are more likely to be burned in the workplace. The economic and social impact from long hospitalizations and from the resulting disfigurement provides a significant negative stigma causing ostracism and rejection.Of all the forms of trauma worldwide, burns are the only type that predominantly afflict women and children. Southeast Asia accounts for 27% of burn-related deaths worldwide; 70% of people dying from burns in this region are women.66 Cooking on wood, charcoal, or low kerosene stoves also puts children at risk, particularly from scalding (Fig. 49-12). Small children in the WHO African region have triple the number of burn deaths as children worldwide. Con-trast this with the United States, where more burns and burn deaths affect men.People living in rural areas suffer disproportionately because there are fewer facilities capable of managing the acute and chronic aspects of burns and because the population is gen-erally poorer. Surgical grafting and management of contractures is often best done in specialized burn centers, but these are rare in LMICs. Telemedicine has been shown to be effective in man-aging burns and preventing complications, and now, in the era of high resolution mobile phones, it can effectively diagnose and triage many burn patients appropriately.67 Telemedicine can also be useful in providing much-needed education of rural providers in basic burn care (Box: Telemedicine and Tele-education at the University of Utah).6801234567Deaths per year (millions)InjuryHIV/AIDS, TB, and malariaInjuries and violence:the scale of the problemFigure 49-10. Injuries and violence: the scale of the problem. (Reproduced with permission from World Health Organization, Geneva. Injuries and violence: the facts. http://www.who.int/ violence_injury_prevention/key_facts/VIP_key_fact_1.pdf.)Figure 49-9. Underlying unmet cancer burden in Haiti (2010). (Reproduced with permission from Intermountain Healthcare. Photo contributor: R. Dirk Noyes, MD.)Brunicardi_Ch49_p2077-p2112.indd 208413/02/19 5:54 PM 2085GLOBAL SURGERYCHAPTER 49Figure 49-11. Change in traffic fatality risk (deaths per 10,000 persons, 1975–1998). (Reproduced with permission from Intermountain Healthcare.)Telemedicine and Tele-education at the University of UtahThe University of Utah’s Burn Center has utilized Project ECHO (Extension for Community Healthcare Outcomes), an HIPAA-compliant tele-education platform developed at the University of New Mexico. Project ECHO provides live, free, interactive educational materials to rural physicians, nurses, and EMTs in eight surrounding states.69 This model has been expanded internationally through the University of New Mexico to 21 countries, with the potential to drastically improve the knowledge base of providers in many resource-limited settings.70Direct patient care has also been achieved at the University of Utah’s Burn Center, through their Telemedicine outreach program. “TeleBurn” currently provides approximately 400 video consultations per year, serving 80 sites in five surrounding states that lack specialized burn care. For a region like the Intermountain West, where travel can be limited by inclement weather and long distances, the TeleBurn program provides better access to specialty care, at lower costs to patients.71Figure 49-12. Domestic kitchen: risk factor for burns in women and children in LMICs. (Used with permission from James H. Kenney, Jr.)CanadaAustriaFranceIndiaChinaUnited StatesColumbiaBotswana400350250200150100500–50–100High income countriesLow income countriesHigh income countriesLow income countriesPercentage changeBrunicardi_Ch49_p2077-p2112.indd 208513/02/19 5:54 PM 2086SPECIFIC CONSIDERATIONSPART IISTRATEGIES FOR DEVELOPMENTEssential Surgery: Current and Evolving ConceptsDr. Jim Yong Kim, President of the World Bank, aptly stated that surgery is an “indivisible, indispensable part of health care.”72 The wisdom of this statement has been supported by the findings of two landmark publications in 2015: Disease Control Priorities, third edition (DCP3), and the Lancet Com-mission on Global Surgery 2030 (LCGS).7,16 According to the DCP3, “the provision of essential surgical procedures would avert 1.5 million deaths a year or 6.7% of all avertable deaths in LMICs,” and according to the Lancet Commission, 5 billion people do not have access to safe, affordable surgical and anes-thesia care when needed. Taken together, these and other find-ings suggest that without the provision of accessible, affordable essential surgical care in all LMICs, the lofty goal of another Lancet Commission report, Global Health 2035: A World Con-verging Within a Generation, would be unachievable.73 This earlier Lancet Commission believes that, with adequate invest-ment in global health, all countries could reduce their infectious, maternal, and childhood mortality rates down to those currently seen in the best-performing middle-income countries (e.g., the 4C countries: Chile, China, Costa Rica, and Cuba) within a gen-eration by 2035. They also make the interesting observation that the LMICs can use their own resources for much of the funding needed.The critical role of essential surgical and anesthesia ser-vices in global health, in general, and in saving lives and disabil-ities in LMICs, in particular, has been established by fact-based evidence and analysis provided by the two landmark publica-tions of 2015, DCP3 and LCGS. Table 49-1 summarizes the key findings and recommendations of the two publications.The DCP3 adopted a working definition of essential sur-gical conditions as those that (a) are primarily or extensively treated by surgery; (b) have a large health burden; and (c) can be successfully treated by a surgical procedure that is cost-effective and feasible to promote globally. Using this def-inition, the DCP3 identified 44 essential procedures, most of which can be performed in first-level hospitals (Table 49-2).74 The first-level (district) hospital is the appropriate platform to provide essential surgical service. These procedures rank among the most cost-effective of all interventions and include those that treat injuries, obstetric complications (including fistulas), abdominal emergencies, cataracts, and congenital anomalies.The LCGS Report, based on extensive research and analy-sis of factual evidence, provides recommendations to improve access to safe, affordable anesthesia and surgical care in LMICs. Essential surgical services should be integrated into a compre-hensive platform of healthcare delivery. At the core of delivery of essential surgery is the first (district) hospital, which must be capable of delivering three bellwether essential surgery pro-cedures (hysterectomy, laparotomy, and treatment of an open fracture). A hospital that can provide these three procedures safely is presumed to have the necessary expertise in general and orthopedic surgery, obstetrics, and anesthesia to perform all essential surgical procedures.The cost of untreated surgical conditions is huge and, until now, not recognized. At the present time, some 33 million individuals face catastrophic health expenditure for surgical and anesthesia care in LMICs. The LCGS estimates that it would cost U.S. $420 billion to scale up the surgical workforce 9Table 49-1Key findings and recommendations from the Disease Control Priorities (DCP3) and the Lancet Commission for Global Surgery (LCGS)DCP3LCGSProvision of essential surgery in LMICs would prevent 1.5 million deaths, or 6.7% of all avertable deaths5 billion people lack access to safe, affordable surgical and anesthesia care when neededEssential surgical procedures rank among the most cost-effective of all health interventions143 million more operations are needed in LMICs, where only 6% of all worldwide procedures are now doneEffective and affordable measures (such as task-sharing) increase access to surgical care33 million face catastrophic health expenditure from surgery and anesthesia care each yearInvestments must be made to expand capacity buildingWithout urgent investment, LMICs will lose US $12.3 trillion in economic productivity between 2015 and 2030Substantial disparities exist between countries in safety of surgical and anesthetic care. Feasible and affordable measures (e.g., surgical safety checklist) improve safety and qualitySurgery is an indivisible, indispensable part of health care. Surgical care should be part of the National Health Care System, and should be “available, accessible, safe, timely, and affordable.”Universal coverage of essential surgery should be publicly financed early on the path to universal health coverage LMIC = Low and Middle Income CountryTable 49-2Essential surgical procedures that can be performed in first level (District) hospitals (DCP3)Obstetric Complications Severe postpartum hemorrhage, obstructed labor, prolonged labor, eclampsia, prolapsed cord, fetal distress, tubal pregnancy, postabortion endometritis/myometritis, postabortion sepsis, intrauterine fetal deathTrauma and Violence Major limb fracture/injury, joint dislocation, major soft tissue injury, pneumo/hemothorax, ruptured spleenAcute Surgical Emergencies Strangulated hernia, intestinal obstruction, intestinal perforation, appendicitis, liver abscess, major wound infection, osteomyelitis/septic arthritisNonacute Surgical Conditions Congenital hernia, hernia, breast cancer, chronic osteomyelitis, hydrocele, urethral stricture, prostatic hypertrophy, cataract, eye injuryBrunicardi_Ch49_p2077-p2112.indd 208613/02/19 5:54 PM 2087GLOBAL SURGERYCHAPTER 49to have 20 surgical, anesthetic, and obstetric providers (SAOPs) per 100,000 population in LMICs by 2030. This figure must be compared to the U.S. $20.7 trillion loss in global economy that surgical conditions would be responsible for.Recent studies have shown that essential surgical condi-tions account for about 18% of the global burden of disease. Investment in essential surgical services is critical and should be done early in the path towards universal health coverage (UHC). The barriers to essential surgical services in LMICs are formi-dable. The shortage in surgical workforce is huge, and it is clear that the deficit cannot be satisfactorily addressed without task sharing. Infrastructure deficits (clinics, hospitals, equipment, drugs, blood banks, etc) are equally enormous. The first (district) hospital is the important platform for delivery of essential surgical services. The DCP3 estimates that it would cost U.S. $43 million annually of additional spending to provide universal coverage of essential surgery applicable to first-level hospitals worldwide.Outreach and EngagementMany models for outreach and engagement have had a positive impact on the accessibility of surgery. Organizations participat-ing in outreach are guided by a wide range of motivations and resources (Fig. 49-13). Some organizations are purely humani-tarian and service oriented; others are primarily educational. Some even use the promise of healthcare to advance political, religious, or personal agendas.Many patients have benefited from the multitude of service-oriented volunteer “missions” providing much needed surgical care that would otherwise have been unavailable. While volun-teerism and medical missions provide needed clinical surgical care for underserved populations, they may not be a sustainable solution to long-term manpower shortages for health.75 Com-prehensive initiatives are necessary to engage local healthcare professionals and organizations, governments, and academic institutions to build sustainable capacity.76Charitable Surgical Delivery Platforms. A significant bur-den of surgical disease is addressed through charitable organi-zations. The DCP3 divides these charitable surgical delivery platforms into two types: temporary delivery platforms and spe-cialty surgical hospitals (Table 49-3).77Short-term charitable surgical platforms bring entire surgi-cal teams along with equipment and supplies needed to operate in local facilities for a short period of time. Local physicians provide the majority of follow-up care.78-80 Self-contained plat-forms bring the entire surgical infrastructure (fully functional operating rooms, postoperative recovery capability) through various modes of transportation: airplanes, ships, trucks, and buses. These self-contained platforms tend to stay in-country longer, may still provide short-term care, and tend not to leave behind any physical structure.78,80,81Little information exists on outcomes and cost-effectiveness of these temporary surgical platforms. Where no other services Politicians/AdministratorsResourcesFinancialHumanPoliticalMotivationsHumanitarianEducationalAcademicPoliticalOtherCataractHerniaVesico-vaginalfistulaLaparoscopicsurgeryEducatorsIndividualpeopleHealthcareprovidersCountryProvinceUrban vs.RuralDisease(technique specific)GeographicTargeted audienceGlobalsurgery initiativesPoliticians/administratorsFigure 49-13. Global surgery initiatives. (Reproduced with permission from Intermountain Healthcare.)Brunicardi_Ch49_p2077-p2112.indd 208713/02/19 5:54 PM 2088SPECIFIC CONSIDERATIONSPART IIexist, they may provide needed services. However, some of these charitable organizations report higher complications rates in lower-resource settings, which seem to increase even more with complex procedures. Some of these platforms include edu-cation for local care providers along with clinical care. While some question their ability to sustainably train local surgical teams, one charitable partnership with short-term, concentrated surgical training trips over 9 years documented a countrywide transition from open cholecystectomy to laparoscopic cholecys-tectomy in Mongolia.82Specialty surgical hospitals establish entire hospitals or facilities within existing hospitals. Some target specific diseases (Addis Ababa Fistula Hospital) while others provide a wide range of surgical and medical services (Pan-African Academy of Christian Surgeons [PAACS] mission hospitals); many are supported through partnerships with various charitable and gov-ernmental organizations.77International OrganizationsUnited Nations. Committed to maintaining international peace, developing friendly relations between nations, and promoting better standards of living (conquering hunger, dis-ease, and illiteracy) and human rights, representatives from 51 nations in 1945 signed the United Nations (UN) Charter at the United Nations Conference on International Organization in San Francisco, California.83 There are now 193 member states.84 The UN promotes a social justice agenda advocating for world-wide health, engagement of philanthropies, and civil society in global health initiatives, and it supports the sustainable develop-ment goals (SDGs).85Sustainable Development Goals. In September 2000, the UN led a worldwide, organized effort to set benchmarks for social, economic, and environmental development. Leaders from 189 countries agreed on eight specific “millennium devel-opment goals” (MDGs), spanning poverty, mortality, education, sustainability, and development.86The MDGs created a framework for improvement that some criticized as unattainable; nevertheless nearly 1 billion people were lifted out of extreme poverty, and primary education for girls made measurable improvements.87 Still, many challenges, including some related to lack of surgical care, remained. In 2015, the UN General Assembly reconvened to raise the bar yet again, in what was declared a “supremely ambitious and transforma-tive vision.”88 Eight MDGs became 17 SDGs with 169 specific targets, to be achieved by 2030 (Table 49-4).85 Most relevant to the global surgeon is SDG #3, “good health and well-being,” which builds upon the MDGs’ primarily maternaland child-mortality focus, as well as communicable disease prevention. SDG #3 broadens the focus to nine health targets, including a one-third reduction in deaths by noncommunicable diseases, as well as halving the rate of deaths and injuries from road traffic accidents by 2020. In addition, a novel push to strengthen and retain the global health workforce and systems for protection and prevention of disease also falls squarely within the realm of the surgical provider. Finally, the SDGs have garnered praise for closely involving local stakeholders, versus the expert consensus that produced the MDGs. Funding to work towards achievement of the SDGs is also divided between wealthier and poorer nations, whereas the MDGs relied primarily on funding from HICs to sup-port their mission.89World Health Organization. The initial UN Conference in 1945 voted to establish a new international health organization. The Constitution of the World Health Organization (WHO) was approved and ratified in 1948.83 The first World Assembly in 1948 established malaria, tuberculosis, venereal diseases, maternal and child health, sanitary engineering, and nutrition as WHO priorities. One of the WHO’s greatest public health sto-ries is the worldwide eradication of smallpox that began with the USSR proposal for the WHO-led program in 1958 culminating in the last identified case in Somalia in 1977.While the disease burden from communicable diseases has abated in large part from these successful international coopera-tive interventions, little has been done to address the growing global burden of surgical disease. Despite the laudable aims of the 1978 Declaration of Alma Alta, which expressed the need for urgent action for the world community to protect and pro-mote health for all people, the declaration did so by crowning primary health care as the key to achieving the goal of health for all—which was then accepted by the member countries in the World Health Organization.90 Although the Alma Ata slogan Table 49-3Examples of charitable surgical delivery platformsTemporary DeliveryShort-Term Trips World Surgical Foundation Kenya Orthopedic Program APRIDEC Medical Outreach Group Self-Contained Mobile Surgical Platforms Mercy Ships Cinterandes FoundationSpecialty Surgical Hospitals Addis Ababa Fistula Hospital Aravind Eye Hospital Mission Hospitals (PAACS*)*Pan-African Association of Christian hospitalsTable 49-4Sustainable development goals 1No poverty 2Zero hunger 3Good health and well-being 4Quality education 5Gender equality 6Clean water and sanitation 7Affordable and clean energy 8Decent work and economic growth 9Industry, innovation, and infrastructure10Reduced inequalities11Sustainable cities and communities12Responsible consumption and production13Climate action14Life below water15Life on land16Peace, justice, and strong institutions17Partnerships for the goalsBrunicardi_Ch49_p2077-p2112.indd 208813/02/19 5:54 PM 2089GLOBAL SURGERYCHAPTER 49“health for all by 2000” did not materialize, it did galvanize efforts for global partnerships for healthcare improvements and poverty reduction. In 2015, the World Health Assembly (WHA) published resolution WHA 68.15, which proclaimed surgical and anesthesia care as a crucial component of primary care worldwide—for the first time in history. The resolution urged member states to complete nine actions, including prioritizing a core set of emergency and essential surgery and anesthesia services at the primary care level, ensuring access to essential medications and infection control techniques, and developing policies for providers’ minimum skills, among others. Addition-ally, the Director-General of the WHO was asked to complete ten actions related primarily to policyand advocacy-related endeavors at the international level. The resolution was voted in unanimously by 194 member states.91The Violence and Injury Prevention Program (VIP) and the Global Initiative for Emergency and Essentials Surgical Care (GIEESC) are two programs related to surgery within the WHO that began before 2008. But as a response to a growing recognition of the significant unmet surgical need, in 2008 the WHO for the first time included basic surgery as a component for community primary health care (Fig. 49-14).92The Global Initiative for Emergency and Essential Surgical Care. The Clinical Procedures (CPR) team in the WHO Department of Essential Health Technologies (EHT) convened a multidisciplinary group of experts from various surgical disci-plines, professionals, and civic leaders from national and inter-national organizations, as well as representatives from various WHO departments, in December 2005 in Geneva, Switzerland to formally organize the Global Initiative for Emergency and Essential Surgical Care (GIEESC).93 GIEESC’s main aim was to assist member states with capacity strengthening in the safe Waste disposalinspectionMammographyAlcoholismHerniaPlacentapraeviaTrafficaccidentConsultantsupportReferral formulti-drugresistanceReferral forcomplicationsGenderviolenceSurgeryMaternityEnvironmental health labTraining centreTrainingsupportCancerscreeningcentreWomen’sshelterAlcoholicsanonymousCommunitymentalhealth unitEmergencydepartmentHospitalSpecialized careDiagnosticservicesTB controlcentreDiabetes clinicCTscanCytologylabDiagnostic supportPap smearsSelf-helpgroupLiaisoncommunityhealth workerOtherOtherSocialservicesNGOsSpecialized prevention servicesCommunityPrimary-care team:continuous,comprehensive,person-centred careFigure 49-14. Emergency and essential surgery: an integral component of primary care. (Reproduced with permission from The World Health Report 2008—primary Health Care (Now More Than Ever). http://www.who.int/whr/2008/en/.)Mongolia GIEESCThe WHO situational analysis tool, developed in 2007 to assess the availability of emergency and essential surgical care (EESC) at individual health facilities, has been utilized to document limited infrastructure, human resources, procedures, equipment, and supplies available for even basic EESC in many countries.95 For example, there were no trained surgeons or anesthetists at 44 first-referral hospitals in Mongolia.3 Only 66% of the facilities had electricity, and 45% had running water (Fig. 49-15).Most facilities lacked any policy for EESC, disaster preparedness, basic equipment to provide EESC, or any and appropriate use of emergency and essential surgical care (procedures, equipment) at resource-limited healthcare facilities through training and education programs. The training program was built around the WHO Integrated Management of Emer-gency and Essential Surgical Care (IMEESC) tool kit.94 The tool kit included best practice protocols, guidelines on policies, training curriculum, emergency equipment, teaching slides, and monitoring and evaluation instructions. Additionally, low-cost editions of the manual Surgical Care at the District Hospital have been made available in local languages. As of 2015, GIEESC had over 2100 members in 140 countries.95 A Mongolian edition facilitated early expansion of GIEESC throughout the country. Mongolia has improved basic infrastructure, human resources, and capabilities; and the use of the tool kit system has led to its incorporation into the countrywide healthcare plan96 (Box: Mongolia GIEESC).Brunicardi_Ch49_p2077-p2112.indd 208913/02/19 5:54 PM 2090SPECIFIC CONSIDERATIONSPART IIFigure 49-15. First Level (Soum) Hospital (left); Suturing of lacerated tongue by natural light (right). (Reproduced with permission from Intermountain Healthcare. Photo contributor: Raymond R. Price, MD.)BayankhongorKhentiiBayan-UlgiiBulganTuvDundgobiKhovdAltaiUvurkhangaiDornodDarkhanUulSukhbaatarOrkhonGobi-Sumber187 Soum doctors from 14 Aimags (Soum doctors = Doctor of health care centers)657 Surgeons and anesthesia doctors from aimag and city hospitals 29 Midwife and feldshers from rural provinces50 Nurses from rural provincesFigure 49-16. EESC Project: Mongolia 2004–2010. (Reproduced with permission from Henry JA, Orgoi S, Govind S, et al: Strengthening surgical services at the soum (first-referral) hospital: the WHO emergency and essential surgical care (EESC) program in Mongolia, World J Surg. 2012 Oct;36(10):2359-2370.)access to training for EESC. Adopting a health systems strengthening approach to rectify these glaring deficiencies, Mongolia implemented a nationwide EESC program involving 14 of the 21 provinces (Aimags) from 2004 to 2010 (Fig. 49-16).96 In 6 years, dramatic improvements in short-term process measures were identified using the WHO Monitoring and Process form: 57.1% increase in availability of emergency rooms; 59.1% increase in the supply of emergency tool kits; and a 73.6% increase in the recording of emergency cases (Figs. 49-17 and 49-18).96 More importantly, countrywide morbidity and mortality dropped significantly (Fig. 49-19).97Violence and Injury Prevention. The Violence and Injury Prevention (VIP) program promotes numerous activities to assist countries to prevent and mitigate the consequences of violence and injury.98 While injury prevention is paramount, VIP provides guidance for strengthening trauma systems in countries of all economic levels to improve emergency care and rehabilitation. VIP encourages development of systematic data collection and analysis to better guide appropriate interventions. Prevention programs include the WHO Helmet initiative, while the Essential Trauma Care Project (EsTC) creates standards for the care of injured patients and promotes systematic capacity building. VIP advocates support for the UN Decade of Action for Road Safety 2011–2020 and initiatives to achieve SDG 3.6, Brunicardi_Ch49_p2077-p2112.indd 209013/02/19 5:54 PM 2091GLOBAL SURGERYCHAPTER 49halving the number of global deaths and injuries from road traf-fic accidents by 2020, and SDG 11.2, which aims to provide access to safe, affordable, accessible, and sustainable transport systems for all by 2030.99WHO Safe Surgery Saves Lives Initiative. Surgeons have always sought ways to prevent perioperative complications. Aseptic technique, one of the greatest forms of prevention in surgical care, requires vigilant reinforcement to prevent serious wound infections. In resource-limited areas inad-equate perioperative monitoring, lack of critical medications, and poor documentation place patients at increased risk for serious complications. The WHO Safe Surgery Saves Lives Initiative is a worldwide attempt to prevent perioperative complications.100Deaths from surgery occur at 0.4% to 0.8% globally; however, they may exceed 5% to 10% in developing countries. There are about 1 million deaths and 7 million disabling com-plications related to surgery worldwide, 50% of which are estimated to be preventable. The WHO Safe Surgery Saves Lives initiative targets preventable surgical injuries.100 The initiative identified 10 basic and essential objectives that can help prevent perioperative injuries (Table 49-5).101 A simple, three-stage checklist (initiated as the patient enters the operat-ing room, just before the procedure, and just prior to the patient leaving the room) implemented in eight high-, middle-, and low-income countries found a 50% reduction in the failure to meet basic safety standards resulting in a 50% decrease in mor-tality (Fig. 49-20).102Global Surgery and Public HealthSurgical care is increasingly recognized as an integral compo-nent of public health. Traditional teaching portrays sur-gery as the antithesis of public health: treating the individual instead of the community, reactionary instead of pre-ventative, and too expensive especially for countries with devel-oping economies. Yet in reality, surgery and public health share many priorities and would benefit from greater integration in many areas (Fig. 49-21). For example, providing access to obstetrical care or birth attendants for every delivery could 10BeforeAfter0102030405060Wound debridementWound suturing, dressing, suture removalIncision and drainage of abscessesResuscitationFracture managementPenetrating injuriesBlunt injuriesAmputationBurns managementSkin graftingContracture releaseChest tube insertionCricothyroidotomy/TracheostomyRemoval of foreign bodyVenous peripheral cutdownUterine rupture/ectopic pregnancySuprapubic puncture/cystostomyLocal anaesthestic inÿltrationFigure 49-17. Surgical procedures performed 1 to 2 years post training (13 Soum hospitals evaluated). (Reproduced with permission from Henry JA, Orgoi S, Govind S, et al: Strengthening surgical services at the soum (first-referral) hospital: the WHO emergency and essential surgical care (EESC) program in Mongolia, World J Surg. 2012 Oct;36(10):2359-2370.)Brunicardi_Ch49_p2077-p2112.indd 209113/02/19 5:54 PM 2092SPECIFIC CONSIDERATIONSPART IIprevent the majority of vesicovaginal fistulas and markedly decrease the most common cause of maternal death—hemorrhage—for entire communities. Ninety percent of mortal-ity from injury occurs in LMICs, providing another area for surgical teams to lead preventative, population-based strategies to improve public health.103 Male circumcision is another exam-ple of a well-documented preventative, minor surgical proce-dure, capable of reducing the transmission of HIV.104,1050102030405060708090Establishmentof emergencyroomSupply ofemergency kitsRecording ofemergencycare casesInstructions onfacility andinstrumentusageBeforeAfterFigure 49-18. Pilot Soum hospitals’ evaluation 2 years post training. (Reproduced with permission from Henry JA, Orgoi S, Govind S, et al: Strengthening surgical services at the soum (first-referral) hospital: the WHO emergency and essential surgical care (EESC) program in Mongolia, World J Surg. 2012 Oct;36(10):2359-2370.).60.50.40.30.20.10.00200120022003200420052006200720082009Percentage of deathsPercentage of complicationsFigure 49-19. Surgical morbidity and mortality: Mongolia 2001–2009. (Reproduced with permission from Intermountain Healthcare.)Brunicardi_Ch49_p2077-p2112.indd 209213/02/19 5:54 PM 2093GLOBAL SURGERYCHAPTER 49devotes an entire volume to essential surgery, emphasizing its importance as a key part of health worldwide.7 There are three significant developments helping to accelerate the integration of surgery and public health:1. Improved understanding of the burden of surgical disease and its significant component of the overall burden of global disease2. Recognition that surgery has a primary, secondary, and ter-tiary preventative role (Table 49-6)3. Documentation that surgical care can be cost-effective for community-based healthcareTable 49-5Ten basic and essential objectives for safe surgery (WHO*)1. Operate on the correct patient at the correct site2. Use method known to prevent harm from anesthetic administration, while protecting the patient from pain3. Recognize and effectively prepare for life-threatening loss of airway or respiratory function4. Recognize and effectively prepare for risk of high blood loss5. Avoid inducing any allergic or adverse drug reaction known to be a significant risk for the patient6. Consistently use method known to minimize risk of surgical site infection7. Prevent inadvertent retention of instruments or sponges in surgical wounds8. Secure and accurately identify all surgical specimens9. Effectively communicate and exchange critical patient information for the safe conduct of the operation10. Establish routine surveillance of surgical capacity, volume, and results*WHO: World Health Organization.Data from WHO Guidelines for Safe Surgery 2009.PreventiondiagnosistreatmentrehabilitationSurgeryPublichealthFigure 49-21. Overlapping priorities of surgery and public health. (Reproduced with permission from Intermountain Healthcare.)Even after Learmonth presented his landmark lecture in 1949 “The Contributions of Surgery to Preventive Medicine” at the University of London’s Heath Clark Lecture series, surgery has been neglected as a component of public health.106,107 DCP3 Before induction of anaesthesia Before skin incisionBefore patient leaves operating roomSurgical safety checklist(with at least nurse and anaesthetist)(with nurse, anaesthetist and surgeon)(with nurse, anaesthetist and surgeon)This checklist is not intended to be comprehensive. Additions and modifications to fit local practice are encouraged.Nurse verbally confirms: The name of the procedure Completion of instrument, sponge and needle counts Specimen labeling (read specimen labels aloud, including patient name) Whether there are any equipment problems to be addressedTo surgeon, anaesthetist and nurse: What are the key concerns for recovery and management of this patient?Based on the WHO Surgical Safety Checklisthttp://whqlibdoc.who.int/publications/2009/9789241598590_eng_Checklist.pdf© World Health Organization 2009 All rights reservedHas the patient confirmed his/her identity,site, procedure, and consent? YesIs the site marked? Yes Not applicableIs the anaesthesia machine and medicationcheck complete? YesIs the pulse oximeter on the patient andfunctioning? YesDoes the patient have a:Known allergy? No YesDifficult airway or aspiration risk? No Yes, and equipment/assistance availableRisk of >500 ml blood loss (7 ml/kg in children)? No Yes, and two IVs/central access and fluids planned Confirm all team members have introduced themselves by name and role. Confirm the patient’s name, procedure, and where the incision will be made.Has antibiotic prophylaxis been given within the last 60 minutes? Yes Not applicableAnticipated critical eventsto Surgeon: What are the critical or non-routine steps? How long will the case take? What is the anticipated blood loss?To anaesthetist: Are there any patient-specific concerns?To nursing team: Has sterility (including indicator results) been confirmed? Are there equipment issues or any concerns?Is essential imaging displayed? Yes Not applicableFigure 49-20. Surgical safety checklist. (Reproduced with permission from WHO surgical safety checklist, 2009, http://whqlibdoc.who.int/publications/2009/9789241598590_eng_Checklist.pdf. © World Health Organization 2009 All rights reserved.)Brunicardi_Ch49_p2077-p2112.indd 209313/02/19 5:54 PM 2094SPECIFIC CONSIDERATIONSPART IIStrategies for Integration of Global Surgery and Public Health. Three areas stand out as opportunities for integration of global surgery and public health: education, professional societies, and multinational health policy organizations. From an education standpoint, several universities in HICs have developed formal programs for the study of surgery and public health.108,109Diseases commonly present in very late stages in LMICs and in disadvantaged populations in developed countries. Many morbid conditions could have been cured while localized in their earlier stages and likely eradicated by a local surgical pro-cedure. Early recognition and treatment of surgically correctable diseases is a critical preventive role for surgery. Many surgical procedures are not only a form of tertiary prevention, but are also forms of primary prevention (Table 49-7).110Assigning Disease Priorities. Global surgery interventions can be prioritized to identify those conditions in which clini-cians and public health professionals should collaborate most closely—targeting those diseases that impose the largest bur-den on a society and have a highly successful surgical outcome (Table 49-8).94,111 There are four broad, high-priority areas where surgery has an important role for public health interventions: trauma care; obstetrical emergencies; acute-surgical emergen-cies; and nonacute surgical conditions that significantly affect the quality of life (Table 49-9).10Trauma Care. The Essential Trauma Care Project (EsTC) begun in 2001 is a collaboration effort between the International Association for Trauma Surgery and Intensive Care, an inte-grated society within the International Society of Surgery-Societe-Internationale Chirurgie (ISS-SIC) and the World Health Organization (WHO), specifically the Violence and Injury Prevention unit. The project culminated in a document that identified 11 core essential trauma care services (“the rights of the injured patient”) that ought to be available at all levels of healthcare facilities (Table 49-10).112 In addition, the docu-ment delineated 260 human and physical resources that should be available based on the type of facility (Table 49-11).Table 49-6Prevention strategiesPREVENTION STRATEGYTARGETGOAL1. PrimaryRoot causes of diseaseEliminate or reduce risk of developing illness2. SecondaryIllness or disease at earliest stagesLimit progression of disease3. TertiaryDisease at later stagesCure or limit the effect of existing diseaseData from deVries C, RR Price: Global Surgery and Public Health: A New Paradigm, 1st ed. Sudbury, MA: Jones & Bartlett Learning, LLC; 2012.Table 49-7The role of surgery for primary prevention of cancerTERTIARY SURGICAL PROCEDUREPRIMARY CANCER PREVENTEDBreast lumpectomy for ductal carcinoma in situBreastColonoscopic polypectomyColonColposcopy and excisionCervicalResection of actinic keratosisSkinResection of leukoplakia and erythroplakiaOralData from Riviello R, Meara JG, Rogers SO. Comemntary: Cancer Care and Control–the role of surgery. Global Surgery and Anesthesia, 2010. http://www.ghdonline.org/surgery/discussion/cancer-care-and-control-the-role-of-surgery/.Table 49-8Prioritization of surgical conditionsPRIORITY*PUBLIC HEALTH BURDENSURGICAL PROCEDURE SUCCESSFULCOST-EFFECTIVE AND FEASIBLE TO PROMOTE GLOBALLY1HighHighlyHighly2ModerateModeratelyModerately3LowNeither highly or moderatelyLow*Priority one implies that all three conditions must be met. The priority should be shifted to 2 or 3 if any of the conditions are moderate or low.Data from Mock C, Cherian M, Juillard C, et al: Developing priorities for addressing surgical conditions globally: furthering the link between surgery and public health policy, World J Surg. 2010 Mar;34(3):381-385.Table 49-9The role of surgery for public health strategiesTrauma carePrevention of death and chronic disability by the provision of timely, expert, and complete surgical careObstetrical emergenciesTimely surgical intervention in obstructed labor, in preand post-partum hemorrhage, and other obstetrical complicationsAcute surgical emergenciesProvision of competent surgery to treat a wide range of emergency abdominal and nonabdominal conditionsNonacute surgical conditionsSurgical care for several elective conditions that have a significant effect on the quality of life such as cataract, otitis media, clubfoot, and herniasData from Jamison DT, Breman JG, Measham AR et al: Disease Control Priorities in Developing Countries, 2nd ed. New York, NY: Oxford University Press for the World Bank; 2006.Brunicardi_Ch49_p2077-p2112.indd 209413/02/19 5:54 PM 2095GLOBAL SURGERYCHAPTER 49The EsTC recommendations provide a cost-effective framework for LMICs to improve their trauma care. These recommendations have been used as a planning guide and as an advocacy statement. To catalyze strengthening trauma and emergency care in lowand middle-income countries, in 2007, the WHA adopted a resolution on emergency care systems (resolution WHA 60.22).113,114 This first-ever WHA resolution dedicated specifically to trauma care highlights the importance accorded by world governments in caring for their injured.Quality improvement programs provide inexpensive tools to strengthen trauma systems. National trauma registries, integral for trauma research, can be used to monitor and improve patient outcomes.115,116 Yet very few trauma regis-tries exist in LMICs.117,118 The World Bank stated, “It is criti-cal for LMICs to create or strengthen existing trauma systems to improve outcomes.”119,120 Trauma systems exist in varying states of development in different countries, and even within countries. Initiatives to strengthen trauma systems target the full spectrum of services: prevention, prehospital and defini-tive hospital care, rehabilitation, and process improvement and patient safety initiatives. Nearly 2 million lives could be saved each year if LMICs could design and implement simple trauma care initiatives that reduced the case fatality rates among seri-ously injured patients to equal those in HICs (Fig. 49-22).119,120 In one Canadian province, introducing simple prehospital Table 49-10Essential trauma care services1. Obstructed airway appropriately maintained2. Impaired breathing supported3. Pneumothorax and hemothorax promptly diagnosed and treated4. Bleeding promptly stopped (internal or external)5. Shock recognized and treated appropriately (I.V. fluids)6. Timely decompression of space occupying lesions to prevent secondary brain injury7. Abdominal injuries diagnosed and promptly repaired (intestinal injuries and others)8. Disabling extremity injuries corrected9. Potentially unstable spine injuries identified and managed (early immobilization)10. Minimize consequences of injuries by appropriate rehabilitative services11. Medication to provide above services and relieve pain readily availableData from Mock C, Joshipura M, Goosen J, et al: Overview of the Essential Trauma Care Project, World J Surg. 2006 Jun;30(6):919-929.Table 49-11Airway management recommendations for physical and human resources based on type of facility (sample from EsTC*) FACILITY LEVELKNOWLEDGE AND SKILLSBASICGENERAL PRACTITIONERSPECIALISTTERTIARYAssessment of airway compromiseEEEEManual maneuvers (chin lift, jaw thrust)EEEEInsertion of oral or nasal airwayDEEEEndotracheal IntubationDDEEEquipment and supplies    Oral or nasal airwayDEEELaryngoscopeDDEEEndotracheal tubeDDEECapnographyIDDDE: essential; D: desirable; I: irrelevant (not usually to be considered as the level in question).*EsTC: Essential Trauma Care.Data from Mock C, Lromand JD, Goosen J, et al: Guidelines for essential trauma care. Geneva: World Health Organization; 2004.Kumasi,Ghana0LowMiddleCountry incomeHigh20406080Fatalities (percent)(ISS ˜9)Monterrey,MexicoSeattle,WashingtonUnited StatesFigure 49-22. Case fatality rates for severely injured people, 1998. Note: ISS = injury severity score. Income classifications are based on status at the time of the study. Ghana is now a lower-middle income country, and Mexico is an upper-middle-income country. (Reproduced with permission from Intermountain Healthcare.)Brunicardi_Ch49_p2077-p2112.indd 209513/02/19 5:54 PM 2096SPECIFIC CONSIDERATIONSPART IIinterventions and improving the focus on trauma at the policy level demonstrated consistent improvement in trauma-related morbidity and mortality, over a relatively short time period (Fig. 49-23).121Obstetrical and Other Acute Surgical Emergencies.  Reduction of maternal deaths and long-term disability are high priorities for the international community.122 Despite the 44% reduction in maternal deaths from 1990 to 2015, approxi-mately 830 women—mostly in LMICs—still die daily from preventable causes related to pregnancy and childbirth.123 For every maternal death, 30 women are incapacitated by chronic problems that reduce their quality of life and ability to care for their families. High priority surgical procedures to improve maternal health include cesarean section, hysterectomy for postpartum bleeding and uterine rupture, management of ectopic pregnancy, and dilatation and curettage.111 In 2015, the LCGS reported that maternal mortality was closely related to density of surgical, anesthetic, and obstetrical providers (SAOPs). They showed that maternal mortality throughout the world appeared to decrease—by 13.1% on average—for every 10 unit increase in SAOPs per 100,000 persons, a strong argument for addressing maldistribution of providers related to surgical disease.16In terms of nonobstetrical acute surgical emergencies, about 90% could be addressed by developing the capability to care for the 10 most common acute surgical conditions in any local region. While a few types of disease processes vary by geo-graphical location, there are many that are universal, including appendicitis, strangulated hernia, small bowel obstruction, per-forated peptic ulcer, fractures, lacerations, and wounds.Nonacute Surgical Conditions. Even common nonacute conditions can have significant impact on the quality of life. Hernias can prevent otherwise healthy individuals from work-ing, especially in societies where the economy relies heavily on manual labor. Cleft lip and cleft palate deformities interfere with the ability to speak or eat properly and predispose affected indi-viduals to chronic ear infections leading to hearing loss. Many live in isolation because social ostracism prevents them from attending school, marrying, or holding jobs.124 Plastic surgeons who pioneered global outreach for reconstructive procedures for cleft lip and palate opened the door for subsequent outreach by other specialties, including ophthalmology, orthopedics, general surgery, urology, and dentistry.125-127The most common form of blindness is caused by cata-racts. Cataracts decrease the quality of life and the socioeco-nomic status for both the blind person and his or her family. The fact that 90% of blind people no longer work reveals the extra burdens carried by the family members who care for them.128 The Himalayan Cataract Project (HCP) is a highly successful initiative focusing on cataracts in Asia and Africa. HCP pri-orities and measurable outcomes illustrate how combining key public health concepts with a comprehensive approach to sur-gical care creates a model for curing disease, building econo-mies, and delivering hope in resource-poor areas9 (Box: The Himalayan Cataract Project: A Sustainable Public Health Approach for Curing Blindness).1992–930%10%20%30%Trauma mortality40%50%60%1993–941994–951995–961996–971997–981998–991999–002000–012001–021990: Government ofQuebec deÿnes traumacare as a priority1993: Four Quebechospitals designatedlevel 1 trauma centers1993: Introduction ofguidelines aimed atreducing prehospital times1995: Implementation oftriage and transfer protocolsbased on injury severity1995: Designation oflevel II and III centers1996–97: Specializedtrauma centersdesignated2002: Eliminationof MDs fromprehospital care1994–95: Traumabecomes a priority inlevel 1 centers2000: Guidelines todecrease MD dispatch toprehospital traumaFigure 49-23. Improvement in mortality among severely injured patients in Canada through evolving interventions. Note: Inclusion criteria specified death as a result of injury or an injury severity score (ISS) exceeding 12, a prehospital index exceeding 3, two or more injuries with an abbreviated injury scale score of 3 or higher, or a hospital stay exceeding 3 days. (Adapted with permission from Liberman M, Mulder D, Lavoie A et al. Implementation of a Trauma Care System: Evolution through Evaluation, J Trauma. 2004 Jun;56(6):1330-1335.)Brunicardi_Ch49_p2077-p2112.indd 209613/02/19 5:54 PM 2097GLOBAL SURGERYCHAPTER 49The Himalayan Cataract Project (HCP): A Sustainable Public Health Approach for Curing BlindnessAccording to the WHO criteria, 285 million people worldwide are visually disabled. Of that population, 39 million are classified as bilaterally blind; 90% live in the developing world where poor water quality, lack of sanitation, malnutrition, and inadequate services cause a higher incidence of eye disease.128 The most common cause of avoidable blindness in LMICs is cataract (43%). Nepal has one of the highest incidences of cataracts partially due to increased exposure to ultraviolet sunlight encountered at its higher elevations; 62% of total blindness in Nepal is due to cataracts.129In 1995, Sanduk Ruit joined forces with Geoffrey Tabin to establish the Himalayan Cataract Project (HCP). In the early 1990s, difficult geography with inadequate transportation, the high cost of intraocular lenses, and a lack of trained ophthalmologists, assistants, and nurses limited access to cataract surgery for the poor.HCP developed and defined six priorities, each with an associated public health principle and outcome measurement that provided the basis for assessing success and for implementing change (Fig. 49-24). HCP’s care model targeted the entire population of blind people with cataracts regardless of the ability to pay. Since most of the potential patients lived in remote areas, HCP found it imperative to take cataract surgery to the local communities. The Tilganga Institute of Ophthalmology (TIO) in Katmandu, Nepal, has served as a base from which 493 doctors and over 19,000 ophthalmic personnel of all levels have received training since 1994. Through the TIO and its outreach programs, over 4,657,748 people have been screened, and more than 307,611 eye surgeries have been performed since 1994 (Fig. 49-25).130The TIO developed an ophthalmology residency training program implementing standards set forth by the American Academy of Ophthalmology. In addition to the formal residency program for ophthalmologists, HCP established training programs for community eye care workers in a three-year Ophthalmic Assistant Training Program.Ruit developed an innovative sutureless technique for cataract surgery yielding equivalent results to those in developed countries but also reproducible in resource-constrained areas. By redesigning the intraocular lens implant and mass producing it locally in Nepal for U.S. $4, Ruit and Tabin provided a low-cost alternative to the higher-priced lens produced in developed countries. A local business—the Fred Hollows Intraocular Lens Factory—mass produces the lenses and supports the local economy by creating a new sustainable business.131HCP also designed a compassion-driven, culturally acceptable method for cost-recovery that involves a sliding scale for payment: 45% of patients pay U.S. $120; 20% pay a smaller amount based on their economic situation; and 35% receive cataract surgery for free.With the rapidity and scale of success experienced in Nepal, HCP and TIO began expanding their efforts globally. HCP is now actively working to replicate and proliferate their model in countries throughout South Asia and Africa by developing high-quality eye care systems, supporting local institutions, and training local doctors and ophthalmic personnel. Since 2005, HCP has trained over 300 ophthalmic personnel from 19 countries.HCPprioritiesPublic healthprinciplesImplementationAccessibleAppropriateDisruptive technologySustainable growthAffordableSustainabilityHumanitarianHigh qualityInnovationDirect impactAffordabilityReplicationEntire populationCare at local levelCare comparable to western standardsDisease with high incidence/prevalenceDesigned $4 lensLocal businessSkills transferBuilding infrastructureDelivery model$20 cost/cataractMeet needs of current populationCulturally and economically acceptableFigure 49-24. Himalayan cataract project priorities, public health principles, and outcome measurements. (Redrawn from Himalayan Cataract Project and Tilganga Eye Center, Cureblindness.org, 129-131, by permission. Illustration reproduced with permission from Intermountain Healthcare.)Brunicardi_Ch49_p2077-p2112.indd 209713/02/19 5:54 PM 2098SPECIFIC CONSIDERATIONSPART IICancer InitiativesSurgery for cancer in public health plays a role not only for curative surgery, but also for early diagnosis, prevention, and palliation.52,110,132,133 Solid tumors, in their early stages, presents insidiously as a nonacute surgical problem. Due to cancer’s recent recognition as a leading cause of death, cancer has been identified as a health priority in LMICs. Most solid tumors are incurable without surgery and at a minimum require surgical excision of the primary lesion.110It is often not appreciated that surgeons provide a signif-icant amount of primary care and are the principle providers involved in endoscopic screening and treatment of gastrointes-tinal tumors in LMICs. In countries without specialized ser-vices, low-cost and effective treatment options combining early prevention and treatment with off-patent drug use have led to coverage of cancer treatment in several middle-income coun-tries’ national health insurance plans.52 Cancer care provides significant opportunity for including surgery in community-wide public health programs as a high priority according to the prioritization model (see Table 49-6); cancer has a high public health burden, is treated with highly successful procedures, and can be cost-effective and feasible globally. In 2009, a coalition of leaders in cancer care and public health organized the Global Task Force on Expanded Access to Cancer Care and Control in Developing Countries (GTFCCC).134 GTFCCC’s mission is to expand access to cancer prevention, detection, and care in LMICs. Successful partnerships have already been entered into Haiti, Rwanda, Mexico, Malawi, and Jordan.Cost-Effectiveness of Surgical Care. Funders in healthcare look for measurable return on their investments. While compari-son of outcomes and objective measures would be ideal, reality demonstrates that healthcare budgets more commonly are dic-tated by politics rather than actual need. Nevertheless, in a world of limited resources and tightening budgets for healthcare, cost-effective analyses of various options for intervention are critical for policy makers. Comparing various options that have differ-ent outcomes is an approach called cost-utility analysis (CUA). Surgical interventions can be evaluated by specific diseases or conditions, or by systems or services required to support the delivery of surgical care. In 1990, the World Bank defined the Disability Adjusted Life Year (DALY) as the sum of Years of Life Lost (YLL) due to premature mortality in the population and the Years Lost due to Disability (YLD) for people living with the health condition or its consequences (DALY = YLL + YLD). Evaluating the cost per DALY averted is one approach for comparing the cost-utility between medical and surgical interventions. Recent surgical cost/DALY studies identifying the cost-effectiveness of various types of surgical care have allowed surgical initiatives to be considered when prioritizing public health initiatives.The World Bank arbitrarily defined U.S. $100 per DALY averted per day in low-income countries as highly cost-effective. Compared to other public health initiatives, developing basic and emergency surgical care at the district level hospital is as cost-effective as, or more so, than typical public health programs such as retroviral treatments for HIV/AIDS or immunization for measles (Fig. 49-26).135-139Using the WHO’s cost-effectiveness standards, investing in emergency obstetrical systems, including timely caesarean delivery, can also be considered “highly cost-effective” for 48 of 49 countries in which there are currently inadequate numbers of cesarean deliveries.140,141 The median cost per DALY averted by cesarean-section was $304. In addition, the cost-benefit ratio in 46 of 49 countries was >1, suggesting that investment in cae-sarean delivery is a viable economic proposition.Inguinal hernia repair is one of the most common opera-tions performed worldwide. Tension-free inguinal hernia repairs performed with mosquito netting or polypropylene mesh were cost-effective in Western Ecuador and Western Ghana ($78.18 per DALY and $12.88 per DALY averted, respectively).136,142 Using mosquito netting in India was 3700 times cheaper than using traditional polypropylene mesh.143Using “value of lost output” (VLO) data representing 90% of the world’s population, it is estimated that U.S. $20.7 trillion would be lost between 2015 and 2030 due to unmet surgical needs and their inherent morbidity and mortality.144 Projected 1119941996199820002002200420062008201020122014201635,00030,00025,00020,00015,00010,00050000SurgeriesYearFigure 49-25. Eye surgeries at Tilganga Eye Center and outreach. Note: 2015 was the year of a devastating earthquake in Nepal. (Redrawn from Himalayan Cataract Project and Tilganga Eye Center, Cureblindness.org, 129-131, by permission. Illustration reproduced with permission from Intermountain Healthcare.)Brunicardi_Ch49_p2077-p2112.indd 209813/02/19 5:54 PM 2099GLOBAL SURGERYCHAPTER 49economic losses of such magnitude have underlined the impor-tance of prioritizing surgical infrastructure and the cost-effective nature of many interventions within the surgical realm.Factors Affecting Utilization and Outcome for Surgical Care. There are three major factors that severely limit utiliza-tion of surgical services:1. Socioeconomic and cultural factors2. Accessibility of facilities3. Quality of care (Fig. 49-27)145The decision to seek timely care is affected by the costs associated with time off from work and inability to support the family during the absence, transportation and lodging, and the surgical services themselves. Cultural and religious tradi-tions may define acceptability of various treatment options. For example, many people in Mongolia refuse to have surgery on Tuesdays as this is viewed as a “bad luck” day. Understanding local customs and cultural concerns can improve utilization of surgical services.At the intersection of cost and culture are “willingness to pay” (WTP) models, which predict how a society’s perceived costs of obtaining care versus tolerating a medical condition will lead to or prevent them from seeking care. Such calcula-tions can inform which policies are most likely to yield improved health for a country or region, and they rely heavily on per capita gross domestic product (GDP) and DALYs averted. It is vital to understand that these models, and the policies they inform, are context-dependent. What is perceived as socially valuable in Tanzania may be seen as overpriced or unnecessary in Haiti. As global surgical advocates work with public health experts to strengthen surgical systems, it will be important to remember that context, culture, and cost are indivisible from one another.146Austere environments, difficult terrain, and long distances from health care facilities significantly delay or prevent access to surgical care. Triage and transfer guidelines along with tele-medicine have the potential to mitigate the limitations of geog-raphy. However, without adequately trained care providers and support staff, the risk for poor outcomes is increased.Recognizing these three important factors for increasing utilization and outcomes, Mongolia initiated a public health approach for the management of gallbladder disease incorpo-rating minimally invasive surgery (Box: The Public Health Approach to Management of Gallbladder Disease in Mongolia).Figure 49-26. Cost-effectiveness of surgical interven-tions, compared to two key medical interventions. Note: DALY = disability-adjusted life year. (Reproduced with permission from Intermountain Healthcare.)Orthopedic surgery tripTrauma centerCesarean deliveryHydrocephalus repairTrachoma surgeryCleft lip and palate repairHernia repairSurgical hospitalCataract surgeryObstetric hospitalMeasles vaccinationAntiviral therapy for HIV$1/DALY$10/DALY$100/DALY$1000/DALYRange Cost/DALY (2012 US$)Figure 49-27. Factors affecting utilization and outcome of surgical care. (Adapted with permission from UNFPA United Nations Population Fund (UNFPA); Setting stan-dards for emergency obstetric and new-born care; Available from: https://www.unfpa.org/resources/setting-standardsemergency-obstetric-and-newborn-care. Illustration reproduced with permission from Intermountain Healthcare.)Socioeconomic/cultural factorsAccessibility offacilitiesQuality ofcarePhase IDecision toseek carePhase IIIdentifying & reachingmedical facilityPhase IIIReceipt of adequate &appropriate treatmentFactors affectingutilization & outcomePhases of delayBrunicardi_Ch49_p2077-p2112.indd 209913/02/19 5:54 PM 2100SPECIFIC CONSIDERATIONSPART IIThe Public Health Approach to Management of Gallbladder Disease in MongoliaMongolia, the most sparsely populated country in the world, covers a large geographic area nestled between China and Siberia.147 The austere environment with extremes of weather, dry deserts, and high mountains present significant obstacles for road building limiting transportation for patients in the vast rural areas (Fig. 49-28). Significant deficiencies in infrastructure, supplies, equipment, and human resources at primary healthcare facilities exist: sporadic electricity, no fully qualified surgeons or anesthesiologists, and less than half the facilities with running water.3 In 2006, Healthcare expenditures reached only U.S. $23.2 per capita.148,149The second most common cause of inpatient morbidity in Mongolia has transitioned to gastrointestinal diseases with liver disease, appendicitis, and gallbladder disease the top three causes.150 While laparoscopic cholecystectomy was introduced in Mongolia in 1994, by 2005 only 2% of gallbladders were removed laparoscopically, and then, only in the capital city.151 A cohort study in 2005 comparing open with laparoscopic cholecystectomy by Dr. Sergelen, the chief of surgery at the Health Sciences University of Mongolia (HSUM), found the wound infection rate to be significantly lower, hospital stays shorter, and hospital expenditures 50% less with laparoscopy compared to open cholecystectomy.152Dr. Sergelen formulated a plan to expand access to laparoscopic surgery throughout Mongolia. This plan targeted the three main areas affecting utilization and outcome:1. Quality of Care:a. Develop a laparoscopic training didactic and practical course to train surgical teams and transfer skills safely.b. Improve the surgical infrastructure for each facility.c. Expand the surgical residency to include laparoscopic training.2. Accessibility of Quality Care:a. Begin training surgical teams in the capital city, but then expand them to four carefully selected regional diagnostic treatment and referral centers (RDTRCs) in all four quadrants of the country.b. Invite industry to offer cost-affordable supplies and replacement parts to sustain the laparoscopic equipment in Mongolia.3. Socioeconomic/Cultural Factors:a. Educate the public on the increased benefits of laparoscopic surgery so they would initiate lobbying efforts demanding the government increase funding for these services.b. Educate government leaders about the need and benefit of laparoscopic cholecystectomy for the Mongolian people.The strategic initiative that began by expanding laparoscopic cholecystectomy within the capital city and then to the four key Regional Diagnostic and Treatment Referral Centers (RDTRCs) created the foundation for countrywide access to high-quality modern surgery for a regionally prevalent disease (Fig. 49-29).147,153In 2011, through a multinational partnership (HSUM, the Dr. WC Swanson Family Foundation (SFF), the Society of American Gastrointestinal and Endoscopic Surgeons (SAGES), and the University of Utah Department of Surgery), Mongolia experienced a Figure 49-28. Rural Ger. (Used with permission from Michelle K. Price.)Brunicardi_Ch49_p2077-p2112.indd 210013/02/19 5:54 PM 2101GLOBAL SURGERYCHAPTER 49dramatic transformation from open to laparoscopic cholecystectomy; laparoscopic replaced open cholecystectomy and became the primary method to remove the gallbladder in Mongolia (Fig. 49-30).154As people began to see their neighbors return to functional ability faster with the laparoscopic approach, the Mongolian people developed increased trust in their healthcare providers and the quality of care they could receive. The Ministry of Health committed increased funding for laparoscopic surgery and changed existing laws making it easier for hospitals to purchase the needed equipment and supplies solidifying the needed financial and business models to support laparoscopic surgery in Mongolia.By 2016, with the introduction of laparoscopic training into the surgical residency program and development of laparoscopic fellowship training for surgical teams from outlying provinces, 17 of 21 provinces now provide laparoscopic cholecystectomy allowing patients the benefits of less pain, smaller incisions, fewer wound infections, and more rapid return to work (Fig. 49-31).KhovdChoybalsanUlaanbaatarErdenetArvaikheerMurunArvaikheer regionaldiagnostic and treatmentreferral centerHospital #1Hospital #2Cancer hospitalNomun hospitalMurungeneral hospitalErdenet regionaldiagnostic and treatmentreferral centerKhovd regionaldiagnostic and treatmentreferral centerChoybalsan regionaldiagnostic and treatmentreferral centerRussiaChinaFigure 49-29. The public health approach to expanding laparoscopy to the regional diagnostic treatment and referral centers of Mongolia (RDTRCs). (Reproduced with permission from Intermountain Healthcare.)20050204060Percent of total cases801002006200720082009Year2010201120122013U1BAU1BR1BR1BR2R3BR3R4BR2R5BR4R5BR6BU2BU2BU1U3AU1Ap ˜ 0.001CROSSOVER FROM OPEN TO LAP CHOLE(SAGES)(SAGES)RURALURBANU1BAU1BR1BR1BR2R3BR3R4BR2R5BR4R5BR6BU2BU2BU1U3AU1A(SAGES)= Open= Laparoscopy= Plan for countrywide lap surgery expansion= Advanced course= Basic course= UrbanN= RuralN= Center numberABURNFigure 49-30. Transition from open to laparoscopic cholecystectomy in Mongolia. (Reproduced with permission from Wells KM, Lee YJ, Erdene S, et al: Building operative care capacity in a resource limited setting: The Mongolian model of the expansion of sustainable laparo-scopic cholecystectomy, Surgery. 2016 Aug;160(2):509-517.)Brunicardi_Ch49_p2077-p2112.indd 210113/02/19 5:54 PM 2102SPECIFIC CONSIDERATIONSPART IIIntegrating Value into Global SurgeryAnother topic closely related to quality is the concept of value in healthcare, often described in terms of the value equation. The value equation states that value equals quality plus service, divided by cost. In this model, systems that generate high-quality care, at lower costs, produce greater value for stakeholders in that system (i.e., patients, physicians, insurers, and hospitals). This discussion is most pertinent in high-income countries such as the United States, where rising healthcare expenditures are cause for worry. It is also relevant in LMICs, where proposed interventions to improve quality must also control cost. A bidi-rectional exchange of information related to surgical systems between HICs and LMICs may provide one strategy for reduc-tion of cost in HICs and maximization of quality in LMICs.Advanced Surgical Care for Resource-Poor AreasLimited financial, physical, and human resources, political and social conflicts, and austere environments cause many to believe that advanced surgical care is inappropriate in resource poor countries.111,155-157 Misconception of the needs and abilities of people in LMICs cause some policymakers to discount the desire of people worldwide for advanced surgical care.144 Developing these capabilities in resource-poor coun-tries has the potential to decrease overall cost and actually develop the infrastructure necessary to entice physicians and other healthcare workers to remain in their own countries. Establishing advanced surgical care requires expertise and ser-vices that symbiotically support and improve general medical care. Therefore, many developing countries are actively build-ing capacity and capability to provide the full spectrum of modern surgical care locally.158As economies improve and the benefits of laparoscopic surgery for resource-poor areas become better delineated, patients and doctors, surgical societies, ministries of health, and industries are demanding the benefits of minimally invasive surgery for patients and communities.150,159-165 The economic impact of laparoscopy may be even greater in LMICs than in developed countries.166 Worldwide, surgeons have identified laparoscopic training as one of their greatest needs. In a 2010 survey, developing laparoscopic and endoscopic skills were identified as the most important skills desired by surgeons from the West Africa College of Surgeons (WACS) (Fig. 49-32).167Transplantation is another area of great interest to people in poor countries partly because of the high prevalence of kidney failure and because chronic dialysis facilities are limited. Hepatoma and liver failure are very common in countries with a strong prevalence of hepatitis B and C. Transplantation has become the treatment of choice for end-stage kidney disease in developed countries as it dramatically improves the qual-ity of life and increases survival rates compared to medical management.168 Yet, transplantation eludes most of the developing world. Initial attempts to transport critically ill patients from LMICs to developed countries for kidney transplantation were cost-prohibitive.169 With the alarming increase in the rate at which young people have been presenting with kidney disease in developing countries, the increased utilization placed on the few dialysis machines has been overwhelming.170 Dialysis units which previously were utilized three times a week, now oper-ate 24 hours a day, 7 days a week, and cannot begin to provide the needed services to the multitudes needing treatment. Even programs to develop peritoneal dialysis cannot fully ease the demand.12Remaining states without laparoscopic surgery capabilityLaparoscopic Surgery expanded with internal Mongolian trainersLaparoscopic Surgery developed with HSUM/SFF/SAGES/U of U partnershipBayankhongorArhangaiKhovsgolZavkhanUvsKhentiiBayan-UlgiiBulganTuvDundgobiOmnogoviDomogoviKhovdGovi-altaiUvurkhangaiDornodSelengeDarkhanUulSukhbaatarOrkhonGobi-SumberFigure 49-31. Laparoscopic cholecystectomy expanded to 17 of 21 provinces in Mongolia by 2016. (Data from Raymond Price via personal communication with Dr. Erdene Sergelen. Illustration reproduced with permission from Intermountain Healthcare.)Brunicardi_Ch49_p2077-p2112.indd 210213/02/19 5:54 PM 2103GLOBAL SURGERYCHAPTER 49The majority of kidney transplants in developing countries are from living related donation because of cultural and legal prohibitions precluding cadaveric transplantation. Laparoscopic living related donation has the potential to increase the volun-tary donor pool as patients have less postoperative pain, return to work and activities quicker, and have much better cosmesis than open surgery.171 Ethical concerns exist for nonrelated dona-tions, however, because of concern for coercion in some coun-tries. Adapting to the limited resources, surgeons have described various cost-saving techniques to facilitate the laparoscopic approach in resource poor areas, such as using endoclips instead of staplers for vascular control, modifications to the surgical approach, and suprapubic extraction of the kidney rather than endocatch removal.171-173Academic Global SurgeryThere has been a paradigm shift from traditional reliance on intermittent short-term volunteerism toward a strengthening of the education and research pillars for surgical healthcare in developing regions, a role ideally suited for academic sur-gery. Global surgery is emerging as a new academic field of endeavor (Table 49-12). Academic institutions have histori-cally pioneered discovery in disease causation and treatment. As globalization expands, academic surgical programs are begin-ning to respond by broadening their vision and mission. This vision and mission includes interdisciplinary and collaborative approaches to designing innovative, affordable surgical care that is accessible to all through research, education, development, and advocacy.174,175Responding to the challenges of disparities, new genera-tions of students, faculty, philanthropists, private industry lead-ers, and policymakers have demonstrated a growing passion to address global surgery as part of global health.176,177 Prior to 1984, only 0.32% of physicians and 0.12% of nurses were involved in international health (either paid or volunteer).178 Recently, interest in global health has exploded among medical students, residents, and faculty in the United States.179,180Figure 49-32. West African College of Surgeons: most desired skills. CT = computed tomography; MRI = magnetic resonance imag-ing. (Adapted with permission from Akporiaye L. Trigen survey: West African College of Surgeons. Trigen, Lagos, Nigeria. Unpublished data. 2010. Illustration reproduced with permission from Intermountain Healthcare.)706050403020100Open surgical skills(suturing, dissection)Minimal access skillsEndoscopic skillsSurgical critical careIntraoperative respiratory &hemodynamic monitoringRadiologic image interpretation(ultrasound, CT, MRI)Ultrasound skillsTable 49-12Examples of academic global surgery programsINSTITUTIONNAME OF GLOBAL SURGERY CENTERBrigham and Women’s HospitalCenter for Surgery and Public HealthEmory University School of MedicineGlobal Surgery ProgramHarvard Medical SchoolProgram in Global Surgery and Social ChangeKing’s College LondonKing’s Center for Global Health and Health PartnershipsMcGill UniversityCentre of Global SurgeryOregon Health and Sciences UniversityGlobal Health Advocacy Program in SurgeryUniversity of British ColumbiaBranch for International Surgical CareUniversity of California San FranciscoCenter for Global Surgical StudiesUniversity of ChicagoGlobal Surgery ProgramUniversity of UtahCenter for Global SurgeryBrunicardi_Ch49_p2077-p2112.indd 210313/02/19 5:54 PM 2104SPECIFIC CONSIDERATIONSPART IIAcademic involvement in global surgery provides train-ing for the next generation of surgical leaders where they can learn the necessary skills to develop systems for quality and affordable surgical care, both locally and internationally. Leaders for the 21st century will need to know how to provide outstanding cost-effective clinical care for all environments.Global Surgery programs use a variety of methods to engage faculty, residents, and students to foster an envi-ronment of creativity and innovation necessary to generate new ideas for solving some of the most vexing problems in global health. For example, some academic collabora-tive programs introduce medical, engineering, and business students to the fascinating world of medical device innova-tion focusing on a variety of communities with very limited resources.181,182 Other academic endeavors include global surgery resident rotations, fellowships, journal clubs, classes (locally and online), certificates, Masters of Public Health, bilateral exchange programs, and a variety of educational, research, and entrepreneurial meetings (local, national, and international). Many of these activities provide opportuni-ties for collaborative scholarly work (journal publications, books, book chapters, films, grants, research trials) that pres-ent new avenues for academic advancement supporting both colleagues from abroad as well as the home institution. More importantly, Ministries of Health are responding to results of these scholarly works by designing policies that include surgi-cal care in their countrywide health plans.Partnering academic programs from high-income coun-tries with LMICs and/or with NGOs provides opportuni-ties for collaboration183 (Box: Academic Global Surgery 13Global surgery engagementsLEVEL OF INTEGRATIONAssociationAllianceCollaborationPartnership+–Figure 49-33. Training outcomes from NGO/academic partner-ship. (Reproduced with permission from IVUmed and Intermoun-tain Healthcare.)Academic Global Surgery PartnershipsA. Rwanda Human Resources for Health (HRH) ProgramThe Rwanda Human Resources for Health (HRH) program is an ambitious 7-year long program of the Ministry of Health (MOH) of Rwanda, funded by the U.S. Government and the Global Fund to Fight AIDS, Tuberculosis, and Malaria. The HRH Program seeks to greatly expand and improve Rwanda’s health care workforce by strengthening national training programs of specialized physicians, nurses, oral health providers, and health managers. The HRH Program is also designed to strengthen the capacity of academic institutions in Rwanda to sustain the training programs initiated and supported by the HRH Program through (a) recruitment and retention of Rwandan faculty, (b) transfer of knowledge and skills to Rwandan faculty, (c) establishment of additional academic partnerships and collaborations between Rwandan academic institutions and U.S. academic institutions. Currently, 22 U.S. academic medical centers and universities are participating in this program, in collaboration with the University of Rwanda—College of Medicine and Health Sciences (UR-CMHS) training faculty. Since the launch of the program in 2012, U.S. institutions have deployed about 100 faculty members per year across these four health-related professions. The recruited U.S. faculty are twinned with UR faculty and senior trainees, paired along common goals and interests, and together they engage in a diversity of activities—including teaching, training, research, clinical care, and care delivery improvement projects.The program is currently in its fifth year (August 2016–July 2017). Focusing our discussion on the surgical disciplines, the annual intake of postgraduate students (residents) has dramatically increased. The anesthesiology residency, whose annual matriculation ranged from zero to three residents, now routinely admits 10 new residents yearly. The surgery residency has divided into the four specialties of general surgery, orthopedics, urology, and neurosurgery. Annual matriculation across all for programs now ranges from 15 to 20 compared to 3 to 6, prior to the HRH program’s support of the surgery department. In July 2016, UR graduated eight new general surgeons and one new urologist, the largest output to date. Similar training output is noted across the other disciplines and specialties as well. As a result, Rwanda is now on track to achieve most of its targets for the health workforce. Most graduates are deployed across provincial hospitals to provide specialty level care in a decentralized fashion, while a portion are maintained at the teaching hospitals to be recruited as new faculty. The HRH Program also aims to strengthen the quality of the training programs through competency-based training and pedagogic innovation, improvements in infrastructure and equipment within the schools at the CMHS and the teaching hospitals, and stronger administration of the training programs. As the HRH program comes into its final years, efforts are underway towards faculty professional development program that will both ensure that the UR-CMHS is able to Partnerships). Global surgery engagements exist along a con-tinuum from simple associations, to alliances, collaborations, or formal partnerships (Fig. 49-33). A true partnership usually involves specified and joint rights and responsibilities. The other engagements vary depending on the amount of integra-tion between the institutions and organizations. Successful sustainable progress for global surgery can occur within any of the different levels of engagement. Many partnerships begin with a simple association or alliance before growing into a formal partnership.Academic Global Surgery helped progress the founda-tional knowledge in defining the burden of surgical disease, clarifying the cost-effectiveness of surgical care, and estab-lishing baseline values of surgical capacity.184 Further work is necessary to move beyond data collection and to use this foun-dational knowledge to now develop interventional strategies and stimulate sustainable solutions for accessible, affordable, appropriate surgical care for all.185Brunicardi_Ch49_p2077-p2112.indd 210413/02/19 5:54 PM 2105GLOBAL SURGERYCHAPTER 49continue making the aforementioned human resource gains independent of this large foreign aid grant, and that the relationships and collaborations forged between academic institutions may continue to grow and find new avenues for productive work together.186—Robert Riviello, MD, MPH, FACSB. Coordinating Nongovernmental Organizations (NGO) and Academic Organizations: IVUmedNonprofit organizations (NGO) have filled a niche in establishing surgical care in countries where training centers and healthcare systems are historically nonexistent or understaffed. More recently, professional organizations have developed a focus on specific diseases or patient groups and have become a resource for education and training in poor countries.For more than 20 years, the IVUmed NGO has focused on urological education and hands-on training in Africa, Asia, and Latin America. IVUmed evolved from a need identified by plastic surgeons that had seen many children with hypospadias and other urological anomalies, such as exstrophy, when providing care for children with cleft lip and palate. Adult surgeons were not trained in the delicate reconstruction of pediatric genitourinary anomalies, and pediatric surgeons were not trained in endoscopic or reconstructive urological surgery. The program has expanded to support training in all aspects of urological care, including adult reconstruction, oncology, and endoscopic management of stones and prostatic disease.As a nonprofit organization, IVUmed is a partnership between surgeons, anesthesiologists and nurses, academic medical centers, urological professional associations, industry, and the public with urologic surgery training in more than 20 countries. It also provides North American trainees scholarships to travel to low-resource countries to learn and to share knowledge gained in their own programs. Many former scholars become mentors for other residents when they complete their training. The sites with the longest collaborations have developed their own educational programs in general urology or subspecialty areas and are now providing advanced training and care locally (see Fig. 49-33).C. Cancer Disparities Consortium in West AfricaNoncommunicable diseases, such as cancer, are a major public health problem in lowand middle-income countries (LMIC). In many LMIC, surgeons, due to the lack of medical oncologists, treat all stages of noninfectious related cancers, such as breast and colorectal cancer (CRC). In 2011, to address the disparity in outcomes for patients with cancer in West Africa compared to the United States, a research and training collaboration was formed between the Obafemi Awolowo University Teaching Hospital in Nigeria and Memorial Sloan Kettering Cancer Center (MSK) in New York. This relationship has now grown to become a consortium of five Nigerian hospitals and the Global Cancer Disparity Initiative Team at MSK.The consortium began by focusing on important questions regarding CRC: how can early stage patients be identified; what are the demographics of CRC patients in Nigeria; and is the biology of CRC different in Nigeria compared to the USA? These questions are being answered, with the support of two NIH grants, by creating a robust prospective database with a matching biobank. With over 250 patients, the consortium can now describe the metastatic patterns, stages of presentation, and risk factors for CRC in West Africa. Given that over 65% of patients present with stage IV disease, the development of a risk model to identify patients with early stage disease is a priority. This is being accomplished with a 400-patient prospective trial of colonoscopy in patients over 45 years of age with rectal bleeding in three Nigerian cities. Future projects include studying new technologies for CRC and breast cancer screening.—Peter Kingham, MD, FACSEthicsThe ethics involved in working outside one’s own country are complex. While a practitioner’s scope of practice is usually constrained by regulation in America and Europe, in many countries the limits of what one can do are neither regulated nor enforced. Guidelines for what should be done, where, and under what circumstances are beyond the expertise of some ministries of health. Some problems are so episodic that they are not anticipated, and few guidelines exist. For example, in natural disasters and emergencies, should any willing provider from any country be granted permission to provide care? Should specific disaster-related training be encouraged or required?187,188 In the nonacute setting, should practitioners not licensed or credentialed in their home environments be allowed to perform volunteer surgery in other countries? What entity should oversee the flow of volunteer practitioners? Can a standard set of guidelines meet the needs of most countries? Currently, there is little cross-national agreement between state entities, like ministries of health and independent organizations and individuals. While many countries require at least temporary licensure, some do not. In many cases enforce-ment is inconsistent.With respect to research, the poor historically have not received benefit from research performed on them. In inter-national studies, even local collaborators have been left out of study design and publication.189 As internet communications have improved, these lapses are no longer tolerated.190 Informed consent for surgical procedures, in the appropriate language and respectful of local customs, is becoming the norm. Few hospitals outside academic medical centers have institutional review boards (IRBs) to oversee the implementation and review of clinical research. In recent years, peer reviewed journals have become more mindful of attribution of credit, and authors are strongly encouraged to design and report studies with local input at all levels.With regard to transplantation, many countries have laws against cadaveric transplants because of the very real concern for illegal marketing of organs. Even living-donor Brunicardi_Ch49_p2077-p2112.indd 210513/02/19 5:54 PM 2106SPECIFIC CONSIDERATIONSPART IItransplantation has seen effects of coercion in some regions and for some populations such as prisoners. Nevertheless, the need and popular desire for transplantation is accelerating acquisition of skills and technology to make transplantation available worldwide.191Finally, what is considered ethical in one country or com-munity might be considered highly unethical in another. Con-sent for surgery may in one setting rest with the patient, but in another, with the community or family. Values about privacy vary markedly from region to region. Health information in many cultures is considered to be a community concern, not the personal property of an individual patient.Innovation in Global SurgeryThe pressing need for surgical care at all levels and the shortage of fully trained surgeons, anesthesiologists, and support personnel as well as equipment and supplies means that opportunities abound for innovation. Innovations in education, including simulation, can shorten the time necessary for learn-ing technical skills. Gaming technology can teach algorithms for interpretation of X-rays and ultrasounds. Telemedicine/tele-health is transforming education through combinations of clini-cal case-based learning and massively open online courses (MOOC) (Box: Telemedicine). The potential for education innovation in surgery beyond the apprenticeship system cham-pioned by Halsted in 1904 is vast.14Sophisticatedtechnology thatsimplifiesLow-cost,innovativebusiness modelsEconomicallycoherent valuenetworkRegulations and standards thatfacilitatechangeFigure 49-34. Elements of disruptive innovation. (Reproduced with permission from Intermountain Healthcare.)Innovation that radically changes the way we do things and that changes a paradigm of a service or system is called “disruptive”; it abruptly changes an older and more expensive system in favor of a less expensive, more widely available technology or process. The ability for disruptive innovations to transform products and services into affordable realities requires three main factors: a sophisticated technology that simplifies, a low-cost business model, and an economically coherent value network (Fig. 49-34).195Regulations and standards that vary between countries and locales can facilitate or impede disruptive change. While disrup-tions often are not qualitatively superior to the status quo, they make the process both less expensive and more accessible, and through multiple iterations, ultimately improve quality as they cycle through the transformative process.Decentralizing education, laboratory testing, and medical records have been made possible through free and open-source software, apps, and devices such as smart phones, tablets, and laptop computers. Monitoring and imaging devices and lapa-roscopic instruments designed for low resource environments have the potential to not only improve accessibility in poor countries but also to radically reduce surgical costs in wealthy ones.196THE FUTURE FOR GLOBAL SURGERYSurgeons of the future will need to educate themselves in areas that have not historically been taught in surgical curricula. Beyond the technical aspects of surgical practice, there is a complex ecosystem that supports surgical care. Surgeons must become more aware of the complexities of cost in order to be able to shape the environment in which they work. They must understand better what patients are seeking from the surgical experience, rather than focusing primarily on a narrow view of what surgery might have to offer. Surgeons must engage in policy development and advocate for affordable and accessible surgical care without sacrificing quality. Thoughtful technology design can focus on improving quality and on decreasing cost, both in poor and wealthy countries. Building surgical capac-ity through a health systems-focused approach, with robust data collection, and establishment of global surgery centers of Telementoring in Global SurgeryOne excellent example of successful telementoring in surgery is a program started by Allan Okrainec, MD, a minimally invasive surgeon at the University of Toronto, and Georges Azzie, MD, a pediatric surgeon at Toronto’s Hospital for Sick Children. In the mid-2000s, the two imagined utilizing laparoscopic box trainers and videoconferencing technology via Skype to teach minimally invasive techniques to surgeons in LMICs.192 As part of the “Go Global” Initiative of the Society of American Gastrointestinal and Endoscopic Surgeons (SAGES), Dr. Okrainec’s team traveled to Botswana in 2007 to teach a 3-day Fundamentals of Laparoscopic Surgery (FLS) course in person. Although only two of twenty surgeons achieved certification, average posttest scores showed promising improvement.Realizing that continued mentorship promotes success, Dr. Okrainec’s team reconfigured their teaching model to include telesimulation. In 2009, they carried out an 8-week course in FLS, with weekly meetings via videoconference and real-time simulation demonstration and feedback between Botswana and Toronto. This time, 100% of participants in the tele-simulation group attained certification.193 Subsequently, the team expanded its program to Colombia, with similar success in skill acquisition.194 Since 2009, the program has expanded to 15 countries, with satellite telesimulation sites in Colombia and Ukraine. They have trained more than 300 individuals in FLS skills around the world.Brunicardi_Ch49_p2077-p2112.indd 210613/02/19 5:54 PM 2107GLOBAL SURGERYCHAPTER 49excellence will stimulate improvements in the provision of sur-gical and anesthesia services.197 Further integration of surgical care into national health plans of governments should encour-age increased investments and political will necessary to create capacity, leading to timely, quality surgical care to all without risk of financial ruin.16,91 Our colleagues in public health and the World Bank, Paul Farmer and Jim Kim, have challenged us: “We need our surgical colleagues to speak fluently about rebuilding infrastructure, training, personnel, and delivering high-quality care to the very poorest.”106REFERENCESEntries highlighted in bright blue are key references. 1. Shrime MG, Bickler SW, Alkire BC, Mock C. Global burden of surgical disease: an estimation from the provider perspec-tive. Lancet Glob Health. 2015;3(suppl 2):S8-S9. 2. Weiser TG, Regenbogen SE, Thompson KD, et al. An esti-mation of the global volume of surgery: a modelling strategy based on available data. Lancet. 2008;372(9633):139-144. 3. Chang L, Lacy BE, Spiegel BM. Quantifying surgical and anesthetic availability at primary health facilities in Mongolia. World J Surg. 2011;35(2):272-279. 4. Contini S, Taqdeer A, Cherian M, et al. Emergency and essen-tial surgical services in Afghanistan: still a missing challenge. World J Surg. 2010;34(3):473-479. 5. Choo S, Perry H, Hesse AA, et al. Assessment of capacity for surgery, obstetrics and anaesthesia in 17 Ghanaian hos-pitals using a WHO assessment tool. Trop Med Int Health. 2010;15(9):1109-1115. 6. Kushner AL, Cherian MN, Noel L, Spiegel DA, Groth S, Etienne C. Addressing the Millennium Development Goals from a surgical perspective: essential surgery and anes-thesia in 8 lowand middle-income countries. Arch Surg. 2010;145(2):154-159. 7. Debas HT, Donkor P, Gawande A, Jamison DT, Kruk ME, Mock CN, eds. Essential Surgery. Disease Control Priori-ties. 3rd ed. Vol 1. Washington, DC: World Bank; 2015. doi: 10.1596/978-1-4648-0346-8. 8. Alkire BC, Shrime MG, Dare AJ, Vincent JR, Meara JG. Global economic consequences of selected surgical diseases: a modeling study. Lancet Glob Health. 2015;3:S21-S27. 9. deVries C, Price RR. Global Surgery and Public Health: A New Paradigm. 1st ed. Sudbury, MA: Jones and Bartlett Learning; 2012:300. 10. Debas HT. Surgery. In: Jamison DT, ed. Disease Control Pri-orities in Developing Countries. 2nd ed. New York: Oxford University Press; 2006:1245-1259. 11. Chao TE, Sharma K, Mandigo M, et al. Cost-effectiveness of sur-gery and its policy implications for global health: a systematic review and analysis. Lancet Glob Health. 2014;2(6):e334-e345. 12. Grimes CE, Henry JA, Maraka J, et al. Cost-effectiveness of surgery in lowand middle-income countries: a systematic review. World J Surg. 2014;38(1):252-263. 13. International Finance Corporation. The Business of Health in Africa: Partnering with the Private Sector to Improve Peo-ple’s Lives. Available at: https://www.unido.org/sites/default/files/2016-01/IFC_HealthinAfrica_Final_0.pdf. Accessed August 22, 2018. 14. Central Intelligence Agency. CIA World Fact Book. 2018. Available at: https://www.cia.gov/library/publications/the-world-factbook/. Accessed August 22, 2018. 15. World Health Organization. World Health Statistics 2012. Available at: http://www.who.int/gho/publications/world_health_statistics/2012/en/. Accessed August 22, 2018. 16. Meara JG, Leather AJM, Hagander L, et al. Global surgery 2030: evidence and solutions for achieving health, welfare, and economic development. Lancet. 2015;386(9993):569-624. 17. Casey KM. Putting the “global” back in global health. Arch Surg. 2012;147(5):404-407. 18. Copenhagen Consensus Center. Nobel Laureates: More should be spent on hunger, health: top economists identify the smart-est investments for policy-makers and philanthropists. 2012. Available at: https://www.copenhagenconsensus.com/sites/default/files/CC12+Results+Press+Release+Final_0.pdf. 19. Kydland F, Stokey N, Schelling T, et al. Post-2015 consensus. Copenhagen Consensus Available at: http://www.copenhagen-consensus.com/sites/default/files/outcomedocument_col.pdf. Accessed August 22, 2018. 20. Lancet Commissioners. The Lancet Commission on global surgery, 2015. Available at: http://www.lancetglobalsurgery .org/lancet-commissioners. Accessed August 22, 2018. 21. 68th World Health Assembly. Emergency and Essential Surgi-cal Care, World Health Organization. Available at: http://who .int/surgery/wha-eb/en/ 22. Dare AJ, Grimes CE, Gillies R, et al. Global Surgery: defining an emerging global health field. Lancet. 2014;384:2245-2247. 23. deVries CR, Rosenberg JS. Global surgical ecosys-tems: a need for systems strengthening. Ann Glob Health. 2016;82(4):605-613. 24. Chu K, Rosseel P, Gielis P, Ford N. Surgical task shifting in Sub-Saharan Africa. PLoS Med. 2009;6:e1000078. 25. Sheldon GF, Ricketts TC, Charles A, King J, Fraher EP, Meyer A. The global health workforce shortage: role of surgeons and other providers. Adv Surg. 2008;42:63-85. 26. Crisp N, Chen L. Global supply of health professionals. New Engl J Med. 2014;370:950-957. 27. Mkandawire N, Ngulube C, Lavy C. Orthopaedic clinical officer program in Malawi: a model for providing orthopaedic care. Clin Orthop Relat Res. 2008;466(10):2385-2391. 28. Pereira C, Cumbi A, Malalane R, et al. Meeting the need for emergency obstetric care in Mozambique: work performance and histories of medical doctors and assistant medical officers trained for surgery. BJOG. 2007;114(12):1530-1553. 29. Kruk ME, Pereira C, Vaz F, Bergström S, Galea S. Economic evaluation of surgically trained assistant medical officers in performing major obstetric surgery in Mozambique. BJOG. 2007;114(10):1253-1260. 30. Sherwood KL, Price RR, White TW, Stevens MH, Van Boerum DH. A role in trauma care for advanced practice clinicians. JAAPA. 2009;22(6):33-36, 41. 31. Ozgediz D, Kijjambu S, Galukande M, et al. Africa’s neglected surgical workforce crisis. Lancet. 2008;371:627-628. 32. Rodriguez MI, Gordon-Maclean C. The safety, efficacy and acceptability of task sharing tubal sterilization to midlevel providers: a systematic review. Contraception. 2014;89(6):504-511. 33. Mullan, F. The metrics of the physician brain drain. N Engl J Med. 2005;353(17):1810-1818. 34. Humphries N, McAleese S, Matthews A, Brugha R. “Emigra-tion is a matter of self-preservation. The working conditions...are killing us slowly”: qualitative insights into health professional emigration from Ireland. Hum Resour Health. 2015;13:35. 35. Hagopian A, Thompson MJ, Fordyce M, Johnson KE, Hart LG. The migration of physicians from sub-Saharan Africa to the United States of America: measures of the African brain drain. Hum Resour Health. 2004;2(1):17. 36. Tankwanchi AB, Vermund SH, Perkins DD. Moni-toring Sub-Saharan African physician migration and recruitment post-adoption of the WHO code of practice: tem-poral and geographic patterns in the United States. PLoS One. 2015;10(4):e0124734.Brunicardi_Ch49_p2077-p2112.indd 210713/02/19 5:54 PM 2108SPECIFIC CONSIDERATIONSPART II 37. Hagander LE, Hughes CD, Nash K, et al. Surgeon migra-tion between developing countries and the United States: train, retain, and gain from brain drain. World J Surg. 2013;37(1):14-23. 38. Mills EJ, Schabas WA, Volmink J, et al. Should active recruit-ment of health workers from Sub-Saharan Africa be viewed as a crime? Lancet. 2008;371:685-688. 39. McCoy D, Bennett S, Witter S, et al. Salaries and incomes of health workers in sub-Saharan Africa. Lancet. 2008;371(9613):675-681. 40. Riviello R, Ozgediz D. International medical graduates and the global surgical workforce: the perspective from the other side. J Am Coll Surg. 2008;207(1):143-144. 41. World Health Organization. Health workers for all and all for health workers. The Kampala declaration and agenda for global action. Available at: http://www.who.int/workforceal-liance/Kampala%20Declaration%20and%20Agenda%20web%20file.%20FINAL.pdf. Accessed August 22, 2018. 42. Global population to pass 10 billion by 2100, UN projections indicate. UN News. May 3, 2011. Available at: http://www .un.org/apps/news/story.asp?NewsID=38253#.UST1tDfheSp. 43. Population ageing and development: ten years after Madrid. available at: http://www.un.org/esa/population/publications/popfacts/popfacts_2012-4.pdf. Accessed August 22, 2018. 44. He W, Goodkind D, Kowal P. An Aging World: 2015. Available at: https://www.census.gov/content/dam/Census/library/publi-cations/2016/demo/p95-16-1.pdf. Accessed August 22, 2018. 45. Husain I, Patierno K, Zosa-Feranil I, et al. Fostering Eco-nomic Growth, Equity, and Resilience in Sub-Saharan Africa: the Role of Family Planning. Available at: https://www.prb.org/wp-content/uploads/2016/10/pace10.16-report-FosteringEconomic-Growth-Equity.pdf. Accessed August 22, 2018. 46. Salomon JA, Vos T, Hogan DR. Common values in assessing health outcomes from disease and injury: disability weights measurement study for the Global Burden of Disease Study 2010. Lancet. 2012;380(9859):2129-2143. 47. Murray CJ, Vos T, Lozano R, et al. Disability-adjusted life years (DALYs) for 291 diseases and injuries in 21 regions, 1990-2010: a systematic analysis for the Global Burden of Disease Study 2010. Lancet. 2012;380(9859):2197-2223. 48. Groen RS, Samai M, Stewart KA, et al. Untreated surgical con-ditions in Sierra Leone: a cluster randomised, cross-sectional, countrywide survey. Lancet. 2012;380(9847):1082-1087. 49. Petroze RT, Groen RS, Niyonkuru F, et al. Estimating opera-tive disease prevalence in a low-income country: results of a nationwide population survey in Rwanda. Surgery. 2013;153(4):457-464. 50. Gupta S, Groen RS, Kyamanywa P, et al. Surgical care needs of low-resource populations: an estimate of the prevalence of surgically treatable conditions and avoidable deaths in 48 countries. Lancet. 2015;385(suppl 2):S1. 51. Duda RB, Hill AG. Surgery in developing countries: should surgery have a role in population-based health care? Am Coll Surg Bull. 2007;92(5):12-18, 35. 52. Farmer P, Frenk J, Knaul FM, et al. Expansion of cancer care and control in countries of low and middle income: a call to action. Lancet. 2010;376(9747):1186-1193. 53. The Global Burden of Disease Cancer Collaboration. The global burden of cancer 2013. JAMA Oncol. 2015;1:505-527. 54. Mody GN, Nduaguba A, Ntirenganya F, Riviello R. Char-acteristics and presentation of patients with breast cancer in Rwanda. Am J Surg. 2013;205:409-413. 55. Gelband H, Jha P, Sankaranarayanan R, Horton S, eds. Cancer: Disease Control Priorities. 3rd ed. Vol 3. Washington, DC: World Bank; 2015. 56. Hoekstra HJ, Wobbes T, Heineman E, et al. Fighting global disparities in cancer care: a surgical oncology view. Ann Surg Oncol. 2016;23:2131-2136. 57. Mock C, Joshipura M, Goosen J, Maier R. Overview of the Essential Trauma Care Project. World J Surg. 2006;30:919-929. 58. Mock C. Strengthening care for the injured globally. J Trauma. 2011;70(6):1307-1316. 59. World Health Organization. Injury and violence: the facts. 2004 Available at: http://www.who.int/violence_injury_pre-vention/key_facts/VIP_key_fact_1.pdf. Accessed August 22, 2018. 60. World Health Organization. Violence and Injury Prevention: Injury and violence: the facts. Available at: http://www.who .int/violence_injury_prevention/key_facts/VIP_key_facts .pdf?ua=1. Accessed August 22, 2018. 61. Lozano R, Naghavi M, Foreman K, et al. Global and regional mortality from 235 causes of death for 20 age groups in 1990 and 2010: a systematic analysis for the Global Burden of Dis-ease Study 2010. Lancet. 2012;380(9859):2095-2128. 62. World Health Organization. Global status report on road safety 2015. Available at: http://www.who.int/violence_injury_pre-vention/road_safety_status/2015/en/. Accessed August 22, 2018. 63. American College of Surgeons. Rural Trauma Team Devel-opment Course. 3rd ed. Available at: https://www.facs.org/quality-programs/trauma/education/rttdc. Accessed August 22, 2018. 64. Kopits E, Cropper M. Traffic fatalities and economic growth. Accid Anal Prev. 2005;37:169-178. 65. World Health Organization. Burns. Available at: http://www .who.int/mediacentre/factsheets/fs365/en/. Accessed August 22, 2018. 66. World Health Organization. A WHO Plan for Burn Preven-tion and Care. Available at: http://apps.who.int/iris/bitstream/handle/10665/97852/9789241596299_eng.pdf?sequence. Accessed August 22, 2018. 67. Saffle JR, Edelman L, Theurer L, Morris SE, Cochran A. Telemedicine evaluation of acute burns is accurate and cost-effective. J Trauma. 2009;67(2):358-365. 68. Shokrollahi K, Sayed M, Dickson W, et al. Mobile phones for the assessment of burns: we have the technology. Emerg Med J. 2007;24(11):753-755. 69. Keough GJ, Matherly AF, Cochran A. Expanding burn care knowledge in a rural region through project exten-sion for community healthcare outcomes. JAMA Surg. 2017;152(4):401-402. 70. New Mexico School of Medicine. Project ECHO. Available at: https://echo.unm.edu. Accessed August 22, 2018. 71. The University of Utah Health. Telemedicine: teleburn care. Available at: http://healthcare.utah.edu/burncenter/telemedi-cine.php. Accessed August 22, 2018. 72. Kim JY. Opening address to the inaugural “The Lancet Commission on Global Surgery” meeting. The World Bank. January 17, 2014. Boston, MA. http://www.lancetglobalsur-gery.org/january-videos 73. Jamison DT, Summers LH, Alleyne G, et al. Global health 2035: a world converging within a generation. Lancet. 2013;82(9908):1898-1955. 74. Luboga S, Macfarlane SB, von Schreeb J, et al. Increasing access to surgical services in Sub-Saharan Africa: priorities for national and international agencies recommended by the Bellagio Essen-tial Surgery Group. PLoS Med. 2009;6(12):e1000200. 75. Kingham TP, Price RR, Casey KM, Rogers SO, Kushner AI. Beyond volunteerism: augmenting surgical care in resource-limited settings. Bull Am Col Sur. 2011;96(7):16-21. 76. Gosselin RA, Gyamfi YA, Contini S. Challenges of meet-ing surgical needs in the developing world. World J Surg. 2011;35(2):258-261. 77. Shrime MG, Sleemi A, Ravilla TD. Specialized surgical plat-forms. In: Essential Surgery: Disease Control Priorities. 3rd ed. Vol 1. Washington DC: World Bank; 2015:231-244.Brunicardi_Ch49_p2077-p2112.indd 210813/02/19 5:54 PM 2109GLOBAL SURGERYCHAPTER 49 78. APRIDEC Medical Outreach Group. Available at: http://apridec .org. Accessed August 22, 2018. 79. Price R, Sergelen O, Unursaikhan C. Improving surgical care in Mongolia: a model for sustainable development. World J Surg. 2013;37(7):1492-1499. 80. Cheng LH, McColl L, Parker G. Thyroid surgery in the UK and on board the Mercy Ships. Br J Oral Maxillofac Surg. 2012;50(7):592-596. 81. Rodas E, Vicuna A, Merrell RC. Intermittent and mobile surgical services: logistics and outcomes. World J Surg. 2005;29(10):1335-1339. 82. Wells KM, Lee YJ, Erdene S, et al. Building operative care capacity in a resource limited setting: the Mongolian model of the expansion of sustainable laparoscopic cholecystec-tomy. Surgery. 2016;160(2):509-517. 83. The United Nations. Origin and History. Available at: http://www.un.org/en/about-un/index.html. Accessed August 22, 2018. 84. The United Nations. About the UN: Overview. Available at: http://www.un.org/en/sections/about-un/overview/index.html. Accessed August 22, 2018. 85. The United Nations. Sustainable Development Goals: 17 Goals to Transform Our World. Available at: http://www .un.org/sustainabledevelopment/sustainable-development-goals/. Accessed August 22, 2018. 86. The University of Manchester Brooks World Poverty Insti-tute. The Millennium Development Goals (MDGs): A Short History of the World’s Biggest Promise. Available at: https://www.unidev.info/Portals/0/pdf/bwpi-wp-10009.pdf. Accessed August 22, 2018. 87. Millenium Development Goals and Beyond 2015. 2018. United Nations Millennium Project, http://www.un.org/mil-lenniumgoals/bkgd.shtml. 88. The United Nations. Transforming Our World: the 2030 Agenda for Sustainable Development. United Nations General Assembly, Seventieth session, 25 September 2015. Available at: http://www.un.org/ga/search/view_doc.asp?symbol=A/RES/70/1&Lang=E. Accessed August 22, 2018. 89. Kumar S, Kumar N, Vivekadhish S. Millennium development goals (MDGS) to sustainable development goals (SDGS): addressing unfinished agenda and strengthening sustainable development and partnership. Indian J Community Med. 2016;41:1-4. 90. Alma Ata Declaration. October 31, 2012. Available at: http://en.wikipedia.org/wiki/Alma_Ata_Declaration. Accessed 2018. 91. Price R, Makasa E, Hollands M. World Health Assem-bly Resolution WHA68.15: strengthening emergency and essential surgical care and anesthesia as a component of universal health coverage—addressing the public health gaps arising from lack of safe and accessible surgical and anesthetic services. World J Surg. 2015;39:2115-2125. 92. World Health Organization. Primary Health Care: Now More than Ever. Available at: http://www.who.int/whr/2008/whr08_en.pdf. Accessed August 22, 2018. 93. World Health Organization. Report: WHO Meeting Towards a Global Initiative for Emergency and Essential Surgical Care (GIEESC). 2005. Available at: http://www.who.int/ surgery/mission/GIEESC2005_Report.pdf. Accessed August 22, 2018. 94. Spiegel DA, Abdullah F, Price RR, Gosselin RA, Bickler SW. World health organization global initiative for emergency and essential surgical care: 2011 and beyond. World J Surg. 2012;1462-1469. 95. World Health Organization. WHO Global Initiative for Emer-gency and Essential Surgical Care Sixth Biennial and Tenth Anniversary Meeting. Available at: http://apps.who.int/iris/bitstream/10665/206541/1/WHO_HIS_SDS_2016.11_eng .pdf?ua=. Accessed August 22, 2018. 96. Henry JA, Orgoi S, Govind S, Price RR, Lundeg G, Kehrer B. Strengthening surgical services at the Soum (First-referral) hos-pital: the WHO emergency and essential surgical care (EESC) program in Mongolia. World J Surg. 2012;36(10):2359-2370. 97. Indicators of Surgical Operation (Mongolia 2001-2009). 2010 [cited 2017 March 25]; Available from: www.doh.gov.mn. 98. World Health Organization. Injury and violence: the facts. Available at: http://www.who.int/violence_injury_preven-tion/key_facts/VIP_key_facts.pdf?ua=1. Accessed August 22, 2018. 99. The United Nations. United Nations Road Traffic Collabo-ration: UN General Assembly adopts a resolution “Improv-ing global road safety.” Available at: http://www.who.int/violence_injury_prevention/media/news/2016/15_04/en/. Accessed August 22, 2018. 100. Haynes AB, Weiser TG, Berry WR, et al. A surgical safety checklist to reduce morbidity and mortality in a global popula-tion. N Engl J Med. 2009;360(5):491-499. 101. World Health Organization. WHO guidelines for safe surgery 2009: Safe surgery saves lives. Available at: http://apps.who .int/iris/bitstream/handle/10665/44185/9789241598552_eng .pdf?sequence=1. Accessed August 22, 2018. 102. World Health Organization WHO surgical safety checklist. Available at: http://www.who.int/patientsafety/safesurgery/checklist/en/. Accessed August 22, 2018. 103. Peden M, McGee K, Krug E. Injury: A Leading Cause of the Global Burden of Disease. Geneva: World Health Organiza-tion; 2002. 104. Auvert B, Taljaard D, Lagarde E, Sobngwi-Tambekou J, Sitta R, Puren A. Randomized, controlled intervention trial of male circumcision for reduction of HIV infection risk: the ANRS 1265 Trial. PLOS Med. 2005;3(5):e226. 105. Weiss HA, Quigley MA, Hayes RJ. Male circumcision and risk of HIV infection in sub-Saharan Africa: a systematic review and meta-analysis. AIDS. 2000;14:2361-2370. 106. Farmer PE, Kim JY. Surgery and global health: a view from beyond the OR. World J Surg. 2008;32(4):533-536. 107. Learmonth J. The Contributions of Surgery to Preven-tive Medicine. London: Oxford University Press, Geoffrey Cumberlege, Publisher to the University; 1951:55. 108. Brigham and Women’s Hospital. Center for Surgery and Pub-lic Health. Available at: http://www.brighamandwomens.org/research/labs/CenterforSurgeryandPublicHealth/default.aspx. Accessed August 22, 2018. 109. UC San Diego School of Medicine, Department of Surgery. Available at: https://medschool.ucsd.edu/som/surgery/educa-tion/Pages/Global-Surgery.aspx 110. Riviello R, Meara JG, Rogers SO. Commentary: cancer care and control—the role of surgery. Global Surgery and Anes-thesia 2010. Available at: http://www.ghdonline.org/surgery/discussion/cancer-care-and-control-the-role-of-surgery/. Accessed August 22, 2018. 111. Mock C, Cherian M, Juillard C, et al. Developing priorities for addressing surgical conditions globally: furthering the link between surgery and public health policy. World J Surg, 2010;34(3):381-385. 112. Mock C, Lormand JD, Goosen J, Joshipura M, Peden M, Guidelines for Essential Trauma Care. Geneva: World Health Organization; 2004:106. 113. Sixtieth World Health Assembly. Health systems: emergency-care systems. Available at: http://www.wpro.who.int/mnh/A60_R22-en.pdf. Accessed August 22, 2018. 114. Mock C. WHA resolution on trauma and emergency care ser-vices. Inj Prev. 2007;13(4):285-286. 115. Haider AH, Hashmi ZG, Gupta S, et al. Benchmark-ing of trauma care worldwide: the potential value of an International Trauma Data Bank (ITDB). World J Surg. 2014;38(8):1882-1891.Brunicardi_Ch49_p2077-p2112.indd 210913/02/19 5:54 PM 2110SPECIFIC CONSIDERATIONSPART II 116. Mann NC, Mullins RJ, MacKenzie EJ, et al. Systematic review of published evidence regarding trauma system effectiveness. J Trauma. 1999;47(3 suppl):S25-S33. 117. O’Reilly GM, Joshipura M, Cameron PA, Gruen R. Trauma registries in developing countries: a review of the published experience. Injury. 2013;44(6):713-721. 118. Stelfox HT, Joshipura M, Chadunchachai W, et al. Trauma quality improvement in low and middle income countries of the Asia-Pacific region: a mixed methods study. World J Surg. 2012;36(8):1978-1992. 119. Gosselin R, Charles A, Joshipura M, et al. Surgery and Trauma Care. Disease Control Priorities. 3rd ed. Vol 1. New York: World Bank; 2015. 120. Mock C, Joshipura M, Arreola-Risa C, Quansah R. An esti-mate of the number of lives that could be saved through improvements in trauma care globally. World J Surg. 2012;36(5):959-963. 121. Liberman M, Mulder D, Lavoie A, et al. Implementation of a trauma care system: evolution through evaluation. J Trauma. 2004;56:1330-1335. 122. Khan KS, Wojdyla D, Say L, Gülmezoglu AM, Van Look PF. WHO analysis of causes of maternal death: a systematic review. Lancet. 2006;367(9516):1066-1074. 123. World Health Organization. Maternal mortality fact sheet. 2016 Available at: http://www.who.int/mediacentre/factsheets/fs348/en/index.html. Accessed August 22, 2018. 124. Corlew DS. Perspectives on plastic surgery and global health. Ann Plast Surg. 2009;62(5):473-477. 125. Smile Train. 2017. Available at: http://www.smiletrain.org/. Accessed August 22, 2018. 126. Operation Smile. 2017. Available at: http://www.operations-mile.org/. Accessed August 22, 2018. 127. ReSurge International. 2016. Available at: http://resurge.org/home/home.cfm. Accessed August 22, 2018. 128. World Blindness Overview. 2017. Available at: http://www .cureblindness.org/world-blindness/. Accessed August 22, 2018. 129. Nepal. 2017. Available at: http://www.cureblindness.org/where/himalayas/nepal/. Accessed August 22, 2018. 130. Tilganga Eye Centre. 2017. Available at: http://www.cureblindness.org/what/infrastructure/specialty-hospitals/ tilganga/. Accessed August 22, 2018. 131. HCP’s Eye Care Model. 2017. Available at: http://www.cure-blindness.org/what/hcp-eye-care-model/. Accessed August 22, 2018. 132. Kushner A. Malawi esophageal cancer palliative care program. In: Kingham P, ed. Quarterly Newsletter, Society of Interna-tional Humanitarian Surgeons. New York; Society of Interna-tional Humanitarian Surgeons: 2009. 133. Agarwal G, Ramakant P, Forgach ER, et al. Breast cancer care in developing countries. World J Surg. 2009;33(10):2069-2076. 134. Global Task Force on Expanded Access to Cancer Care and Control in Developing Countries: 2017 Available at: http://gtfccc.harvard.edu/icb/icb.do?keyword=k69586&tabgroupid= icb.tabgroup132925. Accessed August 22, 2018. 135. Ozgediz D, Riviello R. The “other” neglected diseases in global public health: surgical conditions in sub-Saharan Africa. PLoS Med. 2008;5(6):e121. 136. Shillcutt SD, Clarke MG, Kingsnorth AN. Cost-effectiveness of groin hernia surgery in the Western Region of Ghana. Arch Surg. 2010;145(10):954-961. 137. Gosselin RA, Heitto M. Cost-effectiveness of a district trauma hospital in Battambang, Cambodia. World J Surg. 2008;32(11):2450-2453. 138. Gosselin RA, Thind A, Bellardinelli A. Cost/DALY averted in a small hospital in Sierra Leone: what is the relative contribu-tion of different services? World J Surg. 2006;30(4):505-511. 139. McCord C, Chowdhury Q. A cost effective small hospital in Bangladesh: what it can mean for emergency obstetric care. Int J Gynaecol Obstet. 2003;81(1):83-92. 140. Alkire BC, Vincent JR, Burns CT, Metzler IS, Farmer PE, Meara JG. Obstructed labor and caesarean delivery: the cost and benefit of surgical intervention. PLoS One. 2012;7(4):e34595. 141. Murray CJ. Quantifying the burden of disease: the techni-cal basis for disability-adjusted life years. Bull World Health Organ. 1994;72:429-445. 142. Shillcutt SD, Sanders DL, Teresa Butrón-Vila M, Kingsnorth AN. Cost-effectiveness of inguinal hernia surgery in north-western ecuador. World J Surg. 2013;37(1):32-41. 143. Tongaonkar RR, et al. Preliminary multicentric trial of cheap indigenous mosquito-net cloth for tension-free hernia repair. Indian J Surg. 2003;65(1):89-95. 144. Alkire BC, Shrime MG, Dare AJ, et al. The global economic consequences of selected surgical diseases: a modelling study. Lancet Glob Health. 2015;3(suppl 2):S21-S27. 145. United Nations Population Fund (UNFPA); Providing emer-gency obstetric and newborn care to all in need. Available at: http://www.unfpa.org/public/mothers/pid/4385. Accessed August 22, 2018. 146. Marseille E, Larson B, Kazi DS, et al. Thresholds for the cost-effectiveness of interventions: alternative approaches. Bull World Health Organ. 2015;93:118-124. 147. Price R, Sergelen O, Unursaikhan C. Improving surgical care in Mongolia: a model for sustainable development. World J Surg. 2012;37:1492-1499. 148. Gunsentsoodol B, Nachin B, Dashzeveg T. Surgery in Mongo-lia. Arch Surg. 2006;141(12):1254-1257. 149. List of countries by total health expenditure per capita. Avail-able at: http://en.wikipedia.org/wiki/List_of_countries_by_total_health_expenditure_%28PPP%29_per_capita. Accessed August 22, 2018. 150. Health Indicators 2007, National Center for Health Development:Ulaanbataar. Ministry of Health, Mongolia. Available at: http://www.chd.mohs.mn/images/pdf/sma/uzuulelt/ENGLISH2007.pdf. Accessed October 30, 2018. 151. Rusher AH. Outreach surgery. Surgical technology arrives in Mongolia. Bull Am Coll Surg. 1999;84(3):21-25. 152. Sergelen O. Development of laparoscopic surgery in Mongolia. 2006. Available at: http://www.gfmer.ch/Medical_education_En/PGC_RH_2006/Reviews/pdf/Orgoi_laparoscopy_2006.pdf. Accessed August 22, 2018. 153. Straub CM, Price RR, Matthews D, Handrahan DL, Sergelen D. Expanding laparoscopic cholecystectomy to rural Mongo-lia. World J Surg. 2011;35(4):751-759. 154. Wells KM, Lee YJ, Erdene S, et al. Building operative care capacity in a resource limited setting: the Mongolian model of the expansion of sustainable laparoscopic cholecystectomy. Surgery. 2016;160(2):509-517. 155. Manning RG, Azziz AQ. Should laparoscopic cholecystec-tomy be practiced in the developing world? The experience of the first training program in Afghanistan. Ann Surg. 2009; 249(5):794-798. 156. Contini S, Taqdeer A, Gosselin RA. Should laparoscopic cho-lecystectomy be practiced in the developing World? The expe-rience of the first training program in Afghanistan. Ann Surg. 2010;251(3):574; author reply 575. 157. Alfa-Wali M, Antoniou A. Should laparoscopic cholecys-tectomy be practiced in the developing world? Ann Surg. 2010;251(2):387; author reply 387-388. 158. Castadot RG, Magarick RH, Sheppard L, Burkman RT. A review of ten years’ experience with surgical equipment in international health programs. Int J Gynaecol Obstet. 1986;24(1):53-60.Brunicardi_Ch49_p2077-p2112.indd 211013/02/19 5:54 PM 2111GLOBAL SURGERYCHAPTER 49 159. Udwadia TE. Navigating laparoscopic surgery into the next decade in developing countries—a personal perspec-tive. Langenbecks Arch Surg. 2007;392(1):99-104. 160. Udwadia TE. One world, one people, one surgery. Surg Endosc. 2001;15(4):37-343. 161. Vargas G, Price RR, Sergelen O, Lkhagvabayar B, Batcholuun P, Enkhamagalan T. A successful model for laparoscopic train-ing in Mongolia. Int Surg. 2012;97(4):363-371. 162. Clegg-Lamptey JN, Amponsah G. Laparoscopic cholecystec-tomy at the Korle Bu Teaching Hospital, Accra, Ghana: an initial report. West Afr J Med. 2010;29(2):113-116. 163. Baigrie RJ, Stupart D. Introduction of laparoscopic colorectal cancer surgery in developing nations. Br J Surg. 2010;97(5):625-627. 164. Udwadia TE. Low-cost laparoscopic cholecystectomy. (Br J Surg. 2002; 89:1602-1607). Br J Surg. 2003;90(6):761. 165. Piukala S. Laparoscopic cholecystectomy: complications and experiences in Tonga. Pac Health Dialog. 2006;13(2): 107-110. 166. Udwadia TE, Udwadia RT, Menon K, et al. Laparoscopic sur-gery in the developing world. An overview of the Indian scene. Int Surg. 1995;80(4):371-375. 167. Akporiaye L. Trigen survey: West African College of Sur-geons. Trigen, Lagos, Nigeria. Unpublished data. 2010. 168. Al-Bazzaz PH. Kidney transplantation in Erbil, Iraq: a single-center experience. Saudi J Kidney Dis Transpl. 2010;21(2):359-362. 169. Basinda SL, Maro EE, McLarty DG, Young AE, Wing AJ. Ten Tanzanian transplants: problems and perspectives. Postgrad Med J. 1988;64(756):778-782. 170. Korle-Bu to begin kidney transplant in last quarter. 2012. Available at: http://www.ghanaweb.com/GhanaHomePage/NewsArchive/artikel.php?ID=238839. Accessed August 22, 2018. 171. Kumar A, Dubey D, Gogoi S, Arvind NK. Laparoscopy-assisted live donor nephrectomy: a modified cost-effective approach for developing countries. J Endourol. 2002;16(3):155-159. 172. Kumar A, Chaudhary H, Srivastava A, Raghavendran M. Laparoscopic live-donor nephrectomy: modifications for developing nations. BJU Int. 2004;93(9):1291-1295. 173. Simforoosh N, Basiri A, Tabibi A, Shakhssalim N. Laparo-scopic donor nephrectomy—an Iranian model for developing countries: a cost-effective no-rush approach. Exp Clin Trans-plant. 2004;2(2):249-253. 174. Wells KM, Price RR, Finlayson SG, deVries CR. Fundamen-tals for establishing and maintaining an academic centre for global surgery: the University of Utah Experience. Lancet Glob Health. 2014;2(S47):47. 175. Price RR, Butler MW, deVries CR, Abdullah F. Promoting, developing, and sustaining academic global surgery programs. In: Swaroop M, Krishnaswami S, eds. Academic Global Surgery. New York: Springer International Publishing; 2016. 176. Banerjee A. Medical electives: a chance for international health. J R Soc Med. 2010;103(1):6-8. 177. Powell AC, Casey K, Liewehr DJ, Hayanga A, James TA, Cherr GS. Results of a national survey of surgical resident interest in international experience, electives, and volun-teerism. J Am Coll Surg. 2009;208(2):304-312. 178. Baker TD, Weisman C, Piwoz E. U.S. physicians in international health. Report of a current survey. JAMA. 1984;251(4):502-504. 179. Busnaina I. Medical school admissions doctor. 2012. Available at: https://www.usnews.com/education/blogs/medical-school-admissions-doctor/2012/04/09/medical-students-should-consider-overseas-clinical-experience. 180. Provenzano AM, Graber LK, Elansary M, Khoshnood K, Rastegar A, Barry M. Short-term global health research projects by U.S. medical students: ethical challenges for partnerships. Am J Trop Med Hyg. 2010;83(2):211-214. 181. University of Utah Health: Transforming Healthcare through Innovation: Center for Medical Innovation. Available from: http://healthsciences.utah.edu/center-for-medical-innovation/ 182. Stanford University: Extreme: Design for Extreme Affordabil-ity. Available at: https://extreme.stanford.edu.) 183. Busse H, Azazh A, Teklu S, et al. Creating change through collaboration: a twinning partnership to strengthen emergency medicine at Addis Ababa University/Tikur Anbessa Special-ized Hospital—a model for international medical education partnerships. Acad Emerg Med. 2013;20(12):1310-1318. 184. Blair KJ, Paladino L, Shaw PL, Shapiro MB, Nwomeh BC, Swaroop M. Surgical and trauma care in lowand middle-income countries: a review of capacity assessments. J Surg Res. 2017;210:139-151. 185. Carlson LC, Lin JA, Ameh EA, et al. Moving from data col-lection to application: a systematic literature review of surgi-cal capacity assessments and their applications. World J Surg. 2015;39(4):813-821. 186. Cancedda C, Riviello R, Wilson K, et al. Building workforce capacity abroad while strengthening global health programs at home: participation of seven Harvard-affiliated institutions in a health professional training initiative in Rwanda. Acad Med. 2017;92(5):649-658. 187. Sztajnkrycer MD, Madsen BE, Alejandro Báez A. Unstable ethical plateaus and disaster triage. Emerg Med Clin North Am. 2006;24(3):749-768. 188. Ramsey KM, Weijer CR. Ethics of surgical training in devel-oping countries. World J Surg. 2007;31(11):2067-2069; discussion 2070-2071. 189. Zumla A, Costello A. Ethics of healthcare research in develop-ing countries. J R Soc Med. 2002;95(6):275-276. 190. Kushner AL, Kyamanywa P, Adisa CA, et al. Editorial policy on co-authorship of articles from lowand middle-income countries. World J Surg, 2011;35:2367-2368. 191. Cameron JS, Hoffenberg R. The ethics of organ transplanta-tion reconsidered: paid organ donation and the use of executed prisoners as donors. Kidney Int. 1999;55(2):724-732. 192. International Surgery Canada. Telementoring in Botswana. Available at: http://internationalsurgerycanada.com/telemen-toring-in-botswana. Accessed August 22, 2018. 193. Okrainec A, Henao O, Azzie G. Telesimulation: an effec-tive method for teaching the fundamentals of laparoscopic surgery in resource-restricted countries. Surg Endosc. 2010;24(2):417-422. 194. Henao O, Escallon J, Green J, et al. Fundamentals of lapa-roscopic surgery in Colombia using telesimulation: an effective educational tool for distance learning. Biomedica. 2013;33(1):107-114. 195. Christensen CM, Grossman JH, Hwang J. The Innovator’s Prescription. New York: McGraw-Hill; 2009:441. 196. Beck M. New low-cost surgical tool could help patients in third world. The Wall Street Journal. September 23, 2016. 197. Ng-Kamstra JS, Greenberg SLM, Abdullah F, et al. Global Surgery 2030: a Roadmap for high income country actors. BMJ Global Health. 2016;1(1):e000011.Brunicardi_Ch49_p2077-p2112.indd 211113/02/19 5:54 PM
Brunicardi_Ch49_p2077-p2112.indd 211213/02/19 5:54 PMThis page intentionally left blankENHANCED RECOVERY AFTER SURGERYHistory and Overview of Enhanced RecoveryAs anesthetic techniques, antibiotics, and minimally invasive surgery have improved surgical care over the centuries, fur-ther strategies to continue to improve patient outcomes have emerged. A novel perioperative regimen for patients following colon surgery using early oral nutrition, early mobilization, and epidural analgesia was first described in 1995 by Professor Hen-rik Kehlet from Copenhagen, Denmark in a small group of nine patients.1 He subsequently outlined a more detailed multimodal approach to perioperative care in 1997, reducing length of stay to a median of 2 days following sigmoid resection, and thus, has been described as the founder of enhanced recovery after surgery (ERAS).2,3 Soon thereafter, several others duplicated that applying standard perioperative care protocols could reduce length of stay following colon surgery.4The ERAS Study Group was founded in 2001 by Professor Ken Fearon and Professor Olle Ljungqvist to further expand on the ideas proposed by Professor Kehlet. As there was a great discrepancy between actual practices and evidence-based best practices, as well as geographical and practitioner variations in care, the group desired to create a consensus on best practices with guidelines that could be employed in the clinical arena. The primary goal of ERAS is to treat the surgical patient in a multidisciplinary team approach throughout the perioperative course with the unified goal of accelerating functional recov-ery and optimizing patient outcomes based on evidence-based medicine (Fig. 50-1).In order to develop the key tenets of ERAS, the details of preoperative care, intraoperative surgical and anesthetic tech-nique, and postoperative care were scrutinized and standards for each facet of care were developed (Fig. 50-2).ERAS and its associated principles truly represented a paradigm shift in perioperative care, breaking from the clas-sical teaching of prolonged fasting postoperatively until signs of bowel function, excessive fluid administration, and delayed postoperative mobilization. Instead, mitigating the metabolic and stress responses to surgery through multimodal care and uti-lizing evidenced based medicine allows for “fast-track” recov-ery and improved outcomes.Each facet of perioperative care may have modest benefit to the patient when applied alone, but when an integrated, mul-timodal enhanced recovery pathway (ERP) is used, the benefi-cial effects become synergistic. Patients return to presurgical functional states faster, spend less time in the hospital, and expe-rience less morbidity.5 Furthermore, resource utilization is reduced, healthcare system cost is less, and societal cost is lower with faster return to work and reduced homecare needs.6 Though initial studies of ERP were primarily performed for colorectal surgery, ERP can be applied to a wide variety of specialties in the inpatient and outpatient setting including urology, orthopedics, and gynecology. Preoperative OptimizationFirst proposed in 1949 by the anesthesiologist, Dr. J. Albert Lee, a preanesthetic and presurgical evaluation by an anesthesiolo-gist is associated with improved outcomes for the efficiency of the operating room, the hospital, and most importantly, the patient.7 The use of a preoperative evaluation results in identify-ing patients at elevated respiratory risk, a 55% decrease in pre-operative testing, an 88% reduction in case cancellations, reduction in day of surgery delays, reduced total length of stay, a positive impact on hospital finances with cost reduction, and lower in-hospital mortality.8-13 Therefore, while it is very impor-tant for the surgeon to see the patient prior to a surgery, it is also 1Optimizing Perioperative Care: Enhanced Recovery and Chinese MedicineJennifer Holder-Murray, Stephen Esper, Zhiliang Wang, Zhigang Cui, and Xima Wang 50chapterEnhanced Recovery after Surgery 2113History and Overview of Enhanced Recovery / 2113Preoperative Optimization / 2113Metabolic Stress Response to Surgery / 2116Preoperative Fasting and Preoperative Carbohydrate Loading / 2117Intraoperative Considerations / 2117Perioperative Pain Management / 2119Postoperative Nausea and Vomiting Prevention / 2121Early Nutrition and Postoperative Ileus Prevention / 2121Mobilization / 2122ERAS in CRS / 2122ERAS in Hepatopancreaticobiliary Surgery / 2123ERAS in Gastrectomy and Esophagectomy / 2123ERAS in Bariatric Surgery / 2123ERAS in Other Surgical Specialties / 2123Setting Up an ERAS Program / 2124Traditional Chinese Medicine in  Surgical Patients 2124History of Traditional Chinese Medicine / 2124Preoperative Nutritional Optimization / 2126Bowel Preparation for Surgery / 2126Preoperative Optimization During Sepsis and Infection / 2126Perioperative Pain Management / 2127Postoperative Nausea and Vomiting Prevention / 2127Early Nutrition and Postoperative Ileus Prevention / 2127Traditional Chinese Medicine in Common Surgical Conditions / 2127Brunicardi_Ch50_p2113-p2136.indd 211301/03/19 9:39 AM 2114Key Points1 Enhanced recovery after surgery (ERAS) is a paradigm shift in the surgical care of patients. As a multimodal, integrated, evidence-based care pathway, ERAS optimizes patient care in the preoperative, intraoperative, and post-operative setting in order to achieve best patient outcomes. Patients recover faster, experience less physiological stress, enjoy shorter stays in the hospital, and have fewer complications.2 Setting appropriate expectations, optimizing nutritional and physical status through prehabilitation, and treating medical comorbidities optimizes patients before surgery.3 Achieving normovolemia both intraoperatively and post-operatively is important in order to maintain perfusion without volume overload, as hypervolemia and hypovo-lemia are both associated with significant complications. Goal-directed therapy approaches maintain normovolemia with zero fluid balance.4 Intravenous normal saline administration results in hyper-chloremia, which has been associated with increased mor-tality and morbidity.5 As pain is a subjective response and cannot therefore be experienced while unconscious, the use of opioids intraop-eratively should generally be avoided in order to minimize the multiorgan system side effects of these medications. Additionally, avoiding intraoperative opioids actually improves postoperative pain scores and reduces the need for postoperative opioids.6 Multimodal analgesia, which includes oral or IV nonopioid analgesia and regional analgesic techniques, can reduce postoperative physiological stress and decrease complica-tions associated with surgery as part of a pain management regimen. Multimodal analgesia has been shown to reduce the number of opioids required for analgesia.7 The strategies for avoiding postoperative nausea and vom-iting include the avoidance of general anesthesia, the use of totally intravenous anesthesia, avoidance of nitrous oxide and volatile agents, minimizing intraoperative and postoperative opioids, and adequate hydration.8 Enhanced recovery after surgery care pathways can be applied to numerous types of surgery including colorectal, liver, pancreas, bariatric, gynecologic, and urologic sur-gery with success.9 Traditional Chinese medicine has been practiced for thou-sands of years and serves as a distinct cultural heritage of China. Its unique theories and methods are still applied widely in the practice of modern medicine, including dis-ease prevention, disease treatment, and perioperative management.10 Acupuncture and transcutaneous electroacupuncture can reduce the number of opioids utilized in the perioperative setting. Additionally, acupuncture, transcutaneous elec-troacupuncture, and some Chinese herb decoctions are effective in the prevention and treatment of postoperative nausea and vomiting.highly important for the patient to have an opportunity to dis-cuss the upcoming perisurgical and perianesthetic experience with a physician that is trained in the realm of periopera-tive optimization. Setting Expectations and Patient Education. Setting expectations in the preoperative clinic helps to orient patients regarding the entire surgical experience, from what they are expected to do at home before the surgery to the entire length of the recovery both in the hospital and at home. Information on the procedure and typical recovery should be clear, well defined, and consistently reinforced from all healthcare person-nel that interact with the patient. Clear expectations of goals prior to surgery, in the hospital, and after discharge should be communicated long before the surgery. Expected length of stay and disposition should also be clearly communicated in order to optimize timely discharge. The preoperative clinic helps in this role and to establish the patient as the leader in his or her own care. The patient must understand that his or her active partici-pation throughout the perioperative experience will facilitate the recovery. A surgeon can do an operation. An anesthesiologist can keep a patient alive while the patient asleep. However, in reality, it is up to the patient to make his or her own care a prior-ity. If individuals train for a race, should they not also prepare for their procedure so that the recovery is swift? The optimiza-tion for success at surgery begins preoperatively with smoking cessation, exercise, and nutrition, but it also continues in the hospital and after discharge with pain control, physical activ-ity, discharge planning, and returning to daily activities. Clear expectations at each point in the perioperative continuum, which are communicated to the patient, will improve the perioperative experience for the patient and the provider.According to Costa, “Evidence shows that patients suffer needlessly due to inadequate preoperative preparation and lack of information regarding their postoperative course as indicated by reports of unexpected pain, fatigue, and the inability to care for oneself.”14 Patients enter physician offices and procedures with a great deal of fear and anxiety related to the identification of a disease, the consequences of treatment of this disease, and/or the fear of death. Eliciting the patient’s concerns and provid-ing optimal communication and education can allay much of this fear and anxiety. There is a substantial perioperative cul-ture change that is brought about by the elements of ERAS, and many patients have personally had or have had a close relative that has experienced surgery that likely did not include many 2ERAS: Team-centered approachPatientSurgical teamPreoperative nursing teamAnesthesiology teamPACU nursing teamInpatient nursing teamOffice/clinic teamERAS educatorPharmacyERAS project managerInformation technological teamFigure 50-1. Enhanced recovery multidisciplinary team. ERAS = enhanced recovery after surgery; PACU = postanesthesia care unit.Brunicardi_Ch50_p2113-p2136.indd 211401/03/19 9:39 AM 2115OPTIMIZING PERIOPERATIVE CARE: ENHANCED RECOVERY AND CHINESE MEDICINECHAPTER 50components of ERAS. Therefore, this culture change must be clearly disseminated to the patients and include new fasting guidelines, analgesic management, and patient participation in preoperative optimization. Patients can then anticipate and plan for certain events and sensations, such as what and when to eat and drink, how to exercise, what medications will be used, what tubes or lines will be present, and what criteria are used for dis-charge and return to daily activities. This kind of teaching has been defined as a therapeutic communication to help the patient face and cope with the surgical procedure in a calm manner.15Approximately 90 million people have difficulty under-standing and subsequently acting upon health information dis-tributed to them.16 Further, the ability of patients to process and understand basic information to make appropriate health decisions is directly related to socioeconomic status and to Caucasian race; furthermore, the readability of patient-directed healthcare material may be too advanced for comprehension by much of the surgical population.17,18 Thus, it is appropriate for patient information material to be at no higher than a sixth grade reading level, friendly, clear, concise, and simply designed. The employment of audiovisual aids may assist some patients as well.Nutrition. Surgery results in a significant catabolic stress response on the body, triggering inflammation and nutrient depletion. This stress response results in downstream effects on numerous organ systems and can lead to a higher risk of post-operative complications. Ensuring preoperative adequate nutri-tion is imperative before a large surgical procedure in order to mitigate adverse outcomes.While enteral or parenteral nutritional supplementation can be considered for the most nutritionally compromised patient, the enteral route is always preferred if clinically appropriate and can be adequately achieved in a timely fashion. Two main approaches to preoperative enteral nutrition include standard oral nutrition supplements and immunonutrition supplements, each providing extra protein and calories to supplement the diet. There is no statistical difference in infections, complications, and length of hospital stay between patients given standard oral versus immunonutrition supplements.19Standard oral nutrition products are high in protein, contain vitamins and minerals, and are widely available. Immunonutrition supplements usually similarly contain high protein, vitamins, and minerals, but they also have the addition of arginine to improve immunity and tissue repair and omega-3 fatty acids to mediate the inflammatory response.19 The exact dosage of arginine and omega-3 fatty acids that contribute to improved outcomes is not known. Standard oral nutrition prod-ucts may contain no or lesser quantities of arginine and omega-3 fatty acids when compared to immunonutrition supplements. The exact duration and frequency of supplementation have not been established; however, it is clear that the use of standard oral nutrition products has a positive impact on surgical out-comes by reducing postsurgical complications.19Exercise and Prehabilitation. Prehabilitation is defined as “the process of enhancing the functional capacity of the indi-vidual to enable him or her to withstand a stressful event.”20,21 Both exercise and prehabilitation, which have, heretofore, focused on cardiopulmonary rehabilitation prior to surgery, are very important to optimization of patient outcomes. Peri-operative cardiopulmonary exercise testing and prehabilitation in relation to ERAS programs around the world have been ana-lyzed, and it is noted that a reduction in fitness prior to sur-gery is associated with increased mortality and morbidity in the postoperative arena.22 Patients who actively exercise even when suffering from documented coronary artery disease, heart failure, hypertension, diabetes, chronic obstructive pulmonary disease, depression, dementia, cancer, and stroke have better outcomes.23-36 Furthermore, other literature supports the signifi-cant merits of exercise therapy and cardiopulmonary exercise therapy before and after major surgery, with the ability to reduce infection, hospital-associated complications, length of stay, and postoperative mortality.37There is a significant amount of evidence indicating that exercise training is feasible and safe in patients with a spec-trum of severe cardiac and pulmonary diseases as many of these patients require surgery to manage other disease processes. A randomized controlled trial involving 246 low-risk patients undergoing cardiac surgery reported a 1-day reduction in ICU stay and a reduced hospital length of stay in the intervention group.38 Cardiopulmonary fitness was found to be a strong independent predictor of survival after lung surgery, especially for non–small cell lung cancer.39 Preliminary nonrandomized Preoperative phasePatient education & set expectationsSmoking & alcohol cessationPrehabilitation with diet & exerciseShortened fastingAntimicrobial prophylaxisVTE prophylaxisMinimize bowel preparationIntraoperative phasePain blocksMinimally invasive surgeryGoal-directed fluid therapyMultimodal pain reliefPrevention of PONVAvoidance of tubes, drains, linesNormothermiaPostoperative phaseGoal-directed fluid therapyPrevention of PONVEarly ambulationEarly feedingMultimodal pain reliefEarly urinary catheter removalDefined discharge criteriaFigure 50-2. Phases and components of an enhanced recovery after surgery pathway. VTE = venous thromboembolism; PONV = postopera-tive nausea and vomiting.Brunicardi_Ch50_p2113-p2136.indd 211501/03/19 9:39 AM 2116SPECIFIC CONSIDERATIONSPART IIdata from patients undergoing elective rectal cancer surgery within an ERAS program have shown the feasibility of provid-ing a cardiopulmonary exercise interval training program that is delivered three times per week for 6 weeks in a hospital setting after neoadjuvant chemoradiotherapy and before surgery.40 The interval following neoadjuvant therapy offers a unique window of time to improve the fitness and nutrition of many oncologic patients, which is especially important as these patients can often be some of the most debilitated.The addition of physical fitness and activity to a preopera-tive regimen for elderly patients undergoing major abdominal surgery significantly improved mortality, discharge to home versus a care facility, and length of stay.41 While this study showed that patients benefited from 60-minute sessions 2 to 4 weeks prior to surgery, even brief therapy before surgery, ranging from 1 day to 7 days before major abdominal surgery, have been associate with a significant decrease in postopera-tive complications.42,43 Therefore, some oncologic or semiurgent patients may actually benefit from preoperative cardiopulmo-nary exercise programs.Smoking Cessation. Clearly tobacco use, especially smok-ing, has been well documented across all surgical specialties to increase postoperative mortality, as well as increase postopera-tive complications including prolonged ventilation, pneumonia, deep venous thrombosis, wound infection, delayed wound heal-ing, and reduced bone fusion.44-47 Physiologically, the carbon monoxide and nicotine from tobacco products increase heart rate and blood pressure and the body’s demand for oxygen. Nic-otine also causes vasoconstriction, reducing perfusion to many tissue beds. Obviously, it is advantageous for patients to cease smoking preoperatively. There is debate about the duration of the nicotine free days needed preoperatively to offer best out-comes, though the literature suggests that the longer duration of smoking cessation prior to surgery portends better outcomes.48 This is likely to allow for bronchiolar and collagen remodeling and the several weeks following last exposure that are needed to achieve blood free of nicotine and its derivatives.Metabolic Stress Response to SurgeryMultiple organ systems interact in numerous metabolic and inflammatory cascades following the stress response to surgery leading to insulin resistance and protein catabolism (Fig. 50-3). Neuroendocrine responses, stress hormones cascades, activation of cytokine, and immune reactions all occur, leading to a cata-bolic state.49 Central to this metabolic and inflammatory cas-cade is the development of insulin resistance, whereby a normal insulin concentration results in a subnormal biologic response. As insulin is the main anabolic hormone involved in glucose control, fat metabolism, and protein balance, insulin resistance disrupts many metabolic pathways.Hyperglycemia from insulin resistance results from an increase in glucose production and a decrease in glucose uptake by the periphery. In a fed state, insulin levels surge to 6 to 8 times basal levels, which stops glucose production and increases peripheral glucose uptake threeto fourfold.50 When fasting, insulin levels remain in a relative steady state with minimal effects on glucose and protein metabolism. Even when insulin levels increase to three times basal levels, there is no increase in peripheral glucose uptake. Therefore, in the postoperative fast-ing state, without the assistance of exogenous insulin, peripheral Counterregulatory hormonescytokinesGlycogenolysisGlucoseLipolysisInsulinresistanceWhole-bodyprotein catabolismGluconeogenesisHypothalamusPituitaryGlycerolAmino acidsAcute-phaseproteinsHyperglycemiaPyruvateGlycolysisProteolysisLactateInjury siteAfferentsensorynervesSympathetic nervesHumoral agentsNeural impulsesFigure 50-3. Metabolic stress response to surgery results in insulin resistance. (Reproduced with permission from McGill University Health Center Patient Education Office, Montreal, Quebec, Canada.)Brunicardi_Ch50_p2113-p2136.indd 211601/03/19 9:39 AM 2117OPTIMIZING PERIOPERATIVE CARE: ENHANCED RECOVERY AND CHINESE MEDICINECHAPTER 50glucose uptake is reduced. The resulting hyperglycemia can be corrected, however, with the use of exogenous insulin, and when normoglycemia is achieved in the perioperative period, the main components of metabolism also normalize.51The preoperative and postoperative fasting state triggers insulin resistance resulting in a catabolic state with gluconeo-genesis and protein breakdown. Following prolonged fasting states with stress such as following surgery, protein catabolism can be increased several fold over baseline. As less glycogen is stored in the muscle and loss of lean body mass occurs, there is less muscle function and therefore less capacity to mobilize.In addition to the typical metabolic effects of surgery, pain has been demonstrated to increase insulin resistance. In healthy male volunteers undergoing painful stimulation, glucose uptake was reduced as a direct result of decreased insulin sensitivity.52 In addition, serum cortisol, epinephrine, and free fatty acids were all increased following painful stimulation.Elective surgery results in a state of insulin resistance, with the magnitude of surgery corresponding to a decrease in insulin sensitivity.53 For example, the difference in insulin sen-sitivity following laparoscopic cholecystectomy versus open cholecystectomy is 2.5-fold. More complex abdominal surgery such as an open colorectal resection results in a 3.5-fold increase in insulin resistance over laparoscopic cholecystectomy. As lev-els of insulin resistance increase, complications also increase.54 In addition to an association with complications, insulin resis-tance has been shown to be an independent predictor of length of stay.53The increased postoperative complications associated with insulin resistance may be not only from the direct meta-bolic effects of insulin on glucose but also from free radical formation. In peripheral tissues that are independent of insulin metabolism, and therefore do not store glycogen, the increased plasma glucose levels result in greater glycolysis and oxygen free radical formation. This leads to alterations in gene expres-sion, which in turn propagates a cycle of increased inflamma-tion causing even more insulin resistance.55 Elective surgery has been implicated in increased inflammatory gene pathways and changes in insulin signaling genes in both adipose and skeletal muscle tissues.56,57Components of an ERP may offset the metabolic and stress responses of surgery. Preoperative carbohydrate supple-mentation has been shown to counter the catabolic effects of the fasted state by stimulating glucose uptake and transition-ing metabolism to a more anabolic state with improved insulin sensitivity.58 Preoperative carbohydrate supplementation also reduces protein loss and improves muscle strength postopera-tively.59-61 When preoperative carbohydrate supplementation is added to epidural analgesia, there is even greater improvement in insulin resistance.62Preoperative Fasting and Preoperative Carbohydrate LoadingTraditionally, patients have been instructed to fast for 6 to 12 hours before surgery to reduce the risk of aspiration of gastric contents during the induction of anesthesia. This fasting state results in a prolonged period without nutrients or hydration prior to and during surgery, and it can lead to insulin resistance, hyper-glycemia, failure to achieve a postsurgical anabolic state, and sometimes, the need for insulin. Both European and American Societies of Anesthesiology guidelines have supported the use of clear liquid oral intake up to 2 hours prior to surgery with the exception of patients with gastroparesis, intestinal obstruction, or dysphagia.63-65 Carbohydrate oral intake up to 2 hours prior to surgery does not increase aspiration in healthy adults under-going elective surgery and in fact reduces preoperative hunger, thirst, anxiety, and nausea.66,67 In addition, a fasting time of 2 to 4 hours versus more than 4 hours actually results in smaller gastric volume and a higher gastric pH value.68-75 Nevertheless, prior to the introduction of ERAS, the dogma of prolonged nothing-by-mouth status widely adopted many decades ago had little advocacy to change, despite evidence supporting more lib-eral fasting parameters. Current guidelines support fasting from clear liquids for 2 hours and solid food for 6 hours.Preoperative carbohydrate loading prior to surgery in the form of a carbohydrate rich clear liquid improves patient nausea and discomfort over preoperative water hydration or a prolonged fasting state.76 It may also have further benefits over low carbohydrate clear liquid beverages or fasting by changing the overnight fasting state to a fed state and thus altering glu-cose, protein, and fat metabolism by increasing postoperative insulin sensitivity.77-79 Furthermore, in patients whose expected length of stay is greater than 2 days, there is a significant length of stay reduction in patients that receive preoperative carbohy-drate loading.80 The best carbohydrate loading drink is unclear as studies are heterogeneous and the carbohydrate content is variable. Nevertheless, the carbohydrate drink should be hypo-osmolar for faster gastric emptying, result in a fed state with full glycogen stores, and reduce postoperative insulin resis-tance. The most commonly studied carbohydrate loading drink includes 100 g of carbohydrate the evening prior and 50 g of carbohydrate 2 to 3 hours prior to surgery.Intraoperative ConsiderationsSurgical Considerations. Prevention of surgical site infection consists of the use of mechanical, chemical, and/or antimicro-bial modalities. Mechanical and chemical methods include the use of patient bathing preoperatively and skin preparation with betadine, chlorhexidine, or similar chemical in order to limit the microbial content of the skin. Additionally, the appropriate use of antimicrobial prophylaxis should be employed and follow guidelines specific to the type of surgery and for duration of antibiotic prophylactic administration.Minimally invasive surgical approaches should be con-sidered as minimally invasive techniques have demonstrated improved outcomes across surgical specialties, including reduc-tions in length of stay and postoperative complications. Addi-tionally, the use of catheters or drains should be limited unless necessary, as these hinder the patient’s perceived ability for ambulation.81-84Hypothermia Prevention. Hypothermia is a common periop-erative problem. Up to 90% of all patients undergoing elective surgery suffer from inadvertent postoperative hypothermia.85,86 Those at highest risk include patients over the age of 60 years, and/or patients that have malnourishment, preexisting hypo-thermia, preexisting medical comorbidities that impair body temperature regulation (including advanced diabetes with neu-ropathy and hypothyroidism), who are undergoing general anes-thesia, and who are undergoing a major long surgery. Further, in patients who experience hypothermia, surgical complications are increased, including impaired wound healing, wound infec-tion, pressure ulcers, cardiac disorders including arrhythmia and infarction, as well as increased bleeding requiring blood transfu-sion (Table 50-1).Brunicardi_Ch50_p2113-p2136.indd 211701/03/19 9:39 AM 2118SPECIFIC CONSIDERATIONSPART IITable 50-1Relative risk of elective surgical complications secondary to hypothermia86 RELATIVE RISK95% CONFIDENCE INTERVALSImpaired wound healing3.251.35–7.84Cardiac disorders4.491–20.16Blood transfusion1.331.06–1.66The reasons for hypothermia are multifactorial. Radiation, the transfer of heat by electromagnetic waves through space without a medium, accounts for 50% to 70% of heat loss. Con-vection, the loss of heat through ambient air stream, accounts for 15% to 25% of heat loss. Evaporation accounts for 5% to 20%, and conduction accounts for 3% to 5%.85 Temperature reduction can also be accelerated by cold intravenous fluids, low operating room temperatures, and a decreased thermoregu-latory threshold, which occurs during the administration of gen-eral anesthesia. Further, the ability to compensate for reduction in body temperature is also compromised by muscle relaxation and anesthesia in general, as these processes impair shivering and thermoregulatory vasoconstriction.87 There are steps to take to prevent this hypothermia including active, convective heating using clean, filtered, forced-air warming blankets in patients in the preoperative area (prewarming) and also during anesthesia; thermal insulation; warmer ambient operating room tempera-tures, warmed irrigation solutions during surgery; and warmed infusions and blood products.88-99Venous Thromboembolism Prophylaxis. Venous throm-boembolism (VTE), which includes deep venous thrombosis (DVT) and pulmonary embolism (PE), is the number one cause of potentially preventable death in common but preventable causes of morbidity and mortality in the perioperative patient. Several national quality improvement organizations have cited VTE prophylaxis for patients at risk as a priority for individual physicians and for hospitals because this intervention reduces adverse patient outcomes and hospital costs.Surgical patients have increased risk for VTE due to advanced age, multiple medical comorbidities, prolonged pro-cedure times, the inflammatory and hypercoagulable state of surgery, and immobility. Specific risk factors include major general, vascular, or orthopedic surgery; lower extremity paral-ysis due to spinal cord injury; fracture of the pelvis, hip, or long bones; multiple trauma; cancer; prior VTE; age 40 years and higher; obesity; immobility; oral contraceptive use; hypervis-cosity syndromes; and severe cardiopulmonary disease (prior myocardial infarction, congestive heart failure, chronic obstruc-tive pulmonary disease).Postoperative DVT is usually asymptomatic, and fatal PE can often be the first sign of VTE. DVT occurs after approxi-mately 25% of all major surgeries without prophylaxis, and PE occurs after 7%. Since screening modalities (such as venous duplex imaging) in asymptomatic patients have low sensitivity to detect clot, the best approach is to systematically apply pre-vention strategies to all patients undergoing surgery, with treat-ment choices based on patient-related and procedure-related risks.VTE prophylaxis is therefore an important component in optimal perioperative care and current surgical practice and should be included in all practice guidelines. Appropriate VTE prophylaxis should be given preoperatively, intraopera-tively, and postoperatively based upon current guidelines for the surgery type.100 Examples of nonpharmacologic methods include early ambulation, graduated compression stockings, and intermittent pneumatic compression devices. Pharmaco-logic methods include the use of low dose unfractionated hepa-rin, low molecular weight heparin, and in some case, factor Xa inhibitors.Perioperative Fluid Management. Current and traditional fluid management strategies, which are based on a fixed fluid requirement per patient per case, have failed to improve out-comes. More modern goal-directed therapy (GDT) intravenous fluid approaches rely on the use of advanced medical devices, including esophageal Doppler monitors and other noninvasive cardiac output or bioimpedence models to determine whether or not patients are “fluid responsive” during surgery.101 In the setting of a normal ejection fraction, fluid is only administered when the expectation is that cardiac output will increase, and vasopressors are utilized if the aforementioned devices show fluid will not increase cardiac output. Excess fluid in certain general surgical cases can cause ileus and bowel edema, and in cardiac cases, it can cause hemodilution. Patients random-ized to restricted and liberal fluid resuscitation strategies found a clear linear relationship between total fluids administered (and weight gain) and complications following colorectal surgery including pulmonary edema and tissue-healing complications.102 Further multiple studies exist demonstrating fewer complica-tions with normovolemia than with liberal strategies of fluid resuscitation.102-108It must be understood that goal-directed therapy does, in no way, mean reduction in fluid administration. For some pro-cedures, it may be necessary to administer more than anticipated fluid volumes (orthopedics), while for others, the opposite may be true (abdominal). Normovolemia is important to maintain perfusion without volume overload. Thus, the idea behind goal-directed therapy is to maintain zero fluid balance coupled with minimal weight gain or loss. Hypovolemia is associated with reduced circulating blood volume, decreased renal perfusion, altered coagulation, microcirculation compromise, and endothe-lial dysfunction, among other processes. Hypervolemia is asso-ciated with splanchnic edema, decreased pulmonary gas exchange secondary to pulmonary edema, impaired wound heal-ing, anastomotic dehiscence, decreased mobility, altered coagu-lation, and endothelial dysfunction, amidst others processes109 (Fig. 50-4). Esophageal Doppler is a mode by which ultrasound is used to monitor and guide intraoperative fluid management has been used quite frequently. The use of this device for fluid optimi-zation has been studied in several randomized controlled trials or meta-analyses, all of which showed a significant reduction in length of stay of up to 4 days.110,111 Reductions in length of stay have been seen in gastrointestinal surgery, trauma surgery, urologic surgery, and also the orthopedic population.112-116 Alter-native devices such as arterial waveform analyzers and pulse oximeter waveform analyzers have been studied and may be promising with the added advantage of lower cost over esopha-geal Doppler.Postoperatively, once the patient is adequately tolerat-ing at least a liquid diet and maintaining adequate hydration, 3Brunicardi_Ch50_p2113-p2136.indd 211801/03/19 9:39 AM 2119OPTIMIZING PERIOPERATIVE CARE: ENHANCED RECOVERY AND CHINESE MEDICINECHAPTER 50supplemental intravenous fluids should be minimized or ter-minated. The use of Dopplers or other volume status wave form analyzers have not been studied in the nonventilated postoperative patient and therefore cannot be used to reli-ably assess volume status. Clinical judgment based on patient factors, surgery type, and the clinical findings should be considered in the decision to continue intravenous flu-ids. However, once the patient is able to maintain adequate hydration, supplemental fluids should be used judiciously to limit fluid overload, tissue and lower extremity edema, and the constraints that the intravenous medication pole has upon patient-initiated ambulation.It is not enough to have normovolemia, but one must also consider the type of fluid that should be used for resuscitation. From a recent Cochrane review, there is no evidence that col-loids are superior to crystalloid for resuscitation in patients.117 Therefore, crystalloid fluids should generally be the primary intravenous fluid during the perioperative course. In cardiac sur-gery, the utilization of 0.9% normal saline solution was associ-ated with hyperchloremia and poor postoperative outcomes, including higher length of stay and increased mortality.118 Fur-ther, a more balanced crystalloid, such as Plasma-Lyte, was associated with improved outcomes in 22,851 surgical patients.119 In this study, there was a 2.05 odds ratio predictor of mortality with normal saline. Other complications such as acute kidney injury, gastrointestinal complications, major hemor-rhage, and major infection were also increased in the group of patients that were hyperchloremic after normal saline adminis-tration. Based on such evidence, it would seem prudent to pro-ceed with a more balanced solution, such as PlasmaLyte, to reduce complications. Perioperative Pain ManagementAccording to the International Association for the Study of Pain (IASP) Taxonomy, the definition of pain is described as “an unpleasant sensory and emotional experience associated with actual or potential tissue damage, or described in terms of such damage.”120 There are two important implications of this: pain is completely subjective in that it is whatever the patient says it is, and patients cannot experience pain while unconscious.121 This has some effects on how the anesthesiologist treats sympathetic stimulation in the operating room. Heretofore, elevations in heart rate and blood pressure were treated with opioid medica-tions, as these sympathetic markers were considered surrogates for patients experiencing pain while under general anesthesia. However, other medications can be used to treat the sympa-thetic response to surgery such as β-blockers and deepening the anesthesia without administering opioid medications while the patient is unable to experience the pain.The mainstay of alleviating pain has historically relied almost exclusively on opioids, especially with the usage of patient controlled analgesia devices (PCAs). However, limiting opioids in the perioperative setting is of substantial benefit. Opi-oids, in fact, reduce pain immediately after administration. However, they also worsen pain scores after they wear off, increase postoperative opioid requirements, increase nausea and vomiting, cause respiratory depression, reduce gastrointestinal motility, worsen urinary retention, induce endocrine dysfunc-tion, and suppress the immune system.87 There have been a number of randomized controlled trials that have shown that as opioid administration increases, pain scores and postoperative nausea and vomiting increase.121-129 Exposure to any fentanyl or opioid in the operating room worsens postoperative pain scores and should therefore be limited or omitted.122,123,127,129 Opioid containing PCAs have been the standard for opioid administra-tion because of their safety and efficacy in patients to control the administration of opioids. However, because a PCA only offers opioid medication, there is the possibility that the desired analgesic effect will be associated with the aforemen-tioned complications of opioids. Despite their disadvantages, opioids are still quite useful in the treatment of pain. However, the ERAS protocols focus on opioids as a single component of a comprehensive pain relief strategy, not as the mainstay for treatment. Instead, multimodal 45Complications andpostoperative morbidityNormovolemiaVolume statusHypervolemia consequences• Hyperchloremic acidosis• Pulmonary edema• Impaired wound healing• Anastamotic dehiscence• Decreased tissue perfusion• Altered coagulation• Multiple organ failureHypovolemia consequences• Reduced intravascular volume• Hypotension• Endothelial dysfunction• Altered coagulation• Decreased renal blood flow• HypoxiaFigure 50-4. Volume status affects postoperative morbidity. (Reproduced with permission from Francis N, Kennedy RH, Ljungqvist O, et al: Manual of Fast Track Recovery for Colorectal Surgery. London: Springer-Verlag; 2012.)Brunicardi_Ch50_p2113-p2136.indd 211901/03/19 9:39 AM 2120SPECIFIC CONSIDERATIONSPART IITable 50-2Analgesic medications ADVANTAGESDISADVANTAGESOpioids141Relieve pain immediately after administrationWorsen pain scores after opioids wear offIncrease postoperative opioid requirementsCentral Nervous System: Euphoria/dysphoria Sedation Respiratory depression Nausea/vomiting Cough suppressionCardiovascular: Bradycardia/tachycardia Arterial/venous dilationRenal: Antidiuretic Increased sodium resorption Urinary retentionGastrointestinal: Decreased motility Constipation Biliary colicEndocrine: Stimulates release of antidiuretic hormone Stimulates release of prolactin Stimulates release of somatotropin Decreases luteinizing hormoneImmunologic: Decreased immune system function Cancer growthNSAIDs142Reduce inflammationSynergistic effect with opioidsRenal insufficiencyIncreased bleedingDelay healingAdverse cardiovascular riskLocal anesthetics140Opioid-sparing effectDecrease PONVReduce ileusPossible anticancer effectCardiac toxicityCentral nervous system toxicityKetamine136,137,143Opioid-sparing effectMay prevent opioid-induced hyperalgesia and chronic pain syndromesDysphoriaHallucinationsGabapentinoids130-135Opioid-sparing effectReduce opioid side effectsReduce postoperative painVisual disturbancesanalgesia should be emphasized by utilizing multiple medi-cations to limit postoperative pain and therefore opioid use. Multimodal analgesia mitigates the side effects of opioids by opioid reduction and enhances pain management. Preoperative and postoperative administration of acetaminophen and cele-coxib or other nonsteroidal anti-inflammatory drugs, as well as gabapentin have been shown to be efficacious.130-135 Intra-operatively, the utilization of ketamine, lidocaine, and magne-sium, act as adjunctive measures to limit pain and have been utilized to reduce the utilization of opioids in the postoperative period.136-140 Administration of lidocaine and ketamine can also be continued in the postoperative setting (Table 50-2).Neuraxial opioid analgesia, the administration of opioids through either the intrathecal or epidural route, can be accom-plished by either a single shot (both spinal and epidural) or catheter-based therapy (epidural). The use of opioids by this route was shown to have improved pain relief when compared to preoperative oral, IV, or intramuscular morphine.144 Further, neuraxial opioid analgesia is associated with lower postopera-tive pain scores in adults and children who undergo surgery.145 Neuraxial analgesia can also be performed with local anesthetic only. Finally, the American Pain Society (APS) recommends the utilization of such postoperative analgesic methods in patients who undergo major surgeries, including thoracic and abdominal Brunicardi_Ch50_p2113-p2136.indd 212001/03/19 9:39 AM 2121OPTIMIZING PERIOPERATIVE CARE: ENHANCED RECOVERY AND CHINESE MEDICINECHAPTER 50procedures, cesarean sections, and hip and lower-extremity sur-geries; this is especially recommended for patients at risk for cardiopulmonary complications or prolonged ileus.145Multimodal analgesia can also include regional analgesic techniques such as peripheral nerve blocks, paravertebral blocks, plexus blocks, and local infiltration, which can reduce postoperative physiological stress and decrease complications associated with surgery as part of a regimen.146 These techniques have been shown to reduce the amount of opioids required for analgesia and also have been shown to reduce the adverse events seen with epidural local anesthetics (such as urinary reten-tion and hypotension) and/or opioid-containing PCAs. Postoperative Nausea and Vomiting PreventionPostoperative nausea and vomiting (PONV) is very common and can cause significant distress to patients, with the incidence of vomiting at approximately 30%, nausea at 50%, and the com-bination of PONV as high as 80%. All result in poor patient satisfaction, increased recovery room length of stay, and higher costs to the health-care system.147-152 This could further increase the time to first feeding, which in turn may prolong ileus and/or hospital stay.Dr. Gan and colleagues developed a consensus guideline for the management of nausea and vomiting and details the risk and possible choices for the treatment of PONV.153 Risk factors include female sex, history of PONV or motion sick-ness, nonsmoking, younger age, general versus regional anes-thesia, use of volatile anesthetics and nitrous oxide, postoperative opioids, duration of anesthesia, and the type of surgery including cholecystectomy, laparoscopy, gynecologi-cal, and strabismus. The strategies for avoiding PONV include the avoidance of general anesthesia, the use of totally intravenous anesthesia, avoidance of nitrous oxide and volatile agents, minimizing intraoperative and postoperative opioids, and adequate hydration.150,152,154-159 The medications to prevent, abort, and reduce PONV include perphenazine, aprepitant, dexamethasone, scopolamine, dolasetron, granisetron, and ondansetron, among others.160-164 PONV should be tar-geted before it occurs for optimal prevention (Fig. 50-5). Early Nutrition and Postoperative Ileus PreventionPostoperative ileus is the most common cause of prolonged hospital stay and readmissions following surgery on the diges-tive tract, occurring in up to 19% of cases.165 Not only is this adverse to the individual patient clinically, this also results in doubling of the total cost of the index hospital stay and thus carries a tremendous socioeconomic impact globally.166 Numer-ous risk factors contribute to postoperative ileus and include open surgery, increased surgery length of time, blood transfu-sion, fasting, fluid overload, opioids, postoperative nausea and vomiting, and other pharmacological agents. While some risk factors are unavoidable in certain patients, others are modifi-able, and therefore minimization of the risk of postoperative ileus is achievable.Nasogastric tubes (NGTs) were previously used prophy-lactically to prevent ileus, limit distension on the gastrointestinal anastomosis, as well as to prevent pulmonary complications. However, NGT use actually delays return of gastrointesti-nal activity and increases pulmonary complications without preventing anastomotic leaks in numerous types of surgery, including gastroduodenal, biliary, trauma, and esophageal.167-169 Therefore, the routine use of NGTs for prophylaxis should be avoided.Addressing the numerous risk factors for postoperative ileus has a benefit on the reduction of the incidence of postoper-ative ileus. For example, mitigating the surgical trauma through 67Risk Factors:History of PONV/motion sicknessNonsmokerFemale sexPostoperative opioidsEmetogenic surgeryLow:Choose 1 treatmentMedium/High:Choose 2 treatmentsTotally intravenous anesthesiaRegional anesthesiaDexamethasoneAntidopaminergic5-HT3 antagonistDimenhydrinateScopolaminePatientPerphenazineFigure 50-5. Risk factors of and treatment options for postoperative nausea and vomiting. PONV = postoperative nausea and vomiting.Brunicardi_Ch50_p2113-p2136.indd 212101/03/19 9:39 AM 2122SPECIFIC CONSIDERATIONSPART IIminimally invasive surgery and meticulous surgery with mini-mal blood loss reduces postoperative ileus, either directly by limiting the inflammatory response with smaller incisions or indirectly through reduced opioid use.170-174 Anesthetic tech-nique can also aid in prevention of postoperative nausea and vomiting, which in turn reduces the need for parenteral opioids, a known risk factor for postoperative ileus. Multimodal pain strategies and neuraxial blocks reduce opioid use and therefore minimize nausea, improve early enteral nutrition, limit intra-venous fluid administration, and improve ambulation. Main-tenance of normovolemia in the perioperative setting should be achieved as fluid overload and dehydration both negatively affect return of bowel function, length of stay, and complica-tions.105,106,175 Clearly, each facet of the perioperative care pro-cess is intricately intertwined to the next and has implications in total body homeostasis.Other measures may also assist in the prevention of post-operative ileus; however, the role of each in the setting of an ERAS pathway is unclear. Chewing gum is hypothesized to reduce postoperative ileus by stimulating the cephalovagal reflex and is considered a form of sham feeding. Prior to the introduction of ERAS, the use of chewing gum in multiple abdominal surgeries demonstrated faster intestinal recovery with variable impact on length of stay.176-178 Following the use of ERAS and associated early enteral feeding, the benefit of chewing gum is less clear.179,180 Alvimopan is a mu opioid recep-tor antagonist that is administered prior to surgery and twice daily postoperatively. Pooled analysis of phase III trials dem-onstrated a reduction in postoperative NGT use, faster return of bowel function, and earlier discharge by 0.7 days.181 However, following ERAS implementation, small studies demonstrate a reduction in ileus and length of stay with the use of alvimopan in open surgeries without a benefit in laparoscopic surgery.182-184MobilizationThough no metric of mobilization has been clearly defined, early mobilization following surgery is an important compo-nent of ERAS that accelerates the return to baseline functional status. Prolonged postoperative bedrest leads to decondition-ing, increased deep venous thrombosis risk, and loss of muscle mass. Deterioration of mobility and activities of daily living can be seen in older patients after only 2 days of hospitalization.185 Therefore, preoperative encouragement of an exercise program and perioperative mobilization can have dramatic impacts on not only the elderly but all patients undergoing surgery. Patients that begin a preoperative exercise program are more active post-operatively and have a faster return to baseline exercise capacity when compared to patients undergoing a postoperative exercise program.186 As patients in an ERAS program are directed to spend time out of bed and to ambulate, early mobilization is therefore encouraged. Many other facets of ERAS will assist in this early mobilization: postoperative nausea prevention, limit-ing drain use, and improved pain control. Setting preoperative expectations of mobility through patient education in the clinic setting and postoperative nursing unit engagement in promot-ing mobility provide the proper setting for improved patient compliance with early and frequent mobilization. However, compliance with this is highly variable and difficult to track and may be hindered if pain in inadequately controlled or if the patient is tethered to devices such as drains, catheters, and IVs. As with other components of ERAS, engagement of all provid-ers of patient care from outpatient nursing, to inpatient nursing, physicians, and physical therapists, will improve compliance not only with mobility but often with other components as well. Reinforcement of expectations can be achieved with preopera-tive educational pamphlets, postoperative daily task lists, mobil-ity logs, and pedometers.ERAS in CRSAs the initial development of ERAS pathways occurred in colon surgery patients, the largest preponderance of data exists in this surgical specialty with the first ERAS guidelines developed in 2012 after many studies demonstrated positive outcomes apply-ing the basic tenets of ERAS surgery.81 In 1997, Henrik Kehlet published the initial series of patients, applying novel periopera-tive care strategies to colon resection patients.2,3 Following this, several groups also applied these principles to colon resection patients. These studies demonstrated that the principles of early mobilization, early feeding, and optimized intravenous fluid administration resulted in patients tolerating a diet sooner, faster return of bowel function, and earlier discharge.187-189 Further-more, these studies elucidated reduction in complications such as urinary tract infections, ileus, and cardiopulmonary compli-cations. Nygren et al also demonstrated that muscle strength and lung function were less reduced after colon resection within an enhanced recovery protocol compared to traditional periopera-tive care.187 Additionally, as ERAS is expected to diminish the metabolic and hormonal stress response to surgery, attenuation of TNF-α, IL-1β, IL-6, and IFG-γ occurred after ERAS cases when compared to traditional perioperative care, and cortisol levels were not found to increase immediately postoperatively in ERAS, while those with traditional perioperative care experi-enced immediate and sustained cortisol elevation.190Larger series of patients followed with Delaney et al pub-lishing a single institutional experience of 1000 consecutive laparoscopic colectomy patients with short length of stay and low readmission and mortality rates.191 The protocol was further applied to rectal surgery with success.187,192 Meta-analyses and systematic reviews demonstrate less opioid use, shorter length of stay, decreased morbidity, and no increase in readmission rates for laparoscopic or open colon or rectal resections when an ERAS protocol is utilized.193-197 Several groups have even discharged patients in as little as 24 hours following colon resec-tion, with Gignoux et al even discharging patients on the same day.198-200 ERAS can also be applied to octogenarian patients with compliance to the protocols and with no increased readmis-sion or mortality rates.201 Also, patients with diverting stomas can benefit from ERAS protocols, though diverting ileostomy may slightly delay discharge over patients with no ileostomy.202Adherence to the numerous tenets of ERAS is inversely related to length of stay postoperatively in colorectal sur-gery.203,204 When compliance with ERAS measures is lower, length of stay is longer. The strongest predictors for shorter duration of stay include preoperative carbohydrate loading, no nasogastric tube, early mobilization, early oral nutrition, totally intravenous anesthesia, early removal of urinary catheter, and the use of nonopioid analgesia. Predictors for deviation from an ERAS program and thus resultant longer length of stay include pathologic diagnosis, intraoperative complications, high blood loss, surgery length, lack of mobilization, emesis, persistent use of intravenous fluids, reinsertion of urinary catheter, and poor pain control.205-208 Though readmissions are no higher than traditional perioperative care, several factors have been impli-cated in readmission, including poor ERAS compliance and Brunicardi_Ch50_p2113-p2136.indd 212201/03/19 9:39 AM 2123OPTIMIZING PERIOPERATIVE CARE: ENHANCED RECOVERY AND CHINESE MEDICINECHAPTER 50preoperative neoadjuvant chemoradiation.209,210 Predictive tools using artificial neural networks may assist in clinical decision-making.209 The most common reasons for readmission include bowel obstruction and skin and soft tissue infection. While patient and quality outcomes are clearly important, the added benefit of cost savings has been demonstrated. Surgery using the tenets of ERAS is both less costly for direct and indirect costs to the hospital and effective.211 Furthermore, patients in an ERAS program returned to work faster and had less caregiver burden, resulting in huge indirect savings as well.6ERAS in Hepatopancreaticobiliary SurgeryAn initial experience applying an ERAS protocol in 61 con-secutive patients undergoing liver resection demonstrated 92% of patients tolerating a diet on postoperative day 1, a reduction in length of stay from 8 to 6 days, and no increased readmis-sions or morbidity.212 A subsequent randomized trial in patients undergoing open major liver resection demonstrated a length of stay reduction from 7 to 4 days with a decrease in medically related postoperative complications and no increase in surgi-cal complications or readmission; ERAS patients also reported improved quality of life over controls.213 Several meta-analyses have similarly supported the use of ERAS protocols in liver surgery, citing reduced morbidity, hospital stays, cost, and time to recovery of bowel function without increasing mortality or readmission rates.214-216 When adherence to all elements of an ERAS protocol for liver resection was less, hospital length of stay was longer.217In 2012, the ERAS Society published recommendations for patients undergoing pancreaticoduodenectomy after several studies published early outcomes in this surgical population.82 Patients undergoing pancreaticoduodenectomy often have high rates of delayed gastric emptying; the use of ERAS has reduced the incidence of delayed gastric emptying by nearly half, thus allowing earlier feeding in this complex patient population.218,219 Additionally, multiple prospective cohort or retrospective stud-ies have shown that ERAS protocols offer significant benefit to patients undergoing both distal pancreatectomy and pancre-aticoduodenectomy with reduced hospital stay and complica-tions.220-226 Several meta-analyses or systematic reviews have confirmed shorter length of stays, decreased complications, and lower cost with ERAS protocols.227-230 Furthermore, the use of ERAS protocols in elderly patients undergoing pancreaticoduo-denectomy continue to show improved outcomes in length of stay and morbidity, showing that ERAS protocols allow this more fragile patient population to recover faster.231,232ERAS in Gastrectomy and EsophagectomyPatients undergoing foregut surgery have notoriously been sub-jected to prolonged periods of nasogastric tube decompression and resultant starvation while surgical dogma dictated this fast-ing time diminished the risk of complications from anastomotic leak. Nevertheless, more liberal removal of the nasogastric tube and limited fasting, as components of ERAS protocols, have demonstrated improved recovery and outcomes. Randomized controlled trials demonstrate that removal of the nasogastric tube in the operating room and early feeding, as components in an ERAS program, result in shorter length of stay, fewer grade III or higher postoperative complications, and faster return to baseline weight and functional status.233,234 Multiple nonran-domized studies and meta-analyses verify reduction in length of stay and no increase in complications.235-238 In 2014, consen-sus guidelines for ERAS after gastrectomy were published, and these include no routine use of nasogastric decompression, early feeding within the first postoperative day, and early consider-ation for nutritional support if the patient is malnourished or unable to maintain at least 60% of caloric requirements.239Esophagectomy surgery is notoriously complicated and fraught with complications secondary to multiple factors includ-ing surgical complexity and medical comorbidity. Postoperative management is governed by the idiosyncrasies of the operating surgeon more so than many other specialties and therefore het-erogeneous. While studies of ERAS in gastrectomy suggest no routine use of nasogastric tubes and include early feeding, most ERAS programs for esophagectomy encompass all components not related to feeding, but prolonged nasogastric decompression remains.240 Many of these patients, however, do receive early enteral nutrition through the use of jejunostomy tubes com-monly placed at the time of resection. When defined protocols are followed in this cohort of patients, length of stay is reduced, and complications and readmissions are, at a minimum, not increased.241-243 Systematic reviews demonstrate a reduction in length of stay, anastomotic leak, and pulmonary complications without increased mortality or readmission.244,245ERAS in Bariatric SurgeryBariatric surgeons have applied clinical pathways to both the preoperative and postoperative periods for many years, which have resulted in improved outcomes. The adoption of ERAS protocols in these clinical pathways has offered further success for these patients. A randomized trial for laparoscopic sleeve gastrectomy demonstrated a reduced length of stay to 1 day post-operatively in ERAS patients, and others have also discharged patients on postoperative day 1 following Roux-en-Y gastric bypass.246-248 Furthermore, earlier discharge of patients on post-operative day 1 has not been demonstrated to increase resource utilization, with no increase in patient phone calls, emergency department visits, or readmissions.249 A meta-analysis confirms success of ERAS in bariatric surgery with reduction of length of stay without increase in complication or complication sever-ity, while a second meta-analysis demonstrates an increase in minor complications without increasing patient morbidity.250,251 Following a thorough review of the literature supporting its use, the ERAS Society published guidelines for ERAS bariatric pro-tocols in 2016.84ERAS in Other Surgical SpecialtiesThough ERAS has been applied more broadly to complex abdominal surgery, there is surprising little data in its use in large ventral hernia repair and other abdominal wall reconstruc-tive techniques. Three studies report experience in open large ventral hernia repair with varying techniques of abdominal wall reconstruction including myofascial release.252-254 Each study cites faster return of gastrointestinal function and reduction in length of stay by up to 2.5 days. Furthermore, there were no increases in readmission, postoperative complications, or reop-eration. Though no long-term follow-up, there is no report that early feeding results in intestinal compromise from “tight” clo-sure or early hernia recurrence. In fact, as ERAS reduces the incidence of postoperative vomiting and ileus, it is likely very beneficial for this patient population.ERAS has been introduced to non–general surgery subspe-cialties as well. Complex urological procedures such as radical cystectomy have trialed ERAS over the last decade with favor-able results. In this patient population, length of stay was reduced, and complications were similar to or reduced when Brunicardi_Ch50_p2113-p2136.indd 212301/03/19 9:39 AM 2124SPECIFIC CONSIDERATIONSPART IIcompared to baseline controls.255-257 Similarly, ERAS has been applied to both minimally invasive and open complex cytore-ductive gynecological oncology surgery with favorable results for earlier discharge and decreased pain.258-263 Total joint replacement surgery in orthopedics has also used ERAS with improved early mobility, a significant length of stay reduc-tion, and decreased morbidity.264,265 Setting Up an ERAS ProgramThe successful implementation of an enhanced recovery pro-gram depends heavily upon cultural change and excellent orga-nizational behavior. As the ERAS program encompasses so many facets of patient care, the implementation team should not only include surgeons and anesthesiologists but also inpa-tient and outpatient nurses, pharmacists, information technology specialists, compliance officers, and hospital administration.Initial strategy for ERAS implementation should define the scope of practice change by identifying the current state and the goal state of care. Protocol content can be discussed in a small group of engaged stakeholders. Once the protocol ele-ments are defined, all stakeholders should review and discuss the protocol in detail in order to identify barriers to implementa-tion, identify solutions to these barriers, and finalize the proto-col. This allows for all stakeholders to remain engaged and have ownership in the protocol. Appropriate informational resources for hospital and office staff education are created in order to have a thorough and successful educational campaign. Patient informational resources should also be developed in order to set clear expectations throughout the perioperative process. Addi-tionally, and importantly, standardized order sets are also devel-oped to ensure that all components of an ERAS program have little variation in order to improve compliance. A final imple-mentation date is defined after coordinating that all stakeholders are indeed ready for launch. Appropriate educational campaigns are performed in a timely fashion prior to final implementation to outpatient office staff, inpatient units, preoperative and post-operative care units, operating room personnel and physicians, and midlevel providers and trainees (Fig. 50-6).Compliance and auditing should be done with relative frequency in the beginning, from weekly to biweekly and then monthly. Team meetings with all stakeholders present allow the team to address any issues in timely fashion with a mul-tidisciplinary approach and thus upholds accountability. The frequency of checkpoint meetings can be reduced over time. Sharing data of successes and failures keeps the team engaged. It is also recommended that a financial team be employed. The financial savings after adoption of an ERAS protocol can be substantial from reduction in length of stay, medication use, and resource utilization. Ideally, a portion of the cost savings should be funneled back into the ERAS program in order to ensure program maintenance and compliance and also to assist with expansion to other service lines or patient care improvement projects.TRADITIONAL CHINESE MEDICINE IN SURGICAL PATIENTSHistory of Traditional Chinese MedicineTraditional Chinese medicine is one of China’s outstanding national cultural heritages and the quintessence of China, shar-ing a deep history and common homology with the Chinese culture.266 It is derived from the rich experience and theoretical knowledge that Chinese people have used to combat disease for thousands of years. The achievements of traditional Chinese medicine caught the attention of the world because it examines each function of the human organism and adjusts those func-tions to achieve ultimate balance.Traditional Chinese medicine is the oldest medicine in China. It is a medical system with unique theory, style, diagno-ses, and treatments, which were gradually formed throughout the historical medical practice of the Chinese nation. Its devel-opment not only depended on the practice but also resulted from the systemic mode of thinking and Chinese philosophy of protecting life shape. Yet, it is a traditional subject that still stands in the modern world of science.Traditional Chinese medicine theory mainly resulted from the summary of practice and was continuously enriched and developed in practice. As early as 2000 years ago, Huang Di Nei Jing wrote the earliest existing theory of traditional Chinese medicine in China, and it summarized the treatment experience and medical theory to that time. Combining the achievements of other natural science branches and simple materialism and dialectical thinking of the Chinese culture, Huang Di Nei Jing comprehensively expounded the knowledge of human anatomy, physiology, and pathology and also stated the diagnosis, treat-ment, and prevention of disease, thus founding the preliminary theoretical basis of traditional Chinese medicine.Based on herbal remedies of primitive people, Shen Nong Ben Cao was the earliest existing monograph on herbal pharma-cology in China.267 It summed the study of herbology to date, including 365 kinds of drugs until the Han Dynasty. Long-term clinical practice and modern scientific research show that the effects of the drugs described in the book are mostly correct.In the third century, the famous physician Zhongjing Zhang of the Eastern Han Dynasty delved into the classical medical books such as Su Wen, Zhen Jing, and Nan Jing and extensively collected the effective prescriptions, combining this with his own clinical experience. He published a famous book about typhoid fever, Shang Han Bing Za Lun. This book established the theoretical system and treatment principles that applied dialectical therapy of Chinese medicine and influenced the future of traditional Chinese medicine.In 610 a.d., Yuanfang Chao et al wrote Treatise on the Etiology of Various Diseases, which is the earliest exiting mono-graph on causes of symptomatology in China. This book also recorded the intestinal anastomosis, abortion, tooth extraction, and other operations, indicating the breadth of surgery practiced at that time. Subsequently, the ancient Chinese government in 659 a.d. issued Tang Xiu Ben Cao; it was not only the first phar-macopoeia of ancient China but also the first national pharma-copoeia of the world. It was published 883 years earlier than the Nuremberg Pharmacopoeia, which was issued by the European Nuremberg government in 1542 a.d.The Tang Dynasty physician Simiao Sun authored Bei Ji Qian Jin Yao Fang and Qian Jin Yi Fang. In these two books, clinical subjects, acupuncture, dietary therapy, disease preven-tion, and life preservation were discussed. These were an out-standing achievement of the time, especially in the prevention and treatment of nutritional deficiency diseases.Between the 12th and 14th centuries, i.e., the Jin and Yuan eras of China, several new Chinese medicine theories emerged. There were four representative scholars. Wansu Liu (1120–1200 a.d.) thought the symptoms of shanghan (exogenous febrile disease) were related to “excessive internal heat,” so the herbal 8Brunicardi_Ch50_p2113-p2136.indd 212401/03/19 9:39 AM 2125OPTIMIZING PERIOPERATIVE CARE: ENHANCED RECOVERY AND CHINESE MEDICINECHAPTER 50Figure 50-6. Implementation process of an enhanced recovery after surgery pathway. ERAS = enhanced recovery after surgery; CRNA = certified registered nurse anesthetist; NP = nurse practitioner; PA = physician assistant; IT = information technology; PACU = postanesthesia care unit; APP = advanced practice provider; LOS = length of stay; PCA = patient-controlled analgesia.Define ERAS teamSite workflow meetingsCommunication & trainingImplementation & initial monitoringDefine site-specific teamleaders:• Anesthesiologist• Surgeon• Quality nurse coordinatorDefine implementation teammembers, including:Anesthesiologists, surgeons,nurses, CRNAs, NPs, PAs,fellows, residents, ITIntro team meeting• General ERAS overview with core leadership teamDiscuss protocol logistics and workflow:• Site meetings to discuss logistics of implementing ERASEscalation of site issues tocore team• Site leadership to escalate issues to leadership teamImplementation planning:• Site leadership team to ensure all workflow issues have been addressed and implementation date plannedProtocol & order set training:• Clinic• Pre-Op nurses• PACU nurses & anesthesia• Floor nurses• APPsMonthly monitoring of keyoutcomes × 3 mos(minimum):Including: Overall LOS, Post-OpLOS, 30-day readmission andPCA utilization, and othersMonthly meeting × 3 mos(minimum):• Discussion of initialimplementation issues• Include all members of site-specific implementation teamImplement protocol &order set go-liveMonthly checkpointmeeting with ERASleadershipGo-live communication:ERAS site coordinator tocommunicate go-live date forprotocol & order set to siteteam and ERAS projectmanagerGo-live date must be givento ERAS PM at least 1month prior to go-liveERAS nurse educator toliaise with site championsERAS order set to beimplemented up to twoweeks prior to theprotocol for order entryERAS leadership teamto provide outcomesto ERAS site teamBrunicardi_Ch50_p2113-p2136.indd 212501/03/19 9:39 AM 2126SPECIFIC CONSIDERATIONSPART IIcharacteristics of cold and cool were used in treatment, and this was known as the “cold and cool” treatment style. Congzheng Zhang (approximately 1156–1228 a.d.) thought the cause of disease was “exogenous evil” (exogenous pathogenic factor) invading the human body; therefore, the treatment focused on “eliminating evil,” through the diaphoresis, emetic, and/or purgative methods, which were known as the “offensive pre-cipitation” style. Dongyuan Li (1180–1251 a.d.) proposed that “internal injury of viscera causes various diseases,” and pyretic tonification of the spleen and stomach was emphasized in the treat-ment, known as the “invigorating the spleen” style. Zhenheng Zhu (1281–1358 a.d.) thought “yang was always excessive, while yin was always insufficient” in the body, so the treatment was focused on nourishing yin and cutting down heat, which was known as the “nourishing yin” style.In approximately the 11th century, the Chinese began to use human pox vesicle exposure as vaccination to prevent smallpox and thus pioneered the field of medical immunology and vaccination. In the 17th to 19th centuries, due to the epi-demics of infectious diseases, the seasonal febrile disease theory developed. This theory broke the traditional Chinese medicine long-term conception that the pathogens invaded from the sur-face to the inside of the body. In the mid-17th century when bacteriology had not yet appeared, this was undoubtedly a great pioneering work and laid the groundwork for the epidemiology of the spread of disease.In the period from the Opium War (1838–1842 a.d.) to the founding of the People’s Republic of China in 1949 a.d., Western medicine was introduced to the continent of China. However, Western medicine and Chinese medicine theories were unique to each other. There was almost no interchange between them, either in theory or in practice; yet together, they formed a unique and relatively mature theoretical system. In the 1920s to 1930s, Western medicine proposed abolishing Chinese medicine. At the same time, Chinese medicine did not deny the merits of Western medicine but thought that Chinese medicine was superior to Western medicine. However, there were several advocates to combine the theories who published such works as “Chinese Medicine for Main, Western Medicine for Use,” “Using Their Respective Strengths, Reaching the Same Goal by Different Means,” and “Chinese Medicine Treat Internal Disease, Western Medicine Treat Surgical Disease.”268 In short, the pervasive opinion was to learn from the other’s strong points to make up for one’s deficiencies. This forged the trail for establishing modern Chinese integrative medicine.In the past decade, a series of significant progresses and breakthroughs have been made in the modern study of tradi-tional Chinese medicine theory and its application to clinical practice. For example, acupuncture anesthesia can be used for small splint fixation, and the treatment of acute abdomen inte-grates both traditional Chinese and Western medicine.269 Most lately, Tu Yo Yo’s team found that artemisinin, derived from the wormwood plant, treats malaria, and the team was awarded the Nobel Prize in 2015.Clearly, integration of traditional Chinese medicine with modern science and technology will advance knowledge and treatment. Modern diagnostic instruments and techniques have become auxiliary methods of clinical diagnosis and treatment of traditional Chinese medicine, making up for the deficiency of the traditional “four ways of diagnosis” methods and improv-ing the accuracy and efficiency of traditional Chinese medicine diagnosis and treatment. Thus, modern science and technology’s infiltration, transformation, and integration in all aspects of Chi-nese medicine will be one of the distinctive characteristics of the future development of Chinese medicine.In summary, traditional Chinese medicine and pharmacy are an important part of the splendid culture of the Chinese nation, making outstanding contributions over thousands of years because of its systemic theory, distinctive treatment methods, sig-nificant efficacy, and abundant historical documentation. Modern Chinese medicine includes traditional Chinese medicine and thus offers integrated and superior health service. This integration of Eastern and Western medical ideas and philosophies are important for the future of this modern medical era.270 Preoperative Nutritional OptimizationMany surgical abdominal diseases have a long incubation period before clinical presentation, during which time the patients may develop malnutrition including specific nutrient deficiencies and hypoproteinemia. These comorbidities directly influence the sur-gical treatment and postoperative effect of the patient undergoing an operation. In this setting, some experts advocate the use of parenteral nutrition and other adjunctive nutritional measures. These measures can often improve the patient’s nutritional sta-tus, but they are difficult to popularize because of the high cost of treatment and common complications with parenteral nutrition.In traditional Chinese medicine theory, it is thought that there are a variety of “asthenic symptoms” in patients who need surgical treatment and that applying the treatment principle of “treating deficiency with tonification” improves conditions throughout the body. On the basis of the traditional Chinese medicine theory of the “concept of holism” and “treatment according to syndrome differentiation,” the all nourishing decoction (Shiquan Dabu decoction) and Buzhong Yiqi decoc-tion are used in patients with the “deficiency of vital energy and blood syndrome” before surgery and have achieved good results.271-275 Similar success has been shown with the Shenmai injection and Astragalus injection.276,277 For example, when tra-ditional Chinese medicine is used effectively to treat patients with breast cancer before an operation, it enhances the general body status, improves the patient’s energy, and regulates the liver and kidney functions, which ultimately promotes the suc-cess of the operation and controls progression of the tumor.278,279Bowel Preparation for SurgeryIn gastrointestinal surgery, the method of “purgation and offen-sive precipitation” is used in preparation for the operation. Either Large Chengqi decoction or Seasoning Chengqi decoc-tion significantly increases the gastrointestinal motility and washes the gastrointestinal stagnation to prepare the bowel for surgery. These decoctions also improve visceral blood flow and peritoneal absorption, promote early recovery of postoperative bowel function, and prevent superimposed infection of the intes-tine and the effect of endotoxin.280,281Preoperative Optimization During Sepsis and InfectionDue to infection, endotoxemia, blood loss, and other factors, many critically ill patients will deteriorate or progress to shock. Initial surgery during profound shock may be counterproductive until adequate resuscitation is achieved. In addition to resuscita-tion, blood transfusion, and antimicrobial treatment if indicated for sepsis, the traditional Chinese medicine treatment based on dialectics can help to create a favorable condition for surgery, if indicated.9Brunicardi_Ch50_p2113-p2136.indd 212601/03/19 9:39 AM 2127OPTIMIZING PERIOPERATIVE CARE: ENHANCED RECOVERY AND CHINESE MEDICINECHAPTER 50For traumatic shock and anaphylactic shock patients, the use of flavored pure ginseng decoction supplemented by blood transfusion and other comprehensive antishock measures, can rapidly raise blood pressure and provide a more optimal set-ting for surgical treatment.282 Qingdan decoction and Qingyi decoction, which are composed of herbs to clear away heat and toxins, remove stasis, purge the bowel, and are used to treat acute obstructive suppurative cholangitis and hemorrhagic and/or necrotizing pancreatitis.283-285Perioperative Pain ManagementThe application of traditional Chinese medicine in perioperative pain management is has become more prevalent in recent years. Research of acupuncture for analgesia began in the 1950s in China and has developed into a combined acupuncture and medicine anesthesia that is currently recognized by the medical field.286 During surgery, the combined anesthesia is composed of acupuncture and opioid drugs. Experimental data show that the combined acupuncture anesthesia could reduce the dose of opioid by 50%.287 Acupuncture also helps the management of postoperative pain by enhancing the level of the endogenous opioid, encephalin. Encephalin restrains the pain signal from being transmitted to the central nervous system, blocks the body’s reaction to pain, and increases the pain threshold accord-ingly.288 In several clinical trials, the needed doses of opioid at 8, 24, and 72 hours postoperatively were reduced in acupuncture groups compared to control groups.289 In addition, electroacu-puncture has been demonstrated to be effective at alleviating postoperative pain and assisting in recovery. One randomized controlled trial shows electroacupuncture significantly reduced the dose of fentanyl used, improved the quality of recovery and decreased the incidence of anesthesia related side effects for patients undergoing surgery.290 Postoperative Nausea and Vomiting PreventionPONV is a common complication after surgery. Acupuncture and herbs can be applied to prevent and treat PONV. Acupunc-ture or transcutaneous electroacupuncture improves stress-induced impairment in gastric motility functions, significantly inhibits the frequency of transient lower esophageal sphincter relaxations in response to gastric distention, and suppresses retrograde peristaltic contraction.291-293 In clinical trials, intra-operative P6 acupuncture point (Neiguan acupoint) stimulation during surgery significantly reduces the incidence of PONV over 24 hours, and the efficacy of P6 stimulation is similar to that of commonly used antiemetic drugs in the prevention of PONV.294 Furthermore, electroacupuncture restrains the release of gastrointestinal peptides and consequently relieves PONV with an efficacy comparable to ondansetron.295 Moreover, a randomized, prospective, double-blinded clinical trial shows that auricular acupressure within 24 hours postoperatively has a similar effect to prevent PONV.296Additionally, some Chinese herb decoctions, such as Liu Jun Zi decoction and Cheng Qi decoction, administrated periop-eratively, show possible effectiveness to reduce the severity of PONV and to relieve abdominal distension.297,298Early Nutrition and Postoperative Ileus PreventionIn traditional Chinese medicine, acupuncture and decoctions have a role in the prevention of postoperative ileus. For example, early acupuncture on Zusanli, Shangjuxu, and Xijuxu acupoints, combined with early enteral nutrition, can effectively improve gastrointestinal function and shorten the length of stay after sur-gery.299 In addition, Dachengqi decoction applied to patients after laparotomy improves gastric dysrhythmia, promotes intestinal peristalsis, and enhances gastrointestinal motility.300,301 Further-more, in one randomized trial, the combination of Simo decoc-tion and acupuncture reduces the incidence of postoperative ileus and shortens hospital stay for patient undergoing abdominal sur-gery when compared to the perioperative use of chewing gum.302 Other traditional Chinese medicine methods such as electroacu-puncture combined with Evodia hot compress, confers benefit in postoperative recovery of gastrointestinal function of patients who have undergone abdominal surgery.303Traditional Chinese Medicine in Common Surgical ConditionsColon Surgery. Several traditional Chinese medicine decoc-tions can assist in bowel preparation prior to surgery. For exam-ple, during the bowel cleansing before surgery, Dachengqi decoction can be used to promote bowel peristalsis and evacua-tion, thus preventing contamination during surgery and reducing the risk of postoperative complications of infection. Addition-ally, after colon surgery, traditional Chinese medicine therapies such as acupuncture and decoctions prevent postoperative ileus, reduce the incidence of PONV, and promote the recovery of colon function. As a result, traditional Chinese medicine can shorten the hospital stay after colon surgery.Appendicitis. In general, patients suffering from acute appen-dicitis will undergo appendectomy. Exceptionally, when a case of acute simple appendicitis or a periappendiceal abscess is encountered, Chinese herbs together with antibiotics can serve as an alternative treatment. In early acute simple appendicitis, oral Qinghua decoction can help the appendix infection resolve without surgical management.304 This nonsurgical treatment also can be applied to patients with periappendiceal abscess that is unsuitable for surgery. These Chinese medicine herbs activate blood flow, dissolve stasis, clear heat, and remove toxicity.Biliary Disease. Cholelithiasis is a common disease of the biliary tract that can result in cholecystitis and the possible need for cholecystectomy. Several traditional Chinese medicine herbs can relieve the symptoms of acute cholecystitis and delay the progression of the disease, possibly preventing the need for cholecystectomy. These Chinese medicine herbs are composed of herbs for clearing heat and secreting bile (Qing Re Li Dan), herbs for promoting circulation of Qi and relieving pain (Xing Qi Zhi Tong), and herbs for clearing heat and promoting diure-sis (Qing Re Li Shi). According to different Chinese medicine therapies, the use of these herbs can also be applied to patients postoperatively from abdominal or biliary surgery to adjust bili-ary excretion and/or prevent cholestasis.Unfortunately, severe cholecystitis or cholangitis may progress to liver abscess. When a liver abscess develops, per-cutaneous catheter drainage and Chinese medicine herbs are applied in Chinese medicine practice.305 Generally, in the early stage of abscess, Chinese medicine herbs are used for clearing heat and removing toxicity (Qing Re Jie Du) and for promoting blood circulation and removing blood stasis (Huo Xue Hua Yu). When abscess is evident, Chinese medicine herbs for clearing heat and cooling blood are added.305 The main function of these Chinese medicine herbs is to relieve infection, reduce inflam-mation, and activate intestinal motility in order to evacuate the 10Brunicardi_Ch50_p2113-p2136.indd 212701/03/19 9:39 AM 2128SPECIFIC CONSIDERATIONSPART IItoxicity, reduce the inflammatory response, and thus hasten recovery.Pancreas Surgery. In recent years, the early use of traditional Chinese medicine and enteral nutrition treatment in patients after pancreaticoduodenectomy, can help to hasten recovery in gastrointestinal function, improve nutritional status and immune function, and also reduce postoperative complications. The combined use of total parenteral nutrition and Astragalus injection can improve the nutrition status of patients with obstructive jaundice and improve the immune function of these patients.306 All Nourishing (Shiquan Dabu) decoction has the role of increasing the level of plasma albumin and hemoglobin, which can be used as a recipe in surgical nutrition therapy.307Intestinal Obstruction. Adhesive ileus is the most com-mon type of small intestinal obstruction and also is the kind to which traditional Chinese medicine therapies apply widely. The methods of traditional Chinese medicine treatment include acupuncture, Chinese herbal enema, and gastrointestinal intuba-tion. Acupuncture or transcutaneous electroacupuncture applied to acupoints such as Zusanli point, Neiguan point, Zhongwan point, and Tianshu point has remarkable regulatory effects on gastrointestinal function and can promote relief of obstruction.308 Dachengqi decoction combined with the Chinese medicine herbs for clearing heat and removing toxicity (Qing Re Jie Du), and for promoting blood circulation and removing blood stasis (Huo Xue Hua Yu), can enhance gastrointestinal motility, improve blood circulation of the intestine, reduce intestinal capillary perme-ability, protect the barrier function of the intestinal mucosa, and help inflammatory edema to resolve.309 Additionally, acupunc-ture, Chinese herbal enema, and gastrointestinal intubation can shorten the time of the obstructive event and reduce the length of stay in patients suffering from adhesive intestinal obstruction.310 These methods of traditional Chinese medicine treatment can also be applied to the treatment of postoperative ileus.REFERENCESEntries highlighted in bright blue are key references. 1. Bardram L, Funch-Jensen P, Jensen P, et al. Recovery after lap-aroscopic colonic surgery with epidural analgesia, and early oral nutrition and mobilisation. Lancet. 1995;345:763-764. 2. Kehlet H. Multimodal approach to control postopera-tive pathophysiology and rehabilitation. Br J Anaesth. 1997;78:606-617. 3. Kehlet H, Mogensen T. Hospital stay of 2 days after open sigmoidectomy with a multimodal rehabilitation programme. Br J Surg. 1999;86:227-230. 4. Delaney CP, Fazio VW, Senagore AJ, et al. “Fast track” post-operative management protocol for patients with high co-mor-bidity undergoing complex abdominal and pelvic colorectal surgery. Br J Surg. 2001;88:1533-1538. 5. Nicholson A, Lowe MC, Parker J, et al. Systematic review and meta-analysis of enhanced recovery programmes in surgical patients. Br J Surg. 2014;101:172-188. 6. Lee L, Mata J, Ghitulescu GA, et al. Cost-effectiveness of enhanced recovery versus conventional perioperative manage-ment for colorectal surgery. Ann Surg. 2015;262:1026-1033. 7. Lee JA. The anaesthetic out-patient clinic. Anaesthesia. 1949;4:169-174. 8. Chase CR, Merz BA, Mazuzan JE. Computer assisted patient evaluation (CAPE): a multi-purpose computer system for an anesthesia service. Anesth Analg. 1983;62:198-206. 9. Fischer SP. Development and effectiveness of an anesthesia preoperative evaluation clinic in a teaching hospital. Anesthe-siology. 1996;85:196-206. 10. van Klei WA, Moons KG, Rutten CL, et al. The effect of out-patient preoperative evaluation of hospital inpatients on can-cellation of surgery and length of hospital stay. Anesth Analg. 2002;94:644-649. 11. Gibby GL. How preoperative assessment programs can be justified financially to hospital administrators. Int Anesthesiol Clin. 2002;40:17-30. 12. Ferschl MB, Tung A, Sweitzer B, et al. Preoperative clinic visits reduce operating room cancellations and delays. Anes-thesiology. 2005;103:855-859. 13. Blitz JD, Kendale SM, Jain SK, et al. preoperative evalua-tion clinic visit is associated with decreased risk of in-hospital postoperative mortality. Anesthesiology. 2016;125:280-294. 14. Costa MJ. The lived perioperative experience of ambula-tory surgery patients. AORN J. 2001;74:874-881. 15. Kruzik N. Benefits of preoperative education for adult elective surgery patients. AORN J. 2009;90:381-387. 16. Nielsen-Bohlman L, Panzer AM, Kindig DA, eds. Health Literacy: A Prescription to End Confusion. Washington DC; 2004. 17. Stallings E. Literacy and culture as determinants of health: Designing education for improved outcomes. Drew University, 2015. 18. Badarudeen S, Sabharwal S. Assessing readability of patient education materials: current role in orthopaedics. Clin Orthop Relat Res. 2010;468:2572-2580. 19. Hegazi RA, Hustead DS, Evans DC. Preoperative stan-dard oral nutrition supplements vs immunonutrition: results of a systematic review and meta-analysis. J Am Coll Surg. 2014;219:1078-1087. 20. Ditmyer MM, Topp R, Pifer M. Prehabilitation in preparation for orthopaedic surgery. Orthop Nurs. 2002;21:43-51; quiz 52-54. 21. Topp R, Ditmyer M, King K, et al. The effect of bed rest and potential of prehabilitation on patients in the intensive care unit. AACN Clin Issues. 2002;13:263-276. 22. Levett DZ, Grocott MP. Cardiopulmonary exercise testing, prehabilitation, and enhanced recovery after surgery (ERAS). Can J Anaesth. 2015;62:131-142. 23. Thompson PD, Franklin BA, Balady GJ, et al. Exercise and acute cardiovascular events placing the risks into perspective: a scientific statement from the American Heart Association Council on Nutrition, Physical Activity, and Metabolism and the Council on Clinical Cardiology. Circulation. 2007;115: 2358-2368. 24. Thompson PD, Buchner D, Pina IL, et al. Exercise and physi-cal activity in the prevention and treatment of atherosclerotic cardiovascular disease: a statement from the Council on Clini-cal Cardiology (Subcommittee on Exercise, Rehabilitation, and Prevention) and the Council on Nutrition, Physical Activity, and Metabolism (Subcommittee on Physical Activity). Circulation. 2003;107:3109-3116. 25. Belardinelli R, Georgiou D, Cianci G, et al. Randomized, con-trolled trial of long-term moderate exercise training in chronic heart failure: effects on functional capacity, quality of life, and clinical outcome. Circulation. 1999;99:1173-1182. 26. Mandic S, Myers J, Selig SE, et al. Resistance versus aerobic exercise training in chronic heart failure. Curr Heart Fail Rep. 2012;9:57-64. 27. O’Connor CM, Whellan DJ, Lee KL, et al. Efficacy and safety of exercise training in patients with chronic heart failure: HF-ACTION randomized controlled trial. JAMA. 2009;301:1439-1450. 28. Cornelissen VA, Buys R, Smart NA. Endurance exercise bene-ficially affects ambulatory blood pressure: a systematic review and meta-analysis. J Hypertens. 2013;31:639-648.Brunicardi_Ch50_p2113-p2136.indd 212801/03/19 9:39 AM 2129OPTIMIZING PERIOPERATIVE CARE: ENHANCED RECOVERY AND CHINESE MEDICINECHAPTER 50 29. Cornelissen VA, Smart NA. Exercise training for blood pres-sure: a systematic review and meta-analysis. J Am Heart Assoc. 2013;2:e004473. 30. Hayashino Y, Jackson JL, Fukumori N, et al. Effects of supervised exercise on lipid profiles and blood pressure con-trol in people with type 2 diabetes mellitus: a meta-analysis of randomized controlled trials. Diabetes Res Clin Pract. 2012;98:349-360. 31. Thomas DE, Elliott EJ, Naughton GA. Exercise for type 2 diabetes mellitus. Cochrane Database Syst Rev. 2006;CD002968. 32. Waschki B, Kirsten A, Holz O, et al. Physical activity is the strongest predictor of all-cause mortality in patients with COPD: a prospective cohort study. Chest. 2011 140:331-342. 33. Cooney GM, Dwan K, Greig CA, et al. Exercise for depres-sion. Cochrane Database Syst Rev. 2013;CD004366. 34. Forbes D, Thiessen EJ, Blake CM, et al. Exercise programs for people with dementia. Cochrane Database Syst Rev. 2013:CD006489. 35. Saunders DH, Sanderson M, Brazzelli M, et al. Physical fit-ness training for stroke patients. Cochrane Database Syst Rev. 2013:CD003316. 36. Des Guetz G, Uzzan B, Bouillet T, et al. Impact of physical activity on cancer-specific and overall survival of patients with colorectal cancer. Gastroenterol Res Pract. 2013:340851. 37. Hoogeboom TJ, Dronkers JJ, Hulzebos EH, et al. Merits of exercise therapy before and after major surgery. Curr Opin Anaesthesiol. 2014;27:161-166. 38. Arthur HM, Daniels C, McKelvie R, et al. Effect of a preoper-ative intervention on preoperative and postoperative outcomes in low-risk patients awaiting elective coronary artery bypass graft surgery. A randomized, controlled trial. Ann Intern Med. 2000;133:253-262. 39. Jones LW, Watson D, Herndon JE, et al. Peak oxygen con-sumption and long-term all-cause mortality in nonsmall cell lung cancer. Cancer. 2010;116:4825-4832. 40. West MA, Lythgoe D, Barben CP, et al. Cardiopulmonary exercise variables are associated with postoperative morbid-ity after major colonic surgery: a prospective blinded obser-vational study. Br J Anaesth. 2014;112:665-671. 41. Dronkers JJ, Chorus AMJ, van Meeteren NLU, et al. The asso-ciation of pre-operative physical fitness and physical activ-ity with outcome after scheduled major abdominal surgery. Anaesthesia. 2013;68:67-73. 42. Fagevik Olsen M, Hahn I, Nordgren S, et al. Randomized controlled trial of prophylactic chest physiotherapy in major abdominal surgery. Br J Surg. 1997;84:1535-1538. 43. Kundra P, Vitheeswaran M, Nagappa M, et al. Effect of pre-operative and postoperative incentive spirometry on lung functions after laparoscopic cholecystectomy. Surg Laparosc Endosc Percutan Tech. 2010;20:170-172. 44. Krueger JK, Rohrich RJ. Clearing the smoke: the scientific rationale for tobacco abstention with plastic surgery. Plast Reconstr Surg. 2001;108:1063-1073; discussion 1074-1077. 45. Furlong C. Smoking cessation and its effects on outcomes of surgical interventions. London Health Observatory and Barnet PCT, 2005. Available at: www.LHO.org.uk. 46. Ngaage DL, Martins E, Orkell E, et al. The impact of the duration of mechanical ventilation on the respiratory outcome in smokers undergoing cardiac surgery. Cardiovasc Surg. 2002;10:345-350. 47. Cole CW, Hill GB, Farzad E, et al. Cigarette smoking and peripheral arterial occlusive disease. Surgery. 1993;114: 753-756; discussion 756-757. 48. Theadom A, Cropley M: Effects of preoperative smoking ces-sation on the incidence and risk of intraoperative and postop-erative complications in adult smokers: a systematic review. Tob Control. 2006;15:352-358. 49. Ljungqvist O, Fearon K, Little R. In Gibney M, Elia M, Ljungqvist O, et al, eds. The Human Nutrition Textbook Series. Oxford, UK: Blackwell Science; 2005. 50. Nygren J, Thorell A, Efendic S, et al. Site of insulin resis-tance after surgery: the contribution of hypocaloric nutrition and bed rest. Clin Sci (Lond). 1997;93:137-146. 51. Brandi LS, Frediani M, Oleggini M, et al. Insulin resistance after surgery: normalization by insulin treatment. Clin Sci (Lond). 1990;79:443-450. 52. Greisen J, Juhl CB, Grofte T, et al. Acute pain induces insulin resistance in humans. Anesthesiology. 2001;95:578-584. 53. Thorell A, Nygren J, Ljungqvist O. Insulin resistance: a marker of surgical stress. Curr Opin Clin Nutr Metab Care. 1999;2:69-78. 54. Sato H, Carvalho G, Sato T, et al. The association of preop-erative glycemic control, intraoperative insulin sensitivity, and outcomes after cardiac surgery. J Clin Endocrinol Metab. 2010;95:4338-4344. 55. Brownlee M. The pathobiology of diabetic complications: a unifying mechanism. Diabetes. 2005;54:1615-1625. 56. Witasp A, Nordfors L, Schalling M, et al. Increased expres-sion of inflammatory pathway genes in skeletal muscle during surgery. Clin Nutr. 2009;28:291-298. 57. Witasp A, Nordfors L, Schalling M, et al. Expression of inflammatory and insulin signaling genes in adipose tissue in response to elective surgery. J Clin Endocrinol Metab. 2010;95:3460-3469. 58. Svanfeldt M, Thorell A, Hausel J, et al. Effect of “preop-erative” oral carbohydrate treatment on insulin action—a randomised cross-over unblinded study in healthy subjects. Clin Nutr. 2005;24:815-821. 59. Henriksen MG, Hessov I, Dela F, et al. Effects of preop-erative oral carbohydrates and peptides on postoperative endocrine response, mobilization, nutrition and muscle function in abdominal surgery. Acta Anaesthesiol Scand. 2003;47:191-199. 60. Crowe PJ, Dennison A, Royle GT. The effect of pre-operative glucose loading on postoperative nitrogen metabolism. Br J Surg. 1984;71:635-637. 61. Yuill KA, Richardson RA, Davidson HI, et al. The admin-istration of an oral carbohydrate-containing fluid prior to major elective upper-gastrointestinal surgery preserves skeletal muscle mass postoperativel—a randomised clini-cal trial. Clin Nutr. 2005;24:32-37. 62. Soop M, Carlson GL, Hopkinson J, et al. Randomized clinical trial of the effects of immediate enteral nutrition on metabolic responses to major colorectal surgery in an enhanced recovery protocol. Br J Surg. 2004;91:1138-1145. 63. Practice guidelines for preoperative fasting and the use of pharmacologic agents to reduce the risk of pulmonary aspi-ration: application to healthy patients undergoing elective procedures: a report by the American Society of Anesthesi-ologist Task Force on Preoperative Fasting. Anesthesiology. 1999;90:896-905. 64. American Society of Anesthesiologists Committee. Practice guidelines for preoperative fasting and the use of pharmaco-logic agents to reduce the risk of pulmonary aspiration: appli-cation to healthy patients undergoing elective procedures: an updated report by the American Society of Anesthesiologists Committee on Standards and Practice Parameters. Anesthesi-ology. 2011;114:495-511. 65. Smith I, Kranke P, Murat I, et al. Perioperative fasting in adults and children: guidelines from the European Society of Anaesthesiology. Eur J Anaesthesiol. 2011;28:556-569. 66. Hausel J, Nygren J, Lagerkranser M, et al. A carbohydrate rich drink reduces preoperative discomfort in elective surgery patients. Anesth Analg. 2001;93:1344-1350.Brunicardi_Ch50_p2113-p2136.indd 212901/03/19 9:39 AM 2130SPECIFIC CONSIDERATIONSPART II 67. Brady M, Kinn S, Stuart P. Preoperative fasting for adults to prevent perioperative complications. Cochrane Database Syst Rev. 2003;CD004423. 68. Agarwal A, Chari P, Singh H. Fluid deprivation before operation. The effect of a small drink. Anaesthesia. 1989; 44:632-634. 69. Hutchinson A, Maltby JR, Reid CR. Gastric fluid volume and pH in elective inpatients. Part I: coffee or orange juice versus overnight fast. Can J Anaesth. 1988;35:12-15. 70. Maltby JR, Sutherland AD, Sale JP, et al. Preoperative oral fluids: is a five-hour fast justified prior to elective surgery? Anesth Analg. 1986;65:1112-1116. 71. McGrady EM, Macdonald AG. Effect of the preoperative administration of water on gastric volume and pH. Br J Anaesth. 1988;60:803-805. 72. Phillips S, Hutchinson S, Davidson T. Preoperative drinking does not affect gastric contents. Br J Anaesth. 1993;70:6-9. 73. Read MS, Vaughan RS. Allowing pre-operative patients to drink: effects on patients’ safety and comfort of unlimited oral water until 2 hours before anaesthesia. Acta Anaesthesiol Scand. 1991;35:591-595. 74. Sutherland AD, Maltby JR, Sale JP, et al. The effect of pre-operative oral fluid and ranitidine on gastric fluid volume and pH. Can J Anaesth. 1987;34:117-121. 75. Yagci G, Can MF, Ozturk E, et al. Effects of preoperative car-bohydrate loading on glucose metabolism and gastric contents in patients undergoing moderate surgery: a randomized, con-trolled trial. Nutrition. 2008;24:212-216. 76. Hausel J, Nygren J, Lagerkranser M, et al. A carbohydrate-rich drink reduces preoperative discomfort in elective surgery patients. Anesth Analg. 2001;93:1344-1350. 77. Smith MD, McCall J, Plank L, et al. Preoperative carbohy-drate treatment for enhancing recovery after elective surgery. Cochrane Database Syst Rev. 2014;CD009161. 78. Soop M, Nygren J, Myrenfors P, et al. Reoperative oral car-bohydrate treatment attenuates immediate postoperative insulin resistance. Am J Physiol Endocrinol Metab. 2001;280(4): E576-E583. 79. Nygren J, Soop M, Thorell A, et al. Preoperative oral car-bohydrates and postoperative insulin resistance. Clin Nutr. 1999;18:117-120. 80. Awad S, Varadhan KK, Ljungqvist O, et al. A meta-analysis of randomised controlled trials on preoperative oral carbohydrate treatment in elective surgery. Clin Nutr. 2013;32:34-44. 81. Gustafsson UO, Scott MJ, Schwenk W, et al. Guidelines for perioperative care in elective colonic surgery: Enhanced Recovery After Surgery (ERAS[R]) Society recommenda-tions. Clin Nutr. 2012;31:783-800. 82. Lassen K, Coolsen MM, Slim K, et al. Guidelines for peri-operative care for pancreaticoduodenectomy: Enhanced Recovery After Surgery (ERAS[R]) Society recommenda-tions. World J Surg. 2013;37:240-258. 83. Nygren J, Thacker J, Carli F, et al. Guidelines for peri-operative care in elective rectal/pelvic surgery: Enhanced Recovery After Surgery (ERAS[R]) Society recommenda-tions. Clin Nutr. 2012;31:801-816. 84. Thorell A, MacCormick AD, Awad S, et al. Guidelines for perioperative care in bariatric surgery: Enhanced Recovery After Surgery (ERAS) Society recommendations. World J Surg. 2016;40(9):2065-2083. 85. Torossian A, Brauer A, Hocker J, et al. Preventing inadver-tent perioperative hypothermia. Dtsch Arztebl Int. 2015; 112:166-172. 86. Moola S, Lockwood C. Effectiveness of strategies for the management and/or prevention of hypothermia within the adult perioperative environment. Int J Evid Based Healthc. 2011;9:337-345. 87. Barash PG CB, Stoelting RK. Clinical Anesthesia. Philadelphia: Lippincott Williams & Wilkins; 2006:1400. 88. Jin Y, Tian J, Sun M, et al. A systematic review of randomised controlled trials of the effects of warmed irrigation fluid on core body temperature during endoscopic surgeries. J Clin Nurs. 2011;20:305-316. 89. Roberson MC, Dieckmann LS, Rodriguez RE, et al. A review of the evidence for active preoperative warming of adults undergoing general anesthesia. AANA J. 2013;81:351-356. 90. Horn EP, Schroeder F, Gottschalk A, et al. Active warming during cesarean delivery. Anesth Analg. 2002;94:409-414. 91. Horn EP, Bein B, Bohm R, et al. The effect of short time periods of pre-operative warming in the prevention of peri-operative hypothermia. Anaesthesia. 2012;67:612-617. 92. Vanni SM, Braz JR, Modolo NS, et al. Preoperative combined with intraoperative skin-surface warming avoids hypother-mia caused by general anesthesia and surgery. J Clin Anesth. 2003;15:119-125. 93. Kellam MD, Dieckmann LS, Austin PN. Forced-air warm-ing devices and the risk of surgical site infections. AORN J. 2013;98:354-366; quiz 367-369. 94. Galvao CM, Marck PB, Sawada NO, et al. A systematic review of the effectiveness of cutaneous warming systems to prevent hypothermia. J Clin Nurs. 2009;18:627-636. 95. De Witte JL, Demeyer C, Vandemaele E. Resistive-heating or forced-air warming for the prevention of redistribution hypo-thermia. Anesth Analg. 2010;110:829-833. 96. Sessler DI, McGuire J, Sessler AM. Perioperative thermal insulation. Anesthesiology. 1991;74:875-879. 97. Alderson P, Campbell G, Smith AF, et al. Thermal insula-tion for preventing inadvertent perioperative hypothermia. Cochrane Database Syst Rev. 2014;CD009908. 98. Sessler DI. Complications and treatment of mild hypothermia. Anesthesiology. 2001;95:531-543. 99. Andrzejowski JC, Turnbull D, Nandakumar A, et al. A ran-domised single blinded study of the administration of pre-warmed fluid vs active fluid warming on the incidence of peri-operative hypothermia in short surgical procedures. Anaesthesia. 2010;65:942-945. 100. Douketis JD. The 2016 American College of Chest Physicians treatment guidelines for venous thromboembolism: a review and critical appraisal. Intern Emerg Med. 2016;11:1031-1035. 101. Reid TR, Race ER, Wolff BH, et al. Enhanced in vivo therapeu-tic response to interferon in mice with an in vitro interferon-resistant B-cell lymphoma. Cancer Res. 1989;49:4163-4169. 102. Brandstrup B, Tonnesen H, Beier-Holgersen R, et al. Effects of intravenous fluid restriction on postoperative complications: comparison of two perioperative fluid regi-mens: a randomized assessor-blinded multicenter trial. Ann Surg. 2003;238:641-648. 103. Gonzalez-Fajardo JA, Mengibar L, Brizuela JA, et al. Effect of postoperative restrictive fluid therapy in the recovery of patients with abdominal vascular surgery. Eur J Vasc Endo-vasc Surg. 2009;37:538-543. 104. Holte K, Foss NB, Andersen J, et al. Liberal or restrictive fluid administration in fast-track colonic surgery: a randomized, double-blind study. Br J Anaesth. 2007;99:500-508. 105. Lobo DN, Bostock KA, Neal KR, et al. Effect of salt and water balance on recovery of gastrointestinal function after elective colonic resection: a randomised controlled trial. Lancet. 2002;359:1812-1818. 106. MacKay G, Fearon K, McConnachie A, et al. Randomized clinical trial of the effect of postoperative intravenous fluid restriction on recovery after elective colorectal surgery. Br J Surg. 2006;93:1469-1474. 107. McArdle GT, McAuley DF, McKinley A, et al. Preliminary results of a prospective randomized trial of restrictive versus Brunicardi_Ch50_p2113-p2136.indd 213001/03/19 9:39 AM 2131OPTIMIZING PERIOPERATIVE CARE: ENHANCED RECOVERY AND CHINESE MEDICINECHAPTER 50standard fluid regime in elective open abdominal aortic aneu-rysm repair. Ann Surg. 2009;250:28-34. 108. Vermeulen H, Hofland J, Legemate DA, et al. Intravenous fluid restriction after major abdominal surgery: a randomized blinded clinical trial. Trials. 2009;10:50. 109. Francis N, Kennedy RH, Ljunggvist O, Mythen M. Manual of Fast Track Recovery for Colorectal Surgery. London: Springer; 2012. 110. Walsh SR, Tang T, Bass S, et al. Doppler-guided intra-operative fluid management during major abdominal sur-gery: systematic review and meta-analysis. Int J Clin Pract. 2008;62:466-470. 111. Giglio MT, Marucci M, Testini M, et al. Goal-directed haemo-dynamic therapy and gastrointestinal complications in major surgery: a meta-analysis of randomized controlled trials. Br J Anaesth. 2009;103:637-646. 112. Gan TJ, Soppitt A, Maroof M, et al. Goal-directed intraopera-tive fluid administration reduces length of hospital stay after major surgery. Anesthesiology. 2002;97:820-826. 113. Noblett SE, Snowden CP, Shenton BK, et al. Randomized clinical trial assessing the effect of Doppler-optimized fluid management on outcome after elective colorectal resection. Br J Surg. 2006;93:1069-1076. 114. Pillai P, McEleavy I, Gaughan M, et al. A double-blind ran-domized controlled clinical trial to assess the effect of Dop-pler optimized intraoperative fluid management on outcome following radical cystectomy. J Urol. 2011;186:2201-2206. 115. Sinclair S, James S, Singer M. Intraoperative intravascular volume optimisation and length of hospital stay after repair of proximal femoral fracture: randomised controlled trial. BMJ. 1997;315:909-912. 116. Wakeling HG, McFall MR, Jenkins CS, et al. Intraopera-tive oesophageal Doppler guided fluid management shortens postoperative hospital stay after major bowel surgery. Br J Anaesth. 2005;95:634-642. 117. Perel P, Roberts I, Ker K. Colloids versus crystalloids for fluid resuscitation in critically ill patients. Cochrane Database Syst Rev. 2013;CD000567. 118. McCluskey SA, Karkouti K, Wijeysundera D, et al. Hyper-chloremia after noncardiac surgery is independently associated with increased morbidity and mortality: a propensity-matched cohort study. Anesth Analg. 2013;117:412-421. 119. Shaw AD, Bagshaw SM, Goldstein SL, et al. Major complica-tions, mortality, and resource utilization after open abdominal surgery: 0.9% saline compared to Plasma-Lyte. Ann Surg. 2012;255:821-829. 120. IASP. Part III: pain terms, a current list with definitions and notes on usage. In: Merskey H, ed. Classification of Chronic Pain. 2nd ed. Seattle: IASP Press; 1994:209-214. 121. Thiele RH HT. Enhanced Recovery After Surgery (ERAS): Protocol in Colorectal Surgery. Second Annual Monitoring Conference, UPMC Department of Anesthesiology. Pittsburgh, PA, 2014. 122. Chia YY, Liu K, Wang JJ, et al. Intraoperative high dose fen-tanyl induces postoperative fentanyl tolerance. Can J Anaesth. 1999;46:872-877. 123. Collard V, Mistraletti G, Taqi A, et al. Intraoperative esmolol infusion in the absence of opioids spares postoperative fen-tanyl in patients undergoing ambulatory laparoscopic chole-cystectomy. Anesth Analg. 2007;105:1255-1262. 124. Coloma M, Chiu JW, White PF, et al. The use of esmolol as an alternative to remifentanil during desflurane anesthesia for fast-track outpatient gynecologic laparoscopic surgery. Anesth Analg. 2001;92:352-357. 125. Crawford MW, Galton S, Naser B. Postoperative morphine consumption in children with sickle-cell disease. Paediatr Anaesth. 2006;16:152-157. 126. Gottschalk A, Durieux ME, Nemergut EC. Intraopera-tive methadone improves postoperative pain control in patients undergoing complex spine surgery. Anesth Analg. 2011;112:218-223. 127. Guignard B, Bossard AE, Coste C, et al. Acute opioid toler-ance: intraoperative remifentanil increases postoperative pain and morphine requirement. Anesthesiology. 2000;93:409-417. 128. Mendel HG, Guarnieri KM, Sundt LM, et al. The effects of ketorolac and fentanyl on postoperative vomiting and analge-sic requirements in children undergoing strabismus surgery. Anesth Analg. 1995;80:1129-1133. 129. Sukhani R, Vazquez J, Pappas AL, et al. Recovery after propo-fol with and without intraoperative fentanyl in patients under-going ambulatory gynecologic laparoscopy. Anesth Analg. 1996;83:975-981. 130. Rorarius MG, Mennander S, Suominen P, et al. Gabapentin for the prevention of postoperative pain after vaginal hyster-ectomy. Pain. 2004;110:175-181. 131. Parikh HG, Dash SK, Upasani CB. Study of the effect of oral gabapentin used as preemptive analgesia to attenuate post-operative pain in patients undergoing abdominal surgery under general anesthesia. Saudi J Anaesth. 2010;4:137-141. 132. Pandey CK, Sahay S, Gupta D, et al. Preemptive gabapentin decreases postoperative pain after lumbar discoidectomy. Can J Anaesth. 2004;51:986-989. 133. Pandey CK, Priye S, Singh S, et al. Preemptive use of gaba-pentin significantly decreases postoperative pain and rescue analgesic requirements in laparoscopic cholecystectomy. Can J Anaesth. 2004;51:358-363. 134. Dirks J, Fredensborg BB, Christensen D, et al. A randomized study of the effects of single-dose gabapentin versus placebo on postoperative pain and morphine consumption after mas-tectomy. Anesthesiology. 2002;97:560-564. 135. Dierking G, Duedahl TH, Rasmussen ML, et al. Effects of gabapentin on postoperative morphine consumption and pain after abdominal hysterectomy: a randomized, double-blind trial. Acta Anaesthesiol Scand. 2004;48:322-327. 136. Bell RF, Dahl JB, Moore RA, et al. Peri-operative ketamine for acute post-operative pain: a quantitative and qualitative systematic review (Cochrane review). Acta Anaesthesiol Scand. 2005;49:1405-1428. 137. Celerier E, Rivat C, Jun Y, et al. Long-lasting hyperalgesia induced by fentanyl in rats: preventive effect of ketamine. Anesthesiology. 2000;92:465-472. 138. Seyhan TO, Tugrul M, Sungur MO, et al. Effects of three dif-ferent dose regimens of magnesium on propofol requirements, haemodynamic variables and postoperative pain relief in gyn-aecological surgery. Br J Anaesth. 2006;96:247-252. 139. Dube L, Granry JC. The therapeutic use of magnesium in anesthesiology, intensive care and emergency medicine: a review. Can J Anaesth. 2003;50:732-746. 140. Vigneault L, Turgeon AF, Cote D, et al. Perioperative intra-venous lidocaine infusion for postoperative pain control: a meta-analysis of randomized controlled trials. Can J Anaesth. 2011;58:22-37. 141. Benyamin R, Trescot AM, Datta S, et al. Opioid complications and side effects. Pain Physician. 2008;11:S105-S120. 142. de Cosmo G. The use of NSAIDs in the postoperative perioid: advantage and disadvantages. J Anesth Crit Care. 2015;3(4). 143. Kurdi MS, Theerth KA, Deva RS. Ketamine: current applica-tions in anesthesia, pain, and critical care. Anesth Essays Res. 2014;8:283-290. 144. American Society of Anesthesiologists Task Force on Acute Pain Management. Practice guidelines for acute pain manage-ment in the perioperative setting: an updated report by the American Society of Anesthesiologists Task Force on Acute Pain Management. Anesthesiology. 2012;116:248-273.Brunicardi_Ch50_p2113-p2136.indd 213101/03/19 9:39 AM 2132SPECIFIC CONSIDERATIONSPART II 145. Chou R, Gordon DB, de Leon-Casasola OA, et al. Manage-ment of postoperative pain: a clinical practice guideline from the American Pain Society, the American Society of Regional Anesthesia and Pain Medicine, and the American Society of Anesthesiologists’ Committee on Regional Anesthesia, Executive Committee, and Administrative Council. J Pain. 2016;17:131-157. 146. De Pinto M, Dagal A, O’Donnell B, et al. Regional anes-thesia for management of acute pain in the intensive care unit. Int J Crit Illn Inj Sci. 2015;5:138-143. 147. Fortier J, Chung F, Su J. Unanticipated admission after ambulatory surgery—a prospective study. Can J Anaesth. 1998;45:612-619. 148. Gold BS, Kitz DS, Lecky JH, et al. Unanticipated admis-sion to the hospital following ambulatory surgery. JAMA. 1989;262:3008-3010. 149. Hill RP, Lubarsky DA, Phillips-Bute B, et al. Cost-effectiveness of prophylactic antiemetic therapy with ondansetron, droperi-dol, or placebo. Anesthesiology. 2000;92:958-967. 150. Sinclair DR, Chung F, Mezei G. Can postoperative nausea and vomiting be predicted? Anesthesiology. 1999;91:109-118. 151. Koivuranta M, Laara E, Snare L, et al. A survey of postopera-tive nausea and vomiting. Anaesthesia. 1997;52:443-449. 152. Apfel CC, Laara E, Koivuranta M, et al. A simplified risk score for predicting postoperative nausea and vomiting: con-clusions from cross-validations between two centers. Anesthe-siology. 1999;91:693-700. 153. Gan TJ, Diemunsch P, Habib AS, et al. Consensus guidelines for the management of postoperative nausea and vomiting. Anesth Analg. 2014;118:85-113. 154. Apfel CC, Korttila K, Abdalla M, et al. A factorial trial of six interventions for the prevention of postoperative nausea and vomiting. N Engl J Med. 2004;350:2441-2451. 155. Apfel CC, Philip BK, Cakmakkaya OS, et al. Who is at risk for postdischarge nausea and vomiting after ambulatory sur-gery? Anesthesiology. 2012;117:475-486. 156. Kranke P, Apefel CC, Papenfuss T, et al. An increased body mass index is no risk factor for postoperative nausea and vom-iting. A systematic review and results of original data. Acta Anaesthesiol Scand. 2001;45:160-166. 157. Scuderi PE, James RL, Harris L, et al. Multimodal antiemetic management prevents early postoperative vomiting after out-patient laparoscopy. Anesth Analg. 2000;91:1408-1414. 158. Tramer M, Moore A, McQuay H. Omitting nitrous oxide in general anaesthesia: meta-analysis of intraoperative aware-ness and postoperative emesis in randomized controlled trials. Br J Anaesth. 1996;76:186-193. 159. Tramer M, Moore A, McQuay H. Meta-analytic comparison of prophylactic antiemetic efficacy for postoperative nausea and vomiting: propofol anaesthesia vs omitting nitrous oxide vs total i.v. anaesthesia with propofol. Br J Anaesth. 1997;78:256-259. 160. Tramer MR, Reynolds DJ, Moore RA, et al. Efficacy, dose-response, and safety of ondansetron in prevention of postop-erative nausea and vomiting: a quantitative systematic review of randomized placebo-controlled trials. Anesthesiology. 1997;87:1277-1289. 161. Schnabel A, Eberhart LH, Muellenbach R, et al. Efficacy of perphenazine to prevent postoperative nausea and vomit-ing: a quantitative systematic review. Eur J Anaesthesiol. 2010;27:1044-1051. 162. Gan TJ, Apfel CC, Kovac A, et al. A randomized, double-blind comparison of the NK1 antagonist, aprepitant, versus ondan-setron for the prevention of postoperative nausea and vomit-ing. Anesth Analg. 2007;104:1082-1089. 163. Wang JJ, Ho ST, Lee SC, et al. The use of dexamethasone for preventing postoperative nausea and vomiting in females undergoing thyroidectomy: a dose-ranging study. Anesth Analg. 2000;91:1404-1407. 164. Bailey PL, Streisand JB, Pace NL, et al. Transdermal scopol-amine reduces nausea and vomiting after outpatient laparos-copy. Anesthesiology. 1990;72:977-980. 165. Delaney CP, Senagore AJ, Viscusi ER, et al. Postoperative upper and lower gastrointestinal recovery and gastrointesti-nal morbidity in patients undergoing bowel resection: pooled analysis of placebo data from 3 randomized controlled trials. Am J Surg. 2006;191:315-319. 166. Asgeirsson T, El-Badawi KI, Mahmood A, et al. Postopera-tive ileus: it costs more than you expect. J Am Coll Surg. 2010;210:228-231. 167. Nelson R, Tse B, Edwards S. Systematic review of prophy-lactic nasogastric decompression after abdominal operations. Br J Surg. 2005;92:673-680. 168. Nelson R, Edwards S, Tse B. Prophylactic nasogastric decom-pression after abdominal surgery. Cochrane Database Syst Rev. 2005;CD004929. 169. Daryaei P, Vaghef Davari F, Mir M, et al. Omission of naso-gastric tube application in postoperative care of esophagec-tomy. World J Surg. 2009;33:773-777. 170. Chapuis PH, Bokey L, Keshava A, et al. Risk factors for prolonged ileus after resection of colorectal cancer: an observational study of 2400 consecutive patients. Ann Surg. 2013;257:909-915. 171. Lacy AM, Garcia-Valdecasas JC, Pique JM, et al. Short-term outcome analysis of a randomized study comparing laparo-scopic vs open colectomy for colon cancer. Surg Endosc. 1995;9:1101-1105. 172. Schwenk W, Bohm B, Haase O, et al. Laparoscopic versus conventional colorectal resection: a prospective randomised study of postoperative ileus and early postoperative feeding. Langenbecks Arch Surg. 1998;383:49-55. 173. Shussman N, Brown MR, Johnson MC, et al. Does nasogastric tube decompression get used less often with laparoscopic and hand-assisted compared with open colectomy? Surg Endosc. 2013;27:4564-4568. 174. Uemura K, Tatewaki M, Harris MB, et al. Magnitude of abdominal incision affects the duration of postoperative ileus in rats. Surg Endosc. 2004;18:606-610. 175. Varadhan KK, Lobo DN. A meta-analysis of randomised con-trolled trials of intravenous fluid therapy in major elective open abdominal surgery: getting the balance right. Proc Nutr Soc. 2010;69:488-498. 176. Ho YM, Smith SR, Pockney P, et al. A meta-analysis on the effect of sham feeding following colectomy: should gum chewing be included in enhanced recovery after surgery pro-tocols? Dis Colon Rectum. 2014;57:115-126. 177. Purkayastha S, Tilney HS, Darzi AW, et al. Meta-analysis of randomized studies evaluating chewing gum to enhance postoperative recovery following colectomy. Arch Surg. 2008;143:788-793. 178. Short V, Herbert G, Perry R, et al. Chewing gum for postop-erative recovery of gastrointestinal function. Cochrane Data-base Syst Rev. 2015;CD006506. 179. Atkinson C, Penfold CM, Ness AR, et al. Randomized clinical trial of postoperative chewing gum versus standard care after colorectal resection. Br J Surg. 2016;103:962-970. 180. Lim P, Morris OJ, Nolan G, et al. Sham feeding with chewing gum after elective colorectal resectional surgery: a random-ized clinical trial. Ann Surg. 2013;257:1016-1024. 181. Delaney CP, Wolff BG, Viscusi ER, et al. Alvimopan, for post-operative ileus following bowel resection: a pooled analysis of phase III studies. 2007; Ann Surg 245:355-363. 182. Adam MA, Lee LM, Kim J, et al. Alvimopan provides addi-tional improvement in outcomes and cost savings in enhanced recovery colorectal surgery. Ann Surg. 2016;264:141-146. 183. Barletta JF, Asgeirsson T, El-Badawi KI, et al. Introduction of alvimopan into an enhanced recovery protocol for colectomy Brunicardi_Ch50_p2113-p2136.indd 213201/03/19 9:39 AM 2133OPTIMIZING PERIOPERATIVE CARE: ENHANCED RECOVERY AND CHINESE MEDICINECHAPTER 50offers benefit in open but not laparoscopic colectomy. J Lapa-roendosc Adv Surg Tech A. 2011;21:887-891. 184. Keller DS, Flores-Gonzalez JR, Ibarra S, et al. Is there value in alvimopan in minimally invasive colorectal surgery? Am J Surg. 2016;212:851-856. 185. Hirsch CH, Sommers L, Olsen A, et al. The natural history of functional morbidity in hospitalized older patients. J Am Geriatr Soc. 1990;38:1296-1303. 186. Gillis C, Li C, Lee L, et al. Prehabilitation versus rehabilita-tion: a randomized control trial in patients undergoing colorec-tal resection for cancer. Anesthesiology. 2014;121:937-947. 187. Nygren J, Soop M, Thorell A, et al. An enhanced-recovery protocol improves outcome after colorectal resection already during the first year: a single-center experience in 168 con-secutive patients. Dis Colon Rectum. 2009;52:978-985. 188. Teeuwen PH, Bleichrodt RP, Strik C, et al. Enhanced recovery after surgery (ERAS) versus conventional postoperative care in colorectal surgery. J Gastrointest Surg. 2010;14:88-95. 189. Zargar-Shoshtari K, Connolly AB, Israel LH, et al. Fast-track surgery may reduce complications following major colonic surgery. Dis Colon Rectum. 2008;51:1633-1640. 190. Ren L, Zhu D, Wei Y, et al. Enhanced Recovery After Sur-gery (ERAS) program attenuates stress and accelerates recov-ery in patients after radical resection for colorectal cancer: a prospective randomized controlled trial. World J Surg. 2012;36:407-414. 191. Delaney CP, Brady K, Woconish D, et al. Towards optimizing perioperative colorectal care: outcomes for 1,000 consecutive laparoscopic colon procedures using enhanced recovery path-ways. Am J Surg. 2012;203:353-355; discussion 355-356. 192. Keane C, Savage S, McFarlane K, et al. Enhanced recovery after surgery versus conventional care in colonic and rectal surgery. ANZ J Surg. 2012;82:697-703. 193. Esteban F, Cerdan FJ, Garcia-Alonso M, et al. A multicen-tre comparison of a fast track or conventional postoperative protocol following laparoscopic or open elective surgery for colorectal cancer surgery. Colorectal Dis. 2014;16:134-140. 194. Gouvas N, Gogos-Pappas G, Tsimogiannis K, et al. Imple-mentation of fast-track protocols in open and laparoscopic sphincter-preserving rectal cancer surgery: a multicenter, comparative, prospective, non-randomized study. Dig Surg. 2012;29:301-309. 195. Greco M, Capretti G, Beretta L, et al. Enhanced recovery program in colorectal surgery: a meta-analysis of randomized controlled trials. World J Surg. 2014;38:1531-1541. 196. Vlug MS, Wind J, van der Zaag E, et al. Systematic review of laparoscopic vs open colonic surgery within an enhanced recovery programme. Colorectal Dis. 2009;11:335-343. 197. Zhuang CL, Huang DD, Chen FF, et al. Laparoscopic versus open colorectal surgery within enhanced recovery after sur-gery programs: a systematic review and meta-analysis of ran-domized controlled trials. Surg Endosc. 2015;29:2091-2100. 198. Garulli G, Lucchi A, Berti P, et al. “Ultra” E.R.A.S. in laparoscopic colectomy for cancer: discharge after the first flatus? A prospective, randomized trial. Surg Endosc. 2017;31:1806-1813. 199. Gignoux B, Pasquer A, Vulliez A, et al. Outpatient colec-tomy within an enhanced recovery program. J Visc Surg. 2015;152:11-15. 200. Lawrence JK, Keller DS, Samia H, et al. Discharge within 24 to 72 hours of colorectal surgery is associated with low readmission rates when using Enhanced Recovery Pathways. J Am Coll Surg. 2013;216:390-394. 201. Pawa N, Cathcart PL, Arulampalam TH, et al. Enhanced recovery program following colorectal resection in the elderly patient. World J Surg. 2012;36:415-423. 202. Anderin K, Gustafsson UO, Thorell A, et al. The effect of diverting stoma on postoperative morbidity after low anterior resection for rectal cancer in patients treated within an ERAS program. Eur J Surg Oncol. 2015;41:724-730. 203. Group EC: the impact of enhanced recovery protocol compli-ance on elective colorectal cancer resection: results from an international registry. Ann Surg. 2015;261:1153-1159. 204. Bakker N, Cakir H, Doodeman HJ, et al. Eight years of expe-rience with enhanced recovery after surgery in patients with colon cancer: impact of measures to improve adherence. Surgery. 2015;157:1130-1136. 205. Boulind CE, Yeo M, Burkill C, et al. Factors predicting devia-tion from an enhanced recovery programme and delayed dis-charge after laparoscopic colorectal surgery. Colorectal Dis. 2012;14:e103-110. 206. Keller DS, Bankwitz B, Woconish D, et al. Predicting who will fail early discharge after laparoscopic colorectal surgery with an established enhanced recovery pathway. Surg Endosc. 2014;28:74-79. 207. Oh HK, Ihn MH, Son IT, et al. Factors associated with failure of enhanced recovery programs after laparoscopic colon can-cer surgery: a single-center retrospective study. Surg Endosc. 2016;30:1086-1093. 208. Smart NJ, White P, Allison AS, et al. Deviation and failure of enhanced recovery after surgery following laparoscopic colorectal surgery: early prediction model. Colorectal Dis. 2012;14:e727-e734. 209. Francis NK, Luther A, Salib E, et al. The use of artificial neu-ral networks to predict delayed discharge and readmission in enhanced recovery following laparoscopic colorectal cancer surgery. Tech Coloproctol. 2015;19:419-428. 210. Francis NK, Mason J, Salib E, et al. Factors predicting 30-day readmission after laparoscopic colorectal cancer surgery within an enhanced recovery programme. Colorectal Dis. 2015;17:O148-O154. 211. Lee L, Li C, Landry T, et al. A systematic review of economic evaluations of enhanced recovery pathways for colorectal sur-gery. Ann Surg. 2014;259:670-676. 212. van Dam RM, Hendry PO, Coolsen MM, et al. Initial experience with a multimodal enhanced recovery pro-gramme in patients undergoing liver resection. Br J Surg. 2008;95:969-975. 213. Jones C, Kelliher L, Dickinson M, et al. Randomized clini-cal trial on enhanced recovery versus standard care following open liver resection. Br J Surg. 2013;100:1015-1024. 214. Ni TG, Yang HT, Zhang H, et al. Enhanced recovery after sur-gery programs in patients undergoing hepatectomy: a meta-analysis. World J Gastroenterol. 2015;21:9209-9216. 215. Wang C, Zheng G, Zhang W, et al. Enhanced recovery after surgery programs for liver resection: a meta-analysis. J Gas-trointest Surg. 2017;21:472-486. 216. Yang R, Tao W, Chen YY, et al. Enhanced recovery after surgery programs versus traditional perioperative care in laparoscopic hepatectomy: a meta-analysis. Int J Surg. 2016; 36:274-282. 217. Xu X, Wang Y, Feng T, et al. Nonstrict and individual enhanced recovery after surgery (ERAS) in partial hepatec-tomy. Springerplus. 2016;5:2011. 218. Balzano G, Zerbi A, Braga M, et al. Fast-track recovery pro-gramme after pancreaticoduodenectomy reduces delayed gastric emptying. Br J Surg. 2008;95:1387-1393. 219. Zouros E, Liakakos T, Machairas A, et al. Improvement of gastric emptying by enhanced recovery after pancreaticoduo-denectomy. Hepatobiliary Pancreat Dis Int. 2016;15:198-208. 220. Abu Hilal M, Di Fabio F, Badran A, et al. Implementation of enhanced recovery programme after pancreatoduodenectomy: a single-centre UK pilot study. Pancreatology. 2013;13:58-62. 221. Braga M, Pecorelli N, Ariotti R, et al. Enhanced recovery after surgery pathway in patients undergoing pancreaticoduodenec-tomy. World J Surg. 2014;38:2960-2966.Brunicardi_Ch50_p2113-p2136.indd 213301/03/19 9:39 AM 2134SPECIFIC CONSIDERATIONSPART II 222. Coolsen MM, van Dam RM, Chigharoe A, et al. Improving outcome after pancreaticoduodenectomy: experiences with implementing an enhanced recovery after surgery (ERAS) program. Dig Surg. 2014;31:177-184. 223. Dai J, Jiang Y, Fu D. Reducing postoperative complications and improving clinical outcome: enhanced recovery after surgery in pancreaticoduodenectomy—a retrospective cohort study. Int J Surg. 2017;39:176-181. 224. Morgan KA, Lancaster WP, Walters ML, et al. Enhanced recovery after surgery protocols are valuable in pancreas sur-gery patients. J Am Coll Surg. 2016;222:658-664. 225. Pecorelli N, Capretti G, Balzano G, et al. Enhanced recovery pathway in patients undergoing distal pancreatectomy: a case-matched study. HPB (Oxford). 2017;19:270-278. 226. Richardson J, Di Fabio F, Clarke H, et al. Implementation of enhanced recovery programme for laparoscopic distal pancre-atectomy: feasibility, safety and cost analysis. Pancreatology. 2015;15:185-190. 227. Coolsen MM, van Dam RM, van der Wilt AA, et al. Sys-tematic review and meta-analysis of enhanced recovery after pancreatic surgery with particular emphasis on pancreatico-duodenectomies. World J Surg. 2013;37:1909-1918. 228. Kagedan DJ, Ahmed M, Devitt KS, et al. Enhanced recovery after pancreatic surgery: a systematic review of the evidence. HPB (Oxford). 2015;17:11-16. 229. Lei Q, Wang X, Tan S, et al. Application of enhanced recovery after surgery program in perioperative management of pancre-aticoduodenectomy: a systematic review (in Chinese). Zhong-hua Wei Chang Wai Ke Za Zhi. 2015;18:143-149. 230. Xiong J, Szatmary P, Huang W, et al. Enhanced recovery after surgery program in patients undergoing pancreaticoduode-nectomy: a PRISMA-compliant systematic review and meta-analysis. Medicine (Baltimore). 2016;95:e3497. 231. Coolsen MM, Bakens M, van Dam RM, et al. Implement-ing an enhanced recovery program after pancreaticoduo-denectomy in elderly patients: is it feasible? World J Surg. 2015;39:251-258. 232. Partelli S, Crippa S, Castagnani R, et al. Evaluation of an enhanced recovery protocol after pancreaticoduodenectomy in elderly patients. HPB (Oxford). 2016;18:153-158. 233. Tanaka R, Lee SW, Kawai M, et al. Protocol for enhanced recovery after surgery improves short-term outcomes for patients with gastric cancer: a randomized clinical trial. Gastric Cancer. 2017;20(5):861-871. 234. Mingjie X, Luyao Z, Ze T, et al. Laparoscopic radical gastrec-tomy for resectable advanced gastric cancer within enhanced recovery programs: a prospective randomized controlled trial. J Laparoendosc Adv Surg Tech A. 2017;27(9):959-964. 235. Abdikarim I, Cao XY, Li SZ, et al. Enhanced recovery after surgery with laparoscopic radical gastrectomy for stomach carcinomas. World J Gastroenterol. 2015;21:13339-13344. 236. Beamish AJ, Chan DS, Blake PA, et al. Systematic review and meta-analysis of enhanced recovery programmes in gas-tric cancer surgery. Int J Surg. 2015;19:46-54. 237. Chen ZX, Liu AH, Cen Y. Fast-track program vs traditional care in surgery for gastric cancer. World J Gastroenterol. 2014;20:578-583. 238. Makuuchi R, Sugisawa N, Kaji S, et al. Enhanced recov-ery after surgery for gastric cancer and an assessment of preoperative carbohydrate loading. Eur J Surg Oncol. 2017;43:210-217. 239. Mortensen K, Nilsson M, Slim K, et al. Consensus guidelines for enhanced recovery after gastrectomy: Enhanced Recov-ery After Surgery (ERAS[R]) Society recommendations. Br J Surg. 2014;101:1209-1229. 240. Gemmill EH, Humes DJ, Catton JA. Systematic review of enhanced recovery after gastro-oesophageal cancer surgery. Ann R Coll Surg Engl. 2015;97:173-179. 241. Ford SJ, Adams D, Dudnikov S, et al. The implementation and effectiveness of an enhanced recovery programme after oesophago-gastrectomy: a prospective cohort study. Int J Surg. 2014;12:320-324. 242. Schmidt HM, El Lakis MA, Markar SR, et al. accelerated recovery within standardized recovery pathways after esopha-gectomy: a prospective cohort study assessing the effects of early discharge on outcomes, readmissions, patient satisfac-tion, and costs. Ann Thorac Surg. 2016;102:931-939. 243. Tang J, Humes DJ, Gemmil E, et al. Reduction in length of stay for patients undergoing oesophageal and gastric resec-tions with implementation of enhanced recovery packages. Ann R Coll Surg Engl. 2013;95:323-328. 244. Findlay JM, Gillies RS, Millo J, et al. Enhanced recovery for esophagectomy: a systematic review and evidence-based guidelines. Ann Surg. 2014;259:413-431. 245. Markar SR, Karthikesalingam A, Low DE. Enhanced recovery pathways lead to an improvement in postoperative outcomes following esophagectomy: systematic review and pooled anal-ysis. Dis Esophagus. 2015;28:468-475. 246. Barreca M, Renzi C, Tankel J, et al. Is there a role for enhanced recovery after laparoscopic bariatric surgery? Preliminary results from a specialist obesity treatment center. Surg Obes Relat Dis. 2016;12:119-126. 247. Hahl T, Peromaa-Haavisto P, Tarkiainen P, et al. Outcome of laparoscopic gastric bypass (LRYGB) with a program for enhanced recovery after surgery (ERAS). Obes Surg. 2016;26:505-511. 248. Lemanu DP, Singh PP, Berridge K, et al. Randomized clinical trial of enhanced recovery versus standard care after laparo-scopic sleeve gastrectomy. Br J Surg. 2013;100:482-489. 249. Rickey J, Gersin K, Yang W, et al. Early discharge in the bar-iatric population does not increase post-discharge resource utilization. Surg Endosc. 2017;31:618-624. 250. Malczak P, Pisarska M, Piotr M, et al. Enhanced recovery after bariatric surgery: systematic review and meta-analysis. Obes Surg. 2017;27:226-235. 251. Singh PM, Panwar R, Borle A, et al. Efficiency and safety effects of applying ERAS protocols to bariatric surgery: a sys-tematic review with meta-analysis and trial sequential analysis of evidence. Obes Surg. 2017;27:489-501. 252. Fayezizadeh M, Petro CC, Rosen MJ, et al. Enhanced recov-ery after surgery pathway for abdominal wall reconstruction: pilot study and preliminary outcomes. Plast Reconstr Surg. 2014;134:151S-159S. 253. Jensen KK, Brondum TL, Harling H, et al. Enhanced recovery after giant ventral hernia repair. Hernia. 2016;20:249-256. 254. Majumder A, Fayezizadeh M, Neupane R, et al. Ben-efits of multimodal enhanced recovery pathway in patients undergoing open ventral hernia repair. J Am Coll Surg. 2016;222:1106-1115. 255. Arumainayagam N, McGrath J, Jefferson KP, et al. Introduc-tion of an enhanced recovery protocol for radical cystectomy. BJU Int. 2008;101:698-701. 256. Cerruto MA, De Marco V, D’Elia C, et al. Fast track surgery to reduce short-term complications following radical cystectomy and intestinal urinary diversion with Vescica Ileale Padovana neobladder: proposal for a tailored enhanced recovery pro-tocol and preliminary report from a pilot study. Urol Int. 2014;92:41-49. 257. Mukhtar S, Ayres BE, Issa R, et al. Challenging boundaries: an enhanced recovery programme for radical cystectomy. Ann R Coll Surg Engl. 2013;95:200-206. 258. Campos PAC, Martinez JG, Fernandez PJG, et al. Periop-erative fast track program in intraoperative hyperthermic intraperitoneal chemotherapy (HIPEC) after cytoreduc-tive surgery in advanced ovarian cancer. Eur J Surg Oncol. 2011;37:543-548.Brunicardi_Ch50_p2113-p2136.indd 213401/03/19 9:39 AM 2135OPTIMIZING PERIOPERATIVE CARE: ENHANCED RECOVERY AND CHINESE MEDICINECHAPTER 50 259. Chapman JS, Roddy E, Ueda S, et al. enhanced recovery path-ways for improving outcomes after minimally invasive gyne-cologic oncology surgery. Obstet Gynecol. 2016;128:138-144. 260. de Groot JJ, van Es LE, Maessen JM, et al. Diffusion of Enhanced Recovery principles in gynecologic oncology sur-gery: is active implementation still necessary? Gynecol Oncol. 2014;134:570-575. 261. Lindemann K, Kok PS, Stockler M, et al. enhanced recov-ery after surgery for advanced ovarian cancer: a system-atic review of interventions trialed. Int J Gynecol Cancer. 2017;27:1274-1282. 262. Marx C, Rasmussen T, Jakobsen DH, et al. The effect of accel-erated rehabilitation on recovery after surgery for ovarian malignancy. Acta Obstet Gynecol Scand. 2006;85:488-492. 263. Wijk L, Franzen K, Ljungqvist O, et al. Implementing a structured enhanced recovery after surgery (ERAS) protocol reduces length of stay after abdominal hysterectomy. Acta Obstet Gynecol Scand. 2014;93:749-756. 264. Khan SK, Malviya A, Muller SD, et al. Reduced short-term complications and mortality following enhanced recovery pri-mary hip and knee arthroplasty: results from 6,000 consecu-tive procedures. Acta Orthop. 2014;85:26-31. 265. Scott NB, McDonald D, Campbell J, et al. The use of enhanced recovery after surgery (ERAS) principles in Scot-tish orthopaedic units—an implementation and follow-up at 1 year, 2010-2011: a report from the Musculoskeletal Audit, Scotland. Arch Orthop Trauma Surg. 2013;133:117-124. 266. Zhou B, Sun R. About the cultural support of the develop-ment of traditional chinese medicine. The 12th National Symposium on Chinese Medicine Culture. 74-79. 267. Yang M, Li J. Analysis on the development of tradi-tional chinese medicine. Contemporary Medicine Forum. 2014;12:277-278. 268. Yu M. Chinese medicine and Western medicine: two kinds of philosophies and two different cultures of medicine. Journal of Zhengzhou University of Light Industry (Social Science). 2012;13:7-12. 269. Yue X. The Historical stages of the formation and develop-ment of traditional Chinese medicine. Guangming Journal of Chinese Medicine(CJGMCM). 2012;27:207-210. 270. Tong X, Zhang Z, Li A. The confusion of chinese medicine development and its countermeasures. Chinese Journal of Basic Medicine in Traditional Chinese Medicine. 2003;9:52-55. 271. Geng D. Research progress of shiquan dabu decoction. Chinese Traditional Patient Medicine. 2003;25:837-840. 272. Han D, Chen Z, Xing B. Therapeutic rules of analogous pre-scriptions for tonify and replenish the middle qi. Chinese Archives of Traditional Chinese Medicine. 2010;28:595-598. 273. Liu K, Wang B. Influences of Buzhong Yiqi Decoction on gastrointestinal feunction and nutrition status of gastric carcinoma after operation. Chinese Journal of Experimental Traditional Medical Formulae. 2015;21:152-156. 274. Su P, Li W. The effect of Shiquan Dabu Decoction tegether with enteral nutrition for patients with lung cancer after sur-gery. Journal of Nanjing University of Traditional Chinese Medicine. 2015;31:17-20. 275. Yang A, Xiang F, Yang L. Effect of Shiquan Dabu Tang com-bined with Wuwei Xiaodu Yin on immune functions in post-operative Qi and blood deficiency patients with esophagus cancer. Chinese Journal of Experimental Traditional Medical Formulae. 2016;22:174-178. 276. Cui J. The effects of Shenmai injection on cellular immuno-logic function in the perioperative patients with gastroentero-logical tumors. Pract Clin Med. 2007;8:39-41. 277. Liang C. Clinical observation on the protective effect of huangqi injection on the myocardium of coronary heart dis-ease in the perioperative period. Shan Xi Journal of Tradi-tional Chinese Medicine. 2011;17:17-18. 278. Ruan L, Deng Y. Study of effect of xiaoaiping in enhanc-ing efficacy of neoadjuvant chemotherapy for breast cancer and its mechanism. Journal of Chinese Materia Medica. 2005;40:749-752. 279. Tan M, Guo Z, Bin X. The effect of elemene local intra-arte-rial infusion to apoptosis and proliferation in breast cancer. Chinese J Clin Oncol. 2001;28:267-269. 280. Wu X. Research on Acute Abdomen. 1st ed. China; 1988. 281. Xie J, Wu X. Research on three cheng qi decoction used in the bowel preparation. Chinese Journal of Surgery of Integrated Traditional and Western Medicine. 1996;2:355-357. 282. Li X. Flavored pure ginseng decoction treating 75 cases of traumatic shock. Journal of Emergency in Traditional Chinese Medicine. 2003;12:413. 283. Ji C, Liu J, Chen H. Effect of Qingdan Decoction combined with biliary decompression on the liver function and inflam-matory factors in acute cholangitis severe type rats. Journal of Traditional Chinese Medicine. 2013;54:512-515. 284. Wang X, Zhang X. The effect of Qingyi decoction on bacte-rial and endotoxin translocation from intestine in acute hem-orrhagic necrotizing pancreatitis in rat. Chinese Journal of General Surgery. 2010;19:255-258. 285. Yao G, Wu X. Clinical study of treatment of severe acute pancreatitis with Qingyi decoction. Chinese Journal of Surgery of Integrated Traditional and Western Medicine. 1997;3:244-246. 286. Han J. Research on acupuncture anesthesia-analgesia. Acupunct Res. 2016;41:377-387. 287. Arranz L, Guayerbas N, Siboni L. Effect of acupuncture treat-ment on the immune function impairment found in anxious women. Am J Chinese Med. 2007;35:35-51. 288. Liu Y. The effect of transcutaneous electroacupuncture on serum level of glucocose and cortisol in patient underwent thyroidectomy. Chinese Journal of Traditional Medical Science and Technology. 2013;20:180-181. 289. Sun Y, Gan TJ, Dubose JW, et al. Acupuncture and related techniques for postoperative pain: a systematic review of randomized controlled trials. Br J Anaesth. 2008;101:151-160. 290. Zhang Q, Gao Z, Wang H, et al. The effect of pre-treatment with transcutaneous electrical acupoint stimulation on the quality of recovery after ambulatory breast surgery: a pro-spective, randomised controlled trial. Anaesthesia. 2014;69: 832-839. 291. Zou D, Chen WH, Iwakiri K, et al. Inhibition of transient lower esophageal sphincter relaxations by electrical acu-point stimulation. Am J Physiol Gastrointest Liver Physiol. 2005;289:G197-G201. 292. Shiotani A, Tatewaki M, Hoshino E, et al. Effects of elec-troacupuncture on gastric myoelectrical activity in healthy humans. Neurogastroenterol Motil. 2004;16:293-298. 293. Tatewaki M, Strickland C, Fukuda H, et al. Effects of acupuncture on vasopressin-induced emesis in con-scious dogs. Am J Physiol Regul Integr Comp Physiol. 2005;288:R401-R408. 294. Arnberger M, Stadelmann K, Alischer P, et al. Monitoring of neuromuscular blockade at the P6 acupuncture point reduces the incidence of postoperative nausea and vomiting. Anesthe-siology. 2007;107:903-908. 295. El-Deeb AM, Ahmady MS. Effect of acupuncture on nausea and/or vomiting during and after cesarean section in compari-son with ondansetron. J Anesth. 2011;25:698-703. 296. Feng C, Popovic J, Kline R, et al. auricular acupressure in the prevention of postoperative nausea and emesis a randomized controlled trial. Bull Hosp Jt Dis (2013). 2017;75:114-118. 297. Okuno S, Hirayama K, Inoue J. Effects of rikkunshito on the postoperative nausea and vomiting (PONV) after laparoscopic gynecological surgery. Masui. 2008;57:1502-1509.Brunicardi_Ch50_p2113-p2136.indd 213501/03/19 9:39 AM 2136SPECIFIC CONSIDERATIONSPART II 298. Zhang X, Zhang D, Yang Y. Effects of Houpupaiqi Heji on the gastrintestinal function of patients after gastric cancer surgery. Mod Oncol. 2015;23:1268-1270. 299. Zhang X, Yuan H, Qin W. Study on early enteral nutrition combined with acupuncture to promote the recovery of gastro-intestinal function in patients after surgery. Chinese Journal of Surgery of Integrated Traditional and Western Medicine. 2016;22:542-545. 300. Jian W, Heng L, Hui QQ. Effect of Da-Cheng-Qi-Tang on gastrointestinal motility in patients undergoing laparotomy. Hepatogastroenterology. 2011;58:1887-1892. 301. You S, Wu X, Liu M. Effects of dachengqi decoction on gut hormones and intestinal movement after cholecystectomy. Zhongguo Zhong Xi Yi Jie He Za Zhi. 1994;14:522-524. 302. Yang Y, Zuo HQ, Li Z, et al. Comparison of efficacy of simo decoction and acupuncture or chewing gum alone on postop-erative ileus in colorectal cancer resection: a randomized trial. Sci Rep. 2017;7:37826. 303. Chen Z, Cao L, Wen Z, et al. Study of Evodia hot compress plus electro-acupuncture in patients who have undergone abdominal surgery. Int J Clin Exp Med. 2015;8:16167-16174. 304. Wu X. Practice of Abdominal Surgery. 3rd ed. Tianjin Science and Technology Press; 2004. 305. Cui Z, Kong D. 74 cases of biiliary liver abscess treated with integrated traditional and western medicine. Chinese Journal of Surgery of Integrated Traditional and Western Medicine. 2014;20:167-169. 306. Sun S, Xu W. Effects of TPN and immune regulator radix astragali on postoperative patients of obstructive jaundice. J Parenter Enteral Nutr. 2002;9:151-157. 307. Ma X, Yang W, Zhang X. The study of effect of shiquan dabu decoction in surgeical nutrition therapy. Beijing Journal of Traditional Chinese Medicine. 1991;4:31-32. 308. Dong Y, Cui Z. Acupuncture research on adhesive intestinal obstruction. Clin J Chinese Med. 2001;3:86-88. 309. Li G, Ma J, Shang H, et al. Application of Dechengqi decoc-tion in abdominal surgery. World Chinese Journal of Diges-tion. 2008;16:1672-1676. 310. Li H, Hong Y, Huang M. Clinical effect observation of Chinese herbal enema, external application and acupuncture in adhe-sive ileus. Journal of Guangzhou University of Traditional Chinese Medicine. 2007;24:282-285.Brunicardi_Ch50_p2113-p2136.indd 213601/03/19 9:39 AM
Understanding, Evaluating, and Using Evidence for Surgical PracticeAndrew J. Benjamin, Andrew B. Schneider, Jeffrey B. Matthews, and Gary An 51chapterINTRODUCTIONThe singular importance of this chapter rests on the following chain of reasoning:1. The state of surgical science and knowledge is constantly changing.2. The education of a surgeon is a continuous process.3. Surgeons need to know how to evaluate new surgical knowl-edge to maintain their education in order to best serve their patients.4. This chapter provides guidance as to how surgeons might navigate, interpret and apply this new knowledge.Notably, this reasoning also applies to the process of acquisition of new knowledge itself, which explains why this inaugural chapter on evidence-based medicine is occurring in the 11th edition of this book. Recognizing the impermanence and fluidity of knowledge is a critical insight for the responsible surgeon, but so too is realizing that “good practice” cannot occur without reference points as to what should be done given the current imperfect state of knowledge. These dual recognitions inform the organization of this chapter, which introduces and describes the currently accepted approach to evidence-based medicine, and then follows by noting a series of current issues that anticipate the likelihood that what is meant by “evidence-based medicine” will evolve over the coming years. Also note that this chapter is not intended to be a primer on statistics and clinical trial design; there are entire textbooks devoted to those subjects. Rather, this chapter will focus on how those tools are aggregated and presented in order to inform a surgeon how to keep abreast with current developments in practice.WHAT IS EVIDENCE-BASED MEDICINE?For centuries, the practice of medicine was guided primarily by anecdotal experience, often based on rationales that did not arise from a rigorous scientific process and sustained by the fundamental barriers associated with being able to learn from one’s experience (e.g., cognitive bias). For example, treatments such as bloodletting and purging were based on ostensible prin-ciples of bodily humors originating from the Ancient Greeks, and persisted well into the 18th century despite repeated disas-trous outcomes. To a great degree, the goal of the Scientific Method, through its emphasis on skepticism and falsifiability, is predicated upon overriding observational/experiential bias by the application of rigorous methodology statistical analysis. The dangers of bias were recognized at the dawn of the Scien-tific Era, and continue to manifest today (Box: The History and Sources of Bias in Biomedical Literature).Introduction2137What is Evidence-Based Medicine?2137Searching for Information: Patient/Population, Intervention, Comparison, and Outcome / 2139Types of Studies / 2139Hierarchies of Evidence / 2140Tools to Evaluate a Body of Evidence / 2140Synthesis of Evidence—Clinical Guidelines / 2142The Challenges of Applying EBM to Surgery2144Analysis of a Surgical Randomized Control Trial / 2144Internal Validity / 2144External Validity / 2146Additional Challenges to Conducting a Surgical RCT / 2146Use and Misuse of Statistical Significance2147Type I and Type II Errors / 2147P Values / 2147Alternative to P Values / 2148How do the Tools of EBM Perform?2148External Consistency / 2148Internal Consistency / 2148System Issues / 2148Validity / 2149Implications of EBM / 2149The Alternatives to EBM2149What can Researchers do to Improve the Validity of Research Findings?2149The History and Sources of Bias in Biomedical LiteratureIn Sir Francis Bacon’s initial description of the scientific method in his Novum Organum1 he notes what he terms the “idols of the mind,” in essence recognizing and classifying the sources of cognitive bias that limit the reliability of sub-jective observation and interpretation. These “idols” are:• Idols of the tribe (Idola tribus): A humans’ tendency to per-ceive more order and regularity in systems than truly exists, and arises from their preconceived ideas about things• Idols of the cave (Idola specus): Arising from an individ-ual’s personal limitations in reasoning due to particular personalities, subjective likes and dislikesBrunicardi_Ch51_p2137-p2152.indd 213728/02/19 4:19 PM 2138• Idols of the marketplace (Idola fori): Arising from the con-fusion in the use of language and taking some words in sci-ence to have a different meaning than their common usage• Idols of the theatre (Idola theatri): Arising from the following of academic dogma and not asking questions about the worldThese descriptions still resonate today, illustrating just how long the dangers of cognitive bias have been recognized, and just how embedded those tendencies may be. For instance, the following are sources of bias in biomedical literature:• Publication bias: publishers incentivized to accept posi-tive results• Prevailing field bias: supporting entrenched opinions• Citation bias: tendency to cite positive studies• Time-lag bias: delay the reporting of negative results• Reporting bias: emphasizing positive over negative resultsKey Points1 Cognitive bias is inescapable, and limits the ability of both individual practitioners and the surgical field in general, to advance and improve in a scientific fashion. Evidence Based Medicine is an attempt to codify the process of interpret-ing experience, assessing the literature and translating it into practice.2 Dealing with and interpreting the vast amount of surgical literature available on the Internet can be daunting, and this task can be aided by the application of identified formats for executing online search. The PICO (Patient/Population, Intervention, Comparison and Outcome) format is a com-monly used method for codifying online search.3 Not all literature or evidence is created equal. There exist various approaches, such as the Oxford Center for Evidence Based Medicine (CEBM) Levels of Evidence or the GRADE (Grading and Recommendations, Assessment, Development and Evaluation) system, that have been developed to provide guidance in assessing and reifying scientific literature.4 The conversion of evidence into clinical practice often mani-fests in the creation of clinical guidelines. As with all things related to evidence based medicine, not all guidelines are created equal, and therefore there are certain characteristics that can be used to evaluate the quality of a particular clini-cal guideline.5 There are specific challenges in the application of evidence based medicine to surgery, not least of which is the difficulty in performing a truly randomized clinical trial. The CONSORT (Consolidated Standard of Reporting Clinical Trials) guidelines were developed to serve as minimal rec-ommendations for reporting randomized clinical trials.6 The well-known saying “There are lies, damn lies and then statistics” points to the recognition that statistical tools can be prone to misuse, and emphasizes the need to understand the appropriate application, limits of and interpretation of reported statistics.7 Evidence based medicine has not thus far been held to its own standards of evidence. Recognizing that available “evidence” is a constantly shifting landscape should warn one against the dangers of epistemic certainty, and further emphasizes the fact that surgical education is an ongoing and perpetual process.In the medical field, the transition from accumulated anec-dote to true statistical analysis can be seen in the emergence of clinical epidemiology as a field in 1938, which began to shift the focus from descriptions of individual patients to trends affect-ing entire populations. This shift, however, was accompanied by new challenges, as different means of turning anecdotal experience into statistics (e.g., case series, observational stud-ies, retrospective studies, prospective studies) meant that now practitioners needed to be able to compare these “scientific” presentations against each other in order to best establish their practices. The processes and methods of aggregating, compar-ing, and translating these different types of data from the medi-cal literature into clinical practice were explicitly established in the latter part of the 20th century, particularly arising from efforts at McMaster University, which eventually led to a fun-damental framework for literature-informed medical decision-making known as evidence-based medicine (EBM).EBM is defined as the “conscientious, explicit and judi-cious use of current best evidence in making decisions about treating individual patients.”2,3 This term was coined by Gordon Guyatt in 1991, focusing on assessing the credibility of the medical literature, understanding the presented results, and applying the information to individual practice. EBM is defined by three epistemological principles4:• Principle 1: Not all evidence is created equal, and the practice of medicine should be based on the best available evidence• Principle 2: The pursuit of truth is best accomplished by evaluation of the totality of the evidence, and not selecting evidence that favors a particular claim• Principle 3: Clinical decision-making requires consideration of patients’ values and preferenceThe adoption of EBM in the discipline of surgery has lagged compared to nonsurgical specialties. To a great extent, this is due to the challenges of achieving the highest level of evidence noted in principle 1: definitive conclusions from a randomized controlled trial (RCT). A literature analysis of MEDLINE from 1966 to 2000 demonstrated that only 15.1% of the 134,689 RCTs evaluated a surgical topic.5 In the early days of EBM during the 1990s, surgical RCTs accounted for only 7% of published articles in surgical journals; most of the articles were retrospective studies and case series,6 which are essentially aggregated anecdotes. Over the next decade, the rela-tive frequency of RCTs in surgery further decreased, account-ing for 3.4% of all publications in 2003.5 As a result, most of the available evidence to guide surgical practice today remains based on retrospective reviews, nonrandomized trials, and expert opinion. The barriers to performing prospective RCTs in surgery remain substantial: standardization of clinical pre-sentation and, of course, accounting for variations in operative technique and the ability to blind studies to reduce experimental bias. The relative paucity in RCTs in surgery make it even more 1Brunicardi_Ch51_p2137-p2152.indd 213828/02/19 4:19 PM 2139UNDERSTANDING, EVALUATING, AND USING EVIDENCE FOR SURGICAL PRACTICECHAPTER 51important that surgeons understand the best-practice methods to critically appraise available evidence, while recognizing the limitations and potential pitfalls of those methods, in order to optimize their practice and decision-making regarding patient care when high quality evidence may not be available. Herein we present the steps of such a workflow, starting with an initial search for information, identification of the classes of informa-tion that such a search can return, and then guidelines by which that information is evaluated, compared, and aggregated.Searching for Information: Patient/Population, Intervention, Comparison, and OutcomeTechnology has substantively changed how information can be sought and retrieved. Online search engines such as MEDLINE via PubMed, which contains over 26 million citations, have dramatically enhanced the ability to access bio-medical literature.7 However, there is a very real potential for such access to become overwhelming. Effective and efficient use of search engines can be enhanced by framing the clinical question in a format designed to improve the relevancy of search results. PICO is one such format, where the acronym stands for Patient/Population, Intervention, Comparison, and Outcome.8• Patient or population is the specific group of individuals for which the questions is being asked.• Intervention is the treatment or technique of interest for the defined patient or population. Intervention might be a proce-dure, such as “laparoscopic appendectomy” or be defined as an exposure of interest, such as “smoking.”• Comparison is the alternative treatment or technique to which you are comparing the intervention. Terms might include, for example, “open appendectomy” or “observation.”• Outcome of interest is the final step of the PICO format. Examples include “mortality,” “operative time,” and “wound infection.”As with all online search strategies, there is a trade-off between the specificity of the search and the breadth of the returned items. When using PICO to inform clinical decision-making, it is generally advantageous to be as precise and specific as possible when initiating a search: this increases the likelihood the search will return information most germane to the particular clinical scenario. This is accomplished by the use of “AND” in the framing of the search to encompass the set of questions of interest. For example, one could construct a query consisting of a particular procedure, with a particular method, with a particular outcome metric, such as “(distal pancreatectomy) AND splenectomy AND (splenic preservation) AND morbidity” to frame a PICO question.Types of StudiesPrinciple 1 of EBM states that not all evidence is created equal; therefore, evaluating the evidentiary quality of the results of an online search requires classifying the returned search items by type of study. As noted earlier, acknowledging that the “gold standard” level of evidence, RCTs, are rare in the surgical literature, the application of EBM to surgery requires increased familiarity with the types of alternative studies available, with their relative strengths and weaknesses. These types are listed below:• Meta-analysis: A meta-analysis is a technique to combine similarly published data in order to increase the overall 2statistical power compared to each study individually. The amount of interstudy heterogeneity (methods, study popula-tion, endpoints, etc.) should be limited to allow for the gen-eration of informative conclusions. The pooling of similar studies enables researchers to generate a new statistical con-clusion based on a substantially larger sample size. These approaches, though useful, have their limitations: the inclu-sion of inappropriate studies and the mislabeling of a meta-analysis leading to inaccurate conclusions. Attention should be directed toward this type of evidence when clinical guide-lines do not exist.• Systematic Review: Like meta-analyses, systematic reviews use standardized methods to search for and appraise studies in order to attempt to reduce bias. However, systematic reviews do not utilize quantitative methods to summarize the results. For this reason, systematic reviews are often not considered to provide the same strength of evidence as a meta-analysis.• Cross-Sectional Studies: In a cross-sectional study, expo-sures and outcomes are measured at a single point in time. The prevalence of the outcome is then compared in patients who did and did not have the exposure. Multiple exposures and outcomes can be measured at the same time, which is an advantage; however, there are important limitations. One significant limitation is that a temporal relationship cannot be determined between exposure and outcome because they are measured simultaneously. These studies will often form the foundation for more definitive studies.• Case Control Study: In a case-control study, cohorts are determined by the presence or absence of a particular out-come of interest. This is in contrast to a cross-sectional study where samples are determined by the presence or absence of an exposure. Once the samples have been identi-fied based upon outcome, then possible prior exposures are identified, and the odds of those exposures are compared between cohorts.• Case Series: A Case Series involves a report of a small group of patients that share specified clinical features; this gener-ally does not include description of a control group. Case series are prevalent in the field of surgery, and some of the most famous eponymous procedures originated from case series, including the Whipple procedure9 and Nissen fundo-plication.10 This type of study provides weak evidence due to issues with patient selection, biases, and confounding factors. However, the findings from a case series can be used to gen-erate hypotheses for a randomized control trial.• Expert Opinion: Expert opinions represent the lowest level of evidence and is representative of a clinician’s individual experience and anecdotes. Prior to evidence-based medicine, expert opinion was the primary means of teaching medicine and shaping the field. However, the opinions of clinicians can vary substantially leading to a wide range of potential unproven treatments for a medical issue. Thus, expert opinion should only be solicited in the complete absence of evidence in the literature.It should also be noted that irrespective of the type of study or recommendation, there are additional factors that can contribute to bias in publication. To a great degree these are extrapolations of the sources of individual cognitive bias, but writ large across an entire community (see Box: The History and Sources of Bias in Biomedical Literature).Brunicardi_Ch51_p2137-p2152.indd 213928/02/19 4:19 PM 2140SPECIFIC CONSIDERATIONSPART IIHierarchies of EvidenceThe original architects of EBM codified the notion that certain types of evidence are superior to others based on charac-teristics of study design, depicting this concept as a “pyra-mid,” with expert opinion comprising the base of the pyramid and randomized controlled trials at the peak (Fig. 51-1). Although conceptually appealing, this initial attempt to “rank” the evidence was relatively simplistic and rested on unproven assumptions that RCT were inherently superior to observational studies. While RCTs theoretically provide higher quality evi-dence compared to observational studies, RCTs can also have significant limitations and biases (see later section, “The Chal-lenges of Applying EBM to Surgery”). Furthermore, translating the results from well-crafted RCTs can be challenging, where the specific restrictive criteria for executing a high-quality RCT can inherently limit its applicability to clinical scenarios not specifically noted or tested in the RCT. Therefore, one could find oneself in the situation of trying to compare an RCT on a related but clearly distinct use case with a well performed obser-vational study that more closely approximated the clinical sce-nario in question. This led to the subsequent development of more refined frameworks to assess the quality of evidence in order to try and address these issues, although there is currently no consensus on a single framework. The current situation is that while many newer systems have devised ways in which studies can move up and down the pyramid, for well-designed studies, the pyramid largely remains intact.The initial hierarchies of evidence were limited because they entangled the method of evidence collection with underly-ing study design. They failed to recognize principle 2 of EBM: “the pursuit of truth is best accomplished by evaluation of the totality of evidence” and the principle that “health claims be based upon systematic reviews which summarize the best avail-able evidence.”4 The earliest hierarchies positioned systematic reviews at the top of the pyramid followed by RCTs; how-ever, this classification failed to acknowledge that systematic reviews can summarize any type of evidence. Cohort studies, case-control studies, and even case reports can be the subject of systematic review. The importance of systematic review in EBM cannot be understated: systematic reviews are the most 3cited type of study, and these studies are essential for the devel-opment of clinical guidelines and influencing the direction of future studies.2,11 When applied in a timely manner, systematic reviews have resulted in major practice changes, for example, encouraging early postoperative enteral feeding compared to parenteral nutrition to prevent sepsis.12Tools to Evaluate a Body of EvidenceBy 2002, over 100 unique evidence rating systems existed,2 and the differences among them may be nontrivial. Depending upon the specific criteria used, the “strength” of evidence might dif-fer widely from system to system. For example, the American Association of Orthopedic Surgeons (AAOS) published guide-lines in 2009 for prevention of venous thromboembolism (VTE) in patients undergoing hip or knee surgery that conflicted with the widely used American College of Chest Physician (ACCP) guidelines, despite having access to the same data. While the ACCP considered VTE prophylaxis to be a grade 1 recommen-dation with level A evidence, the AAOS recommendation var-ied based upon risk of pulmonary embolism and bleeding, with no recommendation being greater than B and all recommenda-tions being based upon level III evidence.13 In the following section we present a few of the most widely accepted tools for assessing the quality of evidence.CEBM Levels of Evidence. One of the most widely adopted systems for grading evidence is the Oxford Center for Evi-dence Based Medicine (CEBM) Levels of Evidence. The origi-nal CEBM system was released in 2000 and was subsequently updated in 2011. Earlier systems of evidence ranking were criti-cized because they categorically placed randomized trials above observational studies, although observational studies and even anecdotes can occasionally give the “best” evidence in certain clinical situations. CEBM was therefore developed to not only improve the ranking of evidence but also to aid clinicians in quickly searching for the best evidence available for a given clinical question (Table 51-1). It is designed as both a tool for traditional critical appraisal as well as a pragmatic system that clinicians can use to answer clinical questions in real time. It can be used as a heuristic that clinicians and patients can utilize to answer clinical questions quickly and without resorting to preap-praised sources.14 The CEBM Levels of Evidence system begins with choosing a clinical question from the first column of the table provided by the creators (see Table 51-1) (for example, “How common is the problem?”, “Does this intervention help?”, or “Is this test worthwhile?”). Therefore, each row of the CEBM Levels of Evidence represents a series of steps one should fol-low to find the best evidence for the question chosen. Strong evidence is likely to be found in columns to the left of the table, while weak evidence will be found in columns to the right. After completing a clinical query using the table, a final “level” of evidence is assigned on a scale from 1 to 5 based upon the types of studies found to answer the initial question (1 = highest rated evidence; 5 = lowest rated evidence). However, the levels are not intended to provide one with a definitive judgment regarding the quality of evidence. There may be cases where “lower level” evi-dence—for example, an observational study with a large treat-ment effect—provides stronger evidence than a “higher level” study, such as a systematic review with an inconclusive result.CEBM should be thought of as a hierarchy of the likely best evidence. An advantage of CEBM is that it allows the potential of resorting to individual studies for the best evidence, while other systems generally assume that there is a systematic RCTCohort studyCase control studyCase seriesCase reportsAnimal researchIn-vitro researchExpert experience/opinionFigure 51-1. Evidence-based hierarchy.Brunicardi_Ch51_p2137-p2152.indd 214028/02/19 4:19 PM 2141UNDERSTANDING, EVALUATING, AND USING EVIDENCE FOR SURGICAL PRACTICECHAPTER 51Table 51-1Oxford center for evidence-based medicine 2011 levels of evidenceQUESTIONSTEP 1 (LEVEL 1*)STEP 2 (LEVEL 2*)STEP 3 (LEVEL 3*)STEP 4 (LEVEL 4*)STEP 5 (LEVEL 5)How common is the problem?Local and current random sample surveys (or censuses)Systematic review of surveys that allow matching to local circumstances**Local non-random sample**Case-series**n/aIs this diagnostic or monitoring test accurate? (Diagnosis)Systematic review of cross-sectional studies with consistently applied reference standard and blindingIndividual cross-sectional studies with consistently applied reference standard and blindingNon-consecutive studies, or studies without consistently applied reference standards**Case-control studies, or “poor or non-independent reference standard**Mechanism-based reasoningWhat will happen if we do not add a therapy? (Prognosis)Systematic review of inception cohort studiesInception cohort studiesCohort study or control arm of randomized trial*Case-series or case-control studies, or poor quality prognostic cohort study**n/aDoes this intervention help? (Treatment Benefits)Systematic review of randomized trials or n-of-1 trialsRandomized trial or observational study with dramatic effectNon-randomized controlled cohort/follow-up study**Case-series, case-control studies, or historically controlled studies**Mechanism-based reasoningWhat are the COMMON harms? (Treatment Harms)Systematic review of randomized trials, systematic review of nested case-control studies n-of-1 trial with the patient you are raising the question about, or observational study with dramatic effectIndividual randomized trial or (exceptionally) observational study with dramatic effectNon-randomized controlled cohort/follow-up study (post-marketing surveillance) provided there are sufficient numbers to rule out a common harm. (For long-term harms the duration of follow-up must be sufficient.)**Case-series, case-control, or historically controlled studies**Mechanism-based reasoningWhat are the RARE harms? (Treatment Harms)Systematic review of randomized trials or n-of-1 trialRandomized trial or (exceptionally) observational study with dramatic effect   Is this (early detection) test worthwhile? (Screening)Systematic review of randomized trialsRandomized trialNon-randomized controlled cohort/follow-up study**Case-series, case-control, or historically controlled studies**Mechanism-based reasoning*Level may be graded down on the basis of study quality, Imprecision, Indirectness (study PICO does not match questions PICO), because of inconsistency between studies, or because the absolute effect size is very small; Level may be graded up if there is a large or very large effect size.**As always, a systematic review is generally better than an individual study.How to cite the Levels of Evidence TableOCEBM Levels of Evidence Working Group*. “The Oxford 2011 Levels of Evidence”.Oxford Centre for Evidence-Based Medicine. http://www.cebm.net/index.aspx?o=5653*OCEBM Table of Evidence Working Group = Jeremy Howick, Iain Chalmers (James Lind Library), Paul Glasziou, Trish Greenhaigh, Carl Heneghan, Alessandro Liberati, Ivan Moschetti, Bob Phillips, Hazel Thornton, Olive Goddard, and Mary HodgkinsanBrunicardi_Ch51_p2137-p2152.indd 214128/02/19 4:19 PM 2142SPECIFIC CONSIDERATIONSPART IIDefinitions of GRADE Evidence QualityHigh quality – Further research is very unlikely to change confidence in the estimate of effect.Moderate quality – Further research is likely to have an important impact confidence in the estimate of effect and may change the estimate.Low quality – Further research is very likely to have an important impact on confidence in the estimate of effect and is likely to change the estimate.Very low quality – Any estimate of effect is very uncertain.review available. Additionally, other systems are built around considering the strength of evidence for therapeutic effects and harms, while CEBM allows appraisal of evidence for prevalence of disease, accuracy of diagnostic tests, prognosis, therapeutic effects, rare harms, common harms, and usefulness of screening.Grading and Recommendations, Assessment, Development, and Evaluation. Alternatively, the Grading and Recommendations, Assessment, Development and Evaluation (GRADE) system classifies the quality of evidence into one of four levels: high, moderate, low, and very low15 (Box: Definitions of GRADE Evidence Quality). Evidence quality in the GRADE system is not assigned solely on study design. For example, a randomized controlled trial begins at “high quality,” but may be demoted due to one or more of the following: study limitations, inconsistent results, indirectness of evidence, imprecision, or reporting bias. Alternatively, observational studies (cohort or case-control studies) start as “low quality” but may be upgraded if there is a large magnitude of the treatment effect, evidence of a dose-response relationship, or if all plausible biases would decrease the magnitude of a treatment effect. Thus, the GRADE system of evaluating the quality of evidence provides more granularity than the traditional hierarchy system, which assigns quality based upon study design alone. Although the GRADE system has significant advantages, it is more complex and has a steeper learning curve than traditional systems. Finally, GRADE is intended for appraising a body of evidence, such as in a systematic review.In addition to providing a transparent approach to grading evidence quality, the GRADE system outlines an approach to the development and assignment of strength to clinical recommendations. GRADE’s sophisticated hierarchy of evidence allows the system to protect against both superficial assessment and unwarranted confidence in all classes of study design. Since its development, the increasing use of GRADE has resulted in higher quality and rigor of systematic reviews due to standards outlined by the system.15 In creating a recommendation regarding a body of evidence, GRADE allows experts to account for limitations in bodies of evidence comprising of RCTs, while also allowing for the rating of observational studies as high quality in cases where RCTs are not feasible (i.e., an RCT cannot ethically be performed). GRADE therefore potentially allows for observational studies to provide definitive evidence of causal association (e.g., alcohol causing cirrhosis or asbestos causing mesothelioma) where RCTs may not be ethical or necessary.One of the major advantages of GRADE is that it specifi-cally addresses the process of moving from evidence to recom-mendations. The process begins with the creation of a summary of findings table. A summary of findings table consists of a presentation not only of evidence quality but also estimates of the relative and absolute effects of patient-centered outcomes (Fig. 51-2). The summary of findings format was created to min-imize framing effects, where different raters may come to varied conclusions based upon identical information due to the infor-mation having a contrasting presentation in terms of gain versus loss.16 GRADE and similar EBM systems specifically takes into consideration judgement of risk versus benefit, resource use, feasibility, and equity to attempt to make decision-making as consistent as possible across a range of reviewers.2 Despite all of the aforementioned considerations when constructing a guide-line, it is important to realize that patient values or preferences may immediately invalidate any recommendation. Evidence is often constructed based upon measurement of outcomes such as morbidity, mortality, or survival; however, patients may be more concerned with quality of life or avoiding invasive inter-ventions. GRADE attempts to acknowledges this intrinsic vari-ability within its system of grading.In terms of the overall strength of a recommendation that GRADE can assign, two grades are possible: “strong” and “weak.” A strong recommendation is one where positive effects of an intervention clearly outweigh the negative effects or vice versa. A weak recommendation is one where the asso-ciation is less clear, either because of low quality evidence or because the evidence clearly suggests that the positive and negative effects are similar. However, quality of evidence is not the only factor that affects the strength of a recommenda-tion (Table 51-2). Factors such as uncertainty of patient values or whether an intervention is an appropriate use of resources can play a role in the strength of a recommendation as well. Therefore, it is important to note that a “strong” or “weak” rec-ommendation may be given regardless of the classification of the evidence. For example, there is a strong recommendation that patients with Zollinger-Ellison syndrome be treated with PPI. This recommendation is made despite weak evidence to support this practice because the potential benefits far out-weigh the potential risks.17Although the systems for grading evidence are well devel-oped, it is important to remember that the studies used for evi-dence are judged based on their internal validity, or the extent to which a causal conclusion is warranted based upon applica-tion of the results to the study population. This means that care must be exercised when applying a recommendation to a given patient, as the external validity of a recommendation, or gener-alizability of a causal conclusion to populations outside of the scope of the original studies, may not be appropriate. Therefore, all evidence must be applied within the context of the patient in front of you.Synthesis of Evidence—Clinical GuidelinesThe Institute of Medicine defines a clinical guideline as “state-ments that include recommendations, intended to optimize patient care, that are informed by a systematic review of evidence and an assessment of the benefits and harms of alterna-tive care options.”18 Clinical guidelines may reflect previous published studies of varying design and quality, as well as expert opinion, and often represent the highest level of applied clinical evidence. Numerous guidelines have been published; however, like individual studies, even guidelines can vary in quality. The highest quality and most clinically useful guide-lines tend to have the following qualities:4Brunicardi_Ch51_p2137-p2152.indd 214228/02/19 4:19 PM 2143UNDERSTANDING, EVALUATING, AND USING EVIDENCE FOR SURGICAL PRACTICECHAPTER 51Summary of findings:Compression stockings compared with no compression stockings for people taking long flightsPatients or population: Anyone taking a long flight (lasting more than 6 hours)Settings: International air travelIntervention: Compression stockings1Comparison: Without stockingsOutcomesIllustrative comparative risks* (95% CI)Relativeeffect(95% CI)Number ofparticipants(studies)Qualityof theevidence(GRADE)Comments Assumed riskCorresponding riskWithout stockingsWith stockingsSymptomaticdeep vein thrombosis (DVT)See comment  See comment  Not estimable2821(9 studies)See comment0 participants developed symptomatic DVT in these studies.Symptom-lessdeep vein thrombosis Low risk population2RR 0.10(0.04 to 0.26) 2637(9 studies) ++++High10 per 10001 per 1000  (0 to 3)High risk population230 per 10003 per 1000(1 to 8)Superficial vein thrombosis13 per 10006 per 1000(2 to 15)RR 0.45(0.18 to 1.13)1804(8 studies)+++OModerate3 OedemaPost-flight values measured on a scale from 0, no oedema, to 10, maximum oedema.The mean oedema score ranged across control groups from6 to 9.The mean oedema score in the intervention groups was on average4.7 lower(95% CI –4.9 to –4.5). 1246(6 studies)++OOLow4 Pulmonary embolusSee commentSee commentNot estimable2821(9 studies)See comment0 participants developed pulmonary embolus in these studies.5DeathSee commentSee commentNot estimable2821(9 studies)See comment0 participants died in these studies.Adverse effectsSee commentSee commentNot estimable1182(4 studies)See commentThe tolerability of the stockings was described as very good with no complaints of side effects in 4 studies.6*The basis for the assumed risk is provided in footnotes. The corresponding risk (and its 95% confidence interval) is based on the assumed risk in the intervention group and the relative effect of the intervention (and its 95% CI).CI: Confidence interval; RR: Risk ratio GRADE: GRADE Working Group grades of evidence (see explanations)11 All the stockings in the 9 trials included in this review were below-knee compression stockings. In four trials the compression strength was 20–30 mmHg at the ankle. It was 10–20 mmHg in the other four trials. Stockings come in different sizes. If a stocking is too tight around the knee it can prevent essential venous return causing the blood to pool around the knee. Compression stockings should be fitted properly. A stocking that is too tight could cut into the skin on a long flight and potentially cause ulceration and increased risk of DVT. Some stockings can be slightly thicker than normal leg covering and can be potentially restrictive with tight foot wear. It is a good idea to wear stockings around the house prior to travel to ensure a good, comfortable fitting. Stockings were put on 2 to 3 hours before the flight in most of the trials. The availability and cost of stockings can vary.2Two trials recruited high risk participants defined as those with previous episodes of DVT, coagulation disorders, severe obesity, limited mobility due to bone or joint problems, neoplastic disease within the previous two years, large varicose veins or, in one of the studies, participants taller than 190 cm and heavier than 90 kg. The incidence for 7 trials that excluded high risk participants was 1.45% and the incidence for the 2 trials that recruited high-risk participants (with at least one risk factor) was 2.43%. We have rounded these off to 10 and 30 per 1000 respectively.3The confidence interval crosses no difference and does not rule out a small increase.4The measurement of oedema was not validated or blinded to the intervention. All of these studies were conducted by the same investigators.5If there are very few or no events and the number of participants is large, judgement about the quality of evidence (particularly judgements about precision) may be based on the absolute effect. Here the quality rating may be considered “high” if the outcome was appropriately assessed and the event, in fact, did not occur in 2821 studied participants.6None of the other trials reported adverse effects, apart from 4 cases of superficial vein thrombosis in varicose veins in the knee region that were compressed by the upper edge of the stocking in one trial.Figure 51-2. Example of a “summary of findings” table.Brunicardi_Ch51_p2137-p2152.indd 214328/02/19 4:19 PM 2144SPECIFIC CONSIDERATIONSPART IITable 51-2Factors that affect the strength of a recommendationFACTOREXAMPLES OF STRONG RECOMMENDATIONSEXAMPLES OF WEAK RECOMMENDATIONSQuality of evidenceMany high quality randomized trials have shown the benefit of inhaled steroids in asthmaOnly case series have examined the utility of pleurodesis in pneumothoraxUncertainty about the balance between desirable and undesirable effectsAspirin in myocardial infarction reduces mortality with minimal toxicity, inconvenience, and costWarfarin in low risk patients with atrial fibrillation results in small stroke reduction but increased bleeding risk and substantial inconvenienceUncertainty or variability in values and preferencesYoung patients with lymphoma will invariably place a highervalue on the life prolonging effects of chemotherapy than on treatment toxicityOlder patients with lymphoma may not place a higher value on the life prolonging effects of chemotherapy than on treatment toxicityUncertainty about whether the intervention represents a wise use of resourcesThe low cost of aspirin as prophylaxis against stroke in patients with transient ischemic attacksThe high cost of clopidogrel and of combination dipyridamole and aspirin as prophylaxis against stroke in patients with transient ischaemic attacks1. An explicit description of development and funding pro-cesses that is publicly available.2. A transparent process that minimizes bias, distortion, and conflicts of interest.3. Developed by a multidisciplinary panel composed of: clini-cians, methodological experts, and representatives, includ-ing a patient or consumer, of populations expected to be affected by the guideline.4. Utilizes rigorous systematic evidence review and considers quality, quantity, and consistency of the aggregate of avail-able evidence.5. Summarizes evidence about potential benefits and harms relevant to each recommendation.6. Explains the parts that values, opinion, theory, and clinical experience play in deriving recommendations.7. Provides a rating of the level of confidence in the evidence underpinning each recommendation and a rating of the strength of each recommendation.8. Undergoes extensive external review that includes an open period for public comment.9. Has a mechanism for revision when new evidence becomes available.Depending upon the clinical question, such guidelines are often interpreted as the standard of care. However, multiple clinical guidelines may be applicable with respect to various aspects of a given clinical situation and must not be followed blindly without considering specific situational issues through the lens of an experienced clinician. Moreover, guidelines do not (and probably cannot) exist for all clinical situations. Clini-cians often must resort to other resources to enrich the context in which decisions are made, and, as with all evidence, care must be taken not to extrapolate the application of a clinical guideline beyond its specific conditions.THE CHALLENGES OF APPLYING EBM TO SURGERYAs noted earlier, the application of EBM to surgery has lagged behind other fields of medicine, and this has been attributed to the difficulty in establishing a sufficient mass of evidence with the “gold standard” RCT. Here we describe the process of evaluating the quality of a RCT and note the challenges related to the execution of a high-quality RCT in a surgical context.Analysis of a Surgical Randomized Control TrialSufficient knowledge of the trial’s methodological accuracy and results are essential for critical appraisal. However, less than half of journal articles adequately report the study design.19 This deficiency led to the development of the Consoli-dated Standards of Reporting Trials (CONSORT) guidelines in 1992, which was subsequently revised in 2010.20 These guide-lines are a minimal set of recommendations for reporting RCTs (blinding, randomization, etc) to facilitate critical appraisal. Many of the surgical journals now require completion of a CONSORT checklist prior to submission of the RCT manu-script (Fig. 51-3). Establishing this requirement has standard-ized the way articles are presented and analyzed. The two key aspects to focus on when assessing a RCT are internal and external validity.Internal ValidityDetermining the degree that the results of the RCT are accurate and consistent for the sample patients is called internal validity. Without internal validity, a study cannot be properly appraised, as the study was not constructed properly to answer the hypoth-esis without avoiding bias or confounding factors.21 The internal validity of a RCT requires the evaluation of several properties: randomization, blinding, equivalence among groups, complete-ness of follow-up, and accuracy of analysis. These properties are discussed in the following section.Randomization. Randomization is the creation of participant groups with similar known and unknown prognostic factors to achieve the goal of eliminating selection bias. For example, if the investigator can decide which treatment the patient receives, he or she may assign a participant to a study arm that is more favorable for that specific patient. On outcomes analysis, certain groups may have an overestimated treatment effect due to patient selec-tion and not necessarily the intervention itself. The methodology 5Brunicardi_Ch51_p2137-p2152.indd 214428/02/19 4:19 PM 2145UNDERSTANDING, EVALUATING, AND USING EVIDENCE FOR SURGICAL PRACTICECHAPTER 51SectionItem NoChecklist itemTitle and Abstract1aIdentification as a randomized trial in the title1bStructured summary of trial design, methods, results, and conclusionsBackground and Objectives2aScientific background and explanation of rationale2bSpecific objectives or hypothesesTrial Design3aDescription of trial design (such as parallel, factorial) including allocation ratio3bImportant changes to methods after trial commencement with reasonsParticipants4aEligibility criteria for participants4bSettings and locations where the data were collectedInterventions5The interventions for each group with sufficient details to allow replication, including how and when they were administeredOutcomes6aCompletely defined pre-specified primary and secondary outcome measures, including how and when they were assessed6bAny changes to trial outcomes after the trial commenced, with reasonsSample size7aHow sample size was determined7bWhen applicable, explanation of any interim analyses and stopping guidelinesRandomization: Sequence Generation8aMethod used to generate the random allocation sequence8bType of randomization; details of any restriction (such as blocking and block size)Allocation concealment mechanism9Mechanism used to implement the random allocation sequenceImplementation10Who generated the random allocation sequence, who enrolled participants, and who assigned interventionsBlinding11aIf done, who was blinded after assignment to interventions and how11bIf relevant, description of the similarity of interventionsResults Participant flow13aFor each group, the numbers of participants who were randomly assigned, received intended treatment, and were analyzed for the primary outcome13bFor each group, losses and exclusions after randomization, together with reasonsRecruitment14aDates defining the periods of recruitment and follow-up14bWhy the trial ended or was stoppedBaseline data15A table showing baseline demographic and clinical characteristics for each groupNumbers analyzed16For each group, number of participants (denominator) included in each analysis and whether the analysis was by original assigned groupsOutcomes and estimation17aFor each primary and secondary outcome, results for each group, and the estimated effect size and its precision (such as 95% confidence interval)17bFor binary outcomes, presentation of both absolute and relative effect sizes is recommendedAncillary analyses18Results of any other analyses performed, including subgroup analyses and adjusted analyses, distinguishing pre-specified from exploratoryHarms19All important harms or unintended effects in each groupDiscussion Limitations20Trial limitations, addressing sources of potential bias, imprecision, and, if relevant, multiplicity of analysesGeneralizability21Generalizability (external validity, applicability) of the trial findingsInterpretation22Interpretation consistent with results, balancing benefits and harms, and considering other relevant evidenceOther Information Registration23Registration number and name of trial registryProtocol24Where the full trial protocol can be accessed, if availableFunding25Sources of funding and other support (such as supply of drugs), role of fundersFigure 51-3. CONSORT checklist. (Reproduced with permission from Schulz KF, Altman DG, Moher D, et al: CONSORT 2010 statement: updated guidelines for reporting parallel group randomised trials, Int J Surg. 2011;9(8):672-677.)Brunicardi_Ch51_p2137-p2152.indd 214528/02/19 4:19 PM 2146SPECIFIC CONSIDERATIONSPART IIof randomization should always be reported and carefully ana-lyzed by the reader. Certain approaches of randomization called quasi-random allocation (date of birth, day of week, participant number, etc.) are not truly random and cannot be fully concealed from study personnel. Additionally, the concept of randomization eliminating bias is only theoretical. To truly ensure the probability of confounders being equally balanced between groups, a trial must be repeated indefinitely. Understanding this impracticality, we accept that randomization will suffice.Blinding. Blinding aims to reduce certain biases that can affect the outcome of the study. A subject’s knowledge of the group that they were randomized can lead to a performance bias, which can influence subjective outcomes (placebo effect). Importantly, authors should be explicitly clear regarding which groups (sub-jects, clinicians, assessors) are blinded and avoid using non-specific phrases such as “double-blinded” or “triple-blinded.” Achieving blinding and minimizing bias is a major hurdle in the execution of surgical RCTs, where there are the ethical dilemmas surrounding “sham” or placebo surgery22 (though for a counter-argument, see reference no. 23). Moreover, blinding is impossible when comparing an operative versus a nonoperative intervention.Equivalence Among Groups. During accrual, randomiza-tion helps to ensure that each group in the study shares equiva-lent baseline demographics and unmeasured biases. However, throughout the study, each group should be treated equally (excluding the actual intervention) with respect to the number of clinical visits, diagnostic tests, etc. Enforcing the same pro-tocol to each study participant further decreases sources of bias and provides increased validity when performing final analysis.Completeness of Follow-Up. Attrition bias is the differences that occur between the groups when participants withdraw from the study. A pattern can usually be identified (the treatment, side effects of treatment, long follow-up time, or other factors) that leads to withdrawal from the study. These events can hinder the ability to interpret the results of the study, and researchers should consider these implications during trial design. Furthermore, the mechanism of attrition may manifest in a bias; patients who elect to remain in a study may in fact select for characteristics that affect or determine efficacy (see the following section).Accuracy of Analysis. Analyzing the results of only partici-pants who completed all follow-up visits throughout the study can lead to skewed and inaccurate conclusions. Thus, most RCTs follow the principle of intention-to-treat (ITT) analysis. ITT analysis includes study participants who underwent initial randomization assignment regardless of events that transpired after randomization; thus ITT analysis is often described as “once randomized, always analyzed.” Removal of noncompli-ers from statistical analysis may overestimate the effect size of the intervention. Furthermore, in clinical practice, a portion of patients will be noncompliant, and thus ITT analysis will more accurately represent the overall population.External ValidityThe goal of an RCT is to show a causative relationship between an intervention and an outcome. However, to change clinical practice, the results of the RCT must be both relevant and gen-eralizable to the clinical population; this assessment is called external validity.Number Needed to Treat. The number needed to treat (NNT) is defined as the number of patients that undergo the interven-tion before a single patient benefits compared to the control group in the trial. It is computed as the inverse of the risk dif-ference between two groups. The smaller the NNT, the more efficacious a treatment. For example, in an RCT comparing laparoscopic cholecystectomy to observation to prevent recur-rent idiopathic acute pancreatitis, the number needed to treat was five patients.24 The NNT should also be weighed against the adverse effects of the intervention.Number Needed to Harm. While NNT reports the number of patients who undergo the intervention before a single patient benefits, number needed to harm (NNH) describes how many patients undergo the intervention for one person to have an adverse event. The higher the NNH, the safer a treatment is. In general, interventions with a low NNT and high NNH are pre-ferred. However, NNT and NNH should not be used in isolation when determining the appropriateness of intervention as neither number takes into account the degree of benefit to harm.Generalizability of Results. RCTs have specific exclusion and inclusion criteria to recruit a study population that is homogenous with the goal of limiting sources of bias. While this method is appropriate for RCTs, the results may not directly translate to “real-world” situations with greater heterogeneity within the potential target population (see prior comment in “Hierarchies of Evidence”), leading to a potentially significant discrepancy between trial results and their implementation for day-to-day clinical decisions. In addition, RCTs often come to a conclusion that determines the best treatment for the “average” patient enrolled in the trial. However, most patients are not “average,” and therefore the proposed conclusion may not be relevant. Additional studies about the intervention of interest in more heterogeneous populations can help convince physicians to change their clinical practice; these correlate to phase 4 pharmaceutical trials and point to the importance of continued postpractice change data collection and analysis. More importantly, principle 3 of EBM, which states that “clinical decisions should be influenced by patient values and preference,” needs to be accounted for, especially with the implementation of a new practice guideline or pattern.Additional Challenges to Conducting a Surgical RCTIn addition to methodological issues that might limit the reli-ability of a RCT, there are also considerable logistical barriers to performing a RCT. These are not trivial factors, and they contribute heavily to the number and size of RCTs that can be done, particularly in surgical populations.Recruitment. One of the most challenging aspects of an RCT is recruiting an adequate number of patients to provide a high and sufficient degree of statistical power to demonstrate a measurable difference between interventions. This becomes exponentially more difficult with the prevalence of certain rare diseases. To help overcome low accrual, many trials expand their study to other hospitals and facilities at the expense of increased heterogeneity. While this may decrease internal valid-ity, the benefit is the increase in external validity.Learning Curves and Expertise-Based Design. Pharma-ceutical-based RCTs normally have higher internal validity compared to surgical trials because of the effect of surgeon experience and technique affecting patient outcomes; this is especially impactful when new surgical procedures are intro-duced. While the administration of a drug is a straightforward process without measurable deviation, the same cannot be said Brunicardi_Ch51_p2137-p2152.indd 214628/02/19 4:19 PM 2147UNDERSTANDING, EVALUATING, AND USING EVIDENCE FOR SURGICAL PRACTICECHAPTER 51Table 51-3Decisions regarding the null hypothesisTABLE OF ERROR TYPES NULL HYPOTHESIS (H0) ISTRUEFALSEDecision about null hypothesis (H0) RejectType I error (false positive)Correct inference (true positive)Fail to rejectCorrect inference (true negative)Type II error (false negative)regarding surgery. Novel surgical procedures have defined learning curves even for the most experienced surgeons. During this learning process, surgeon inexperience, either in technical features of the procedure or procedure-related decision-making, can lead to adverse patient outcomes. Thus, neglecting the learn-ing curve can lead to an underestimation of the success of the experimental intervention; conversely, accounting for the learn-ing curve can be necessary in assessing how a new procedure can best be disseminated across the community. Furthermore, beyond the evaluation of new procedures, even with established procedures each individual surgeon is likely to have acquired throughout his/her career unique techniques and habits when operating on patients. This heterogeneity of surgeon experience and technique can limit standardization for a trial intervention.To help solve the issue of surgeon heterogeneity and inex-perience, RCTs can employ “expertise-based design.” In this method, patients remain randomized to either the intervention or control, but the operating surgeons are experts in the surgery they are performing. This technique is already followed during cross-specialty RCTs, such as open gastrostomy tube placement versus interventional-radiology (IR) gastrostomy tube place-ment. However, this does not model every day clinical practice because not all surgeons are considered experts in the procedure described in a particular trial.All-or-None Situation. Despite continual pressure to prove treatment effect by using a RCT, there are situations when conducting a trial does not make ethical or common sense. A famous example is from the British Medical Journal in 2003 that questioned as to why there are no RCTs evaluating the use of parachutes during gravitational free-fall.25 The authors state that the evidence to support the use of parachutes is purely observational yet it is considered a “gold standard” practice. This demonstrates the concept of an all-or-none situation, where the study population exposed to a risk experiences the outcome and none of the population experiences the outcome with the intervention. Performing an RCT on this type of situation would be dangerous and unethical, and thus purely observational data can provide a high degree of sufficient evidence.Noninferiority Trials. As reviewed earlier, trialing a new therapy compared to a placebo or sham raises serious ethical issues, especially when an effective therapy has already been established. Moreover, a portion of randomized control trials today are evaluating secondary endpoints, such as quality of life, safety, and cost efficiency of a new therapy compared to the existing gold standard. These studies are called noninferiority trials, with the intent to prove efficacy that is not worse than the existing therapy. For example, a 2004 study compared open versus laparoscopic colectomy for colon cancer. The aim was to show similar oncologic endpoints with improved secondary outcomes (improved cosmesis, decreased postoperative pain, decreased hernia incidence).26 The prevalence of these trials have increased substantially from under 100 in 2005 to nearly 600 in 2015.27 The most important consideration when evaluating this type of trial is the prespecified margin of noninferiority, a value that is largely arbitrary in the literature.28USE AND MISUSE OF STATISTICAL SIGNIFICANCEThe use of statistical methods is central to the scientific process; it is only through statistics that the problem of induction29 can be addressed. While this chapter is not intended to be 6a comprehensive description of statistical methods, understand-ing the appropriate application of statistical tools is critical to being able to assess the conclusions presented in the literature, and therefore we present a summary of those statistical terms that are most germane to being able to interpret a clinical study.Type I and Type II ErrorsBy necessity, statistical testing requires declaration of a null hypothesis, usually corresponding to the “default” state (i.e., no difference or the patient is healthy). The alternative hypothesis would then negate the stated null hypothesis (i.e., there is a dif-ference or the patient is unhealthy). The result of a statistical significance test may either reject or accept the null hypothesis, and this result can correspond with the true state (a correct deci-sion) or not correspond with the true state (an error). Two types of error are possible (Table 51-3).Type I Error. A type I error occurs when the null hypothesis is rejected but is actually true in the population. This may also be referred to as a false positive. The type I error rate, denoted by the Greek letter α (alpha), is the probability that the null hypothesis is rejected given that it is true. The error rate may also be referred to as the significance level, and often a value of 0.05, or 5%, is frequently used in the literature.Type II Error. A type II error is the failure to reject the null hypothesis when the null hypothesis is false. This error may also be referred to as a false negative. The type II error rate is denoted by the Greek letter β (beta), and is related to the power of a study. Power can range from 0 to 1, and as power increases, there is decreasing probability of making a type II error. Power is related to three main factors: (a) the statistical significance criterion of the study, (b) the magnitude of the effect of interest, and (c) the sample size used to detect the effect. Power analysis can be used to calculate the minimum sample size required for a study so that one can be likely to detect an effect of a given size.P ValuesThe P value was an innovation most closely associated with Sir Ronald Fisher, one of the founders of modern statistics. The definition of a P value is the probability of an observed result given the assumption that the null hypothesis is true. The arbi-trary value established for a result having statistical significance rather than “pure chance” is less than 1 in 20 defined as a P value less than 0.05.30 Put differently, the chance of making a false-positive conclusion is 5% at a P value of 0.05 (type I error). This risk of making a false-positive conclusion is called a “type I error.” Importantly, the P value reported in the study is specific for that study’s patient sample and may not be gen-eralizable to the overall population. The probability of a false positive report not actually having an association depends not Brunicardi_Ch51_p2137-p2152.indd 214728/02/19 4:19 PM 2148SPECIFIC CONSIDERATIONSPART IIonly on the associated P value, but also the prior probability that the association is real and the statistical power of the given study.31,32 The basis of this is due to perpetual undersampling of all possible relationships in a given scientific domain. This will inherently lead to type I errors with respect to all clinical pos-sibilities. Recently, statisticians have postulated that utilizing a P value of 0.05 will lead to wrong conclusions at least 30% of the time and may be even higher with underpowered studies.33The use of P values also categorizes statistical conclusions in a binary format. Should a P value of 0.049 be significant but a 0.051 not be significant? Furthermore, P values provide no insight into the effect size being measured. Simply, an intervention may be statistically significant but lack any clinical significance. Purely utilizing a P value to determine the value of research findings without assessing the effect size, confidence interval, and power of the study can be misleading.Despite these flaws identified in P values, the frequency of their appearance in modern literature has continued to increase.34 Each reader should be carefully skeptical of P values and await replication with similar significance for confirmation. Fisher did not anticipate or endorse the use of the modern P <0.05 criteria. Rather, he envisioned that experiments would be repeated until the investigator was sure that he or she had learned how to use the experimental intervention to get a predictable result.Alternative to P ValuesOne potential alternative to Fisher’s approach and the limita-tion of P values is Bayesian statistics. The common element of Bayesian statistics is to provide a probability of a hypothesis being true by using prior knowledge or empirical data to esti-mate four probabilities:1. The probability that the hypothesis is true.2. The probability that the hypothesis is true given the observed data.3. The probability that the alternative hypothesis is true.4. The probability that the data would have been observed if the alternative hypothesis is true.These parameters are used to calculate a Bayes factor, or a ratio of the likelihood probability of two competing hypotheses. One difficulty for many studies is that there can be very little reli-able data that can be used to estimate these probability parameters.It is important to remember that both P values and Bayes factors are mathematically defined entities, and many of the issues that have arisen with P values are due to how they are interpreted by scientists and clinicians. A false interpretation of a Bayes fac-tor is just as troublesome as a false interpretation of a P value.HOW DO THE TOOLS OF EBM PERFORM?As mentioned previously, GRADE has been widely adopted by national and international medical societies, health-related branches of government, healthcare regulatory bodies, and online medical resources such as UpToDate.16 Widespread use of the system has emphasized consistency in the rating of guidelines and an easy to understand strength assessment based upon evi-dence quality. However, at the heart of any EBM system is a central paradox: as systems have evolved during the EBM move-ment, there is no evidence that the systems themselves are reliable.7External ConsistencyGRADE is one of several EBM systems that aim to evaluate evidence and create recommendations, but it is unknown how it compares with other previously established systems.The GRADE Working Group attempted to address this question by comparing six different systems (The American College of Chest Physicians Evidence-Based Guidelines, Australian National Health and Medical Research Council Guidelines, Oxford Centre for Evidence-Based Medicine, Scottish Intercollegiate Guidelines Network, U.S. Preventive Services Task Force Recommendations, U.S. Task Force on Community Preventive Services Recommendations) on 12 criteria to assess the overall usefulness of each approach. The authors found that there was poor agreement about the sensibility of the six systems.35 Given that there is no agreed upon or proven gold standard, one may be concerned about the lack of external consistency among different systems. GRADE was constructed to overcome these issues; however, the system’s ability to do so has never been formally assessed.The example of the Surviving Sepsis Campaign (SSC), an important attempt to produce guidelines to improve the care of patients with sepsis or septic shock, suggests that GRADE has not overcome these problems. The endorsement of the SSC by many influential organizations underscores its importance. Nonetheless, the SSC illustrates some of the important difficul-ties with grading in general and with the GRADE system (Box: Examples of Inconsistent Use of EBM).Examples of Inconsistent Use of EBMSurviving Sepsis Campaign• The Surviving Sepsis Campaign recommended rapid use of intravenous antibiotics in their 2004 guidelines, which was given a grade of “E,”36 corresponding to a recommenda-tion based upon level IV or V evidence, or the lowest levels possible.• In the 2008 update, the same recommendation was given; however, it was given a grade of 1B/1D (depend-ing on if shock was present), corresponding to a “strong” recommendation.37• Between 2004 and 2008, three additional studies were published; however, none were randomized controlled trials or came to conclusions that were different than the numerous studies that were published prior to 2004.38-40 Internal ConsistencyIn 2005, the GRADE working group published a pilot study of the system which found varied levels of agreement on the qual-ity of evidence for the outcomes in question among 17 asses-sors (kappa values [Box: The Kappa Coefficient] for agreement beyond chance ranged from 0 to 0.82; mean k = 0.27; k <0 for four judgements). The authors concluded that “judgements about evidence and recommendations are complex” and stated that with discussion they could resolve most disagreements.41 No assessment of reliability or proof of usefulness has been presented regarding the GRADE system since these findings.42System IssuesThe GRADE group considers the “strength” of their recom-mendations to reflect “the degree of confidence that the desir-able effects of adherence to a recommendation outweigh the The Kappa CoefficientThe Kappa coefficient is a statistic that measures inter-rater agreement for qualitative items. It is thought to be a more robust measure than simple percent agreement since κ takes into account the possibility of the agreement occurring by chance. In general, κ values < 0 indicate no agreement, 0 to 0.2 slight agreement, 0.21 to 0.4 fair agreement, 0.41 to 0.60 moderate agreement, 0.61 to 0.80 substantial agreement, and 0.81 to 1 as almost perfect agreement.Brunicardi_Ch51_p2137-p2152.indd 214828/02/19 4:19 PM 2149UNDERSTANDING, EVALUATING, AND USING EVIDENCE FOR SURGICAL PRACTICECHAPTER 51Internal ConsistencyIn 2005, the GRADE working group published a pilot study of the system which found varied levels of agreement on the qual-ity of evidence for the outcomes in question among 17 asses-sors (kappa values [Box: The Kappa Coefficient] for agreement beyond chance ranged from 0 to 0.82; mean k = 0.27; k <0 for four judgements). The authors concluded that “judgements about evidence and recommendations are complex” and stated that with discussion they could resolve most disagreements.41 No assessment of reliability or proof of usefulness has been presented regarding the GRADE system since these findings.42System IssuesThe GRADE group considers the “strength” of their recom-mendations to reflect “the degree of confidence that the desir-able effects of adherence to a recommendation outweigh the The Kappa CoefficientThe Kappa coefficient is a statistic that measures inter-rater agreement for qualitative items. It is thought to be a more robust measure than simple percent agreement since κ takes into account the possibility of the agreement occurring by chance. In general, κ values < 0 indicate no agreement, 0 to 0.2 slight agreement, 0.21 to 0.4 fair agreement, 0.41 to 0.60 moderate agreement, 0.61 to 0.80 substantial agreement, and 0.81 to 1 as almost perfect agreement.undesirable effects.”43 However, at the same time, the GRADE system allows the strength of a given recommendation to exist independent of the quality of evidence that underpins that recom-mendation. The GRADE Working Group states that “separating the judgements regarding the quality of evidence from judge-ments about the strength of recommendations is a critical and defining feature of this new grading system.”42 However, such a system allows for “high quality” evidence for small effects while “low quality” evidence with a strong recommendation is highly implausible except for certain obvious observations.Finally, the touted advantage of the leveling process in determining the quality of evidence requires significant indi-vidual adjudication. A given study design begins at a level of quality and can be upgraded or downgraded based on several judgments regarding adequacy of blinding, follow-up, consis-tency, generalizability, and effect size. Graders are supposed to balance the level of quality using these factors, yet each is fun-damentally different and cannot be simply added or subtracted, and it is therefore up to individual judgment as to how to weigh each factor.ValidityThe GRADE system is well described in a series of publica-tions; however, none of the publications provide validation, data, or proof of the usefulness of the system. The only pub-lication with data is mentioned earlier, which showed a low kappa for interobserver agreement.41 Based upon the systematic tenets of EBM and lack of literature-based proof for the effec-tiveness of GRADE, there would not be a basis for its use in creating recommendations. For example, no RCT assessing the effect of using EBM on patient outcomes has been undertaken. Therefore, EBM does not satisfy its own requirements and is, ironically, a form of systematic expert opinion. There is no data to suggest that systematic EBM approaches are superior to the decision-making capabilities of competent physicians with knowledge of the recent medical literature.Implications of EBMThe GRADE Working Group suggests that “strong recommen-dations should require little debate and would be implemented in most circumstances.”42 Although most strong recommenda-tions are likely accurate, definitive recommendations may have unintended consequences. For example, a definitive recom-mendation may have the effect of limiting debate or further research on a topic where the recommendation is misguided, and there are numerous examples where “strong” recommenda-tions were later retracted. High-level EBM recommendations concluded that antibiotic prophylaxis should be used in necro-tizing pancreatitis based upon multiple prospective randomized controlled trials, meta-analyses, and systematic reviews.14,44,45 These recommendations were later reversed, as additional tri-als showed that there was no benefit to antibiotic use in these patients.46A valid concern regarding EBM is that established systems may lead to “strong” recommendations that are hard to challenge. This may even lead to situations where life-saving prospective studies are deemed “unethical” due to the presence of high-level, strong recommendations. As such, some groups have even issued warnings about converting practice guidelines into law.47,48THE ALTERNATIVES TO EBMEBM is appealing due to its ability to reduce and cope with uncer-tainty; however, the ability to mitigate uncertainty is not without drawbacks. The various EBM systems that exist are not always consistent in their evaluation of evidence, and even a single sys-tem may assign varying grades based on several subjective fac-tors. Finally, the performance of EBM in improving patient care has never been validated. Therefore, while most certainly a useful tool, the limitations of EBM must be recognized to avoid blind adherence to guidelines and oversimplification of the complex clinical decision making that occurs in daily clinical care.Although striving for certainty is understandable, it is con-trary to the reality of medicine in which decisions regarding indi-vidual patients are inherently complex. In fact, as science strives for “precision” and “individualized” medicine, EBM’s focus of creating guidelines to care for the “average” patient will exist as a paradox. The best physicians function on a foundation of scien-tific theory expressed in a setting of practical knowledge gained in a local context, or tacit knowledge. This is how complex phys-iology and pathology are combined to make a specific decision for an individual patient. Therefore, although it is tempting to think that EBM makes surgery more scientific, one must remem-ber that EBM itself is not founded in scientific principal.So, what is the alternative? The alternative is a common-sense application of scientific principals and healthy skepticism for the ongoing use of EBM as a guideline for practice. This allows physicians to use published guidelines, applied within the context of their practice, until a grading system has defini-tively been shown to positively affect patient outcomes or more precise application of patient data is made possible. Recommen-dations certainly can be useful information; however, clinicians should also understand that there is a nuance with respect to adherence to guidelines and that much lies outside the reaches of EBM. As such, understanding that daily clinical practice involves hundreds of decisions that require varying proportions of explicit and tacit knowledge is important in devising a system where guidelines are flexible and receptive to continual feed-back based upon the experiences of practicing physicians.WHAT CAN RESEARCHERS DO TO IMPROVE THE VALIDITY OF RESEARCH FINDINGS?Although it is impossible to know the truth with absolute certainty, researchers can take steps to ensure that the posttest probability is maximized. First, researchers can attempt to obtain better-powered evidence. Although even high-powered, low-bias meta analyses are not perfect, they do approach a theoretical “gold standard” of research, and although increasing power is important in arriving at correct conclusions, even high-powered studies can have significant biases. Additionally, obtaining large-scale evidence may not be possible for many research questions.Brunicardi_Ch51_p2137-p2152.indd 214928/02/19 4:19 PM 2150SPECIFIC CONSIDERATIONSPART IICrisis of Reproducibility and Medical Reversal: Implications for EBM“You keep using that word. I do not think it means what you think it means.”—Inigo Montoya from The Princess BrideThis chapter started by noting that the landscape of scientific knowledge is constantly evolving and that this fact impacts how we use and evaluate evidence as well. This 11th edition of Schwartz’s Principles of Surgery is being produced at a particularly volatile period in biomedical research as basic assumptions as to how scientific literature determines what constitutes “evidence” are being reassessed in a critical fashion. We believe it does a disservice to our readers if we fail to note and describe these trends, as they directly affect the basis of this chapter. The reassessment of biomedical literature and clinical trials can be loosely grouped into two distinct, but related topics: the crisis of reproducibility and the issue of medical reversal.The Crisis of ReproducibilityOver the past decade it has become increasingly recognized that certain medical studies, held forth as index publications upon which were based either fundamental precepts of practice or to justify entire directions of drug discovery, could not be repro-duced independently. This failure strikes at a fundamental assumption of science: that well performed studies with sufficient statistical significance represented generalizable knowledge that could be built upon. However, estimates of irreproducibility range from 75% to 90% based on mathematical inference, and practical investigations have shown as few as 0 in 52 observa-tional study findings being confirmed by randomized controlled trials (RCTs).49 Methodological errors in study design, patient selection, or research practices have been proposed as major contributing factors in the debate over replication of scientific stud-ies. However, despite the importance of replicating research findings, there is increasing concern that in modern research there is an intrinsic bias towards positive results in publication. Biases in study design, data collection, data analysis, or presentation of findings can lead to research findings when they do not truly exist. As bias increases, the positive predictive value (PPV) of a given finding being true decreases considerably. The overall effect of bias again depends on both the power and prestudy odds of a given study. In some fields, it may in fact be the case that research findings are simply a measure of the prevailing bias. Medical research operates in areas with low preand poststudy probability for true findings, meaning it may be quite common that observed effect sizes varying around the null hypothesis (what one would expect from chance alone) are simply measuring the prevailing bias of a given field.In addition to bias, the globalization of research means that at any given time it is almost a certainty that multiple research teams are investigating the same question or topic. Despite this fact, research findings by single teams are often considered in isolation, and the first to report a finding receives significantly more attention than subsequent studies. Suppose multiple research teams are investigating a given question with the null hypothesis being that there is no difference in treatment two treatment strategies. The probability that at least one of the groups will claim a significant research finding increases, and the positive predictive value decreases as the number of research teams increases. Unfortunately, there is little way to control for this phenomenon other than increasing the power of each individual study.Due to the combination of the aforementioned factors, the current framework of research means it is quite difficult to end up with a PPV >50%. Based on mathematical principles, even a well-constructed, adequately powered RCT with a pretest probability of 50% will arrive at a true conclusion only about 85% of the time.31 These findings limit the available literature upon which evidence-based medicine (EBM) relies and place a greater burden on practitioners when they are attempting to analyze and draw conclusions from what they find.Medical ReversalA related topic that directly impacts how EBM is carried out is that of medical reversal. This term was introduced by Vinay Prasad and Adam Cifu in 201150,51 to describe the process and pitfalls by which a previously established practice or drug falls out of favor because it is subsequently identified not to work. As such, the issue of medical reversal is impacted by the decision for a particular therapy to become adopted in the first place (ostensibly based on the principles of EBM) and the barriers to how subsequent evi-dence (either acquired through studies, or, more importantly, upon a more critical reassessment of the basis of its initial adoption) can reverse a prior recommendation. The set of intersecting issues related to medical reversal are highly complex (interested readers are encouraged to delve into the growing list of reports on this topic), but in terms of EBM, central issues addressed in medical reversal pertain to the use of surrogate endpoints in clinical trials, the presentation/misrepresentation of clinical trial effects, the effect of bias (academic and economic) in trial reporting and dissemination, and the strength and reliability of alternatives to RCTs (for all their flaws). As with the crisis of reproducibility, understanding the factors of medical reversal directly impacts what is appropriately considered “evidence” when executing EBM, placing greater responsibility on the surgical practitioner when deter-mining what is appropriate or optimal care.It should come as no surprise to the attentive reader that many of the issues related to the crisis of reproducibility and medical reversal refer back to the sources of bias and potentially perverse incentives originally noted by Francis Bacon back in 1620 (Box: The History and Sources of Bias in Biomedical Literature).Brunicardi_Ch51_p2137-p2152.indd 215028/02/19 4:19 PM 2151UNDERSTANDING, EVALUATING, AND USING EVIDENCE FOR SURGICAL PRACTICECHAPTER 51Second, as was noted previously, multiple teams often simultaneously address a given research question, and it is not proper to focus on any one study in isolation. Instead, clinicians should focus on the body of evidence in its entirety. A poten-tial solution would be connecting groups through networking of data. This would allow for more accurate analysis and drawing of conclusions, although it would require a significant change in the culture of academic research practices.Today, clinicians rely on the statistics provided in a scien-tific study to provide a summary of the results. We place trust and confidence that the paper’s biostatistician accurately and truthfully calculated these statistics without incorporating con-scious bias. Each article should completely answer four ques-tions regarding the results of the study:1. What is the statistical significance of the results?2. What is the effect size and is this clinical relevant?3. What is the confidence interval?4. What is the underlying power of the study to detect a mean-ingful difference?Significant progress has been made since the adoption of EBM; however, the current direction of EBM-based guidelines have focused on populations as opposed to the complex, nuanced interactions that occur on a case by case basis. Algorithmic protocols actually serve to steer the focus away from an individual patient, at times leading to a disconnect between patients and physicians when physicians propose treatment based upon guidelines that do not adhere to that patient’s goals and values. So what can surgeons do to combat this, and how should they practice? One must ask: “What is the best course of action for this patient, in these circumstances, at this point in their illness or condition?” Therefore, evidence must be synthesized and then individualized for each patient encounter by interconnecting it with the ethics, personality, and values associated with the case at hand. Tools such as risk calculators are useful in informing discussion, but they should by no means be definitive evidence to recommend for or against a particular treatment. Judgment remains necessary in the practice of medicine, and therefore guidelines should be thought of as “rules of thumb” that require context as opposed to “rules of law.”REFERENCESEntries highlighted in bright blue are key references. 1. Bacon F, Fowler T. Bacon’s Novum Organum. Oxford: Clarendon Press; 1878. 2. Djulbegovic B, Guyatt GH. Progress in evidence-based medi-cine: a quarter century on. Lancet. 2017;390(10092):415-423. Available at: http://dx.doi.org/10.1016/S0140-6736(16) 31592-6. Accessed August 27, 2018. 3. Sackett DL, Rosenberg WM, Gray JA, Haynes RB, Richardson WS. Evidence based medicine: what it is and what it isn’t. BMJ. 1996;312(7023):71-72. 4. Djulbegovic B, Guyatt GH, Ashcroft RE. Epistemologic inquiries in evidence-based medicine. Cancer Control. 2009;16(2):158-168. 5. Wente MN, Seiler CM, Uhl W, Buchler MW. Perspectives of evidence-based surgery. Dig Surg. 2003;20(4):263-269. 6. Solomon MJ, McLeod RS. Clinical studies in surgical journals—have we improved? Dis Colon Rectum. 1993;36(1):43-48. 7. Pollock AV. Surgical evaluation at the crossroads. Br J Surg. 1993;80(8):964-966. 8. Richardson WS, Wilson MC, Nishikawa J, Hayward RS. The well-built clinical question: a key to evidence-based decisions. ACP J Club. 1995;123(3):A12-A13. 9. Whipple AO, Parsons WB, Mullins CR. Treatment of carcinoma of the ampulla of vater. Ann Surg. 1935;102(4):763-779. 10. Nissen R. A simple operation for control of reflux esophagitis (in German). Schweiz Med Wochenschr. 1956;86(suppl 20): 590-592. 11. Patsopoulos NA, Analatos AA, Ioannidis JP. Relative citation impact of various study designs in the health sciences. JAMA. 2005;293(19):2362-2366. 12. Moore FA, Feliciano DV, Andrassy RJ, et al. Early enteral feeding, compared with parenteral, reduces postoperative septic complications. The results of a meta-analysis. Ann Surg. 1992;216(2):172-183. 13. Eikelboom JW, Karthikeyan G, Fagel N, Hirsh J. American Association of Orthopedic Surgeons and American College of Chest Physicians guidelines for venous thromboembolism prevention in hip and knee arthroplasty differ: what are the implications for clinicians and patients? Chest. 2009;135(2): 513-520. 14. Bassi C, Larvin M, Villatoro E. Antibiotic therapy for prophylaxis against infection of pancreatic necrosis in acute pancreatitis. Cochrane Database Syst Rev. 2003;(4):CD002941. 15. Guyatt GH, Oxman AD, Vist GE, et al. GRADE: an emerg-ing consensus on rating quality of evidence and strength of recommendations. BMJ. 2008;336(7650):924-926. 16. Higgins JPT, Green S, eds. Cochrane Handbook for Systematic Reviews of Interventions. Version 5.1.0. The Cochrane Collabo-ration; 2011. Available at: https://handbook-5-1.cochrane.org. Accessed August 27, 2018. 17. Delle Fave G, Kwekkeboom DJ, Van Cutsem E, et al. ENETS Consensus Guidelines for the management of patients with gastroduodenal neoplasms. Neuroendocrinology. 2012;95(2):74-87. 18. Graham R, Mancher M, Miller Wolman D, Greenfield S, Steinberg E, eds. Institute of Medicine (US) Committee on Standards for Developing Trustworthy Clinical Prac-tice Guidelines. Clinical Practice Guidelines We Can Trust. Washington DC: National Academies Press; 2011. 19. Adie S, Harris IA, Naylor JM, Mittal R. CONSORT compliance in surgical randomized trials: are we there yet? A systematic review. Ann Surg. 2013;258(6):872-878. 20. Schulz KF, Altman DG, Moher D; Consort Group. CON-SORT 2010 statement: updated guidelines for reporting par-allel group randomised trials. Int J Surg. 2011;9(8):672-627. 21. Higgins JPT, Altman DG, Gøtzsche PC, et al. The Cochrane Collaboration’s tool for assessing risk of bias in randomised trials. BMJ. 2011;343:d5928. 22. Das AK. Randomised clinical trials in surgery: a look at the ethical and practical issues. Indian J Surg. 2011;73(4): 245-250. 23. Wartolowska K, Judge A, Hopewell S, et al. Use of placebo controls in the evaluation of surgery: systematic review. BMJ. 2014;348:g3253. 24. Raty S, Pulkkinen J, Nordback I, et al. Can laparoscopic cholecystectomy prevent recurrent idiopathic acute pancreatitis? A prospective randomized multicenter trial. Ann Surg. 2015; 262(5):736-741. 25. Smith GC, Pell JP. Parachute use to prevent death and major trauma related to gravitational challenge: systematic review of randomised controlled trials. BMJ. 2003;327(7429): 1459-1461. 26. Clinical Outcomes of Surgical Therapy Study Group, Nelson H, Sargent DJ, et al. A comparison of laparoscopically assisted and open colectomy for colon cancer. N Engl J Med. 2004;350(20):2050-2059.Brunicardi_Ch51_p2137-p2152.indd 215128/02/19 4:19 PM 2152SPECIFIC CONSIDERATIONSPART II 27. Mauri L, D’Agostino RB Sr. Challenges in the design and interpretation of noninferiority trials. N Engl J Med. 2017;377(14):1357-1367. 28. Ho PM, Peterson PN, Masoudi FA. Evaluating the evi-dence: is there a rigid hierarchy? Circulation. 2008; 118(16):1675-1684. 29. Hume D, Norton DF, Norton MJ. A Treatise of Human Nature. Oxford; New York: Oxford University Press; 2000. 30. Dahiru T. P-value, a true test of statistical significance? A cautionary note. Ann Ib Postgrad Med. 2008;6(1):21-26. 31. Ioannidis JP. Why most published research findings are false. PLoS Med. 2005;2(8):e124. 32. Wacholder S, Chanock S, Garcia-Closas M, El Ghormli L, Rothman N. Assessing the probability that a positive report is false: an approach for molecular epidemiology studies. J Natl Cancer Inst. 2004;96(6):434-442. 33. Colquhoun D. An investigation of the false discovery rate and the misinterpretation of P values. R Soc Open Sci. 2014;1(3): 140216. 34. Chavalarias D, Wallach JD, Li AH, Ioannidis JP. Evolution of reporting P values in the biomedical literature, 1990-2015. JAMA. 2016;315(11):1141-1148. 35. Atkins D, Eccles M, Flottorp S, et al. Systems for grading the quality of evidence and the strength of recommendations I: critical appraisal of existing approaches The GRADE Working Group. BMC Health Serv Res. 2004;4(1):38. 36. Dellinger RP, Carlet JM, Masur H, et al. Surviving Sepsis Campaign guidelines for management of severe sepsis and septic shock. Crit Care Med. 2004;32(3):858-873. 37. Dellinger RP, Levy MM, Carlet JM, et al. Surviving Sepsis Campaign: international guidelines for management of severe sepsis and septic shock: 2008. Crit Care Med. 2008;36(1): 296-327. 38. Houck PM, Bratzler DW, Nsa W, Ma A, Bartlett JG. Timing of antibiotic administration and outcomes for Medicare patients hospitalized with community-acquired pneumonia. Arch Intern Med. 2004;164(6):637-644. 39. Kumar A, Haery C, Paladugu B, et al. The duration of hypotension before the initiation of antibiotic treatment is a critical determinant of survival in a murine model of Escherichia coli septic shock: association with serum lactate and inflammatory cytokine levels. J Infect Dis. 2006;193(2):251-258. 40. Proulx N, Frechette D, Toye B, Chan J, Kravcik S. Delays in the administration of antibiotics are associated with mortality from adult acute bacterial meningitis. QJM. 2005;98(4):291-298. 41. Atkins D, Briss PA, Eccles M, et al. Systems for grading the quality of evidence and the strength of recommendations II: pilot study of a new system. BMC Health Serv Res. 2005;5(1):25. 42. Kavanagh BP. The GRADE system for rating clinical guidelines. PLoS Med. 2009;6(9):e1000094. 43. The GRADE Working Group. 2018. Available at: http://www .gradeworkinggroup.org. Accessed August 27, 2018. 44. Sharma VK, Howden CW. Prophylactic antibiotic administration reduces sepsis and mortality in acute necrotizing pancreatitis: a meta-analysis. Pancreas. 2001;22(1):28-31. 45. Bassi C, Mangiante G, Falconi M, Salvia R, Frigerio I, Pederzoli P. Prophylaxis for septic complications in acute necrotizing pancreatitis. J Hepatobiliary Pancreat Surg. 2001;8(3):211-215. 46. Villatoro E, Mulla M, Larvin M. Antibiotic therapy for prophylaxis against infection of pancreatic necrosis in acute pancreatitis. Cochrane Database Syst Rev. 2010;(5):CD002941. 47. Fein IA, Corrato RR. Clinical practice guidelines: culture eats strategy for breakfast, lunch, and dinner. Crit Care Med. 2008;36(4):1360-1361. 48. Jacobson PD. Transforming clinical practice guidelines into legislative mandates: proceed with abundant caution. JAMA. 2008;299(2):208-210. 49. Begley CG, Ioannidis JP. Reproducibility in science: improv-ing the standard for basic and preclinical research. Circ Res. 2015;116(1):116-126. 50. Prasad V, Cifu A. Medical reversal: why we must raise the bar before adopting new technologies. Yale J Biol Med. 2011;84(4):471-478. 51. Prasad V, Gall V, Cifu A. The frequency of medical reversal. Arch Intern Med. 2011;171(18):1675-1676.Brunicardi_Ch51_p2137-p2152.indd 215228/02/19 4:19 PM
Ambulatory SurgeryMarcus Adair, Stephen Markowiak, Hollis Merrick, James R. Macho, Kara Richardson, Moriah Muscaro, Munier Nazzal, and F. Charles Brunicardi 52chapterINTRODUCTIONAmbulatory SurgeryAmbulatory Surgery is a multidisciplinary field in which surgi-cal procedures are performed on patients who are not expected to be admitted to the hospital. The field includes procedures performed on patients in the setting of hospital outpatient departments (HOPDs), freestanding ambulatory surgery cen-ters (ASCs), and those performed in doctor’s offices. The word ambulatory comes from the Latin ambulare, which means “to walk,” indicating that the patients arrived at the procedure on their own and departed after the procedure to their home environment.1Improved anesthesia techniques, the development of min-imally invasive procedures, and changes to healthcare policy (particularly healthcare funding) have been the driving fac-tors behind the increase in ambulatory surgery. Prior to these advances, almost all surgery was performed in an inpatient hos-pital setting. Any outpatient surgeries were minor, performed in physicians’ offices, and paid for by Medicare and insurers as part of the physician’s office visit reimbursement.2Since the early 1980s, the volume of ambulatory surgery has increased in the United States.2,3 Between 1981 and 2005, the number of outpatient surgeries nationwide grew almost 10-fold to over 32.0 million per year. Outpatient procedures grew from 19% to 60% of all surgical procedures, by volume, in the United States from 1981 to 2011.2,4,5 Strong financial incentives exist for hospi-tals to shift some surgeries to an outpatient setting. The number of Medicare-certified ASCs has also increased steadily, from fewer than 300 in the early 1980s2 to 5532 in 2016 (Fig. 52-1).5By definition, procedures at ASCs and physician’s offices are performed without the full resources of a hospital. The press has sensationalized a few adverse patient outcomes in these set-tings and made claims about the overall safety based on these isolated events. However, much of the convenience, high patient satisfaction rates, and cost-efficiency of ambulatory surgery is lost when performed in a hospital setting. Thus, the challenge underlying ambulatory surgery is performing safe operations on carefully selected patients in a manner that is patient-family–centric and economical.A majority of large hospitals also have their own outpatient surgery departments that exist within the hospital. ASCs per-form procedures faster and more efficiently than HOPDs and at higher volume than both HOPDs and physicians’ offices. Addi-tionally, the number of certified, freestanding ASCs nationwide has eclipsed the total number of hospitals by more than 1000 centers.5 For these reasons, a plurality of outpatient surgical vol-ume in the United States is now performed in ASCs. It is critical for the modern surgeon to have a grasp of the unique clinical challenges and economic impacts of ambulatory surgery.Ambulatory Surgery CentersASCs are independent healthcare that offer patients the conve-nience of having surgery performed safely without admission to a hospital. ASCs provide only elective surgical services rather than emergency care. According to the Centers for Medicare & Medicaid Services (CMS), effective May 18, 2009, “ASCs are any distinct entity that operates exclusively for the purpose of providing surgical services to patients not requiring hospi-talization and which the expected duration of services would not exceed 24 hours following an admission.”4 Ambulatory sur-gery centers should not be confused with office-based surgery practices or with other outpatient centers that provide diagnos-tic services or primary healthcare, such as urgent care centers, community health centers, mobile diagnostic units, or rural health clinics. ASCs are distinguished from these other health-care facilities by (a) their use of a referral system for accept-ing patients and (b) their maintenance of a dedicated operating room. The first feature means that any patient who wants to be treated in an ambulatory surgery center must first consult a Introduction2153Ambulatory Surgery / 2153Ambulatory Surgery Centers / 2153Aspects Leading to Increased Utilization / 2154History of Ambulatory Surgery and Ambulatory Surgery Centers2154Procedures Performed2156Benefits of Ambulatory Surgery Centers2156Factors Contributing to Popularization of ASCs / 2157Regulation, Costs, and Quality2158Regulation / 2158Costs / 2158Quality / 2159Ownership / 2159Potential for Conflict of Interest / 2159Challenges2159Reimbursement / 2159Patient Selection / 2159ASCs vs. Hospital Outpatient Departments vs. Office-Based Surgical Suites / 2160Aging Population / 2160Conclusion2160Brunicardi_Ch52_p2153-p2162.indd 215328/02/19 4:17 PM 2154199660005000Number of ASCs4000300020001000019982000200220042006200820102012Figure 52-1. Number of Medicare-certified ambulatory surgery centers from 1996 to 2013.Key Points1 Define ambulatory surgery and the unique aspects of ambu-latory surgery centers (ASCs).2 Understand the history of ambulatory surgery and ASCs in the United States.3 Review the most common procedures performed in ASCs compared to those performed in a hospital setting.4 Discuss the financial benefits for patients and physicians within the structure of ASCs as they pertain to physician ownership, healthcare systems partnerships, and insurance reimbursement.5 Understand the regulatory and accreditation processes that affect ASCs.6 Predict how anticipated medical advances, technological development, and an aging population will affect the field of ambulatory surgery.primary healthcare provider (PCP) and choose to have the con-dition treated by surgery rather than an alternative approach. The second characteristic means that all ASCs must have at least one dedicated operating room and the equipment needed to per-form surgery safely and ensure quality patient care.1 Patients who choose to have surgery in an ASC arrive on the day of their procedure, have their surgery in a fully equipped operating room, and recover under the care of a highly-skilled anesthesia team, all without hospital admission.Aspects Leading to Increased UtilizationTechnological Developments. Improvements in anesthe-sia have facilitated the safe practice of outpatient surgery by the use of new medications, improved techniques in regional anesthesia, and better management of postoperative pain. The development of minimally invasive surgical techniques such as fiberoptic endoscopy, arthroscopy, ophthalmologic procedures, and laparoscopic and robotic surgery have made it possible for patients to be discharged the on the same day as the surgery.Reduced Cost for Patients Without Compromise in Quality of Care. Ambulatory surgery facilities are highly specialized centers originating from a service model rather than the tradition hospital model. This approach allows for streamlined processes and reduced costs. Staffing is the largest cost for most healthcare facilities including ASCs, thus same-day surgery eliminates the need for overnight nursing and support staff.ASCs Offer Reduced Cost for Healthcare Systems. A review of commercial medical claims data found that annual U.S. healthcare costs are reduced by approximately $3.8 billion due to the availability of ASCs. Patients save more than $1.5 bil-lion due to lower deductibles and coinsurance payments. Over the next decade, ASCs are expected to save the U.S. healthcare system between $32.5 and $57.6 billion. This cost reduction is driven by the fact that, in general, ASC prices are significantly lower than HOPD prices for the same procedure in all mar-kets, regardless of payer.6 Table 52-1 displays the cost savings compared to hospital outpatient departments for the most com-monly performed procedures at ASCs nationwide. While most hospitals offer outpatient surgery, ambulatory surgery centers are regarded as a superior choice for certain procedures because of facility efficiencies and price regulation under the outpatient prospective payment system.6HISTORY OF AMBULATORY SURGERY AND AMBULATORY SURGERY CENTERSAmbulatory surgical practice traces its history from the early work of itinerant dental surgeons who traveled their circuits by horseback and trains. They frequently operated in hotel rooms and then moved on. In 1909, James Nicoll (Fig. 52-2), a pediatric surgeon in Scotland, wrote of his experiences with ambulatory anesthesia and surgery on nearly 9000 children as outpatients during a 10-year interval at Glasgow Royal Hospi-tal for Sick Children.8 Operations included cleft lip and palate repair, correction of pyloric stenosis, mastoidectomy, repair of inguinal and umbilical hernias, and management of spina bifida and depressed skull fractures. Nicoll pleaded with his fellow surgeons to perform more pediatric operations on an outpatient basis, stating that “a large number of the cases at present treated in-door constitutes a waste of the resources of a children’s hos-pital . . . . The results obtained in the out-patient department at a tithe [small part] of the cost are equally good.”8Ralph Waters (Fig. 52-3) was a pioneer in the field of ambulatory surgery. He developed an office-based practice in Sioux City, Iowa in 1919. Waters used nitrous oxide, morphine, and scopolamine. He believed medical conditions had to be well controlled prior to surgery and that certain medical condi-tions precluded outpatient care. In these ways, Waters’ clinic became the prototype for the modern free-standing ASC. Waters subsequently went on to establish the first academic residency program for training anesthesiologists at the University of Wisconsin.9Prior to the advent of freestanding ASCs, the concept of ambulatory surgery first needed to gain acceptance in the form of HOPDs. In 1959, Eric Webb and Horace Graves advocated out-patient surgery because of a shortage of hospital beds in Vancou-ver. The first HOPD in the United States was established in 1962 at the University of California, Los Angeles by David Cohen and John Dillon, who also sought to address a shortage of hospital beds. These efforts proved to be safe and cost-effective.9Brunicardi_Ch52_p2153-p2162.indd 215428/02/19 4:17 PM 2155AMBULATORY SURGERYCHAPTER 52Figure 52-2. James Henderson Nicoll, pediatric surgeon. (Repro-duced with permission from University of Glasgow Archives & Special Collections, University collection, GB 248 PH/PR 2475.)Figure 52-3. Ralph Milton Waters, anesthesiologist. (Used with permission from the American Society of Anesthesiologists.)Table 52-1Comparison of top 10 procedures performed at ASCs vs. hospitals nationwideTOP 10 PROCEDURES PERFORMED AT AMBULATORY SURGICAL CENTERS BY VOLUME AND CPT CODENUMBER PERFORMEDAVG PAY PER CLAIMSAVINGS AT ASCTOP 10 PROCEDURES PERFORMED AT HOSPITAL OUTPATIENT DEPARTMENTS (HOPD) BY VOLUME AND CPT CODENUMBER PERFORMEDAVG PAY PER CLAIM 1. Cataract surgery with intraoccular lens(66984)1155, 283$959$219 1. Subcutaneous tissue debridement (11042)841,517$213 2. Esophagogastroduodenoscopy with biopsy (43239)524,082$301$110 2. Esophagogastroduodenoscopy with biopsy (43239)628,900$411 3. Colonoscopy and biopsy (45380)416,218$352$172 3. Aspiration/injection of joint (20610)578,407$141 4. Colonoscopy with lesion removal (45385)331,565$401$20 4. Cataract surgery with IOL implant (66984)512,191$1,178 5. Spine epidural injection foraminal (64483)282,962$335  5. Colonoscopy and biopsy (45380)472,886$524 6. Postlaser cataract surgery capsulotomy (66821)275,760$227  6. Colonoscopy with lesion removal (45385)350,001$421 7. Spine epidural injection lumbar, sacral (62311)210,159$358$120 7. Spine epidural injection lumbar, sacral (62311)326,956$478 8. Injection, paravertebral facet joint (64493)174,450$306  8. Insertion of temporary bladder catheter (51702)308,614$69 9. Diagnostic colonoscopy (45378)157,951$401$100 9. Appl. of multilayer compression system (29581)303,026$9710. Colorectal screening, high-risk individual (G0105)128,181$33310. Diagnostic colonoscopy (45378)253,350$501The first truly freestanding ASC, “SurgiCenter,” was opened in Phoenix, Arizona by Wallace A. Reed and John L. Ford in 1970 (Fig. 52-4). Reed and Ford were committed to pro-viding timely, convenient, and comfortable surgical services to patients in their community, and therefore, avoiding more imper-sonal venues like regular hospitals. Prior to opening SurgiCen-ter, Reed and Ford were frustrated with having patients wait 6 weeks or more to get elective surgery, and in some cases, found surgeries canceled because the rooms booked were needed for emergencies.9Brunicardi_Ch52_p2153-p2162.indd 215528/02/19 4:17 PM 2156SPECIFIC CONSIDERATIONSPART IIFigure 52-4. Image of “SurgiCenter” in 1970. (Used with permission from Banner Health.)Figure 52-5. George Isaac Minimally Invasive Surgery Center at the University of Toledo Medical Center. (Used with permission from University of Toledo.)In its first 6 months, Surgicenter performed more than 1200 operations by 153 surgeons. No adverse cardiac events occurred during the procedures, and only one patient was hos-pitalized following surgery (due to poorly controlled diabetes, not because of the operation itself).10 SurgiCenter’s incredible success resulted in more than 400 visitors touring the facility in the first year in order to learn about the new model for patient care.11 Reed and Ford realized that a tremendous need existed for freestanding, independent ASCs. According to Reed, this propelled the formation of what eventually became the Ambula-tory Surgery Center Association (ASCA), a major credentialing body within the field of ambulatory surgery.11The Orkand Report of 1976, a U.S. government–spon-sored study of outpatient surgery, concluded that ambulatory surgical facilities can significantly reduce costs while main-taining the same high quality of surgical and anesthetic care achieved in hospitals.12The Society for Ambulatory Anesthesia (SAMBA) was established in 1984 to further the development of ambulatory anes-thesiology as a subspecialty. The field continued to advance with the publication of Wetchler’s Anesthesia for Ambulatory Surgery in 1985, the introduction of the journal Ambulatory Surgery in 1993, and with the first state requiring accreditation for all outpatient facilities (California in 1996). Many other states have since adopted these high standards and require accreditation of ASCs. CMS now requires certification for all ASCs (Fig. 52-5 and 52-6).5PROCEDURES PERFORMEDBy 1982, CMS had approved payments to ASCs for more than 200 procedures. Steady growth in the number of ASCs (Fig. 52-7) and the number of surgical procedures performed in the outpatient setting, including HOPDs, has continued since. Each year physicians perform more than 23 million procedures in ASCs. This shift toward outpatient procedures has increased due to advancements in medical practice and technology that have reduced the need for overnight hospital stays. Most patients, except those with complicated health conditions, can be served in the outpatient setting. Common ASC procedures include colonoscopies, cataract surgeries, tonsillectomies, and arthroscopic orthopedic surgeries. CMS currently approves and reimburses more than 3500 procedures in the ASC setting.5 New developments continue to expand the scope of ASCs.ASCs may perform surgeries in several specialties or dedi-cate their services to one specialty, such as eye care or sports medicine. The procedure must not pose a significant safety risk and not require an overnight stay when performed in an ASC. The types of surgical procedures performed in ASCs have undergone significant changes in recent years. Many of the early ASCs were outpatient centers for plastic surgery. Advances in minimally invasive surgical techniques in other specialties, how-ever, led to the establishment of ASCs for orthopedic, dental, and ophthalmologic procedures. See Fig. 52-8 for a recent anal-ysis of specialty services provided by ASCs nationwide.BENEFITS OF AMBULATORY SURGERY CENTERSSince their founding over 40 years ago, ASCs have grown exponentially. These distinct entities have provided physi-cians an avenue to provide specialized, efficient, and quality Figure 52-6. ProMedica Parkway Surgery Center. (Used with permission from ProMedica Health Systems.)Brunicardi_Ch52_p2153-p2162.indd 215628/02/19 4:17 PM 2157AMBULATORY SURGERYCHAPTER 5219486171118694117415 (AK)2 (GU)21 (HI)12218366426347196924956081693533941724 (PR)1 (VI)67136104523318610125122779923413411626 (NH)56 (MA)10 (RI)48 (CT)269 (NJ)23 (DE)345 (MD)3 (DC)79452Figure 52-7. As of June 2017, California has 794 ASCs, making it the leading state in terms of number of ASCs. It is followed by Florida with 417 ASCs and Texas with 366 ASCs. Vermont and the U.S. Virgin Islands have the lowest number of ASCs with one each.13Painmanagement10%Urology5%Orthopedics15%Plastic8%Gi14%Ophthalmology30%Other18%Figure 52-8. Specialties served in ASCs. GI = gastroenterology. (Reproduced with permission from Centers for Medicare & Medicaid Services, 2011.)care to patients who need surgical procedures. Patient satisfac-tion with same-day surgery has remained relatively high since ASCs started in 1970. It is important to recognize that patients undergoing generally nonemergent surgery that does not require a hospital stay are relatively satisfied overall. Historically, the field of ambulatory surgery has been associated with very high patient satisfaction.14-15 In the future, the CMS Consumer Assessment of Healthcare Providers and Systems (CAHPS) sur-vey will report on nationwide patient satisfaction with ASCs and HOPDs.16Factors Contributing to Popularization of ASCsCost. In many cases an outpatient procedure performed in an ASC is between one-half to one-third the cost as the same pro-cedure performed in a hospital. In large part, ASCs affect cost savings by eliminating overnight hospitalizations and emer-gency procedures. ASCs perform fewer extensive diagnostic tests and dispense fewer medications. These facilities are not staffed around the clock and are not encumbered by the need for expensive and highly specialized equipment as are hospitals. For example, the Medicare Payment Advisory Commission found that a cataract operation cost only $942 at an ambulatory surgery center in 2001 as opposed to $1334 at a hospital. Figures for an endoscopy and biopsy of the upper digestive tract were $429 and $359; for a diagnostic colonoscopy, $429 and $401; and for epi-dural anesthesia, $320 and $183, respectively5,7 (see Table 52-1).Organization, staffing, and specialization may play a large role in the cost differences between ASCs and HOPDs. On aver-age, patients who were treated in ASCs spend 31.8 fewer min-utes undergoing procedures than patients who were treated in HOPDs. ASCs could generate savings of $363 to $1000 per outpatient case.4Comfort. Whereas most hospitals keep patients recovering from a surgical procedure in separate rooms, in an ASC the patient usually can spend the recovery period after surgery with their loved ones. Limiting the number of delays and disruption of emergent cases allows the surgeon to spend more time with the patient in the preoperative and postoperative areas.17-19Convenience. Because ASCs usually schedule routine cases lasting no longer than 2 hours (average 30–45 minutes), and handle no emergency cases, scheduling is typically accurate. By avoiding the logjam, ASCs reduce the waiting time for elective procedures. A study by Hair et al reviewing Medicare patients again showed freestanding ASCs performed surgeries in less time than hospital-based ASCs overall and for procedures on various anatomic systems that resulted in reduced total time spent in facility with earlier discharge.19 These results corrobo-rate the notion that freestanding ASCs tend to be more efficient than HOPDs.20 One possible advantage for patients would be that they are able to leave an ASC relatively quickly after their surgery, resulting in less time away from work and family. This may be particularly true for pediatric patients or parents.Efficiency. This advantage is particularly important to sur-geons. It takes much less time to prepare an operating room in a specialized ASC for the next patient than in a standard hospital. Improved efficiency allows the surgeon to treat more Brunicardi_Ch52_p2153-p2162.indd 215728/02/19 4:17 PM 2158SPECIFIC CONSIDERATIONSPART IIpatients in the same amount of time than he or she would be able to do in a hospital; some surgeons maintain that they can do three times the number of procedures in an ASC as they could in a hospital setting. Many doctors prefer working in an ASC because they can set the standards for staffing, safety precautions, and postoperative care, rather than having these things decided for them by a hospital manager.1 Trentman and coauthors discuss several factors that affect patient flow and could result in differences in preoperative and recovery times for outpatient procedures between ASCs and hospitals.20 For example, compared to the situation in hospitals, in ASCs sur-geons are more likely to be assigned to a single operating room for all cases, which reduces delays; the operating room often is closer to the preoperative and recovery rooms because facili-ties are smaller; teams of staff have clearer and more consistent roles, with less personnel turnover; and staffing is not done by shifts—that is, staff members go home only after all cases are finished, which creates incentives to work quickly. In addition, hospitals may be more likely to have emergency add-on and bring-back cases for more complex cases that compete with outpatient procedures for operating room time.3,5,19 These dif-ferences suggest that hospitals would have to adopt a substan-tially different and highly specialized organizational model to achieve the same efficiencies as ASCs.REGULATION, COSTS, AND QUALITYRegulationHealthcare facilities in the United States are highly regulated by federal and state entities. ASCs are included in this over-sight, with both federal and state laws and regulations govern-ing all aspects of them. Independent observers evaluate the safety and quality of care provided in ASCs through three pro-cesses: Medicare certification, state licensure, and voluntary accreditation.To obtain Medicare certification, ASCs must meet the Medicare certification requirements, known as the Conditions for Coverage. These conditions include specifying standards for administration of anesthesia, quality evaluation, operating and recovery rooms, medical staff, nursing services, and other aspects of care. An ASC must have an inspection conducted by a state official or a representative of an organization that the government has authorized to conduct that inspection. These inspectors visit the ASC to verify that it meets established stan-dards. Each state determines the specific requirements ASCs must meet for licensure. An ASC does not have to be certi-fied by Medicare in order to be accredited by JCAHO; how-ever, most ASCs provide care to Medicare beneficiaries, so it is important to meet their requirements in order to be reimbursed appropriately. Medicare inspection and certification of ambu-latory surgery centers is a separate process from professional accreditation.To obtain state licensure, many states have independent rules and regulations as well as associated fees. These third-party bodies can include Accreditation Association for Ambulatory Healthcare (AAAHC), American Association for Accreditation of Ambulatory Surgery Facilities (AAAASF), and the Joint Commission on Accreditation of Healthcare Organizations (JCAHO). In states for which accreditation is not mandated, ASCs may undergo voluntary accreditation through these same associations. In 37 states, any party looking to open an ASC must demonstrate a need for the ASC to exist.21 State licensure requirements generally exist for both healthcare facilities and healthcare professionals.14There was previously controversy as to whether accredi-tation status affects safety outcomes. In multivariate analyses that controlled for facility volume and patient characteristics, patients at Joint Commission–accredited facilities were still significantly less likely to be hospitalized after colonoscopy. Specifically, compared with patients treated in nonaccredited ASCs regulated by the state agency, patients treated at accred-ited facilities were less likely to be hospitalized within 7 to 30 days after surgery.22 All accredited ASCs must meet spe-cific standards that are evaluated during on-site inspections. Patients who visit accredited ASCs can be assured that those medical facilities have rigorous checkpoints to ensure high standards.The Ambulatory Surgery Center Association (ASCA) or ASC Association has an integral role to ensure top-quality healthcare from the nation’s ASCs. The ASCA was established when the two leading national ASC associations—Federated Ambulatory Surgery Association (FASA) and the American Association of Ambulatory Surgery Centers (AAASC)—merged. The ASCA serves as the national membership orga-nization as well as the advocacy group for ASCs.21 The ASCA works with legislative and regulatory bodies, liaises with other organizations to improve access, reduce the costs of healthcare, encouraging insurance coverage of outpatient procedures, and works to establish standards for ASCs. ASCA requires all of its facility members to be accredited, licensed, or Medicare certi-fied. The ASCA was instrumental in forming the accrediting body that is now the largest accreditor of ambulatory surgery centers in the country.22CostsToday, more than 5300 Medicare-certified ASCs offer simi-lar services compared to those performed at HOPDs, and do so at a more efficient rate with lower costs. ASCs are able to accomplish this by decreasing administrative and overhead expenses.5 Expenses for an ASC include staff wages, insur-ance, utilities, rent, janitorial services, as well as resources necessary to handle patient records, including technology sys-tems. ASCs are able to schedule procedures without the risk of surgeries getting moved or cancelled due to emergencies. Additionally, ASCs enable patients to go home on the same day, therefore spending less time with staff in postoperative recovery rooms.Starting in 1982, Medicare has covered surgical proce-dures provided in ASCs.21 There are two primary elements of total cost in a surgical procedure: the cost of physicians’ pro-fessional services and cost of the facility. Typically, providers bill for professional service separately, whereas facility costs are paid to the ASCs. Currently Medicare provides separate payments for 3500 surgical procedures under the ASC pay-ment system.5 The payment system is maintained by CMS, which adjusts fees annually to maintain budget neutrality. Through the Medicare Prescription Drug, Improvement, and Modernization Act of 2003, payments to ASCs are based on the Outpatient Prospective Payment System (OPPS) and capped at no more than 59% of what is paid to hospitals for the same service.5During the period of 2008 to 2011, the growth in number of ASCs plateaued. The system saved an estimated $7.5 bil-lion for the Medicare program and its beneficiaries.5 However, Brunicardi_Ch52_p2153-p2162.indd 215828/02/19 4:17 PM 2159AMBULATORY SURGERYCHAPTER 52growth in procedure volume during this time was greater in ASCs than in hospitals.3 This suggests that physicians and patients still preferred using ASCs, possibly due to advantages in cost, convenience, comfort, or the inability for hospitals to meet demand for outpatient surgeries.QualityThe majority of ambulatory surgery centers ensure safety through maintaining certification and licensing of the facili-ties and associated staff. There are strict regulations in place at both the state and federal level that ensure quality in ASCs, which have been detailed earlier. ASCs are held to the same high standard of care as all U.S. medical facilities. They have comparable rates of use of perioperative antibiotics, patient falls, wrong-site surgery, and use of safety checklists.23 Nation-wide and among all procedures, from 2014 to 2016 fewer than 2% of all visits to ASCs resulted in an unplanned hospital visit within 7 days.5 Of these hospital visits, 1.6% were emergency department or observation stays, and 0.6% were unplanned inpatient admissions.24 CMS is working to develop a new qual-ity measure that will track unplanned hospitalizations after care at an ASC. This would help create increasing data on the quality of ASCs. Due to the isolated nature of ASCs, provid-ers are often unaware when a patient goes to the emergency department or is admitted to an unaffiliated hospital following a procedure. Thus, such a measure from the CMS will help educate providers and allow for continued quality improve-ment among ASCs.Looking at the general surgical population, cholecys-tectomy represents a key procedure to track because it is frequently performed, requires technical skill, and can result in serious complications. Provided appropriate patient selec-tion, outpatient cholecystectomy has been demonstrated to be safely performed in ASCs. ASCs charge significantly less for performing this procedure after controlling for the variety of indications (median of $6028 for ASCs compared to $10,876 for HOPDs).25OwnershipIn 2017, 90% of ASCs have partial or complete physician own-ership, while 25% to 30% of ASCs are at least partially owned by hospitals, as compared to HOPDs, which are by definition owned and operated exclusively by the hospital. A trend is developing for hospitals to purchase ASC ownership stakes due to their cost efficiency and as a means of diversifying revenue streams.26 Physicians have been a driving force in the devel-opment of ASCs through their ownership and building of new facilities. Ownership of an ASC provides many clear advantages to the physician because of the increased control and autonomy over their practice. Some advantages include ease of scheduling, shorter waiting times to get patients in for elective surgery, and the ability to hire specially trained and highly skilled staff. Phy-sicians can also avoid the bureaucracies of a hospital, including having elective surgeries cancelled to make room for emergent surgeries and delays due to more complicated surgeries. They can also ensure that the facility has specialized equipment for their particular specialty and can design the facility to meet their specific needs.26 Furthermore, physicians who perform surgeries in their own ASCs receive a share of the ASC’s facility payment in addition to payment for their professional services. This could present a conflict of interest in terms of referring patients and lowering the threshold for surgery, as discussed further in the next section.Potential for Conflict of InterestApproximately 90% of ASCs nationwide have at least some physician ownership stake. Many are joint ventures between hospitals and physicians.27 Increasing investment in these cen-ters may be explained in a number of ways, including an attempt by providers to assert greater control over their professional lives, such as by having greater authority in scheduling sur-geries and in purchasing equipment. Alternatively, this invest-ment trend may be explained by declining reimbursements for physician services and rising practice costs. These economic pressures have intensified providers’ interest in nontraditional revenue sources, such as ASC investment, as a means of gen-erating income.Ownership entitles physicians to collect a share of the facil-ity’s profits from referrals, in addition to their professional fees. One potential conflict of interest is that physician-owners might lower their thresholds for intervention, exposing the patient and healthcare system to the harm and cost associated with unneces-sary treatment. After differences between patients and health-care markets are adjusted for, physicians with ownership in an ASC have been found to perform a higher number of procedures compared with nonowner physicians at the same facilities.27 It has been noted that the increase in outpatient surgery at ASCs was more than double the decline in similar procedures per-formed in the hospital setting.28-29The other potential conflict in physician ASC ownership is in regard to patient referral. There is some evidence that physi-cians with an ownership stake may refer well-insured patients to their own facilities while referring Medicare and Medicaid patients to hospital outpatient clinics.30-32Regardless of the reason for increasing investment in and utilization of ASCs, it is important to note that ASC owner-ship creates a potential conflict of interest for physicians. In the United States, physician financial interests are heavily regulated by the Stark Law. This can be either a financial investment, employment, or compensation agreement. To avoid conflicts of interest and potential legal violations, physicians should consult with attorneys and advisors knowledgeable in medical law and ethics prior to entering a financial relationship.33CHALLENGESReimbursementSavings from use of ASCs are primarily to the patient and health-care system. Reimbursement to ASCs for services provided is, as a direct result, lower than reimbursement paid to hospitals for the same procedures. It is up to ASCs, which operate as private corporations, to find profit and viability by keeping their costs low through efficiency and staffing. Some steps suggested to improve the financial viability of maintaining an ASC include increasing the variety of procedures offered and grouping sur-geries in such a way as to maximize staffing usage.34Patient SelectionSafe use of ASCs is based on identification of patients who are unlikely to require admission to a hospital after their procedure. Thus far, ASCs do very well in this aspect. Unplanned admis-sions after ambulatory surgery occur in approximately 0.5% to 2.0% of cases.5,35-37 In the future, ASCs will be challenged to reduce this unplanned admission rate even further.Patients with Medicaid insurance, lower median household income, and a greater preoperative comorbidity burden have the Brunicardi_Ch52_p2153-p2162.indd 215928/02/19 4:17 PM 2160SPECIFIC CONSIDERATIONSPART IIhighest odds of unplanned acute care use. These patients may benefit from interventions that enhance and streamline postop-erative follow-up.38 Additionally, the potential costs associated with postoperative acute care following procedures performed in ASCs are not insignificant. Patient specific predictors of unplanned hospital admission include age 65 years or older, anticipated operating time longer than 120 minutes, cardiac comorbidities, peripheral vascular disease, cerebrovascular dis-ease, malignancy, positive for human immunodeficiency virus (HIV), and regional or general anesthesia use.39The strongest predictor for unplanned inpatient hospital admission was the individual patient’s own history of previ-ous hospitalizations, particularly among older adults. African American and Hispanic individuals also have had a markedly elevated risk of inpatient hospital admission, possibly related to cultural or socioeconomic issues of access to care.40 These mea-sures may provide a valuable target for quality improvement, cost improvement, and innovation.ASCs vs. Hospital Outpatient Departments vs. Office-Based Surgical SuitesCompetition is increasing among ASCs, HOPDs, and office-based surgical practices. The same improvements in anesthe-sia and surgical equipment that made outpatient surgery in a freestanding ASCs safe to perform have also led to a growing number of office based surgical suites and HOPDs. Procedures such as dental, ophthalmologic, endoscopy, cosmetic surgery, and liposuction are increasingly being performed in office-based facilities.41Physicians’ offices are under lower regulatory oversight in comparison to ASCs and HOPDs. This has resulted in the phenomenon of “practice drift,” whereby physicians perform procedures outside of their typical scope of practice. Despite several high-profile adverse events in lay media, prospective studies have demonstrated office-based surgical suites to be of similar safety.41,42 A recent, large study in the area of cosmetic surgery compared hospital-based procedures with office-based surgical suites and with ASCs and found accredited office-based surgical suites to be a safe alternative to ASCs and hospitals.43Aging PopulationWith increased risk of complications from surgery, the older adult population present a unique challenge to ASCs. ASCs must be prepared for complications that may arise from operating on older patients, and they must do so without the same resources as a hospital. The potential benefit of outpatient surgery for elderly patients is substantial, however, as older adults often suffer from postoperative cognitive dysfunction in an inpatient setting, which may be minimized with early discharge.44 Addi-tional benefits include lower cost to patients on fixed incomes and increased time and comfort at home.CONCLUSIONASCs represent a large benefit to society because of their poten-tial to reduce the financial burden of the healthcare system on the economy. At the same time, ASCs also provide high-quality care which is patient and family centered and convenient for providers. ASCs reduce the length of stay and minimize surgi-cal delays and cancellations. In the future, ASC quality will be rigorously tracked due to more regulatory oversight and data collection. The future of ambulatory surgical centers remains bright. Case numbers are increasing across many specialties, including general surgery, plastic surgery, vascular, urologic, and orthopedic practices. Surgeons should follow the matura-tion of ambulatory surgery closely.REFERENCESEntries highlighted in bright blue are key references. 1. Senagore EAJ. Ambulatory surgery centers. In: Encyclopedia of Surgery. 1st ed. Farmington Hills, MI: Gale Group; 2004:37-43. 2. Hall MJ, Schwartzman A, Zhang J, Liu X. Ambulatory surgery data from hospitals and ambulatory surgery centers: United States, 2010. Natl Health Stat Report. 2017;(102):1-15. 3. Cullen KA, Hall MJ, Golosinskiy A. Ambulatory surgery in the United States, 2006. Natl Health Stat Report. 2009;(11):1-25. 4. Munnich EL, Parente S. Procedures take less time at ambu-latory surgery centers, keeping costs down and ability to meet demand up. Health Affairs 2014;33(5):764-769. 5. Medicare Payment Advisory Commission. 2018. Report to the Congress: Medicare Payment Policy. Washington, DC: MedPAC. Available at: http://www.medpac.gov/-documents-/reports. Accessed August 27, 2016. 6. Advancing Surgical Care Association. Medicare cost savings tied to ASCs. 2013. Available at: http://www.advancingsurgicalcare.com/medicarecostsavings. Accessed August 27, 2018. 7. Definitive Healthcare. Top 10 outpatient procedures at ASCs and hospitals. 2014. Available at: https://www.definitivehc.com/news/top-10-outpatient-procedures-at-ascs-and-hospitals. Accessed August 27, 2018. 8. Nicoll J. The surgery of infancy. Br Med J. 1909;18:753-754. 9. Eger EI, Saidman LJ, Westhorpe RN, eds. The Wondorous Story of Anesthesia. New York: Springer; 2014. 10. The report. Arizona Republic. Sept. 10, 1970. 11. Ambulatory Surgery Center Association. Looking back and looking forward where it all began. FASA Update. May/June 2004. 12. Orkand DS. Comparative Evaluation of Costs, Quality, and System Effects of Ambulatory Surgery Performed in Alterna-tive Settings: Final Report. Washington: U.S. Dept. of Health, Education, and Welfare, Health Care Financing Administra-tion, Office of Policy Planning and Research; 1977. 13. Ambulatory Surgery Center Association. Number of ASCs per State. ASCs: a positive trend in healthcare. Advancing Surgi-cal Care. June 2017. Available at: https://www.ascassociation.org/advancingsurgicalcare/asc/numberofascsperstate. Accessed August 27, 2018. 14. Koenig L, Doherty J, Dreyfus J, Xanthapoulos J. An Analysis of Recent Growth of Ambulatory Surgical Centers. KNG Con-sulting. June 5, 2009. Available at: http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.512.4498&rep=rep1&type= pdf 15. Colorado Ambulatory Surgery Center Association. Ambulatory surgery center history. Available at: https://www.coloradoasc.org/general-resources/asc-history/. Accessed August 27, 2018. 16. Centers for Medicare & Medicaid Services. Overview. www .cms.gov/Medicare/Medicare-Fee-for-Service-Payment/ASCPayment/index.html. 17. Manchikanti L. Ambulatory surgery centers and interven-tional techniques: a look at long-term survival. Pain Physician. 2011;14(2):177-215. 18. Ambulatory Surgery Center Association. What is an ASC? Available at: https://www.advancingsurgicalcare.com/ advancingsurgicalcare/asc/whatisanasc, Accessed August 27, 2018. 19. Hair B, Hussey P, Wynn B. A comparison of ambulatory periop-erative times in hospitals and freestanding owners. Am J Surg. 2012;204(1):23-27. 20. Trentman TL, Mueller JT, Gray RJ, Pockaj BA, Simula DV. Outpatient surgery performed in an ambulatory surgery center Brunicardi_Ch52_p2153-p2162.indd 216028/02/19 4:17 PM 2161AMBULATORY SURGERYCHAPTER 52versus a hospital: comparison of perioperative time intervals. Am J Surg. 2010;200(1):64-67. 21. Rechtoris M. 51 things to know about the ASC industry. Becker’s ASC Review. Available at: https://www.beckersasc.com/asc-turnarounds-ideas-to-improve-performance/50-things-to-know-about-the-asc-industry-2017.html. Accessed August 27, 2018. 22. Ambulatory Surgery Center Association. Medicare certifi-cation. Available at: www.ascassociation.org/federalregula-tions/medicarecertification. Accessed August 27, 2018. 23. Ambulatory Surgery Center Quality Collaboration. Quarterly Report, 2nd Quarter 2018. http://www.ascquality.org/qualityre-port.cfm. 24. Dickson V. CMS seeks closer look at quality of care at ambu-latory surgical centers. Modern Healthcare. 2017. Available at: http://www.modernhealthcare.com/article/20170711/NEWS/170719987. Accessed August 27, 2018. 25. Paquette IM, Smink D, Finlayson SR. Outpatient cholecys-tectomy at hospitals versus freestanding ambulatory surgical centers. J Am Coll Surg. 2008;206(2):301-305. 26. Ambulatory Surgery Center Association. Benefits of physician ownership. 2011. Available at: https://www.advancingsurgicalcare. com/asc/benefitsofphysicianownership. Accessed August 27, 2018. 27. Becker’s Hospital Review. ASC ownership trends in 2017: more complex joint venture deals. Available at: www.beckershospitalreview.com/hospital-transactions-and-valuation/asc-ownership-trends-in-2017-more-complex-joint-venture-deals.html. Accessed August 27, 2018. 28. Conrad DA, Sales A, Liang SY, et al. Impact of financial incen-tives on physician productivity in medical groups. Health Serv Res. 2002;37(4):885-906. 29. Hollenbeck BK, Dunn RL, Suskind AM, Strope SA, Zhang Y, Hollingsworth JM. Ambulatory surgery centers and their intended effects on outpatient surgery. Health Serv Res. 2015;50(5):1491-1507. 30. Plotzke MR, Courtmanche C. Does procedure profitability impact whether an outpatient surgery is performed at an ambu-latory surgery center or a hospital? Health Econ. 20(7):817-830. 31. Mitchell JM. Effect of physician ownership of specialty hos-pitals and ambulatory surgery centers on frequency of use of outpatient orthopedic surgery. Arch Surg. 2010;145(8):732-738. 32. Gable JR, Fahlman C, Kang R, Wozniak G, Kletke P, Hay JW. Where do I send thee? Does physician-ownership affect referral patterns to ambulatory surgery centers? Health Affairs. 2008;27(3):165-174. 33. U.S. Department of Health and Human Services. Office of the Inspector General. A Roadmap for New Physicians: Fraud & Abuse Laws. Available at: oig.hhs.gov/compliance/physician-education/01laws.asp. Accessed August 27, 2018. 34. American College of Surgeons. Should your health care system invest in an ambulatory surgery center? A decision-making framework [Internet]. Bulletin of the American College of Surgeons. 2017 [cited 2018 Nov 28]; Available from: http://bulletin.facs.org/2017/11/should-your-health-care-system-invest-in-an-ambulatory-surgery-center-a-decision-making-framework/. 35. Mezei G, Chung F. Return hospital visits and hospital readmis-sions after ambulatory surgery. Ann Surg. 1999;230(5):721-727. 36. Twersky R, Fishman D, Homel P. What happens after discharge? Return hospital visits after ambulatory surgery. Anesth Analg. 1997;84:319-324. 37. Fox JP, Vashi AA, Ross JS, Gross CP. Hospital based, acute care after ambulatory center discharge. Surgery. 2014;155(5): 743-753. 38. Molina G, Neville BA, Lipsitz SR, Gibbons L, Childers AK, et al. Postoperative acute care use after freestanding ambulatory surgery. J Surg Res. 2016;205(2):331-340. 39. Fleisher LA, Pasternak LR, Lyles A. A novel index of ele-vated risk of inpatient hospital admission immediately fol-lowing outpatient surgery. Arch Surg. 2007;142(3):263-268. 40. Fleisher LA, Pasternak LR, Herbert R, Anderson GF. Inpa-tient hospital admission and death after outpatient surgery in elderly patients: importance of patient and system charac-teristics and location of care. Arch Surg. 2004;139(1):67-72. 41. Urman RD, Punwani N, Shapiro FE. Office-based surgical and medical procedures: educational gaps. Ochsner J 2012; 12(4):383-388. 42. Coldiron B, Shreve E, Balkrishnan R. Patient injuries from surgical procedures performed in medical offices: three years of Florida data. Dermatol Surg. 2004;30(12 pt 1):1435-1443, discussion 1443. 43. Gupta V, Parikh R, Nguyen L, et al. Is office-based surgery safe? Comparing outcomes of 183,914 aesthetic surgical procedures across different types of accredited facilities. Aesthet Surg J. 2017;37(2):226-235. 44. Aurini L, White P. Anesthesia for the elderly outpatient. Curr Opin Anesthesiol. 2014;27:563-575.Brunicardi_Ch52_p2153-p2162.indd 216128/02/19 4:17 PM
Brunicardi_Ch52_p2153-p2162.indd 216228/02/19 4:17 PMThis page intentionally left blankBACKGROUNDIntroductionThe basic American surgical training model is patterned after that established by William Steward Halsted at the Johns Hopkins Hospital in the late 19th century. By tradition, it has consisted of a regulated apprenticeship system with incremental increases in clinical responsibility for resident surgeons over a specified period of time culminating with the expectation that independent surgical practice will be possible at its conclu-sion. While this approach has served well throughout the 20th century, the pace of changes in healthcare delivery and society itself has driven the need for new approaches to education and training. Among the important changes that the surgical training community has had to confront are an expanding array of medi-cal and surgical therapies, complex, new and sometimes disrup-tive technologies advancing at a dizzying pace, and increasing recognition of the opportunities for errors and adverse outcomes because of inadequate preparation for this new world of surgical practice.1 Appreciation of the scale and insidious consequences of medical errors began to take hold in the 1990s when the groundbreaking Institute of Medicine report “To Err is Human” presented to the public a dire picture of the frequency and impli-cations of medical errors.2 Among the proposed new approaches to deal with this problem was the use of simulation training.Simulation is the imitation of an actual or possible real-world condition or event. The degree to which a simulation resembles its real-world counterpart describes its fidelity. There are innumerable specific applications of simulation to train or assess human performance on anticipated real-world tasks. As such, it is a valuable tool with great potential to increase safety in high-stakes undertakings such as commercial aviation, military training, and nuclear power generation. These are a few areas where such training has been implemented successfully. With the advent of widely available digital computing, the level of technology applied to simulation and simulators has made near-complete fidelity possible. Moreover, the enormous expense associated with full motion flight simulation, for example, has been made acceptable by safety gains that benefit entire popula-tions. In medicine, there has been gradual acceptance of the role of simulation to achieve these same goals, and this has led to an array of simulation methods and uses that specifically target surgical providers at all levels. The fundamental justification for commitment of resources to simulation is an ethical one: to reduce patient risk associated with invasive surgical procedures or management of complex clinical problems. Simulation meth-ods provide opportunities for surgical learners to practice their skills under safe conditions in preparation for clinical experi-ences and to be assessed and deemed ready for those encounters.Skills Labs and Skills TrainingThe history of surgical skills training outside the clinical oper-ating room (OR) is a long one, involving practice of surgical skills and procedures using various models, including animals and cadavers. Newer training practices, including simulation use in a laboratory setting, have emerged that focus on objec-tive assessment of skill and establishment of specific, defined levels of proficiency. These assessment-based approaches are relatively recent educational developments and are being imple-mented as a means to improve surgeon skill in a safe setting for both learners and patients.3 The use of inanimate benchtop mod-els to test surgical skills required a leap into the world of vali-dation of measurement methodologies. The most important of these pioneering efforts was the implementation of the objective Skills and SimulationNeal E. Seymour and Carla M. Pugh 53chapterBackground2163Introduction / 2163Skills Labs and Skills Training / 2163Scientific Underpinnings of Simulator Use / 2165Simulation in Graduate Medical Education / 2165“Bootcamps” / 2166Specific Simulation Training and Assessment Applications2166Training Basic Surgical Skills / 2166Fundamentals of Laparoscopic Surgery / 2168Bench Models for Training Specific Procedural Skills / 2168Transfer of Training / 2169Virtual Reality / 2169Virtual Reality for Flexible Endoscopy / 2172Virtual Reality for Endovascular Interventions / 2173Patient-Specific VR Surgery Simulation / 2174Robotic Surgery Simulators / 2174Fundamentals of Robotic Surgery / 2174Nontechnical Skills2175High-Fidelity Patient Simulation and Team Skills / 2175Error Prevention2177Simulation and Patient Outcomes2178Simulation Training for the Practicing Surgeon and Maintenance of Skill2179Future Considerations2179Brunicardi_Ch53_p2163-p2186.indd 216322/02/19 4:39 PM 2164Key Points1 Learning basic skills at the point of care imposes inef-ficiencies that might very well endanger support for the education mission.2 In 2006, the Accreditation Council for Graduate Medical Education Residency Review Committee for Surgery instituted a formal requirement for simulation training in surgical residency.3 Procedural skills training in a simulated environment has been shown to transfer to the real-life clinical setting.4 Early studies of virtual reality training using both proficiency-based and non–proficiency-based training methods showed it to be an effective means of improving laparoscopic skill both in the lab and in the operating room compared to non–virtual reality trained controls.5 Use of proficiency-based training in the context of a larger curriculum appears to be the best way to achieve good training results irrespective of the training platform used.6 When assessing simulator validity, researchers have noted that the use of robotic surgery simulators does translate to the clinical environment and the learning curve for initial console training for surgeons is significantly decreased.7 Simulation training for communication and other teamwork-pertinent nontechnical skills requires learners to be embedded in realistic scenarios pertinent to a healthcare team’s actual clinical responsibilities.8 Simulation technology allows trainees the opportunity to execute a variety of tasks and procedures while also expe-riencing the cognitive demands of surgery, including error correction and surgical planning decisions.9 The immediate future of simulation in surgery will likely see expanded use of proficiency-based training given the consistent demonstrations of effectiveness in improving surgeon skills and improved educational outcomes as mea-sured in clinical settings.10 Advances in wearables, motion tracking, and sensor tech-nologies allow for a wide variety of hybrid and augmented experiences in simulation as well as extensive opportuni-ties for the development of new performance metrics.structured assessment of technical skills (OSATS) program by educators at the University of Toronto.4,5 Using a series of repro-ducible physical models of surgical tasks (excision of a skin lesion, bowel anastomosis, insertion of a T tube, and abdominal wall closure) and carefully designed rating instruments, it was possible to show validity of these measurements when com-pared with skill manifested during surgery in animal models. This demonstration of practical measurement of skill in the lab, where observation for skills rating purposes can be more read-ily achieved, was seminal in sparking both additional interest in lab-based training and in simulation as a mainstream educa-tional method for surgeons.The advent of laparoscopic general surgery in the late 1980s and early 1990s, a disruptive technology at that time, was a major driver for the use of surgical simulation to gain unfa-miliar and nonintuitive skills needed to safely perform limited-access videoscopic surgery. The recognition that bile duct injury risk is increased by surgeon inexperience stimulated interest in simulation in order to separate a component of the psychomotor learning curve for laparoscopy from the clinical OR and patient by transfering it to the training lab.6-8 At the same time, interest in the science of skills acquisition and measurement made efforts to gain surgical proficiency with simulation more meaningful. The measured performance characteristics of experienced sur-geons came to be appreciated as useful learning targets for less experienced surgical learners, and the concept of proficiency-based training began to be implemented successfully not only for research purposes but also for formative education.9As simulation began to be used more extensively and skills labs either evolved or merged with multidisciplinary education centers using simulation as a primary instructional method, recognition of such centers as focal points for surgical education also grew. The American College of Surgeons (ACS) Education Division recognized early on that simulation training was an important educational method that surgeons could take advantage of and began to explore ways to facilitate growth and implement training centers. In 2006, the ACS began to accredit education centers engaged in simulation training as Level 1 (comprehensive) and Level 2 (focused) Education Institutes.10 The consortium of 95 institutes, as of early 2017, now spans the globe with centers across the United States and Canada as well as several institutions outside of North America.In 2007, the American College of Surgeons and the Asso-ciation of Program Directors in Surgery (APDS) initiated a project to provide a standardized skills curriculum for surgi-cal residents. These efforts produced the modular ACS-APDS skills curricula that represent the first comprehensive and widely available resource that prescribes simulation experi-ences as the principal means to achieve educational objectives.11 The resources and curricula are readily available to residency programs to address surgical resident learning needs and to facilitate simulation lab use as mandated by the Accreditation Council for Graduate Medical Education (ACGME). The three components of the curriculum are basic technical skills, proce-dural skills, and team skills. Although these have been acknowl-edged to be valuable and have been utilized to meet resident training needs, implementation has been limited according to a recent survey of residency programs.12 Elements of the basic skills curriculum were reported to be used by 36% of respon-dents while procedural and team training modules were reported to be in use by about half as many programs. Nonetheless, the article notes that simulation methods had permeated surgical education and the various stakeholder organizations had taken steps to either endorse or implement programs for simulation use. The need to explore simulation-based education, as stated by the Surgical Council on Resident Education (SCORE), sug-gests a pathway by which simulation methods might become fully integrated into standardized cognitive elements of surgical residency curriculum.13 Based on current trends, a competency framework can be envisioned that combines advanced forms of Brunicardi_Ch53_p2163-p2186.indd 216422/02/19 4:39 PM 2165SKILLS AND SIMULATIONCHAPTER 53standards-based learning using simulation and measured per-formance in the OR for purposes of trainee advancement and certification.Scientific Underpinnings of Simulator UseThe assumption that surgical technical skills can be effec-tively learned and tested outside the OR serves as the basis for simulation based assessment of skills before, during, and following training. This capability permits the explicit descrip-tion of understandable surgeon performance characteristics including those that can be characterized as desirable training goals (e.g., “expert”). The effectiveness of specific models of training can also be ascertained by comparative studies examin-ing educational endpoints, such as rate of learning, or testable performance either in simulations or in clinical settings. Sim-ulation-based learning has been described using various peda-gogical models to help educators understand and leverage the most effective strategies to achieve educational goals. The most fundamental concept used to justify time spent in skills training is the prospect of achieving progressively higher levels of skill pertinent to clinical care. For medical care providers, this pro-gression is commonly related to the learning model described by Dreyfus and Dreyfus.14 This model depicts changes in specific mental functions (recollection, recognition, decision, awareness) associated with incremental steps in the progres-sion from novice status to that of expert (Fig. 53-1). The rel-evance of Anders Ericsson’s description of deliberate practice to development of clinical skills is also widely accepted.15 This is predicated on the concept that “expert” performance is fun-damentally different than normal performance and results from behaviors that “reflect a life-long period of deliberate effort to improve performance in a specific domain.”16 The drive to achieve mastery in surgery, provides an aspirational model for the surgeon’s use of simulation because the opportunity for deliberate, repetitive practice of numerous skills in the clinical setting alone is insufficient and in many cases nearly impossi-ble. For this concept to be translated into effective educational results, simulation-based education must be of high quality, and the curricular framework created for its use must be directed toward carefully crafted, attainable, and clinically relevant edu-cational goals.Simulation in Graduate Medical EducationSurgery residency has been a particular area of focus for simula-tion use in assessment and training. The need for safe and rapid skills development is especially important in this group of learn-ers whose time in training is limited and for whom every hour spent in education must be prioritized for highest impact. The added direct costs of operative care in training institutions has also provides a strong imperative to conduct training that mini-mizes negative implications of resident involvement in surgical cases.17 Learning basic skills at the point of care imposes inef-ficiencies that might very well endanger support for the education mission.11. Transcends reliance on rules, guidelines, and maxims2. Intuitive grasp of situations based on deep understanding3. Has a vision of what is possible4. Uses an analytical approach in new situationsExpertProÿcient1. Holistic view of situation2. Prioritizes importance of aspects3. Perceives deviations from the normal pattern4. Employs maxims for guidance, with meanings that adapt to the situation at handNovice1. Rigid adherence to taught rules or plans2. No exercise of discretionary judgementAdvancedbeginner1. Limited situational perception2. All aspects of work treated separately with equal importanceCompetent1. Coping with crowdedness (multiple activities, information)2. Some perception of actions in relation to goals3. Deliberate planning4. Formulates routinesFigure 53-1. Dreyfus model describing stepwise skills development. In surgery, specific stages of expertise are achieved through cognitive learning, technical practice, and experience and are defined by specific cognitive and behavioral characteristics affecting how we perceive, process, and act in the task environment. (Reproduced with permission from University of South Australia; Teaching and Learning in Health Sciences: https://lo.unisa.edu.au/mod/book/view.php?id=611284&chapterid=104113.)Brunicardi_Ch53_p2163-p2186.indd 216522/02/19 4:39 PM 2166SPECIFIC CONSIDERATIONSPART IIDespite early examples of excellence in simulation lab use and fairly wide availability, a survey of residency programs in 2006 suggested the quality of usage for laparoscopic skills training was probably low and that more than half did not use a defined curriculum.18 Also in 2006, the ACGME Residency Review Committee (RRC) for Surgery instituted a formal requirement for simulation training in surgical residency.19 While the core program requirement did not define any specific educational objectives, performance outcomes, or specific methods to be used, there was a mandate that simulation in surgical education be objectives-based and that it be incorpo-rated into residency curricula within 2 years. As of 2016, the relevant core program requirement indicates that “resources must include simulation and skills laboratories” and that “these facilities must address acquisition and maintenance of skills with a competency-based method of evaluation.”20 Since the original notification of the need to conduct this training, man-dated activities have expanded with the pairing of ACGME statements and new American Board of Surgery (ABS) require-ments for certifications in Fundamentals of Laparoscopic Surgery (FLS; instituted for 2010 residency graduates) and in Fundamentals of Endoscopic Surgery (FES; instituted for 2018 residency graduates). Both of these certifications demand lab-based practice in order to successfully pass respective technical skill test components.Both high and low technology and fidelity, off-the-shelf, simulation training solutions have become available for sur-gery residents’ lab-based training. Curricular content such as the ACS-APDS skills modules are readily available to facilitate a sufficient level of implementation to meet the RRC require-ments, although preparation methods have not been specifically prescribed by either the ACGME or the ABS. In 2015, the ABS issued a new requirement for a comprehensive multilevel Flexible Endoscopy Curriculum (FEC) paired with FES certification. This curriculum states explicitly that experiential requirements at the lower levels can be met with simulation methods but it is left to individual programs to decide what preparatory practice in simulation might consist of for their own residents.21Options for simulation use in surgical training are cur-rently numerous and can be implemented with basic facilities and equipment, but the determination to use these methods suc-cessfully requires considerable effort that is greatly aided by fully motivated and engaged faculty members with protected time. There are now numerous guides and recommendations for successful surgical simulation lab start-ups.18,22-24“Bootcamps”Preparatory training for surgery residency both before and immediately after the start of residency is now a widely used educational practice. The rationale for these programs includes early development of basic skills that would be of obvious use to the new trainee as well as determination of the status of basic skills that would serve as a needs assessment to model curricu-lar efforts expected to be most appropriate for the individual resident.25-27 The suggestion that new interns will render safer care has been garnered from results of intensive, short-duration preparatory training that shows higher level of skills measured in simulation are feasible compared to the “control” situation of not using such training.28 However, none of the current reports address whether intensive preparatory training addresses the “July Effect” by improving clinical effectiveness during the earliest months of training.28Much of the training and assessment during these pro-grams is accomplished using simulation methods. No stan-dardized approach has yet been suggested, and at the present time the impact of specific simulation components is difficult to assess for senior students entering surgical training, or new interns. Sound recommendations on this await further study. A single meta-analysis of postgraduate “boot camp” programs both prior to or at the start of residency found that all programs utilized high and low technology simulation methods as “a key component.”29 Although the analysis included all medical spe-cialties, 93% of the studies were surgical in nature, underscor-ing the perceived value of this preparatory training for new surgeons. The examined studies were those where preand posttraining effects were measured in some way. The compiled data revealed that trainees who completed the programs had uni-formly strong increases in skills development, knowledge, and confidence. In 2014 the ABS, ACS, APDS, and Association for Surgical Education, citing the evidence of effectiveness of these now numerous preparatory courses, officially endorsed them as a useful method to position fourth-year students and interns for early success in residency.30 Whether preresidency exposure to surgical simulation can influence a medical student’s decision to pursue a surgical career remains to be determined.SPECIFIC SIMULATION TRAINING AND ASSESSMENT APPLICATIONSTraining Basic Surgical SkillsThe use of the simulation lab to train open, laparoscopic, and flexible endoscopic basic skills in preparation for care and prac-tice clinical constitutes the most accessible and widely adopted set of simulation training practices. In connection with these, the term “proficiency-based” training (sometimes used synony-mously with competency-based or objectives-based) is often used, and can be defined as the use of meaningful performance standards as educational goals for training. Implicit in the term is the expectation that if proficiency standards are achieved, a learner will be better positioned to perform to a desirable stan-dard in the clinical setting. Even these most basic skills have been shown to improve with proficiency-based training.31 Addi-tional benefits of proficiency-based approaches to basic surgical skills include knowledge of a surgical learner’s specific educa-tional needs and design of a larger skills curriculum roadmap that envisions progression to more advanced skills training.Educators at Southern Illinois University implemented a program of intensive lab-based practice of basic skills as a pre-liminary requirement to participate in operative cases. Termed “Verification of Proficiency,” this program targets junior train-ees for assessment of skill using OSATS-like rating instruments, but its unique feature is the definition of a minimal level of skill that would permit a resident to assume the role of operator for specific case types.32,33More recently, the concept of “proficiency-based progression” has been used to describe a formalized process of use of sequenced proficiency standards and a continuum of progres-sively more advanced and challenging simulation experiences as a potential future model of training.34 Such a model would span whatever period of time was necessary for each learner to progress from basic surgical skills to more advanced ones.Open Surgical Skills. A variety of benchtop models for prac-tice and assessment of basic open skills are available, the most 2Brunicardi_Ch53_p2163-p2186.indd 216622/02/19 4:39 PM 2167SKILLS AND SIMULATIONCHAPTER 53Table 53-1ACS-APDS basic skills curriculum components• Asepsis and instrument identification• Knot tying• Suturing• Skin flaps• Skin grafts• Urethral catheterization• Airway management• Chest tube insertion• Central line insertion• Surgical biopsy• Laparotomy opening and closure• Basic laparoscopy skills• Advanced laparoscopy skills• Hand-sewn bowel anastomosis• Stapled bowel anastomosis• Arterial anastomosisFigure 53-2. Abdominal wall closure model made from commonly available materials using instructions in the ACS-APDS Basic Skills Curriculum module for this task.well-known of which are the OSATS tasks that remain in use more than 20 years after their inception. The ACS-APDS Basic Skills Curriculum (Table 53-1) is a useful resource for this.Generally, lower-fidelity models are more cost effec-tive for repetitive training because durability with reuse may be better than high-fidelity physical models and replacement costs can be minimized for many tasks. Examples can include simple models for abdominal wall closure (Fig. 53-2). The use of low-fidelity models in well-formulated curricular train-ing can be very effective in increasing resident skill, although high-quality measurement can be labor intensive. Bowel and vascular anastomosis training has been an especially impor-tant point of focus given their prominence and highly technical nature in clinical practice. In a recent analysis of resident expe-rience with gastrointestinal anastomosis, Nemeth reported that although frequently performed (average 67 per resident), stapled anastomosis experience predominates during training (91% of laparoscopic procedures and 82% of open ones), suggesting a relatively small clinical experience with hand-sewn anastomotic methods, which remain critically relevant.35 Simulated bowel anastomosis models are widely available (Fig. 53-3), and there are numerous reports of successful curriculum-based devel-opment of this core technical skill generally utilizing OSATS rating instruments.36-38 Although further study is required to demonstrate a clinical effect of this training, other experience strongly suggests that use of proficiency-based anastomosis training should be the next step. In an example of how this could be used for trainee benefit, Palter conducted a randomized trial of use of a proficiency-based technical skills and cognitive cur-riculum for abdominal wall closure.39 The technical skills com-ponent utilized a low-fidelity model for an OSATS assessments of both lab and OR performance. Residents in the intervention arm performed better on both clinical abdominal wall closure and a test of procedural knowledge than controls.Basic Laparoscopic Manipulative Skills. Current evidence supports the concept that basic laparoscopic skills should be developed in the training lab, avoiding safety concerns as well as the expenditure of time and effort that would result from learning in clinical settings. Specific programs for basic laparo-scopic skills development coupled with skills assessment were set forth 20 years ago at a time when this need was newly articu-lated for surgeons at all levels.7,40,41 These utilized videoscopic training “boxes” for two-handed practice using laparoscopic instruments to manipulate box contents. Programs such as the Rosser drills employed various dexterity tasks emphasizing time for task completion as a measure of performance. Later, McGill investigators began to apply greater scientific rigor to the design Brunicardi_Ch53_p2163-p2186.indd 216722/02/19 4:39 PM 2168SPECIFIC CONSIDERATIONSPART IIABFigure 53-3. A. Hand-sewn GI anastomosis from the ACS-APDS Basic Skills Curriculum module for this task. A full instructional presen-tation is available with the curriculum along with an assessment instrument for the educator to use. B. OSATS stapled bowel anastomosis model. (Reproduced with permission from de Montbrun SL, Macrae H Simulation in surgical education, Clin Colon Rectal Surg. 2012 Sep;25(3):156-165.)and testing of basic skills curricula, with a particular focus on the ability to characterize the skills acquisition process and dif-ferences between learner groups based on careful repetitive measurement.42 Further study showed that performance, mea-sured using these bench training tasks, correlated with perfor-mance measured in vivo animal models.43 In addition to helping learners prepare for basic tissue manipulation, training on basic tasks were found to shorten the learning curves for more com-plex laparoscopic tasks such as suturing.44Fundamentals of Laparoscopic SurgeryFundamentals of Laparoscopic Surgery (FLS) was devised by minimally invasive surgical leaders in the Society of American Gastrointestinal and Endoscopic Surgeons as a means to assess laparoscopic surgical knowledge and skills for the purposes of certification of basic ability.45 This program represents the first broadly applied effort to demonstrate achievement of a specified level of basic surgical skill with such specific test-ing. Although most utilized by surgical residents, the resulting skills certification is applicable to a broad range of learners, including surgeons in practice as well as laparoscopic sur-geons in specialties other than general surgery. FLS consists of separate tests of knowledge and technical ability. The lat-ter component required integration of simulation tasks with a high degree of validation for both effectiveness in discerning skill and relevance to the respective clinical tasks. The McGill Inanimate System for Training and Evaluation of Laparoscopic Skills (MISTELS) tasks were selected as the technical skills assessment component.46 These were developed independently from the FLS program and adapted to the FLS based on the predictive value of a subset of the tasks for clinical skills mani-fested in the OR. These tasks have remained core features of the certifying examination and have been extensively studied both as training curriculum components and as predictors of clinical performance.47,48 Recent work has suggested that spe-cific proficiency-based training can increase pass rates on FLS to 100%, supporting the general suppositions about the benefits of this model of training.49The more recently available FES serves a similar purpose to FLS for flexible endoscopy.50 This certification adds the important feature of use of a virtual reality flexible endoscopy simulator as one of the platforms for delivery of the technical skills test.Bench Models for Training Specific Procedural SkillsProcedure-specific simulation offers a unique opportunity to practice and evaluate wholesome surgical skill. This includes training and evaluating the relationship between basic and com-plex technical skills and surgical decision-making. While the majority of procedural simulation trainers focus on bedside procedures such as central venous catheter placement, blad-der catheterization, and intubation, a number of trainers also have been designed to simulate more complex procedures such as laparoscopic ventral hernia, laparoscopic colectomy, and robotic nephrectomy.51-53 Currently, both virtual reality and physical or hybrid models are used for procedure-specific simulations.54 While each technology has specific benefits, there is still a critical need for fabrication and design approaches that are efficient, cost effective, and produce anatomically accurate models with realistic tissue properties.55 A number of groups have explored the use of three-dimensional (3D) printing with varying degrees of success.56,57 As the printing substrate materi-als and 3D machines continue to decrease in price and increase in ease of use, there will likely be a significant upsurge in the use of this approach to facilitate development of procedure spe-cific simulations. In addition to full immersion virtual reality, a number of groups are still exploring the benefits of computer-based learning for training procedure-specific surgical skills.58The training and assessment benefits of procedure-specific simulation are numerous. Not only does it allow an opportunity to assess technical skill in the context of a multistep procedure, forced errors and critical decisions can be combined with this technology, allowing for a more in-depth learning experience and skills assessment. By way of example, two multistep bed-side procedures were modified: bladder catheterization and central venous catheter insertion. Both simulations had embed-ded clinical scenarios, which if executed incorrectly in real life might produce patient injury due to incorrect technique or equipment choices. During the implementation of these modi-fied, multistep procedures, it was possible to identify individual cognitive and technical errors that serve as opportunities for additional training.59,60 The ACS-APDS Procedural Skills Curriculum was developed to complement the Basic Skills Curriculum and offers detailed learning objectives for a vari-ety of surgical procedures. The goal of this curriculum was to address holistic surgical skills in a context where both technical Brunicardi_Ch53_p2163-p2186.indd 216822/02/19 4:39 PM 2169SKILLS AND SIMULATIONCHAPTER 53Table 53-2ACS-APDS procedural skills curriculum components• Laparoscopic ventral hernia repair• Open colon resection, lap right colon resection• Laparoscopic sigmoid resection• Open right colon resection• Laparoscopic/open bile duct exploration• Laparoscopic ventral/incisional hernia repair (porcine model)• Laparoscopic appendectomy• Laparoscopic Nissen fundoplication• Sentinal node biopsy and axillary lymph node dissection• Open inguinal/femoral hernia repair• Laparoscopic inguinal hernia repair• Laparoscopic/open splenectomy• Laparoscopic/open cholecystectomy• Gastric resection and peptic ulcer disease• Parathyroidectomy/thyroidectomyand cognitive performance could be assessed at the same time.11 The simulation scenarios defined for this curriculum are listed in Table 53-2.Similar to the literature on basic skills training and assess-ment, procedural skills training and assessment has been shown to benefit learners when delivered via a structured curriculum. In addition, procedural skills training in a simulated environ-ment has been shown to transfer to the real-life clinical setting. In 2005, Issenberg et al published a review of the features and uses of simulation training that lead to effective learning.61 After reviewing 109 articles that specifically used simulation as an educational intervention and not for assessment alone, Issenberg and colleagues noted that feedback, repetitive practice, and curricular intervention were among the top three features that lead to effective learning. Of note, in this same article, it was noted that simulator validity was at the bottom of the list of features that lead to effective learning. In essence, trainees need protected time to engage in simulation-based learning exercises that have a high-level focus on deliberate and repetitive practice based on personalized feedback. This model is very similar to that used to train professional athletes.62Transfer of TrainingThe determination that simulation-based education is effective requires assessment of training effect in either the clinical setting or one with a demonstrated relationship to a clinical setting. The latter might result from comparison to a validated “gold standard” training method. Establishing a relationship between lab-based training and performance in the OR requires validated measures of operative skills such as the widely used Global Assessment of Operative Laparoscopic Skills (GOALS) method described by Vassiliou.63 The majority of studies of laparoscopic simulation training that examine transfer of skills to the clinical OR make comparisons to control groups without highly structured and non-simulation based training. The results of these studies should eliminate any doubts that surgical learners, especially students and residents, can achieve training benefits from both proficiency-based and timeor repetitionor session number-based simulation practice. When the results of proficiency-based training are dissected out from the other models of training, consistently higher levels of clinical or 3animal OR performance is observed with such training compared to without.64-67 In one such review of skills transfer studies conducted between 2007 and 2013, Dawe reported results for general surgery and gynecology procedures using different virtual reality and non-VR laparoscopic simulation platforms (Table 53-3).48,67-77 For the 12 randomized controlled trials with surgical residents as study subjects, all but one showed significantly better clinical performance for intervention groups compared to non–simulation-trained controls.The comprehensive reviews of skills transfer data under-score the wide disparities in study design characteristics, metrics, simulator types, and the difficulties in comparing effectiveness of different simulation interventions. The “transfer effectiveness ratio” (TER) has been forwarded as a means of expressing the relative magnitude of the training effect and may provide a basis for comparison of cost or time efficiency of different training methods.78 To determine TER for a simulation training effort, one would calculate the difference in clinical effort (time or some other measure such as number of cases) between simulator-trained and alternative-trained groups to achieve a desired level of clinical performance, divided by training time received by the simulator-trained group.Korndorffer raised concerns with studies of transfer of training when, irrespective of the improved results in lab performance with proficiency-based practice, residents studied by their group did not readily meet performance standards for more advanced skills set by expert surgeons in practice.79 Looking for opportunities to maximize the effectiveness of simulation training, Stefanidis proposed training to “automaticity” by adding a secondary visuospatial task to practice with laparoscopic suturing, but only after proficiency levels were achieved with more standard laparoscopic suturing practice.80 It was suggested that the added attentional challenge likely prompted the achievement of automaticity, the end result of which was much greater performance than was seen for proficiency-based practice alone. It is not clear, however, that simply adding to task difficulty improves training results if learner capabilities are not taken into account. In a separate study, Stefanidis also reported that increased task difficulty during proficiency-based training causes measurable increases in cognitive workload and that when confronted with these challenges, novice learners did not perform better than those in proficiency-based training at a lower level of difficulty, suggesting a possible mismatch between task challenges and capacity to learn.81 More work is required to characterize the proper balance of training difficulty and the capacity for learning in specific learners or learner groups.Virtual RealityThe use of virtual reality (VR) simulation as a way to deliver training experiences in surgery was proposed by Satava in 1993.82 Within a few years, practical applications of this technology led to the first commercially available laparoscopic simulators and studies to determine their value. The earliest and most functional VR platform was MIST-VR which permitted manipulation of abstract virtual objects using a realistic physical interface that transduced instrument motion into actions that could be observed in the virtual environment (Fig. 53-4).83 Even without a force feedback apparatus and haptic, or “sense of touch,” cues expected with instrument–instrument or instrument–object interactions, learners could experience the psychomotor challenges of videolaparoscopy and iteratively train until Brunicardi_Ch53_p2163-p2186.indd 216922/02/19 4:39 PM 2170SPECIFIC CONSIDERATIONSPART IITable 53-3Randomized trials studying the effects of virtual reality training on surgical and OB-GYN resident operative performance vs. control trainees without virtual reality trainingAUTHOR (YEAR)PARTICIPANTS (N) AND SIMULATORPROCEDURE ASSESSEDCONCLUSIONAhlberg et al68 (2007)PGY 1–2 surgery residentsIG (7); Lap Sim VR simulatorCG (6) no simulationLaparoscopic cholecystectomyIG made fewer errors (P = 0.004), exposure (P = 0.040), clipping and tissue division (P <0.008), and dissection (P <0.031) compared with CGBanks et al69 (2007)PGY 1 GYN residentsIG (10); Limbs & Things box trainerCG (10) no simulationBilateral tubal ligationIG scored higher than CG with all three evaluation tools: task-specific checklist (P = 0.002), OSATS (P = 0.003), pass-fail grade (P = 0.003)Cosman et al70 (2007)Junior surgical traineesIG (5); Lap Sim VR simulatorCG (5) no simulationLaparoscopic cholecystectomy (clip application and cystic artery division)IG had fewer errors (P = 0.05), better bimanual coordination (P = 0.05), higher global score (P = 0.04) than CGGala et al71 (2013)GYN residentsIG (48); FLS box trainerCG (54) no simulationPomeroy bilateral tubal ligationIG had higher OSATS progression score than CG (P = 0.03)Hogle et al72 (2009)PGY 1 surgery residentsIG (6); Lap Sim VR simulatorCG (6) no simulationLaparoscopic cholecystectomyNo significant difference between IG and CG in GOALSDomain areas of depth perception, bimanual dexterity, efficiency, tissue handling, autonomyLarsen et al73 (2009)Firstand second-year OB-GYN registrarsIG (13); Lap Sim VR simulatorCG (11) no simulationSalpingectomyIG had higher score than CG in OSA-LS scale (P <0.001). IG completed procedure faster than CG (P <0.001)Sroka et al48 (2010)PGY 1–3 surgery residentsIG (8); FLS box trainerCG (8) no simulationLaparoscopic cholecystectomy (excision from liver bed)IG had higher total GOALS score than CG (P <0.001) and better GOALS domain scores for bimanual dexterity (P = 0.04), tissue handling (P = 0.04)Van Sickle et al74 (2008)PGY 3, 5–6 surgery residentsIG (11); MIST-VR simulatorCG no simulationNissen fundoplication (placement of intracorporeal sutures)IG completed task in less time (P <0.003), committed fewer errors (P <0.01), and had fewer needle manipulations (P <0.05) than CGZendejas et al75 (2011)Surgery residentsIG (26); Guildford MATTU TEP hernia task trainerCG (24) no simulationTEP inguinal hernia repairIG faster on first procedure (P <0.001) and had higher participation rates (P <0.001). For subsequent repairs IG remained faster than CG. GOALS score higher for IG (P = 0.001). Complications and overnight stay less likely for first TEP procedure in IG (P <0.05).Palter et al76 (2012)PGY 2–4 surgery residentsIG (9); curriculum including simulation training on LapSim VR simulatorCG (9) no simulationRight hemicolectomyIG had higher OSATS score (P = 0.030) than CG.IG able to perform more operative steps than CG (P = 0.021)Palter et al77 (2013)PGY 1–2 surgery residentsIG (9); curriculum including simulation training on LapSim VR simulator and on FLS box trainerCG (9) no simulationCholecystectomyIG had higher OSATS scores for first four procedures (P = 0.004, P = 0.036, P = 0.021, P = 0.023)PGY = postgraduate year; IG = intervention group; CG = control group; VR = virtual reality; OSATS = Objective Structured Assessment of Technical Skills; GOALS = Global Operative Assessment of Laparoscopic Skills; OSA-LS = Objective Structured Assessment of Laparoscopic Salpingectomy; TEP = totally extraperitoneal.Simulators: LapSim VR simulator (Surgical Science, Gothenburg, Sweden); laparoscopic stimulator and Minimal Access Therapy Unit (MATTU) (Limbs and Things, Bristol, UK); Fundamentals of Laparoscopic Surgery (FLS) Training Box simulator (SAGES, Los Angeles, California, USA); Minimally Invasive Surgical Trainer—Virtual Reality (MIST-VR; Mentice, Gothenburg, Sweden).Modified with permission from Dawe SR, Pena GN, Windsor JA, et al. Systematic review of skills transfer after surgical simulation-based training, Br J Surg. 2014 Aug;101(9):1063-1076.Brunicardi_Ch53_p2163-p2186.indd 217022/02/19 4:39 PM 2171SKILLS AND SIMULATIONCHAPTER 53ABFigure 53-4. The surgical interface for MIST VR (A), consisting of rightand left-handed laparoscopic instruments on a gimbaled mount that transduces instrument motions into digital spatial data, which determine the location and actions of instruments in the virtual space (shown in B) in the course of manipulating two-handed virtual objects. Although basic renderings of geometric shapes, these virtual objects could be grasped, positioned, and treated with electrosurgery instruments, and they were shown to be an effective means to transfer skills to clinical surgery despite a relatively low level of fidelity to human tissues and absence of haptic feedback in the instrument interface.Table 53-4Studies comparing laparoscopic operative performance after training on virtual reality simulators vs. videoscopic box trainersAUTHOR (YEAR)STUDY ARMS (N)SUBJECTSPROFICIENCY-BASED TRAINING?CONCLUSIONSHamilton et al92 (2002)VR (24)Box trainer (25)Firstand second-year surgical residentsNoImproved rater-blinded global assessments of laparoscopic cholecystectomy for VR but not box-trainer trained subjectsYoungblood et al93 (2005)VR (16)Box trainer (17)No training (13)Medical studentsNoVR-trained students performed better than box trainer-trained on selected tasks in live porcine model. Both trained groups outperformed nontrained.Diesen et al94 (2011)VR (10)Box trainer (8)InternsMedical studentsNoNo difference in interval blinded video assessments of animal OR task performanceVR = virtual reality; OR = operating room.performance goals for precision, efficiency, and error avoidance were achieved. Performance measurement was automated and included time, instrument motion, and electrosurgery use metrics, as well as a tally of the occurrence of predefined errors. All metrics were free of human observer bias. Early studies of VR training using both proficiency-based and non–proficiency-based training methods showed it to be an effective means of improving laparoscopic skill both in the lab and in the operating room compared to non-VR trained controls.68,84-87 Since the first studies of this type were performed almost 20 years ago, several comprehensive reviews of the growing body of literature on VR have continued to support the conclusion that skills acquired in VR transfer to the clinical setting (Table 53-3), not only for laparoscopy, but also for flexible endoscopy, sinuscopic surgery, and endovascular interventions.66,67,88-91 Largely due to small study sizes and some 4design limitations, the quality of evidence of these studies is consistently described as below level I.Based on available evidence, expanded use of VR for skills training could be justified, but few comparisons of training effectiveness have been made between physical laparoscopic video trainer (“box” trainer) and laparoscopic VR simulator-based training. Crossover studies designed to determine if training in one environment improves performance in the other have not been especially helpful in defining the value of either. Only a few studies have compared the effects of the two training methods on OR performance (Table 53-4). Although some advantage has been suggested, the prevailing view is that both can be used for highly effective laparoscopic practice. Until better comparisons are made, use of proficiency-based training in the context of a larger curriculum appears to be the best way to achieve good training results irrespective of the training platform used.5Brunicardi_Ch53_p2163-p2186.indd 217122/02/19 4:39 PM 2172SPECIFIC CONSIDERATIONSPART IIVR simulator systems are significant capital investments for simulation centers that have competing procurement priori-ties. In a prospective randomized trial, Orzech analyzed the cost impact of each type of training across Canadian residency pro-grams and found that the transfer of training effect was greater for VR as compared to the box trainer group. However, box trainer use was found to be more cost effective except in larger residencies.95 Although the reasons for the latter finding require further analysis, the high acquisition costs of VR systems can be offset by an economy of scale benefit not realized with physical models where staffing for purposes of task setup and assess-ment and consumable items related to many tasks represent additive costs. Flexible endoscopy VR simulator device sharing was shown to work effectively for a skills acquisition program across a network of Texas institutions where procurement of numerous such simulators might not be practical.96The role of haptics has been debated for laparoscopic VR simulators since the inclusion of sophisticated force feedback hardware adds substantially to the cost of surgical VR as well as to system computing demands. In simulated endoscopic and laparoscopic procedures, effective haptic cues are important contributors to the fidelity of the experience. For basic skills acquisition these features have not been shown to offer significant advantages over nonhaptic VR systems, although for more advanced skills haptic cues may permit greater precision of instrument use.97,98 However, surgical VR has advanced to the point where inventories of procedure types offered on specific commercially available systems are quite extensive and these will inevitably increase and encompass entire procedures. The realism of the user experience, including the haptic experience, may prove essential to effective learning of advanced surgical skills in a new generation of VR devices. The current generation of laparoscopic simulators are highly capable devices with a high degree of graphical realism, full haptic features, and numerous tasks available for training basic and procedural skills for general surgical, urologic, and gynecologic procedures (Fig. 53-5).Despite encouraging progress made in VR simulation, two separate publications in 2007 and 2015 identified ongoing com-putational challenges in development of very high-fidelity simu-lations for surgery.99,100 These include the unique VR problems of modeling human tissues and the added demands of rendering the appropriate deformations when tissues are manipulated. One of the practical examples of this is that of guidewire behavior during VR as compared to real-life endovascular procedures, where variable elasticity characteristics of blood vessel walls were observed to result in real tissue or wire deformations that the VR software could not depict accurately.101 Also identified were disparities between levels of resourcing for surgical VR versus mainstream computer gaming, raising important ques-tions on how the full power of this technology can be realized to more fully simulate complex operations with a high degree of fidelity and realism.Virtual Reality for Flexible EndoscopyThe use of virtual reality simulation to train for flexible endos-copy procedures is now well established and supported by consistent evidence of both skills transfer. Sedlack compared colonoscopy skills between small groups of inexperienced VR-trained and nontrained gastroenterology fellows and found that VR training resulted in farther progression into the colon, better inspection skills, and a higher percentage of completed studies (those that reached the cecum).102 This performance advantage extended out to 30 posttraining procedures. In the years since that report, four randomized controlled trials of VR training with blinding to training status during posttraining clinical colonos-copy have been conducted.103-106 Despite methodological issues with each of these trials (no proficiency-based training, unsuper-vised VR practice on one, vaguely defined training characteris-tics of control groups), all but one showed training benefits for Figure 53-5. Three different current generation laparoscopic virtual reality simulators. A. LapVR VR Simulator, CAE Healthcare, Sarasota, FL. B. Simbionix LAP Mentor VR simulator, Littleton, CO. C. LapSim VR simulator, Surgical Science AB, Gothenburg, Sweden.ABCBrunicardi_Ch53_p2163-p2186.indd 217222/02/19 4:39 PM 2173SKILLS AND SIMULATIONCHAPTER 53ABFigure 53-6. Representation of patient-specific aortic vascular anatomy during simulation of endovascular aortic replacement (EVAR) for abdominal aortic aneurysm, with distal graft limbs in the ballerina (A. crossed) and standard (B. uncrossed) configurations. This example of patient-specific rehearsal requires preparation the virtual aorta from a DICOM (Digital Imaging and Communications in Medicine) format file of patient computed tomography (CT) or CT angiogram imaging data. Image is rendered on ANGIO Mentor VR simulator (3D Systems, Littleton, CO). (Reproduced with permission from Pakeliani D, Van Herzeele I, Lachat ML, et al: EVAR 2020: Training Future Aortic Spe-cialists. Emerging needs and the role of simulation. Endovascular Today 2017 March;16(3):95-100.)previously inexperienced VR-trained residents versus controls, especially in the earlier posttraining clinical cases based on either subjective determination of competency or measurement of procedure length. The study that did not show improved clini-cal performance compared to controls was a noninferiority com-parison to control subjects with undefined patient-based training where the two groups performed comparably well. Randomized trials of VR training for upper endoscopy have shown signifi-cant performance advantages in both procedure length and sub-jective assessment of competency compared to both nontrained and patient-based training control groups.107-109Based on the highly standardized test environment that can be experienced in VR and concurrent validity to clinical endos-copy, the SAGES FES program utilizes VR flexible endoscopy simulation for certification of skills. Systematic review of pub-lished literature on VR flexible endoscopy skills cite the need for better quality evidence in support of best training practices and improved patient outcomes.110 Further study is required, especially in the area of proficiency-based VR flexible endos-copy training, which has been generally underutilized.Virtual Reality for Endovascular InterventionsVirtual reality simulation has been shown to be an effective alternative to training with animal or cadaver models for catheter-based vascular interventions. Current simulations allow development of basic guidewire and catheter handling skills, as well as practice in use of fluoroscopy, angioplasty, and stenting techniques. Procedural training for coronary, carotid, renal, neuro, peripheral vascular, and other interven-tions are feasible with measurement of learner performance in numerous areas such as procedure and fluoroscopy time, con-trast use, and intervention effectiveness. Simulators display fluoroscopy images and allow for the selection and insertion of virtual catheter, balloon, and stent types, which are pertinent to the procedure being performed (Fig. 53-6). In small randomized trials, VR training has been shown to increase residents’ periph-eral angioplasty skills with transfer of lab-acquired skills to the clinical OR.111,112 After having previously shown that VR simu-lator assessment can effectively discriminate the level of clini-cal experience with carotid artery stenting among experienced interventionalists, Van Herzeele demonstrated that experienced interventionalists could also significantly increase carotid artery stenting skills following a 2-day intensive course of didactic and VR training for this procedure.113,114 Following training, decreased procedure and fluoroscopy time and decreased time for placement and retrieval of the embolic protection device were observed. Although differing clinical outcomes were not seen in this small study, it was noted that internal carotid artery spasm frequency decreased after training.The incorporation of actual patient vascular anatomic information taken from computerized tomography data into a vascular interventional simulation as an aid to procedural plan-ning or technical procedure performance has been referred to as “mission rehearsal” or more commonly now, procedure specific rehearsal or procedure specific simulation. It has been described most extensively for carotid artery stenting procedures and high-lights how VR simulation can be directed toward the immedi-ate problems of clinical practice. Cates’ brief report of a single procedure was followed by small studies further demonstrat-ing the feasibility and general impressions of the value of this method.115-117 In a randomized comparison of trainees who per-formed either part-task rehearsal or rehearsal of the entire proce-dure, Willaert reported that a similar performance benefit could be achieved, suggesting a potentially more time-efficient way to train, although the embolic protection device was in place slightly longer in the part-task-trained group.118Brunicardi_Ch53_p2163-p2186.indd 217322/02/19 4:39 PM 2174SPECIFIC CONSIDERATIONSPART IIIn a recent multinational European study, Desender and colleagues randomized a series of 100 patients scheduled to undergo elective endovascular aneurysm repair (EVAR) for infrarenal aortic aneurysm to either have their procedure rehearsed with VR simulation preoperatively or to have the pro-cedure performed without rehearsal.119 There were 26% fewer minor errors, 76% fewer major errors, and a 27% fewer errors causing procedural delay in the VR rehearsal group. In addition, this group had significantly fewer angiograms performed to visualize proximal and distal graft landing zones. In a follow-up of this study, Desender reported that patient-specific rehearsal before EVAR resulted in alteration of the operative plan for proximal landing zone (54%), distal landing zone (76%), stent graft main body size (16%), contralateral limb size (34%) or orientation (16%), and iliac extension size (28%). Ninety-two percent of these changes were implemented during the actual EVAR case.119Patient-Specific VR Surgery SimulationIn addition to patient specific rehearsal for endovascular inter-ventions, VR simulations for OR surgical procedures have begun to use patient imaging data to rehearse procedures preop-eratively. While many surgeons consciously and subconsciously mentally rehearse procedures before entering the operating room, this process does not allow for fully explicit informa-tion sharing between team members. Moreover, even when the surgeon verbalizes a plan for other members of the OR team after the mental rehearsal, it is not uncommon to unintentionally exclude important details that team members may value. The use of anatomically accurate VR simulations, based on patient-specific anatomy, may allow for team-based rehearsals and reduce the risk of human error. In addition, VR-based rehearsals may also facilitate doctor-patient communication.120Patient-specific VR simulations have recently emerged for a variety of complex operations including pancreatectomies, hepatectomies, renal surgery, and hand surgery.120-123 For one of the renal surgery simulations, patient-specific computed tomog-raphy (CT) data was captured and used to create 3D imaging for incorporation into the simulation.122 The anatomical accuracy of various structures such as arteries, veins, ureters, and even tumors was reported to be high. Another group compared the appearance of individual vascular structures while performing several patient-specific virtual hepatectomies simultaneously with real-life hepatectomies and also noted a high degree of accuracy. In addition, similar to the way CT angiograms are used in the OR for surgical planning, this group was able to increase and decrease the transparency level of the patient spe-cific VR simulation and use it both as a real-time operative guide (minimal transparency mode) as well as an operative planning guide (high transparency–vessel only view). This enabled one system to be used seamlessly throughout the actual operation.123According to reports, the time needed to create patient-specific VR simulations is relatively short. On average, it took approximate 2.5 hours each for both the hepatectomy and pan-createctomy simulations.120 In addition, compared to the use of 3D printed simulations, patient-specific VR simulations are readily reusable and do not consume as many resources. While these recent advances are quite promising, patient-specific VR simulators are a new technology, and thus additional studies are required to more fully understand the pros and cons of introduc-ing this technology into the patient care arena. As there contin-ues to be major improvements in patient-specific 3D rendering, including organ and tissue deformation in reaction to surgical manipulation, this increases the possibility of even more sophis-ticated and accurate VR simulations that can be used for pre-operative planning and rehearsing for complicated procedures.Robotic Surgery SimulatorsAfter the da Vinci surgical system was first introduced in the United States in 1999, a number of simulation systems for teaching robotic surgery emerged. While there have been sev-eral versions of the da Vinci system deployed worldwide, the basic system components usually include dual hand controls, foot pedals, and a controllable 3D camera.124 Consistency in these system components allow for similar consistency in simu-lation design and delivery. Currently, there are four different simulators geared towards imparting some level of competency in using the da Vinci System: the SEP-Robot (SurgicalSim Educational Platform Robot; SimSurgery, Oslo, Norway); RoSS (Robotic Surgery Simulator-Simulated Surgical Systems, San Jose, CA); dV-Trainer (Mimic Simulation, Seattle, WA), and the da Vinci Skills Simulator (Intuitive Surgical, Santa Clara, CA).124,125 The SEP-Robot is a desktop-like system for training robotic skills in a VR graphical interface. The da Vinci Skills Simulator, also called the “backpack,” is a hardware system that loads VR simulations into the actual da Vinci console.126 The RoSS and dV-Trainer systems are stand-alone devices with surgical controls resembling those of the da Vinci system.124 These simulators largely focus on hand-eye coordination, tissue manipulation, suturing and knot tying.127 The major benefit of VR simulators for training da Vinci robotic skills is that they produce performance metrics including time, error measures, and motion analysis.124 These simulators are increasingly being used for training novice surgeons in robotic skills for a variety of surgical specialties.When assessing simulator validity, researchers have noted that the use of robotic surgery simulators does translate to the clinical environment and the learning curve for initial console training for surgeons is significantly decreased.124,126 Unfortunately, the available robotic surgery simulators still come with a high sticker price and varying agreement on the level of fidelity that is currently present in these technologies.124 These deficiencies are likely due to the early stage of the robotic surgery approach, and it is likely that cheaper and more sophis-ticated systems will be available in the near future.128Fundamentals of Robotic SurgeryThe Fundamentals of Robotic Surgery (FRS) is a robotic surgi-cal skills training and assessment program designed to provide a proficiency-based curriculum of basic technical skills to prepare surgeons for performing robotic surgery procedures across a wide range of specialties. The FRS program was developed over a 2-year period by subject matter experts from multiple surgi-cal societies, surgical educational societies, surgical boards, and other governing organizations through a series of four consensus conferences, which included over 80 international robotic sur-gery experts, behavioral psychologists, medical educators, stat-isticians, and psychometricians.129 The multidisciplinary team of experts agreed upon the critical skills and tasks to be included in a comprehensive basic curriculum, and a task deconstruction was performed to identify the tasks, subtasks, and errors that needed to be measured. A modified Delphi methodology was then used to create a matrix of specific robotic surgery tasks, common errors, desired outcomes, and quantitative metrics to 6Brunicardi_Ch53_p2163-p2186.indd 217422/02/19 4:39 PM 2175SKILLS AND SIMULATIONCHAPTER 53Table 53-5The four online modules for the fundamentals of robotic surgery curriculumModule 1Introduction to Surgical Robotic Systems, includes an overview of minimally invasive surgery, advantages of robotic assisted surgery, components of robotic systems, and system functionalityModule 2Didactic Instructions for Robotic Surgery Systems, provides an overview of robotic surgery systems, as well as detailed information regarding the pre-, intra-, and postoperative phasesModule 3Psychomotor Skills Curriculum, consists of background and general principles of the psychomotor tasks, an introduction to the physical model on which the tasks are performed, and general scoring guidelines for all the tasks, followed by detailed descriptions of each task, including the targeted primary and secondary skills and metricsModule 4Team Training and Communication Skills, includes background on the degradation of situation awareness and the TeamSTEPPS process followed by detailed content covering communication, situational awareness, mutual support, leadership, the preoperative phase, robotic docking, intraoperative phase, postoperative phase, and a review of five scenariossupport those outcomes. Finally, a second round classic Delphi anonymous rating was used to ensure concurrence, prioritize the task rankings, and eliminate low-scoring tasks.All trainees must first complete an online curriculum consisting of four modules. Each of the four online modules is followed by a short quiz, requiring a minimum of 70% cor-rect to proceed in the training (Table 53-5). The curriculum also includes a cumulative, cognitive test following completion of all modules.ABFigure 53-7. A. The simulated abdominal cavity for training in the Fundamentals of Robotic Surgery. B. The 18-cm removable dome model featuring well-defined areas for executing each of the seven psychomotor exercises outlined in Table 53-6. (Used with permission from the Institute for Surgical Excellence.)Following online course completion, trainees must com-plete seven psychomotor exercises using a surgical robot, a simulated abdomen, and an 18-cm, removable dome model (Fig. 53-7).The psychomotor exercises consist of the following tasks: docking/instrument insertion, ring tower transfer, knot tying, railroad track, 3rd arm cutting, puzzle piece dissection, and ves-sel energy dissection (Table 53-6).NONTECHNICAL SKILLSFor surgeons, the term “nontechnical skills” refers to the cog-nitive knowledge and teamwork-related abilities that must be integrated with psychomotor skills and abilities. There are no sharp demarcations between these areas of skill, but different simulation methods are suitable for training each, and all should be addressed.High-Fidelity Patient Simulation and Team SkillsRecognition of the role of human factors in the occurrence of preventable errors has spawned various efforts to train behav-iors conducive to high-performing teams. Crew resource man-agement (CRM) training utilizing simulation has been credited with increased safety in aviation.130,131 Lessons learned from CRM have been adapted to medical training with simulators focusing on medical team performance in complex clinical situ-ations. This development came about in the 1990s driven pri-marily by anesthesiologists responsible for establishing the first high-fidelity simulation environments.132,133 These were devel-oped for simulation of crisis-level events where management could be practiced under realistic but safe conditions.134-136 Such training could be scaled to involve a single learner to focus on clinical management up to an entire care team able to practice team processes. Development of a program for such training requires an understanding of the principles underlying team effectiveness and the specific characteristics of an expert team. In a 2012 discussion paper on team-based health care emerging from the Best Practices Innovation Collaborative of the Institute of Medicine (IOM) Roundtable on Value & Science-Driven Health Care, such principles were clearly laid out following a careful analysis of effective medical teams across the country (Table 53-7).137 This document provides an excellent review of characteristics and values that surgical teams can aspire to. The necessity to train these skills has been widely accepted as Brunicardi_Ch53_p2163-p2186.indd 217522/02/19 4:39 PM 2176SPECIFIC CONSIDERATIONSPART IITable 53-6The seven psychomotor dome tasks for the fundamentals of robotic surgery curriculumTask 1: Docking/Instrument InsertionThe first psychomotor exercise provides training and assessment of proper docking and instrument insertion using the simulated abdomen.Task 2: Ring Tower TransferThe trainee removes a ring from the right middle tower and places it on the lower left tower. Primary skills assessed include hand, eye, and instrument coordination, camera navigation, and use of the camera pedal.Task 3: Knot TyingThe trainee ties a surgeon’s knot to approximate two eyelets such that they touch each other. Primary skills assessed include appropriate handling of suture material and tying secure knots.Task 4: Railroad TrackThe trainee must perform horizontal mattress suturing through a series of target points to approximate the tissue. Primary skills assessed include holding and manipulation of the needle, following the curve of the needle, utilizing the full range of motion of the endowrist, and using graspers.Task 5: 3rd Arm CuttingThe trainee must switch control between different instruments to use the monopolar scissors to cut a simulated vein. Primary skills assessed include switching between and controlling multiple robot arms and cutting.Task 6: Puzzle Piece DissectionIn this task, the trainee must cut and remove a puzzle shape without incising the underlying tissue or cutting outside of the lines. Primary skills assessed include dissection, cutting, atraumatic tissue handling, sharp dissection, and blunt dissection.Task 7: Vessel Energy DissectionThe trainee must dissect through a fat layer to expose a vessel then coagulate the vessel at two points and finally cut the vessel between the two coagulated points. Primary skills assessed include accurate activation and use of energy sources, dissection of vessels and tissues, cutting and coagulation of vessels, and multiple arm control.Table 53-7Principles of team-based health care• Shared goals: The team—including the patient and, where appropriate, family members or other support persons—works to establish shared goals that reflect patient and family priorities, and can be clearly articulated, understood, and supported by all team members.• Clear roles: There are clear expectations for each team member’s functions, responsibilities, and accountabilities, which optimize the team’s efficiency and often make it possible for the team to take advantage of division of labor, thereby accomplishing more than the sum of its parts.• Mutual trust: Team members earn each other’s trust, creating strong norms of reciprocity and greater opportunities for shared achievement.• Effective communication: The team prioritizes and continuously refines its communication skills. It has consistent channels for candid and complete communication, which are accessed and used by all team members across all settings.• Measurable processes and outcomes: The team agrees on and implements reliable and timely feedback on successes and failures in both the functioning of the team and achievement of the team’s goals. These are used to track and improve performance immediately and over time.Reproduced with permission from Mitchell P, Wynia M, Golden R, et al. Core Principles & Values of Effective Team-Based Health Care. Discussion Paper. Institute of Medicine, October 2012.a means of increasing the safety of healthcare. There are meth-ods to accomplish medical team training that do not involve simulation, but high-fidelity patient simulation has proven to be highly effective in increasing health care team competency, and systematic reviews have given evidence based endorsement of this approach.138Simulation training for communication and other teamwork-pertinent nontechnical skills requires learners to be embed-ded in realistic scenarios pertinent to a healthcare team’s 7actual clinical responsibilities where activities and interactions prompted by the simulated clinical circumstances can be prac-ticed and observed. The computer-driven high-fidelity manikin simulator serving as the “patient” at the center of these activities can be monitored and controlled to demonstrate realistic physi-ology consistent with the clinical condition needed for the scenario.139 Software-driven, physiologic changes from the baseline state can occur in response to either manual commands or programmed adjustments to accurately depict, for example, new, ongoing and unexpected clinical developments with blood loss, sepsis, or myocardial ischemia. Basic interventions such as airway management, drug administration and wound care for moulaged body parts can also be performed. Hybrid simulations using both manikin and open abdominal or laparoscopic surgi-cal simulators have also been used to extend scenarios to an operating room setting, with all members of the surgical team engaged in their role-specific tasks.136,140,141 These events can be conducted in a dedicated simulation suite or in an actual clinical area where it would be termed in situ simulation.The postsimulation debriefing is an essential compo-nent of simulation-based team training. This is where learning points are reinforced and progress towards desired knowledge, attitudes, and behavior can be developed.142,143 Participants are prompted to reflect on the events of the simulation and to openly discuss positive and negative aspects of the experience. The debriefing environment and discussion ought to be open, nonjudgmental, and directed at improvement in individual and overall team performance. A facilitator with strong content knowledge should ensure that the discussion includes identifica-tion of gaps between the observed and desired performance. An Brunicardi_Ch53_p2163-p2186.indd 217622/02/19 4:39 PM 2177SKILLS AND SIMULATIONCHAPTER 53effective facilitator is cognizant of the need to keep the debrief-ing learner-centric and to keep discussion focused on oppor-tunities for improvement. Although debriefing is uniformly viewed as essential to health care team simulation effectiveness and structured debriefing models are frequently cited as highly effective, there is no consensus on which specific methods, including video review debriefings, represent best practices.144 Quality of implementation is consistently cited as the most important contributing factor to effectiveness of debriefing.The complexity of team-managed clinical events makes measurement of team performance challenging, but several assessment tools have been developed and used successfully in simulation settings. NOTECHS (Non-Technical Skills) and the NOTSS (Non-Technical Skills for Surgeons) instruments have been used to study nontechnical abilities of individuals in surgi-cal teams.141,145-147 The principal focus of these rating scales is on the quality and effectiveness of situational awareness and com-munication. Instruments such as the Mayo High Performance Teamwork scale or the surgery-specific OTAS (Observational Team Assessment Scale) place focus on the team dynamics that extend beyond the single team member.148,149 These have been used to detect changes in team performance with training. Rosen suggested a framework for a best practices approach to team performance assessment in simulation that details specific appli-cations of measurement techniques in the simulation training environment.150Simulation training directed at nontechnical skills has been shown to improve clinical performance and improve knowledge and attitudes about team functioning as measured in simulated surgical settings such as the trauma bay and the OR for interdis-ciplinary surgical teams and for surgical trainees.136,151-154 Two systematic reviews of simulation training to increase team skills in the operating room consistently bear out this result, but both also cited the small number of studies where simulation training effects were investigated in the clinical OR setting and lack of evidence of improved clinical outcomes with such training.155,156ERROR PREVENTIONError avoidance and prevention are the overarching goals of sur-gical care and the time-honored focus of surgical training.157 Fac-ulty who are responsible for training the next generation of highly qualified surgeons must facilitate the delicate balance between resident autonomy and patient safety. From a training perspective, gradual increases in patient responsibility, autonomous decision-making, and operative action provide a critical opportunity for independent hands-on performance, critical thinking, and action-based skill assessment. However, resident autonomy must be bal-anced with the goal of delivering high-quality, error-free patient care. A key component to achieving residency training goals includes exposure to techniques and strategies for avoiding errors. The relationship between errors and patient safety is well estab-lished in the literature and is also the cornerstone of the case review process for surgical morbidity and mortality conferences.158 Simulation technology allows trainees the opportunity to execute a variety of tasks and procedures while also experiencing the cognitive demands of surgery, including error correction and surgical planning decisions. Fig. 53-8 presents a framework for categorizing surgical errors that may take place on the cognitive-motor continuum.159Simulation-based curricular approaches to exposing and training surgical errors include (a) the use of error-enabled 8CognitiveError preventionWhat will prevent an error?Knows the anatomy: right technique; natural hx of disease; how to avoid an errorSelect the right operation; the right stitch; the right instrumentWhat should you be concerned about?Cognitive-motorError recognitionEstimate errorrisk for: technicalapproach andpatient selectionWhich of thesemay result in anerror?Error rescueWhat areyour optionsfor errorrescue?Describewhat youwould do ifError preventionPre-error makesadjustments totechnical approachbased on errorpreventionError recognitionNear miss recognitionfollowed by correctiveactionError rescuePost-error knows andexecutes options forerror correctionIdentify propertechnique;potential error:error riskKnows -surgicaloptionsExample: Plansahead of time toadjust tensionduring knot tyingbased on tissuetypeExample: Recognizesthat the first knot wasa little tight then makesan adjustment to getthe second knot justrightExample: First knotpulled throughRescue: Freshenstissue edge, placesa new stitchError loopFigure 53-8. A framework for understanding error prevention, error recognition, and error rescue/correction during both the cognitive phase as well as the cognitive-motor phase where there is fluid integration and updating of motor and cognitive decisions. This fluid integration allows for an error loop, as each decision is based on the results of each motor action in a dynamic fashion where an error can take place with each decision or action. (Reproduced with permission from Pugh CM, Santacaterina S, DaRosa DA, et al: Intra-operative decision making: more than meets the eye, J Biomed Inform. 2011 Jun;44(3):486-496.)Brunicardi_Ch53_p2163-p2186.indd 217722/02/19 4:39 PM 2178SPECIFIC CONSIDERATIONSPART IIsimulations, where the learner can make any of a variety of errors during the course of the task; and (b) the use of forced-error simulations, where the learner experiences a specific, usually unexpected error and demonstrates error management as well as options for correction. Error management is a human factors process that includes making, detecting, and correcting errors.160,161 Several studies show that there is wide variation in the timing and type of operative decisions that residents make when interacting with an error-enabled simulation.112,162-164 Specific error training simulations have been developed using a cognitive task analysis approach to guide the design of error scenarios. Cognitive task analysis involves the use of structured interviews to explore how experts approach the error management process, including intraoperative decision-making and technical approaches.165,166 The error-enabled approach allows for a broad assessment of learning needs. The forced-error approach allows instructors to engage in specific error management skills and metrics. Error-enabled and forced-error surgical simulation trainers have been used in a variety of research and training modules to allow observation and assessment of surgical residents as they independently perform operative procedures and practice the error management process.112,166,167Another approach to error training and assessment is the use of assessments that focus on errors. Current assessment tools for surgical skills include task-specific and global rating scales, final product analysis, and documentation of critical fail-ures.160,168 These existing tools for assessing surgical residents largely focus on manual techniques and procedure time and do not capture the cause of resident performance failures.169 Use of error-related theories in human factors allows for the devel-opment of error-centric skills assessments.161,170,171 One study used previously developed human error classifications, includ-ing omission versus commission and cognitive versus technical as a means of assessing surgical residents.162 Omission errors were defined as failure to perform a step entirely. Commis-sion errors represented failure to perform a step correctly. For example, failure to measure the hernia defect was categorized as an omission error, whereas measuring the hernia defect with an inaccurate method was categorized as a commission error. Errors in information, diagnosis, and strategy were categorized as cognitive, and errors in action, procedure, or mechanics were classified as technical. Use of assessment surveys with this type of differentiation allows for development of error metrics in sur-gery and focused error training and feedback.172SIMULATION AND PATIENT OUTCOMESSurgical simulation training is intended to make patient care safe and free of avoidable errors and to maximize opportunities for good clinical outcomes. The Kirkpatrick four-level scale (Table 53-8) characterizes educational intervention effects, including those that might improve surgeon performance in clinical settings (Kirkpatrick level 3) or those that might actually improve patient outcomes (Kirkpatrick level 4).173 Despite the expanding use of simulation in proficiency-based practice models over at least 15 years, there are surprisingly few studies of simulation-based surgical training that can be described as Kirkpatrick level 4. On the other hand, there are numerous studies showing that clinician performance during the course of clinical care is improved after simulation training (Kirkpatrick level 3). As detection of changes in clinical Table 53-8Kirkpatrick level scale of educational outcomesKIRKPATRICK LEVELLEVEL DESCRIPTIONDESCRIPTION FOR SIMULATIONLevel 1ReactionDid the learner perceive value in using a simulator or participating in simulation training?Level 2LearningDid the learner’s knowledge, skill, or attitude improve as a result of the simulation training?Level 3Behavioral changeDid the knowledge, skills, and attitudes acquired during simulation transfer to the clinical environment?Level 4Institutional impactDid the simulation training program lead to improved patient outcomes?Data from Cox T, Seymour N, Stefanidis D: Moving the Needle: Simulation’s Impact on Patient Outcomes, Surg Clin North Am. 2015 Aug;95(4):827-838.outcomes can be quite challenging, it may be difficult to isolate simulation training effects from numerous other factors that can also affect patient outcomes. When looking specifically at a low-frequency complication event such as bile duct injury with laparoscopic cholecystectomy, the detection of a small, positive training effect is statistically improbable. However, the use of available Kirkpatrick level 3 data to support assumptions about training benefits is fully supportable given the preponderance of literature showing such benefit.The best current evidence for improved patient outcomes with simulation is that of technical and cognitive training for central venous catheter (CVC) insertion. In 2009, Barsuk et al monitored catheter-related bloodstream infection incidence in an ICU setting over a 32-month period before and after institu-tion of proficiency-based simulation training. After simulation-trained medical residents began performing CVC insertion, an 85% reduction in these infections was observed (3.2 per 1000 catheter-days reduced to 0.50 infections per 1000 catheter-days).174 Subsequently, the same group reported that the finan-cial savings realized with these improved outcomes amounted to a 7:1 return of the investment for the training.175 In a similar sin-gle unit observational study, Burden et al reported a reduction in catheter-related bloodstream infection incidence from 6.47 per 1000 catheter days to 2.44 per 1000 catheter days after training intervention and comparable financial savings with shorter ICU and hospital stays.176 Single cohort studies have inherent weak-nesses, but a somewhat smaller randomized trial of simulation training versus traditional apprenticeship model-trained controls also showed this reduced infection incidence (1.0 vs. 3.4 infec-tions per 1000 catheter-days, respectively).177Riley and colleagues conducted a study in three small community hospitals, administering TeamSTEPPS (Team Strategies and Tools to Enhance Performance and Patient Safety) didactic team training to perinatal care teams at one hospital, TeamSTEPPS with an accompanying program of in situ simula-tions at a second, and no intervention at the third hospital, which Brunicardi_Ch53_p2163-p2186.indd 217822/02/19 4:39 PM 2179SKILLS AND SIMULATIONCHAPTER 53served as the study control.178,179 The simulation interventions were designed to involve triage, labor and delivery, and OR components of care. Perinatal outcomes were assessed using the Weighted Adverse Outcomes Score (WAOS). Simulation train-ing resulted in improved clinical results with a 37.4% decrease in WAOS observed in the simulation intervention group, while similar benefit was not observed in either the didactic-trained or control groups.TeamSTEPPS with supplemental simulation training was also studied by Capella and colleagues for team performance and patient outcomes in trauma care.180 Trauma resuscitations for successive 2-month periods separated by didactic and scenario-based simulation training to subjectively-defined proficiency levels (33 before training, 40 after training) were assessed in multiple teamwork domains including overall performance using the TPOT (Trauma Team Performance Observation Tool). Significant improvements were observed post training in leader-ship, situational monitoring, mutual support, communication, and overall scoring. In addition, time to OR was also observed to decrease. Steinemann and colleagues reported on a larger number of trauma resuscitations, 141 before and 103 after in situ trauma bay patient simulation training with accompanying didactic instruction.181 Although significant improvements in patient outcomes were not observed in this study, resuscitation time did decrease following training.In a comprehensive review of literature examining simula-tion impact on patient outcomes, Zendejas identified 50 stud-ies purporting to show patient outcomes.182 For the majority of these, the quality of clinical outcomes evidence was considered low, and appropriate validity data were reported for results in only a small number of published reports. In a subsequent review of 1328 articles resulting from an exhaustive literature search, Cox identified 12 individual articles that reported suf-ficient patient outcomes data to be considered Kirkpatrick level 4.183 Concerns regarding the relatively few studies of this nature are primarily methodological and relate to the prepon-derance of use of the observational preand posttraining study model with its inherent bias risk, rather than randomized con-trolled trials. These studies have also tended to be quite limited in size. In surgery, the general areas of surgeon performance that have lent themselves to study of educational outcomes in the clinical setting after simulation training include technical abilities and observable behaviors during team-based activi-ties. The use of decreased operative time or technical errors as clinical outcomes after simulation training might suggest, but do not clearly establish, a patient safety or other efficacy benefit. However, these metrics have frequently been used to make the case for the potential for such benefits in skills transfer studies for procedures such as laparoscopic cholecystectomy and lapa-roscopic hernia repair.56,63 There is a clear need to obtain high quality evidence of how proficiency-based simulation training impacts surgical patient outcomes.In a recent study examining intern response to pediatric codes, simulation training was shown to significantly reduce the time to request help, to initiate bag-mask ventilation, and to ini-tiate chest compressions.184 Citing the rarity of pediatric codes, investigators measured this effect in in mock code situations using patient simulators. This use of a high-fidelity simulation environment as a surrogate for clinical events, that might oth-erwise be difficult to observe, may be the only practical model available for the study of provider performance outcomes with educational interventions.SIMULATION TRAINING FOR THE PRACTICING SURGEON AND MAINTENANCE OF SKILLGiven the current requirement for FLS and FES certification in residency, some authors have posed the important question of whether such certification should be applied more broadly to surgeons in practice.185 In a 2012 press release, both the ACS and SAGES made the recommendation that all surgeons per-forming laparoscopy obtain FLS certification. The potential to lower malpractice litigation risk under a self-insurance model was used as justification to certify 37 surgeons in FLS in the Harvard system in 2009.186 In a recent report, surgical oncolo-gists new to minimally invasive inguinal lymph node dissec-tion (MILND) were FLS tested prior to performance of their first clinical procedures, which were video-assessed using the GOALS scoring method.187 The FLS score was shown to corre-late with both GOALS results and operative time but not lymph node yield. However, evidence that a lab-based technical and cognitive skills test predicts observed operative technical skill in practicing surgeons is promising and warrants investigative follow-up.At the present time, the American Board of Surgery’s requirements for Maintenance of Certification (MOC) do not specifically include any certification of technical skills that might use surgical simulation.188 Nonetheless, simulation training and testing can be made available to surgeons in practice to provide an avenue for specific training. Although most investigations of VR use for laparoscopy have examined basic skills acquisition in the lab setting far in advance of any measured impact in the clinical OR, a recent innovative study of the use of a VR simulator for “warm-up” practice immediately before a procedure showed that this improved OR performance.189 As new surgical procedures and technologies are introduced to clinical practice, simulation training solutions could serve just as important a purpose to prepare for these as simulation training methods currently serve for laparoscopic surgery. In a recent publication relating to practicing surgeons, Sullivan et al. provide a framework for development of simulation-based certification models for both trainees and faculty surgeons.190FUTURE CONSIDERATIONSSimulation-based training and assessment is firmly established in surgical education, especially in graduate medical education where learners have been more extensively studied than any other simulation user group. The immediate future of simulation in surgery will likely see expanded use of proficiency-based training given the consistent demonstrations of effectiveness in improving surgeon skills and improved educa-tional outcomes as measured in clinical settings.The question of what types of simulation-based assess-ments and training activities might be possible raises questions of where technological advances might open new opportunities.191 The advancement of virtual reality is inevitable, and much richer virtual experiences entering the mainstream in surgical educa-tion seems likely in the near future. Three-dimensional printing technology has been growing in its use and applications and has greatly facilitated the development of anatomically accurate bench top simulations for complex surgical procedures. Some of the materials allow for elegant instrument-based dissections, including the use of electrosurgery.192-1949Brunicardi_Ch53_p2163-p2186.indd 217922/02/19 4:39 PM 2180SPECIFIC CONSIDERATIONSPART IIAdvances in wearables, motion tracking, and sensor tech-nologies allow for a wide variety of hybrid and aug-mented experiences in simulation as well as extensive opportunities for the development of new performance metrics. One study using sensor technology for evaluating clinical breast examination skills noted key performance differences in expe-rienced physicians. Both the sensor data and sensor-guided video analysis allowed for skill quantifications that were previ-ously unknown but critical to performance excellence.195-196Opportunities for remote collaboration are now greatly improved with higher internet speeds, improvements in aug-mented reality technology, and ever-increasing camera reso-lution. VIPAR (Virtual Interactive Presence and Augmented Reality) allows for the visual field of a surgeon to be converted to a simulation and projected in a remote location.197-198 As such, the system allows for intraoperative collaboration and telementoring.199Irrespective of what new simulation and engineering tech-nologies emerge, these technologies are here not just to stay but to grow as assessment and educational tools. This presents abundant opportunities for simulation leaders in surgery to improve the delivery of care by defining best practice in sim-ulation applications and keeping step with current and future changes in surgical practice.REFERENCESEntries highlighted in bright blue are key references. 1. Leape LL. Error in medicine. JAMA. 1994;272(23):1851-1857. 2. To err is human: building a safer health system. Washington, DC: National Academy Press, Institute of Medicine; 1999. 3. Satava RM. Historical review of surgical simulation—a personal perspective. World J Surg. 2008;32(2):141-148. 4. Martin JA, Regehr G, Reznick R, et al. Objective struc-tured assessment of technical skill (OSATS) for surgical residents. Br J Surg. 1997;84(2):273-278. 5. Reznick R, Regehr G, MacRae H, Martin J, McCulloch W. Testing technical skill via an innovative “bench station” examination. Am J Surg. 1997;173(3):226-230. 6. A prospective analysis of 1518 laparoscopic cholecystec-tomies. The Southern Surgeons Club. N Engl J Med. 1991; 324(16):1073-1078. 7. Rosser JC, Rosser LE, Savalgi RS. Skill acquisition and assessment for laparoscopic surgery. Arch Surg. 1997; 132(2):200-204. 8. Derossis AM, Bothwell J, Sigman HH, Fried GM. The effect of practice on performance in a laparoscopic simulator. Surg Endosc. 1998;12(9):1117-1120. 9. Gallagher AG, Ritter EM, Champion H, et al. Virtual reality simulation for the operating room: proficiency-based training as a paradigm shift in surgical skills training. Ann Surg. 2005;241(2):364-372. 10. Sachdeva AK. Establishment of American College of Surgeons-accredited Education Institutes: the dawn of a new era in surgical education and training. J Surg Educ. 2010;67(4):249-250. 11. Scott DJ, Dunnington GL. The new ACS/APDS Skills Curriculum: moving the learning curve out of the operating room. J Gastrointest Surg. 2008;12(2):213-221. 12. Korndorffer JR, Arora S, Sevdalis N, et al. The American College of Surgeons/Association of Program Directors in Surgery National Skills Curriculum: adoption rate, challenges and strategies for effective implementation into surgical residency programs. Surgery. 2013;154(1):13-20. 13. Bell RH. Surgical council on resident education: a new organization devoted to graduate surgical education. J Am Coll Surg. 2007;204(3):341-346. 14. Carraccio CL, Benson BJ, Nixon LJ, Derstine PL. From the educational bench to the clinical bedside: translating the Dreyfus developmental model to the learning of clinical skills. Acad Med. 2008;83(8):761-767. 15. Ericsson KA. Deliberate practice and acquisition of expert performance: a general overview. Acad Emerg Med. 2008;15(11):988-994. 16. Ericsson KA, Krampe RT, Tesch-Romer C. The role of deliberate practice in the acquisition of expert performance. Psychol Rev. 1993;100(3):363-406. 17. Bridges M, Diamond DL. The financial impact of teaching surgical residents in the operating room. Am J Surg. 1999;177(1):28-32. 18. Gould JC. Building a laparoscopic surgical skills training laboratory: resources and support. JSLS. 2006;10(3):293-296. 19. Britt LD, Richardson JD. Residency review committee for surgery: an update. Arch Surg. 2007;142(6):573-575. 20. ACGME Program Requirements for Graduate Medical Education in General Surgery. Revised Common Program Requirements effective: July 1, 2018. Available at: https://www.acgme.org/Portals/0/PFAssets/ProgramRequirements/440GeneralSurgery2018.pdf?ver=2017-10-03-110315-270. Accessed August 27, 2018. 21. American Board of Surgery. Flexible Endoscopy Curriculum for General Surgery Residents. 2014. Available at: https://www .absurgery.org/xfer/abs-fec.pdf. Accessed August 27, 2018. 22. Haluck RS, Satava RM, Fried G, et al. Establishing a simulation center for surgical skills: what to do and how to do it. Surg Endosc. 2007;21(7):1223-1232. 23. Friedell ML. Starting a simulation and skills laboratory: what do I need and what do I want? J Surg Educ. 2010;67(2):112-121. 24. Meier AH. Running a surgical education center: from small to large. Surg Clin North Am. 2010;90(3):491-504. 25. Brunt LM, Halpin VJ, Klingensmith ME, et al. Accelerated skills preparation and assessment for senior medical students entering surgical internship. J Am Coll Surg. 2008;206(5): 897-904; discussion 904-897. 26. Fernandez GL, Page DW, Coe NP, et al. Boot cAMP: educational outcomes after 4 successive years of preparatory simulation-based training at onset of internship. J Surg Educ. 2012;69(2):242-248. 27. Krajewski A, Filippa D, Staff I, Singh R, Kirton OC. Implementation of an intern boot camp curriculum to address clinical competencies under the new Accreditation Council for Graduate Medical Education supervision requirements and duty hour restrictions. JAMA Surg. 2013;148(8):727-732. 28. Cohen ER, Barsuk JH, Moazed F, et al. Making July safer: simulation-based mastery learning during intern boot camp. Acad Med. 2013;88(2):233-239. 29. Blackmore C, Austin J, Lopushinsky SR, Donnon T. Effects of postgraduate medical education “boot camps” on clinical skills, knowledge, and confidence: a meta-analysis. J Grad Med Educ. 2014;6(4):643-652. 30. American Board of Surgery; American College of Surgeons; Association of Program Directors in Surgery; Association for Surgical Education. Statement on surgical preresidency preparatory courses. Surgery. 2014;156(5):1059-1060. 31. Gomez PP, Willis RE, Schiffer BL, Gardner AK, Scott DJ. External validation and evaluation of an intermediate proficiency-based knot-tying and suturing curriculum. J Surg Educ. 2014;71(6):839-845. 32. Sanfey H, Ketchum J, Bartlett J, et al. Verification of proficiency in basic skills for postgraduate year 1 residents. Surgery. 2010;148(4):759-766; discussion 766-757.10Brunicardi_Ch53_p2163-p2186.indd 218022/02/19 4:39 PM 2181SKILLS AND SIMULATIONCHAPTER 53 33. Sanfey H, Dunnington G. Verification of proficiency: a prerequisite for clinical experience. Surg Clin North Am. 2010;90(3):559-567. 34. Satava RM, Gallagher AG. Next generation of procedural skills curriculum development: proficiency-based progression. J Health Spec. 2015;3:198-205. 35. Nemeth ZH, Lazar EL, Paglinco SR, et al. Experience of general surgery residents in the creation of small bowel and colon anastomoses. J Surg Educ. 2016;73(5):844-850. 36. Jensen AR, Wright AS, McIntyre LK, et al. Laboratory-based instruction for skin closure and bowel anastomosis for surgical residents. Arch Surg. 2008;143(9):852-858; discussion 858-859. 37. Olson TP, Becker YT, McDonald R, Gould J. A simulation-based curriculum can be used to teach open intestinal anastomosis. J Surg Res. 2012;172(1):53-58. 38. Egle JP, Malladi SV, Gopinath N, Mittal VK. Simulation training improves resident performance in hand-sewn vascular and bowel anastomoses. J Surg Educ. 2015;72(2):291-296. 39. Palter VN, Grantcharov T, Harvey A, Macrae HM. Ex vivo technical skills training transfers to the operating room and enhances cognitive learning: a randomized controlled trial. Ann Surg. 2011;253(5):886-889. 40. Melvin WS, Johnson JA, Ellison EC. Laparoscopic skills enhancement. Am J Surg. 1996;172(4):377-379. 41. Rosser JC, Rosser LE, Savalgi RS. Objective evaluation of a laparoscopic surgical skill program for residents and senior surgeons. Arch Surg. 1998;133(6):657-661. 42. Derossis AM, Fried GM, Abrahamowicz M, et al. Development of a model for training and evaluation of laparoscopic skills. Am J Surg. 1998;175(6):482-487. 43. Fried GM, Derossis AM, Bothwell J, Sigman HH. Comparison of laparoscopic performance in vivo with performance measured in a laparoscopic simulator. Surg Endosc. 1999;13(11):1077-1081; discussion 1082. 44. Stefanidis D, Hope WW, Korndorffer JR, Markley S, Scott DJ. Initial laparoscopic basic skills training shortens the learning curve of laparoscopic suturing and is cost-effective. J Am Coll Surg. 2010;210(4):436-440. 45. Peters JH, Fried GM, Swanstrom LL, et al. Development and validation of a comprehensive program of education and assessment of the basic fundamentals of laparoscopic surgery. Surgery. 2004;135(1):21-27. 46. Fraser SA, Klassen DR, Feldman LS, et al. Evaluating laparoscopic skills: setting the pass/fail score for the MISTELS system. Surg Endosc. 2003;17(6):964-967. 47. Fried GM, Feldman LS, Vassiliou MC, et al. Proving the value of simulation in laparoscopic surgery. Ann Surg. 2004;240(3):518-525; discussion 525-518. 48. Sroka G, Feldman LS, Vassiliou MC, et al. Fundamentals of laparoscopic surgery simulator training to proficiency improves laparoscopic performance in the operating room—a randomized controlled trial. Am J Surg. 2010;199(1):115-120. 49. Scott DJ, Ritter EM, Tesfay ST, et al. Certification pass rate of 100% for fundamentals of laparoscopic surgery skills after proficiency-based training. Surg Endosc. 2008;22(8):1887-1893. 50. Vassiliou MC, Dunkin BJ, Fried GM, et al. Fundamentals of endoscopic surgery: creation and validation of the hands-on test. Surg Endosc. 2014;28(3):704-711. 51. Pugh C, Plachta S, Auyang E, Pryor A, Hungness E. Outcome measures for surgical simulators: is the focus on technical skills the best approach? Surgery. 2010;147(5):646-654. 52. Lin E, Szomstein S, Addasi T, et al. Model for teaching laparoscopic colectomy to surgical residents. Am J Surg. 2003;186(1):45-48. 53. Ghazi A, Stone J, Candela B, Richards M, Joseph J. Simulated inanimate model for physical learning experience (simple) for robotic partical nephrectomy using a 3-D printed kidney model. J Urol. 2015;193(4S):e778. 54. Kim M, Ni T, Cendan J, Kurenov S, Peters J. A haptic-enabled toolkit for illustration of procedures in surgery (TIPS). Stud Health Technol Inform. 2007;125:209-213. 55. Khan IS, Kelly PD, Singer RJ. Prototyping of cerebral vasculature physical models. Surg Neurol Int. 2014;5:11. 56. Olivieri LJ, Su L, Hynes CF, et al. “Just-in-time” simulation training using 3-D printed cardiac models after congenital cardiac surgery. World J Pediatr Congenit Heart Surg. 2016;7(2):164-168. 57. Anderson JR, Thompson WL, Alkattan AK, et al. Three-dimensional printing of anatomically accurate, patient specific intracranial aneurysm models. J Neurointerv Surg. 2016;8(5):517-520. 58. Cendan J, Kim M, Kurenov S, Peters J. Developing a multimedia environment for customized teaching of an adrenalectomy. Surg Endosc. 2007;21(6):1012-1016. 59. Nathwani JN, Law KE, Ray RD, et al. Resident performance in complex simulated urinary catheter scenarios. J Surg Res. 2016;205(1):121-126. 60. O’Connell-Long BR, Ray RD, Nathwani JN, Fiers RM, Pugh CM. Errors in bladder catheterization: are residents ready for complex scenarios? J Surg Res. 2016;206(1):27-31. 61. Issenberg SB, McGaghie WC, Petrusa ER, Lee Gordon D, Scalese RJ. Features and uses of high-fidelity medical sim-ulations that lead to effective learning: a BEME systematic review. Med Teach. 2005;27(1):10-28. 62. University of Texas Medical Branch at Galveston. Surgeons, athletic, musical pros join forces to devise new surgical training program. ScienceDaily.com. Available at: https://www.sciencedaily.com/releases/2015/09/150918081113.htm. Accessed August 27, 2018. 63. Vassiliou MC, Feldman LS, Andrew CG, et al. A global assessment tool for evaluation of intraoperative laparo-scopic skills. Am J Surg. 2005;190(1):107-113. 64. Sturm LP, Windsor JA, Cosman PH, et al. A systematic review of skills transfer after surgical simulation training. Ann Surg. 2008;248(2):166-179. 65. Palter VN, Grantcharov TP. Simulation in surgical education. CMAJ. 2010;182(11):1191-1196. 66. Zendejas B, Brydges R, Hamstra SJ, Cook DA. State of the evidence on simulation-based training for laparoscopic surgery: a systematic review. Ann Surg. 2013;257(4): 586-593. 67. Dawe SR, Pena GN, Windsor JA, et al. Systematic review of skills transfer after surgical simulation-based training. Br J Surg. 2014;101(9):1063-1076. 68. Ahlberg G, Enochsson L, Gallagher AG, et al. Proficiency-based virtual reality training significantly reduces the error rate for residents during their first 10 laparoscopic cholecystectomies. Am J Surg. 2007;193(6):797-804. 69. Banks EH, Chudnoff S, Karmin I, Wang C, Pardanani S. Does a surgical simulator improve resident operative performance of laparoscopic tubal ligation? Am J Obstet Gynecol. 2007;197(5):541.e541-545. 70. Cosman PH, Hugh TJ, Shearer CJ, et al. Skills acquired on virtual reality laparoscopic simulators transfer into the operating room in a blinded, randomised, controlled trial. Stud Health Technol Inform. 2007;125:76-81. 71. Gala R, Orejuela F, Gerten K, et al. Effect of validated skills simulation on operating room performance in obstetrics and gynecology residents: a randomized controlled trial. Obstet Gynecol. 2013;121(3):578-584. 72. Hogle NJ, Chang L, Strong VE, et al. Validation of laparoscopic surgical skills training outside the operating room: a long road. Surg Endosc. 2009;23(7):1476-1482. 73. Larsen CR, Soerensen JL, Grantcharov TP, et al. Effect of virtual reality training on laparoscopic surgery: randomised controlled trial. BMJ. 2009;338:b1802.Brunicardi_Ch53_p2163-p2186.indd 218122/02/19 4:39 PM 2182SPECIFIC CONSIDERATIONSPART II 74. Van Sickle KR, Ritter EM, Baghai M, et al. Prospective, randomized, double-blind trial of curriculum-based training for intracorporeal suturing and knot tying. J Am Coll Surg. 2008;207(4):560-568. 75. Zendejas B, Cook DA, Bingener J, et al. Simulation-based mastery learning improves patient outcomes in laparo-scopic inguinal hernia repair: a randomized controlled trial. Ann Surg. 2011;254(3):502-509; discussion 509-511. 76. Palter VN, Grantcharov TP. Development and validation of a comprehensive curriculum to teach an advanced minimally invasive procedure: a randomized controlled trial. Ann Surg. 2012;256(1):25-32. 77. Palter VN, Orzech N, Reznick RK, Grantcharov TP. Validation of a structured training and assessment curriculum for technical skill acquisition in minimally invasive surgery: a randomized controlled trial. Ann Surg. 2013;257(2):224-230. 78. Aggarwal R, Ward J, Balasundaram I, et al. Proving the effectiveness of virtual reality simulation for training in laparoscopic surgery. Ann Surg. 2007;246(5):771-779. 79. Korndorffer JR, Dunne JB, Sierra R, et al. Simulator training for laparoscopic suturing using performance goals translates to the operating room. J Am Coll Surg. 2005;201(1):23-29. 80. Stefanidis D, Scerbo MW, Montero PN, Acker CE, Smith WD. Simulator training to automaticity leads to improved skill transfer compared with traditional proficiency-based training: a randomized controlled trial. Ann Surg. 2012;255(1):30-37. 81. Stefanidis D, Korndorffer JR, Markley S, et al. Closing the gap in operative performance between novices and experts: does harder mean better for laparoscopic simulator training? J Am Coll Surg. 2007;205(2):307-313. 82. Satava RM. Virtual reality surgical simulator. The first steps. Surg Endosc. 1993;7(3):203-205. 83. Wilson MS, Middlebrook A, Sutton C, Stone R, McCloy RF. MIST VR: a virtual reality trainer for laparoscopic surgery assesses performance. Ann R Coll Surg Engl. 1997;79(6):403-404. 84. Seymour NE, Gallagher AG, Roman SA, et al. Virtual reality training improves operating room performance: results of a randomized, double-blinded study. Ann Surg. 2002;236(4):458-463; discussion 463-454. 85. Grantcharov TP, Kristiansen VB, Bendix J, et al. Randomized clinical trial of virtual reality simulation for laparoscopic skills training. Br J Surg. 2004;91(2):146-150. 86. Schijven MP, Jakimowicz JJ, Broeders IA, Tseng LN. The Eindhoven laparoscopic cholecystectomy training course—improving operating room performance using virtual reality training: results from the first E.A.E.S. accredited virtual reality trainings curriculum. Surg Endosc. 2005;19(9):1220-1226. 87. Aggarwal R, Tully A, Grantcharov T, et al. Virtual reality simulation training can improve technical skills during laparoscopic salpingectomy for ectopic pregnancy. BJOG. 2006;113(12):1382-1387. 88. Larsen CR, Oestergaard J, Ottesen BS, Soerensen JL. The efficacy of virtual reality simulation training in laparoscopy: a systematic review of randomized trials. Acta Obstet Gynecol Scand. 2012;91(9):1015-1028. 89. Nagendran M, Gurusamy KS, Aggarwal R, Loizidou M, Davidson BR. Virtual reality training for surgical trainees in laparoscopic surgery. Cochrane Database Syst Rev. 2013(8):CD006575. 90. Piromchai P, Avery A, Laopaiboon M, Kennedy G, O’Leary S. Virtual reality training for improving the skills needed for performing surgery of the ear, nose or throat. Cochrane Database Syst Rev. 2015(9):CD010198. 91. See KW, Chui KH, Chan WH, Wong KC, Chan YC. Evidence for endovascular simulation training: a systematic review. Eur J Vasc Endovasc Surg. 2016;51(3):441-451. 92. Hamilton EC, Scott DJ, Fleming JB, et al. Comparison of video trainer and virtual reality training systems on acquisition of laparoscopic skills. Surg Endosc. 2002;16(3):406-411. 93. Youngblood PL, Srivastava S, Curet M, et al. Comparison of training on two laparoscopic simulators and assessment of skills transfer to surgical performance. J Am Coll Surg. 2005;200(4):546-551. 94. Diesen DL, Erhunmwunsee L, Bennett KM, et al. Effectiveness of laparoscopic computer simulator versus usage of box trainer for endoscopic surgery training of novices. J Surg Educ. 2011;68(4):282-289. 95. Orzech N, Palter VN, Reznick RK, Aggarwal R, Grantcharov TP. A comparison of 2 ex vivo training curricula for advanced laparoscopic skills: a randomized controlled trial. Ann Surg. 2012;255(5):833-839. 96. Van Sickle KR, Buck L, Willis R, et al. A multicenter, simulation-based skills training collaborative using shared GI Mentor II systems: results from the Texas Association of Surgical Skills Laboratories (TASSL) flexible endoscopy curriculum. Surg Endosc. 2011;25(9):2980-2986. 97. Panait L, Akkary E, Bell RL, et al. The role of haptic feedback in laparoscopic simulation training. J Surg Res. 2009;156(2):312-316. 98. Thompson JR, Leonard AC, Doarn CR, Roesch MJ, Broderick TJ. Limited value of haptics in virtual reality laparoscopic cholecystectomy training. Surg Endosc. 2011;25(4):1107-1114. 99. Seymour NE, Røtnes JS. Challenges to the development of complex virtual reality surgical simulations. Surg Endosc. 2006;20(11):1774-1777. 100. Olasky J, Sankaranarayanan G, Seymour NE, et al. Identifying opportunities for virtual reality simulation in surgical education: a review of the proceedings from the Innovation, Design, and Emerging Alliances in Surgery (IDEAS) Conference: VR Surgery. Surg Innov. 2015;22(5):514-521. 101. Gindre J, Bel-Brunon A, Rochette M, et al. Patient-specific finite-element simulation of the insertion of guidewire during an EVAR procedure: guidewire position prediction validation on 28 cases. IEEE Trans Biomed Eng. 2017;64(5):1057-1066. 102. Sedlack RE, Kolars JC. Computer simulator training enhances the competency of gastroenterology fellows at colonoscopy: results of a pilot study. Am J Gastroenterol. 2004;99(1):33-37. 103. Ahlberg G, Hultcrantz R, Jaramillo E, Lindblom A, Arvidsson D. Virtual reality colonoscopy simulation: a compulsory practice for the future colonoscopist? Endoscopy. 2005;37(12):1198-1204. 104. Cohen J, Cohen SA, Vora KC, et al. Multicenter, randomized, controlled trial of virtual-reality simulator training in acquisition of competency in colonoscopy. Gastrointest Endosc. 2006;64(3):361-368. 105. Park J, MacRae H, Musselman LJ, et al. Randomized controlled trial of virtual reality simulator training: transfer to live patients. Am J Surg. 2007;194(2):205-211. 106. Haycock A, Koch AD, Familiari P, et al. Training and transfer of colonoscopy skills: a multinational, randomized, blinded, controlled trial of simulator versus bedside training. Gastrointest Endosc. 2010;71(2):298-307. 107. Ferlitsch A, Schoefl R, Puespoek A, et al. Effect of virtual endoscopy simulator training on performance of upper gastrointestinal endoscopy in patients: a randomized controlled trial. Endoscopy. 2010;42(12):1049-1056. 108. Ende A, Zopf Y, Konturek P, et al. Strategies for training in diagnostic upper endoscopy: a prospective, randomized trial. Gastrointest Endosc. 2012;75(2):254-260. 109. Shirai Y, Yoshida T, Shiraishi R, et al. Prospective randomized study on the use of a computer-based endoscopic simulator for training in esophagogastroduodenoscopy. J Gastroenterol Hepatol. 2008;23(7 pt 1):1046-1050.Brunicardi_Ch53_p2163-p2186.indd 218222/02/19 4:39 PM 2183SKILLS AND SIMULATIONCHAPTER 53 110. Walsh CM, Sherlock ME, Ling SC, Carnahan H. Virtual reality simulation training for health professions trainees in gastrointestinal endoscopy. Cochrane Database Syst Rev. 2012(6):CD008237. 111. Chaer RA, Derubertis BG, Lin SC, et al. Simulation improves resident performance in catheter-based intervention: results of a randomized, controlled study. Ann Surg. 2006;244(3):343-352. 112. Hseino H, Nugent E, Lee MJ, et al. Skills transfer after proficiency-based simulation training in superficial femoral artery angioplasty. Simul Healthc. 2012;7(5):274-281. 113. Van Herzeele I, Aggarwal R, Choong A, et al. Virtual reality simulation objectively differentiates level of carotid stent experience in experienced interventionalists. J Vasc Surg. 2007;46(5):855-863. 114. Van Herzeele I, Aggarwal R, Neequaye S, et al. Experienced endovascular interventionalists objectively improve their skills by attending carotid artery stent training courses. Eur J Vasc Endovasc Surg. 2008;35(5):541-550. 115. Cates CU, Patel AD, Nicholson WJ. Use of virtual reality simulation for mission rehearsal for carotid stenting. JAMA. 2007;297(3):265-266. 116. Hislop SJ, Hedrick JH, Singh MJ, et al. Simulation case rehearsals for carotid artery stenting. Eur J Vasc Endovasc Surg. 2009;38(6):750-754. 117. Willaert W, Aggarwal R, Bicknell C, et al. Patient-specific simulation in carotid artery stenting. J Vasc Surg. 2010; 52(6):1700-1705. 118. Willaert W, Aggarwal R, Harvey K, et al. Efficient implementation of patient-specific simulated rehearsal for the carotid artery stenting procedure: part-task rehearsal. Eur J Vasc Endovasc Surg. 2011;42(2):158-166. 119. Desender L, Van Herzeele I, Lachat M, et al. A multicentre trial of patient specific rehearsal prior to EVAR: impact on procedural planning and team performance. Eur J Vasc Endovasc Surg. 2017;53(3):354-361. 120. Endo K, Sata N, Ishiguro Y, et al. A patient-specific surgical simulator using preoperative imaging data: an interactive simulator using a three-dimensional tactile mouse. J Comp Surg. 2014;1(10). 121. Eschweiler J, Stromps JP, Fischer M, et al. Development of a biomechanical model of the wrist joint for patient-specific model guided surgical therapy planning: Part 1. Proc Inst Mech Eng H. 2016;230(4):310-325. 122. Makiyama K, Yamanaka H, Ueno D, et al. Validation of a patient-specific simulator for laparoscopic renal surgery. Int J Urol. 2015;22(6):572-576. 123. Oshiro Y, Yano H, Mitani J, et al. Novel 3-dimensional virtual hepatectomy simulation combined with real-time deformation. World J Gastroenterol. 2015;21(34):9982-9992. 124. Liu M, Curet M. A review of training research and virtual reality simulators for the da Vinci surgical system. Teach Learn Med. 2015;27(1):12-26. 125. Bric J, Connolly M, Kastenmeier A, Goldblatt M, Gould JC. Proficiency training on a virtual reality robotic surgical skills curriculum. Surg Endosc. 2014;28(12):3343-3348. 126. Lyons C, Goldfarb D, Jones SL, et al. Which skills really matter? Proving face, content, and construct validity for a commercial robotic simulator. Surg Endosc. 2013;27(6):2020-2030. 127. Abboudi H, Khan MS, Aboumarzouk O, et al. Current status of validation for robotic surgery simulators—a systematic review. BJU Int. 2013;111(2):194-205. 128. Moglia A, Ferrari V, Morelli L, et al. A systematic review of virtual reality simulators for robot-assisted surgery. Eur Urol. 2016;69(6):1065-1080. 129. Smith R, Patel V, Satava R. Fundamentals of robotic surgery: a course of basic robotic surgery skills based upon a 14-society consensus template of outcomes measures and curriculum development. Int J Med Robot. 2014;10(3):379-384. 130. Helmreich RL. On error management: lessons from aviation. BMJ. 2000;320(7237):781-785. 131. Helmreich RL, Davies JM. Anaesthetic simulation and lessons to be learned from aviation. Can J Anaesth. 1997;44(9):907-912. 132. Gaba DM, DeAnda A. A comprehensive anesthesia simulation environment: re-creating the operating room for research and training. Anesthesiology. 1988;69(3):387-394. 133. Gaba DM. Improving anesthesiologists’ performance by simulating reality. Anesthesiology. 1992;76(4):491-494. 134. Boet S, Bould MD, Fung L, et al. Transfer of learning and patient outcome in simulated crisis resource management: a systematic review. Can J Anaesth. 2014;61(6):571-582. 135. Fung L, Boet S, Bould MD, et al. Impact of crisis resource management simulation-based training for interprofessional and interdisciplinary teams: a systematic review. J Interprof Care. 2015;29(5):433-444. 136. Paige JT, Kozmenko V, Yang T, et al. High-fidelity, simulation-based, interdisciplinary operating room team training at the point of care. Surgery. 2009;145(2):138-146. 137. Mitchell P, Wynia M, Golden R, et al. Core principles & values of effective team-based health care. Discussion Paper, Institute of Medicine. 2012. Available at: https://www.nationalahec.org/pdfs/vsrt-team-based-care-principles-values.pdf. Accessed August 27, 2018. 138. Eddy K, Jordan Z, Stephenson M. Health professionals’ experience of teamwork education in acute hospital settings: a systematic review of qualitative literature. JBI Database System Rev Implement Rep. 2016;14(4):96-137. 139. Cooper JB, Taqueti VR. A brief history of the development of mannequin simulators for clinical education and training. Qual Saf Health Care. 2004;13 Suppl 1:i11-18. 140. Paige JT, Kozmenko V, Yang T, et al. Attitudinal changes resulting from repetitive training of operating room personnel using of high-fidelity simulation at the point of care. Am Surg. 2009;75(7):584-590; discussion 590-581. 141. Powers KA, Rehrig ST, Irias N, et al. Simulated laparoscopic operating room crisis: An approach to enhance the surgical team performance. Surg Endosc. 2008;22(4):885-900. 142. Fanning RM, Gaba DM. The role of debriefing in simulation-based learning. Simul Healthc. 2007;2(2):115-125. 143. Paige JT, Arora S, Fernandez G, Seymour N. Debriefing 101: training faculty to promote learning in simulation-based training. Am J Surg. 2015;209(1):126-131. 144. Levett-Jones T, Lapkin S. The effectiveness of debriefing in simulation-based learning for health professionals: a systematic review. JBI Libr Syst Rev. 2012;10(51): 3295-3337. 145. Undre S, Koutantji M, Sevdalis N, et al. Multidisciplinary crisis simulations: the way forward for training surgical teams. World J Surg. 2007;31(9):1843-1853. 146. Yule S, Flin R, Maran N, et al. Surgeons’ non-technical skills in the operating room: reliability testing of the NOTSS behavior rating system. World J Surg. 2008;32(4): 548-556. 147. Yule S, Parker SH, Wilkinson J, et al. Coaching non-technical skills improves surgical residents’ performance in a simulated operating room. J Surg Educ. 2015;72(6):1124-1130. 148. Malec JF, Torsher LC, Dunn WF, et al. The mayo high performance teamwork scale: reliability and validity for evaluating key crew resource management skills. Simul Healthc. 2007;2(1):4-10. 149. Healey AN, Undre S, Vincent CA. Developing observational measures of performance in surgical teams. Qual Saf Health Care. 2004;13(suppl 1):i33-40. 150. Rosen MA, Salas E, Wilson KA, et al. Measuring team performance in simulation-based training: adopting best practices for healthcare. Simul Healthc. 2008;3(1):33-41.Brunicardi_Ch53_p2163-p2186.indd 218322/02/19 4:39 PM 2184SPECIFIC CONSIDERATIONSPART II 151. Knudson MM, Khaw L, Bullard MK, et al. Trauma training in simulation: translating skills from SIM time to real time. J Trauma. 2008;64(2):255-263; discussion 263-254. 152. Hamilton NA, Kieninger AN, Woodhouse J, et al. Video review using a reliable evaluation metric improves team function in high-fidelity simulated trauma resuscitation. J Surg Educ. 2012;69(3):428-431. 153. Gettman MT, Pereira CW, Lipsky K, et al. Use of high fidelity operating room simulation to assess and teach communication, teamwork and laparoscopic skills: initial experience. J Urol. 2009;181(3):1289-1296. 154. Dedy NJ, Bonrath EM, Zevin B, Grantcharov TP. Teaching nontechnical skills in surgical residency: a systematic review of current approaches and outcomes. Surgery. 2013;154(5): 1000-1008. 155. Tan SB, Pena G, Altree M, Maddern GJ. Multidisciplinary team simulation for the operating theatre: a review of the literature. ANZ J Surg. 2014;84(7-8):515-522. 156. Cumin D, Boyd MJ, Webster CS, Weller JM. A systematic review of simulation for multidisciplinary team training in operating rooms. Simul Healthc. 2013;8(3):171-179. 157. Darosa DA, Pugh CM. Error training: missing link in surgical education. Surgery. 2012;151(2):139-145. 158. Birkmeyer JD, Finks JF, O’Reilly A, et al. Surgical skill and complication rates after bariatric surgery. N Engl J Med. 2013;369(15):1434-1442. 159. Schmidt RA, Lee TD. Motor Learning and Performance: From Principles to Application. 5th ed. Champaign, IL: Human Kinetics; 2014. 160. Kontogiannis T. User strategies in recovering from errors in man-machine systems. Safety Science. 1999;32(1):49-68. 161. Rasmussen J. Human errors: A taxonomy for describing human malfunction in industrial installations. J Occup Accident. 1982;4(2-4):311-333. 162. D’Angelo AL, Law KE, Cohen ER, et al. The use of error analysis to assess resident performance. Surgery. 2015;158(5):1408-1414. 163. Pugh CM, DaRosa DA, Santacaterina S, Clark RE. Faculty evaluation of simulation-based modules for assessment of intraoperative decision making. Surgery. 2011;149(4):534-542. 164. Tang B, Hanna GB, Cuschieri A. Analysis of errors enacted by surgical trainees during skills training courses. Surgery. 2005;138(1):14-20. 165. Clark RE, Pugh CM, Yates KA, et al. The use of cognitive task analysis to improve instructional descriptions of procedures. J Surg Res. 2012;173(1):e37-42. 166. Law KE, Ray RD, D’Angelo AD, et al. Exploring senior residents’ intraoperative error management strategies: a potential measure of performance improvement. J Surg Educ. 2016;73(6):e64-e70. 167. Pugh CM, Santacaterina S, DaRosa DA, Clark RE. Intra-operative decision making: more than meets the eye. J Biomed Inform. 2011;44(3):486-496. 168. Schmitz CC, DaRosa D, Sullivan ME, et al. Development and verification of a taxonomy of assessment metrics for surgical technical skills. Acad Med. 2014;89(1):153-161. 169. Falcone JL, Hamad GG. The American Board of Surgery Certifying Examination: a retrospective study of the decreasing pass rates and performance for first-time examinees. J Surg Educ. 2012;69(2):231-235. 170. Reason JT. Human Error. Cambridge, England: Cambridge University Press; 1990. 171. Hooper BJ, O’Hare DP. Exploring human error in military aviation flight safety events using post-incident classification systems. Aviat Space Environ Med. 2013;84(8):803-813. 172. Wiegmann DA. Analysis of error management strategies during cardiac surgery: theoretical and practical implications. Paper presented at: Proceedings of the Human Factors and Ergonomics Society Annual Meeting, 2010. 173. Yardley S, Dornan T. Kirkpatrick’s levels and education “evidence.” Med Educ. 2012;46(1):97-106. 174. Barsuk JH, Cohen ER, Feinglass J, McGaghie WC, Wayne DB. Use of simulation-based education to reduce catheter-related bloodstream infections. Arch Intern Med. 2009;169(15):1420-1423. 175. Cohen ER, Feinglass J, Barsuk JH, et al. Cost savings from reduced catheter-related bloodstream infection after simulation-based education for residents in a medical intensive care unit. Simul Healthc. 2010;5(2):98-102. 176. Burden AR, Torjman MC, Dy GE, et al. Prevention of central venous catheter-related bloodstream infections: is it time to add simulation training to the prevention bundle? J Clin Anesth. 2012;24(7):555-560. 177. Khouli H, Jahnes K, Shapiro J, et al. Performance of medical residents in sterile techniques during central vein catheterization: randomized trial of efficacy of simulation-based training. Chest. 2011;139(1):80-87. 178. Riley W, Davis S, Miller K, et al. Didactic and simulation nontechnical skills team training to improve perinatal patient outcomes in a community hospital. Jt Comm J Qual Patient Saf. 2011;37(8):357-364. 179. Agency for Healthcare Research and Quality. TeamSTEPPS Guide to Action: Creating a Safety Net for your Healthcare Organization. Available at: https://www.onlineregistrationcenter .com/company_images/347/TeamSTEPPS_GuideToAction .pdf. Accessed August 27, 2018. 180. Capella J, Smith S, Philp A, et al. Teamwork training improves the clinical care of trauma patients. J Surg Educ. 2010;67(6):439-443. 181. Steinemann S, Berg B, Skinner A, et al. In situ, multidisciplinary, simulation-based teamwork training improves early trauma care. J Surg Educ. 2011;68(6):472-477. 182. Zendejas B, Brydges R, Wang AT, Cook DA. Patient outcomes in simulation-based medical education: a systematic review. J Gen Intern Med. 2013;28(8):1078-1089. 183. Cox T, Seymour N, Stefanidis D. Moving the needle: simulation’s impact on patient outcomes. Surg Clin North Am. 2015;95(4):827-838. 184. Ross JC, Trainor JL, Eppich WJ, Adler MD. Impact of simulation training on time to initiation of cardiopulmonary resuscitation for first-year pediatrics residents. J Grad Med Educ. 2013;5(4):613-619. 185. Hafford ML, Van Sickle KR, Willis RE, et al. Ensuring competency: are fundamentals of laparoscopic surgery training and certification necessary for practicing surgeons and operating room personnel? Surg Endosc. 2013;27(1): 118-126. 186. Derevianko AY, Schwaitzberg SD, Tsuda S, et al. Malpractice carrier underwrites Fundamentals of Laparoscopic Surgery training and testing: a benchmark for patient safety. Surg Endosc. 2010;24(3):616-623. 187. Zendejas B, Jakub JW, Terando AM, et al. Laparoscopic skill assessment of practicing surgeons prior to enrollment in a surgical trial of a new laparoscopic procedure. Surg Endosc. 2017;31(8):3313-3319. 188. Buyske J. Forks in the road: the assessment of surgeons from the American Board of Surgery perspective. Surg Clin North Am. 2016;96(1):139-146. 189. Calatayud D, Arora S, Aggarwal R, et al. Warm-up in a virtual reality environment improves performance in the operating room. Ann Surg. 2010;251(6):1181-1185. 190. Sullivan SA, Anderson BM, Pugh CM. Development of technical skills: education, simulation, and maintenance of certification. J Craniofac Surg. 2015;26(8):2270-2274.Brunicardi_Ch53_p2163-p2186.indd 218422/02/19 4:39 PM 2185SKILLS AND SIMULATIONCHAPTER 53 191. Badash I, Burtt K, Solorzano CA, Carey JN. Innovations in surgery simulation: a review of past, current and future techniques. Ann Transl Med. 2016 Dec;4(23):453. 192. Gause CD, Hsiung G, Schwab B, et al. Advances in pediatric surgical education: a critical appraisal of two consecutive minimally invasive pediatric surgery training courses. J Laparoendosc Adv Surg Tech A. 2016;26(8):663-670. 193. Cheung CL, Looi T, Lendvay TS, Drake JM, Farhat WA. Use of 3-dimensional printing technology and silicone modeling in surgical simulation: development and face validation in pediatric laparoscopic pyeloplasty. J Surg Educ. 2014;71(5):762-767. 194. Chan HH, Siewerdsen JH, Vescan A, et al. 3D rapid prototyping for otolaryngology-head and neck surgery: applications in image-guidance, surgical simulation and patient-specific modeling. PLoS One. 2015;10(9):e0136370. 195. Laufer S, Cohen ER, Kwan C, et al. Sensor technology in assessments of clinical skill. N Engl J Med. 2015 Feb 19;372(8):784-786. 196. Laufer S, D’Angelo AD, Kwan C, et al. Rescuing the Clinical Breast Examination: Advances in Classifying Technique and Assessing Physician Competency. Ann Surg. 2016 Sep 21. 197. Shenai MB, Dillavou M, Shum C, et al. Virtual interactive presence and augmented reality (VIPAR) for remote surgical assistance. Neurosurgery. 2011;68(1 suppl):200-207; discussion 207. 198. Shenai MB, Tubbs RS, Guthrie BL, Cohen-Gadol AA. Virtual interactive presence for real-time, long-distance surgical collaboration during complex microsurgical procedures. J Neurosurg. 2014;121(2):277-284. 199. Ponce BA, Jennings JK, Clay TB, et al. Telementoring: use of augmented reality in orthopaedic education: AAOS exhibit selection. J Bone Joint Surg Am. 2014;96(10):e84.Brunicardi_Ch53_p2163-p2186.indd 218522/02/19 4:39 PM
Brunicardi_Ch53_p2163-p2186.indd 218622/02/19 4:39 PMThis page intentionally left blankWeb-Based Education and Implications of Social MediaLillian S. Kao and Michael E. Zenilman 54chapterINTRODUCTIONSurgical education has changed significantly over the past two decades. Disruptive forces such as work hour restrictions and the advent of laparoscopy have forced educators to rethink how and where to teach residents. Technologies, including the inter-net and web-based applications, have further enabled educators to redesign surgical education (Fig. 54-1). The internet has become an integral tool not just in surgical education but also in Americans’ lives by changing the way that people communicate with each other, access information, and conduct their daily lives. Today, almost 9 in 10 American adults use the internet. Furthermore, the internet has revolutionized education by allowing for expanded reach, asynchronous learning whereby students and instructors do not have to be on the same time schedule, and multimedia materials.Like internet usage, social media has seen a rise in adop-tion over the past decade. Social media is a term that encom-passes multiple computer-mediated platforms that are used for creating and sharing information, ideas, and other content. Social media facilitates communication and interactions across virtual networks. Commonly used platforms include Facebook, Twitter, Snapchat, and Instagram. Social media can be used for multiple purposes including social and professional network-ing; however, this chapter will focus on its uses in surgical education.WEB-BASED EDUCATIONWeb-based educational resources include lectures and webi-nars, simulators, assessment tools, and interactive mentoring and coaching. Furthermore, entire web-based curricula have been developed that can link to online resources such as journal articles, interactive anatomy modules, and videos of operations. There are multiple advantages to web-based education. For sur-gical trainees, web-based educational materials allow access regardless of time of day or night, provide interactive tools for learning (i.e., anatomy), and videos for viewing operations and procedures. Furthermore, for practicing surgeons, web-based educational resources include forums for sharing challenging cases and procuring advice, activities for obtaining continuing 12education, and rapid access to information about new technolo-gies and research. However, there may also be disadvantages in terms of costs and technical problems.Multiple studies have evaluated learning outcomes after implementation of web-based educational interventions. In sur-gical education, these interventions may be used to teach patient care and decision-making via online case studies, convey knowledge using online didactic materials, or introduce surgical skills. However, studies evaluating these interventions tend to be nonrandomized, small, and single center. A 2008 systematic review and meta-analysis by Cook et al evaluated the effect of internet-based learning across healthcare in general. The review suggested that internet-based learning is better than no interven-tion but has similar effectiveness as traditional educational methods. A more recent 2015 systematic review by Jayakumar et al focused on web-based education in surgery. They reported a positive effect, but the majority of studies included in the review lacked a control. Based on the current literature, the internet should be considered one tool among many that can facilitate learning. However, further studies are necessary to identify the key elements that improve effectiveness. Web-based educational materials should be developed keeping adult learning theories and principles in mind.Web-based surgical curricula have been developed both at an institutional and at a national level. A widely-used curricu-lum is the Surgical Council on Resident Education (SCORE) curriculum, which is available via an online portal. Developed in 2006, SCORE is based on the six core competencies required of a graduating resident: patient care, medical knowledge, professionalism, communication, practice-based learning, and systems-based practice. SCORE is the result of an ongoing col-laborative effort of the American Board of Surgery, American College of Surgeons, American Surgical Association, Asso-ciation of Program Directors in Surgery, Association for Surgical Education, Residency Review Committee for Surgery of the Accreditation Council of Graduate Medical Education, and Society of American Gastrointestinal and Endoscopic Surgeons. The SCORE curriculum provides content for topics to be covered during a 5-year general surgery residency and is adding fellowship-level content as well. The SCORE Portal modules for each topic include learning objectives, discussion 3Introduction2187Web-Based Education2187Social Media–Based Education2188What is Social Media? / 2188Journal Clubs / 2190Live-Tweeting Conferences / 2190Interactive Forums and Communities / 2190Public Education / 2192Pitfalls in Web and Social Media–Based Education2192Implications and Future Directions2194Brunicardi_Ch54_p2187-p2196.indd 218713/02/19 2:37 PM 2188Disruptive forces1995200020052010ImpactSurgical educationEnabling technologiesFigure 54-1. The relationship between disruptive forces, enabling technologies, and surgical education. (Reproduced with permission from Pugh CM, Watson A, Bell RH, Jr, et al. Surgical education in the internet era. J Surg Res. 2009 Oct;156(2):177-182.)Key Points1 The internet has become an integral tool not just in surgical education but also in Americans’ lives by changing the way that people communicate with each other, access informa-tion, and conduct their daily lives.2 The internet has revolutionized surgical education by allow-ing for expanded reach—asynchronous learning whereby students and instructors do not have to be on the same time schedule—and multimedia materials such as interactive les-sons and videos.3 Despite the appeal of web-based education, systematic reviews and meta-analyses have failed to identify high-quality studies demonstrating that it is superior to standard educational methods in improving learning outcomes.4 Web-based and virtual reality simulators can be used both to teach technical skills and to assess performance. Virtual reality simulators have been effective in training surgeons on technical skills that translate to operating room performance.5 Online and social media–based journal clubs can overcome barriers associated with traditional journal clubs such as lack of a convenient time and no local clinical or methodological experts. However, they may require more time and commit-ment from the leaders, and they may not be as effective as traditional, in-person, faculty-moderated journal clubs.6 Social media rapidly and exponentially increases the spread of information.7 Multiple pitfalls exist with regards to web and social media–based education, including but not limited to: (a) need for more widespread adoption and use, (b) lack of accuracy and regulatory oversight over educational content, (c) issues regarding patient confidentiality and privacy, (d) nondisclo-sure of conflicts of interest, and (e) paucity of evidence for effectiveness of these materials for improving knowledge, attitudes, skills, and outcomes.8 Social media has become a necessary component of surgical practice.questions, text resources and videos, and self-assessment quizzes. Although improvements in quality examination per-formance among residencies that subscribe to SCORE are prom-ising, no studies have definitely demonstrated that SCORE use improves resident knowledge, skills, or clinical performance.Web-based education can also be used for assessing and teaching surgical skills. In 2013, Birkmeyer et al performed a study that correlated surgical skills in bariatric surgery, based on blinded reviews of videotaped operations, to clini-cal outcomes. The ability to discriminate surgeons with good and poor technical skills using video-based assessments has signifi-cant implications for training surgeons and for evaluating their performance. With regards to training, multiple web-based and virtual reality simulators have been developed that allow resi-dents to practice tasks and skills repetitively at their own pace and on their own time. These simulators can quantify efficiency of motion and time to complete a task as well as provide 4real-time feedback. These metrics have been demonstrated to have construct validity (in that they measure what they are sup-posed to be measuring) and criterion validity (in that they cor-relate with operative performance). For example, randomized trials have demonstrated that surgical simulation training corre-lates with decreased operative time and improves subjectively rated performance on technical skills in the live setting. Web-based assessments have also been used in combination with physical simulators to provide similar metrics.With regards to surgeons in practice, there has been increased enthusiasm for the use of video-based coaching to complement intraoperative teaching. In particular, postopera-tive review of videotaped procedures allows surgeons to receive individualized feedback about opportunities for improvement without the time constraints or pressures of the operating room. Randomized trials of surgical coaching in simulated settings suggests benefits over traditional simulator training, and larger trials in a live setting are ongoing. Although most coaching occurs face-to-face, there are opportunities to use web-based coaching. As an example, telementoring has been used to proc-tor surgeons in the operating room, even across the globe.Barriers to web-based education include the up-front costs for development and the need for technical expertise. As already noted, web-based education for teaching knowledge may not be more effective than traditional methods. On the other hand, simulation and video-based coaching hold significant prom-ise in improving training in and assessment of surgical skills. However, widespread implementation of video-based coaching will require a culture shift for surgeons to accept assistance and resources such as time, availability of coaches, and finances. Ongoing studies will provide data regarding the effectiveness of these educational strategies.SOCIAL MEDIA–BASED EDUCATIONWhat is Social Media?Social media is a term describing websites and web-based applications that enable users to share ideas, information, and Brunicardi_Ch54_p2187-p2196.indd 218813/02/19 2:37 PM 2189WEB-BASED EDUCATION AND IMPLICATIONS OF SOCIAL MEDIACHAPTER 54@Twitteruser1@Twitteruser2A@Twitteruser1@Twitteruser2BFigure 54-2. Social media usage can be (a) unidirectional or (b) bidirectional. User names on Twitter are denoted by “@”. A. @Twitteruser2 is following @Twitteruser1. She is receiving all of his messages in her Twitter feed. However, @Twitteruser1 does not follow her back and therefore does not receive her messages in return. B. @Twitteruser1 and @Twitteruser2 follow each other. Therefore, they each receive each other’s messages in their Twitter feeds.content through virtual networking. Although social media is often used to interact with friends and family, social media can also be used for educational and professional purposes. Examples include Twitter-based journal clubs, Facebook-based discussion forums, and professional networking sites such as LinkedIn or ResearchGate. Social media platforms can serve different purposes including social networking, microblogging, blogging, photo sharing, video sharing, and crowdsourcing.Commonly used social media platforms in surgery include Facebook, Twitter, and YouTube. Facebook is the most popular social networking site; it can be accessed via desktops, laptops, and mobile phones. It allows users to exchange information, photos, and videos with specified contacts or “friends” with whom there is a two-way relationship. Twitter is another popu-lar social media platform. It is a microblogging site that, like Facebook, allows exchange of messages and photos but limits messages or tweets to 140 characters or less. Twitter users may have one or two-way relationships with other users. Followers of a user receive all of that person’s tweets in their Twitter feed. YouTube is a social media platform that allows users to share videos.Social media usage in surgery may be unidirectional or bidirectional (Fig. 54-2). For example, journals such as the New England Journal of Medicine may have a large number of followers but may be following very few users back. Given that the number of journal articles published daily has risen expo-nentially, particularly with the advent of open access journals, keeping up with the surgical literature can be overwhelming. Following journals on social media is one strategy for staying updated. Although conventional media outlets such as newspa-pers and news channels may draw attention to practice-changing studies, social media is another platform by which such infor-mation can be promoted and disseminated by journals. Many surgical journals have an online and social media presence, and many have social media editors who curate the posted materials. Popular social media platforms for journals include Facebook and Twitter. Both platforms allow journals to post text, figures, and links to abstracts or journal articles. Both platforms allow others to share information or comment on articles. However, Twitter restricts text to 140 characters. A recent innovation that may counteract the limited number of allowed characters is the visual abstract, which is a concise pictorial representation of an article’s key points (Fig. 54-3). Recently, a prospective, case-control crossover study was performed whereby tweets about articles from Annals of Surgery were either accompanied by a visual abstract or tweeted with text alone. Accompaniment of a tweet with a visual abstract resulted in a threefold increase in article visits. Thus, the majority of journal followers may merely receive the information about new publications (uni-directional flow of information). However, users may also choose to respond to posts with comments (bidirectional flow of information).Surgicaltreatment ASurgicaltreatment BOutcomesComplications15%11%MortalityAuthor A et al. Journal. Date.Journal Logo8%4%Comparison of Surgical Treatment A VersusSurgical Treatment BPatients with disease XFigure 54-3. A visual abstract is a graphical summary of the main results of a journal article.Brunicardi_Ch54_p2187-p2196.indd 218913/02/19 2:37 PM 2190SPECIFIC CONSIDERATIONSPART IIJournal ClubsJournals may promote bidirectional flow of information by hosting social media–based journal clubs. From an educational standpoint, journal clubs have traditionally served not only as an adjunct to lectures but also as a forum to teach about critical appraisal of the literature. Furthermore, when facilitated by faculty with clinical expertise on the subject being discussed, surgical trainees can bet-ter evaluate how to incorporate the evidence into practice. How-ever, barriers to traditional journal clubs may include poor participation, lack of a convenient time, or absence of local exper-tise in either the clinical topic or research methodology. Social media–based journal clubs can help to overcome these barriers by allowing for asynchronous discussion and expert moderators. Online journal clubs can be carried out in real time, but they also allow respondents to comment hours or even days later to a conversation. Multiple specialties, including surgery, have developed social media–based journal clubs. Tips for suc-cessfully launching an online journal club can be garnered from the expanding experience with them (Table 54-1).Social media–based journal clubs in surgery have been conducted via Facebook, Twitter, or a combination of the two platforms. They have also taken the form of a blog. Although commonly associated with personal journals or diaries, blogs can also be found on professional websites that are updated frequently by a person or group (i.e., by a journal or surgical society). Conversations from journal club discussions can also be compiled and summarized into a transcript either manually or using web-based applications such as Storify. These transcripts can be posted on the journal website or shared. Furthermore, 5aTable 54-1Ten tips for setting up an online journal club TIP 1Create an online home page that serves as a launching pad for your journal club discussions 2Develop and register a hashtag on Twitter 3Incorporate not only Twitter but other collaborative platforms as part of your online journal club 4Ensure that the time of the journal club is convenient for your target audience 5Help prepare participants by aggregating other online resources relevant to the article 6Consider inviting the authors of the featured article or other experts in the field 7Suggest journal club participants consider using specific Twitter management applications during the Tweet chat 8Engage the participants to cultivate and incentivize more discussion 9Connect to the online community by following and engaging with other relevant social media accounts10Link back to the original paper by inserting a comment on PubMed CommonsData from Chan TM, Thoma B, Radecki R, et al. Ten steps for setting up an online journal club, J Contin Educ Health Prof. 2015 Spring;35(2):148-154.summaries from either in-person or online journal clubs can be added to the PubMed citation via PubMed Commons.Preliminary data suggests that online journal clubs increase discussion about articles, views of the abstract, and downloads (Fig. 54-4). For example, the International Gen-eral Surgery Journal Club held four moderated discussions of journal articles on Twitter between March and June 2014. The reviewed articles covered topics relating to bariatric surgery (March), venous thromboembolism in trauma (April), diverticu-litis (May), and contralateral prophylactic mastectomy for breast cancer (June). Although the authors and invited experts only moderated discussions for 3 days, Twitter activity increased in the days preceding and following these discussions. Further-more, daily views of the article and downloads increased cor-respondingly. Thus, online journal clubs are a potential strategy for increasing surgeon education about seminal articles.While social media–based journal clubs hold much appeal, there is a paucity of data regarding their effectiveness in teach-ing participants about critical appraisal skills. A multicenter randomized trial compared journal clubs moderated by a faculty member to online discussions. Surgical resi-dents in both arms utilized modules developed by the Evidence Based Reviews in Surgery Steering Committee; these modules include the relevant guide to critical appraisal and a method-ological and clinical review. Residents randomized to the mod-erated group scored higher on a validated test evaluating critical appraisal skills. Further study is required to assess the effective-ness of social media–based journal clubs in disseminating new knowledge as well as in teaching critical appraisal.Live-Tweeting ConferencesTraditionally, surgeons have attended regional and national conferences to network, learn new information relevant to their practice, and exchange ideas. However, with the advent of social media, surgeons no longer have to physically attend a conference to perform all those activities. Live-tweeting is a term used to describe the posting of comments on Twitter about an event while it is ongoing. Multiple surgical and nonsurgical societies have adopted Twitter to expand the reach of their conferences. By denoting tweets as emanating from a specific conference with a unique hashtag, the reach and number of impressions can actually be measured (Fig. 54-5). The reach refers to the number of unique recipients of messages from a specific group of Twitterers (or people posting on Twitter). Impressions refers to each time a message was delivered to a recipient; a recipient may receive the same message more than once. Neither reach nor impressions measure whether the recipient read the tweet. As an example of how reach and impressions can be used to provide metrics for social media, the Healthcare Hashtag Project allows registered conference hashtags to track the latest tweets, the most prolific Twitterers of conference-related tweets, the most commonly mentioned Twitterers, and the number of impressions (Fig. 54-6) (https://www.symplur.com/healthcare-hashtags/). As noted in the figure, social media rapidly and exponentially increases the spread of information. Transcripts of conference-related tweets can also be assembled to allow a conversation thread to be organized into a cohesive discussion.Interactive Forums and CommunitiesInteractive forums and communities are another method by which both the internet and social media can be used for 5b6Brunicardi_Ch54_p2187-p2196.indd 219013/02/19 2:37 PM 2191WEB-BASED EDUCATION AND IMPLICATIONS OF SOCIAL MEDIACHAPTER 54ATimeDaily HTML Views & PDF Downloads of Featured Article During Each of 4 Monthly IGSJC Twitter Journal ClubsTweets025050075010001250Tweet Activity on #IGSJC10. Mar24. Mar7. Apr21. Apr5. May19. May2. JunB0100Number of HTML Views PDF Downloads200300400100Dates of Journal Club +/–5 DaysMarch 3-5June 4-50255075HTML ViewPDF DownloadFigure 54-4. Impact of a social media–based journal club on Twitter activity, hypertext markup language (HTML) views, and portable document format (PDF) downloads. A. Activity during a Twitter-based journal club such as the International General Surgery Journal Club (IGSJC) can be tracked by denoting the journal club related tweets with a hashtag (#IGSJC). Twitter activity increased during each of four journal clubs. B. Daily HTML views and PDF downloads of featured articles also increased around the time period of the four Twitter journal clubs. (Unpublished data from Sarah Bryczowski and Michael E. Zenilman.)@Twitteruser14 followers(3 unique, 1 shared)Reach: 7 unique usersImpressions: 8 impressionsEach user receivedtweet from@Twitteruser1:1 impression eachReceivedtweet fromboth users:2impressionsEach user receivedtweet from@Twitteruser2:1 impression each@Twitteruser24 followers(3 unique, 1 shared)Figure 54-5. Difference between reach and impressions in Twitter. If there are two Twitter users and each has three unique followers and one shared follower, then there are seven unique recipients of their combined tweets. Their total reach is seven unique users. If both users tweet the same message, then one user will have received the message twice. However, each time the message was delivered counts as an impression; thus, the followers will have a total of eight impressions.Brunicardi_Ch54_p2187-p2196.indd 219113/02/19 2:37 PM 2192SPECIFIC CONSIDERATIONSPART IIImpressionsTweetsParticipantsAvg Tweets/HourAvg Tweets/Participant4272298443,601The Numbers@User1 123@User2 65@User3 62@User4 46@User5 42@User6 32@User7 21@User8 19@User9 17@User10 16Top 10 by Mentions@User3 27@User11 25@User7 23@User4 23@User12 19@User13 13@User14 12@User15 11@User2 10@User1 9Top 10 by Tweets@User13 103,937@User24 80,956@User4 42,976@User3 40,911@User6 28,966@User41 22,534@User52 14,566@User72 13,514@User35 11,965@User68 9862Top 10 by ImpressionsThe #Surgery Conference In˜uencersFigure 54-6. Example of conference analytics from Healthcare Hashtags (https://www.symplur.com/healthcare-hashtags/). Sur-gery conferences can tag tweets by using a prespecified hashtag (i.e., #SurgeryConference) to denote conference-related messages. These can then be tracked. A mention occurs when a user includes another user’s name in the tweet. Note in the example that even if there are only a few users tweeting about a conference, the number of impressions can be large if several of those users have a large number of followers. For example, @User13 only tweeted 13 times but had 103,937 impressions.educational purposes. They are examples of crowdsourcing whereby information is gathered by enlisting the assistance of a large number of participants. Crowdsourcing often involves the general public or a loosely defined group of individuals as opposed to outsourcing, which tasks a project to a specific company or group. For example, Wikipedia is an example of crowdsourcing. In surgery, an example of crowdsourcing are the web-based communities formed by the American College of Surgeons. Members can belong to one or more communities which are based on specialty (i.e., general surgery or endocrine surgery), geography (i.e., Florida Chapter), level of education (i.e., medical students or senior surgeons), special interest (i.e., surgeon writers), or issue (i.e., quality improvement and advo-cacy). Members can post and respond to discussion threads that cover a wide range of topics including advice for challenging cases, surgical history, and political issues.An example of a social media–based interactive forum is the International Hernia Collaboration (IHC) which is housed on Facebook. Participants include not only surgeons but also healthcare providers and industry representatives interested in improving outcomes after hernia surgery. Membership in the IHC is limited to those who have been vetted and approved. The forum allows members to ask for advice on difficult cases, debate controversial topics, post step-by-step instructions on procedures or management strategies, and disseminate informa-tion rapidly to a wide audience. Collaborative forums such as the IHC allow for real-time, interactive, case-based, continuing education.Public EducationThe educational opportunities provided by the internet and social media are not limited to healthcare providers. The inter-net and social media are also being increasingly used to educate patients and their families. There are multiple media through which health education is spread, including, but not limited to, online or social media discussion forums run by patients, patient support groups, healthcare providers, or healthcare orga-nizations; blogs or newsrooms; or electronic and mobile health patient portals. Social media allows patients rapid access to information regardless of time or location. However, as noted in the following section, the accuracy of social media–based educational materials cannot be guaranteed, and patients should utilize caution in relying on the information to make important healthcare decisions.PITFALLS IN WEB AND SOCIAL MEDIA–BASED EDUCATIONDespite the many advantages of web and social media–based education, significant potential pitfalls still remain. First, widespread adoption and utilization is a challenge. Although internet and mobile phone usage is prevalent, effec-tiveness of web-based educational materials is dependent upon trainees’ and surgeons’ uptake of the technology and available resources. Despite increasing availability of the internet and mobile technology, not all surgeons use it for educational pur-poses. For example, a systematic review and meta-analysis by Guraya et al found that three out of four medical students use social networking sites, but only one out of five uses them for educational purposes. Furthermore, lack of utilization can impact educational effectiveness. In the previously mentioned multicenter trial comparing a moderated journal club to an online version, low participation in the Internet journal club was postulated to be a significant factor in the poorer perfor-mance on a critical appraisal test. More attention to instruc-tional design may improve uptake and effectiveness. A systematic review and meta-analysis by Cook et al determined that features such as interactivity, practice exercises, repeti-tion, and feedback are associated with improved learning out-comes. The authors also noted that the evidence base upon which to design internet-based learning programs is limited by poor study methodology, failure to use conceptual frame-works, and lack of adherence to reporting standards. Thus, while the aforementioned features should be considered in designing future web and social media–based educational pro-grams, further evidence-based guidance is needed.Second, the quality of information available online and via social media may not be accurate or reliable. Multiple reports have been published regarding the inaccuracies of web-based educational materials. Surgeons and surgical trainees should carefully evaluate the source of educational material, search for conflicts of interest that may result in biased information, assess how recently the information was updated, and cross-check references. The lay public may have more difficulty in identifying trustworthy surgical educational materials on the internet. Healthcare providers should guide patients to reputable websites and to encourage discussion regarding the accuracy of the content.Third, useful dialog and advice about difficult cases must be balanced with ethical considerations surrounding patient con-fidentiality and privacy. Appropriate safeguards must be taken 7Brunicardi_Ch54_p2187-p2196.indd 219213/02/19 2:37 PM 2193WEB-BASED EDUCATION AND IMPLICATIONS OF SOCIAL MEDIACHAPTER 54Table 54-2The American College of Physicians Ethics, Professionalism and Human Rights Committee; the American College of Physicians Council of Associates; and the Federation of State Medical Boards Special Committee on Ethics and Professionalism published a position paper on online medical professionalismPosition 1Use of online media can bring significant educational benefits to patients and physicians, but it may also pose ethical challenges. Maintaining trust in the profession and in patient–physician relationships requires that physicians consistently apply ethical principles for preserving the relationship, confidentiality, privacy, and respect for persons to online settings and communications.Position 2The boundaries between professional and social spheres can blur online. Physicians should keep the two spheres separate and comport themselves professionally in both.Position 3Email or other electronic communications should only be used by physicians in an established patient–physician relationship and with patient consent. Documentation about patient care communications should be included in the patient’s medical record.Position 4Physicians should consider periodically “self-auditing” to assess the accuracy of information available about them on physician-ranking websites and other sources online.Position 5The reach of the internet and online communications is far and often permanent. Physicians, trainees, and medical students should be aware that online postings may have future implications for their professional lives.Data from Farnan JM1, Snyder Sulmasy L, Worster BK, et al: Online medical professionalism: patient and public relationships: policy statement from the American College of Physicians and the Federation of State Medical Boards, Ann Intern Med. 2013 Apr 16;158(8):620-627.to ensure that patients cannot be identified based on provided information, that patients have consented to have their informa-tion posted anonymously, and that all case-related comments are appropriate and professional. While common sense should be utilized in posting about patient cases, only a few organizations have published guidelines for how to safeguard against potential pitfalls. In 2013, the American College of Physicians Ethics, Professionalism, and Human Rights Committee; the American College of Physicians Council of Associates; and the Federa-tion of State Medical Boards Special Committee on Ethics and Professionalism published a position statement about online medical education (Table 54-2). The paper stated that “Maintain-ing trust in the profession and in patient–physician relationships requires that physicians consistently apply ethical principles for preserving the relationship, confidentiality, privacy, and respect for persons to online settings and communications.”Fourth, conflicts of interest must be clearly stated. Jour-nals require authors to declare relevant conflicts of interest, but multiple studies suggest that these often go unreported. Simi-larly, conflicts of interest should be disclosed on social media. However, such disclosures may be more difficult on social media due to the limited number of allowable characters (i.e., 140 characters for Twitter) or to the way information is propa-gated. For example, a surgeon may disclose an industry relation-ship on an original tweet, but the disclosure may not appear in subsequent comments of a discussion thread. Surgeons post-ing on social media must make it their ethical and professional obligation to disclose their conflicts of interest. Furthermore, users of social media content must be aware of the potential for bias introduced by undisclosed conflicts of interest and per-form due diligence in assessing the reliability of the source. Lastly, regulatory bodies and professional organizations should publish standardized guidelines for disclosing on social media or develop mechanisms by which disclosure can be publicly accessed (such as the Open Payments database).Fifth, professionalism must always be maintained. Sur-geons posting content on the web or on social media must be aware that information will be widely disseminated and avail-able for posterity; messages posted on social media cannot be fully retracted. As already mentioned, surgeons must strive to maintain patient privacy, ensure accuracy of information, and disclose conflicts of interest. Furthermore, surgeons must be aware of unintentional interpretations of messages (i.e., as discriminatory or unprofessional). Multiple studies of health-care providers’ social media sites have identified potentially and clearly unprofessional content; these studies have included medical students, residents, and practicing surgeons. Despite the prevalence of unprofessional content, few surgical residency programs have formal institutional social media policies. Fur-thermore, the American College of Physicians and Federation of State Medical Boards position statement only addresses a few of the issues surrounding web-based activities including for patient and physician education (Table 54-3).Table 54-3Online medical professionalism and educationPOSITIONS ON PROFESSIONALISM IN ONLINE PATIENT AND PHYSICIAN EDUCATION• The Internet can be a powerful tool for education.• Physicians should guide patients to high quality online resources that are accurate and objective. These sites should have peer-reviewed content or have verifiable mechanisms for quality control of information.• Online resources for learning can be used by patients and physicians.• The internet and social networking can be used to improve public health. Physicians engaged in online communities should ensure the security of the networks and restriction of participation to verified users. Clinical scenarios should not contain any personal identifying information, and patient consent should be obtained before sharing the vignette.• Discussion of frustrations online undermines trust and professionalism and should be avoided.Data from Farnan JM1, Snyder Sulmasy L, Worster BK, et al: Online medical professionalism: patient and public relationships: policy statement from the American College of Physicians and the Federation of State Medical Boards, Ann Intern Med. 2013 Apr 16;158(8):620-627.Brunicardi_Ch54_p2187-p2196.indd 219313/02/19 2:37 PM 2194SPECIFIC CONSIDERATIONSPART IILastly, studies evaluating the effectiveness of web-based education have had varied results. A recent systematic review by Taveira-Gomes et al assessed 251 articles using computer-based learning methodologies in medical education; the num-ber of articles on this topic has increased over time. The most commonly used metrics for evaluating the effectiveness of these methodologies were assessments of knowledge, attitudes, and skills. The majority of studies reported positive effects on these outcomes, although the more rigorous studies (i.e., randomized trials) were less likely to find a positive effect. Online activ-ity (i.e., number of posts or views) was tracked in a few stud-ies, but results were conflicting regarding whether increased engagement correlated with improved performance. This review suggests that high-quality studies are needed of web-based edu-cational interventions and that these studies need to include measures of clinical performance and outcomes.IMPLICATIONS AND FUTURE DIRECTIONSThe Society of University Surgeons’ Social and Legislative Committee issued a position statement entitled: “Social media is a necessary component of surgery practice.” Given the rapid pace with which technology is advancing and the familiar-ity of the current generation (Generation Z) with the inter-net, surgeons have no choice but to harness the power of the internet and social media or risk being left behind. Many jour-nals are phasing out print versions, and several journals are already online only. Furthermore, textbooks may also become a relic from the past as publishers move towards developing digi-tal versions that include interactive graphics, audio, and video.As surgical education continues to evolve, future directions may include broader indications for utilization of weband social media-based resources. For example, video-based coaching with face-to-face discussions have been used postoperatively to sup-plement intraoperative teaching. However, preoperative crowd-sourcing in planning a challenging case or intraoperative video telementoring are other applications of video-based coaching.Future research efforts should focus on identifying the most effective formats and components of web and social media–based educational interventions, using rigorous methods to compare educational methods, and measuring clinical out-comes. Moreover, standardized guidelines should be instituted in order to safeguard against ethical and professional misconduct.BIBLIOGRAPHYBirkmeyer JD, Finks JF, O’Reilly A, Oerline M, et al; Michigan Bariatric Surgery Collaborative. Surgical skill and complica-tion rates after bariatric surgery. N Engl J Med. 2013;369(15): 1434-1442. This study correlated blinding reviewer ratings of videotaped laparoscopic gastric bypass procedures to clinical outcomes. Greater skill was associated with lower rates of com-plications, reoperations, readmissions, and emergency depart-ment visits.Bresnahan ER, Huynh DTK, Jacob B. Social media and education in hernia repair. In: Hope WW, Cobb WS, Adrales GL, eds. Textbook of Hernia. Cham: Springer International Publishing; 2017:373-379. This book chapter describes the International Hernia Collaboration, which is a Facebook-based community of practicing surgeons, trainees, and industry representatives. The goals of the collaboration include exchange of ideas and advice regarding patient care, discussion and debate of controversial topics in hernia management, and dissemination of information to a global audience.Chan TM, Thoma B, Radecki R, et al. Ten steps for setting up an online journal club. J Contin Educ Health Prof. 2015; 35(2):148-154. Written by a multidisciplinary group of authors, this article provides 10 helpful hints for setting up an online journal club, using examples from existing journal clubs.Cook DA, Levinson AJ, Garside S, Dupras DM, Erwin PJ, Montori VM. Instructional design variations in internet-based learn-ing for health professions education: a systematic review and meta-analysis. Acad Med. 2010;85(5):909-922. This systematic review and meta-analysis of 51 studies, including 30 random-ized trials, identified several key features of internet-based learning interventions that were associated with improved learning outcomes: interactivity, practice exercises, repeti-tion, and feedback. However, the evidence base upon which to design internet-based learning programs is limited by poor study designs, failure to use conceptual frameworks, and lack of adherence to reporting standards.Cook DA, Levinson AJ, Garside S, Dupras DM, Erwin PJ, Montori VM. Internet-based learning in the health professions: a meta-analysis. JAMA. 2008;300(10):1181-1196. This meta-analysis of 201 studies reported that internet-based instruction had a positive effect on educational outcomes as compared to no intervention, but that there was similar effectiveness between internet-based instruction and traditional educational methods.Farnan JM, Synder Sulmasy L, Worster BK, Chaudhry HJ, Rhyne JA, Arora VM; American College of Physicians Ethics, Profes-sionalism and Human Rights Committee; American College of Physicians Council of Associates; Federation of State Medical Boards Special Committee on Ethics and Professionalism. Online medical professionalism: patient and public rela-tionships: policy statement from the American College of Physicians and the Federation of State Medical Boards. Ann Intern Med. 2013;158(8):620-627. This position statement pro-vides recommendations on issues relating to professional use of the internet and social media including but not limited to: use of social media for nonclinical purposes, patient confidentiality in online discussions, and use of web-based patient education resources.Guraya SY. The usage of social networking sites by medical stu-dents for educational purposes: a meta-analysis and systematic review. N Am J Med Sci. 2016;8(7):268-278. This review of 10 articles published between 2004 and 2014 suggested that although 75% of medical students use social networking sites, only 20% use them for academic or educational purposes. Fur-thermore, none of these studies evaluated whether use of social media improved academic performance.Ibrahim AM, Lillemoe KD, Klingensmith ME, Dimick JE. Visual abstracts to disseminate research on social media: a prospective, case-control crossover study. Ann Surg. 2017;266(6):e46-e48. This prospective, case-control crossover study compared the impact of tweets alone versus tweets accompanied by a visual abstract on article visits; there was a threefold increase when visual abstracts accompanied the tweets.Jayakumar N, Brunckhorts O, Dasgupta P, Khan MS, Ahmed K. e-Learning in surgical education: a systematic review. J Surg Educ. 2015;72(6):1145-1157. This systematic review of 38 studies suggested that while the majority of studies evaluating electronic learning in surgical education demonstrate a positive effect, most lack a proper control.McLeod RS, MacRae HM, McKenzie ME, Victor JC, Brasel KJ; Evidence Based Reviews in Surgery Steering Committee. A moderated journal club is more effective than an Internet journal club in teaching critical appraisal skills: results of a multicenter randomized controlled trial. J Am Coll Surg. 8Brunicardi_Ch54_p2187-p2196.indd 219413/02/19 2:37 PM 2195WEB-BASED EDUCATION AND IMPLICATIONS OF SOCIAL MEDIACHAPTER 542010;211(6):769-776. This multicenter randomized trial reported that surgical residents who participated in a journal club moderated by a faculty member scored higher on a vali-dated test of critical appraisal than those who participated in an online journal club.Pugh CM, Watson A, Bell RH Jr, et al. Surgical education in the internet era. J Surg Res. 2009;156(2):177-182. This article describes the factors that led to a change in surgical education over the last two decades.Taveira-Gomes T, Ferreira P, Taveira-Gomes I, Severo M, Ferreira MA. What are we looking for in computer-based learning inter-ventions in medical education? A systematic review. J Med Internet Res. 2016;18(8):e204. This systematic review assessed recent studies on computer-based learning (CBL) for types of software platforms and interventions and adherence to current recommendations for CBL research.Brunicardi_Ch54_p2187-p2196.indd 219513/02/19 2:37 PM