tabula-sapiens-bladder-scanvi / README.md

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	---
	library_name: scvi-tools
	license: cc-by-4.0
	tags:
	- biology
	- genomics
	- single-cell
	- model_cls_name:SCANVI
	- scvi_version:1.2.0
	- anndata_version:0.11.1
	- modality:rna
	- tissue:various
	- annotated:True
	---


	ScANVI is a variational inference model for single-cell RNA-seq data that can learn an underlying
	latent space, integrate technical batches and impute dropouts.
	In addition, to scVI, ScANVI is a semi-supervised model that can leverage labeled data to learn a
	cell-type classifier in the latent space and afterward predict cell types of new data.
	The learned low-dimensional latent representation of the data can be used for visualization and
	clustering.

	scANVI takes as input a scRNA-seq gene expression matrix with cells and genes as well as a
	cell-type annotation for a subset of cells.
	We provide an extensive [user guide](https://docs.scvi-tools.org/en/1.2.0/user_guide/models/scanvi.html).

	- See our original manuscript for further details of the model:
	[scANVI manuscript](https://www.embopress.org/doi/full/10.15252/msb.20209620).
	- See our manuscript on [scvi-hub](https://www.biorxiv.org/content/10.1101/2024.03.01.582887v2)
	how to leverage pre-trained models.

	This model can be used for fine tuning on new data using our Arches framework:
	[Arches tutorial](https://docs.scvi-tools.org/en/1.0.0/tutorials/notebooks/scarches_scvi_tools.html).


	# Model Description

	Tabula Sapiens is a benchmark, first-draft human cell atlas of nearly 500,000 cells from 24 organs of 15 normal human subjects.

	# Metrics

	We provide here key performance metrics for the uploaded model, if provided by the data uploader.

	<details>
	<summary><strong>Coefficient of variation</strong></summary>

	The cell-wise coefficient of variation summarizes how well variation between different cells is
	preserved by the generated model expression. Below a squared Pearson correlation coefficient of 0.4
	, we would recommend not to use generated data for downstream analysis, while the generated latent
	space might still be useful for analysis.

	Cell-wise Coefficient of Variation:

	\| Metric \| Training Value \| Validation Value \|
	\|-------------------------\|----------------\|------------------\|
	\| Mean Absolute Error \| 1.77 \| 1.80 \|
	\| Pearson Correlation \| 0.87 \| 0.88 \|
	\| Spearman Correlation \| 0.79 \| 0.77 \|
	\| R² (R-Squared) \| 0.52 \| 0.51 \|

	The gene-wise coefficient of variation summarizes how well variation between different genes is
	preserved by the generated model expression. This value is usually quite high.

	Gene-wise Coefficient of Variation:

	\| Metric \| Training Value \|
	\|-------------------------\|----------------\|
	\| Mean Absolute Error \| 16.06 \|
	\| Pearson Correlation \| 0.73 \|
	\| Spearman Correlation \| 0.77 \|
	\| R² (R-Squared) \| 0.08 \|

	</details>

	<details>
	<summary><strong>Differential expression metric</strong></summary>

	The differential expression metric provides a summary of the differential expression analysis
	between cell types or input clusters. We provide here the F1-score, Pearson Correlation
	Coefficient of Log-Foldchanges, Spearman Correlation Coefficient, and Area Under the Precision
	Recall Curve (AUPRC) for the differential expression analysis using Wilcoxon Rank Sum test for each
	cell-type.

	Differential expression:

	\| Index \| gene_f1 \| lfc_mae \| lfc_pearson \| lfc_spearman \| roc_auc \| pr_auc \| n_cells \|
	\| --- \| --- \| --- \| --- \| --- \| --- \| --- \| --- \|
	\| fibroblast \| 0.97 \| 1.03 \| 0.77 \| 0.96 \| 0.34 \| 0.90 \| 5557.00 \|
	\| macrophage \| 0.94 \| 1.05 \| 0.73 \| 0.95 \| 0.30 \| 0.88 \| 5338.00 \|
	\| bladder urothelial cell \| 0.93 \| 0.89 \| 0.80 \| 0.97 \| 0.42 \| 0.91 \| 4151.00 \|
	\| T cell \| 0.95 \| 1.86 \| 0.74 \| 0.90 \| 0.24 \| 0.86 \| 2916.00 \|
	\| myofibroblast cell \| 0.93 \| 1.88 \| 0.66 \| 0.88 \| 0.34 \| 0.84 \| 2078.00 \|
	\| plasma cell \| 0.88 \| 1.87 \| 0.72 \| 0.89 \| 0.14 \| 0.86 \| 1141.00 \|
	\| mast cell \| 0.93 \| 2.78 \| 0.61 \| 0.82 \| 0.21 \| 0.79 \| 1029.00 \|
	\| pericyte \| 0.93 \| 2.05 \| 0.74 \| 0.88 \| 0.27 \| 0.78 \| 875.00 \|
	\| mature NK T cell \| 0.86 \| 3.00 \| 0.67 \| 0.82 \| 0.42 \| 0.87 \| 508.00 \|
	\| smooth muscle cell \| 0.94 \| 2.88 \| 0.72 \| 0.81 \| 0.28 \| 0.82 \| 290.00 \|
	\| vein endothelial cell \| 0.79 \| 3.02 \| 0.70 \| 0.86 \| 0.36 \| 0.79 \| 278.00 \|
	\| B cell \| 0.87 \| 3.88 \| 0.58 \| 0.70 \| 0.34 \| 0.75 \| 253.00 \|
	\| capillary endothelial cell \| 0.72 \| 3.22 \| 0.71 \| 0.76 \| 0.38 \| 0.75 \| 77.00 \|
	\| endothelial cell of lymphatic vessel \| 0.75 \| 4.50 \| 0.66 \| 0.73 \| 0.28 \| 0.70 \| 74.00 \|
	\| plasmacytoid dendritic cell \| 0.62 \| 5.99 \| 0.53 \| 0.47 \| 0.32 \| 0.73 \| 18.00 \|

	</details>

	# Model Properties

	We provide here key parameters used to setup and train the model.

	<details>
	<summary><strong>Model Parameters</strong></summary>

	These provide the settings to setup the original model:
	```json
	{
	"n_hidden": 128,
	"n_latent": 20,
	"n_layers": 3,
	"dropout_rate": 0.05,
	"dispersion": "gene",
	"gene_likelihood": "nb",
	"linear_classifier": false,
	"latent_distribution": "normal",
	"use_batch_norm": "none",
	"use_layer_norm": "both",
	"encode_covariates": true
	}
	```

	</details>

	<details>
	<summary><strong>Setup Data Arguments</strong></summary>

	Arguments passed to setup_anndata of the original model:
	```json
	{
	"labels_key": "cell_ontology_class",
	"unlabeled_category": "unknown",
	"layer": null,
	"batch_key": "donor_assay",
	"size_factor_key": null,
	"categorical_covariate_keys": null,
	"continuous_covariate_keys": null,
	"use_minified": false
	}
	```

	</details>

	<details>
	<summary><strong>Data Registry</strong></summary>

	Registry elements for AnnData manager:
	\| Registry Key \| scvi-tools Location \|
	\|-------------------\|--------------------------------------\|
	\| X \| adata.X \|
	\| batch \| adata.obs['_scvi_batch'] \|
	\| labels \| adata.obs['_scvi_labels'] \|
	\| latent_qzm \| adata.obsm['scanvi_latent_qzm'] \|
	\| latent_qzv \| adata.obsm['scanvi_latent_qzv'] \|
	\| minify_type \| adata.uns['_scvi_adata_minify_type'] \|
	\| observed_lib_size \| adata.obs['observed_lib_size'] \|

	- Data is Minified: False

	</details>

	<details>
	<summary><strong>Summary Statistics</strong></summary>

	\| Summary Stat Key \| Value \|
	\|--------------------------\|-------\|
	\| n_batch \| 5 \|
	\| n_cells \| 24583 \|
	\| n_extra_categorical_covs \| 0 \|
	\| n_extra_continuous_covs \| 0 \|
	\| n_labels \| 16 \|
	\| n_latent_qzm \| 20 \|
	\| n_latent_qzv \| 20 \|
	\| n_vars \| 3000 \|

	</details>


	<details>
	<summary><strong>Training</strong></summary>

	<!-- If your model is not uploaded with any data (e.g., minified data) on the Model Hub, then make
	sure to provide this field if you want users to be able to access your training data. See the
	scvi-tools documentation for details. -->
	Training data url: Not provided by uploader

	If provided by the original uploader, for those interested in understanding or replicating the
	training process, the code is available at the link below.

	Training Code URL: https://github.com/YosefLab/scvi-hub-models/blob/main/src/scvi_hub_models/TS_train_all_tissues.ipynb

	</details>


	# References

	The Tabula Sapiens Consortium. The Tabula Sapiens: A multiple-organ, single-cell transcriptomic atlas of humans. Science, May 2022. doi:10.1126/science.abl4896