scvi-tools
Overview
scvi-tools is a comprehensive Python framework for probabilistic models in single-cell genomics. Built on PyTorch and PyTorch Lightning, it provides deep generative models using variational inference for analyzing diverse single-cell data modalities.
When to Use This Skill
Use this skill when:
- •Analyzing single-cell RNA-seq data (dimensionality reduction, batch correction, integration)
- •Working with single-cell ATAC-seq or chromatin accessibility data
- •Integrating multimodal data (CITE-seq, multiome, paired/unpaired datasets)
- •Analyzing spatial transcriptomics data (deconvolution, spatial mapping)
- •Performing differential expression analysis on single-cell data
- •Conducting cell type annotation or transfer learning tasks
- •Working with specialized single-cell modalities (methylation, cytometry, RNA velocity)
- •Building custom probabilistic models for single-cell analysis
Core Capabilities
scvi-tools provides models organized by data modality:
1. Single-Cell RNA-seq Analysis
Core models for expression analysis, batch correction, and integration. See references/models-scrna-seq.md for:
- •scVI: Unsupervised dimensionality reduction and batch correction
- •scANVI: Semi-supervised cell type annotation and integration
- •AUTOZI: Zero-inflation detection and modeling
- •VeloVI: RNA velocity analysis
- •contrastiveVI: Perturbation effect isolation
2. Chromatin Accessibility (ATAC-seq)
Models for analyzing single-cell chromatin data. See references/models-atac-seq.md for:
- •PeakVI: Peak-based ATAC-seq analysis and integration
- •PoissonVI: Quantitative fragment count modeling
- •scBasset: Deep learning approach with motif analysis
3. Multimodal & Multi-omics Integration
Joint analysis of multiple data types. See references/models-multimodal.md for:
- •totalVI: CITE-seq protein and RNA joint modeling
- •MultiVI: Paired and unpaired multi-omic integration
- •MrVI: Multi-resolution cross-sample analysis
4. Spatial Transcriptomics
Spatially-resolved transcriptomics analysis. See references/models-spatial.md for:
- •DestVI: Multi-resolution spatial deconvolution
- •Stereoscope: Cell type deconvolution
- •Tangram: Spatial mapping and integration
- •scVIVA: Cell-environment relationship analysis
5. Specialized Modalities
Additional specialized analysis tools. See references/models-specialized.md for:
- •MethylVI/MethylANVI: Single-cell methylation analysis
- •CytoVI: Flow/mass cytometry batch correction
- •Solo: Doublet detection
- •CellAssign: Marker-based cell type annotation
Typical Workflow
All scvi-tools models follow a consistent API pattern:
# 1. Load and preprocess data (AnnData format)
import scvi
import scanpy as sc
adata = scvi.data.heart_cell_atlas_subsampled()
sc.pp.filter_genes(adata, min_counts=3)
sc.pp.highly_variable_genes(adata, n_top_genes=1200)
# 2. Register data with model (specify layers, covariates)
scvi.model.SCVI.setup_anndata(
adata,
layer="counts", # Use raw counts, not log-normalized
batch_key="batch",
categorical_covariate_keys=["donor"],
continuous_covariate_keys=["percent_mito"]
)
# 3. Create and train model
model = scvi.model.SCVI(adata)
model.train()
# 4. Extract latent representations and normalized values
latent = model.get_latent_representation()
normalized = model.get_normalized_expression(library_size=1e4)
# 5. Store in AnnData for downstream analysis
adata.obsm["X_scVI"] = latent
adata.layers["scvi_normalized"] = normalized
# 6. Downstream analysis with scanpy
sc.pp.neighbors(adata, use_rep="X_scVI")
sc.tl.umap(adata)
sc.tl.leiden(adata)
Key Design Principles:
- •Raw counts required: Models expect unnormalized count data for optimal performance
- •Unified API: Consistent interface across all models (setup → train → extract)
- •AnnData-centric: Seamless integration with the scanpy ecosystem
- •GPU acceleration: Automatic utilization of available GPUs
- •Batch correction: Handle technical variation through covariate registration
Common Analysis Tasks
Differential Expression
Probabilistic DE analysis using the learned generative models:
de_results = model.differential_expression(
groupby="cell_type",
group1="TypeA",
group2="TypeB",
mode="change", # Use composite hypothesis testing
delta=0.25 # Minimum effect size threshold
)
See references/differential-expression.md for detailed methodology and interpretation.
Model Persistence
Save and load trained models:
# Save model
model.save("./model_directory", overwrite=True)
# Load model
model = scvi.model.SCVI.load("./model_directory", adata=adata)
Batch Correction and Integration
Integrate datasets across batches or studies:
# Register batch information scvi.model.SCVI.setup_anndata(adata, batch_key="study") # Model automatically learns batch-corrected representations model = scvi.model.SCVI(adata) model.train() latent = model.get_latent_representation() # Batch-corrected
Theoretical Foundations
scvi-tools is built on:
- •Variational inference: Approximate posterior distributions for scalable Bayesian inference
- •Deep generative models: VAE architectures that learn complex data distributions
- •Amortized inference: Shared neural networks for efficient learning across cells
- •Probabilistic modeling: Principled uncertainty quantification and statistical testing
See references/theoretical-foundations.md for detailed background on the mathematical framework.
Additional Resources
- •Workflows:
references/workflows.mdcontains common workflows, best practices, hyperparameter tuning, and GPU optimization - •Model References: Detailed documentation for each model category in the
references/directory - •Official Documentation: https://docs.scvi-tools.org/en/stable/
- •Tutorials: https://docs.scvi-tools.org/en/stable/tutorials/index.html
- •API Reference: https://docs.scvi-tools.org/en/stable/api/index.html
Installation
uv pip install scvi-tools # For GPU support uv pip install scvi-tools[cuda]
Best Practices
- •Use raw counts: Always provide unnormalized count data to models
- •Filter genes: Remove low-count genes before analysis (e.g.,
min_counts=3) - •Register covariates: Include known technical factors (batch, donor, etc.) in
setup_anndata - •Feature selection: Use highly variable genes for improved performance
- •Model saving: Always save trained models to avoid retraining
- •GPU usage: Enable GPU acceleration for large datasets (
accelerator="gpu") - •Scanpy integration: Store outputs in AnnData objects for downstream analysis