Automated cell type annotation using reference-based methods including CellTypist, scPred, SingleR, and Azimuth for consistent, reproducible cell labeling. Use when automatically annotating cell types using reference datasets.
apm install @majiayu000/bio-single-cell-cell-annotation
[](https://apm-p1ls2dz87-atlamors-projects.vercel.app/packages/@majiayu000/bio-single-cell-cell-annotation)---
name: bio-single-cell-cell-annotation
description: Automated cell type annotation using reference-based methods including CellTypist, scPred, SingleR, and Azimuth for consistent, reproducible cell labeling. Use when automatically annotating cell types using reference datasets.
tool_type: mixed
primary_tool: CellTypist
---
# Automated Cell Type Annotation
## CellTypist (Python)
```python
import celltypist
import scanpy as sc
adata = sc.read_h5ad('adata_processed.h5ad')
# List available models
celltypist.models.models_description()
# Download model
celltypist.models.download_models(model='Immune_All_Low.pkl')
# Load model
model = celltypist.models.Model.load(model='Immune_All_Low.pkl')
# Predict cell types
predictions = celltypist.annotate(adata, model=model, majority_voting=True)
# Add predictions to adata
adata = predictions.to_adata()
# Access predictions
adata.obs['cell_type_celltypist'] = adata.obs['majority_voting']
adata.obs['cell_type_confidence'] = adata.obs['conf_score']
# Visualize
sc.pl.umap(adata, color=['cell_type_celltypist', 'conf_score'])
```
## CellTypist with Custom Model
```python
# Train custom model
new_model = celltypist.train(adata_reference, labels='cell_type', n_jobs=10,
feature_selection=True, use_SGD=True)
# Save model
new_model.write('custom_model.pkl')
# Use custom model
predictions = celltypist.annotate(adata_query, model='custom_model.pkl')
```
## SingleR (R)
```r
library(SingleR)
library(celldex)
library(Seurat)
library(SingleCellExperiment)
seurat_obj <- readRDS('seurat_processed.rds')
sce <- as.SingleCellExperiment(seurat_obj)
# Load reference (multiple available)
ref <- celldex::HumanPrimaryCellAtlasData()
# Other options:
# ref <- celldex::BlueprintEncodeData()
# ref <- celldex::MonacoImmuneData()
# ref <- celldex::ImmGenData() # mouse
# Run SingleR
pred <- SingleR(test = sce, ref = ref, labels = ref$label.main, de.method = 'wilcox')
# Add to Seurat
seurat_obj$SingleR_labels <- pred$labels
seurat_obj$SingleR_pruned <- pred$pruned.labels
# Check annotation quality
plotScoreHeatmap(pred)
plotDeltaDistribution(pred)
```
## SingleR Fine Labels
```r
# Use fine-grained labels
pred_fine <- SingleR(test = sce, ref = ref, labels = ref$label.fine)
# Combine multiple references
ref1 <- celldex::BlueprintEncodeData()
ref2 <- celldex::MonacoImmuneData()
pred_combined <- SingleR(test = sce, ref = list(BP = ref1, Monaco = ref2),
labels = list(ref1$label.main, ref2$label.main))
```
## Azimuth (R/Seurat)
```r
library(Seurat)
library(Azimuth)
seurat_obj <- readRDS('seurat_processed.rds')
# Run Azimuth with PBMC reference
seurat_obj <- RunAzimuth(seurat_obj, reference = 'pbmcref')
# Available references: pbmcref, bonemarrowref, lungref, etc.
# Access predictions
seurat_obj$azimuth_labels <- seurat_obj$predicted.celltype.l2
seurat_obj$azimuth_score <- seurat_obj$predicted.celltype.l2.score
# Visualize
DimPlot(seurat_obj, group.by = 'azimuth_labels', label = TRUE) + NoLegend()
FeaturePlot(seurat_obj, features = 'predicted.celltype.l2.score')
```
## scPred (R)
```r
library(scPred)
library(Seurat)
# Train on reference
reference <- readRDS('reference_seurat.rds')
reference <- getFeatureSpace(reference, 'cell_type')
reference <- trainModel(reference)
# Get training probabilities
get_probabilities(reference)
get_scpred(reference)
# Plot model performance
plot_probabilities(reference)
# Predict on query
query <- readRDS('query_seurat.rds')
query <- scPredict(query, reference)
# Results
query$scpred_prediction
query$scpred_max
```
## Annotation Confidence Filtering
```python
# CellTypist: filter low confidence
high_conf = adata[adata.obs['conf_score'] > 0.5].copy()
# Flag uncertain cells
adata.obs['annotation_uncertain'] = adata.obs['conf_score'] < 0.3
```
```r
# SingleR: use pruned labels (low-quality removed)
seurat_obj$final_labels <- ifelse(is.na(pred$pruned.labels), 'Unknown', pred$labels)
# Azimuth: filter by score
seurat_obj$high_conf_labels <- ifelse(seurat_obj$predicted.celltype.l2.score > 0.7,
seurat_obj$predicted.celltype.l2, 'Low_confidence')
```
## Consensus Annotation
```r
# Combine multiple methods
annotations <- data.frame(
SingleR = seurat_obj$SingleR_labels,
Azimuth = seurat_obj$azimuth_labels,
CellTypist = seurat_obj$celltypist_labels
)
# Majority vote
get_consensus <- function(x) {
tbl <- table(x)
if (max(tbl) >= 2) names(which.max(tbl)) else 'Ambiguous'
}
seurat_obj$consensus_label <- apply(annotations, 1, get_consensus)
```
## Compare Annotations
```python
import pandas as pd
from sklearn.metrics import adjusted_rand_score, normalized_mutual_info_score
# Compare two annotations
ari = adjusted_rand_score(adata.obs['manual_annotation'], adata.obs['celltypist'])
nmi = normalized_mutual_info_score(adata.obs['manual_annotation'], adata.obs['celltypist'])
# Confusion matrix
pd.crosstab(adata.obs['manual_annotation'], adata.obs['celltypist'])
```
## Marker-Based Validation
```r
# Validate predictions with known markers
canonical_markers <- list(
T_cell = c('CD3D', 'CD3E', 'CD4', 'CD8A'),
B_cell = c('CD19', 'MS4A1', 'CD79A'),
Monocyte = c('CD14', 'LYZ', 'S100A8'),
NK = c('NKG7', 'GNLY', 'NCAM1')
)
# Check marker expression per predicted type
DotPlot(seurat_obj, features = unlist(canonical_markers), group.by = 'predicted_labels') +
RotatedAxis()
```
## Related Skills
- single-cell/clustering-annotation - Manual marker-based annotation
- single-cell/cell-communication - Use annotated types for CCC
- single-cell/trajectory-inference - Trajectory on annotated data