scanpy
Single-cell RNA-seq analysis. Load .h5ad/10X data, QC, normalization, PCA/UMAP/t-SNE, Leiden clustering, marker genes, cell type annotation, trajectory, for scRNA-seq analysis.
Best use case
scanpy is best used when you need a repeatable AI agent workflow instead of a one-off prompt. It is especially useful for teams working in multi. Single-cell RNA-seq analysis. Load .h5ad/10X data, QC, normalization, PCA/UMAP/t-SNE, Leiden clustering, marker genes, cell type annotation, trajectory, for scRNA-seq analysis.
Single-cell RNA-seq analysis. Load .h5ad/10X data, QC, normalization, PCA/UMAP/t-SNE, Leiden clustering, marker genes, cell type annotation, trajectory, for scRNA-seq analysis.
Users should expect a more consistent workflow output, faster repeated execution, and less time spent rewriting prompts from scratch.
Practical example
Example input
Use the "scanpy" skill to help with this workflow task. Context: Single-cell RNA-seq analysis. Load .h5ad/10X data, QC, normalization, PCA/UMAP/t-SNE, Leiden clustering, marker genes, cell type annotation, trajectory, for scRNA-seq analysis.
Example output
A structured workflow result with clearer steps, more consistent formatting, and an output that is easier to reuse in the next run.
When to use this skill
- Use this skill when you want a reusable workflow rather than writing the same prompt again and again.
When not to use this skill
- Do not use this when you only need a one-off answer and do not need a reusable workflow.
- Do not use it if you cannot install or maintain the related files, repository context, or supporting tools.
Installation
Claude Code / Cursor / Codex
Manual Installation
- Download SKILL.md from GitHub
- Place it in
.claude/skills/scanpy/SKILL.mdinside your project - Restart your AI agent — it will auto-discover the skill
How scanpy Compares
| Feature / Agent | scanpy | Standard Approach |
|---|---|---|
| Platform Support | Not specified | Limited / Varies |
| Context Awareness | High | Baseline |
| Installation Complexity | Unknown | N/A |
Frequently Asked Questions
What does this skill do?
Single-cell RNA-seq analysis. Load .h5ad/10X data, QC, normalization, PCA/UMAP/t-SNE, Leiden clustering, marker genes, cell type annotation, trajectory, for scRNA-seq analysis.
Where can I find the source code?
You can find the source code on GitHub using the link provided at the top of the page.
SKILL.md Source
# Scanpy: Single-Cell Analysis
## Overview
Scanpy is a scalable Python toolkit for analyzing single-cell RNA-seq data, built on AnnData. Apply this skill for complete single-cell workflows including quality control, normalization, dimensionality reduction, clustering, marker gene identification, visualization, and trajectory analysis.
## When to Use This Skill
This skill should be used when:
- Analyzing single-cell RNA-seq data (.h5ad, 10X, CSV formats)
- Performing quality control on scRNA-seq datasets
- Creating UMAP, t-SNE, or PCA visualizations
- Identifying cell clusters and finding marker genes
- Annotating cell types based on gene expression
- Conducting trajectory inference or pseudotime analysis
- Generating publication-quality single-cell plots
## Quick Start
### Basic Import and Setup
```python
import scanpy as sc
import pandas as pd
import numpy as np
# Configure settings
sc.settings.verbosity = 3
sc.settings.set_figure_params(dpi=80, facecolor='white')
sc.settings.figdir = './figures/'
```
### Loading Data
```python
# From 10X Genomics
adata = sc.read_10x_mtx('path/to/data/')
adata = sc.read_10x_h5('path/to/data.h5')
# From h5ad (AnnData format)
adata = sc.read_h5ad('path/to/data.h5ad')
# From CSV
adata = sc.read_csv('path/to/data.csv')
```
### Understanding AnnData Structure
The AnnData object is the core data structure in scanpy:
```python
adata.X # Expression matrix (cells × genes)
adata.obs # Cell metadata (DataFrame)
adata.var # Gene metadata (DataFrame)
adata.uns # Unstructured annotations (dict)
adata.obsm # Multi-dimensional cell data (PCA, UMAP)
adata.raw # Raw data backup
# Access cell and gene names
adata.obs_names # Cell barcodes
adata.var_names # Gene names
```
## Standard Analysis Workflow
### 1. Quality Control
Identify and filter low-quality cells and genes:
```python
# Identify mitochondrial genes
adata.var['mt'] = adata.var_names.str.startswith('MT-')
# Calculate QC metrics
sc.pp.calculate_qc_metrics(adata, qc_vars=['mt'], inplace=True)
# Visualize QC metrics
sc.pl.violin(adata, ['n_genes_by_counts', 'total_counts', 'pct_counts_mt'],
jitter=0.4, multi_panel=True)
# Filter cells and genes
sc.pp.filter_cells(adata, min_genes=200)
sc.pp.filter_genes(adata, min_cells=3)
adata = adata[adata.obs.pct_counts_mt < 5, :] # Remove high MT% cells
```
**Use the QC script for automated analysis:**
```bash
python scripts/qc_analysis.py input_file.h5ad --output filtered.h5ad
```
### 2. Normalization and Preprocessing
```python
# Normalize to 10,000 counts per cell
sc.pp.normalize_total(adata, target_sum=1e4)
# Log-transform
sc.pp.log1p(adata)
# Save raw counts for later
adata.raw = adata
# Identify highly variable genes
sc.pp.highly_variable_genes(adata, n_top_genes=2000)
sc.pl.highly_variable_genes(adata)
# Subset to highly variable genes
adata = adata[:, adata.var.highly_variable]
# Regress out unwanted variation
sc.pp.regress_out(adata, ['total_counts', 'pct_counts_mt'])
# Scale data
sc.pp.scale(adata, max_value=10)
```
### 3. Dimensionality Reduction
```python
# PCA
sc.tl.pca(adata, svd_solver='arpack')
sc.pl.pca_variance_ratio(adata, log=True) # Check elbow plot
# Compute neighborhood graph
sc.pp.neighbors(adata, n_neighbors=10, n_pcs=40)
# UMAP for visualization
sc.tl.umap(adata)
sc.pl.umap(adata, color='leiden')
# Alternative: t-SNE
sc.tl.tsne(adata)
```
### 4. Clustering
```python
# Leiden clustering (recommended)
sc.tl.leiden(adata, resolution=0.5)
sc.pl.umap(adata, color='leiden', legend_loc='on data')
# Try multiple resolutions to find optimal granularity
for res in [0.3, 0.5, 0.8, 1.0]:
sc.tl.leiden(adata, resolution=res, key_added=f'leiden_{res}')
```
### 5. Marker Gene Identification
```python
# Find marker genes for each cluster
sc.tl.rank_genes_groups(adata, 'leiden', method='wilcoxon')
# Visualize results
sc.pl.rank_genes_groups(adata, n_genes=25, sharey=False)
sc.pl.rank_genes_groups_heatmap(adata, n_genes=10)
sc.pl.rank_genes_groups_dotplot(adata, n_genes=5)
# Get results as DataFrame
markers = sc.get.rank_genes_groups_df(adata, group='0')
```
### 6. Cell Type Annotation
```python
# Define marker genes for known cell types
marker_genes = ['CD3D', 'CD14', 'MS4A1', 'NKG7', 'FCGR3A']
# Visualize markers
sc.pl.umap(adata, color=marker_genes, use_raw=True)
sc.pl.dotplot(adata, var_names=marker_genes, groupby='leiden')
# Manual annotation
cluster_to_celltype = {
'0': 'CD4 T cells',
'1': 'CD14+ Monocytes',
'2': 'B cells',
'3': 'CD8 T cells',
}
adata.obs['cell_type'] = adata.obs['leiden'].map(cluster_to_celltype)
# Visualize annotated types
sc.pl.umap(adata, color='cell_type', legend_loc='on data')
```
### 7. Save Results
```python
# Save processed data
adata.write('results/processed_data.h5ad')
# Export metadata
adata.obs.to_csv('results/cell_metadata.csv')
adata.var.to_csv('results/gene_metadata.csv')
```
## Common Tasks
### Creating Publication-Quality Plots
```python
# Set high-quality defaults
sc.settings.set_figure_params(dpi=300, frameon=False, figsize=(5, 5))
sc.settings.file_format_figs = 'pdf'
# UMAP with custom styling
sc.pl.umap(adata, color='cell_type',
palette='Set2',
legend_loc='on data',
legend_fontsize=12,
legend_fontoutline=2,
frameon=False,
save='_publication.pdf')
# Heatmap of marker genes
sc.pl.heatmap(adata, var_names=genes, groupby='cell_type',
swap_axes=True, show_gene_labels=True,
save='_markers.pdf')
# Dot plot
sc.pl.dotplot(adata, var_names=genes, groupby='cell_type',
save='_dotplot.pdf')
```
Refer to `references/plotting_guide.md` for comprehensive visualization examples.
### Trajectory Inference
```python
# PAGA (Partition-based graph abstraction)
sc.tl.paga(adata, groups='leiden')
sc.pl.paga(adata, color='leiden')
# Diffusion pseudotime
adata.uns['iroot'] = np.flatnonzero(adata.obs['leiden'] == '0')[0]
sc.tl.dpt(adata)
sc.pl.umap(adata, color='dpt_pseudotime')
```
### Differential Expression Between Conditions
```python
# Compare treated vs control within cell types
adata_subset = adata[adata.obs['cell_type'] == 'T cells']
sc.tl.rank_genes_groups(adata_subset, groupby='condition',
groups=['treated'], reference='control')
sc.pl.rank_genes_groups(adata_subset, groups=['treated'])
```
### Gene Set Scoring
```python
# Score cells for gene set expression
gene_set = ['CD3D', 'CD3E', 'CD3G']
sc.tl.score_genes(adata, gene_set, score_name='T_cell_score')
sc.pl.umap(adata, color='T_cell_score')
```
### Batch Correction
```python
# ComBat batch correction
sc.pp.combat(adata, key='batch')
# Alternative: use Harmony or scVI (separate packages)
```
## Key Parameters to Adjust
### Quality Control
- `min_genes`: Minimum genes per cell (typically 200-500)
- `min_cells`: Minimum cells per gene (typically 3-10)
- `pct_counts_mt`: Mitochondrial threshold (typically 5-20%)
### Normalization
- `target_sum`: Target counts per cell (default 1e4)
### Feature Selection
- `n_top_genes`: Number of HVGs (typically 2000-3000)
- `min_mean`, `max_mean`, `min_disp`: HVG selection parameters
### Dimensionality Reduction
- `n_pcs`: Number of principal components (check variance ratio plot)
- `n_neighbors`: Number of neighbors (typically 10-30)
### Clustering
- `resolution`: Clustering granularity (0.4-1.2, higher = more clusters)
## Common Pitfalls and Best Practices
1. **Always save raw counts**: `adata.raw = adata` before filtering genes
2. **Check QC plots carefully**: Adjust thresholds based on dataset quality
3. **Use Leiden over Louvain**: More efficient and better results
4. **Try multiple clustering resolutions**: Find optimal granularity
5. **Validate cell type annotations**: Use multiple marker genes
6. **Use `use_raw=True` for gene expression plots**: Shows original counts
7. **Check PCA variance ratio**: Determine optimal number of PCs
8. **Save intermediate results**: Long workflows can fail partway through
## Bundled Resources
### scripts/qc_analysis.py
Automated quality control script that calculates metrics, generates plots, and filters data:
```bash
python scripts/qc_analysis.py input.h5ad --output filtered.h5ad \
--mt-threshold 5 --min-genes 200 --min-cells 3
```
### references/standard_workflow.md
Complete step-by-step workflow with detailed explanations and code examples for:
- Data loading and setup
- Quality control with visualization
- Normalization and scaling
- Feature selection
- Dimensionality reduction (PCA, UMAP, t-SNE)
- Clustering (Leiden, Louvain)
- Marker gene identification
- Cell type annotation
- Trajectory inference
- Differential expression
Read this reference when performing a complete analysis from scratch.
### references/api_reference.md
Quick reference guide for scanpy functions organized by module:
- Reading/writing data (`sc.read_*`, `adata.write_*`)
- Preprocessing (`sc.pp.*`)
- Tools (`sc.tl.*`)
- Plotting (`sc.pl.*`)
- AnnData structure and manipulation
- Settings and utilities
Use this for quick lookup of function signatures and common parameters.
### references/plotting_guide.md
Comprehensive visualization guide including:
- Quality control plots
- Dimensionality reduction visualizations
- Clustering visualizations
- Marker gene plots (heatmaps, dot plots, violin plots)
- Trajectory and pseudotime plots
- Publication-quality customization
- Multi-panel figures
- Color palettes and styling
Consult this when creating publication-ready figures.
### assets/analysis_template.py
Complete analysis template providing a full workflow from data loading through cell type annotation. Copy and customize this template for new analyses:
```bash
cp assets/analysis_template.py my_analysis.py
# Edit parameters and run
python my_analysis.py
```
The template includes all standard steps with configurable parameters and helpful comments.
## Additional Resources
- **Official scanpy documentation**: https://scanpy.readthedocs.io/
- **Scanpy tutorials**: https://scanpy-tutorials.readthedocs.io/
- **scverse ecosystem**: https://scverse.org/ (related tools: squidpy, scvi-tools, cellrank)
- **Best practices**: Luecken & Theis (2019) "Current best practices in single-cell RNA-seq"
## Tips for Effective Analysis
1. **Start with the template**: Use `assets/analysis_template.py` as a starting point
2. **Run QC script first**: Use `scripts/qc_analysis.py` for initial filtering
3. **Consult references as needed**: Load workflow and API references into context
4. **Iterate on clustering**: Try multiple resolutions and visualization methods
5. **Validate biologically**: Check marker genes match expected cell types
6. **Document parameters**: Record QC thresholds and analysis settings
7. **Save checkpoints**: Write intermediate results at key stepsRelated Skills
azure-quotas
Check/manage Azure quotas and usage across providers. For deployment planning, capacity validation, region selection. WHEN: "check quotas", "service limits", "current usage", "request quota increase", "quota exceeded", "validate capacity", "regional availability", "provisioning limits", "vCPU limit", "how many vCPUs available in my subscription".
raindrop-io
Manage Raindrop.io bookmarks with AI assistance. Save and organize bookmarks, search your collection, manage reading lists, and organize research materials. Use when working with bookmarks, web research, reading lists, or when user mentions Raindrop.io.
zlibrary-to-notebooklm
自动从 Z-Library 下载书籍并上传到 Google NotebookLM。支持 PDF/EPUB 格式,自动转换,一键创建知识库。
discover-skills
当你发现当前可用的技能都不够合适(或用户明确要求你寻找技能)时使用。本技能会基于任务目标和约束,给出一份精简的候选技能清单,帮助你选出最适配当前任务的技能。
web-performance-seo
Fix PageSpeed Insights/Lighthouse accessibility "!" errors caused by contrast audit failures (CSS filters, OKLCH/OKLAB, low opacity, gradient text, image backgrounds). Use for accessibility-driven SEO/performance debugging and remediation.
project-to-obsidian
将代码项目转换为 Obsidian 知识库。当用户提到 obsidian、项目文档、知识库、分析项目、转换项目 时激活。 【激活后必须执行】: 1. 先完整阅读本 SKILL.md 文件 2. 理解 AI 写入规则(默认到 00_Inbox/AI/、追加式、统一 Schema) 3. 执行 STEP 0: 使用 AskUserQuestion 询问用户确认 4. 用户确认后才开始 STEP 1 项目扫描 5. 严格按 STEP 0 → 1 → 2 → 3 → 4 顺序执行 【禁止行为】: - 禁止不读 SKILL.md 就开始分析项目 - 禁止跳过 STEP 0 用户确认 - 禁止直接在 30_Resources 创建(先到 00_Inbox/AI/) - 禁止自作主张决定输出位置
obsidian-helper
Obsidian 智能笔记助手。当用户提到 obsidian、日记、笔记、知识库、capture、review 时激活。 【激活后必须执行】: 1. 先完整阅读本 SKILL.md 文件 2. 理解 AI 写入三条硬规矩(00_Inbox/AI/、追加式、白名单字段) 3. 按 STEP 0 → STEP 1 → ... 顺序执行 4. 不要跳过任何步骤,不要自作主张 【禁止行为】: - 禁止不读 SKILL.md 就开始工作 - 禁止跳过用户确认步骤 - 禁止在非 00_Inbox/AI/ 位置创建新笔记(除非用户明确指定)
internationalizing-websites
Adds multi-language support to Next.js websites with proper SEO configuration including hreflang tags, localized sitemaps, and language-specific content. Use when adding new languages, setting up i18n, optimizing for international SEO, or when user mentions localization, translation, multi-language, or specific languages like Japanese, Korean, Chinese.
google-official-seo-guide
Official Google SEO guide covering search optimization, best practices, Search Console, crawling, indexing, and improving website search visibility based on official Google documentation
github-release-assistant
Generate bilingual GitHub release documentation (README.md + README.zh.md) from repo metadata and user input, and guide release prep with git add/commit/push. Use when the user asks to write or polish README files, create bilingual docs, prepare a GitHub release, or mentions release assistant/README generation.
doc-sync-tool
自动同步项目中的 Agents.md、claude.md 和 gemini.md 文件,保持内容一致性。支持自动监听和手动触发。
deploying-to-production
Automate creating a GitHub repository and deploying a web project to Vercel. Use when the user asks to deploy a website/app to production, publish a project, or set up GitHub + Vercel deployment.