bio-spatial-transcriptomics-spatial-visualization
$
npx mdskill add GPTomics/bioSkills/bio-spatial-transcriptomics-spatial-visualizationGenerate spatial tissue plots overlaying gene expression on histology images.
- Creates visualizations of spatial transcriptomics data with gene expression patterns.
- Depends on Squidpy and Scanpy Python libraries for spatial analysis.
- Executes code patterns matching installed package versions and API signatures.
- Delivers matplotlib images showing clusters, annotations, and expression scores.
SKILL.md
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---
name: bio-spatial-transcriptomics-spatial-visualization
description: Visualize spatial transcriptomics data using Squidpy and Scanpy. Create tissue plots with gene expression, clusters, and annotations overlaid on histology images. Use when visualizing spatial expression patterns.
tool_type: python
primary_tool: squidpy
---
## Version Compatibility
Reference examples tested with: matplotlib 3.8+, numpy 1.26+, scanpy 1.10+, squidpy 1.3+
Before using code patterns, verify installed versions match. If versions differ:
- Python: `pip show <package>` then `help(module.function)` to check signatures
If code throws ImportError, AttributeError, or TypeError, introspect the installed
package and adapt the example to match the actual API rather than retrying.
# Spatial Visualization
**"Plot gene expression on my tissue section"** → Overlay gene expression, cluster assignments, or continuous scores on spatial coordinates with optional histology image background.
- Python: `squidpy.pl.spatial_scatter(adata, color='gene')`, `scanpy.pl.spatial(adata, color='leiden')`
Create visualizations for spatial transcriptomics data.
## Required Imports
```python
import squidpy as sq
import scanpy as sc
import matplotlib.pyplot as plt
```
## Basic Spatial Plot
**Goal:** Create a spatial scatter plot with spots colored by a variable of interest.
**Approach:** Use Squidpy's `spatial_scatter` to overlay expression or metadata values on tissue coordinates.
```python
# Plot spots colored by a variable
sq.pl.spatial_scatter(adata, color='total_counts', size=1.3)
# Multiple variables
sq.pl.spatial_scatter(adata, color=['total_counts', 'n_genes_by_counts'], ncols=2)
```
## Plot with Scanpy
```python
# Scanpy's spatial plot
sc.pl.spatial(adata, color='leiden', spot_size=1.5)
# Multiple genes
sc.pl.spatial(adata, color=['GENE1', 'GENE2', 'GENE3'], ncols=3)
```
## Show Tissue Image
```python
# Plot with tissue background
sc.pl.spatial(adata, color='leiden', img_key='hires', alpha_img=0.5)
# Without tissue
sc.pl.spatial(adata, color='leiden', img_key=None)
```
## Customize Appearance
```python
# Adjust spot size and colors
sc.pl.spatial(
adata,
color='leiden',
spot_size=1.5,
palette='tab20',
title='Cluster assignments',
frameon=False,
)
```
## Gene Expression on Tissue
**Goal:** Visualize gene expression patterns overlaid on tissue spatial coordinates.
**Approach:** Plot individual or multiple genes using Scanpy's spatial plot with configurable colormaps and value ranges.
```python
# Single gene
sc.pl.spatial(adata, color='CD3D', cmap='viridis', vmin=0, vmax='p99')
# Multiple genes side by side
genes = ['CD3D', 'MS4A1', 'CD14', 'NKG7']
sc.pl.spatial(adata, color=genes, ncols=2, cmap='Reds', vmin=0)
```
## Expression with Colorbar Control
```python
fig, axes = plt.subplots(1, 2, figsize=(12, 5))
for ax, gene in zip(axes, ['GENE1', 'GENE2']):
sc.pl.spatial(adata, color=gene, ax=ax, show=False, vmin=0, vmax=5, cmap='viridis')
ax.set_title(gene)
plt.tight_layout()
plt.savefig('gene_expression.png', dpi=300)
```
## Compare Conditions/Samples
```python
# Split by sample
sc.pl.spatial(adata, color='leiden', groups=['sample1', 'sample2'], ncols=2)
# Or manually
samples = adata.obs['sample'].unique()
fig, axes = plt.subplots(1, len(samples), figsize=(5*len(samples), 5))
for ax, sample in zip(axes, samples):
adata_sub = adata[adata.obs['sample'] == sample]
sc.pl.spatial(adata_sub, color='leiden', ax=ax, show=False, title=sample)
plt.tight_layout()
```
## Overlay Annotations
```python
# Plot with custom annotations
fig, ax = plt.subplots(figsize=(8, 8))
sc.pl.spatial(adata, color='leiden', ax=ax, show=False)
# Add text annotations
for cluster in adata.obs['leiden'].unique():
mask = adata.obs['leiden'] == cluster
coords = adata.obsm['spatial'][mask].mean(axis=0)
ax.annotate(f'C{cluster}', coords, fontsize=12, ha='center')
plt.savefig('annotated.png', dpi=300)
```
## Co-expression Plot
**Goal:** Visualize co-localization of two genes using dual-channel RGB encoding.
**Approach:** Normalize expression of each gene to [0,1], assign to red and green channels, and render as a scatter plot.
```python
# Visualize co-expression of two genes
import numpy as np
gene1, gene2 = 'CD3D', 'CD8A'
expr1 = adata[:, gene1].X.toarray().flatten()
expr2 = adata[:, gene2].X.toarray().flatten()
# Create RGB image (red=gene1, green=gene2)
from matplotlib.colors import Normalize
norm = Normalize(vmin=0, vmax=np.percentile(np.concatenate([expr1, expr2]), 99))
colors = np.zeros((adata.n_obs, 3))
colors[:, 0] = norm(expr1) # Red channel
colors[:, 1] = norm(expr2) # Green channel
fig, ax = plt.subplots(figsize=(8, 8))
coords = adata.obsm['spatial']
ax.scatter(coords[:, 0], coords[:, 1], c=colors, s=10)
ax.set_aspect('equal')
ax.set_title(f'{gene1} (red) + {gene2} (green)')
plt.savefig('coexpression.png', dpi=300)
```
## Visualize Spatial Statistics
```python
# Plot Moran's I results
sq.pl.spatial_scatter(adata, color='GENE1', size=1.3)
# Plot neighborhood enrichment
sq.pl.nhood_enrichment(adata, cluster_key='leiden')
# Plot co-occurrence
sq.pl.co_occurrence(adata, cluster_key='leiden')
```
## Interactive Visualization with Napari
**Goal:** Explore spatial data interactively with zoomable tissue images and spot overlays.
**Approach:** Load tissue images and spot coordinates into napari layers for pan-and-zoom exploration.
```python
import napari
# Create viewer
viewer = napari.Viewer()
# Add tissue image
library_id = list(adata.uns['spatial'].keys())[0]
img = adata.uns['spatial'][library_id]['images']['hires']
viewer.add_image(img, name='tissue')
# Add spots
coords = adata.obsm['spatial']
scalef = adata.uns['spatial'][library_id]['scalefactors']['tissue_hires_scalef']
viewer.add_points(coords * scalef, size=10, name='spots')
napari.run()
```
## Save Publication-Quality Figures
**Goal:** Export high-resolution spatial plots suitable for publication.
**Approach:** Configure frameless spatial plots with appropriate DPI and save as both PDF and PNG.
```python
import matplotlib.pyplot as plt
fig, ax = plt.subplots(figsize=(8, 8))
sc.pl.spatial(
adata,
color='leiden',
ax=ax,
show=False,
frameon=False,
title='',
legend_loc='right margin',
)
plt.savefig('figure.pdf', dpi=300, bbox_inches='tight')
plt.savefig('figure.png', dpi=300, bbox_inches='tight')
```
## Multi-Panel Figure
**Goal:** Assemble a composite figure combining spatial plots, gene expression, UMAP, and violin plots.
**Approach:** Create a 2x3 subplot grid with different visualization types for comprehensive data overview.
```python
fig = plt.figure(figsize=(15, 10))
# Tissue with clusters
ax1 = fig.add_subplot(2, 3, 1)
sc.pl.spatial(adata, color='leiden', ax=ax1, show=False, title='Clusters')
# Gene 1
ax2 = fig.add_subplot(2, 3, 2)
sc.pl.spatial(adata, color='CD3D', ax=ax2, show=False, title='CD3D', cmap='Reds')
# Gene 2
ax3 = fig.add_subplot(2, 3, 3)
sc.pl.spatial(adata, color='MS4A1', ax=ax3, show=False, title='MS4A1', cmap='Blues')
# QC metrics
ax4 = fig.add_subplot(2, 3, 4)
sc.pl.spatial(adata, color='total_counts', ax=ax4, show=False, title='Total counts')
# UMAP
ax5 = fig.add_subplot(2, 3, 5)
sc.pl.umap(adata, color='leiden', ax=ax5, show=False, title='UMAP')
# Violin plot
ax6 = fig.add_subplot(2, 3, 6)
sc.pl.violin(adata, ['CD3D', 'MS4A1'], groupby='leiden', ax=ax6, show=False)
plt.tight_layout()
plt.savefig('multi_panel.png', dpi=300)
```
## Crop and Zoom
```python
# Zoom into a region
x_min, x_max = 2000, 4000
y_min, y_max = 2000, 4000
fig, ax = plt.subplots(figsize=(8, 8))
sc.pl.spatial(adata, color='leiden', ax=ax, show=False)
ax.set_xlim(x_min, x_max)
ax.set_ylim(y_max, y_min) # Note: y is inverted in images
plt.savefig('zoomed.png', dpi=300)
```
## Related Skills
- spatial-data-io - Load spatial data
- spatial-statistics - Compute statistics to visualize
- single-cell/clustering - Generate cluster labels
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