--- name: bio-spatial-transcriptomics-spatial-data-io description: Load spatial transcriptomics data from Visium, Xenium, MERFISH, Slide-seq, and other platforms using Squidpy and SpatialData. Read Space Ranger outputs, convert formats, and access spatial coordinates. Use when loading Visium, Xenium, MERFISH, or other spatial data. tool_type: python primary_tool: squidpy measurable_outcome: Execute skill workflow successfully with valid output within 15 minutes. allowed-tools: - read_file - run_shell_command --- # Spatial Data I/O Load and work with spatial transcriptomics data from various platforms. ## Required Imports ```python import squidpy as sq import scanpy as sc import anndata as ad import spatialdata as sd import spatialdata_io as sdio ``` ## Load 10X Visium Data ```python # Load Space Ranger output (standard method) adata = sq.read.visium('path/to/spaceranger/output/') print(f'Loaded {adata.n_obs} spots, {adata.n_vars} genes') # Spatial coordinates are in adata.obsm['spatial'] print(f"Spatial coords shape: {adata.obsm['spatial'].shape}") # Image is in adata.uns['spatial'] library_id = list(adata.uns['spatial'].keys())[0] print(f'Library ID: {library_id}') ``` ## Load Visium with Scanpy ```python # Alternative using Scanpy directly adata = sc.read_visium('path/to/spaceranger/output/') # Access tissue image img = adata.uns['spatial'][library_id]['images']['hires'] scale_factor = adata.uns['spatial'][library_id]['scalefactors']['tissue_hires_scalef'] ``` ## Load 10X Xenium Data ```python # Load Xenium output adata = sq.read.xenium('path/to/xenium/output/') print(f'Loaded {adata.n_obs} cells') # Xenium has single-cell resolution print(f"Cell coordinates: {adata.obsm['spatial'].shape}") ``` ## Load with SpatialData (Recommended for New Projects) ```python import spatialdata_io as sdio # Load Visium as SpatialData object sdata = sdio.visium('path/to/spaceranger/output/') print(sdata) # Load Xenium sdata = sdio.xenium('path/to/xenium/output/') # Access components table = sdata.tables['table'] # AnnData with expression shapes = sdata.shapes # Spatial shapes (spots, cells) images = sdata.images # Tissue images ``` ## Load MERFISH Data ```python # MERFISH (Vizgen MERSCOPE) sdata = sdio.merscope('path/to/merscope/output/') # Or as AnnData adata = sq.read.vizgen('path/to/vizgen/output/', counts_file='cell_by_gene.csv', meta_file='cell_metadata.csv') ``` ## Load Slide-seq Data ```python # Slide-seq / Slide-seqV2 adata = sq.read.slideseq('beads.csv', coordinates_file='coords.csv') ``` ## Load Nanostring CosMx ```python # CosMx spatial molecular imaging sdata = sdio.cosmx('path/to/cosmx/output/') ``` ## Load Stereo-seq Data ```python # Stereo-seq (BGI) sdata = sdio.stereoseq('path/to/stereoseq/output/') ``` ## Load from H5AD with Spatial Coordinates ```python # If you have h5ad with spatial already stored adata = sc.read_h5ad('spatial_data.h5ad') # Verify spatial data exists if 'spatial' in adata.obsm: print('Has spatial coordinates') if 'spatial' in adata.uns: print('Has image data') ``` ## Create Spatial AnnData from Scratch ```python import numpy as np import pandas as pd # Expression matrix X = np.random.poisson(5, size=(1000, 500)) # Spatial coordinates spatial_coords = np.random.rand(1000, 2) * 1000 # x, y in pixels # Create AnnData adata = ad.AnnData(X) adata.obs_names = [f'spot_{i}' for i in range(1000)] adata.var_names = [f'gene_{i}' for i in range(500)] adata.obsm['spatial'] = spatial_coords # Add minimal spatial metadata for Squidpy adata.uns['spatial'] = { 'library_id': { 'scalefactors': {'tissue_hires_scalef': 1.0, 'spot_diameter_fullres': 50}, } } ``` ## Access Spatial Coordinates ```python # Get coordinates as numpy array coords = adata.obsm['spatial'] x_coords = coords[:, 0] y_coords = coords[:, 1] # Get coordinates as DataFrame coord_df = pd.DataFrame(adata.obsm['spatial'], index=adata.obs_names, columns=['x', 'y']) ``` ## Access Tissue Images ```python # Get high-resolution image library_id = list(adata.uns['spatial'].keys())[0] hires_img = adata.uns['spatial'][library_id]['images']['hires'] lowres_img = adata.uns['spatial'][library_id]['images']['lowres'] # Scale factors scalef = adata.uns['spatial'][library_id]['scalefactors'] print(f"Hires scale: {scalef['tissue_hires_scalef']}") print(f"Spot diameter: {scalef['spot_diameter_fullres']}") ``` ## Convert Between Formats ```python # SpatialData to AnnData sdata = sdio.visium('path/to/data/') adata = sdata.tables['table'].copy() adata.obsm['spatial'] = np.array(sdata.shapes['spots'][['x', 'y']]) # Save as h5ad adata.write_h5ad('spatial_converted.h5ad') # Save SpatialData sdata.write('spatial_data.zarr') ``` ## Load Multiple Samples ```python # Load and concatenate multiple Visium samples samples = ['sample1', 'sample2', 'sample3'] adatas = [] for sample in samples: adata = sq.read.visium(f'data/{sample}/') adata.obs['sample'] = sample adatas.append(adata) # Concatenate adata_combined = ad.concat(adatas, label='sample', keys=samples) print(f'Combined: {adata_combined.n_obs} spots') ``` ## Subset by Spatial Region ```python # Select spots in a rectangular region x_min, x_max = 1000, 2000 y_min, y_max = 1500, 2500 coords = adata.obsm['spatial'] in_region = (coords[:, 0] >= x_min) & (coords[:, 0] <= x_max) & (coords[:, 1] >= y_min) & (coords[:, 1] <= y_max) adata_region = adata[in_region].copy() print(f'Selected {adata_region.n_obs} spots') ``` ## Related Skills - spatial-preprocessing - QC and normalization after loading - spatial-visualization - Plot spatial data - single-cell/data-io - Non-spatial scRNA-seq data loading