Quality control and assessment for proteomics data. Use when evaluating proteomics data quality before downstream analysis. Covers sample metrics, missing value patterns, replicate correlation, batch effects, and intensity distributions.
Install with the open skills CLI (global, non-interactive — available in every Claude Code session):
npx skills add FreedomIntelligence/OpenClaw-Medical-Skills --skill "bio-proteomics-proteomics-qc" -g -a claude-code -yOr manually — clone and copy the skill directory (SKILL.md + companion files):
git clone --depth 1 https://github.com/FreedomIntelligence/OpenClaw-Medical-Skills /tmp/OpenClaw-Medical-Skills && cp -r /tmp/OpenClaw-Medical-Skills/skills/bio-proteomics-proteomics-qc ~/.claude/skills/bio-proteomics-proteomics-qcThis skill is a directory: SKILL.md is the entry point; the files below ship with it.
---
name: bio-proteomics-proteomics-qc
description: Quality control and assessment for proteomics data. Use when evaluating proteomics data quality before downstream analysis. Covers sample metrics, missing value patterns, replicate correlation, batch effects, and intensity distributions.
tool_type: mixed
primary_tool: pandas
---
## Version Compatibility
Reference examples tested with: ggplot2 3.5+, limma 3.58+, matplotlib 3.8+, numpy 1.26+, pandas 2.2+, scikit-learn 1.4+, scipy 1.12+, seaborn 0.13+
Before using code patterns, verify installed versions match. If versions differ:
- Python: `pip show <package>` then `help(module.function)` to check signatures
- R: `packageVersion('<pkg>')` then `?function_name` to verify parameters
If code throws ImportError, AttributeError, or TypeError, introspect the installed
package and adapt the example to match the actual API rather than retrying.
# Proteomics Quality Control
**"Check the quality of my proteomics data"** → Assess data quality through identification rates, missing value patterns, replicate correlation, intensity distributions, and batch effect detection before downstream analysis.
- Python: `pandas` + `matplotlib`/`seaborn` for QC metrics and visualization
- R: `limma::plotMDS()`, correlation heatmaps, CV distributions
## Sample Quality Metrics
```python
import pandas as pd
import numpy as np
def sample_qc_metrics(intensity_matrix):
'''Calculate per-sample QC metrics'''
metrics = pd.DataFrame(index=intensity_matrix.columns)
metrics['n_proteins'] = intensity_matrix.notna().sum()
metrics['median_intensity'] = intensity_matrix.median()
metrics['mean_intensity'] = intensity_matrix.mean()
metrics['cv'] = intensity_matrix.std() / intensity_matrix.mean()
metrics['missing_pct'] = 100 * intensity_matrix.isna().sum() / len(intensity_matrix)
return metrics
qc = sample_qc_metrics(log2_intensities)
print(qc)
```
## Replicate Correlation
```python
import seaborn as sns
import matplotlib.pyplot as plt
from scipy.stats import pearsonr
def replicate_correlation(intensity_matrix, sample_groups):
'''Calculate within-group correlations'''
corr_matrix = intensity_matrix.corr(method='pearson')
# Mask for within-group comparisons
results = []
for group in sample_groups.unique():
group_samples = sample_groups[sample_groups == group].index
for i, s1 in enumerate(group_samples):
for s2 in group_samples[i+1:]:
r = corr_matrix.loc[s1, s2]
results.append({'group': group, 'sample1': s1, 'sample2': s2, 'correlation': r})
return pd.DataFrame(results)
# Heatmap
sns.clustermap(intensity_matrix.corr(), cmap='RdBu_r', center=0, vmin=-1, vmax=1,
figsize=(10, 10), annot=False)
plt.savefig('correlation_heatmap.pdf')
```
## Missing Value Patterns
```python
import missingno as msno
def analyze_missing_patterns(intensity_matrix):
'''Analyze missing value patterns'''
# Missing value matrix visualization
msno.matrix(intensity_matrix, figsize=(12, 8))
plt.savefig('missing_pattern.pdf')
# Missing by sample
missing_per_sample = intensity_matrix.isna().sum() / len(intensity_matrix) * 100
# Missing by protein
missing_per_protein = intensity_matrix.isna().sum(axis=1) / intensity_matrix.shape[1] * 100
# Check for systematic patterns
return {'per_sample': missing_per_sample, 'per_protein': missing_per_protein}
```
## Batch Effect Detection with PCA
**Goal:** Detect batch effects in proteomics data by testing whether processing batches explain significant variance in the principal components.
**Approach:** Impute missing values, scale the intensity matrix, run PCA, then test the association of each top PC with batch labels using one-way ANOVA.
```python
from sklearn.preprocessing import StandardScaler
from sklearn.decomposition import PCA
def detect_batch_effects(intensity_matrix, sample_info, batch_col='batch'):
'''PCA to detect batch effects'''
# Impute for PCA (temporary)
imputed = intensity_matrix.fillna(intensity_matrix.median())
scaled = StandardScaler().fit_transform(imputed.T)
pca = PCA(n_components=5)
pcs = pca.fit_transform(scaled)
pc_df = pd.DataFrame(pcs, columns=[f'PC{i+1}' for i in range(5)], index=intensity_matrix.columns)
pc_df = pc_df.join(sample_info)
# Check batch association with PCs
from scipy.stats import f_oneway
for pc in ['PC1', 'PC2', 'PC3']:
groups = [pc_df[pc_df[batch_col] == b][pc] for b in pc_df[batch_col].unique()]
stat, pval = f_oneway(*groups)
print(f'{pc} ~ {batch_col}: F={stat:.2f}, p={pval:.4f}')
return pc_df, pca.explained_variance_ratio_
```
## R: QC with limma
```r
library(limma)
library(ggplot2)
# Intensity distribution
plotDensities(protein_matrix, legend = FALSE, main = 'Intensity Distributions')
# MA plots between samples
for (i in 2:ncol(protein_matrix)) {
plotMA(protein_matrix[, c(1, i)], main = paste('MA:', colnames(protein_matrix)[i]))
}
# MDS plot (similar to PCA)
plotMDS(protein_matrix, col = as.numeric(sample_info$condition))
```
## Coefficient of Variation
```python
def calculate_cv(intensity_matrix, sample_groups):
'''Calculate CV within groups'''
cv_results = []
for group in sample_groups.unique():
group_samples = sample_groups[sample_groups == group].index
group_data = intensity_matrix[group_samples]
# CV per protein
cv = group_data.std(axis=1) / group_data.mean(axis=1) * 100
cv_results.append({'group': group, 'median_cv': cv.median(), 'mean_cv': cv.mean()})
return pd.DataFrame(cv_results)
# Technical replicates should have CV < 20%
# Biological replicates typically 20-40%
```
## Digestion Efficiency
```python
def check_digestion(evidence_df):
'''Check digestion efficiency from MaxQuant evidence.txt'''
# Missed cleavages distribution
mc_dist = evidence_df['Missed cleavages'].value_counts(normalize=True) * 100
print('Missed cleavage distribution:')
print(mc_dist)
# Good digestion: >80% with 0 missed cleavages
if mc_dist.get(0, 0) < 80:
print('Warning: Poor digestion efficiency (<80% fully cleaved)')
return mc_dist
```
## QC Report Summary
```python
def generate_qc_report(intensity_matrix, sample_info):
'''Generate comprehensive QC summary'''
report = {
'n_samples': intensity_matrix.shape[1],
'n_proteins': intensity_matrix.shape[0],
'median_proteins_per_sample': intensity_matrix.notna().sum().median(),
'overall_missing_pct': 100 * intensity_matrix.isna().sum().sum() / intensity_matrix.size,
'median_correlation': intensity_matrix.corr().values[np.triu_indices_from(intensity_matrix.corr(), k=1)].mean(),
}
# Flags
report['flags'] = []
if report['overall_missing_pct'] > 30:
report['flags'].append('High missing values (>30%)')
if report['median_correlation'] < 0.9:
report['flags'].append('Low replicate correlation (<0.9)')
return report
```
## Related Skills
- data-import - Load data before QC
- quantification - Normalization after QC
- differential-abundance - Analysis after QC passes
- data-visualization/heatmaps-clustering - QC heatmaps
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