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Clinpgx Database

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name: clinpgx-database description: "Access ClinPGx pharmacogenomics data (successor to PharmGKB). Query gene-drug interactions, CPIC guidelines, allele functions, for precision medicine and genotype-guided dosing decisions."

ClinPGx Database

Overview

ClinPGx (Clinical Pharmacogenomics Database) is a comprehensive resource for clinical pharmacogenomics information, successor to PharmGKB. It consolidates data from PharmGKB, CPIC, and PharmCAT, providing curated information on how genetic variation affects medication response. Access gene-drug pairs, clinical guidelines, allele functions, and drug labels for precision medicine applications.

When to Use This Skill

This skill should be used when:

  • Gene-drug interactions: Querying how genetic variants affect drug metabolism, efficacy, or toxicity
  • CPIC guidelines: Accessing evidence-based clinical practice guidelines for pharmacogenetics
  • Allele information: Retrieving allele function, frequency, and phenotype data
  • Drug labels: Exploring FDA and other regulatory pharmacogenomic drug labeling
  • Pharmacogenomic annotations: Accessing curated literature on gene-drug-disease relationships
  • Clinical decision support: Using PharmDOG tool for phenoconversion and custom genotype interpretation
  • Precision medicine: Implementing pharmacogenomic testing in clinical practice
  • Drug metabolism: Understanding CYP450 and other pharmacogene functions
  • Personalized dosing: Finding genotype-guided dosing recommendations
  • Adverse drug reactions: Identifying genetic risk factors for drug toxicity

Installation and Setup

Python API Access

The ClinPGx REST API provides programmatic access to all database resources. Basic setup:

uv pip install requests

API Endpoint

BASE_URL = "https://api.clinpgx.org/v1/"

Rate Limits: - 2 requests per second maximum - Excessive requests will result in HTTP 429 (Too Many Requests) response

Authentication: Not required for basic access

Data License: Creative Commons Attribution-ShareAlike 4.0 International License

For substantial API use, notify the ClinPGx team at api@clinpgx.org

Core Capabilities

1. Gene Queries

Retrieve gene information including function, clinical annotations, and pharmacogenomic significance:

import requests

# Get gene details
response = requests.get("https://api.clinpgx.org/v1/gene/CYP2D6")
gene_data = response.json()

# Search for genes by name
response = requests.get("https://api.clinpgx.org/v1/gene",
                       params={"q": "CYP"})
genes = response.json()

Key pharmacogenes: - CYP450 enzymes: CYP2D6, CYP2C19, CYP2C9, CYP3A4, CYP3A5 - Transporters: SLCO1B1, ABCB1, ABCG2 - Other metabolizers: TPMT, DPYD, NUDT15, UGT1A1 - Receptors: OPRM1, HTR2A, ADRB1 - HLA genes: HLA-B, HLA-A

2. Drug and Chemical Queries

Retrieve drug information including pharmacogenomic annotations and mechanisms:

# Get drug details
response = requests.get("https://api.clinpgx.org/v1/chemical/PA448515")  # Warfarin
drug_data = response.json()

# Search drugs by name
response = requests.get("https://api.clinpgx.org/v1/chemical",
                       params={"name": "warfarin"})
drugs = response.json()

Drug categories with pharmacogenomic significance: - Anticoagulants (warfarin, clopidogrel) - Antidepressants (SSRIs, TCAs) - Immunosuppressants (tacrolimus, azathioprine) - Oncology drugs (5-fluorouracil, irinotecan, tamoxifen) - Cardiovascular drugs (statins, beta-blockers) - Pain medications (codeine, tramadol) - Antivirals (abacavir)

3. Gene-Drug Pair Queries

Access curated gene-drug relationships with clinical annotations:

# Get gene-drug pair information
response = requests.get("https://api.clinpgx.org/v1/geneDrugPair",
                       params={"gene": "CYP2D6", "drug": "codeine"})
pair_data = response.json()

# Get all pairs for a gene
response = requests.get("https://api.clinpgx.org/v1/geneDrugPair",
                       params={"gene": "CYP2C19"})
all_pairs = response.json()

Clinical annotation sources: - CPIC (Clinical Pharmacogenetics Implementation Consortium) - DPWG (Dutch Pharmacogenetics Working Group) - FDA (Food and Drug Administration) labels - Peer-reviewed literature summary annotations

4. CPIC Guidelines

Access evidence-based clinical practice guidelines:

# Get CPIC guideline
response = requests.get("https://api.clinpgx.org/v1/guideline/PA166104939")
guideline = response.json()

# List all CPIC guidelines
response = requests.get("https://api.clinpgx.org/v1/guideline",
                       params={"source": "CPIC"})
guidelines = response.json()

CPIC guideline components: - Gene-drug pairs covered - Clinical recommendations by phenotype - Evidence levels and strength ratings - Supporting literature - Downloadable PDFs and supplementary materials - Implementation considerations

Example guidelines: - CYP2D6-codeine (avoid in ultra-rapid metabolizers) - CYP2C19-clopidogrel (alternative therapy for poor metabolizers) - TPMT-azathioprine (dose reduction for intermediate/poor metabolizers) - DPYD-fluoropyrimidines (dose adjustment based on activity) - HLA-B*57:01-abacavir (avoid if positive)

5. Allele and Variant Information

Query allele function and frequency data:

# Get allele information
response = requests.get("https://api.clinpgx.org/v1/allele/CYP2D6*4")
allele_data = response.json()

# Get all alleles for a gene
response = requests.get("https://api.clinpgx.org/v1/allele",
                       params={"gene": "CYP2D6"})
alleles = response.json()

Allele information includes: - Functional status (normal, decreased, no function, increased, uncertain) - Population frequencies across ethnic groups - Defining variants (SNPs, indels, CNVs) - Phenotype assignment - References to PharmVar and other nomenclature systems

Phenotype categories: - Ultra-rapid metabolizer (UM): Increased enzyme activity - Normal metabolizer (NM): Normal enzyme activity - Intermediate metabolizer (IM): Reduced enzyme activity - Poor metabolizer (PM): Little to no enzyme activity

6. Variant Annotations

Access clinical annotations for specific genetic variants:

# Get variant information
response = requests.get("https://api.clinpgx.org/v1/variant/rs4244285")
variant_data = response.json()

# Search variants by position (if supported)
response = requests.get("https://api.clinpgx.org/v1/variant",
                       params={"chromosome": "10", "position": "94781859"})
variants = response.json()

Variant data includes: - rsID and genomic coordinates - Gene and functional consequence - Allele associations - Clinical significance - Population frequencies - Literature references

7. Clinical Annotations

Retrieve curated literature annotations (formerly PharmGKB clinical annotations):

# Get clinical annotations
response = requests.get("https://api.clinpgx.org/v1/clinicalAnnotation",
                       params={"gene": "CYP2D6"})
annotations = response.json()

# Filter by evidence level
response = requests.get("https://api.clinpgx.org/v1/clinicalAnnotation",
                       params={"evidenceLevel": "1A"})
high_evidence = response.json()

Evidence levels (from highest to lowest): - Level 1A: High-quality evidence, CPIC/FDA/DPWG guidelines - Level 1B: High-quality evidence, not yet guideline - Level 2A: Moderate evidence from well-designed studies - Level 2B: Moderate evidence with some limitations - Level 3: Limited or conflicting evidence - Level 4: Case reports or weak evidence

8. Drug Labels

Access pharmacogenomic information from drug labels:

# Get drug labels with PGx information
response = requests.get("https://api.clinpgx.org/v1/drugLabel",
                       params={"drug": "warfarin"})
labels = response.json()

# Filter by regulatory source
response = requests.get("https://api.clinpgx.org/v1/drugLabel",
                       params={"source": "FDA"})
fda_labels = response.json()

Label information includes: - Testing recommendations - Dosing guidance by genotype - Warnings and precautions - Biomarker information - Regulatory source (FDA, EMA, PMDA, etc.)

9. Pathways

Explore pharmacokinetic and pharmacodynamic pathways:

# Get pathway information
response = requests.get("https://api.clinpgx.org/v1/pathway/PA146123006")  # Warfarin pathway
pathway_data = response.json()

# Search pathways by drug
response = requests.get("https://api.clinpgx.org/v1/pathway",
                       params={"drug": "warfarin"})
pathways = response.json()

Pathway diagrams show: - Drug metabolism steps - Enzymes and transporters involved - Gene variants affecting each step - Downstream effects on efficacy/toxicity - Interactions with other pathways

Query Workflow

Workflow 1: Clinical Decision Support for Drug Prescription

  1. Identify patient genotype for relevant pharmacogenes: python # Example: Patient is CYP2C19 *1/*2 (intermediate metabolizer) response = requests.get("https://api.clinpgx.org/v1/allele/CYP2C19*2") allele_function = response.json()

  2. Query gene-drug pairs for medication of interest: python response = requests.get("https://api.clinpgx.org/v1/geneDrugPair", params={"gene": "CYP2C19", "drug": "clopidogrel"}) pair_info = response.json()

  3. Retrieve CPIC guideline for dosing recommendations: python response = requests.get("https://api.clinpgx.org/v1/guideline", params={"gene": "CYP2C19", "drug": "clopidogrel"}) guideline = response.json() # Recommendation: Alternative antiplatelet therapy for IM/PM

  4. Check drug label for regulatory guidance: python response = requests.get("https://api.clinpgx.org/v1/drugLabel", params={"drug": "clopidogrel"}) label = response.json()

Workflow 2: Gene Panel Analysis

  1. Get list of pharmacogenes in clinical panel: python pgx_panel = ["CYP2C19", "CYP2D6", "CYP2C9", "TPMT", "DPYD", "SLCO1B1"]

  2. For each gene, retrieve all drug interactions: python all_interactions = {} for gene in pgx_panel: response = requests.get("https://api.clinpgx.org/v1/geneDrugPair", params={"gene": gene}) all_interactions[gene] = response.json()

  3. Filter for CPIC guideline-level evidence: python for gene, pairs in all_interactions.items(): for pair in pairs: if pair.get('cpicLevel'): # Has CPIC guideline print(f"{gene} - {pair['drug']}: {pair['cpicLevel']}")

  4. Generate patient report with actionable pharmacogenomic findings.

Workflow 3: Drug Safety Assessment

  1. Query drug for PGx associations: python response = requests.get("https://api.clinpgx.org/v1/chemical", params={"name": "abacavir"}) drug_id = response.json()[0]['id']

  2. Get clinical annotations: python response = requests.get("https://api.clinpgx.org/v1/clinicalAnnotation", params={"drug": drug_id}) annotations = response.json()

  3. Check for HLA associations and toxicity risk: python for annotation in annotations: if 'HLA' in annotation.get('genes', []): print(f"Toxicity risk: {annotation['phenotype']}") print(f"Evidence level: {annotation['evidenceLevel']}")

  4. Retrieve screening recommendations from guidelines and labels.

Workflow 4: Research Analysis - Population Pharmacogenomics

  1. Get allele frequencies for population comparison: python response = requests.get("https://api.clinpgx.org/v1/allele", params={"gene": "CYP2D6"}) alleles = response.json()

  2. Extract population-specific frequencies: python populations = ['European', 'African', 'East Asian', 'Latino'] frequency_data = {} for allele in alleles: allele_name = allele['name'] frequency_data[allele_name] = { pop: allele.get(f'{pop}_frequency', 'N/A') for pop in populations }

  3. Calculate phenotype distributions by population: python # Combine allele frequencies with function to predict phenotypes phenotype_dist = calculate_phenotype_frequencies(frequency_data)

  4. Analyze implications for drug dosing in diverse populations.

Workflow 5: Literature Evidence Review

  1. Search for gene-drug pair: python response = requests.get("https://api.clinpgx.org/v1/geneDrugPair", params={"gene": "TPMT", "drug": "azathioprine"}) pair = response.json()

  2. Retrieve all clinical annotations: python response = requests.get("https://api.clinpgx.org/v1/clinicalAnnotation", params={"gene": "TPMT", "drug": "azathioprine"}) annotations = response.json()

  3. Filter by evidence level and publication date: python high_quality = [a for a in annotations if a['evidenceLevel'] in ['1A', '1B', '2A']]

  4. Extract PMIDs and retrieve full references: python pmids = [a['pmid'] for a in high_quality if 'pmid' in a] # Use PubMed skill to retrieve full citations

Rate Limiting and Best Practices

Rate Limit Compliance

import time

def rate_limited_request(url, params=None, delay=0.5):
    """Make API request with rate limiting (2 req/sec max)"""
    response = requests.get(url, params=params)
    time.sleep(delay)  # Wait 0.5 seconds between requests
    return response

# Use in loops
genes = ["CYP2D6", "CYP2C19", "CYP2C9"]
for gene in genes:
    response = rate_limited_request(
        "https://api.clinpgx.org/v1/gene/" + gene
    )
    data = response.json()

Error Handling

def safe_api_call(url, params=None, max_retries=3):
    """API call with error handling and retries"""
    for attempt in range(max_retries):
        try:
            response = requests.get(url, params=params, timeout=10)

            if response.status_code == 200:
                return response.json()
            elif response.status_code == 429:
                # Rate limit exceeded
                wait_time = 2 ** attempt  # Exponential backoff
                print(f"Rate limit hit. Waiting {wait_time}s...")
                time.sleep(wait_time)
            else:
                response.raise_for_status()

        except requests.exceptions.RequestException as e:
            print(f"Attempt {attempt + 1} failed: {e}")
            if attempt == max_retries - 1:
                raise
            time.sleep(1)

Caching Results

import json
from pathlib import Path

def cached_query(cache_file, api_func, *args, **kwargs):
    """Cache API results to avoid repeated queries"""
    cache_path = Path(cache_file)

    if cache_path.exists():
        with open(cache_path) as f:
            return json.load(f)

    result = api_func(*args, **kwargs)

    with open(cache_path, 'w') as f:
        json.dump(result, f, indent=2)

    return result

# Usage
gene_data = cached_query(
    'cyp2d6_cache.json',
    rate_limited_request,
    "https://api.clinpgx.org/v1/gene/CYP2D6"
)

PharmDOG Tool

PharmDOG (formerly DDRx) is ClinPGx's clinical decision support tool for interpreting pharmacogenomic test results:

Key features: - Phenoconversion calculator: Adjusts phenotype predictions for drug-drug interactions affecting CYP2D6 - Custom genotypes: Input patient genotypes to get phenotype predictions - QR code sharing: Generate shareable patient reports - Flexible guidance sources: Select which guidelines to apply (CPIC, DPWG, FDA) - Multi-drug analysis: Assess multiple medications simultaneously

Access: Available at https://www.clinpgx.org/pharmacogenomic-decision-support

Use cases: - Clinical interpretation of PGx panel results - Medication review for patients with known genotypes - Patient education materials - Point-of-care decision support

Resources

scripts/query_clinpgx.py

Python script with ready-to-use functions for common ClinPGx queries:

  • get_gene_info(gene_symbol) - Retrieve gene details
  • get_drug_info(drug_name) - Get drug information
  • get_gene_drug_pairs(gene, drug) - Query gene-drug interactions
  • get_cpic_guidelines(gene, drug) - Retrieve CPIC guidelines
  • get_alleles(gene) - Get all alleles for a gene
  • get_clinical_annotations(gene, drug, evidence_level) - Query literature annotations
  • get_drug_labels(drug) - Retrieve pharmacogenomic drug labels
  • search_variants(rsid) - Search by variant rsID
  • export_to_dataframe(data) - Convert results to pandas DataFrame

Consult this script for implementation examples with proper rate limiting and error handling.

references/api_reference.md

Comprehensive API documentation including:

  • Complete endpoint listing with parameters
  • Request/response format specifications
  • Example queries for each endpoint
  • Filter operators and search patterns
  • Data schema definitions
  • Rate limiting details
  • Authentication requirements (if any)
  • Troubleshooting common errors

Refer to this document when detailed API information is needed or when constructing complex queries.

Important Notes

Data Sources and Integration

ClinPGx consolidates multiple authoritative sources: - PharmGKB: Curated pharmacogenomics knowledge base (now part of ClinPGx) - CPIC: Evidence-based clinical implementation guidelines - PharmCAT: Allele calling and phenotype interpretation tool - DPWG: Dutch pharmacogenetics guidelines - FDA/EMA labels: Regulatory pharmacogenomic information

As of July 2025, all PharmGKB URLs redirect to corresponding ClinPGx pages.

Clinical Implementation Considerations

  • Evidence levels: Always check evidence strength before clinical application
  • Population differences: Allele frequencies vary significantly across populations
  • Phenoconversion: Consider drug-drug interactions that affect enzyme activity
  • Multi-gene effects: Some drugs affected by multiple pharmacogenes
  • Non-genetic factors: Age, organ function, drug interactions also affect response
  • Testing limitations: Not all clinically relevant alleles detected by all assays

Data Updates

  • ClinPGx continuously updates with new evidence and guidelines
  • Check publication dates for clinical annotations
  • Monitor ClinPGx Blog (https://blog.clinpgx.org/) for announcements
  • CPIC guidelines updated as new evidence emerges
  • PharmVar provides nomenclature updates for allele definitions

API Stability

  • API endpoints are relatively stable but may change during development
  • Parameters and response formats subject to modification
  • Monitor API changelog and ClinPGx blog for updates
  • Consider version pinning for production applications
  • Test API changes in development before production deployment

Common Use Cases

Pre-emptive Pharmacogenomic Testing

Query all clinically actionable gene-drug pairs to guide panel selection:

# Get all CPIC guideline pairs
response = requests.get("https://api.clinpgx.org/v1/geneDrugPair",
                       params={"cpicLevel": "A"})  # Level A recommendations
actionable_pairs = response.json()

Medication Therapy Management

Review patient medications against known genotypes:

patient_genes = {"CYP2C19": "*1/*2", "CYP2D6": "*1/*1", "SLCO1B1": "*1/*5"}
medications = ["clopidogrel", "simvastatin", "escitalopram"]

for med in medications:
    for gene in patient_genes:
        response = requests.get("https://api.clinpgx.org/v1/geneDrugPair",
                               params={"gene": gene, "drug": med})
        # Check for interactions and dosing guidance

Clinical Trial Eligibility

Screen for pharmacogenomic contraindications:

# Check for HLA-B*57:01 before abacavir trial
response = requests.get("https://api.clinpgx.org/v1/geneDrugPair",
                       params={"gene": "HLA-B", "drug": "abacavir"})
pair_info = response.json()
# CPIC: Do not use if HLA-B*57:01 positive

Additional Resources

  • ClinPGx website: https://www.clinpgx.org/
  • ClinPGx Blog: https://blog.clinpgx.org/
  • API documentation: https://api.clinpgx.org/
  • CPIC website: https://cpicpgx.org/
  • PharmCAT: https://pharmcat.clinpgx.org/
  • ClinGen: https://clinicalgenome.org/
  • Contact: api@clinpgx.org (for substantial API use)
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