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Interindividual Variability in Drug Response. How do we prescribe drugs?. How do we individualize therapy?. Oops!. Toxicity. No Effect. Too Much. Too Little. ¯ Dose. Dose. No effect. Toxicity. Dose. ¯ Dose. In the age of the Genome Why do people respond differently to drugs?.
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Interindividual Variability in Drug Response How do we prescribe drugs? How do we individualize therapy?
Oops! Toxicity No Effect Too Much Too Little ¯ Dose Dose No effect Toxicity Dose ¯ Dose
In the age of the GenomeWhy do people respond differently to drugs? • Variability in:- • Drug metabolism genotype • Drug transporter genotype • Drug receptor genotype • Drug/drug/environment /genotype interactions
Drug Oxidation - Major Route of Drug Metabolism Family of enzymes (CYPs) in liver Proportion of Pharmaceuticals Metabolized by Individual Cytochrome P450’s Major P450 Content of Human Liver Shimada et al, 1994
Polymorphism of Drug Oxidation • CYP2D6 Debrisoquin/Sparteine • CYP2C19 Mephenytoin • CYP2C9 S-warfarin
debrisoquine/sparteine amphetamine dexfenfluramine quanoxan ondansetron Antipsychotics perphenazine thioridazine haloperidol risperidone (9OH) minaprine venlafaxine fluvoxamine CYP2D6 Substrates Antiarrhythmics encainide flecainide S-mexillitene lidocaine Beta Blockers propafenone S-metoprolol propranolol (4OH) timolol alprenolol bufuralol carvedilol Antidepressants fluoxetine amitriptylline desipramine clomipramine imipramine Analgesics dextromethorphan codeine tramadol
Frequency of Poor Metabolizersin Different Populations CYP2D6 Caucasians 8.0% Japanese 0.5% Chinese 0.7% U.S. Blacks 6.1% (1.9%)
CYP2D6 Allele Frequencies Enzyme Activity Chinese CYP2D6 Caucasian Ghanaian *1 *3 *4 *5 *9 *10 *17 Normal None None None Decreased Decreased Decreased 84.2 0 10.6 2.6 0 2.6 0 57.5 0 10 5 0 12.5 15 52.4 0 0 0 0 47.6 0 Droll; Pharmacogenetics 8: 325-333, 1998
Genetic Polymorphism Prediction of drug toxicity
Genetic Polymorphism Prediction of drug toxicity • Phenformin • Withdrawn because of lactic acidosis • Metabolized by CYP2D6 • Lactic acidosis in PMs
Phenformin and Debrisoquine Woolhouse, Clin Pharmacol Ther, 37: 512-521; 1985.
Metabolism Within a Phenotype • Abnormal alleles • Gene duplication
CYP2D6 - Effects of Gene Duplication Dalen et al., 1998.
CYP2D6 - Gene Duplication* 10.4% 16.0% 3.5% 2.0% 1.8% 1.3% Saudi Arabians Ethiopians Spaniards Zimbabweans Germans Chinese * Includes individuals with more than one extra CYP2D6 gene McLellan et al., 1997
Genetic PolymorphismCYP2C19 • S-hydroxylation of mephenytoin deficient in PM’s Index drug: Mephenytoin (R and S)
Frequency of CYP2C19 Poor Metabolizers Phenotype Genotype Africans African-Americans Caucasians Chinese Japanese Koreans Amerindians 4.1 1.4 2.8 13.6 20.3 13.7 3.8 3.3 2.1 13.8 17.0 16.8 5.7
S-mephenytoin hexobarbital R-mephobarbital phenytoin diazepam citalopram omperazole lansoprazole pantoprazole R-warfarin (8-OH) propranolol (in part) imipramine clomipramine amitryptylline proguanil teniposide nilutamide indomethacin moclobemide CYP2C19 Substrates
Time after Omeprazole (hour) CYP2C19 l PMs ¡ EMs Sohn, JPET 262: 1195-1202; 1992
CYP2C19 Genotype + Intragastric pH Placebo Omeprazole Furuta et al., Clin Pharmacol Ther 65: 552-561, 1999.
H. pylori Cure Rate Based on CYP2C19 Genotype Total cure rate = 52% (n=62) (n=9) (n=25) Percent cure rate (n=28) wt/m1 wt/m2 m1/m2 m1/m1 wt/wt Omeprazole 20 mg/day for 6-8 weeks Amoxicillin 2000 mg/day for 2 weeks T. Furuta et al., Ann. Int. Med., 129: 1027-1030, 1998
CYP2C9 2C9 *3 2C9 *2 Chinese Japanese Korean African-American Caucasian 2.1% 2.2% 1.1% 0.8% 8.5% 0% 0% 0% 2.9% 10.7%
tolbutamide phenytoin S-warfarin tamoxifen diclofenac ibuprofen piroxicam suprofen S-naproxen sulfamethoxazole torsemide losartan busipirone CYP2C9 Substrates
CYP2C9 and Glipizide Kidd et al., Pharmacogenetics, 9: 71-80, 1999.
Warfarin • Racemic mixture of (R) and (S) isomers • (S)warfarin à 7-hydroxywarfarin by CYP2C9 • (R)warfarin à 8-hydroxywarfarin by CYP2C19 • (S) 7-10 X potency of (R) as anticoagulant
CYP2C9 - Allelic Variants WT CYP2C9 *1 CYP2C9 *2 CYP2C9 *3 Impaired hydroxylation in in vitro expression system Single AA substitution
CYP2C9Reduced (S)-Warfarin Clearance in Heterozygotes Takahashi, CPT, 1998
Warfarin Response in AC Clinic • Low dose < 1.5 mg/day • Random AC Clinic > 1.5 mg/day Lancet 353: 717; 1999
Warfarin Dose and Genotype Genotype (%) < 1.5 mg/day > 1.5 mg/day Community CYP2C9 *1/*1 *1/*2 *1/*3 *2/*3 *2/*2 *3/*3 19% 33% 28% 14% 6% 0% 62% 17% 19% 0% 2% 0% 60% 20% 17% 2% 0% 1% Lancet 353: 717; 1999
< 1.5 mg/day > 1.5 mg/day INR > 4 at Induction Minor bleeds (per person years) Major bleeds (per person years) 56% 5.3% 8.3% 17% 1.9% 2.3% Lancet 353: 717; 1999
Adverse effects and Drug Transporters • Polymorphism of MDR-1 • Potential source of altered • Absorption • Tissue concentrations
Effect of MDR-1 Genotype on Digoxin Cmax Hoffmeyer, PNAS 97:3473-3478, 2000
Variable Drug Response and Pharmacogenetics Alleles coding for enzymes and transporters with no or diminished activity contribute concentration related adverse events
Adverse Events Due to Altered Receptors Genotypic variability in receptor response
Survival in Heart Failure S.B. Liggett et al., J. Clin. Invest., 102: 1534-1539, 1998
Pharmacogenetics • Assists prediction of response • Explains variability in response • Role of genotyping/prescribing?
Pharmacogenetics and variability in response • Where are we-Can we? • Predict responses • Prevent adverse responses • Improve therapy
Personalized Medication in the Future GeneChip Analysis S M A R T C A R D Alastair J.J. Wood Xenobio GeneChip GENOME (Confidential) In the future (? years), your doctor will be able to select the best drug to treat your disease and the appropriate dose based on knowledge of your specific genetic makeup!
Pre-Prescription GenotypingGoal is improved patient safety • Metabolism • Prevention of toxicity • Avoiding under treatment • Response • Responders/Non responders • Drug choice • Drug interactions
Genotyping in Clinical Trials - If you know (or think you know) the genotype that responds 1. Prescreen 2. Treat only that genotype 3. Or (if toxicity) do NOT treat that genotype
Better prediction Dose Responders Toxicity Permit use of “toxic drugs” Smaller sample size Faster drug development Orphan drug status (<200,000) Less financial risk What is the indication? Who are the patients (limited population)? May transfer drug development costs to patient/provider Genotyping in Clinical Trials Opportunities Unresolved Issues
Prescribing by GenotypeOther Issues • Single polymorphism vs. Multiple polymorphisms • Non polymorphic (CYP3A) • All targets not yet identified • Informatics Technology is non trivial • Need prospective clinical trials to define benefits
Genotyping for Drug ResponseSimplistic view Drug Metabolizing Genotypes Dose
Genotyping for Drug Response Drug Response Genotypes Epilepsy Genotype Auto-convulsive Sensitivity Genotype Drug Metabolizing Genotypes Toxicity Response Genotypes Dose