The use of mechanistic DM‐PK‐PD modelling to assess the power of pharmacogenetic studies –CYP2C9 and warfarin as an example

What is already known about this subject • Many studies have shown that genetic polymorphisms of the CYP2C9 gene contribute to some of the variability (around 20%) in warfarin dose requirements and therapeutic response to the drug. • It is also clear that this effect must be elicited through differe...

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Bibliographic Details
Published in:British journal of clinical pharmacology 2007-07, Vol.64 (1), p.14-26
Main Authors: Dickinson, Gemma L., Lennard, Martin S., Tucker, Geoffrey T., Rostami‐Hodjegan, Amin
Format: Article
Language:English
Subjects:
Anticoagulants - administration & dosage
Anticoagulants - pharmacokinetics
Aryl Hydrocarbon Hydroxylases - genetics
Biological and medical sciences
Blood Coagulation - genetics
clinical trial simulation
Cytochrome P-450 CYP2C9
cytochrome P450
drug metabolism
Genotype
Humans
in silico
Medical sciences
modelling and simulation
Models, Biological
pharmacogenetics
Pharmacokinetics & Pharmacodynamics
Pharmacology. Drug treatments
Polymorphism, Genetic
Warfarin - administration & dosage
Warfarin - pharmacokinetics
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Summary:What is already known about this subject • Many studies have shown that genetic polymorphisms of the CYP2C9 gene contribute to some of the variability (around 20%) in warfarin dose requirements and therapeutic response to the drug. • It is also clear that this effect must be elicited through differences in the plasma (S)‐warfarin concentration between individuals of different genotypes, although assessing the effects of any single genotype of CYP2C9 on the kinetics of (S)‐warfarin has generally failed. What this study adds • The study aims to simulate the impact of genetic polymorphism in CYP2C9 on both the pharmacokinetics (PK) and pharmacodynamics (PD) of (S)‐warfarin using a mechanistic, population approach to modelling. • The outcomes with respect to the design of studies and their statistical power are compared against those of actual reported studies. • The exercise with warfarin is offered as an example of how prior information on the in vitro PK and PD of new drugs might be used in association with knowledge of relevant genetic polymorphisms and their frequencies to carry out virtual clinical studies as an aid to the design, optimization and powering of subsequent real clinical trials assessing the impact of specific genetic differences. Aim To assess the power of in vivo studies needed to discern the effect of genotype on pharmacokinetics (PK) and pharmacodynamics (PD) using CYP2C9 and (S)‐warfarin as an example. Methods Information on the in vitro metabolism of (S)‐warfarin and genetic variation in CYP2C9 was incorporated into a mechanistic population‐based PK–PD model. The influence of study design on the ability to detect significant differences in PK (AUC0−12 h) and PD (AUEC0−12 h INR) between CYP2C9 genotypes was investigated. Results A study size of 90 (based on the natural abundance of genotypes and uniform dosage) was required to achieve 80% power to discriminate the PK of (S)‐warfarin between wild type (*1/*1) and the combination of all other genotypes. About 250 subjects were needed to detect a difference in anticoagulant response. The power to detect differences between specific genotypes was much lower. Analysis of experimental comparisons of the PK or PD between wild‐type and other individual genotypes indicated that only 21% of cases (20 of 95 comparisons within 11 PD and four PK–PD studies) reported statistically significant differences. This was similar to the percentage expected from our simulations (20%, χ2 test, P = 0.80). Simul
ISSN:0306-5251
1365-2125
DOI:10.1111/j.1365-2125.2007.02850.x