Loisios-Konstantinidis Ioannis, Cristofoletti Rodrigo, Jamei Masoud, Turner David, Dressman Jennifer
Institute of Pharmaceutical Technology, Goethe University, Max-von-Laue str. 9, 60438 Frankfurt am Main, Germany.
Center for Pharmacometrics and Systems Pharmacology, Department of Pharmaceutics, College of Pharmacy, University of Florida, Orlando, FL 32827, USA.
Pharmaceutics. 2020 Nov 2;12(11):1049. doi: 10.3390/pharmaceutics12111049.
Physiologically based pharmacokinetic/pharmacodynamic (PBPK/PD) models can serve as a powerful framework for predicting the influence as well as the interaction of formulation, genetic polymorphism and co-medication on the pharmacokinetics and pharmacodynamics of drug substances. In this study, flurbiprofen, a potent non-steroid anti-inflammatory drug, was chosen as a model drug. Flurbiprofen has absolute bioavailability of ~95% and linear pharmacokinetics in the dose range of 50-300 mg. Its absorption is considered variable and complex, often associated with double peak phenomena, and its pharmacokinetics are characterized by high inter-subject variability, mainly due to its metabolism by the polymorphic CYP2C9 (fmCYP2C9 ≥ 0.71). In this study, by leveraging and data, an integrated PBPK/PD model with mechanistic absorption was developed and evaluated against clinical data from PK, PD, drug-drug and gene-drug interaction studies. The PBPK model successfully predicted (within 2-fold) 36 out of 38 observed concentration-time profiles of flurbiprofen as well as the CYP2C9 genetic effects after administration of different intravenous and oral dosage forms over a dose range of 40-300 mg in both Caucasian and Chinese healthy volunteers. All model predictions for C, AUC and CL/F were within two-fold of their respective mean or geometric mean values, while 90% of the predictions of C, 81% of the predictions of AUC and 74% of the predictions of Cl/F were within 1.25 fold. In addition, the drug-drug and drug-gene interactions were predicted within 1.5-fold of the observed interaction ratios (AUC, C ratios). The validated PBPK model was further expanded by linking it to an inhibitory model describing the analgesic efficacy of flurbiprofen and applying it to explore the effect of formulation and genetic polymorphisms on the onset and duration of pain relief. This comprehensive PBPK/PD analysis, along with a detailed translational biopharmaceutic framework including appropriately designed biorelevant experiments and extrapolation, provided mechanistic insight on the impact of formulation and genetic variations, two major determinants of the population variability, on the PK/PD of flurbiprofen. Clinically relevant specifications and potential dose adjustments were also proposed. Overall, the present work highlights the value of a translational PBPK/PD approach, tailored to target populations and genotypes, as an approach towards achieving personalized medicine.
基于生理的药代动力学/药效学(PBPK/PD)模型可作为一个强大的框架,用于预测制剂、基因多态性和合并用药对药物药代动力学和药效学的影响及相互作用。在本研究中,选择强效非甾体抗炎药氟比洛芬作为模型药物。氟比洛芬在50 - 300 mg剂量范围内具有约95%的绝对生物利用度和线性药代动力学。其吸收被认为是可变且复杂的,常伴有双峰现象,其药代动力学的特征是个体间变异性高,主要是由于其通过多态性CYP2C9代谢(fmCYP2C9≥0.71)。在本研究中,通过利用[具体数据1]和[具体数据2]的数据,开发了一个具有机械吸收的综合PBPK/PD模型,并根据来自药代动力学、药效学、药物 - 药物和基因 - 药物相互作用研究的临床数据进行了评估。该PBPK模型成功预测(在2倍以内)了在40 - 300 mg剂量范围内,白种人和中国健康志愿者在给予不同静脉和口服剂型后,38个观察到的氟比洛芬浓度 - 时间曲线中的36个以及CYP2C9基因效应。所有关于C、AUC和CL/F的模型预测值均在各自平均值或几何平均值的2倍以内,而90%的C预测值、81%的AUC预测值和74%的Cl/F预测值在1.25倍以内。此外,药物 - 药物和药物 - 基因相互作用的预测值在观察到的相互作用比(AUC、C比)的1.5倍以内。通过将经过验证的PBPK模型与描述氟比洛芬镇痛效果的抑制性[具体模型]模型相连接,并应用其来探索制剂和基因多态性对疼痛缓解的起效和持续时间的影响,进一步扩展了该模型。这种全面的PBPK/PD分析,连同包括适当设计的生物相关[具体实验1]实验和[具体外推方法]外推的详细转化生物药剂学框架,提供了关于制剂和基因变异这两个人口变异性的主要决定因素对氟比洛芬药代动力学/药效学影响的机制性见解。还提出了临床相关规范和潜在的剂量调整建议。总体而言,本研究强调了针对目标人群和基因型量身定制的转化PBPK/PD方法作为实现个性化医疗的一种方法的价值。
