Berfin Gülave, Ariel Lesmana, Elizabeth Cm de Lange, J G Coen van Hasselt
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Here, we used a physiologically-based pharmacokinetic (PBPK) model-based approach to evaluate the potential impact of DDIs on BBB transport of morphine by clinically relevant P-gp inhibitor drugs.The LeiCNS-PK3.0 PBPK model was used to simulate morphine distribution at the brain extracellular fluid (brain<sub>ECF</sub>) for different clinical intravenous dosing regimens of morphine, alone or in combination with a P-gp inhibitor. We included 34 commonly used P-gp inhibitor drugs, with inhibitory constants and expected clinical P-gp inhibitor concentrations derived from literature. The DDI impact was evaluated by the change in brain<sub>ECF</sub> exposure for morphine alone or in combination with different inhibitors. Our analysis demonstrated that P-gp inhibitors had a negligible effect on morphine brain<sub>ECF</sub> exposure in the majority of simulated population, caused by low P-gp inhibition. 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引用次数: 0
摘要
p -糖蛋白(P-gp)是一种关键的外排转运蛋白,可能参与血脑屏障(BBB)的药物-药物相互作用(ddi),从而导致中枢神经系统(CNS)药物暴露的改变。吗啡是P-gp底物,因此是P-gp介导的ddi的潜在受害者药物。然而,尚不清楚P-gp抑制剂是否能诱导吗啡中枢神经系统暴露的临床相关变化。在这里,我们采用基于生理的药代动力学(PBPK)模型的方法来评估ddi对临床相关P-gp抑制剂药物对吗啡血脑屏障转运的潜在影响。采用LeiCNS-PK3.0 PBPK模型模拟吗啡在脑细胞外液(brainECF)的分布,以模拟吗啡单独或联合P-gp抑制剂的不同临床静脉给药方案。我们纳入了34种常用的P-gp抑制剂药物,其抑制常数和预期的临床P-gp抑制剂浓度来源于文献。DDI的影响是通过吗啡单独或与不同抑制剂联合使用时脑ecf暴露的变化来评估的。我们的分析表明,在大多数模拟人群中,P-gp抑制剂对吗啡脑ecf暴露的影响可以忽略不计,这是由低P-gp抑制引起的。敏感性分析显示,增加抑制浓度和改变抑制常数对吗啡脑ecf暴露均无主要影响。综上所述,经评估的P-gp抑制剂对吗啡血脑屏障转运的ddi不太可能引起临床相关吗啡中枢神经系统暴露的有意义的变化。开发的CNS PBPK建模方法为评估人类血脑屏障转运体ddi提供了一种通用方法。
Do P-glycoprotein-mediated drug-drug interactions at the blood-brain barrier impact morphine brain distribution?
P-glycoprotein (P-gp) is a key efflux transporter and may be involved in drug-drug interactions (DDIs) at the blood-brain barrier (BBB), which could lead to changes in central nervous system (CNS) drug exposure. Morphine is a P-gp substrate and therefore a potential victim drug for P-gp mediated DDIs. It is however unclear if P-gp inhibitors can induce clinically relevant changes in morphine CNS exposure. Here, we used a physiologically-based pharmacokinetic (PBPK) model-based approach to evaluate the potential impact of DDIs on BBB transport of morphine by clinically relevant P-gp inhibitor drugs.The LeiCNS-PK3.0 PBPK model was used to simulate morphine distribution at the brain extracellular fluid (brainECF) for different clinical intravenous dosing regimens of morphine, alone or in combination with a P-gp inhibitor. We included 34 commonly used P-gp inhibitor drugs, with inhibitory constants and expected clinical P-gp inhibitor concentrations derived from literature. The DDI impact was evaluated by the change in brainECF exposure for morphine alone or in combination with different inhibitors. Our analysis demonstrated that P-gp inhibitors had a negligible effect on morphine brainECF exposure in the majority of simulated population, caused by low P-gp inhibition. Sensitivity analyses showed neither major effects of increasing the inhibitory concentration nor changing the inhibitory constant on morphine brainECF exposure. In conclusion, P-gp mediated DDIs on morphine BBB transport for the evaluated P-gp inhibitors are unlikely to induce meaningful changes in clinically relevant morphine CNS exposure. The developed CNS PBPK modeling approach provides a general approach for evaluating BBB transporter DDIs in humans.
期刊介绍:
Broadly speaking, the Journal of Pharmacokinetics and Pharmacodynamics covers the area of pharmacometrics. The journal is devoted to illustrating the importance of pharmacokinetics, pharmacodynamics, and pharmacometrics in drug development, clinical care, and the understanding of drug action. The journal publishes on a variety of topics related to pharmacometrics, including, but not limited to, clinical, experimental, and theoretical papers examining the kinetics of drug disposition and effects of drug action in humans, animals, in vitro, or in silico; modeling and simulation methodology, including optimal design; precision medicine; systems pharmacology; and mathematical pharmacology (including computational biology, bioengineering, and biophysics related to pharmacology, pharmacokinetics, orpharmacodynamics). Clinical papers that include population pharmacokinetic-pharmacodynamic relationships are welcome. The journal actively invites and promotes up-and-coming areas of pharmacometric research, such as real-world evidence, quality of life analyses, and artificial intelligence. The Journal of Pharmacokinetics and Pharmacodynamics is an official journal of the International Society of Pharmacometrics.
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