了解伏立康唑的代谢:基于生理学的中间向外药代动力学建模框架,将体外实验和临床观察融为一体。

IF 4.6 2区 医学 Q1 PHARMACOLOGY & PHARMACY Clinical Pharmacokinetics Pub Date : 2024-10-30 DOI:10.1007/s40262-024-01434-8
Ayatallah Saleh, Josefine Schulz, Jan-Frederik Schlender, Linda B S Aulin, Amrei-Pauline Konrad, Franziska Kluwe, Gerd Mikus, Wilhelm Huisinga, Charlotte Kloft, Robin Michelet
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引用次数: 0

摘要

背景和目的:伏立康唑(Voriconazole,VRC)是一种广谱抗真菌药物,由于饱和代谢过程、自身抑制和代谢产物介导的对自身形成的抑制,其药代动力学(PK)呈现非线性。VRC PK 的另一个特点是个体间和个体内的高变异性,这主要与细胞色素 P450 (CYP) 2C19 遗传多态性有关。此外,最近的体外研究结果表明,VRC 的主要代谢物伏立康唑 N-氧化物(NO)和羟基伏立康唑(OHVRC)会抑制负责 VRC 代谢的 CYP 酶,从而增加其 PK 变异性。这种变异性带来了治疗失败或不良事件的巨大风险,而这正是 VRC 治疗所面临的主要挑战。了解这些变异性的基本过程和来源对于安全有效的治疗至关重要。这项工作旨在开发一种基于生理的全身药代动力学(PBPK)建模框架,利用体外和体内临床数据,以中间向外的方法阐明 VRC 的复杂代谢及其代谢物 NO 和 OHVRC 对母体 PK 的影响:方法:使用 PK-Sim® 和 MoBi® 以循序渐进的方式建立了 VRC、NO 和 OHVRC 的母体-代谢物耦合 PBPK 模型。根据现有的体外数据,NO 的形成假定由 CYP2C19、CYP3A4 和 CYP2C9 介导,而 OHVRC 的形成则完全由 CYP3A4 介导。假定这两种代谢物都通过肾脏清除率排出体外,同时也考虑了 NO 的肝脏清除率。采用抑制函数来描述 VRC 自身抑制和代谢物介导的抑制对每种 CYP 酶的复杂相互作用网络:该模型采用自下而上和自上而下相结合的方法,结合多项临床研究数据和现有文献,准确预测了不同 CYP2C19 基因型预测表型的健康成人在各种静脉给药方案中的血浆浓度-时间曲线。所有(100%)预测的 VRC 浓度-时间曲线下面积 (AUC) 值和 94% 的最大浓度 (Cmax) 值都达到了 1.25 倍的接受标准,总体绝对平均倍数误差分别为 1.12 和 1.14。此外,NO 和 OHVRC 的所有预测 AUC 值和 Cmax 值均符合 2 倍接受标准:结论:这种全面的 VRC 母体-代谢物 PBPK 模型定量阐明了该药物复杂的代谢过程,并强调了初级代谢物对 VRC PK 的重大影响。该模型结合了自下而上和自上而下的综合方法,从而考虑了 VRC 自身抑制、代谢物介导的抑制以及 CYP2C19 基因多态性的影响,加深了我们对 VRC PK 的理解。此外,该模型在设计进一步的体外实验中起着关键作用,最终可用于儿科人群,提高治疗的个体化程度并改善临床效果。
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Understanding Voriconazole Metabolism: A Middle-Out Physiologically-Based Pharmacokinetic Modelling Framework Integrating In Vitro and Clinical Insights.

Background and objective: Voriconazole (VRC), a broad-spectrum antifungal drug, exhibits nonlinear pharmacokinetics (PK) due to saturable metabolic processes, autoinhibition and metabolite-mediated inhibition on their own formation. VRC PK is also characterised by high inter- and intraindividual variability, primarily associated with cytochrome P450 (CYP) 2C19 genetic polymorphism. Additionally, recent in vitro findings indicate that VRC main metabolites, voriconazole N-oxide (NO) and hydroxyvoriconazole (OHVRC), inhibit CYP enzymes responsible for VRC metabolism, adding to its PK variability. This variability poses a significant risk of therapeutic failure or adverse events, which are major challenges in VRC therapy. Understanding the underlying processes and sources of these variabilities is essential for safe and effective therapy. This work aimed to develop a whole-body physiologically-based pharmacokinetic (PBPK) modelling framework that elucidates the complex metabolism of VRC and the impact of its metabolites, NO and OHVRC, on the PK of the parent, leveraging both in vitro and in vivo clinical data in a middle-out approach.

Methods: A coupled parent-metabolite PBPK model for VRC, NO and OHVRC was developed in a stepwise manner using PK-Sim® and MoBi®. Based on available in vitro data, NO formation was assumed to be mediated by CYP2C19, CYP3A4, and CYP2C9, while OHVRC formation was attributed solely to CYP3A4. Both metabolites were assumed to be excreted via renal clearance, with hepatic elimination also considered for NO. Inhibition functions were implemented to describe the complex interaction network of VRC autoinhibition and metabolite-mediated inhibition on each CYP enzyme.

Results: Using a combined bottom-up and middle-out approach, incorporating data from multiple clinical studies and existing literature, the model accurately predicted plasma concentration-time profiles across various intravenous dosing regimens in healthy adults, of different CYP2C19 genotype-predicted phenotypes. All (100%) of the predicted area under the concentration-time curve (AUC) and 94% of maximum concentration (Cmax) values of VRC met the 1.25-fold acceptance criterion, with overall absolute average fold errors of 1.12 and 1.14, respectively. Furthermore, all predicted AUC and Cmax values of NO and OHVRC met the twofold acceptance criterion.

Conclusion: This comprehensive parent-metabolite PBPK model of VRC quantitatively elucidated the complex metabolism of the drug and emphasised the substantial impact of the primary metabolites on VRC PK. The comprehensive approach combining bottom-up and middle-out modelling, thereby accounting for VRC autoinhibition, metabolite-mediated inhibition, and the impact of CYP2C19 genetic polymorphisms, enhances our understanding of VRC PK. Moreover, the model can be pivotal in designing further in vitro experiments, ultimately allowing for extrapolation to paediatric populations, enhance treatment individualisation and improve clinical outcomes.

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来源期刊
CiteScore
8.80
自引率
4.40%
发文量
86
审稿时长
6-12 weeks
期刊介绍: Clinical Pharmacokinetics promotes the continuing development of clinical pharmacokinetics and pharmacodynamics for the improvement of drug therapy, and for furthering postgraduate education in clinical pharmacology and therapeutics. Pharmacokinetics, the study of drug disposition in the body, is an integral part of drug development and rational use. Knowledge and application of pharmacokinetic principles leads to accelerated drug development, cost effective drug use and a reduced frequency of adverse effects and drug interactions.
期刊最新文献
Understanding Voriconazole Metabolism: A Middle-Out Physiologically-Based Pharmacokinetic Modelling Framework Integrating In Vitro and Clinical Insights. Clinical Pharmacology of Asciminib: A Review. Changes in Plasma Clearance of CYP450 Probe Drugs May Not be Specific for Altered In Vivo Enzyme Activity Under (Patho)Physiological Conditions: How to Interpret Findings of Probe Cocktail Studies. Population Pharmacokinetic Modelling of Norepinephrine in Healthy Volunteers Prior to and During General Anesthesia. Impact of Continuous Infusion Meropenem PK/PD Target Attainment on C-Reactive Protein Dynamics in Critically Ill Patients With Documented Gram-Negative Hospital-Acquired or Ventilator-Associated Pneumonia.
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