The Effect of Retroconversion Metabolism of N-oxide Metabolites by Intestinal Microflora on Piperaquine Elimination in Mice, as well as in Humans Predicted Using a PBPK Model.

IF 2.1 4区 医学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY Current drug metabolism Pub Date : 2023-01-01 DOI:10.2174/1389200224666230320112429
Hongchang Zhou, Liyuan Zhang, Jianbo Ji, Yuewu Xie, Jie Xing
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Abstract

Background: Piperaquine (PQ) and its pharmacologically active metabolite PQ N-oxide (PM1) can be metabolically interconverted via hepatic cytochrome P450 and FMO enzymes.

Objectives: The reductive metabolism of PM1 and its further N-oxidation metabolite (PM2) by intestinal microflora was evaluated, and its role in PQ elimination was also investigated.

Methods: The hepatic and microbial reduction metabolism of PM1 and PM2 was studied in vitro. The reaction phenotyping experiments were performed using correlation analysis, selective chemical inhibition, and human recombinant CYP/FMO enzymes. The role of microbial reduction metabolism in PQ elimination was evaluated in mice pretreated with antibiotics. The effect of the reduction metabolism on PQ exposures in humans was predicted using a physiologically-based pharmacokinetic (PBPK) model.

Results: Both hepatic P450/FMOs enzymes and microbial nitroreductases (NTRs) contributed to the reduction metabolism of two PQ N-oxide metabolites. In vitro physiologic and enzyme kinetic studies of both N-oxides showed a comparable intrinsic clearance by the liver and intestinal microflora. Pretreatment with antibiotics did not lead to a significant (P > 0.05) change in PQ pharmacokinetics in mice after an oral dose. The predicted pharmacokinetic profiles of PQ in humans did not show an effect of metabolic recycling.

Conclusion: Microbial NTRs and hepatic P450/FMO enzymes contributed to the reduction metabolism of PQ Noxide metabolites. The reduction metabolism by intestinal microflora did not affect PQ clearance, and the medical warning in patients with NTRs-related disease (e.g., hyperlipidemia) will not be clinically meaningful.

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利用PBPK模型预测肠道菌群n -氧化物代谢物的反向转化代谢对哌喹在小鼠和人类体内消除的影响
背景:哌喹(PQ)及其药理活性代谢物PQ n -氧化物(PM1)可通过肝细胞色素P450和FMO酶代谢相互转化。目的:评价肠道菌群对PM1及其n -氧化代谢物(PM2)的还原代谢,并探讨其在PQ消除中的作用。方法:体外研究PM1和PM2的肝脏和微生物还原代谢。利用相关分析、选择性化学抑制和人重组CYP/FMO酶进行反应表型实验。在抗生素预处理的小鼠中评估微生物还原代谢在PQ消除中的作用。使用基于生理的药代动力学(PBPK)模型预测了减少代谢对人体PQ暴露的影响。结果:肝脏P450/FMOs酶和微生物硝基还原酶(NTRs)都参与了两种PQ n -氧化物代谢产物的还原代谢。体外生理和酶动力学研究表明,这两种n -氧化物在肝脏和肠道微生物群中具有相当的内在清除率。抗生素预处理对小鼠口服给药后PQ药代动力学无显著影响(P > 0.05)。预测的PQ在人体内的药代动力学特征没有显示代谢再循环的影响。结论:微生物NTRs和肝脏P450/FMO酶参与了PQ氧化物代谢产物的减少代谢。肠道菌群代谢降低不影响PQ清除率,对ntrs相关疾病(如高脂血症)患者的医学警示将不具有临床意义。
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来源期刊
Current drug metabolism
Current drug metabolism 医学-生化与分子生物学
CiteScore
4.30
自引率
4.30%
发文量
81
审稿时长
4-8 weeks
期刊介绍: Current Drug Metabolism aims to cover all the latest and outstanding developments in drug metabolism, pharmacokinetics, and drug disposition. The journal serves as an international forum for the publication of full-length/mini review, research articles and guest edited issues in drug metabolism. Current Drug Metabolism is an essential journal for academic, clinical, government and pharmaceutical scientists who wish to be kept informed and up-to-date with the most important developments. The journal covers the following general topic areas: pharmaceutics, pharmacokinetics, toxicology, and most importantly drug metabolism. More specifically, in vitro and in vivo drug metabolism of phase I and phase II enzymes or metabolic pathways; drug-drug interactions and enzyme kinetics; pharmacokinetics, pharmacokinetic-pharmacodynamic modeling, and toxicokinetics; interspecies differences in metabolism or pharmacokinetics, species scaling and extrapolations; drug transporters; target organ toxicity and interindividual variability in drug exposure-response; extrahepatic metabolism; bioactivation, reactive metabolites, and developments for the identification of drug metabolites. Preclinical and clinical reviews describing the drug metabolism and pharmacokinetics of marketed drugs or drug classes.
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