Impact of Genetic Polymorphisms and Drug-Drug Interactions Mediated by Carboxylesterase1 on Remimazolam Deactivation.

IF 4.4 3区 医学 Q1 PHARMACOLOGY & PHARMACY
Zhuo Wang, Zachary McCalla, Li Lin, Dominic Tornichio, Yaw Agyemang, John A Bastulli, Xiaochun Susan Zhang, Hao-Jie Zhu, Xinwen Wang
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引用次数: 0

Abstract

Remimazolam (Byfavo®), a recent FDA-approved ester-linked benzodiazepine, offers advantages in sedation, such as rapid onset and predictable duration, making it suitable for broad anesthesia applications. Its favorable pharmacological profile is primarily attributed to rapid hydrolysis, the primary metabolism pathway for its deactivation. Thus, understanding remimazolam hydrolysis determinants is essential for optimizing its clinical use. This study aimed to identify the enzyme(s) and tissue(s) responsible for remimazolam hydrolysis and to evaluate the influence of genetic polymorphisms and drug-drug interactions (DDIs) on its hydrolysis in the human liver. An initial incubation study with remimazolam and phosphate buffer saline (PBS), human serum, and the S9 fractions of human liver and intestine demonstrated that remimazolam was exclusively hydrolyzed by human liver S9 fractions. Subsequent incubation studies utilizing a Carboxylesterase inhibitor (Bis-para-nitrophenylphosphate, BNPP), recombinant human Carboxylesterase1 (CES1) and Carboxylesterase 2 (CES2) confirmed that remimazolam is specifically hydrolyzed by CES1 in human liver. Furthermore, in vitro studies with wild-type CES1 and CES1 variants transfected cells revealed that certain genetic polymorphisms significantly impair remimazolam deactivation. Notably, the impact of CES1 G143E was verified using individual human liver samples. Moreover, our evaluation of the DDIs between remimazolam and several other substrates/inhibitors of CES1-including simvastatin, enalapril, clopidogrel and sacubitril- found that clopidogrel significantly inhibited remimazolam hydrolysis at clinically relevant concentrations, with CES1 genetic variants potentially influencing the interactions. In summary, CES1 genetic variants and its interacting drugs are crucial factors contributing to interindividual variability in remimazolam hepatic hydrolysis, holding the potential to serve as biomarkers for optimizing remimazolam use. Significance Statement This investigation demonstrates that remimazolam is deactivated by CES1 in the human liver, with CES1 genetic variants and DDIs significantly influencing its metabolism. These findings emphasize the need to consider CES1 genetic variability and potential DDIs in remimazolam use, especially in personalized pharmacotherapy to achieve optimal anesthetic outcomes.

羧基酯酶1介导的基因多态性和药物间相互作用对雷马唑仑失活的影响
雷马唑仑(Byfavo®)是最近获得美国食品及药物管理局批准的酯联苯二氮卓类药物,在镇静方面具有起效迅速、持续时间可预测等优点,因此适合广泛的麻醉应用。其良好的药理特性主要归功于快速水解,这是其失活的主要代谢途径。因此,了解雷马唑仑水解决定因素对于优化其临床应用至关重要。本研究旨在确定导致雷马唑仑水解的酶和组织,并评估基因多态性和药物相互作用(DDI)对其在人体肝脏中水解的影响。用雷马唑仑和磷酸盐缓冲盐水(PBS)、人类血清以及人类肝脏和肠道的 S9 馏分进行的初步孵育研究表明,雷马唑仑只被人类肝脏 S9 馏分水解。随后利用羧基酯酶抑制剂(双对硝基苯磷酸酯,BNPP)、重组人羧基酯酶 1(CES1)和羧基酯酶 2(CES2)进行的孵育研究证实,人肝中的 CES1 能特异性地水解雷马唑仑。此外,用野生型 CES1 和 CES1 变体转染细胞进行的体外研究表明,某些基因多态性会显著影响雷马唑仑的失活。值得注意的是,CES1 G143E 的影响已通过人体肝脏样本得到验证。此外,我们还评估了雷马唑仑与其他几种 CES1 底物/抑制剂(包括辛伐他汀、依那普利、氯吡格雷和沙库比曲)之间的 DDIs,发现氯吡格雷在临床相关浓度下会明显抑制雷马唑仑的水解,而 CES1 基因变异可能会影响这种相互作用。总之,CES1 基因变异及其相互作用药物是导致雷马唑仑肝水解作用个体间差异的关键因素,有可能成为优化雷马唑仑使用的生物标志物。意义声明 本研究表明,雷马唑仑在人体肝脏中会被 CES1 失活,CES1 基因变异和 DDIs 对其代谢有显著影响。这些发现强调了在使用雷马唑仑时考虑 CES1 基因变异和潜在 DDIs 的必要性,尤其是在个性化药物治疗中,以达到最佳麻醉效果。
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来源期刊
CiteScore
6.50
自引率
12.80%
发文量
128
审稿时长
3 months
期刊介绍: An important reference for all pharmacology and toxicology departments, DMD is also a valuable resource for medicinal chemists involved in drug design and biochemists with an interest in drug metabolism, expression of drug metabolizing enzymes, and regulation of drug metabolizing enzyme gene expression. Articles provide experimental results from in vitro and in vivo systems that bring you significant and original information on metabolism and disposition of endogenous and exogenous compounds, including pharmacologic agents and environmental chemicals.
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