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A Simple Methodology to Differentiate Changes in Bioavailability From Changes in Clearance Following Oral Dosing of Metabolized Drugs.一种简单的方法,可区分口服给予代谢药物后生物利用度的变化和清除率的变化。
Clin Pharmacol Ther. 2020 Aug;108(2):306-315. doi: 10.1002/cpt.1828. Epub 2020 Apr 19.
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Induction of Human Intestinal and Hepatic Organic Anion Transporting Polypeptides: Where Is the Evidence for Its Relevance in Drug-Drug Interactions?诱导人肠道和肝脏有机阴离子转运多肽:其在药物相互作用中的相关性的证据在哪里?
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Clinical Studies on Drug-Drug Interactions Involving Metabolism and Transport: Methodology, Pitfalls, and Interpretation.涉及代谢和转运的药物-药物相互作用的临床研究:方法学、陷阱和解读。
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Understanding drug-drug interaction and pharmacogenomic changes in pharmacokinetics for metabolized drugs.了解代谢药物的药代动力学中的药物-药物相互作用和药物基因组学变化。
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Organic anion transporting polypeptide 2B1 - More than a glass-full of drug interactions.有机阴离子转运多肽 2B1- 远不止一杯药物相互作用。
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使用吸收时间变化来推断肠道转运体参与口服药物相互作用的必要性。

The Necessity of Using Changes in Absorption Time to Implicate Intestinal Transporter Involvement in Oral Drug-Drug Interactions.

机构信息

Department of Bioengineering and Therapeutic Sciences, Schools of Pharmacy and Medicine, University of California San Francisco, 513 Parnassus Ave Rm HSE 1164, UCSF Box 0912, San Francisco, CA, 94143, USA.

出版信息

AAPS J. 2020 Aug 17;22(5):111. doi: 10.1208/s12248-020-00469-6.

DOI:10.1208/s12248-020-00469-6
PMID:32808084
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7478332/
Abstract

INTRODUCTION

In drug discovery and development, it is of high interest to characterize the potential for intestinal drug-drug interactions to alter bioavailability of a victim drug. For drugs that are substrates of both intestinal transporters and enzymes, estimating the relative contribution of each process has proved challenging, especially since the susceptibility of drug to uptake or efflux transporters in vitro does not always translate to clinically significant in vivo involvement. Here we introduce a powerful methodology to implicate intestinal transporters in drug-drug interactions based on the theory that clinically relevant intestinal transporter interactions will result in altered rate of absorption of victim drugs.

METHODS AND MATERIALS

We present exemplary clinical drug-drug interaction studies that utilize well-characterized clinical substrates and perpetrators to demonstrate how mean absorption time (MAT) and time to maximum concentration (t) are expected to change (or remain unchanged) when either intestinal transporters or metabolic enzymes were/are altered. Apixaban was also selected to demonstrate the utility of the methodology, as the purported involvement of both intestinal enzymes and transporters has been suggested in its FDA package insert.

RESULTS AND DISCUSSION

Acute inhibition of gut efflux transporters resulted in decreased MAT and tvalues, induction increased these values, while inhibition of intestinal metabolic enzymes did not result in altered MAT or t. Involvement of intestinal efflux transporters in apixaban disposition is unlikely.

CONCLUSION

Utilization of this simple but powerful methodology to implicate intestinal transporter involvement will have significant impact on how drug-drug interactions are interpreted.

摘要

简介

在药物发现和开发中,描述肠道药物相互作用改变潜在受药物生物利用度的可能性具有重要意义。对于既是肠道转运体又是酶底物的药物,估计每种过程的相对贡献具有挑战性,特别是因为药物在体外对摄取或外排转运体的敏感性并不总是转化为临床上显著的体内参与。在这里,我们介绍了一种基于这样一种理论的强有力的方法,即临床相关的肠道转运体相互作用将导致受药物吸收速度发生改变,从而推断肠道转运体在药物相互作用中的作用。

方法和材料

我们展示了一些示例临床药物相互作用研究,这些研究利用了经过良好表征的临床底物和药物来证明当肠道转运体或代谢酶发生改变时,平均吸收时间(MAT)和最大浓度时间(t)预计会如何变化(或保持不变)。阿哌沙班也被选作方法学的实用性的示例,因为其 FDA 说明书中暗示了其涉及肠道酶和转运体。

结果和讨论

肠道外排转运体的急性抑制导致 MAT 和 t 值降低,诱导增加了这些值,而抑制肠道代谢酶不会导致 MAT 或 t 值改变。阿哌沙班的处置不太可能涉及肠道外排转运体。

结论

利用这种简单但强大的方法推断肠道转运体的参与将对如何解释药物相互作用产生重大影响。