Significant Improvement of Metabolic Characteristics and Bioactivities of Clopidogrel and Analogs by Selective Deuteration

Overview

Journal Molecules

Publisher MDPI

Specialty Biology

Date 2016 Jun 2

PMID 27248988

Citations 6

Authors

Xueyu Xu

Xue Zhao

Zhichao Yang

Hao Wang

Xiangjun Meng

Chong Su

Mingyuan Liu

John Paul Fawcett

Yan Yang

Jingkai Gu

Affiliations

Soon will be listed here.

Abstract

In the search for prodrug analogs of clopidogrel with improved metabolic characteristics and antiplatelet bioactivity, a group of clopidogrel and vicagrel analogs selectively deuterated at the benzylic methyl ester group were synthesized, characterized, and evaluated. The compounds included clopidogrel-d₃ (8), 2-oxoclopidogrel-d₃ (9), vicagrel-d₃ (10a), and 12 vicagrel-d₃ analogs (10b-10m) with different alkyl groups in the thiophene ester moiety. The D₃C-O bond length in 10a was shown by X-ray single crystal diffraction to be shorter than the H₃C-O bond length in clopidogrel, consistent with the slower rate of hydrolysis of 8 than of clopidogrel in rat whole blood in vitro. A study of the ability of the compounds to inhibit ADP-induced platelet aggregation in fresh rat whole blood collected 2 h after oral dosing of rats with the compounds (7.8 μmol/kg) showed that deuteration increased the activity of clopidogrel and that increasing the size of the alkyl group in the thiophene ester moiety reduced activity. A preliminary pharmacokinetic study comparing 10a with vicagrel administered simultaneously as single oral doses (72 μmol/kg of each drug) to male Wistar rats showed 10a generated more of its active metabolite than vicagrel. These results suggest that 10a is a potentially superior antiplatelet agent with improved metabolic characteristics and bioactivity, and less dose-related toxicity.

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