Yamaoka Toshikazu, Kitamura Yoshiaki
DMPK Research Laboratory, Watarase Research Center, Kyorin Pharmaceutical Co., Ltd., 1848, Nogi, Nogi-machi, Shimotsuga-gun, Tochigi 329-0114, Japan.
J Pharmacol Toxicol Methods. 2015 Nov-Dec;76:83-95. doi: 10.1016/j.vascn.2015.08.157. Epub 2015 Aug 24.
Glutathione (GSH) trapping assays are widely used to predict the post-marketing risk for idiosyncratic drug reactions (IDRs) in the pharmaceutical industry. Although several GSH derivatives have been introduced as trapping reagents for reactive intermediates, more sensitive and selective reagents are desired to prevent the generation of erroneous results. In this study, stable isotope labeled GSH ethyl ester (GSHEE-d5) was designed and its detection capability was evaluated.
GSHEE-d5 was synthesized and its detection potential was compared with stable isotope labeled GSH ([(13)C2,(15)N]GSH) as a reference trapping reagent. The trapping reagents were added to human liver microsomes as a 1:1 mixture with GSHEE or GSH, respectively, and incubated with seven IDR positive drugs and three IDR negative drugs. The adducts formed between the reagents and reactive metabolites were analyzed by unit resolution mass spectrometer (MS) using isotope pattern-dependent scan with neutral loss filtering.
A single-step reaction of GSH and ethanol-d6 produced GSHEE-d5 with a yield of 85%. The GSHEE-d5 assay detected adducts with all seven IDR positive drugs, and no adducts were detected with the three IDR negative drugs. In contrast, the [(13)C2,(15)N]GSH assay failed to detect adducts with three of the IDR positive drugs. In the case of diclofenac, the GSHEE-d5 assay showed a 4-times greater signal intensity than the [(13)C2,(15)N]GSH assay.
GSHEE-d5 enabled the detection of reactive metabolites with greater sensitivity and selectivity than [(13)C2,(15)N]GSH. These results demonstrate that GSHEE-d5 would be a useful trapping reagent for evaluating the risk of IDRs with unit resolution MS.
谷胱甘肽(GSH)捕获测定法在制药行业中被广泛用于预测药物上市后发生特异质性药物反应(IDR)的风险。尽管已经引入了几种GSH衍生物作为反应性中间体的捕获试剂,但仍需要更灵敏和更具选择性的试剂来防止产生错误结果。在本研究中,设计了稳定同位素标记的GSH乙酯(GSHEE-d5)并评估了其检测能力。
合成了GSHEE-d5,并将其检测潜力与作为参考捕获试剂的稳定同位素标记的GSH([(13)C2,(15)N]GSH)进行比较。将捕获试剂分别与GSHEE或GSH以1:1的混合物形式添加到人肝微粒体中,并与七种IDR阳性药物和三种IDR阴性药物一起孵育。使用具有中性丢失过滤的同位素模式依赖性扫描,通过单位分辨率质谱仪(MS)分析试剂与反应性代谢物之间形成的加合物。
GSH与乙醇-d6的单步反应产生了产率为85%的GSHEE-d5。GSHEE-d5测定法检测到了与所有七种IDR阳性药物形成的加合物,而三种IDR阴性药物未检测到加合物。相比之下,[(13)C2,(15)N]GSH测定法未能检测到与三种IDR阳性药物形成的加合物。在双氯芬酸的情况下,GSHEE-d5测定法的信号强度比[(13)C2,(15)N]GSH测定法高4倍。
与[(13)C2,(15)N]GSH相比,GSHEE-d5能够更灵敏和更具选择性地检测反应性代谢物。这些结果表明,GSHEE-d5将是一种用于通过单位分辨率MS评估IDR风险的有用捕获试剂。
