Investigation of Human in vivo Metabolism of SEP-227900 Using the Samples from First-in-Human Study by LC-HRMS/UV and NMR.

Yu-Luan Chen, Estela Skende, Armand Gatien Ngounou Wetie, Peter Li-Quan Wang
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引用次数: 0

Abstract

Objective: The study aims to explore the human in vivo metabolism of SEP-227900 (4H-furo[3, 2-b] pyrrole-carboxylic acid, m.w 151.03), a D-amino-acid oxidase (DAAO) inhibitor, by using plasma and urine samples from first-in-human study.

Methods: The human plasma and urine samples were from a single dose cohort that consisted of 9 healthy male volunteers each received an 80- mg dose of SEP-227900 orally. The pooled pre-dose urine and the pooled 0-24 h urine sample were created across 9 subjects by equal volume. Plasma samples were pooled by equal volume across 9 subjects to obtain 0-12 h plasma for metabolite searching, and also pooled by timepoints across 9 subjects to obtain 0.5, 5, and 12-h plasma for semi-quantitation. The plasma was de-proteinized by acetonitrile (1:3 v/v plasma-acetonitrile), then the supernatant was dried down, reconstituted, and injected for LC-HRMS/UV analysis. The urine sample was just simply centrifuged before analysis. LC-HRMS/UV was utilized to search predictable and unknown metabolites and estimate their relative abundances. Accurate mass measurement by Orbitrap-MS and MS/MS was used for metabolite identification. Chromatographic separation was achieved on a MACMOD AQ C8 column (250 × 4.6 mm, 5-μm) with a gradient mobile phase (A: 10 mM NH4Ac; B: acetonitrile; flowrate: 0.700 ml/min) for a total run-time of 65 min. The definite position in the molecule for the glucuronidation metabolism was characterized by the detected migration phenomenon, methylation with diazomethane (CH2N2), and NMR.

Results: Unchanged parent drug and four metabolite peaks were detected in humans: M1 was a mono-oxidative metabolite of SEP-227900; M2 was a glucuronide conjugate of SEP-227900; M3 was a glycine conjugate of SEP-227900; M4 was a glycine conjugate of M1. The specific position of the oxidation in M1 solely based on the mass spectral (MS and MS/MS) data was not identified. However, for the major metabolite M2, the acyl glucuronidation was unambiguously determined through multiple pieces of experimental evidence such as the observation of a migration pattern, mono-methylation by diazomethane, and NMR measurement. This determination is of significance related to the safety evaluation of investigational new drug development. The glycine conjugate of SEP-227900, i.e., M3, was found to be the most abundant metabolite in human urine (approximately 3-fold higher level than the glucuronide level). All together (mainly glycine-conjugate and glucuronide), it resulted in greater than 80% of the dosed amount in urine excretion (a separate measurement showed 23% of the dosed amount in urine excretion as the glucuronide).

Conclusion: Four metabolites were found in humans: SEP-227900-glycine conjugate, SEP- 227900-glucuronide, mono-oxidative metabolite, and its consequent glycine conjugate. The glucuronide metabolite was identified as acyl glucuronide. Greater than 80% of the dosed amount of SEP-227900 was excreted in the urine, mainly in the forms of glycine- and glucuronide- conjugates.

用LC-HRMS/UV和NMR研究SEP-227900在人体内的代谢。
目的:通过首次人体试验的血浆和尿液样本,探讨d -氨基酸氧化酶(DAAO)抑制剂SEP-227900 (4h -呋喃[3,2 -b]吡咯-羧酸,m.w 151.03)的体内代谢情况。方法:人类血浆和尿液样本来自一个单剂量队列,由9名健康男性志愿者组成,每人口服80 mg剂量的SEP-227900。在9名受试者中按等体积制作了混合的给药前尿液和混合的0-24小时尿液样本。将9名受试者的血浆样本按等体积汇总,获得0-12 h的血浆用于代谢物搜索,并按时间点汇总,获得0.5、5和12 h的血浆进行半定量。血浆用乙腈(1:3 v/v血浆-乙腈)去蛋白,然后将上清干燥,重组,注入LC-HRMS/UV分析。尿液样本在分析前只是简单地进行了离心。LC-HRMS/UV用于搜索可预测和未知的代谢物,并估计其相对丰度。代谢产物鉴定采用Orbitrap-MS和MS/MS进行精确质量测定。色谱柱为MACMOD AQ C8 (250 × 4.6 mm, 5-μm),流动相为梯度流动相(a: 10 mm NH4Ac;B:乙腈;流速:0.700 ml/min),总运行时间为65 min。葡萄糖醛酸化代谢在分子中的确切位置通过检测到的迁移现象、重氮甲烷(CH2N2)甲基化和NMR来表征。结果:在人体内检测到原药不变和4个代谢峰:M1为SEP-227900的单氧化代谢物;M2为SEP-227900的葡萄糖醛酸缀合物;M3为SEP-227900的甘氨酸偶联物;M4是M1的甘氨酸共轭物。仅根据质谱(MS和MS/MS)数据无法确定M1中氧化的具体位置。然而,对于主要代谢物M2,通过观察迁移模式、重氮甲烷单甲基化和核磁共振测量等多项实验证据,明确确定了酰基葡萄糖醛酸化。这一确定对新药研发的安全性评价具有重要意义。SEP-227900的甘氨酸缀合物,即M3,被发现是人类尿液中最丰富的代谢物(大约是葡萄糖醛酸水平的3倍)。所有这些加在一起(主要是甘氨酸偶联物和葡萄糖醛酸),导致尿排泄剂量的80%以上(另一项测量显示尿排泄剂量的23%为葡萄糖醛酸)。结论:SEP-227900-甘氨酸偶联物、SEP-227900-葡萄糖醛酸、单氧化代谢物及其相应的甘氨酸偶联物在人体中发现了4种代谢物。葡萄糖醛酸代谢产物鉴定为酰基葡萄糖醛酸。超过80%剂量量的SEP-227900通过尿液排出体外,主要以甘氨酸和葡萄糖醛酸缀合物的形式排出体外。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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