Roche Pharma Research and Early Development, Pharmaceutical Sciences, Roche Innovation Center Basel, F. Hoffmann-La Roche Ltd., Basel, Switzerland (S.S., C.F.); Boehringer Ingelheim Pharma GmbH & Co. KG, Biberach a.d. Riß, Germany (B.B., F.R.); Drug Metabolism and Pharmacokinetics Department, Takeda Pharmaceutical International Co., Cambridge, Massachusetts (S.K.C., J.Y.); Genentech, Inc., Drug Metabolism and Pharmacokinetics, South San Francisco, California (C.E.C.A.H., S.C.K.); Bristol-Myers Squibb Pharmaceutical Co., Princeton, New Jersey (W.G.H.); Research Division, Chugai Pharmaceutical Co., Ltd., Gotemba, Japan (F.I.); PK Sciences (ADME), Novartis Institutes for Biomedical Research, Basel, Switzerland (A.D.J.); PK Sciences (ADME), Novartis Institutes for Biomedical Research, One Health Plaza, East Hanover, New Jersey (M.K.); Unilabs York Bioanalytical Solutions, Discovery Park House, Discovery Park, Sandwich, Kent, United Kingdom (A.N.R.N); Drug Metabolism, Pharmacokinetics and Clinical Pharmacology, Agios, Cambridge, Massachusetts (C.P.); Merck Biopharma, Quantitative Pharmacology and Drug Disposition, NCE Drug Disposition, Darmstadt, Germany (H.S., P.S.); and Pfizer, Pharmacokinetics, Dynamics and Metabolism, Groton, Connecticut (D.K.S., S.T., R.S.O.)
Roche Pharma Research and Early Development, Pharmaceutical Sciences, Roche Innovation Center Basel, F. Hoffmann-La Roche Ltd., Basel, Switzerland (S.S., C.F.); Boehringer Ingelheim Pharma GmbH & Co. KG, Biberach a.d. Riß, Germany (B.B., F.R.); Drug Metabolism and Pharmacokinetics Department, Takeda Pharmaceutical International Co., Cambridge, Massachusetts (S.K.C., J.Y.); Genentech, Inc., Drug Metabolism and Pharmacokinetics, South San Francisco, California (C.E.C.A.H., S.C.K.); Bristol-Myers Squibb Pharmaceutical Co., Princeton, New Jersey (W.G.H.); Research Division, Chugai Pharmaceutical Co., Ltd., Gotemba, Japan (F.I.); PK Sciences (ADME), Novartis Institutes for Biomedical Research, Basel, Switzerland (A.D.J.); PK Sciences (ADME), Novartis Institutes for Biomedical Research, One Health Plaza, East Hanover, New Jersey (M.K.); Unilabs York Bioanalytical Solutions, Discovery Park House, Discovery Park, Sandwich, Kent, United Kingdom (A.N.R.N); Drug Metabolism, Pharmacokinetics and Clinical Pharmacology, Agios, Cambridge, Massachusetts (C.P.); Merck Biopharma, Quantitative Pharmacology and Drug Disposition, NCE Drug Disposition, Darmstadt, Germany (H.S., P.S.); and Pfizer, Pharmacokinetics, Dynamics and Metabolism, Groton, Connecticut (D.K.S., S.T., R.S.O.).
Drug Metab Dispos. 2018 Jun;46(6):865-878. doi: 10.1124/dmd.117.079848. Epub 2018 Feb 27.
Since the introduction of metabolites in safety testing (MIST) guidance by the Food and Drug Administration in 2008, major changes have occurred in the experimental methods for the identification and quantification of metabolites, ways to evaluate coverage of metabolites, and the timing of critical clinical and nonclinical studies to generate this information. In this cross-industry review, we discuss how the increased focus on human drug metabolites and their potential contribution to safety and drug-drug interactions has influenced the approaches taken by industry for the identification and quantitation of human drug metabolites. Before the MIST guidance was issued, the method of choice for generating comprehensive metabolite profile was radio chromatography. The MIST guidance increased the focus on human drug metabolites and their potential contribution to safety and drug-drug interactions and led to changes in the practices of drug metabolism scientists. In addition, the guidance suggested that human metabolism studies should also be accelerated, which has led to more frequent determination of human metabolite profiles from multiple ascending-dose clinical studies. Generating a comprehensive and quantitative profile of human metabolites has become a more urgent task. Together with technological advances, these events have led to a general shift of focus toward earlier human metabolism studies using high-resolution mass spectrometry and to a reduction in animal radiolabel absorption/distribution/metabolism/excretion studies. The changes induced by the MIST guidance are highlighted by six case studies included herein, reflecting different stages of implementation of the MIST guidance within the pharmaceutical industry.
自 2008 年美国食品和药物管理局(FDA)发布代谢物在安全性测试中的应用(MIST)指导原则以来,代谢物的鉴定和定量的实验方法、评估代谢物覆盖范围的方法以及生成这些信息的关键性临床和非临床研究的时间安排都发生了重大变化。在本次跨行业综述中,我们讨论了对人体药物代谢物及其对安全性和药物相互作用的潜在贡献的日益关注如何影响行业对人体药物代谢物的鉴定和定量方法。在 MIST 指导原则发布之前,生成全面代谢物图谱的首选方法是放射性色谱法。MIST 指导原则增加了对人体药物代谢物及其对安全性和药物相互作用的潜在贡献的关注,并导致药物代谢科学家的实践发生了变化。此外,该指导原则还建议加速人体代谢研究,这导致了更频繁地从多个递增剂量临床研究中确定人体代谢物图谱。生成全面和定量的人体代谢物图谱已成为一项更紧迫的任务。与技术进步一起,这些事件导致了使用高分辨率质谱法进行更早的人体代谢研究的普遍关注,并减少了动物放射性标记吸收/分布/代谢/排泄研究。本文通过六个案例研究突出了 MIST 指导原则所带来的变化,这些案例反映了制药行业在实施 MIST 指导原则的不同阶段。
