Elucidation of DPP-4 involvement in systemic distribution and renal reabsorption of linagliptin by PBPK modeling with a cluster Gauss–Newton method

IF 3.1 3区 医学 Q2 MEDICINE, RESEARCH & EXPERIMENTAL
Ryo Nakamura, Takashi Yoshikado, Yasunori Aoki, Yuichi Sugiyama, Koji Chiba
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引用次数: 0

Abstract

The dipeptidyl peptidase-4 (DPP-4) inhibitor linagliptin (LNG) exhibits target-mediated drug disposition (TMDD) in clinical settings, characterized by saturable binding to plasma soluble DPP-4 (sDPP-4) and tissue transmembrane DPP-4 (tDPP-4). Previous studies have indicated that saturable renal reabsorption of LNG contributes to its nonlinear urinary excretion observed in humans and wild-type mice, but not in Dpp-4 knockout mice. To elucidate the mechanisms underlying these complex phenomena, including DPP-4-related renal reabsorption of LNG, we employed physiologically-based pharmacokinetic (PBPK) modeling combined with a cluster Gauss–Newton method (CGNM). The CGNM facilitated the exploration of parameters in rat and human PBPK models for LNG and the determination of parameter identifiability. Through PBPK–CGNM analysis using reported autoradiography data ([14C]-LNG) in wild-type and Dpp-4-deficient rats, DPP-4-specific distributions of LNG in various tissues were clearly differentiated from nonspecific parts. By fitting to human plasma concentrations and urinary and fecal excretions of LNG after intravenous and oral administrations, multiple unknown PBPK parameters were simultaneously estimated by the CGNM. Notably, the amount of tDPP-4 and the reabsorption clearance for LNG–DPP-4 complexes were identifiable, indicating their critical role in explaining the complex nonlinear pharmacokinetics of LNG. Compared with previous PBPK analyses, the CGNM allowed us to incorporate greater model complexity (e.g., consideration of tDPP-4 expressions and in vitro binding kinetics), ultimately resulting in a more accurate reproduction of LNG's TMDD. In conclusion, by considering LNG as a high-affinity probe for DPP-4, comprehensive PBPK–CGNM analyses suggested a dynamic whole-body distribution of DPP-4, including its involvement in the renal reabsorption of LNG.

Abstract Image

利用聚类高斯-牛顿法建立 PBPK 模型,阐明 DPP-4 参与利拉利汀的全身分布和肾脏重吸收。
二肽基肽酶-4(DPP-4)抑制剂利拉利汀(LNG)在临床上表现出靶向介导的药物处置(TMDD),其特点是与血浆可溶性 DPP-4(sDPP-4)和组织跨膜 DPP-4(tDPP-4)的可饱和结合。先前的研究表明,LNG 的肾脏重吸收饱和作用导致了其在人类和野生型小鼠中的非线性尿排泄,但在 Dpp-4 基因敲除小鼠中却没有发现这种作用。为了阐明这些复杂现象背后的机制,包括与 DPP-4 相关的 LNG 肾重吸收,我们采用了基于生理学的药代动力学(PBPK)模型,并结合聚类高斯-牛顿法(CGNM)。CGNM 有助于探索大鼠和人类 LNG PBPK 模型中的参数,并确定参数的可识别性。通过使用报告的野生型大鼠和 Dpp-4 基因缺陷大鼠的自显影数据([14C]-LNG)进行 PBPK-CGNM 分析,LNG 在不同组织中的 DPP-4 特异性分布与非特异性分布被清楚地区分开来。通过拟合 LNG 在静脉注射和口服后的人体血浆浓度以及尿液和粪便排泄量,CGNM 同时估算出了多个未知的 PBPK 参数。值得注意的是,tDPP-4 的数量和 LNG-DPP-4 复合物的重吸收清除率是可识别的,这表明它们在解释 LNG 复杂的非线性药代动力学方面起着至关重要的作用。与以前的 PBPK 分析相比,CGNM 使我们能够纳入更复杂的模型(如考虑 tDPP-4 表达和体外结合动力学),最终更准确地再现 LNG 的 TMDD。总之,通过将 LNG 视为 DPP-4 的高亲和力探针,全面的 PBPK-CGNM 分析表明了 DPP-4 在全身的动态分布,包括参与 LNG 的肾重吸收。
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来源期刊
Cts-Clinical and Translational Science
Cts-Clinical and Translational Science 医学-医学:研究与实验
CiteScore
6.70
自引率
2.60%
发文量
234
审稿时长
6-12 weeks
期刊介绍: Clinical and Translational Science (CTS), an official journal of the American Society for Clinical Pharmacology and Therapeutics, highlights original translational medicine research that helps bridge laboratory discoveries with the diagnosis and treatment of human disease. Translational medicine is a multi-faceted discipline with a focus on translational therapeutics. In a broad sense, translational medicine bridges across the discovery, development, regulation, and utilization spectrum. Research may appear as Full Articles, Brief Reports, Commentaries, Phase Forwards (clinical trials), Reviews, or Tutorials. CTS also includes invited didactic content that covers the connections between clinical pharmacology and translational medicine. Best-in-class methodologies and best practices are also welcomed as Tutorials. These additional features provide context for research articles and facilitate understanding for a wide array of individuals interested in clinical and translational science. CTS welcomes high quality, scientifically sound, original manuscripts focused on clinical pharmacology and translational science, including animal, in vitro, in silico, and clinical studies supporting the breadth of drug discovery, development, regulation and clinical use of both traditional drugs and innovative modalities.
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