Local depletion of large molecule drugs due to target binding in tissue interstitial space

IF 3.1 3区 医学 Q2 PHARMACOLOGY & PHARMACY
Tatiana Zasedateleva, Stephan Schaller, Elizabeth C. M. de Lange, Wilhelmus E. A. de Witte
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Abstract

Drug–target binding determines a drug's pharmacodynamics but can also have a profound impact on a drug's pharmacokinetics, known as target-mediated drug disposition (TMDD). TMDD models describe the influence of drug–target binding and target turnover on unbound drug concentrations and are frequently used for biologics and drugs with nonlinear plasma pharmacokinetics. For drug targets expressed in tissues, the effect of TMDD may not be detected when analyzing plasma concentration curves, but it might still affect tissue concentrations and occupancy. This review aimed to investigate the likeliness of such a scenario by reviewing the literature for a typical range of TMDD parameter values and their impact on local drug concentrations and target occupancy in a whole-body PBPK model with TMDD. Our analysis demonstrated that tissue drug concentrations are impacted and significantly depleted in many physiological scenarios. In contrast, the effect on plasma concentrations is much lower, specifically for smaller organs with lower perfusion. Moreover, in scenarios with fast internalization of the drug–target complex, the distribution of large molecules from plasma to tissue interstitial space emerges as a rate-limiting step for the drug–target interaction. These factors may lead to overpredicting local drug concentrations when considering only plasma pharmacokinetics. A sensitivity analysis revealed the high and not always intuitive impact of drug-specific parameters, including the drug molecule hydrodynamic radius, dissociation constant (Kd), drug–target complex internalization rate constant (kint), and target dissociation rate constant (koff), on the drug's pharmacokinetics. Our analysis demonstrated that tissue TMDD needs to be considered even if plasma pharmacokinetics are linear.

Abstract Image

组织间隙中的靶向结合导致大分子药物的局部耗竭。
药物靶点结合决定了药物的药效学,但也会对药物的药代动力学产生深远影响,这就是所谓的靶点介导药物处置(TMDD)。TMDD 模型描述了药物靶点结合和靶点周转对非结合药物浓度的影响,常用于生物制剂和非线性血浆药代动力学药物。对于在组织中表达的药物靶点,在分析血浆浓度曲线时可能检测不到 TMDD 的影响,但它仍可能影响组织浓度和占据率。本综述旨在通过回顾文献,研究 TMDD 参数值的典型范围及其对带有 TMDD 的全身 PBPK 模型中局部药物浓度和靶点占据率的影响,从而探讨这种情况的可能性。我们的分析表明,在许多生理情况下,组织药物浓度都会受到影响并显著降低。相比之下,对血浆浓度的影响要小得多,特别是对灌注量较低的较小器官。此外,在药物-靶点复合物快速内化的情况下,大分子从血浆到组织间隙的分布成为药物-靶点相互作用的限速步骤。如果只考虑血浆药代动力学,这些因素可能会导致对局部药物浓度的预测过高。敏感性分析表明,药物特异性参数(包括药物分子流体力学半径、解离常数 (Kd)、药物-靶点复合物内化速率常数 (kint) 和靶点解离速率常数 (koff))对药物药代动力学的影响很大,而且并不总是很直观。我们的分析表明,即使血浆药代动力学是线性的,也需要考虑组织 TMDD。
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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来源期刊
CiteScore
5.00
自引率
11.40%
发文量
146
审稿时长
8 weeks
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