An integrated quantitative systems pharmacology virtual population approach for calibration with oncology efficacy endpoints.

IF 3.1 3区 医学 Q2 PHARMACOLOGY & PHARMACY CPT: Pharmacometrics & Systems Pharmacology Pub Date : 2024-11-07 DOI:10.1002/psp4.13270
Nathan Braniff, Tanvi Joshi, Tyler Cassidy, Michael Trogdon, Rukmini Kumar, Kamrine Poels, Richard Allen, Cynthia J Musante, Blerta Shtylla
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Abstract

In drug development, quantitative systems pharmacology (QSP) models are becoming an increasingly important mathematical tool for understanding response variability and for generating predictions to inform development decisions. Virtual populations are essential for sampling uncertainty and potential variability in QSP model predictions, but many clinical efficacy endpoints can be difficult to capture with QSP models that typically rely on mechanistic biomarkers. In oncology, challenges are particularly significant when connecting tumor size with time-to-event endpoints like progression-free survival while also accounting for censoring due to consent withdrawal, loss in follow-up, or safety criteria. Here, we expand on our prior work and propose an extended virtual population selection algorithm that can jointly match tumor burden dynamics and progression-free survival times in the presence of censoring. We illustrate the core components of our algorithm through simulation and calibration of a signaling pathway model that was fitted to clinical data for a small molecule targeted inhibitor. This methodology provides an approach that can be tailored to other virtual population simulations aiming to match survival endpoints for solid-tumor clinical datasets.

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用于校准肿瘤疗效终点的综合定量系统药理学虚拟群体方法。
在药物开发过程中,定量系统药理学(QSP)模型正日益成为一种重要的数学工具,用于了解反应的变异性和进行预测,为开发决策提供依据。虚拟人群对于 QSP 模型预测中的不确定性和潜在变异性取样至关重要,但许多临床疗效终点很难通过 QSP 模型来捕捉,因为 QSP 模型通常依赖于机理生物标志物。在肿瘤学领域,将肿瘤大小与无进展生存期等时间到事件终点联系起来,同时考虑到因同意撤回、随访丧失或安全标准而导致的删减,所面临的挑战尤为严峻。在此,我们扩展了之前的工作,并提出了一种扩展的虚拟群体选择算法,该算法可以在存在剔除的情况下联合匹配肿瘤负荷动态和无进展生存时间。我们通过模拟和校准信号通路模型来说明我们算法的核心组成部分,该模型与一种小分子靶向抑制剂的临床数据相匹配。这种方法可用于其他虚拟群体模拟,以匹配实体瘤临床数据集的生存终点。
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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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