通过机制模拟降低临床试验失败的风险。

IF 4.1 Q2 IMMUNOLOGY Immunotherapy advances Pub Date : 2022-08-23 eCollection Date: 2022-01-01 DOI:10.1093/immadv/ltac017
Liam V Brown, Jonathan Wagg, Rachel Darley, Andy van Hateren, Tim Elliott, Eamonn A Gaffney, Mark C Coles
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引用次数: 3

摘要

药物开发通常包括临床前实验、临床试验和统计数据驱动分析的组合。临床开发后期的治疗失败每年给制药业造成数十亿美元的损失。临床试验模拟是一种关键的降低风险策略,将它们与机制模型相结合,可以检验失败机制的假设,并改进试验设计。t细胞活化模型用于模拟短肽癌症疫苗IMA901的临床试验,说明了这一点。模拟结果与观察结果一致,并预测反应受到肽脱落率、肽竞争树突状细胞(DC)结合和DC迁移时间的限制。这些见解被用于假设可改善疗效结果的替代试验设计。该框架说明了机制模型如何补充临床、实验和数据驱动的研究,以理解、测试和改进试验设计,以及人类和小鼠之间的结果如何不同。
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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De-risking clinical trial failure through mechanistic simulation.

Drug development typically comprises a combination of pre-clinical experimentation, clinical trials, and statistical data-driven analyses. Therapeutic failure in late-stage clinical development costs the pharmaceutical industry billions of USD per year. Clinical trial simulation represents a key derisking strategy and combining them with mechanistic models allows one to test hypotheses for mechanisms of failure and to improve trial designs. This is illustrated with a T-cell activation model, used to simulate the clinical trials of IMA901, a short-peptide cancer vaccine. Simulation results were consistent with observed outcomes and predicted that responses are limited by peptide off-rates, peptide competition for dendritic cell (DC) binding, and DC migration times. These insights were used to hypothesise alternate trial designs predicted to improve efficacy outcomes. This framework illustrates how mechanistic models can complement clinical, experimental, and data-driven studies to understand, test, and improve trial designs, and how results may differ between humans and mice.

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