Department of Statistics, Texas A&M University, College Station, Texas, USA.
EMD Serono Research Institute, Billerica, Massachusetts, USA.
CPT Pharmacometrics Syst Pharmacol. 2022 Oct;11(10):1371-1381. doi: 10.1002/psp4.12851. Epub 2022 Aug 5.
One of the objectives of oncology phase I dose-escalation studies has been to determine the maximum tolerated dose (MTD). Although MTD is no longer set as the dose for further development in contemporary oncology drug development, MTD determination is still important for informing the therapeutic index. Bayesian adaptive model-based designs are becoming mainstream in oncology first-in-human trials. Herein, we illustrate via simulations the use of systemic exposure in Bayesian adaptive dose-toxicity models to estimate MTD. We extend traditional dose-toxicity models to incorporate pharmacokinetic exposure, which provides information on exposure-toxicity relationships. We pursue dose escalation until the maximum tolerated exposure (corresponding to the MTD) is reached. By leveraging pharmacokinetics, dose escalation considers exposure and interindividual variability on a continuous rather than discrete domain, offering additional information for dose-escalation decisions. To demonstrate this, we generated 1000 simulations (starting dose of 1/25th the reference dose and six dose levels) for several different scenarios. Both rule-based and model-based designs were compared using metrics of potential safety, accuracy, and reliability. The mean results over simulations and different toxicity scenarios showed that model-based designs were better than rule-based methods and that exposure-toxicity model-based methods have the potential to valuably complement dose-toxicity model-based methods. Exposure-toxicity model-based methods had decreased underdose risk accompanied by a relatively smaller increase in overdose risk, resulting in improved net reliability. MTD estimation accuracy was compromised when exposure variability was large, emphasizing the importance of appropriate control of pharmacokinetic variability in phase I dose-escalation studies.
肿瘤学 I 期剂量递增研究的目标之一是确定最大耐受剂量 (MTD)。尽管在当代肿瘤药物开发中,MTD 不再作为进一步开发的剂量,但 MTD 确定对于告知治疗指数仍然很重要。贝叶斯自适应基于模型的设计在肿瘤学首次人体试验中已成为主流。本文通过模拟说明了在贝叶斯自适应剂量-毒性模型中使用全身暴露来估计 MTD。我们将传统的剂量-毒性模型扩展到包含药代动力学暴露,这提供了有关暴露-毒性关系的信息。我们进行剂量递增,直到达到最大耐受暴露(对应于 MTD)。通过利用药代动力学,剂量递增在连续而不是离散的范围内考虑暴露和个体间变异性,为剂量递增决策提供了额外的信息。为了证明这一点,我们针对几种不同情况生成了 1000 次模拟(起始剂量为参考剂量的 1/25)。使用潜在安全性、准确性和可靠性的指标比较了基于规则和基于模型的设计。模拟和不同毒性情况的平均结果表明,基于模型的设计优于基于规则的方法,并且基于暴露-毒性的方法有可能有价值地补充基于剂量-毒性的方法。基于暴露-毒性的方法降低了剂量不足的风险,同时相对增加了剂量过量的风险,从而提高了净可靠性。当暴露变异性较大时,MTD 估计的准确性会受到影响,这强调了在 I 期剂量递增研究中适当控制药代动力学变异性的重要性。
