Aycock Kenneth I, Battisti Tom, Peterson Ashley, Yao Jiang, Kreuzer Steven, Capelli Claudio, Pant Sanjay, Pathmanathan Pras, Hoganson David M, Levine Steve M, Craven Brent A
Office of Science and Engineering Laboratories, Center for Devices and Radiological Health, United States Food and Drug Administration, Silver Spring, MD, United States.
Dassault Systèmes, Waltham, MA, United States.
Front Med (Lausanne). 2024 Aug 12;11:1433372. doi: 10.3389/fmed.2024.1433372. eCollection 2024.
Computational models of patients and medical devices can be combined to perform an clinical trial (ISCT) to investigate questions related to device safety and/or effectiveness across the total product life cycle. ISCTs can potentially accelerate product development by more quickly informing device design and testing or they could be used to refine, reduce, or in some cases to completely replace human subjects in a clinical trial. There are numerous potential benefits of ISCTs. An important caveat, however, is that an ISCT is a virtual representation of the real world that has to be shown to be credible before being relied upon to make decisions that have the potential to cause patient harm. There are many challenges to establishing ISCT credibility. ISCTs can integrate many different submodels that potentially use different modeling types (e.g., physics-based, data-driven, rule-based) that necessitate different strategies and approaches for generating credibility evidence. ISCT submodels can include those for the medical device, the patient, the interaction of the device and patient, generating virtual patients, clinical decision making and simulating an intervention (e.g., device implantation), and translating acute physics-based simulation outputs to health-related clinical outcomes (e.g., device safety and/or effectiveness endpoints). Establishing the credibility of each ISCT submodel is challenging, but is nonetheless important because inaccurate output from a single submodel could potentially compromise the credibility of the entire ISCT. The objective of this study is to begin addressing some of these challenges and to identify general strategies for establishing ISCT credibility. Most notably, we propose a hierarchical approach for assessing the credibility of an ISCT that involves systematically gathering credibility evidence for each ISCT submodel in isolation before demonstrating credibility of the full ISCT. Also, following FDA Guidance for assessing computational model credibility, we provide suggestions for ways to clearly describe each of the ISCT submodels and the full ISCT, discuss considerations for performing an ISCT model risk assessment, identify common challenges to demonstrating ISCT credibility, and present strategies for addressing these challenges using our proposed hierarchical approach. Finally, in the Appendix we illustrate the many concepts described here using a hypothetical ISCT example.
患者和医疗设备的计算模型可以结合起来进行虚拟临床试验(ISCT),以研究整个产品生命周期中与设备安全性和/或有效性相关的问题。ISCT有可能通过更快地为设备设计和测试提供信息来加速产品开发,或者可用于完善、减少,甚至在某些情况下完全取代临床试验中的人体受试者。ISCT有许多潜在益处。然而,一个重要的警告是,ISCT是现实世界的虚拟表示,在依靠它做出可能对患者造成伤害的决策之前,必须证明其可信性。建立ISCT的可信性面临许多挑战。ISCT可以整合许多不同的子模型,这些子模型可能使用不同的建模类型(例如,基于物理的、数据驱动的、基于规则的),这就需要不同的策略和方法来生成可信性证据。ISCT子模型可以包括用于医疗设备、患者、设备与患者的相互作用、生成虚拟患者、临床决策以及模拟干预(例如,设备植入),以及将基于物理的急性模拟输出转化为与健康相关的临床结果(例如,设备安全性和/或有效性终点)的模型。建立每个ISCT子模型的可信性具有挑战性,但仍然很重要,因为单个子模型的不准确输出可能会损害整个ISCT的可信性。本研究的目的是开始应对其中一些挑战,并确定建立ISCT可信性的一般策略。最值得注意的是,我们提出了一种分层方法来评估ISCT的可信性,该方法包括在证明整个ISCT的可信性之前,先单独系统地收集每个ISCT子模型的可信性证据。此外,遵循FDA评估计算模型可信性的指南,我们提供了一些方法的建议,以清晰描述每个ISCT子模型和整个ISCT,讨论进行ISCT模型风险评估的注意事项,识别证明ISCT可信性的常见挑战,并提出使用我们提出的分层方法应对这些挑战的策略。最后,在附录中,我们用一个假设的ISCT示例来说明这里描述的许多概念。
