Optimization of the O'Hara-Rudy Model of Human Ventricular Action Potential With Respect to Electrolyte Concentrations and Rate Dependence

2018 Computing in Cardiology Conference (CinC) Pub Date : 2018-12-30 DOI:10.22489/CinC.2018.333

C. Bartolucci, Elisa Passini, S. Severi

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引用次数: 2

Abstract

The “Comprehensive In vitro Proarrhythmia Assay” (CiPA) initiative proposes a new mechanistic, model-informed, approach to cardiac safety assessment of new drugs, an approach made possible by a deeper understanding of the ionic currents that play a role in QTc prolongation and in the development of torsades de pointes (TdP). In defining a new paradigm in the field of cardiac safety the proarrhythmic risk would be primarily assessed using preclinical in vitro and in silico human models. In this scenario the best cellular computer model(s) would have to be selected and if necessary improved. The aim of this study has been the upgrade of the most updated human ventricular cell model in order to: 1) correct its response to [Ca2+]∘changes; 2) replicate the steady state action potential duration (APD) rate dependency and 3) the S1S2 APD restitution. The presented model has been validated against the same experimental data used for the original one, in order to verify its consistency and enforce its integration in the use of in silico models for predicting clinical risk of drug-induced arrhythmias.

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关于电解质浓度和速率依赖性的人体心室动作电位的O'Hara-Rudy模型的优化

“综合体外心律失常检测”(CiPA)倡议提出了一种新的机制，模型信息，新药心脏安全性评估的方法，这种方法通过更深入地了解在QTc延长和点扭转(TdP)发展中发挥作用的离子电流而成为可能。在定义心脏安全领域的新范式时，将主要使用临床前体外和计算机人体模型评估促心律失常风险。在这种情况下，必须选择最佳的蜂窝式计算机模型，并在必要时进行改进。这项研究的目的是对最新的人类心室细胞模型进行升级，以便:1)修正其对[Ca2+]°变化的反应;2)复制稳态动作电位持续时间(APD)速率依赖性和3)S1S2 APD恢复。为了验证模型的一致性，并将其整合到预测药物性心律失常临床风险的计算机模型中，本模型已与原始模型进行了相同的实验数据验证。

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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2018 Computing in Cardiology Conference (CinC)

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