Computationally informed point of departure evaluation for proarrhythmic cardiotoxicity assessment using 3D engineered cardiac microtissues from human iPSC-derived cardiomyocytes.

IF 4.1 3区医学 Q2 TOXICOLOGY

Toxicological Sciences Pub Date : 2025-09-01 DOI:10.1093/toxsci/kfaf094

Mark C Daley, Peter Bronk, Tae Yun Kim, Arvin H Soepriatna, Cao T Tran, Ulrike Mende, Kareen L K Coulombe, Bum-Rak Choi

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引用次数: 0

Abstract

Human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) are a promising new approach for in vitro proarrhythmic cardiotoxicity assessment. However, variation due to differentiation batch, individual sample variation, and non-linear responses to test drugs complicate the prediction of proarrhythmic drug concentrations. This study combines a computational human action potential (AP) model of hERG channel block with experimental data from three-dimensional hiPSC-CM engineered microtissues to optimize point of departure (POD) estimation of drug-induced prolongation of AP duration (APD). Computer simulations predicted that APD prolongation from hERG block follows a logistic curve and that >81% hERG block induced early afterdepolarizations (EADs), which significantly shifted the APD response curve. Curve fitting of APD response by logistic, bilinear breakpoint, and maximal curvature was more accurate prior to EAD onset. Goodness-of-fit testing indicated that logistic regression with ≥6 test concentrations was sufficient to accurately estimate PODs. Power analysis, based on experimental variations between batches (n = 14), molds (n = 57), and microtissues (n = 1701), predicted that PODs from 2 ∼ 3 batches with 10 microtissues per mold using a 5% threshold for APD prolongation detected proarrhythmic cardiotoxicity with a negligible false positive rate. We then applied this POD analysis to hiPSC-CM microtissue data after treatment with well-characterized drugs (i.e. cisapride, ranolazine, quinidine, and verapamil). Using bootstrapping, we estimated PODs and confidence intervals that matched concentrations known to cause proarrhythmic effects in patients. This study identified a robust method for calculating PODs for proarrhythmic cardiotoxicity risk in vitro and developed a framework for experimental design in this and other in vitro platforms.

查看原文本刊更多论文

使用来自人类ipsc衍生心肌细胞的3D工程心脏微组织进行心律失常前心脏毒性评估的计算通知出发点评估。

人诱导多能干细胞衍生的心肌细胞（hiPSC-CMs）是体外评估心律失常前心脏毒性的一种有前景的新方法。然而，由于分化批次、个体样本差异和对试验药物的非线性反应而引起的变化使预测抗心律失常药物浓度复杂化。本研究将hERG通道块的计算人体动作电位（AP）模型与三维hiPSC-CM工程微组织的实验数据相结合，优化药物诱导的AP持续时间（APD）延长的出发点（POD）估计。计算机模拟预测，hERG块的APD延长遵循logistic曲线，>81%的hERG块诱导早期后去极化（EADs），这显著改变了APD响应曲线。用logistic、双线性断点和最大曲率拟合的APD反应曲线在EAD发病前更为准确。拟合优度检验表明，≥6个试验浓度的logistic回归足以准确估计pod。基于批次（n = 14）、霉菌（n = 57）和微组织（n = 1701）之间的实验差异，功率分析预测，使用5%的APD延长阈值，来自2 ~ 3批次（每个霉菌10个微组织）的pod检测出心律失常前心脏毒性，假阳性率可以忽略不计。然后，我们将这种POD分析应用于使用特性良好的药物（即西沙匹利、雷诺嗪、奎尼丁和维拉帕米）治疗后的hiPSC-CM显微组织数据。使用自引导，我们估计pod和置信区间与已知引起患者心律失常影响的浓度相匹配。本研究确定了一种计算体外促心律失常心脏毒性风险pod的可靠方法，并为本研究和其他体外平台的实验设计开发了一个框架。

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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来源期刊

Toxicological Sciences 医学-毒理学

CiteScore

7.70

自引率

7.90%

发文量

118

审稿时长

1.5 months

期刊介绍： The mission of Toxicological Sciences, the official journal of the Society of Toxicology, is to publish a broad spectrum of impactful research in the field of toxicology. The primary focus of Toxicological Sciences is on original research articles. The journal also provides expert insight via contemporary and systematic reviews, as well as forum articles and editorial content that addresses important topics in the field. The scope of Toxicological Sciences is focused on a broad spectrum of impactful toxicological research that will advance the multidisciplinary field of toxicology ranging from basic research to model development and application, and decision making. Submissions will include diverse technologies and approaches including, but not limited to: bioinformatics and computational biology, biochemistry, exposure science, histopathology, mass spectrometry, molecular biology, population-based sciences, tissue and cell-based systems, and whole-animal studies. Integrative approaches that combine realistic exposure scenarios with impactful analyses that move the field forward are encouraged.