普罗帕酮对kcnh2相关短QT综合征的影响:一项模型研究

2016 IEEE International Conference on Bioinformatics and Biomedicine (BIBM) Pub Date : 2016-12-01 DOI:10.1109/BIBM.2016.7822744

Cunjin Luo, Kuanquan Wang, Henggui Zhang

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引用次数: 1

摘要

已确定的遗传性短QT综合征(SQTS)与心律失常和猝死的风险增加有关。本研究旨在利用ten Tusscher和Panfilov建立的心脏多尺度生物物理详细模型，探讨普罗帕酮对kcnh2相关的短QT综合征(SQT1)的潜在影响。为了模拟正常细胞和SQT1细胞的药理作用，普罗帕酮降低了离子电导率。基于McPate等人的实验数据，采用剂量依赖性IKr阻断法模拟普罗帕酮的药理作用。通过分析动作电位(AP)谱和1D组织水平来预测普罗帕酮对SQT1的影响。低、高剂量普罗帕酮均可延长SQT1细胞APD和QT间期。提示大剂量普罗帕酮治疗SQT1疗效优越。然而，普罗帕酮在低剂量时没有显著改变APD或QT间期，而在高剂量时明显缩短。我们的模拟数据显示，普罗帕酮对SQT1具有剂量依赖性的抗心律失常作用，对健康细胞具有促心律失常作用。这些计算机模拟有助于更好地理解使用普罗帕酮的健康或SQT1患者心律失常发生或终止的潜在机制。

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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Effects of propafenone on KCNH2-linked short QT syndrome: A modelling study

The identified genetic short QT syndrome (SQTS) is associated with an increased risk of arrhythmia and sudden death. This study was to investigate the potential effects of propafenone on KCNH2-linked short QT syndrome (SQT1) using a multi-scale biophysically detailed model of the heart developed by ten Tusscher and Panfilov. The ion electrical conductivities were reduced by propafenone in order to simulate the pharmacological effects in healthy and SQT1 cells. Based on the experimental data of McPate et al., the pharmacological effect of propafenone was modelled by dose-dependent IKr blocking. Action potential (AP) profiles and 1D tissue level were analyzed to predict the effects of propafenone on SQT1. Both low- and high- dose of propafenone prolonged APD and QT interval in SQT1 cells. It suggests the superior efficacy of high dose of propafenone on SQT1. However, propafenone did not significantly alter the healthy APD or QT interval at low dose, whereas markedly shortened them at high dose. Our simulation data show that propafenone has a dose-dependently anti-arrhythmic effect on SQT1, and a pro-arrhythmic effect on healthy cells. These computer simulations help to better understand the underlying mechanisms responsible for the initiation or termination of arrhythmias in healthy or SQT1 patients using propafenone.

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2016 IEEE International Conference on Bioinformatics and Biomedicine (BIBM)

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