Phenomenological analysis of simple ion channel block in large populations of uncoupled cardiomyocytes.

IF 0.8 4区 数学 Q4 BIOLOGY Mathematical Medicine and Biology-A Journal of the Ima Pub Date : 2023-06-14 DOI:10.1093/imammb/dqad001
Radostin D Simitev, Antesar Al Dawoud, Muhamad H N Aziz, Rachel Myles, Godfrey L Smith
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Abstract

Current understanding of arrhythmia mechanisms and design of anti-arrhythmic drug therapies hinges on the assumption that myocytes from the same region of a single heart have similar, if not identical, action potential waveforms and drug responses. On the contrary, recent experiments reveal significant heterogeneity in uncoupled healthy myocytes both from different hearts as well as from identical regions within a single heart. In this work, a methodology is developed for quantifying the individual electrophysiological properties of large numbers of uncoupled cardiomyocytes under ion channel block in terms of the parameters values of a conceptual fast-slow model of electrical excitability. The approach is applied to a population of nearly 500 rabbit ventricular myocytes for which action potential duration (APD) before and after the application of the drug nifedipine was experimentally measured (Lachaud et al., 2022, Cardiovasc. Res.). To this end, drug action is represented by a multiplicative factor to an effective ion conductance, a closed form asymptotic expression for APD is derived and inverted to determine model parameters as functions of APD and $\varDelta $APD (drug-induced change in APD) for each myocyte. Two free protocol-related quantities are calibrated to experiment using an adaptive-domain procedure based on an original assumption of optimal excitability. The explicit APD expression and the resulting set of model parameter values allow (a) direct evaluation of conditions necessary to maintain fixed APD or $\varDelta $APD, (b) predictions of the proportion of cells remaining excitable after drug application, (c) predictions of stimulus period dependency and (d) predictions of dose-response curves, the latter being in agreement with additional experimental data.

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大量未偶联心肌细胞中简单离子通道阻滞的现象学分析。
目前对心律失常机制的理解和抗心律失常药物治疗的设计取决于来自单个心脏同一区域的肌细胞具有相似(如果不是相同的话)动作电位波形和药物反应的假设。相反,最近的实验显示,来自不同心脏和单个心脏内相同区域的未偶联健康肌细胞存在显著的异质性。在这项工作中,开发了一种方法,用于根据电兴奋性的概念快-慢模型的参数值来量化离子通道阻滞下大量未耦合心肌细胞的个体电生理特性。该方法应用于近500只兔心室肌细胞,实验测量了应用硝苯地平药物前后的动作电位持续时间(APD) (Lachaud et al., 2022, cardiovascular .)。>)。为此,药物作用由有效离子电导的乘法因子表示,推导出APD的封闭形式渐近表达,并倒置以确定模型参数作为每个肌细胞的APD和$\varDelta $APD(药物诱导的APD变化)的函数。使用基于最优兴奋性原始假设的自适应域程序校准两个与协议相关的自由量。明确的APD表达和由此产生的模型参数值集允许(a)直接评估维持固定APD或$ varDelta $APD所需的条件,(b)预测药物应用后仍可兴奋的细胞比例,(c)预测刺激期依赖性和(d)预测剂量-反应曲线,后者与其他实验数据一致。
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来源期刊
CiteScore
2.20
自引率
0.00%
发文量
15
审稿时长
>12 weeks
期刊介绍: Formerly the IMA Journal of Mathematics Applied in Medicine and Biology. Mathematical Medicine and Biology publishes original articles with a significant mathematical content addressing topics in medicine and biology. Papers exploiting modern developments in applied mathematics are particularly welcome. The biomedical relevance of mathematical models should be demonstrated clearly and validation by comparison against experiment is strongly encouraged. The journal welcomes contributions relevant to any area of the life sciences including: -biomechanics- biophysics- cell biology- developmental biology- ecology and the environment- epidemiology- immunology- infectious diseases- neuroscience- pharmacology- physiology- population biology
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