An Electromechanical Model-Based Study on the Dosage Effects of Ranolazine in Treating Failing HCM Cardiomyocyte.

IF 2.3 4区医学 Q3 BIOPHYSICS

Cellular and molecular bioengineering Pub Date : 2025-02-21 eCollection Date: 2025-04-01 DOI:10.1007/s12195-025-00842-5

Taiwei Liu, Mi Zhou, Fuyou Liang

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引用次数: 0

Abstract

Background and objective: Hypertrophic cardiomyopathy (HCM) is associated with a significant risk of progression to heart failure (HF). Extensive experimental and clinical research has highlighted the therapeutic benefits of ranolazine in alleviating electrophysiological abnormalities and arrhythmias in the context of HCM and HF. Despite these findings, there is a shortage of studies examining the electromechanical responses of failing HCM cardiomyocytes to ranolazine and the impact of ranolazine dosage on outcomes across varying degrees of HF. This study aims to systematically address these issues.

Methods: A computational modeling approach was utilized to quantify alterations in electromechanical variables within failing HCM cardiomyocytes subsequent to ranolazine treatment. The model parameters were calibrated against extant literature data to delineate the spectrum of HF severities and the changes in ion channels following the administration of various doses of ranolazine.

Results: The inhibition of the augmented late Na⁺ current in failing HCM cardiomyocyte with an adequate amount of ranolazine was found to be effective in alleviating electrophysiological abnormalities (e.g., prolongation of action potential (AP), Ca²⁺ overload in diastole), which contributed to improving the diastolic function of the cardiomyocyte, albeit with a modest negative effect on the systolic function. A threshold drug dose was identified for achieving a significant normalization of the overall electromechanical profile. The threshold drug dose for effective therapy was observed to be contingent upon the severity of HF and the status of certain key ion channels. Furthermore, it was determined that an increase of the drug dose beyond the threshold did not yield substantial additional improvements in the principal electromechanical variables.

Conclusions: The study demonstrated the presence of a threshold dose of ranolazine for effective treatment of failing HCM cardiomyocyte, and further established that this threshold is influenced by the severity of HF and the functional status of key ion channels. These findings may serve as theoretical evidence for comprehending the mechanisms underlying ranolazine's therapeutic efficacy in treating failing HCM hearts. Moreover, the study underscores the potential clinical value of personalized dosing strategies.

Supplementary information: The online version contains supplementary material available at 10.1007/s12195-025-00842-5.

查看原文本刊更多论文

雷诺嗪治疗衰竭HCM心肌细胞剂量效应的机电模型研究。

背景和目的：肥厚性心肌病（HCM）与进展为心力衰竭（HF）的显著风险相关。大量的实验和临床研究强调了雷诺嗪在缓解HCM和HF的电生理异常和心律失常方面的治疗益处。尽管有这些发现，但关于衰竭HCM心肌细胞对雷诺嗪的机电反应以及雷诺嗪剂量对不同程度HF结局的影响的研究还很缺乏。本研究旨在系统地解决这些问题。方法：采用计算建模方法量化雷诺嗪治疗后衰竭HCM心肌细胞内机电变量的变化。根据现有文献数据对模型参数进行校准，以描绘不同剂量雷诺嗪后HF严重程度的频谱和离子通道的变化。结果：适量的雷诺氮唑抑制衰竭HCM心肌细胞的晚期Na+电流增强，可有效缓解电生理异常（例如，动作电位延长（AP），舒张期Ca2+超载），这有助于改善心肌细胞的舒张功能，尽管对收缩功能有适度的负面影响。确定了一个阈值药物剂量，以实现总体机电剖面的显著正常化。观察到有效治疗的阈值药物剂量取决于HF的严重程度和某些关键离子通道的状态。此外，确定超过阈值的药物剂量的增加不会对主要机电变量产生实质性的额外改善。结论：本研究证实雷诺嗪存在一个阈值剂量，可有效治疗衰竭HCM心肌细胞，并进一步确定该阈值受HF严重程度和关键离子通道功能状态的影响。这些发现可能为理解雷诺嗪治疗衰竭HCM心脏疗效的机制提供理论依据。此外，该研究强调了个性化给药策略的潜在临床价值。补充信息：在线版本包含补充资料，可在10.1007/s12195-025- 00845 -5获得。

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

Cellular and molecular bioengineering 生物-生物物理

CiteScore

5.60

自引率

3.60%

发文量

审稿时长

>12 weeks

期刊介绍： The field of cellular and molecular bioengineering seeks to understand, so that we may ultimately control, the mechanical, chemical, and electrical processes of the cell. A key challenge in improving human health is to understand how cellular behavior arises from molecular-level interactions. CMBE, an official journal of the Biomedical Engineering Society, publishes original research and review papers in the following seven general areas: Molecular: DNA-protein/RNA-protein interactions, protein folding and function, protein-protein and receptor-ligand interactions, lipids, polysaccharides, molecular motors, and the biophysics of macromolecules that function as therapeutics or engineered matrices, for example. Cellular: Studies of how cells sense physicochemical events surrounding and within cells, and how cells transduce these events into biological responses. Specific cell processes of interest include cell growth, differentiation, migration, signal transduction, protein secretion and transport, gene expression and regulation, and cell-matrix interactions. Mechanobiology: The mechanical properties of cells and biomolecules, cellular/molecular force generation and adhesion, the response of cells to their mechanical microenvironment, and mechanotransduction in response to various physical forces such as fluid shear stress. Nanomedicine: The engineering of nanoparticles for advanced drug delivery and molecular imaging applications, with particular focus on the interaction of such particles with living cells. Also, the application of nanostructured materials to control the behavior of cells and biomolecules.