Elucidating the challenges with categorizing drugs that block cardiac sodium channels − The impact of temperature on drug-cardiac sodium channel interactions

IF 1.8 4区医学 Q4 PHARMACOLOGY & PHARMACY

Journal of pharmacological and toxicological methods Pub Date : 2025-09-01 DOI:10.1016/j.vascn.2025.107805

Huimei Yu, Claudia Alvarez Baron, Jun Zhao, Jose Vicente, Lars Johannesen, Wendy W. Wu, Donglin Guo

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引用次数: 0

Abstract

Class I antiarrhythmic drugs (AADs) are categorized into Class IA, IB and IC subgroups based on their distinct electrophysiological consequences on the heart that are thought to arise from distinct interaction characteristics with cardiac sodium channels (Na_V). The original categorization centered on assessing electrophysiological features including drug effects on the maximal upstroke velocity of action potential (AP), AP duration, and effective refractory period using ventricular preparations from animals performed at physiological temperature (PT). Subsequently, categorization assessing drug binding and unbinding kinetics in patch clamp assays in Na_V overexpressing cells at room temperature (RT) was proposed. Temperature is known to impact Na_V gating, hence potentially affecting use- and state-dependence of drug interactions. Whether RT patch clamp data adequately capture drug-Na_V interaction characteristics that allows for the same subgroup categorization as in the original categorization using native tissues is unclear. Similarly, a systematic assessment of the effects on other cardiac ion channels following best practices is also lacking. This study characterized drug-Na_V (Na_V1.5) interaction characteristics of quinidine (IA), mexiletine (IB) and flecainide (IC) at near PT and RT using manual patch clamp. Additionally, drug's potencies on inhibiting the late Na_V1.5, hERG, and Ca_V1.2 currents were conducted at near PT following ICH S7B Q&A 2.1 best practices. At RT, use-dependent block of Na_V1.5 currents and unbinding kinetics were fastest for mexiletine, followed by quinidine, and flecainide. At near PT, use-dependent block and unbinding kinetics of quinidine remained faster than flecainide. Surprisingly, mexiletine showed no use-dependent block and no apparent unbinding at near PT. Preliminary assessment revealed that the three drugs have different effects on other cardiac ionic currents. The three Class I AADs showed distinct interaction characteristics with Na_V1.5 currents. Importantly, temperature-dependent binding and unbinding kinetics for mexiletine and different effects on other cardiac ionic currents for all three drugs were observed. These data provide mechanistic insights to drug-induced changes in myocyte APs that led to Class I AADs categorization, and lay a foundation for future research to identify the commonalities and differences of Class I AADs interacting with Na_V1.5 channels.

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阐明阻断心脏钠通道的药物分类的挑战-温度对药物-心脏钠通道相互作用的影响

一类抗心律失常药物（AADs）被分为IA类、IB类和IC类，基于它们对心脏的不同电生理后果，这些后果被认为是由与心脏钠通道（NaV）的不同相互作用特征引起的。最初的分类集中于评估电生理特征，包括药物对动作电位（AP）最大上冲程速度的影响，AP持续时间，以及在生理温度（PT）下使用动物心室制剂的有效不应期。随后，在室温（RT）下，提出了膜片钳法在NaV过表达细胞中评估药物结合和解除结合动力学的分类。已知温度会影响导航门控，因此可能影响药物相互作用的使用和状态依赖性。RT膜片钳数据是否充分捕获药物- nav相互作用特征，从而允许与使用原生组织的原始分类相同的亚组分类尚不清楚。同样，对其他心脏离子通道影响的系统评估也缺乏最佳实践。本研究采用手动膜片钳对奎尼丁（IA）、美西汀（IB）和氟卡奈（IC）在PT和RT前后的药物- nav （NaV1.5）相互作用特征进行了研究。此外，药物抑制晚期NaV1.5、hERG和CaV1.2电流的效力在接近PT时按照ICH S7B Q&；A 2.1最佳实践进行。在RT下，使用依赖性的NaV1.5电流阻滞和解结合动力学最快的是美西汀，其次是奎尼丁和氟屈奈。在接近PT时，奎尼丁的使用依赖阻滞和解结合动力学仍然比氟喹奈快。令人惊讶的是，美西汀在PT附近没有表现出使用依赖性阻滞和明显的解结合。初步评估显示，这三种药物对其他心脏离子电流有不同的影响。3种I类AADs与NaV1.5电流表现出明显的相互作用特征。重要的是，观察了美西汀的温度依赖性结合和解结合动力学以及这三种药物对其他心脏离子电流的不同影响。这些数据为药物诱导的肌细胞APs变化导致I类AADs分类提供了机制见解，并为进一步研究识别与NaV1.5通道相互作用的I类AADs的共性和差异奠定了基础。

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来源期刊

Journal of pharmacological and toxicological methods PHARMACOLOGY & PHARMACY-TOXICOLOGY

CiteScore

3.60

自引率

10.50%

发文量

审稿时长

26 days

期刊介绍： Journal of Pharmacological and Toxicological Methods publishes original articles on current methods of investigation used in pharmacology and toxicology. Pharmacology and toxicology are defined in the broadest sense, referring to actions of drugs and chemicals on all living systems. With its international editorial board and noted contributors, Journal of Pharmacological and Toxicological Methods is the leading journal devoted exclusively to experimental procedures used by pharmacologists and toxicologists.