Quantum mechanical aspects of cardiac arrhythmias: A mathematical model and pathophysiological implications

IF 1.1 Q4 BIOPHYSICS
Mohammed I. A. Ismail, Abdallah Barjas Qaswal, Mo'ath Bani Ali, Anas Hamdan, Ahmad Alghrabli, Mohamad Harb, Dina Ibrahim, Mohammad Nayel Al-Jbour, Ibrahim Almobaiden, Khadija Alrowwad, Esra'a Jaibat, Mira Alrousan, Mohammad Banifawaz, Mohammed A. M. Aldrini, Aya Daikh, Nour Aldarawish, Ahmad Alabedallat, Ismail M. I. Ismail, Lou'i Al-Husinat
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引用次数: 0

Abstract

Cardiac arrhythmias are serious myocardial electrical disturbances that affect the rate and rhythm of heartbeats. Despite the rapidly accumulating data about the pathophysiology and the treatment, new insights are required to improve the overall clinical outcome of patients with cardiac arrhythmias. Three major arrhythmogenic processes can contribute to the pathogenesis of cardiac arrhythmias; 1) enhanced automaticity, 2) afterdepolarization-triggered activity and 3) reentry circuits. The mathematical model of the quantum tunneling of ions is used to investigate these mechanisms from a quantum mechanical perspective. The mathematical model focuses on applying the principle of quantum tunneling to sodium and potassium ions. This implies that these ions have a non-zero probability of passing through the gate, which has an energy that is higher than the kinetic energy of ions. Our mathematical findings indicate that, under pathological conditions, which affect ion channels, the quantum tunneling of sodium and potassium ions is augmented. This augmentation creates a state of hyperexcitability that can explain the enhanced automaticity, after depolarizations that are associated with triggered activity and a reentry circuit. Our mathematical findings stipulate that the augmented and thermally assisted quantum tunneling of sodium and potassium ions can depolarize the membrane potential and trigger spontaneous action potentials, which may explain the automaticity and afterdepolarization. Furthermore, the quantum tunneling of potassium ions during an action potential can provide a new insight regarding the formation of a reentry circuit. Introducing these quantum mechanical aspects may improve our understanding of the pathophysiological mechanisms of cardiac arrhythmias and, thus, contribute to finding more effective anti-arrhythmic drugs.

心律失常的量子力学方面:数学模型和病理生理意义
& lt; abstract>心律失常是严重的心肌电干扰,影响心跳的速率和节奏。尽管关于病理生理和治疗的数据迅速积累,但需要新的见解来改善心律失常患者的整体临床结果。三种主要的致心律失常过程可能导致心律失常的发病;1)增强的自动性,2)后去极化触发的活动,3)再入电路。利用离子量子隧穿的数学模型,从量子力学的角度研究了这些机制。该数学模型着重于将量子隧穿原理应用于钠离子和钾离子。这意味着这些离子通过栅极的概率非为零,栅极的能量高于离子的动能。我们的数学结果表明,在影响离子通道的病理条件下,钠离子和钾离子的量子隧穿增强。这种增强产生了一种超兴奋状态,这可以解释与触发活动和再入回路相关的去极化后自动性的增强。我们的数学结果表明,钠离子和钾离子的增强和热辅助量子隧穿可以使膜电位去极化并触发自发动作电位,这可能解释了膜电位的自动性和后去极化。此外,钾离子在动作电位期间的量子隧穿可以为再入电路的形成提供新的见解。引入这些量子力学方面可以提高我们对心律失常病理生理机制的理解,从而有助于发现更有效的抗心律失常药物。& lt; / abstract>
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来源期刊
AIMS Biophysics
AIMS Biophysics BIOPHYSICS-
CiteScore
2.40
自引率
20.00%
发文量
16
审稿时长
8 weeks
期刊介绍: AIMS Biophysics is an international Open Access journal devoted to publishing peer-reviewed, high quality, original papers in the field of biophysics. We publish the following article types: original research articles, reviews, editorials, letters, and conference reports. AIMS Biophysics welcomes, but not limited to, the papers from the following topics: · Structural biology · Biophysical technology · Bioenergetics · Membrane biophysics · Cellular Biophysics · Electrophysiology · Neuro-Biophysics · Biomechanics · Systems biology
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