Experimental studies of spiral wave teleportation in a light sensitive Belousov-Zhabotinsky system.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-09-01 DOI:10.1063/5.0216649

Shannyn A Tyler, David Mersing, Flavio H Fenton, Mark R Tinsley, Kenneth Showalter

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Abstract

Cardiac arrythmias are a form of heart disease that contributes toward making heart disease a significant cause of death globally. Irregular rhythms associated with cardiac arrythmias are thought to arise due to singularities in the heart tissue that generate reentrant waves in the underlying excitable medium. A normal approach to removing such singularities is to apply a high voltage electric shock, which effectively resets the phase of the cardiac cells. A concern with the use of this defibrillation technique is that the high-energy shock can cause lasting damage to the heart tissue. Various theoretical works have investigated lower-energy alternatives to defibrillation. In this work, we demonstrate the effectiveness of a low-energy defibrillation method in an experimental 2D Belousov-Zhabotinsky (BZ) system. When implemented as a 2D spatial reaction, the BZ reaction serves as an effective analog of general excitable media and supports regular and reentrant wave activity. The defibrillation technique employed involves targeted low-energy perturbations that can be used to "teleport" and/or annihilate singularities present in the excitable BZ medium.

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光敏贝洛索夫-扎博金斯基系统中螺旋波远距离传输的实验研究。

心律失常是心脏病的一种形式，它使心脏病成为全球死亡的重要原因。与心律失常相关的不规则节律被认为是由于心脏组织中的奇异点在底层可兴奋介质中产生了重入波。消除这种奇异点的通常方法是施加高压电击，从而有效地重置心脏细胞的相位。使用这种除颤技术的一个顾虑是，高能电击会对心脏组织造成持久损伤。各种理论著作都对除颤的低能量替代方法进行了研究。在这项工作中，我们展示了低能量除颤方法在实验性二维别洛乌索夫-扎博金斯基（BZ）系统中的有效性。当作为二维空间反应实施时，BZ 反应可作为一般可激介质的有效类似物，并支持有规则和再入射的波活动。所采用的除颤技术包括有针对性的低能量扰动，可用于 "传送 "和/或湮灭可激 BZ 介质中存在的奇点。

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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