A Time-Varying Equivalent Circuit Modeling and Measuring Approach for Intracardiac Communication in Leadless Pacemakers

Ziliang Wei;Han Wang;Dongming Li;Mang I Vai;Sio Hang Pun;Jiejie Yang;Min Du;Yueming Gao
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Abstract

Intracardiac wireless communication is crucial for the development of multi-chamber leadless cardiac pacemakers (LCP). However, the time-varying characteristics of intracardiac channel pose major challenges. As such, mastering the dynamic conduction properties of the intracardiac channel and modeling the equivalent time-varying channel are imperative for realizing LCP multi-chamber pacing. In this article, we present a limiting volume variational approach based on the electrical properties of cardiac tissues and trends in chamber volume variation. This approach was used to establish a quasi-static and a continuous time-varying equivalent circuit model of an intracardiac channel. An equivalence analysis was conducted on the model, and a discrete time-varying equivalent circuit phantom grounded on the cardiac cycle was subsequently established. Moreover, an ex vivo cardiac experimental platform was developed for verification. Results indicate that in the frequency domain, the congruence between phantom and ex vivo experimental outcomes is as high as 94.3%, affirming the reliability of the equivalent circuit model. In the time domain, the correlation is up to 75.3%, corroborating its effectiveness. The proposed time-varying equivalent circuit model exhibits stable and standardized dynamic attributes, serving as a powerful tool for addressing time-varying challenges and simplifying in vivo or ex vivo experiments.
无引线起搏器心内通信的时变等效电路建模和测量方法
心内无线通信对于多腔无导联心脏起搏器(LCP)的发展至关重要。然而,心内信道的时变特性带来了重大挑战。因此,掌握心内信道的动态传导特性并对等效时变信道进行建模是实现 LCP 多腔起搏的当务之急。在本文中,我们提出了一种基于心脏组织电特性和心腔容积变化趋势的极限容积变异方法。该方法用于建立心内通道的准静态和连续时变等效电路模型。对模型进行了等效分析,随后建立了一个以心动周期为基础的离散时变等效电路模型。此外,还开发了一个体外心脏实验平台进行验证。结果表明,在频域上,模型与体外实验结果的一致性高达 94.3%,证实了等效电路模型的可靠性。在时域,相关性高达 75.3%,证实了其有效性。所提出的时变等效电路模型具有稳定和标准化的动态属性,是应对时变挑战和简化体内或体外实验的有力工具。
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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