4D Cardiac Activation Wave Mapping in In Vivo Swine Model using Acoustoelectric Imaging

2019 IEEE International Ultrasonics Symposium (IUS) Pub Date : 2019-10-01 DOI:10.1109/ULTSYM.2019.8926147

Alexander Alvarez, Cameron Wilhite, Chet Preston, Teodoro Trujillo, Alice McArthur, D. Mustacich, R. Witte

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引用次数: 4

Abstract

Though atrial fibrillation (AF) is a growing public health problem, electrical characterization of the disease with electrocardiography (ECG) is inadequate due to poor spatial resolution. The goal of this study was to investigate propagation of the cardiac activation wave in a healthy swine model using acoustoelectric cardiac imaging (ACI), a noninvasive mapping technology that combines ultrasound with electrical recording to overcome limitations with standard ECG. Real-time 4D ACI with a custom 2D 0.6 MHz matrix US array demonstrated conduction velocities of 2.21 m/s, validated with standard epicardial recording. ACI FWHM at a single timepoint, a measure related to the resolution of ACI in imaging the volume of activation at peak ECG signal, was 7.31 mm, 7.63 mm, and 6.23 mm in the depth, lateral, and elevational directions, respectively. SNR of ACI was 21dB at peak activation. ACI signals tracked through a 4D volume demonstrated appropriate propagation of the signal from base to apex and from endocardium to epicardium. This study demonstrated the potential for this technology to noninvasively map arrhythmias, such as AF, at high resolution.

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利用声电成像技术在猪体内模型中绘制四维心脏激活波

虽然心房颤动(AF)是一个日益严重的公共卫生问题，但由于空间分辨率差，用心电图(ECG)对该疾病的电表征是不充分的。本研究的目的是利用心脏声电成像(ACI)研究健康猪模型中心脏激活波的传播，ACI是一种无创测绘技术，将超声和电记录结合起来，克服了标准心电图的局限性。使用定制2D 0.6 MHz矩阵US阵列的实时4D ACI显示传导速度为2.21 m/s，并通过标准心外膜记录进行验证。单个时间点的ACI FWHM(与ACI成像峰值心电信号激活体积的分辨率相关的指标)在深度、侧向和仰角方向分别为7.31 mm、7.63 mm和6.23 mm。ACI在峰值激活时信噪比为21dB。通过4D体积跟踪ACI信号显示信号从基底到心尖和从心内膜到心外膜的适当传播。这项研究证明了该技术在无创地绘制心律失常(如房颤)的高分辨率地图方面的潜力。

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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2019 IEEE International Ultrasonics Symposium (IUS)

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