Validation of a Customized Method for Estimating Electrical Potentials in the Torso From Atrial Signals: a Computational-Clinical Study

2022 Computing in Cardiology (CinC) Pub Date : 2022-09-04 DOI:10.22489/CinC.2022.369

Camila R Restivo, Gabriel V Costa, I. Sandoval, M. Guillem, J. Salinet

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Abstract

Atrial fibrillation (AF) is a common supraventricular arrhythmia (SVA) in clinical practice and is characterized by uncoordinated electrical activity of the atria. This study aims to evaluate the influence on the forward solution of AF torso biomarkers under different levels of noise, 3D cardiorespiratory torso/atria morphologies, and number of atria electrodes. 2,048 atrial epicardium electrograms (AEGs) from 5 AF mathematical models were used to estimate 771 body surface potentials (BSPs). The BSPs and respective frequency/phase maps of are obtained after: (i) introduction of noise in the AEGs, (ii) 3D geometry torso/atria modification, and (iii) reduction in electrodes (from 2,048 to 256, 128, 64 e 32; interpolation methods: Linear/Laplacian). To reduce biomarkers disparity, a Butterworth bandpass filter (BPF) at different cut-off frequencies (0.5-30, 3–30 and HDF±1 Hz) is applied on the AEGs prior BSPs estimation. The above methodology is extended to two AF patients (EDGAR database). The estimation of AF BSPs, in different noise ranges, limits the effectiveness of the forward solution. Phase biomarkers are sensitive to the AEGs' pre-processing strategy. The BPF around HDF showed the best agreement between the different SNR levels. Due to the 3D morphological changes, HDF areas variability increased.

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从心房信号中估计躯干电位的定制方法的验证:一项计算临床研究

心房颤动(AF)是临床上常见的室上性心律失常(SVA)，其特点是心房电活动不协调。本研究旨在评估不同水平的噪声、三维心肺躯干/心房形态和心房电极数量对房颤躯干生物标志物正向溶液的影响。利用5个AF数学模型的2,048张心房心外膜电图(aeg)估计771个体表电位(BSPs)。bsp和各自的频率/相位图是在以下情况下获得的:(i)在aeg中引入噪声，(ii) 3D几何躯干/心房修改，以及(iii)减少电极(从2,048减少到256、128、64 e 32;插值方法:线性/拉普拉斯)。为了减少生物标志物的差异，在不同的截止频率(0.5- 30,3 -30和HDF±1hz)下应用巴特沃斯带通滤波器(BPF)对aaegs先验BSPs估计。上述方法扩展到2例房颤患者(EDGAR数据库)。在不同噪声范围下对自动对焦BSPs的估计限制了正演解的有效性。相生物标志物对aeg的预处理策略敏感。HDF附近的BPF在不同信噪比水平之间表现出最好的一致性。由于三维形态的变化，HDF面积变异性增加。

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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2022 Computing in Cardiology (CinC)

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