High Coverage and High-Resolution Mapping of Repetitive Patterns During Atrial Fibrillation

2021 Computing in Cardiology (CinC) Pub Date : 2021-09-13 DOI:10.23919/cinc53138.2021.9662754

O. Özgül, B. Hermans, A. Hunnik, S. Verheule, U. Schotten, P. Bonizzi, S. Zeemering

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引用次数: 1

Abstract

Localized AF drivers with repetitive activity are candidate ablation targets for patients with persistent atrial fibrillation (AF). High-density mapping electrodes cover only a fraction of the atria but combining sequential recordings could provide a more comprehensive picture of common repetitive atrial conduction characteristics and enable AF driver localization. We developed a novel algorithm to merge overlapping local activation maps into larger composite maps using recurrence plots. The proposed algorithm was applied to atrial recordings in a goat model of AF (249-electrode mapping array, 2.4 mm inter-electrode distance, $n=16$). Sequential, overlapping recordings were generated by segmenting the mapping region into four spatially overlapping regions. Repetitive activation patterns were detected from recurrence plots generated from the recorded electrograms, and reconstructed with the proposed algorithm. Reconstruction quality was measured as the Pearson correlation between original and reconstructed activation patterns. The average correlation was 0.86. Among pattern properties, such as duration, area, complexity and cycle length, only duration was significantly correlated with the composite map quality ($r=0.126, p < 0.05$). The percentage of the cases where a composite map could be generated was 75.30% which was significantly higher for larger patterns ($p < 0.01$).

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房颤期间重复模式的高覆盖和高分辨率映射

重复性活动的局部房颤驱动因素是持续性房颤(AF)患者的候选消融靶点。高密度映射电极仅覆盖心房的一小部分，但结合顺序记录可以提供更全面的常见重复心房传导特征，并使AF驱动程序定位。我们开发了一种新的算法，利用递归图将重叠的局部激活图合并成更大的复合图。将该算法应用于山羊AF模型的心房记录(249个电极映射阵列，电极间距2.4 mm， $n=16$)。通过将映射区域分割成四个空间重叠的区域，生成顺序的重叠记录。从记录的电图生成的递归图中检测到重复的激活模式，并使用所提出的算法重建。重建质量通过原始激活模式和重建激活模式之间的Pearson相关性来衡量。平均相关系数为0.86。在持续时间、面积、复杂性和周期长度等模式属性中，只有持续时间与复合地图质量显著相关(r=0.126, p < 0.05)。生成复合地图的比例为75.30%，对于较大的模式，这一比例明显更高(p < 0.01)。

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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2021 Computing in Cardiology (CinC)

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