High Dominant Frequencies and Fractionated Potentials Do Not Indicate Focal or Rotational Activation During AF

Journal article (2023)

Authors

R.C. Hendriks Signal Processing Systems - EEMCS
N.M.S. de Groot Erasmus MC
Research Group
Signal Processing Systems (EEMCS) (TU Delft)
Copyright: © 2023 Lianne N. van Staveren, R.C. Hendriks, Yannick J.H.J. Taverne, N.M.S. de Groot
DOI: https://doi.org/10.1016/j.jacep.2023.01.013
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Published Date

2023

Language

English

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Faculty

Electrical Engineering, Mathematics and Computer Science

Department

Microelectronics

Research Group

Signal Processing Systems

Abstract

Background: Dominant frequencies (DFs) or complex fractionated atrial electrograms (CFAEs), indicative of focal sources or rotational activation, are used to identify target sites for atrial fibrillation (AF) ablation in clinical studies, although the relationship among DF, CFAE, and activation patterns remains unclear. Objectives: This study sought to investigate the relationship between patterns of activation underlying DF and CFAE sites during AF. Methods: Epicardial high-resolution mapping of the right and left atrium including Bachmann's bundle was performed in 71 participants. We identified the highest dominant frequency (DF
max) and highest degree of CFAE (CFAE
max) with the use of existing clinical criteria and classified patterns of activation as focal or rotational activation and smooth propagation, conduction block (CB), collision and remnant activity, and fibrillation potentials as single, double, or fractionated potentials containing, respectively, 1, 2, or 3 or more negative deflections. Relationships among activation patterns, DF
max, and potential types were investigated. Results: DF
max were primarily located at the left atrioventricular groove and did not harbor focal activation (proportion focal waves: 0% [IQR: 0%-2%]). Compared with non-DF
max sites, DF
max were characterized by more frequent smooth propagation (22% [IQR: 7%-48%] vs 17% [IQR: 11%-24%]; P = 0.001), less frequent conduction block (69% [IQR: 51%-81%] vs 74% [IQR: 69%-78%]; P = 0.006), a higher proportion of single potentials (72% [IQR: 55%-84%] vs 6%1 [IQR: 55%-65%]; P = 0.003), and a lower proportion of fractionated potentials (4% [IQR: 1%-11%] vs 12% [IQR: 9%-15%]; P = 0.004). CFAE
max were mainly found at the pulmonary veins area, and only 1% [IQR: 0%-2%] of all CFAE
max contained focal activation. Compared with non-CFAE
max sites, CFAE
max sites were characterized by less frequent smooth propagation (1% [IQR: 0%-1%] vs 17% [IQR: 12%-24%]; P < 0.001) and more frequent remnant activity (20% [IQR: 12%-29%] vs 8% [IQR: 5%-10%]; P < 0.001), and harbored predominantly fractionated potentials (52% [IQR: 43%-66%] vs 12% [IQR: 9%-14%]; P < 0.001). Conclusions: Focal or rotational patterns of activation were not consistently detected at DF
max domains and CFAE
max sites. These findings do not support the concept of targeting DF
max or CFAE
max according to existing criteria for AF ablation.

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