Nonlinear interdependence of electrograms as a tool to characterize propagation patterns in atrial fibrillation

•Low nonlinear interdependence values surrounded by high values are related with stable rotors.•Nonlinear interdependence detects regions harboring the core of stable and transient rotors.•Nonlinear interdependence and PLV are correlated in real and virtual electrograms. Ablation of stable sources i...

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Veröffentlicht in:Biomedical signal processing and control 2022-02, Vol.72, p.103282, Article 103282
Hauptverfasser: Orozco-Duque, Andrés, Ugarte, Juan P., Tobón, Catalina
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Sprache:eng
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Zusammenfassung:•Low nonlinear interdependence values surrounded by high values are related with stable rotors.•Nonlinear interdependence detects regions harboring the core of stable and transient rotors.•Nonlinear interdependence and PLV are correlated in real and virtual electrograms. Ablation of stable sources is a promising treatment to reverse the atrial fibrillation (AF) although its underlying mechanisms are still debated. Many attempts have been made to detect stable spiral waves as a target of ablation through univariate processing of intracardiac electrogram signals (EGM). Few researchers have addressed the bivariate assessment in AF, and the existing studies are mainly based on the phase-locking value (PLV). The present work introduces a scheme to assess the AF conduction patterns through the nonlinear interdependence index. Two and three-dimensional computational simulations of cardiac conduction are used to assess the proposed method in characterizing the dynamics of fibrillatory mechanisms such as rotors. In addition, a study with real signals acquired from an AF patient is shown as an example of a possible application in humans. In the simulated episodes, the nonlinear interdependence index characterizes the core of the stable rotors as a region having low interdependence values, surrounded by a high synchronization region. In episodes where multiple reentries coexist, the nonlinear interdependence maps highlight regions harboring the core of stable and transient rotors. Additionally, we found a positive correlation between PLV and nonlinear interdependence index in both real and virtual EGM. The proposed method based on nonlinear synchronization analysis renders relevant information about the fibrillatory dynamics and it is 7.8 times faster than PLV. Hence, the nonlinear interdependence index represents a potential alternative to phase synchronization methods for characterizing AF dynamics.
ISSN:1746-8094
1746-8108
DOI:10.1016/j.bspc.2021.103282