Abstract
The arrhythmogenesis of atrial fibrillation is associated with the presence of fibrotic atrial tissue. Not only fibrosis but also physiological anatomical variability of the atria and the thorax reflect in altered morphology of the P wave in the 12-lead electrocardiogram (ECG). Distinguishing between the effects on the P wave induced by local atrial substrate changes and those caused by healthy anatomical variations is important to gauge the potential of the 12-lead ECG as a non-invasive and cost-effective tool for the early detection of fibrotic atrial cardiomyopathy to stratify atrial fibrillation propensity. In this work, we realized 54,000 combinations of different atria and thorax geometries from statistical shape models capturing anatomical variability in the general population. For each atrial model, 10 different volume fractions (0–45%) were defined as fibrotic. Electrophysiological simulations in sinus rhythm were conducted for each model combination and the respective 12-lead ECGs were computed. P wave features (duration, amplitude, dispersion, terminal force in V1) were extracted and compared between the healthy and the diseased model cohorts. All investigated feature values systematically in- or decreased with the left atrial volume fraction covered by fibrotic tissue, however value ranges overlapped between the healthy and the diseased cohort. Using all extracted P wave features as input values, the amount of the fibrotic left atrial volume fraction was estimated by a neural network with an absolute root mean square error of 8.78%. Our simulation results suggest that although all investigated P wave features highly vary for different anatomical properties, the combination of these features can contribute to non-invasively estimate the volume fraction of atrial fibrosis using ECG-based machine learning approaches.
Highlights
Atrial Fibrillation (AF) is the most common cardiac arrhythmia worldwide and affects2–3% of the European and North American population [1]
Afterwards, we investigated to what extent the volume fraction of fibrotic substrate resulted in altered
To gauge the potential of one specific P wave feature to be a predictor for the fibrotic atrial volume fraction, the P wave feature values resulting from fibrotic infiltration in the reference geometry are shown aside with the color code representing the volume fraction of fibrosis covering the total left atrial (LA) tissue volume
Summary
Atrial Fibrillation (AF) is the most common cardiac arrhythmia worldwide and affects2–3% of the European and North American population [1]. Atrial Fibrillation (AF) is the most common cardiac arrhythmia worldwide and affects. The initiation and maintenance of the abnormal electrical activity requires ectopic foci firing and regions of vulnerable atrial substrate. Fibrotic tissue having undergone structural and electrical remodeling processes provides the necessary substrate properties to contribute to the perpetuation of AF [2,3]. Quantifying the amount of these arrhythmogenic substrate areas could be an important means for individual risk stratification of new-onset AF and arrhythmogenic fibrotic atrial cardiomyopathy (FAM) [4,5]. Catheter ablation is a common treatment option in clinical practice for the purpose of blocking certain conduction pathways in the atria that are suspected to contribute to the onset and maintenance of the arrhythmia. AF recurrence rates between 20 and 60% in patients with large arrhythmogenic substrate areas in the atria [6] underline the need to tailor therapy to the substrate
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