Abstract
Atrial fibrillation (AF) is characterized by complex and irregular propagation patterns, and AF onset locations and drivers responsible for its perpetuation are the main targets for ablation procedures. ECG imaging (ECGI) has been demonstrated as a promising tool to identify AF drivers and guide ablation procedures, being able to reconstruct the electrophysiological activity on the heart surface by using a non-invasive recording of body surface potentials (BSP). However, the inverse problem of ECGI is ill-posed, and it requires accurate mathematical modeling of both atria and torso, mainly from CT or MR images. Several deep learning-based methods have been proposed to detect AF, but most of the AF-based studies do not include the estimation of ablation targets. In this study, we propose to model the location of AF drivers from BSP as a supervised classification problem using convolutional neural networks (CNN). Accuracy in the test set ranged between 0.75 (SNR = 5 dB) and 0.93 (SNR = 20 dB upward) when assuming time independence, but it worsened to 0.52 or lower when dividing AF models into blocks. Therefore, CNN could be a robust method that could help to non-invasively identify target regions for ablation in AF by using body surface potential mapping, avoiding the use of ECGI.
Highlights
Atrial fibrillation (AF) is the most common type of arrhythmia in clinical practice, affecting more than 33 million patients in the world (Chugh et al, 2014)
Classification Problem We proposed to address the location of AF drivers as a supervised classification problem
We evaluated the possibility of using pre-trained convolutional neural networks (CNN) models for AF driver localization, instead of using a custom CNN architecture
Summary
Atrial fibrillation (AF) is the most common type of arrhythmia in clinical practice, affecting more than 33 million patients in the world (Chugh et al, 2014). One of the clinical goals in AF patients is to restore sinus rhythm This objective can be achieved by pharmacological treatment (Lip and Tse, 2007), but termination of arrhythmic processes is usually accomplished by ablation of the cardiac tissue. ECGI combines both numerical modeling of the bioelectric properties of the thorax and signal processing, with the aim of reconstructing the electrophysiological activity on the heart surface by using a non-invasive recording of body surface potentials (BSP) (Brooks and Macleod, 1997; Gulrajani, 1998). Regularization methods are needed to obtain reliable and stable epicardial potential reconstructions (Tikhonov and Arsenin, 1977; Oster and Rudy, 1992; MacLeod and Brooks, 1998; Pedron-Torrecilla et al, 2011; Milanic et al, 2014) For these reasons, inverse problem-based approaches still need further improvement.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
