On the Accuracy of Eikonal Approximations in Cardiac Electrophysiology in the Presence of Fibrosis

Gander, Lia

Pontificia Universidad Católica de Chile

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On the Accuracy of Eikonal Approximations in Cardiac Electrophysiology in the Presence of Fibrosis.pdf

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Gander, Lia Krause, Rolf Weiser, Martin Sahli Costabal, Francisco Pezzuto, Simone

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Fibrotic tissue is one of the main risk factors for cardiac arrhythmias. It is therefore a key component in computational studies. In this work, we compare the monodomain equation to two eikonal models for cardiac electrophysiology in the presence of fibrosis. We show that discontinuities in the conductivity field, due to the presence of fibrosis, introduce a delay in the activation times. The monodomain equation and eikonal-diffusion model correctly capture these delays, contrarily to the classical eikonal equation. Importantly, a coarse space discretization of the monodomain equation amplifies these delays, even after accounting for numerical error in conduction velocity. The numerical discretization may also introduce artificial conduction blocks and hence increase propagation complexity. Therefore, some care is required when comparing eikonal models to the discretized monodomain equation.

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Autor	Gander, Lia Krause, Rolf Weiser, Martin Sahli Costabal, Francisco Pezzuto, Simone
Título	On the Accuracy of Eikonal Approximations in Cardiac Electrophysiology in the Presence of Fibrosis
Volumen	13958
Página inicio	137
Página final	146
Fecha de publicación	2023
Resumen	Fibrotic tissue is one of the main risk factors for cardiac arrhythmias. It is therefore a key component in computational studies. In this work, we compare the monodomain equation to two eikonal models for cardiac electrophysiology in the presence of fibrosis. We show that discontinuities in the conductivity field, due to the presence of fibrosis, introduce a delay in the activation times. The monodomain equation and eikonal-diffusion model correctly capture these delays, contrarily to the classical eikonal equation. Importantly, a coarse space discretization of the monodomain equation amplifies these delays, even after accounting for numerical error in conduction velocity. The numerical discretization may also introduce artificial conduction blocks and hence increase propagation complexity. Therefore, some care is required when comparing eikonal models to the discretized monodomain equation.
Derechos	acceso restringido
DOI	10.1007/978-3-031-35302-4_14
Editorial	Springer
Enlace	https://doi.org/10.1007/978-3-031-35302-4_14 http://www.scopus.com/inward/record.url?eid=2-s2.0-85172722625&partnerID=MN8TOARS https://repositorio.uc.cl/handle/11534/86071
Palabra clave	Cardiac electrophysiology Fibrosis Monodomain model Eikonal model Eikonal-diffusion model
Publicado en / Colección	Lecture Notes in Computer Science
Tema ODS	03 Good health and well-being
Tema ODS español	03 Salud y bienestar
Temática	Tecnología
Tipo de documento	comunicación de congreso