Multidirectional Stimulation in an Isolated Murine Heart: A Computational Model

Multidirectional Stimulation in an Isolated Murine Heart: A Computational Model

It is common to use very high electric fields (E) to defibrillate hearts, which can damage cardiomyocytes, showing the importance of developing methods that can decrease the E applied in defibrillation protocols. We used COMSOL Multiphysics software to model, simulate, and analyze the application of...

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Bibliographic Details
Published in:Biomedical engineering and computational biology Vol. 15
Main Authors: Sá, Lizandra Alcantara, Costa, Jorge A, da Mota Silveira-Filho, Lindemberg, Xavier de Oliveira, Pedro
Format: Journal Article
Language:English
Published: SAGE Publishing 01-01-2024
Online Access:Get full text
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Summary:It is common to use very high electric fields (E) to defibrillate hearts, which can damage cardiomyocytes, showing the importance of developing methods that can decrease the E applied in defibrillation protocols. We used COMSOL Multiphysics software to model, simulate, and analyze the application of an E in an isolated heart with monodirectional and multidirectional stimuli, using 2 pairs of electrodes and the superposition principle as a way to decrease the E applied and reduce the required number of stimulation electrodes. When applying an E of 3 V/cm in the 0°, 30°, and 60° directions, individually in the stimulation chamber, E was equal to 3.2 V/cm and its phases were equal to 0°, 30°, and 60°, respectively, validating the superposition principle. We observed a reduction up to 31.8% in | E| when applying a multidirectional stimulus when comparing to the monodirectional stimulus, in order to stimulate the same area of the heart. For the same amount of stimuli directions, we obtained up to 11.7% reduction of | E|, just by modifying the directions of the applied stimuli. In the simulation developed in this work, the superposition principle was validated in a stimulation chamber. For the same stimulated area, the multidirectional E has been always lower than the monodirectional. We observed that, in order to decrease the intensity of E, both the number of applied stimuli and their directions were relevant issues.
ISSN:1179-5972
1179-5972
DOI:10.1177/11795972241266705