Multiscale and Multiphysics Modeling of Anisotropic Cardiac RFCA: Experimental-Based Model Calibration Multi-Point Temperature Measurements

Overview

Journal Front Physiol

Date 2022 May 6

PMID 35514332

Authors

Leonardo Molinari

Martina Zaltieri

Carlo Massaroni

Simonetta Filippi

Alessio Gizzi

Emiliano Schena

Affiliations

Soon will be listed here.

Abstract

Radiofrequency catheter ablation (RFCA) is the mainstream treatment for drug-refractory cardiac fibrillation. Multiple studies demonstrated that incorrect dosage of radiofrequency energy to the myocardium could lead to uncontrolled tissue damage or treatment failure, with the consequent need for unplanned reoperations. Monitoring tissue temperature during thermal therapy and predicting the extent of lesions may improve treatment efficacy. Cardiac computational modeling represents a viable tool for identifying optimal RFCA settings, though predictability issues still limit a widespread usage of such a technology in clinical scenarios. We aim to fill this gap by assessing the influence of the intrinsic myocardial microstructure on the thermo-electric behavior at the tissue level. By performing multi-point temperature measurements on swine cardiac tissue samples, the experimental characterization of myocardial thermal anisotropy allowed us to assemble a fine-tuned thermo-electric material model of the cardiac tissue. We implemented a multiphysics and multiscale computational framework, encompassing thermo-electric anisotropic conduction, phase-lagging for heat transfer, and a three-state dynamical system for cellular death and lesion estimation. Our analysis resulted in a remarkable agreement between measurements and numerical results. Accordingly, we identified myocardium anisotropy as the driving effect on the outcomes of hyperthermic treatments. Furthermore, we characterized the complex nonlinear couplings regulating tissue behavior during RFCA, discussing model calibration, limitations, and perspectives.

Citing Articles

Proactive esophageal cooling protects against thermal insults during high-power short-duration radiofrequency cardiac ablation.

Mercado Montoya M, Gomez Bustamante T, Berjano E, Mickelsen S, Daniels J, Hernandez Arango P Int J Hyperthermia. 2022; 39(1):1202-1212.

PMID: 36104029 PMC: 9771690. DOI: 10.1080/02656736.2022.2121860.

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