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Abstract

Radiofrequency (RF) catheter ablation treats cardiac diseases by inducing thermal lesion of cardiac tissues through radiofrequency energy operating at around 500 kHz. The electromagnetic wavelength is significantly longer than the size of the radiofrequency active electrode, the tissue is heated through resistive heating. During thermal ablation, the coupled thermo-mechanical property of cardiac tissue influencing the contact area between the electrode and tissue plays a crucial role in the formation of thermal lesions, yet the literature often overlooks the effect of thermal deformation. This paper proposes a thermo-hyperelastic constitutive model for myocardium that models thermal contraction and expansion during ablation. Furthermore, a finite element model was established to investigate the effect of the electro-thermo-mechanical coupling property of myocardium on lesion formation under different contact forces. To ensure convergence, we solved the fully coupled electro-thermo-mechanical finite element model using the segregated step method. The computational results demonstrate that thermal deformation, which causes an expansion in the tissue-electrode contact area, increases lesion width and volume, while its influence on lesion depth is negligible. Specifically, after a 30-s ablation under contact forces of 0.1, 0.15, and 0.2 N, the lesion volume increased from 4.53, 7.66, and 10.62 mm³ (without thermo-mechanical coupling) to 5.36, 8.33, and 13.34 mm³ (with thermo-mechanical coupling), respectively. Similarly, the lesion width increased from 2.68, 3.12, and 3.44 mm to 2.78, 3.22, and 3.62 mm. Moreover, both thermal deformation and contact force exert a minimal effect on lesion formation time.

Keywords

Radiofrequency ablation thermal deformation lesion formation force time integral finite element model

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References

El Baba

Sabayon

Refaat

. Radiofrequency catheter ablation: How to manage and prevent collateral damage? J Innov Card Rhythm Manag 2020; 11(9): 4234–4240.

Joseph

Rajappan

Radiofrequency ablation of cardiac arrhythmias: past, present and future. QJM 2012; 105(4): 303–314.

Nakagawa

Ikeda

Sharma

, et al. Comparison of in vivo tissue temperature profile and lesion geometry for radiofrequency ablation with high power–short duration and moderate power–moderate duration: effects of thermal latency and contact force on lesion formation. Circ Arrhythm Electrophysiol 2021; 14(7): e009899.

Sulkin

Laughner

Hilbert

, et al. Novel measure of local impedance predicts catheter–tissue contact and lesion formation. Circ Arrhythm Electrophysiol 2018; 11(4): e005831.

Amemiya

Takigawa

Goya

, et al. Comparison of two catheters measuring local impedance: local impedance variation vs lesion characteristics and steam pops. J Interv Card Electrophysiol 2022; 65(2): 419–428.

Reddy

Shah

Kautzner

, et al. The relationship between contact force and clinical outcome during radiofrequency catheter ablation of atrial fibrillation in the TOCCATA study. Heart Rhythm 2012; 9(11): 1789–1795.

Yokoyama

Nakagawa

Shah

, et al. Novel contact force sensor incorporated in irrigated radiofrequency ablation catheter predicts lesion size and incidence of steam pop and thrombus. Circ Arrhythm Electrophysiol 2008; 1(5): 354–362.

Münkler

Kröger

Liosis

, et al. Ablation index for catheter ablation of atrial fibrillation- clinical applicability and comparison with Force-time integral. Circ J 2018; 82(11): 2722–2727.

Petras

Leoni

Guerra

, et al. A computational model of open-irrigated radiofrequency catheter ablation accounting for mechanical properties of the cardiac tissue. Int J Numer Methods Biomed Eng 2019; 35(11): e3232.

10.

Yan

, et al. Computer simulation study on the effect of electrode-tissue contact force on thermal lesion size in cardiac radiofrequency ablation. Int J Hyperthermia 2020; 37(1): 37–48.

11.

Yan

Effect of anisotropy in myocardial electrical conductivity on lesion characteristics during radiofrequency cardiac ablation: a numerical study. Int J Hyperthermia 2022; 39(1): 120–133.

12.

Zhang

XF.

Thermoelastic analysis of biological tissue during hyperthermia treatment for moving laser heating using fractional dual-phase-lag bioheat conduction. Int J Therm Sci 2022; 182: 107806.

13.

Liu

Brace

CL.

Numerical simulation of microwave ablation incorporating tissue contraction based on thermal dose. Phys Med Biol 2017; 62(6): 2070–2086.

14.

Singh

Melnik

Coupled thermo-electro-mechanical models for thermal ablation of biological tissues and heat relaxation time effects. Phys Med Biol 2019; 64(24): 245008.

15.

Park

Liu

Hall

, et al. A thermoelastic deformation model of tissue contraction during thermal ablation. Int J Hyperthermia 2018; 34(3): 221–228.

16.

Chen

Wright

Humphrey

JD.

Phenomenological evolution equations for heat-induced shrinkage of a collagenous tissue. IEEE Trans Biomed Eng 1998; 45(10): 1234–1240.

17.

Liu

. Characterization and modeling of tissue contraction during thermal ablation. The University of Wisconsin-Madison, Madison, 2016.

18.

Singh

Melnik

Thermal ablation of biological tissues in disease treatment: A review of computational models and future directions. Electromagn Biol Med 2020; 39(2): 49–88.

19.

Kolawole

Peirlinck

Cork

, et al. Validating MRI-Derived myocardial stiffness estimates using in vitro synthetic heart models. Ann Biomed Eng 2023; 51(7): 1574–1587.

20.

Singh

Melnik

Diagnostics

SIM

. Computational modeling of cardiac ablation incorporating electrothermomechanical interactions. J Eng Sci Med Diagn Ther 2020; 3(4): 041004.

21.

Calzolari

De Mattia

Indiani

, et al. In vitro validation of the lesion size index to predict lesion width and depth after irrigated radiofrequency ablation in a porcine model. JACC Clin Electrophysiol 2017; 3(10): 1126–1135.

22.

Masnok

Watanabe

Catheter contact area strongly correlates with lesion area in radiofrequency cardiac ablation: an ex vivo porcine heart study. J Interv Card Electrophysiol 2022; 63(3): 561–572.

23.

Kalman

Fitzpatrick

Olgin

, et al. Biophysical characteristics of radiofrequency lesion formation in vivo: dynamics of catheter tip-tissue contact evaluated by intracardiac echocardiography. Am Heart J 1997; 133(1): 8–18.

24.

Chik

Barry

Pouliopoulos

, et al. Electrogram-gated radiofrequency ablations with duty cycle power delivery negate effects of ablation catheter motion. Circ Arrhythm Electrophysiol 2014; 7(5): 920–928.

25.

González-Suárez

Pérez

Berjano

Should fluid dynamics be included in computer models of RF cardiac ablation by irrigated-tip electrodes?

Biomed Eng Online 2018; 17(1): 43.

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Computational study on the effect of thermal deformation of myocardium on lesion formation during radiofrequency ablation

Abstract

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