DocumentCode
1037537
Title
Thermal-electrical modeling for epicardial atrial radiofrequency ablation
Author
Berjano, Enrique J. ; Hornero, Fernando
Author_Institution
Departamento de Ingenieria Electronica, Univ. Politecnica de Valencia, Spain
Volume
51
Issue
8
fYear
2004
Firstpage
1348
Lastpage
1357
Abstract
Epicardial radiofrequency ablation is increasingly being used for intraoperative treatment of atrial fibrillation. However, the effect of different parameters on the lesion characteristics has not been sufficiently characterized. We used a finite element model to calculate the temperature distribution in the atrial tissue under different conditions during a constant voltage radiofrequency ablation. Our simulation results show that although in the case of a thin atrium the lesion was less deep for a thin atrium, it was easier to achieve transmurality. While considering a thinner atrium, the location of the hottest point of the lesion shifted from the electrode tip to epicardial surface. This effect was due to the convective cooling of the circulating blood inside the atrium. This convective cooling phenomenon has almost negligible effects for atria thicker than 3 mm. The variability of the cooling values has no significant effect on the lesion, even for thin atria (1-2 mm). Increasing the electrode insertion depth (ID) in the tissue produced larger lesions. However, for thinner atria (thickness <2 mm), this increase in the ID reduced the lesion width. It was also proved that the presence of a fat layer between the electrode and the atrial tissue decreased significantly the lesion dimensions.
Keywords
bioelectric phenomena; biological effects of microwaves; biomedical electrodes; biothermics; cardiology; convection; cooling; finite element analysis; haemodynamics; patient treatment; physiological models; blood circulation; convective cooling; electrode insertion depth; epicardial atrial radiofrequency ablation; epicardial surface; finite element model; intraoperative atrial fibrillation treatment; lesion; temperature distribution; thermal-electrical modeling; transmurality; Atrial fibrillation; Blood; Catheters; Cooling; Electrodes; Finite element methods; Lesions; Minimally invasive surgery; Probes; Radio frequency; Adipose Tissue; Atrial Fibrillation; Body Temperature; Catheter Ablation; Computer Simulation; Energy Transfer; Finite Element Analysis; Heart Atria; Humans; Models, Cardiovascular; Pericardium; Surgery, Computer-Assisted; Thermography;
fLanguage
English
Journal_Title
Biomedical Engineering, IEEE Transactions on
Publisher
ieee
ISSN
0018-9294
Type
jour
DOI
10.1109/TBME.2004.827545
Filename
1315856
Link To Document