Details

Autor(en) / Beteiligte

• Irastorza, Ramiro M
• Maher, Timothy
• Barkagan, Michael
• Liubasuskas, Rokas
• Berjano, Enrique
• d’Avila, Andre

Titel

Anterior vs. posterior position of dispersive patch during radiofrequency catheter ablation: insights from in silico modelling

Ist Teil von

• Europace (London, England), 2023-03, Vol.25 (3), p.1135-1143

Ort / Verlag

US: Oxford University Press

Erscheinungsjahr

2023

Quelle

Oxford Journals 2020 Medicine

Beschreibungen/Notizen

• Abstract Aims To test the hypothesis that the dispersive patch (DP) location does not significantly affect the current distribution around the catheter tip during radiofrequency catheter ablation (RFCA) but may affect lesions size through differences in impedance due to factors far from the catheter tip. Methods An in silico model of RFCA in the posterior left atrium and anterior right ventricle was created using anatomic measurements from patient thoracic computed tomography scans and tested the effect of anterior vs. posterior DP locations on baseline impedance, myocardial power delivery, radiofrequency current path, and predicted lesion size. Results For posterior left atrium ablation, the baseline impedance, total current delivered, current distribution, and proportion of power delivered to the myocardium were all similar with both anterior and posterior DP locations, resulting in similar RFCA lesion sizes (< 0.2 mm difference). For anterior right ventricular (RV) ablation, an anterior DP location resulted in slightly higher proportion of power delivered to the myocardium and lower baseline impedance leading to slightly larger RFCA lesions (0.6 mm deeper and 0.8 mm wider). Conclusions An anterior vs. posterior DP location will not meaningfully affect RFCA for posterior left atrial ablation, and the slightly larger lesions predicted with anterior DP location for anterior RV ablation are of unclear clinical significance. Graphical Abstract Graphical Abstract In silico model of radiofrequency ablation—Human thoracic computed tomography measurements allow the creation of realistic computer simulations of current delivery during ablation of different locations in the heart. Current distribution can be modelled to show differences in ablation with an anterior vs. posterior dispersive patch location.