Copyright © 1989 by the European Society of Cardiology.
© 1989 The European Society of Cardiology
Radiofrequency coagulation of ventricular myocardium: Improved prediction of lesion size by monitoring catheter tip temperature
Department of Cardiology-Angiology University Hospital Münster Albert-Schweitzer-Strasse, Münster, West Germany
*Department of Experimental Research, University Hospital Münster Albert-Schweitzer-Strasse, Münster, West Germany
Received 28 November 1988; revised 10 April 1989; .
Address for reprints: Gerhard Hindricks MD, University Hospital M
nster, Department of Cardiology-Angiology, Albert-Schweitzer-Strasse 33, 4400 Mnster, F.R.G
Abstract
To assess the importance of voltage, current, impedance and catheter tip temperature for the prediction of the size of tissue injury induced by transcatheter radiofrequency application, radiofrequency pulses (500 kHz) were delivered both in vitro and in vivo to isolated ventricular preparations and the intact canine heart, respectively. Radiofrequency coagulations were performed using unipolar electrode configuration. Besides measurements of current and voltage which were used to calculate the delivered power and tissue impedance, the catheter tip temperature was monitored during each application using specially designed 6F USCI catheters with a built-in nickel/chromium-nickel thermoelement. Lesion dimensions were measured and the correlation between lesion volume and delivered radiofrequency energy, maximum changes in catheter tip temperature and the integral of the temperature curve were calculated. First, in a pilot in vitro investigation, 50 radiofrequency coagulations (3.2 W–22.4 W, pulse duration 10 s) were performed in ventricular preparations fromfreshly excised dog hearts. The correlation between applied radiofrequency energy and lesion volume was 0.87; the correlation between maximal catheter tip temperature and lesion volume was 0.82; the correlation between temperature integral and lesion volume was 0.9. In the intact dog heart, 44 radiofrequency pulses were delivered to the left and right ventricular endocardium in 12 anaesthetized dogs (exposure time: 10 s). Delivered power ranged between 5.6 Wand 24.6 W; tissue impedance varied between 92 
and 364 ; lesion volume measured 0–273 mm3; developed peak temperatures ranged from 16.25°C to 196°C. The calculated integral beneath temperature curves measured 126–1971°C.s. The correlation between applied radio-frequency energy and lesion volume was 0.32; the correlation between maximal catheter tip temperature and lesion volume was 0.61. Temperature integral correlated best with the assessed volume of my ocardial necrosis (r = 0.7). No significant arrhythmogenic or haemodynamic side-effects were observed. Macroscopic examination showed a central depression surrounded by a zone of homogenous coagulation. Vaporization and crater formation up to a depth of 4 mm were observed following three radiofrequency discharges. In two of these cases, rapid changes and oscillation of catheter tip temperature were observed. Thus, monitoring of catheter tip temperature during radiofrequency energy application improves the prediction of lesion size. In addition, temperature monitoring might improve the safety of the procedure with respect to the risk of perforation.
Key Words: Catheter ablation • ventricular arrhythmias • radiofrequency energy
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