UNLABELLED: Evaluation of a thermochromic dispersive electrode. INTRODUCTION: Burns at the dispersive electrode are serious complications of diathermy and radiofrequency (RF) ablation procedures. We aimed to create a new methodology to reduce the incidence of dispersive electrode related skin burns. We hypothesized that a dispersive electrode incorporating a thermochromic liquid crystal (TLC) layer could accurately measure underlying skin temperatures and help prevent burns. METHODS AND RESULTS: The TLC electrode was compared with a standard dispersive electrode in 12 male sheep. RF current was delivered with the dispersive electrode fully applied or partially detached to simulate different clinical scenarios. The temperature of the TLC layer, calculated from the hue (color) every 15 seconds, was compared with fluoroptic skin temperature probes. TLC electrodes with a temperature range of 45-58 degrees C were used in six sheep to assess the correlation of TLC temperature distribution with skin temperature and burns. TLC electrodes with a temperature range of 40-50 degrees C were used in another 6 sheep to simulate clinical conditions in which the ablation was stopped if the TLC temperature was >42 degrees C. The TLC measured temperatures correlated well with fluoroptic probes at the skin surface (r=0.94+/-0.05, mean of the absolute difference in temperature difference 0.9+/-0.58 degrees C). Ablations with partial application of standard dispersive electrodes consistently caused skin burns. There were no burns under the TLC electrode when ablations were ceased for temperatures>42 degrees C. CONCLUSIONS: TLC-equipped dispersive electrodes were able to accurately measure skin temperature under the electrode. This technology is likely to prevent dispersive electrode related burns.
UNLABELLED: Evaluation of a thermochromic dispersive electrode. INTRODUCTION: Burns at the dispersive electrode are serious complications of diathermy and radiofrequency (RF) ablation procedures. We aimed to create a new methodology to reduce the incidence of dispersive electrode related skin burns. We hypothesized that a dispersive electrode incorporating a thermochromic liquid crystal (TLC) layer could accurately measure underlying skin temperatures and help prevent burns. METHODS AND RESULTS: The TLC electrode was compared with a standard dispersive electrode in 12 male sheep. RF current was delivered with the dispersive electrode fully applied or partially detached to simulate different clinical scenarios. The temperature of the TLC layer, calculated from the hue (color) every 15 seconds, was compared with fluoroptic skin temperature probes. TLC electrodes with a temperature range of 45-58 degrees C were used in six sheep to assess the correlation of TLC temperature distribution with skin temperature and burns. TLC electrodes with a temperature range of 40-50 degrees C were used in another 6 sheep to simulate clinical conditions in which the ablation was stopped if the TLC temperature was >42 degrees C. The TLC measured temperatures correlated well with fluoroptic probes at the skin surface (r=0.94+/-0.05, mean of the absolute difference in temperature difference 0.9+/-0.58 degrees C). Ablations with partial application of standard dispersive electrodes consistently caused skin burns. There were no burns under the TLC electrode when ablations were ceased for temperatures>42 degrees C. CONCLUSIONS: TLC-equipped dispersive electrodes were able to accurately measure skin temperature under the electrode. This technology is likely to prevent dispersive electrode related burns.
Authors: Pramesh Kovoor; Michael Daly; Jim Pouliopoulos; Vicki Eipper; Barbara Dewsnap; David L Ross Journal: J Interv Card Electrophysiol Date: 2007-08-09 Impact factor: 1.900