Conduction disturbances caused by high current density electric fields. Export

@article{citeulike:441908, abstract = {During internal defibrillation, potential gradients greater than 100 V/cm occur near defibrillation electrodes. Such strong fields may cause deleterious effects, including arrhythmias. This study determined 1) the effects of such strong fields on the propagation of activation and 2) whether these effects were different for monophasic and biphasic shocks. Voltages and potential gradients during the shock, as well as activation sequences before and after the shock, were mapped from 117 epicardial electrodes placed over a 3 x 3-cm area on the right ventricle in six dogs. Pacing at a cycle length of 350 msec was given from a long narrow electrode on the right side of the mapped area to generate parallel activation isochrones. A monophasic shock, 10 msec in duration, or a biphasic shock with both phases 5 msec in duration was delivered 300 msec after the last paced stimulus via a mesh electrode on the left side of the mapped area as the cathode, with the anode on the right atrium. Shocks of 70-850 V were given, and the potential gradient and current density at each recording electrode were calculated from the measured potentials and fiber orientation by using a finite element method. Pacing was resumed 200 msec after the shock, and activation sequences were mapped for up to 5 minutes. Potential gradients ranged from 1 to 189 V/cm with high fields on the left side and low fields on the right side of the mapped area. Where the potential gradient was weak, the first activation sequence after the shock was similar to that before the shock, but activation blocked without conducting into areas where the gradient was greater than 64 +/- 4 (mean +/- SD) V/cm for monophasic and greater than 71 +/- 6 V/cm for biphasic shocks. These values are significantly different (p less than 0.003). The higher the potential gradient, the longer was the duration of block before conduction returned. Block duration, however, was generally shorter for biphasic than for monophasic waveforms of the same field strength. In conclusion, conduction block can follow either waveform, but biphasic waveforms cause less block than monophasic waveforms. This effect may partially explain the increased defibrillation efficacy of biphasic shocks.}, address = {Department of Medicine, Duke University Medical Center, Durham, North Carolina 27710.}, author = {Yabe, S. and Smith, W. M. and Daubert, J. P. and Wolf, P. D. and Rollins, D. L. and Ideker, R. E.}, citeulike-article-id = {441908}, citeulike-linkout-0 = {http://view.ncbi.nlm.nih.gov/pubmed/2335021}, citeulike-linkout-1 = {http://www.hubmed.org/display.cgi?uids=2335021}, issn = {0009-7330}, journal = {Circ Res}, keywords = {electroporation}, month = {May}, number = {5}, pages = {1190--1203}, posted-at = {2005-12-19 17:37:09}, priority = {2}, title = {Conduction disturbances caused by high current density electric fields.}, url = {http://view.ncbi.nlm.nih.gov/pubmed/2335021}, volume = {66}, year = {1990} }

TY - JOUR ID - citeulike:441908 L3 - citeulike-article-id:441908 N2 - During internal defibrillation, potential gradients greater than 100 V/cm occur near defibrillation electrodes. Such strong fields may cause deleterious effects, including arrhythmias. This study determined 1) the effects of such strong fields on the propagation of activation and 2) whether these effects were different for monophasic and biphasic shocks. Voltages and potential gradients during the shock, as well as activation sequences before and after the shock, were mapped from 117 epicardial electrodes placed over a 3 x 3-cm area on the right ventricle in six dogs. Pacing at a cycle length of 350 msec was given from a long narrow electrode on the right side of the mapped area to generate parallel activation isochrones. A monophasic shock, 10 msec in duration, or a biphasic shock with both phases 5 msec in duration was delivered 300 msec after the last paced stimulus via a mesh electrode on the left side of the mapped area as the cathode, with the anode on the right atrium. Shocks of 70-850 V were given, and the potential gradient and current density at each recording electrode were calculated from the measured potentials and fiber orientation by using a finite element method. Pacing was resumed 200 msec after the shock, and activation sequences were mapped for up to 5 minutes. Potential gradients ranged from 1 to 189 V/cm with high fields on the left side and low fields on the right side of the mapped area. Where the potential gradient was weak, the first activation sequence after the shock was similar to that before the shock, but activation blocked without conducting into areas where the gradient was greater than 64 +/- 4 (mean +/- SD) V/cm for monophasic and greater than 71 +/- 6 V/cm for biphasic shocks. These values are significantly different (p less than 0.003). The higher the potential gradient, the longer was the duration of block before conduction returned. Block duration, however, was generally shorter for biphasic than for monophasic waveforms of the same field strength. In conclusion, conduction block can follow either waveform, but biphasic waveforms cause less block than monophasic waveforms. This effect may partially explain the increased defibrillation efficacy of biphasic shocks. IS - 5 JF - Circ Res SN - 0009-7330 AD - Department of Medicine, Duke University Medical Center, Durham, North Carolina 27710. EP - 1203 TI - Conduction disturbances caused by high current density electric fields. VL - 66 SP - 1190 KW - electroporation AU - Yabe, S AU - Smith, WM AU - Daubert, JP AU - Wolf, PD AU - Rollins, DL AU - Ideker, RE PY - 1990/05// UR - http://view.ncbi.nlm.nih.gov/pubmed/2335021 ER -