Taccardi B, Punske BB, Macchi E, MacLeod RS, Ershler PR. Epicardial and intramural excitation during ventricular pacing: effect of myocardial structure. Am J Physiol Heart Circ Physiol 294: H1753-H1766, 2008. First published February 8, 2008 doi:10.1152/ajpheart.01400.2007.-Published studies show that ventricular pacing in canine hearts produces three distinct patterns of epicardial excitation: elliptical isochrones near an epicardial pacing site, with asymmetric bulges; areas with high propagation velocity, up to 2 or 3 m/s and numerous breakthrough sites; and lower velocity areas (Ͻ1 m/s), where excitation moves across the epicardial projection of the septum. With increasing pacing depth, the magnitude of epicardial potential maxima becomes asymmetric. The electrophysiological mechanisms that generate the distinct patterns have not been fully elucidated. In this study, we investigated those mechanisms experimentally. Under pentobarbital anesthesia, epicardial and intramural excitation isochrone and potential maps have been recorded from 22 exposed or isolated dog hearts, by means of epicardial electrode arrays and transmural plunge electrodes. In five experiments, a ventricular cavity was perfused with diluted Lugol solution. The epicardial bulges result from electrotonic attraction from the helically shaped subepicardial portions of the wave front. The highvelocity patterns and the associated multiple breakthroughs are due to involvement of the Purkinje network. The low velocity at the septum crossing is due to the missing Purkinje involvement in that area. The asymmetric magnitude of the epicardial potential maxima and the shift of the breakthrough sites provoked by deep stimulation are a consequence of the epi-endocardial obliqueness of the intramural fibers. These results improve our understanding of intramural and epicardial propagation during premature ventricular contractions and paced beats. This can be useful for interpreting epicardial maps recorded at surgery or inversely computed from body surface ECGs. propagation patterns; excitation mapping KNOWLEDGE OF THE MECHANISMS that govern the spread of excitation in the heart is a necessary prerequisite for understanding and interpreting abnormal sequences that occur in conduction disturbances, cardiac arrhythmias, localized ischemia, and myocardial infarctions. With the recent advancements in cardiac resynchronization therapy and other pacing strategies (15,35), it is even more relevant to better understand the spread of excitation during paced ventricular beats, as affected by the architecture of myocardial fibers and their anisotropic electrical properties.Experimental data published during the last 20 years show that epicardial and intramural ventricular pacing in canine hearts result in complex patterns of epicardial excitation, with multiple distinct areas of relatively slow and fast propagation (2,4,12,23,30,32). Published computer simulations of the spread of excitation in the ventricles, mostly based on eiconal equations, propose possible elect...
