BACKGROUND: Questions remain about the contributions of transmural versus apicobasal repolarization gradients to the configuration of the T wave in control settings and after the induction of short-term cardiac memory. METHODS AND RESULTS: Short-term cardiac memory is seen as T-wave changes induced by altered ventricular activation that persists after restoration of sinus rhythm. We studied cardiac memory in anesthetized, open-chest dogs paced from the ventricle for 2 hours. Unipolar electrograms were recorded from as many as 98 epicardial and 144 intramural sites, and activation times and activation-recovery intervals (ARIs) were measured. In separate experiments, epicardial monophasic action potentials were recorded. We found no appreciable left ventricular intramural gradients in repolarization times (activation time+ARI) in either control conditions or after the induction of memory. In controls, there was a left ventricular apicobasal gradient, with the shortest repolarization times in anterobasal regions and longest repolarization times posteroapically. After induction of memory, repolarization times shortened uniformly throughout the ventricular wall. Monophasic action potential duration at 90% repolarization decreased by approximately 10 ms after induction of memory. CONCLUSIONS: In the intact canine left ventricle at physiological rates, there is no transmural gradient in repolarization. Apicobasal gradients in repolarization time, with shortest repolarization times in anterobasal areas and longest repolarization times in posteroapical regions, are important in the genesis of the T wave. Repolarization times and monophasic action potentials at the 90% repolarization level shorten after the induction of memory. The deeper T wave in the ECG after induction of memory may be explained by the more rapid phase 3 of the action potential.
BACKGROUND: Questions remain about the contributions of transmural versus apicobasal repolarization gradients to the configuration of the T wave in control settings and after the induction of short-term cardiac memory. METHODS AND RESULTS: Short-term cardiac memory is seen as T-wave changes induced by altered ventricular activation that persists after restoration of sinus rhythm. We studied cardiac memory in anesthetized, open-chest dogs paced from the ventricle for 2 hours. Unipolar electrograms were recorded from as many as 98 epicardial and 144 intramural sites, and activation times and activation-recovery intervals (ARIs) were measured. In separate experiments, epicardial monophasic action potentials were recorded. We found no appreciable left ventricular intramural gradients in repolarization times (activation time+ARI) in either control conditions or after the induction of memory. In controls, there was a left ventricular apicobasal gradient, with the shortest repolarization times in anterobasal regions and longest repolarization times posteroapically. After induction of memory, repolarization times shortened uniformly throughout the ventricular wall. Monophasic action potential duration at 90% repolarization decreased by approximately 10 ms after induction of memory. CONCLUSIONS: In the intact canine left ventricle at physiological rates, there is no transmural gradient in repolarization. Apicobasal gradients in repolarization time, with shortest repolarization times in anterobasal areas and longest repolarization times in posteroapical regions, are important in the genesis of the T wave. Repolarization times and monophasic action potentials at the 90% repolarization level shorten after the induction of memory. The deeper T wave in the ECG after induction of memory may be explained by the more rapid phase 3 of the action potential.
Authors: Pablo A Chiale; Julio D Pastori; Hugo A Garro; Luciano Faivelis; Oscar Ianovsky; Rubén A Sánchez; Carlos B Alvarez; Mario D González; Marcelo V Elizari Journal: J Interv Card Electrophysiol Date: 2010-03-24 Impact factor: 1.900
Authors: Rachel C Myles; Olivier Bernus; Francis L Burton; Stuart M Cobbe; Godfrey L Smith Journal: Am J Physiol Heart Circ Physiol Date: 2010-10-01 Impact factor: 4.733
Authors: Hiroshi Ashikaga; Benjamin A Coppola; Bruce Hopenfeld; Eric S Leifer; Elliot R McVeigh; Jeffrey H Omens Journal: J Am Coll Cardiol Date: 2007-02-09 Impact factor: 24.094
Authors: Partho P Sengupta; Vijay K Krishnamoorthy; Josef Korinek; Jagat Narula; Mani A Vannan; Steven J Lester; Jamil A Tajik; James B Seward; Bijoy K Khandheria; Marek Belohlavek Journal: J Am Soc Echocardiogr Date: 2007-05 Impact factor: 5.251