© 1998 American Heart Association, Inc.
Original Contributions |
Electrophysiological Basis of Arrhythmogenicity of QT/T Alternans in the Long-QT Syndrome
Tridimensional Analysis of the Kinetics of Cardiac Repolarization
From the Cardiology Division, Department of Medicine, State University of New York Health Science Center, and Veterans Affairs Medical Center, Brooklyn, NY.
Correspondence to Nabil El-Sherif, MD, SUNY Health Science Center, Cardiology Division, Box 1199, 450 Clarkson Ave, Brooklyn, NY 11203. E-mail el-sherif.nabil{at}brooklyn.va.gov
Abstract—Tachycardia-dependent
QT/T alternans occurs in patients with the congenital or idiopathic
form of long-QT syndrome (LQTS) and may presage the onset of
polymorphic ventricular
tachyarrhythmias. To examine the
electrophysiological basis of
arrhythmogenicity of QT/T alternans in LQTS, the tridimensional
repolarization pattern of QT/T alternans was studied in the
anthopleurin-A model of LQTS, a surrogate for LQT3. In 11
anesthetized mongrel puppies, tridimensional repolarization and
activation patterns were analyzed from 256 to 384 unipolar
electrograms. Cardiac repolarization was evaluated as the
activation-recovery interval (ARI) of local electrograms. To induce
QT/T alternans, the pacing cycle length (CL) was abruptly shortened in
steps of 50 ms from a basic drive of 1000 ms. ARIs were calculated at
epicardial (Epi), midmyocardial (Mid), and endocardial (End) sites. ARI
restitution at each site was assessed by using a single premature
stimulation delivered after the basic drive. ARI alternans occurred at
longer CLs at Mid sites compared with End and Epi sites, and the
magnitude of alternans at Mid sites was greater. Two factors
contributed to the modulation of ARI during QT/T alternans: (1)
differences in restitution kinetics at Mid sites, characterized by
larger 
ARI and a slower time constant (
), and (2) differences in
diastolic intervals resulting in different input to
restitution at the same constant CL. These 2 factors could explain not
only the onset of alternans at Mid sites at longer CLs but also the
critical observation that ARI dispersion between Epi and Mid sites
during alternans was greater than during the slower basic CL. Marked
ARI alternans could be present in local electrograms without
manifest alternation of the QT/T segment in the surface ECG. The latter
was seen at critically short CLs associated with reversal of the
gradient of ARI between Epi and Mid sites, with a consequent reversal
of polarity of the intramyocardial QT wave in alternate cycles. The
arrhythmogenicity of QT/T alternans was primarily due to the greater
degree of spatial dispersion of repolarization during alternans than
during slower rates not associated with alternans. This could result in
functional conduction block and reentrant ventricular
tachyarrhythmias during the fixed drive associated with
alternans.
Key Words: QT/T alternans • long-QT syndrome • ventricular tachyarrhythmia
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