Circulation, Vol 84, 768-777, Copyright © 1991 by American Heart Association
S Kimura, AL Bassett, T Furukawa, N Furukawa and RJ Myerburg
BACKGROUND. Ischemia-induced electrophysiological changes are more
prominent in epicardial cells than in endocardial cells. Epicardial action
potentials shorten more than endocardial action potentials during ischemia.
Since the L-type Ca2+ current plays an important role in the maintenance of
action potential duration, we hypothesized that the Ca2+ current is
affected more in epicardial cells than in endocardial cells during
ischemia. METHODS AND RESULTS. To test this hypothesis, we examined the
effect of metabolic inhibition, a major component of ischemia, on action
potentials and the Ca2+ current in single cells isolated from the
endocardial and epicardial layers of the feline left ventricle. The
membrane voltage and current were measured by using the whole-cell mode of
the patch-clamp technique. During control periods, action potentials
recorded from epicardial myocytes had lower amplitude, a prominent notch
between phases 1 and 2, and shorter action potential duration compared with
those recorded from endocardial myocytes. However, the amplitude and
current-voltage relation of the Ca2+ current were similar in endocardial
and epicardial cells at test potentials of -30 to 60 mV elicited from a
holding potential of -40 mV. The time course of inactivation of the Ca2+
current also was identical in the two cell types. After 15 minutes of
superfusion with glucose-free Tyrode's solution containing 1 mM CN-, action
potential duration was reduced by 13 +/- 7% in endocardial cells and by 80
+/- 9% in epicardial cells (p less than 0.01). The peak Ca2+ current was
reduced by 21 +/- 9% in endocardial cells and by 37 +/- 6% in epicardial
cells (p less than 0.01). CONCLUSIONS. We conclude that enhanced depression
of the Ca2+ current may account in part for the greater action potential
shortening in epicardial cells during ischemia and metabolic inhibition.
ARTICLES
Differences in the effect of metabolic inhibition on action potentials and calcium currents in endocardial and epicardial cells
Department of Medicine (Cardiology), University of Miami School of Medicine, FL 33101.
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