Circulation, Vol 73, 1013-1021, Copyright © 1986 by American Heart Association
CC Gornick, HG Tobler, MC Pritzker, IC Tuna, A Almquist and DG Benditt
In this study we used transmural multipolar electrodes, sonomicrometers
implanted within the left ventricular wall, and cardiac electrical
stimulation techniques to examine the effect of transient mechanical
posterior papillary muscle traction on local myocardial electrophysiologic
characteristics. Nine open-chest dogs were atrially paced (cycle length 400
msec) followed by insertion of timed premature extrastimuli at left
ventricular epicardial pacing sites either in the vicinity of (traction
zone) or remote from (nontraction zone) the site of papillary muscle
traction. Electrophysiologic recordings were made before and during periods
of intermittent papillary muscle traction of predetermined timing,
application rate (25 cm/sec), and duration (170 msec). Papillary muscle
traction was applied in late diastole just before the last beat of each
atrial drive train. In seven of nine dogs application of transient
papillary muscle traction resulted in significantly earlier local
ventricular activation (mean activation advancement 30 +/- 13 msec),
altered QRS morphology of the last conducted atrial drive-train beat, and
relative prolongation of ventricular functional refractory period in the
traction zone. Conversely, in nontraction zones in these seven dogs, early
activation did not occur and refractoriness remained unchanged as tested by
a locally placed extrastimulus. In two of nine dogs traction failed to
induce early activation and changes in refractoriness did not occur.
Alterations in regional myocardial blood flow (assessed by radioactive
microsphere technique) did not appear responsible for the observed changes,
since there was no demonstrable traction-induced difference in regional
blood flow between the traction and nontraction zones.(ABSTRACT TRUNCATED
AT 250 WORDS)
ARTICLES
Electrophysiologic effects of papillary muscle traction in the intact heart
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