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The Journal of Thoracic and Cardiovascular Surgery, Vol 104, 364-373, Copyright © 1992 by The American Association for Thoracic Surgery and The Western Thoracic Surgical Association

ARTICLES

Myocardial oxygen consumption of fibrillating ventricle in hypothermia. Successful account by new mechanical indexes--equivalent pressure- volume area and equivalent heart rate

H Yaku, Y Goto, S Futaki, Y Ohgoshi, O Kawaguchi and H Suga
Department of Cardiovascular Dynamics, National Cardiovascular Center (NCVC) Research Institute, Osaka, Japan.

We studied the effects of cardiac hypothermia on myocardial oxygen consumption of a fibrillating ventricle and evaluated whether myocardial oxygen consumption of a fibrillating ventricle in hypothermia can be accounted for by new mechanical indexes: equivalent pressure-volume area and equivalent heart rate in the isolated cross- circulated canine heart preparation. Equivalent pressure-volume area is the area that is surrounded by a horizontal pressure-volume line at the pressure of a fibrillating ventricle and the end-systolic and end- diastolic pressure-volume relations in the beating state in the pressure-volume diagram. Equivalent pressure-volume area is an analog of the pressure-volume area of a beating heart and has been proposed to be a measure of the total mechanical energy of a fibrillating ventricle. Equivalent heart rate was calculated from myocardial oxygen consumption per minute in both beating and fibrillating states under unloaded conditions as an estimate of the frequency of contractions of individual myocytes on the assumption that individual myocytes during ventricular fibrillation have the same contractility as that in the beating state. We estimated myocardial oxygen consumption per minute of the fibrillating ventricle at various ventricular volumes as a function of both equivalent pressure-volume area and equivalent heart rate. The myocardial oxygen consumption-equivalent pressure-volume area relation during ventricular fibrillation in hypothermia was highly linear, with a correlation coefficient of 0.90 (mean). The relation between estimated and directly measured myocardial oxygen consumption values of a fibrillating ventricle in hypothermia was highly linear (r = 0.98), and the regression line (y = 0.80x + 0.48) was close to the identity line in the working range. Therefore we conclude that equivalent pressure-volume area is the primary determinant of myocardial oxygen consumption during ventricular fibrillation in hypothermia, and myocardial oxygen consumption of a fibrillating ventricle in hypothermia can be accounted for by the combination of equivalent pressure-volume area and equivalent heart rate as in normothermia.