Mechanical determinants of myocardial oxygen consumption with special reference to external work and efficiency.

OBJECTIVE

The aim of the study was to investigate the ambiguous effect of left ventricular afterload on myocardial work, oxygen consumption, and efficiency.

METHODS

Myocardial oxygen consumption and mechanical parameters of the left and right ventricle were measured in situ in a modified heart-lung preparation in the rat. Left ventricular afterload was adjusted arbitrarily by means of a Starling resistor mounted in a shunt circuit between the left ventricle and the caudal caval vein. Left and right ventricular pressure and aortic pressure as well as pulmonary flow and the flow in the shunt circuit were measured. The left ventricular pressure and volume values were converted into wall stress and length data assuming a thick walled sphere, and external work was calculated from left ventricular force and shortening.

RESULTS

Left ventricular external work ran through a maximum with decreasing aortic pressure. Left ventricular oxygen consumption per gram and beat correlated linearly with left ventricular peak wall stress, tension-time integral, and maximum rate of stress development. Left ventricular force and shortening, the two components of external work, acted differently: force determined left ventricular oxygen consumption, whereas shortening had no direct effect on myocardial oxygen consumption, but was important in determining left ventricular efficiency.

CONCLUSIONS

The interplay between left ventricular afterload and coronary perfusion pressure is of special significance for the heart in situ. The decrease in shortening and external work as well as the diminution in efficiency, observed at low aortic pressure values, can be attributed to impaired coronary perfusion. The coronary perfusion pressure must therefore be taken into consideration for the critical examination of the efficiency of the heart in situ.