Global cardiac function: mechano-energetico-informatics.

This review on the global cardiac function covers cardiac mechanics, energetics, and informatics that I have developed with my collaborators over the last 30 years in Japan and USA. We first established E(max) (end-systolic maximum elastance or pressure/volume ratio) as a new index of ventricular contractility using canine hearts. We then expanded the E(max) concept to PVA (systolic pressure-volume area consisting of external mechanical work and mechanical potential energy) as an innovative measure of total mechanical energy of ventricular contraction and discovered it to be a reliable determinant of ventricular energetics or O(2) consumption (V(O(2))). We have discovered that E(max) shifts the V(O(2))-PVA relation and the E(max) dependency (O(2) cost of E(max)) varies among different pathophysiological hearts. We also searched for the basis of E(max) in crossbridge behavior information contained in an X-ray diffraction of papillary muscle. Recently, we established a new integrative analysis to estimate total Ca(2+) recruited for excitation-contraction coupling in a beating heart using the E(max)-PVA-V(O(2)) information. These global, mechano-energetico-informatic approaches seem to facilitate better understanding of cardiac function, as required in the present post-genomic era when more physiomic knowledge is required not only in cardiac function but also in all other physiologic functions.