Glucocorticoid protection of the myocardial cell membrane and the reduction of edema in experimental acute myocardial ischemia

Abstract

A possible protective effect of glucocorticoids on the ischemic myocardium was investigated in in situ dog hearts subjected to regional ischemia and in isolated rat hearts subjected to global ischemia. In the whole-animal preparation, the left anterior descending coronary artery (LAD) was occluded for 3 hours, or for 2 1/2 hours followed by 30 minutes of reperfusion. Dexamethasone phosphate was randomly administered (20 mg. per kilogram intravenously) after 15 minutes of ischemia. Its effects were studied on the following: (1) myocardial cell membrane integrity, using electron microscopic examination of tissue biopsies treated with colloidal lanthanum; (2) myocardial water content, measuring the wet/dry weight of myocardial tissue; (3) ischemic injury, by a count of fuchsinophilic cells at light microscopy. In isolated rat hearts, ischemia was produced by a 60 per cent reduction of coronary flow. Randomized hearts were perfused for 2 hours with dexamethasone, 15 mg. per milliliter in buffered salt solution. Study included determination of tissue water content and coronary vascular resistance. Lanthanum was confined to the extracellular spaces in normal dog myocardium, but it was found all intracellularly after 3 hours of ischemia or after reperfusion. This was associated with morphologic changes characteristic of irreversible cell injury. In the hearts treated with dexamethasone, lanthanum remained excluded from the cells, water content was less (p less than 0.005), and fuchsinophilia less severe (p less than 0.005). Likewise, water content was less (p less than 0.005) and the increase in coronary vascular resistance resulting from ischemia less severe (p less than 0.005) in the dexamethasone-treated isolated rat hearts. Thus dexamethasone administered in pharmacologic doses, early, appeared to stabilize the cell membrane, limit myocardial edema, and reduce the severity of injury, both during ischemia and upon reperfusion.