Swelling of capillary endothelial cells and cardiomyocytes in the ischaemic myocardium of artificially arrested canine hearts.

To establish whether coronary perfusion with cardioplegic solutions results in better intraischaemic structural preservation of endothelial cells than of cardiomyocytes, we determined intraischaemic swelling of these two cell types in hearts differently arrested during global ischaemia at 5 degrees C. Cardiac arrest was induced in situ by aortic cross clamping or by additional coronary perfusion with various cardioplegic solutions. Parameters for cellular swelling were determined, i.e. barrier thickness of capillary endothelial cells and sum of the volume fractions (V(V)) of free sarcoplasm and mitochondria (V(VSp) + V(VMi)) in cardiomyocytes. In order to test the intraischaemic relative increase of cellular volume in both cell types, regression analyses were performed. The results show that the relative intraischaemic volume increase was similar in both cell types after perfusion with histidine-tryptophan-ketoglutarate solution, and significantly less pronounced in capillary endothelial cells after perfusion with University of Wisconsin solution. In hearts arrested with St. Thomas' Hospital solution, a significantly higher volume increase was determined in capillary endothelial cells. Thus, capillary endothelium does not generally show a higher structural preservation than cardiomyocytes during ischaemia. Instead, volume regulation in both types of cells depends on the type of cardioplegic solution used. These results should be taken into consideration in human transplantation medicine.

Electron microscopic stereology of capillary endothelial cells and cardiomyocytes in artificially arrested canine hearts.

In open heart surgery and transplantation, sufficient structural preservation of the myocardium immediately following cardioplegic arrest is a precondition for overcoming ischemia and for resumption of postischemic function. Therefore, we compared the protective effect of three clinically applied cardioplegic solutions with fibrillating and beating hearts using structural criteria. Left ventricular samples were taken from (1) beating, or (2) fibrillating or arrested hearts following coronary perfu-sion with (3) St. Thomas' Hospital solution, (4) histidine tryptophane ketoglutalate (HTK) (Custodiol), or (5) University of Wisconsin (UW) solution and fixed by immersion. Ultrastructural differences in the swelling of capillary endothelial cells and myocytes were quantitatively evaluated using stereological methods. Endothelial cells were somewhat more swollen after St. Thomas perfusion than those in beating and fibrillating hearts. HTK-arrested hearts showed significantly lower values for cellular edema than beating hearts. UW perfusion resulted in the (significantly) lowest degree of endothelial cell edema. Edematous changes in myocytes were significantly greater in St. Thomas-arrested hearts than in UW- or HTK-arrested hearts. Cardiomyocyte edema in beating and fibrillating hearts was comparable to that in St. Thomas-perfused hearts. Thus, the stereol-ogical analysis revealed significant differences between cardioplegic solutions in structural preservation of myocardial ultrastructure.