The use of myocytes as a model for developing successful heart preservation solutions

The development of a successful method to preserve the heart for relatively long periods (24-48 hr) requires demonstrating successful orthotopic transplantation and long-term survival after preservation. There are, however, multiple variables that may affect the quality of heart preservation, and it is nearly impossible to systematically study all the variables in this complicated model. One model that may be useful to study how preservation parameters affect heart cell preservation is the isolated myocyte preparation. In this study myocytes were isolated from the rabbit heart and the effects of up to 24 hr cold storage on viability measured to determine if this would be a suitable preservation model. Myocytes were stored in various preservation solutions including; EuroCollins (EC), two cardioplegic solutions (Stanford ST] and Bretschneider solution HTK]) and the University of Wisconsin solution (UW) with or without the addition of polyethylene glycol. The viability of myocytes was judged by measuring the effects of preservation and rewarming after preservation on cellular morphology (percent rod-shaped cells), ATP concentration, and LDH release. Myocytes preserved in the cardioplegic solutions were least well preserved after 12 and 24 hr storage, as judged by the loss of rod-shaped morphology and lower ATP concentration. Preservation in EC resulted in a decrease in the percent rod-shaped cells after 12 hr and 24 hr storage that was greater than obtained in the UW solutions. The best preservation of myocyte morphology and highest content of ATP was obtained in myocytes stored in the UW solutions, especially those containing PEG. The myocyte model of heart preservation shows a loss of cell integrity that is related to the preservation solution (HTK greater than ST greater than EC greater than UW-PEG) and these results are similar to what has been shown in the past with other models of heart preservation. Thus the myocyte model appears to be a useful method to test how many preservation solutions and preservation variables affect heart cell metabolism. In the future, results from these types of studies may find use in developing improved heart preservation solutions for testing in the orthotopic transplant model.