Robert F. Appleyard

Recovery and Viability of an Acute Myocardial Infarct After Transmyocardial Laser Revascularization

OBJECTIVES The short- and long-term effectiveness of transmyocardial laser revascularization was evaluated in the setting of an acute myocardial infarction. BACKGROUND Theoretically, transmyocardial laser revascularization allows direct perfusion of the ischemic area as ventricular blood flows through the channels to the myocardium. METHODS Infarcts were created by coronary occlusion in 30 sheep. Eighteen of these sheep were studied to assess short-term efficacy. The infarct was reperfused after 1 h by either removing the occlusion or by laser drilling using a high power carbon dioxide laser. The occlusions were left in place for the control group. To monitor regional recovery, percent systolic shortening was measured. To evaluate long-term effectiveness, 12 additional sheep underwent creation of an infarct. Six were treated with the laser, and six were untreated. The animals were restudied 30 days later. RESULTS In the short-term experiment, the control and reperfusion groups exhibited no recovery of regional contractility. The laser group demonstrated improvement throughout the recovery period. There was a significant difference in the area of necrosis within the same area at risk (reperfusion group 44 +/- 6% and control group 39 +/- 5% vs. laser group 6 +/- 2%). After 30 days, none of the control animals showed evidence of contraction in the infarct, whereas the laser-treated animals did. Histologic analysis of the laser-treated infarcts revealed patent channels surrounded by viable myocardium. The control-group infarcts were necrotic and scarred. CONCLUSIONS On the basis of both short- and long-term improved contractility, as well as diminished necrosis in the area at risk, these results indicate that transmyocardial laser revascularization may be an alternative method of treating ischemic heart disease.

Myocardial Stunning and Reperfusion Injury in Cardiac Surgery

Abstract This article reviews the evidence that myocardial stunning during surgical reperfusion after coronary revascularization or heart transplantation is not strictly due to myocardial injury sustained during ischemia, but results from pathophysiological events triggered by reperfusion (reperfusion injury). In sheep, left ventricular (LV) dP/dt and stroke work were reduced up to 50%, and 60% to 70% necrosis was observed in the area at risk during 3 hours reperfusion following coronary occlusion and cardioplegic arrest on bypass. Reperfusion with leukocyte depleted blood, or pharmacological blockade of either thromboxane or leukotriene receptors, provided significant improvements in LV function and myocardial blood flow, with a 40% to 50% reduction in necrosis. Similar results have been obtained using animal hearts subjected to 2 to 3 hours arrest at either 4 °C or 15°C, simulating cardiac preservation and reperfusion after transplantation. Diastolic pressure was significantly elevated, and increases in the time constant for relaxation of LV pressure and coronary vascular resistance were noted. These indices of myocardial stunning were reversed after blocking neutrophil‐endothelial cell interaction with monoclonal antibodies against CD18 or ICAM‐1 receptors, and significant improvements were also obtained after either thromboxane or leukotriene receptor blockade. We conclude that immediate postoperative myocardial stunning results largely from reperfusion injury that occurs due to an acute inflammatory response to ischemia and reperfusion, and that stunning can be largely reversed with appropriate pharmacological intervention.

Right Latissimus Dorsi Cardiomyoplasty Improves Left Ventricular Energetics

BACKGROUND The mechanism by which cardiomyoplasty appears to enhance left ventricular (LV) function is not well understood. We applied the time-varying elastance model to study the effect of cardiomyoplasty on LV function, ventriculovascular coupling, and LV energetics in an acute canine model. METHODS Right latissimus dorsi cardiomyoplasty was performed in 5 dogs. The end-systolic pressure-volume relation was generated by using brief caval occlusions. End-systolic elastance, effective arterial elastance, stroke work, internal work, total mechanical work, and stroke work efficiency (stroke work/total mechanical work) were calculated from these pressure-volume data. Myocardial oxygen consumption and overall mechanical efficiency (stroke work/myocardial oxygen consumption) were predicted using the myocardial oxygen consumption-total mechanical work relation. RESULTS Skeletal muscle contraction significantly increased end-systolic elastance, an index of contractility. Although stroke work did not change significantly, the increase in end-systolic elastance led to a 29% decrease in total mechanical work, a 50% decrease in internal work, and an increase in stroke work efficiency from 53% to 66%. This was consistent with the observed 29% decrease in effective arterial elastance/end-systolic elastance, an indicator of ventriculovascular coupling that is related inversely to stroke work efficiency. Predicted myocardial oxygen consumption decreased by at least 22%, and predicted overall mechanical efficiency increased at a minimum from 16.1% to 18.4%. CONCLUSIONS These results support the theory that cardiomyoplasty unloads the LV by decreasing LV volumes and increasing contractility. These effects appear to improve LV energetics by decreasing total mechanical work without significantly affecting stroke work, resulting in improved stroke work efficiency. The decrease in total mechanical work strongly suggests a decrease in myocardial oxygen consumption and an increase in overall mechanical efficiency.