The acute effects of reperfusion on myocardium reversibly damaged by 15 minutes of severe ischemia in vivo, were studied. Changes in the adenine nucleotide pool, cell volume regulation, myocardial calcium, and ultrastructure were studied at the end of 15 minutes of ischemia and after 0.5, 3.0, and 20 minutes of reflow. Before reperfusion, adenosine triphosphate and the adenylate pool decreased by 63% and 44% of control, respectively, and the adenylate charge was reduced to 0.65. After 3 minutes of reperfusion, the adenylate charge was restored to control by the rephosphorylation of adenosine mono- and diphosphate, but adenosine triphosphate was still reduced by 45%. Mild tissue edema was detected after 0.5 minute of reflow and persisted throughout 20 minutes of reperfusion. The increased tissue water was accompanied by a slight increase in sodium and a marked increase in tissue potassium. Although massive calcium accumulation develops when irreversibly injured tissue is reperfused, no calcium overload was detected during early reperfusion of reversibly injured myocytes. Reperfusion for 3 minutes exaggerated the mitochondrial swelling induced by 15 minutes of ischemia but after 20 minutes of reperfusion, myocardial ultrastructure was essentially normal except for rare swollen, or disrupted, mitochondria. Thus, the cellular abnormalities associated with brief periods of ischemia persist for variable periods of time after reperfusion of reversibly injured myocytes. First: although adenine nucleotide repletion occurs very slowly, the adenylate charge was restored after 3 minutes, indicating rapid resumption of mitochondrial adenosine triphosphate production. Second: calcium overload was not detected, but myocardial edema and increased potassium persisted throughout the 20 minutes of reperfusion. Third: the ultrastructural consequences of ischemia were nearly reversed after 20 minutes of reperfusion.
The effect of repetitive periods of coronary occlusion on myocardial adenine nucleotides, lactate, and infarct size was studied. In one series of dogs, the circumflex artery was occluded for one, two, or four 10-min episodes, each separated by 20 min of reperfusion. Hearts were excised and sampled for metabolic assays after one or more periods of ischemia before or after reperfusion. One 10-min period of ischemia caused a 61% loss of ATP and 41% loss of adenine nucleotides from the most severely ischemic subendocardial zone. Reperfusion resulted in rapid restoration of the adenylate charge but in only slight repletion of the adenine nucleotide pool. However, two or even four 10-min periods of ischemia caused no further adenine nucleotide loss. In contrast, 40 min of continuous coronary occlusion caused an 87% depletion of ATP and 67% of the adenine nucleotide pool from the same subendocardial region. Collateral blood flow was similar during all occlusions, but lactate accumulation was less during later occlusions. In a second series of experiments, myocardial necrosis was quantitated 4 days after four 10-min periods of ischemia. Necrosis was observed in only one of six dogs and, in this dog, was only 1.5% of the anatomic area at risk. Thus intermittent reperfusion prevents cumulative metabolic deficits and myocardial ischemic cell death, perhaps by restoring the capacity for high-energy phosphate (HEP) production and/or washing out deleterious catabolites. A first episode of ischemia also slows HEP utilization in subsequent episodes.
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