Steven Rubins

Consequences of reperfusion after coronary occlusion: Effects on hemodynamic and regional myocardial metabolic function

Abstract Hemodynamic and regional metabolic measurements were obtained in seven closed chest dogs during a control period, 3 hours of coronary occlusion and 5 hours of reperfusion. Reperfusion resulted in intermittent ectopic arrhythmias in five dogs and severe shock in two. It usually caused increases in heart rate, coronary sinus flow and maximal isovolumetric rate of rise in left ventricular pressure (dP/dt), which were associated with a decrease in systemic pressure, left ventricular end-diastolic pressure, systemic vascular resistance and stroke work. A transitory increase in cardiac output occurred. Global myocardial oxygen consumption, which was reduced during occlusion, increased with reperfusion. Reperfusion induced abnormal lactate metabolism and myocardial potassium loss in the previously occluded area and often in the nonoccluded segment as well. Histopathologic changes of accelerated necrosis, reactive hyperemia and hemorrhage were often noted after reperfusion. These studies indicate that reperfusion after 3 hours of occlusion caused serious abnormalities in hemodynamic states, metabolic function and morphologic features of the heart.

Revascularization after 3 hours of coronary arterial occlusion: Effects on regional cardiac metabolic function and infarct size

Two experimental series of closed chest dogs were compared: Group A (five dogs with 7 days of continuous occlusion of the proximal left anterior descending coronary artery); and Group B (six dogs with 7 days of reperfusion after 3 hours of acute occlusion of the same artery). Hemodynamic measurements, ventricular wall motion, coronary sinus blood flow and regional metabolism in both coronary occluded and nonoccluded segments of the left ventricle were measured sequentially. The infarct size was characterized by detailed histopathologic analysis. In the control dogs (Group A), mechanical and metabolic function remained severely depressed after 7 days of occlusion, and mean infarct size was 31.6 percent. In Group B, significant mechanical and metabolic dysfunction developed during 3 hours of occlusion and did not improve during the 1st hour of reperfusion. However, after 7 days of reperfusion, function returned to near preocclusion level. Mean infarct size was 14.2 percent, but in two of the six dogs infarct size was 43 percent and 23 percent, respectively. The study confirmed the unstable character of the early phase of reperfusion, attributed to cell swelling, edema and hemorrhages that resulted in inadequate coronary reflow, arrhythmias and functional derangements. Prolonged reperfusion for 7 days reduced mean infarct size and improved cardiac function.

Closed chest model of intracoronary occlusion for study of regional cardiac function

Abstract A new closed chest animal technique permits selective intracoronary balloon occlusion and measurement of hemodynamic and regional metabolic function before and during occlusion and reperfusion. The distal end of the double lumen balloon catheter provides information about the nature and extent of flow distal to the occlusion and permits blood sampling or administration of pharmacologic agents directly into the ischemic zone. Independent blood sampling from the great cardiac vein by means of a specially designed balloon catheter and from the coronary sinus by cannula allows simultaneous biochemical and regional blood flow measurements from the occluded and nonoccluded segments of the heart. Simultaneous intracoronary epicardial electrocardiograms permit electrophysiologic correlation with regional hemodynamic and metabolic events. The administration of oxygen by tracheal airway can increase partial oxygen tension in the circulation distal to coronary occlusion. When intracoronary pressures distal to occlusion are markedly reduced, the frequency of ventricular fibrillation is much greater.

Correcting arterial hypoxemia by oxygen therapy in patients with acute myocardial infarction: Effect on ventilation and hemodynamics

Hypoxemia and alveolar hyperventilation were common findings in acute myocardial infarction; they were most severe in patients with left ventricular failure or shock. Hyperventilation did not appear to be due to hypoxemia and was not abolished by administration of oxygen. Oxygen administration did not increase tissue oxygen transport in patients with arterial oxygen saturations of 90 per cent or greater because of reductions in cardiac output in excess of increases in oxygen content. Peripheral vascular resistance was increased, and heart rate, blood pressure and left ventricular minute work were unchanged. In patients with arterial oxygen saturations of less than 90 per cent, oxygen administration increased cardiac output, oxygen content and tissue oxygen transport; it had a variable effect on peripheral vascular resistance.

Significance of S-T segment elevations in acute myocardial ischemia: Evaluation with intracoronary electrode technique

A method is described for measuring intracoronary S-T segment elevations in the closed chest, a technique that appears to provide more reliable measurements of myocardial ischemia. Electrodes were inserted through intracoronary balloon catheters that were placed within a coronary artery and its adjoining vein both proximal and at several points distal to a coronary occlusion. Intracoronary arterial and adjacent venous electrocardiograms produced equivalent tracings. The intracoronary S-T segment elevations after coronary occlusion resembled those recorded from the epicardial surface but were free of artifacts noted in open chest studies. Study of progressive alterations of the intracoronary S-T segment after proximal occlusion of the left anterior descending coronary artery in 18 closed chest dogs revealed a peak segment elevation of 3.2 +/- 0.6 mv within 5 minutes, followed within 2 to 3 hours by spontaneous reduction by more than 40% of the S-T elevation over the occluded zone. In 44% of these animals, the S-T elevation decreased spontaneously to less than 1 mv, and in 22% it decreased to the preocclusion control level within 2 hours of occlusion. This spontaneous decrease in S-T elevation was frequently followed by a secondary increase and then S-T segment fluctuations. Reperfusion of the left anterior descending coronary artery after 30 to 60 minutes of occlusion generally led to a prompt reduction in S-T elevation. In some cases S-T elevations persisted up to 14 hours of occlusion, were reduced after reperfusion and exhibited a renewed pronounced increase after subsequent reocclusion of the left anterior descending coronary artery. During the 1st hour after occlusion, the early S-T segment elevation followed by spontaneous reduction reduction generally corresponded temporally with the derangements in myocardial lactate extraction and potassium loss. However, after 1 hour of occlusion no clear-cut correlation could be established between S-T fluctuations and changes in hemodynamic or myocardial metabolic measurements. We conclude that the new closed chest intracoronary electrocardiographic S-T technique might be of use for monitoring the early ischemic myocardial derangements and to assess benefits or drawbacks of treatment in both the experimental animal and man. Correspondence of S-T segment elevation with lactate and potassium alterations in the coronary-occluded region in the 1st hour after occlusion indicates that S-T segment elevation might represent an index of early myocardial ischemia. The spontaneous S-T changes that follow coronary occlusion must be taken into consideration when investigators utilize S-T segment modification as a sign of effectiveness of treatment.

Progressive alterations of cardiac hemodynamic and regional metabolic function after acute coronary occlusion

Abstract Hemodynamic and regional metabolic function was assessed simultaneously in 34 closed chest dogs during a preocclusion control period and 3 hours of intracoronary balloon occlusion of the proximal left anterior descending artery. The data indicate immediate alteration in hemodynamic measurements with many fluctuations in the 3 hour occlusion period. No specific hemodynamic pattern was evident. When the mean data were analyzed, occlusion was found to cause early increases in left ventricular end-diastolic pressure (43 percent) and systemic vascular resistance (21 percent), and decreases in peak systolic pressure (5 percent), maximal rate of rise of left ventricular pressure (dP/dt) (20 percent), cardiac output (19 percent), stroke work (26 percent) and coronary sinus blood flow (19 percent). Regional metabolic measurements showed significantly different metabolic function in the occluded and nonoccluded zones of the left ventricle. Lactate balance decreased to near production levels, and a substantial potassium loss occurred in the occluded zone shortly after occlusion; lactate and potassium balances later fluctuated, but usually remained depressed. Abnormal lactate metabolism and potassium efflux were often observed in the nonoccluded zone. A 6 to 8 percent increase in oxygen extraction was noted in both segments. Progressive alterations in hemodynamic and metabolic function of the heart after coronary occlusion are not uniform and exhibit dynamic fluctuations. Although a direct relation was noted between the degree of metabolic dysfunction and hemodynamic change, individual experiments often revealed a distinct metabolic-mechanical dissociation.