Samuel Meerbaum

Early phase acute myocardial infarct size quantification : Validation of the triphenyl tetrazolium chloride tissue enzyme staining technique

Gross histochemical delineation of myocardium which has lost dehydrogenase enzyme activity has been shown to facilitate macroscopic recognition of necrotic myocardium. The present study was undertaken to assess the accuracy of the triphenyl tetrazolium chloride (TTC) technique for quantitating myocardial infarct size very early after coronary occlusion. In 16 closed-chest dogs the left anterior descending coronary artery was occluded with an intra-arterial balloon. Twelve dogs were killed 6 hours after occlusion, their hearts excised, cut from apex to base into 1 cm thick slices, and incubated in TTC. Whole-mount histologic sections of each slice were prepared. Myocardial infarct size was measured by planimetry of photographs of each gross slice and histologic section using classical criteria of necrosis. Myocardial infarct size determined in 54 slices by the TTC technique and histologically was similar (25 +/- 16% vs 27 +/- 16% of the left ventricular mass, mean +/- SD) with close correlation between the two methods (r = 0.91). Four dogs were killed 3 hours after occlusion and TTC stained and unstained myocardium was studied by electron microscopy. When the TTC technique identified necrosis so did electron microscopy. Areas identified by the TTC technique as non-necrotic were either normal or only ischemic by electron microscopy. Thus, using TTC, necrosis can be quantitated reliably 6, and even 3 hours after coronary occlusion, before histologic changes are clearly diagnostic. This technique represents a reliable, practical means for quantitation of recent infarction and for studying the evolution of ischemic injury in its early phase.

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.

Cross-sectional echocardiography III. Analysis of mathematic models for quantifying volume of symmetric and asymmetric left ventricles

Cross-sectional echocardiography was utilized for quantification of volume in 19 formalin-fixed left ventricles in the presence or absence of ventricular symmetry, defined by the ratio of septal-lateral to anterior-posterior diameter. In 10 symmetric ventricles this ratio was 1.23 +/- 0.06 (mean +/- SEM), whereas in nine asymmetric ventricles the ratio was 1.80 +/- 0.07. Area, diameter, and length measurements were obtained from short- and long-axis cross-sectional images of the left ventricle and volume was calculated by five mathematical models previously described. To evaluate the reliability of each model, echocardiographic left ventricular volume was compared by linear regression and percent error analyses to directly measured fluid volume. In symmetric ventricles, excellent correlations (r = 0.996 to 0.967) and reasonable mean percent errors (6% to 31%) were observed for all models. In asymmetric ventricles, models utilizing short-axis area or two short-axis diameters retained high correlation coefficients (r = 0.985 to 0.956) and similar mean percent errors, but standard formulas previously used with M-mode echo and angiography showed lower correlations (r = 0.886 to 0.873) and higher mean percent errors (52% to 54%). Thus, in the presence of ventricular asymmetry, analysis of short-axis areas or diameters with cross-sectional echocardiography is well suited for quantification of left ventricular volumes.

Assessment of quantitative methods for 2-dimensional echocardiography.

Several 2-dimensional echocardiographic (2-DE) methods were tested in vitro for accuracy of linear and cross-sectional measurements and in vivo for left ventricular (LV) volume reconstruction. With 2-DE instrument settings at low and high gains and with precise in vitro calibrations, we studied myocardial slice thickness (3.0 to 10.0 mm). The 2-DE myocardial thickness was measured by leading-trailing, trailing-leading, and leading-leading methods. Regression analysis of 2-DE versus direct measurements yielded excellent correlations for all 3 methods (r greater than 0.985), with interobserver variability less than 3%. Accuracy of measurement was satisfactory only for the leading-leading method (3 and 6% error at low and high gains, respectively); other methods substantially over- or underestimated thickness. Thin myocardial slices (less than 1 mm thick) were applied to cylinders and fixed in formalin to produce precise cavity areas (1.8 to 7.0 cm2). Regression analysis of 2-DE versus actual cavity area gave high correlations (r greater than 0.970), and low interobserver variability (less than 4%) for the inner edge and leading edge methods, but the leading edge method was the most accurate (1.3 to 2.5% error). In vivo LV volumes in 7 anesthetized dogs were compared with 2-DE and cineangiography. Good correlations (r = 0.92) were obtained, but the inner edge method underestimated angiographic volume, whereas the leading edge method reduced the magnitude of underestimation. Thus, the leading edge method for 2-DE is most accurate not only for linear and cross-sectional measurements of the myocardium, but also for application to in vivo LV volumes.

Diastolic retroperfusion of acutely ischemic myocardium

The effectiveness of coronary venous retroperfusion treatment of an ischemic myocardial segment was assessed by measurements of regional and global myocardial function in 16 dogs. The left anterior descending coronary artery was acutely occluded for 75 minutes. After the first 30 minutes of occlusion, diastolic retroperfusion was instituted for 45 minutes by synchronized pumping of arterial blood from the brachial artery into the anterior interventricular coronary vein. Data collected in the preocclusion control period, during occlusion and the subsequent retroperfusion period included simultaneous measurement os ischemic and border zone myocardial forces, epicardial electrocardiographic S-T segments, intracoronary pressure, coronary blood flow and oxygen pressure (PO2) sampled distal to the site of occlusion. Retroperfusion resulted in significant improvement from the level of regional dysfunction observed after 30 minutes of occlusion: Ischemic zone myocardial force increased 106%, epicardial S-T elevation decreased 46%, normalized peripheral left anterior descending coronary arterial flow increased 50% and distal left anterior descending PO2 decreased 44%. These regional improvements were significant when compared with findings in an untreated series of 12 dogs with 75 minutes occlusion of the left anterior descending coronary artery. Diastolic-augmented coronary venous retroperfusion with arterial blood provided significant but not complete restoration of function in the ischemic segment. Therefore, in the earliest phase of acute myocardial infarction, retroperfusion might represent a useful temporary support to an otherwise inaccessible jeopardized zone of the heart. Regional retroperfusion may constitute an effective emergency procedure, particularly when the occlusive lesions are diffuse and other medical or surgical emergency procedures are inadvisable, unavailable or ineffective.

Real time computerization of two-dimensional echocardiography

A computerized system was developed for real time acquisition, enhanced processing, analysis, and display of cross-sectional images of the left ventricle derived by two-dimensional echocardiography (2DE). The new methodology couples a standard medical imaging computer system to the video output of any current 2DE unit, uses a 128 x 128 or 64 x 64 matrix window and stores the real time 30 frames/sec digitized images on a magnetic disk. Computerized beat-to-beat and frame-by-frame processing employs space-time smoothing the automatic detection of endocardial interfaces by standard threshold and second derivative techniques. Multiple views are displayed in real time with 256 levels of gray and color. The methodology was used to analyze and graphically display frame-by-frame changes throughout the cardiac cycle. In addition, regional wall motion and thickness were analyzed in 12 sectors of individual cross-sections using a standardized angular subdivision originating at the center of area and indexed by an external reference point. An algorithm was developed to correct cross-sectional interference definition from the commonly used trailing-to-leading edge to the more valid leading-to-leading outline technique. Computerized analysis of spatial and temporal variations of cardiac contraction were demonstrated in several clinical and experimental applications, including bicycle exercise testing, investigation of acute myocardial infarction, and assessment of interventions. Initial evaluation indicates that the new real time computerized digital acquisition and data analysis represents a major advances toward quantitation of left ventricular function using 2DE.

Synchronized retroperfusion of coronary veins for circulatory support of jeopardized ischemic myocardium

A retroperfusion system was developed that augments retrograde delivery of arterial blood into an acutely ischemic myocardial region during diastole and facilitates coronary venous drainage in systole. An electrocardiogram-synchronized, gas-actuated bladder pump propels retroperfusate through an autoinflatable balloon catheter whose tip is placed within the regional coronary vein that drains the ischemic myocardium. Experiments were performed in 26 closed chest dogs with 4 hour intracoronary balloon occlusion of the proximal left anterior descending coronary artery. An untreated control series consisted of 13 dogs; the remaining 13 dogs were treated with retroperfusion, which was initiated after the first hour of acute coronary occlusion. Synchronized retroperfusion resulted in a significant 37 +/- 10 per cent (mean +/- standard error of the mean) decrease in left ventricular end-diastolic pressure from 11 +/- 2 to 5 +/- 21 mm Hg, a 20 +/- 4 percent decrease in peak systolic pressure (140 +/- 7 to 110 +/- 6 mm Hg) and a 25 +/- 6 percent reduction in systemic vascular resistance (3,880 +/- 340 to 2,380 +/- 300 dynes sec cm-5). Ischemic region intracoronary S-T segment elevation decreased 40 +/- 15 percent, and potassium loss was reduced 92 +/- 22 percent. Partial pressure of oxygen measured distal to the coronary occlusion decreased 36 +/- 2 percent, suggesting oxygen delivery to and extraction by the jeopardized ischemic myocardium. Ventriculography in four dogs revealed an increase in left ventricular ejection fraction and reversal of ischemic segment dyskinesia by synchronized retroperfusion. A nitro-blue tetrazolium study of 10 excised hearts indicated that 3 hours of synchronized retroperfusion significantly reduced the size of ischemic injury to 3.3 +/- 2 percent of the left ventricle (versus 16.2 +/- 5 percent in the untreated control group). In addition, retroperfusion appeared to correct ischemic arrhythmias. The experimental data suggest that this treatment is capable of improving cardiac function and salvaging jeopardized myocardium. Clinical application is envisioned as a prompt temporary emergency support for acute and profound ischemic dysfunction not readily treatable by other interventions.

Effects of staged versus sudden reperfusion after acute coronary occlusion in the dog

Sudden and staged reperfusion after experimental coronary artery occlusion was studied in relation to recovery of cardiac function and postreperfusion arrhythmias. Eighteen closed chest dogs with 3 hour intracoronary balloon occlusion of the proximal left anterior descending coronary artery were studied using two-dimensional echocardiography over a period of 3 weeks after reperfusion. Nine dogs had sudden reperfusion by abrupt balloon deflation. In nine other dogs reperfusion was staged with partial reflow (20 ml/min) for 2 hours through the central lumen of the catheter during persisting intracoronary balloon inflation, followed by balloon deflation and full reperfusion. Within the first 30 minutes of sudden reperfusion, ischemic zone end-diastolic wall thickness increased significantly, from 6.8 +/- 0.3 mm at 3 hours of occlusion to 10.2 +/- 2.6 mm (p less than 0.05). In contrast, at 30 minutes of partial reflow, wall thickness was 7.5 +/- 0.7 versus 6.8 +/- 0.7 mm at 3 hours of occlusion (NS). A small temporary increase in end-diastolic wall thickness was noted when full reflow was established after 2 hours of staged reperfusion. However, wall thickness was normal on the first day in the staged reperfusion series, while sudden reperfusion delayed recovery to 7 days. Function of the ischemic zone failed to improve substantially until day 3 after sudden reperfusion, whereas it improved consistently starting as early as 30 minutes after institution of the staged reperfusion.(ABSTRACT TRUNCATED AT 250 WORDS)

Prevention of ischemic injury and early reperfusion derangements by hypothermic retroperfusion

Hypothermic synchronized retroperfusion was applied during coronary artery occlusion to determine its ability to alleviate junctional derangements of reperfusion and to reduce infarct size. The proximal left anterior descending coronary artery was occluded in 25 closed chest dogs for 3 hours and then reperfused for 7 days. Thirteen dogs with no reperfusion pretreatment served as a control group (Group A). In 12 dogs, hypothermic retroperfusion was applied from 30 minutes up to 3 hours of the occlusion period (Group B). Sequential two-dimensional echocardiographic and hemodynamic as well as metabolic measurements were performed. Compared with untreated control dogs, dogs with hypothermic synchronized retroperfusion had significantly reduced heart rate and rate-pressure product, decreased left ventricular volumes and improved ejection fraction during the occlusion period. Two-dimensional echocardiographically-derived ischemic zone systolic fractional area change and systolic wall thickening indicated significantly improved function as a result of retroperfusion. During the reperfusion period, untreated control dogs (group A) had more severe derangements in hemodynamics and wall motion than dogs treated by hypothermic retroperfusion (group B). Mortality was 30.7% in group A, 16.7% in group B and 7th day infarct size as percent of the left ventricle was 12.0 +/- 6.5 (mean +/- standard deviation) and 4.2 +/- 5.9, respectively (p less than 0.02). It is concluded that hypothermic synchronized retroperfusion applied after coronary occlusion and before reperfusion significantly improves cardiac function during occlusion, minimizes complications of reperfusion and reduces the ultimate infarct size. Because this form of circulatory assistance helps maintain cardiac function and delays the evolution of myocardial necrosis, its application may be beneficial during an evolving acute myocardial infarction before achievement of surgical or nonsurgical reperfusion.