Complete prevention of myocardial stunning, contracture, low-reflow, and edema after heart transplantation by blocking neutrophil adhesion molecules during reperfusion.

This study tested the hypothesis that preventing neutrophil adhesion during reperfusion, by blocking either the neutrophil membrane CD18 integrin complex or its endothelial and myocyte ligand, intercellular adhesion molecule-1 (ICAM-1), would reduce myocardial inflammation and edema and improve reflow and ventricular function after heart preservation and transplantation. After cardioplegia and insertion of a left ventricular balloon, rabbit hearts were heterotopically transplanted into recipient rabbits either immediately (immediate, n = 12) or after preservation in 4 degrees C saline (3 hours of ischemia, n = 33). Forty-five minutes before reperfusion, recipients of preserved hearts received intravenous infusions of either saline (vehicle, n = 13), anti-CD18 monoclonal antibody (Mab) R15.7 (2 mg/kg) (anti-CD18, n = 10), or anti-ICAM-1 Mab R1.1 (2 mg/kg) (anti-ICAM, n = 10). During 3 hours of reperfusion the slope of the peak-systolic pressure-volume relation and its volume-axis intercept, the exponential elastic coefficient of the end-diastolic pressure-volume relation, the unstressed ventricular volume, and the time constant of the exponential left ventricular pressure decay after dP/dtmin were serially measured. Myocardial blood flow was measured with microspheres from which coronary vascular resistance was calculated. After explanation, the degree of myocardial inflammation, estimated by tissue neutrophil sequestration (myeloperoxidase assay) and myocardial water content were determined. Within each group no significant differences in measurements made at 1, 2, and 3 hours of reperfusion were noted. Compared with the immediate transplantation group, the vehicle group demonstrated a significant increase in myeloperoxidase activity (3380 +/- 456 versus 1712 +/- 552 microU/gm, p < 0.05), coronary vascular resistance (115.5 +/- 13.4 versus 70.5 +/- 10.6 U/gm, p < 0.05), and myocardial water content (79.8% +/- 0.4% versus 75.6% +/- 1.3%, p < 0.05), a significant decrease in unstressed ventricular volume (a leftward shift in the end-diastolic pressure-volume relation) (-0.49 +/- 0.24 versus 0.28 +/- 0.21 ml, p < 0.05), and a marked prolongation in exponential left ventricular pressure delay after dP/dtmin (156.64 +/- 3.81 versus 37.25 +/- 3.34 msec, p < 0.01).(ABSTRACT TRUNCATED AT 400 WORDS)     

Free radical scavengers and myocardial preservation during transplantation

The efficacy of oxygen radical scavengers in preservation of left ventricular (LV) function after prolonged hypothermic global ischemia was investigated in a model of orthotopic cardiac transplantation in sheep. Group 1 hearts (N = 8) received hypothermic crystalloid cardioplegic solution, and were harvested and stored at 4 degrees C in balanced electrolyte solution for six hours prior to transplantation. Group 2 (N = 9) received identical treatment with the addition of 30,000 units of superoxide dismutase to the cardioplegic solution and the administration of 60,000 units of superoxide dismutase coincident with reperfusion. All animals were weaned from cardiopulmonary bypass. Preischemic and postischemic LV function was determined using sonomicrometry and a micromanometer-tipped LV catheter. Coronary blood flow was determined using standard microsphere techniques, and platelet deposition was assayed with autologous platelets labeled with indium 111. Lipid peroxidation products were measured using thiobarbituric acid assay. LV performance was significantly better (p less than .05) in Group 2 hearts when assessed by the slope of the end-systolic pressure-volume relationship and the stroke work versus end-diastolic volume relationship. There was better preservation of endocardial blood flow in the group receiving superoxide dismutase compared with controls (p less than .05). Platelet deposition, as determined by the tissue to blood ratio of scintigraphic counts, was greater (p less than .05) in controls compared with the group receiving superoxide dismutase. In addition, thiobarbituric acid reactive species were significantly less (p less than .05) in Group 2 versus Group 1 hearts.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cariporide (HOE-642) improves cardiac allograft preservation in a porcine model of orthotopic heart transplantation

BACKGROUND: Acute graft dysfunction caused by ischemia-reperfusion injury is recognized as a major source of morbidity and mortality following adult heart transplantation. The aim of this study was to determine whether treating the donor and recipient with cariporide, an inhibitor of the sodium-hydrogen exchanger, could reduce ischemia-reperfusion injury. METHODS: A porcine model of donor brain death, hypothermic ischemic preservation, and orthotopic cardiac transplantation was used. Allografts in both the control group (CON, n=6) and treatment group (CAR, n=6) were arrested and stored for 4 hours in the extracellular crystalloid cardioplegia currently used in the clinical transplantation program at our institution. In addition, both the donor and recipient animals in the CAR group received a single intravenous dose of cariporide (2 mg/kg) 15 minutes before harvesting and reperfusion, respectively. RESULTS: The initial rate of troponin I release was significantly lower in recipients of CAR hearts than in recipients of CON hearts (P =0.020). All hearts were weaned successfully from bypass. More CAR hearts were weaned successfully at the first attempt, at 1 hour post-reperfusion, than CON hearts (6 of 6 vs 3 of 6), but this did not achieve statistical significance. Left ventricular contractility (preload recruitable stroke-work relationship) and left ventricular compliance (end-diastolic pressure-volume relationship) were significantly better preserved in CAR hearts than CON hearts (both P <0.0001). CONCLUSIONS: Myocardial injury was reduced, and contractile function was better preserved in allografts that received cariporide, compared with allografts that received conventional preservation alone.     

Comparative study of the protective effects of a cold potassium cardioplegic solution verses the Collins solution in the preservation of canine hearts for 24 hours by simple immersion method

This study was undertaken to compare the protective effects of a cold potassium cardioplegic solution (K+:23 mEq/l, Na+:25.2 mEq/l) versus the Collins solution (K+:115 mEq/l, Na+:10 mEq/l) on the preservation of isolated canine hearts for 24 hours by simple immersion. To assess the viability of the preserved hearts, recovery of left ventricular function, myocardial water content and myocardial ultrastructures were evaluated before and after preservation. Isovolumic left ventricular function was evaluated with an intra-ventricular balloon method using a preparation of an isolated, blood-perfused heart. The cardioplegic solution group (n = 9) showed significantly better recovery results of pressure developed in the left ventricular (84-76 vs. 35-37%) and dp/dt (90-52% vs. 44-39%) as compared to the Collins solution group (n = 13). Compliance of the left ventricle was well maintained in the cardioplegic solution group. The Collins solution group showed a significant increase of myocardial water content and a remarkable decrease in compliance of the left ventricle after preservation. The quantitative evaluation results of the mitochondrial injury (mitochondria score) found through electron microscopy revealed that the mitochondria of the cardioplegic solution group were less injured as compared to those of the Collins solution group. We concluded that our cold potassium cardioplegic solution offers superior protective effects on the preservation of the heart by simple immersion as compared to the Collins solution.     

Successful long-term preservation of the neonatal heart with a modified intracellular solution.

Current methods of myocardial preservation for transplantation are suboptimal. A newly developed intracellular cardioplegic and storage solution (modified University of Wisconsin solution, group 1) was compared in a randomized, blinded fashion with our present clinical protocol, Stanford cardioplegic solution and saline storage (group 2) in an isolated neonatal pig model. After arrest and storage for 12 hours at 4 degrees C, biopsy specimens were taken from six group 1 hearts and five group 2 hearts for examination under an electron microscope and assessment of high-energy phosphate levels and water content. The remainder (group 1, n = 7; group 2, n = 6) were reperfused with blood for 50 minutes, after which function curves were obtained at left ventricular end-diastolic pressures of 3 to 12 mm Hg and biopsy tissue was taken. Eight control hearts (group 3) were cannulated in situ and perfused on the circuit without arrest or intervening ischemia. Stroke and minute work index curves were approximately threefold and fivefold higher for group 1 (modified University of Wisconsin solution) than for group 2 (Stanford), respectively (p less than 0.01). The hearts preserved with University of Wisconsin solution did not differ in function from unpreserved control hearts (group 3). High-energy phosphate levels were better maintained in group 1 than group 2 (p less than 0.05), and water content was lower (p less than 0.01). Semiquantitative grading of electron micrographs paralleled the functional and biochemical results. Conclusion: Modified University of Wisconsin intracellular solution provides markedly better heart preservation than conventionally used cardioplegic and storage solutions.     

Aortic regurgitation in the heterotopic rat heart transplant: effect on ventricular remodeling and diastolic function.

OBJECTIVES: Use of the heterotopic rat cardiac isograft model is limited by ventricular atrophy attributable to the left ventricle's non-working state. Previous studies indicate that increased left ventricular pressure-volume work minimizes atrophy. We used a simpler approach to increase ventricular work, imposing aortic regurgitation on the transplant. We hypothesized that this would prevent atrophy and preserve left ventricular compliance. METHODS: We analyzed heterotopic transplants with aortic valvotomy and without aortic valvotomy (controls). Recipient native hearts served as separate controls. After 15 to 25 days, we measured cardiac wet weight, dry weight, and water content of all groups and measured echocardiographic left ventricular wall thickness and end-diastolic and end-systolic diameters in both transplant groups. Left ventricular volume infusions yielded pressure-volume data that we analyzed using regression methods. RESULTS: Aortic regurgitant transplants weighed more than control transplants (dry weight, 0.109 +/- 0.013 g vs 0.097 +/- 0.016 g; p = 0.020, 2-way analysis of variance), but all transplants weighed less than native hearts weighed (p = 0.001). Control transplants were less compliant than regurgitant transplants (p = 0.002), but the latter were similar to their own native hearts (p = 0.34). Wall thickness decreased in regurgitant vs control transplants (p = 0.020, Student's t-test), but end-diastolic and end-systolic diameters increased (p < or = 0.001). CONCLUSIONS: Aortic regurgitation in heterotopic transplants improves left ventricular compliance through chamber dilatation without preventing atrophy. Moderate acute aortic regurgitation affects ventricular remodeling more than it stimulates myocardial hypertrophy. Smaller end-diastolic diameter, greater wall thickness, and myocardial edema may explain decreased compliance in non-working transplants.     

Oxygen utilization during isovolumic pressure-volume loading: effects of prolonged extracorporeal circulation and cardioplegic arrest

In canine hearts supported by cardiopulmonary bypass, isovolumic peak developed pressure (PDP, mm Hg) and myocardial oxygen consumption (MVO2, ml O2 X 10(-2)/beat/100 gm left ventricular [LV] weight) were determined at 5-ml increments of LV balloon inflation before and after either 2 hours of potassium cardioplegic arrest (ischemia, N = 7) or a comparable period of normothermic perfusion without ischemia (control, N = 6). The sensitivity of MVO2 as a marker of ischemic injury was compared with preservation of both adenosine triphosphate (ATP) stores and systolic pump function. Over a physiological range of end-diastolic volumes (5 to 35 ml) and end-diastolic pressures (0 to 18 mm Hg), the Frank-Starling curves were not depressed following both cardioplegic arrest and prolonged nonischemic perfusion. Although ATP stores decreased by 26% and 22% (ischemia and control groups, respectively; not significant), these levels did not distinguish the effects of cardioplegic arrest from prolonged perfusion. At the preinterventional measurement in both groups, PDP between 50 and 200 correlated with MVO2 from 3.0 to 10.0 (r = +0.84). Following cardioplegic arrest, postischemic MVO2 increased 137 +/- 6% when measured over the PDP range of 75 to 200 mm Hg (p less than 0.01). This change was not evident at a PDP of less than 75, in the empty beating heart, or in control hearts subjected to nonischemic extracorporeal perfusion. These data suggest that increased utilization of oxygen to develop physiological pressures may be a more sensitive indicator of ischemic injury than shifts in the pressure-volume relationship or depletion of adenine nucleotide stores.     

Superior qualities of University of Wisconsin solution for ex vivo preservation of the pig heart.

The components of the University of Wisconsin solution have the potential to enhance and extend heart preservation. We have evaluated University of Wisconsin solution by comparing it with St. Thomas' Hospital cardioplegic solution in the isolated pig heart subjected to 8 hours of ischemia at 4 degrees C (n = 6 in each). The hearts were perfused ex vivo with enriched autologous blood for the control and the postpreservation assessments. Morphologic, metabolic, and functional evaluations were performed. Left and right ventricular function as assessed by the slope values of systolic and diastolic pressure-volume relationships of isovolumically contracting isolated heart was better preserved by University of Wisconsin solution (percent reduction: left ventricular systolic, 52.4% +/- 5.5% versus 17.7% +/- 6.7% [p less than 0.001]; right ventricular systolic, 125.6% +/- 46.4% versus 65.5% +/- 31.4% [p less than 0.05]; right ventricular diastolic, 112.3% +/- 48.7% versus 40.2% +/- 31.3% [p less than 0.02] after St. Thomas' Hospital and University of Wisconsin preservation, respectively). Postischemic recovery of left ventricular rate of rise of pressure and myocardial oxygen consumption were significantly improved after University of Wisconsin preservation (percent reduction, rate of rise of pressure: St. Thomas' Hospital 39.3% +/- 8.1%; University of Wisconsin 18.1% +/- 4.6%; percent reduction, myocardial oxygen consumption St. Thomas' Hospital 55.1% +/- 6.9%, University of Wisconsin 24.8% +/- 6.7%; p less than 0.001). Microvascular functional integrity as assessed by coronary vascular resistance was well maintained throughout the postischemic period and was similar to the preischemic control value in the University of Wisconsin group. By contrast, a significant increase was found at the beginning of postpreservation reperfusion, with a progressive rise thereafter in the St. Thomas' Hospital group (p less than 0.001). Preservation of myocardial adenosine triphosphate was improved and energy charge was unchanged after 8 hours of ischemia and reperfusion in the University of Wisconsin-preserved hearts compared with the St. Thomas' Hospital-preserved hearts (p less than 0.01). Electron microscopic examination revealed substantially better preservation of the contractile apparatus after preservation with University of Wisconsin solution. Myocytes from hearts receiving University of Wisconsin solution, unlike those given St. Thomas' Hospital solution, showed relaxed myofibrils with prominent I-bands. We conclude that University of Wisconsin solution has the potential to improve the preservation of the heart and possibly prolong the ischemic period in clinical cardiac transplantation.     

Cardiovascular effects of inhaled nitric oxide in a canine model of cardiomyopathy.

BACKGROUND: The inhalation of nitric oxide (NO) in patients with heart failure decreases pulmonary vascular resistance (PVR) and is associated with an increase in pulmonary artery wedge pressure (PAWP). The mechanism for this effect remains unclear. METHODS: In dogs rapid-paced for 8 weeks to induce cardiac dysfunction, we performed left ventricular pressure-volume analysis of unpaced hearts in situ to determine whether during NO inhalation (80 ppm), the mechanism for the rise in PAWP is due to: 1) primary pulmonary vasodilation; 2) a direct negative inotropic effect; or 3) impairment of ventricular relaxation. RESULTS: Inhalation of NO decreased PVR by 51%+/-3.8% (257+/-25 vs 127+/-18 dynes x sec x cm(-5) [NO 80 ppm]; p < 0.001) and increased PAWP (15.4+/-2.4 vs 18.1+/-2.6 mm Hg [NO 80 ppm]; p < 0.001). Calculated systemic vascular resistance remained unchanged. Left ventricular (LV) end-diastolic pressure rose (16.4+/-1.9 vs 19.1+/-1.8 mm Hg [NO 80 ppm]; p < 0.001), as did LV end-diastolic volume (83.5+/-4.0 vs 77.0+/-3.4 mL [NO 80 ppm]; p = 0.006). LV peak +dP/dt was unchanged by NO (1,082+/-105 vs 1,142+/-111 mm Hg/sec [NO 80 ppm]; p = NS). There was a trend toward a stroke volume increase (17.4+/-1.2 vs 18.8+/-1.3 mL; p = NS), but the relaxation time constant and end-diastolic pressure-volume relation were both unchanged. CONCLUSIONS: In this canine model of cardiomyopathy, inhaled NO decreases pulmonary vascular resistance. The associated increase in left ventricular filling pressure appears to be secondary to a primary pulmonary vasodilator effect of NO without primary effects on the contractile or relaxation properties of the left ventricle.     

The effect of fluorocarbon emulsion on 24-hour canine heart preservation by coronary perfusion

This study was designed to evaluate the effects of fluorocarbon emulsion as an oxygen carrier in myocardial preservation. The hearts were preserved for 24 hours by coronary perfusion with either oxygenated crystalloid cardioplegic solution (group C) or crystalloid cardioplegic solution with fluorocarbon added (group FC). The perfusion pressure was kept at 20 mm Hg, and myocardial temperature was maintained at 4 degrees C. Group FC demonstrated better recovery in developed pressure and maximum rate of rise of left ventricular pressure compared with group C. The postpreservation end-diastolic pressure in group C increased significantly compared with the baseline value (value obtained before preservation). On the other hand, group FC showed no significant increase of end-diastolic pressure after preservation. Group FC released a significantly lower level of creatine kinase into its perfusate than did group C. Ultrastructural changes after preservation in group C showed severe ischemic injury, but there was no evidence of ischemic injury in group FC. The use of fluorocarbon emulsion proved beneficial to myocardial protection in long-term preservation of canine hearts.     

Evaluation of a new preservative solution for cardiac graft during hypothermia.

BACKGROUND: Reports conflict on the beneficial effects of several cardioplegic solutions such as University of Wisconsin and St. Thomas' Hospital solutions. Therefore our objective was to assess the efficacy of several cardioplegic solutions for cardiac preservation by comparing University of Wisconsin modified solution (UW-1 and UW-1 + calcium = UW-2), St. Thomas' Hospital solution N degrees 1 (STH-1), Celsior solution, and a solution from our laboratory, Lyon preservation solution (LYPS). METHODS: We randomized male rats (n = 70) to 7 groups: LYPS, Celsior, STH-1, UW-1, UW-2, normal saline solution, and control. All hearts, except control hearts were preserved by cold storage (8 hours, 4 degrees C) in the various solutions. We used isolated non-working-heart preparations (left ventricular function evaluation, n = 5/group) or biopsy specimens (energetic store evaluation, n = 5/group) to assess quality of heart preservation. RESULTS: Hearts stored with the saline solution had a mean left ventricular developed pressure (LVDP) of 3.6 +/- 1.3 mm Hg. In contrast, LYPS and Celsior hearts had mean LVDP close to that of the control hearts (97 +/- 2.6, 92.1 +/- 2.2, and 122 +/- 1.9 mm Hg, respectively), whereas STH-1, UW-1, and UW-2 hearts presented an intermediate functional response (48 +/- 4, 39.9 +/- 4.1, and 69 +/- 1.8 mm Hg, respectively). The STH-1 and saline hearts showed increased release of creatine kinase (541.9 +/- 168 and 1,080.8 +/- 126.2 UI/liter, respectively). The energetic charge (EC = [(0.5 ADP + ATP)/ATP + ADP + AMP]) in Celsior, UW-2, and saline was significantly lower (p < 0.001) than in the other groups. CONCLUSION: The composition of the preservation solutions had a notable effect on myocardial viability. Our results indicated that LYPS and Celsior solutions had comparable efficacy for left ventricular function. However these solutions may offer better preservation than do UW-1, UW-2, or STH-1 solutions.     

Left ventricular mechanics of ejecting, postischemic hearts during left ventricular circulatory assistance

We measured the effects of left ventricular circulatory assistance on ventricular mechanics of ejecting sheep hearts before and after global ischemia. Flows from left atrium to femoral artery ranged between 20 and 100 ml/kg/min during circulatory assistance. In preischemic, ejecting hearts increasing flow through the left ventricular assist device progressively decreased stroke volume, end-diastolic volume, and circumferential systolic wall stress, but only slightly decreased end-systolic volume. In postischemic, ejecting hearts left ventricular assistance progressively and substantially decreased both end-diastolic volume and end-systolic volume; at high flows, end-systolic volume returned to the normal range of preischemic hearts. High flows through the assist device also shifted end-systolic points of pressure-volume loops leftward and increased the stroke work/end-diastolic volume ratio in ejecting postischemic hearts; these observations raise the possibility that left ventricular circulatory assistance acutely improves myocardial contractility of postischemic hearts.     

Left ventricular mechanics and energetics in the dilated canine heart: acute versus chronic mitral regurgitation.

The effects of volume overload associated with mitral regurgitation on left ventricular systolic mechanics, energetics, mechanical to external stroke work efficiency, and ventriculoarterial coupling were examined in 11 conscious, closed-chest dogs. Miniature radiopaque tantalum markers were implanted into the myocardium to measure left ventricular volume, and biplane cinefluoroscopic images were obtained 1 week and 3 months after creation of mitral regurgitation. Echocardiographically determined left ventricular mass increased from 116 +/- 28 to 152 +/- 29 gm (p less than 0.001). Left ventricular end-diastolic and end-ejection volumes increased by 24% and 27%, respectively. Global left ventricular systolic performance was assessed by the slopes (linear regression) of the end-systolic pressure-volume and end-systolic stress-volume relationships corrected for change in end-diastolic volume; normalized end-systolic pressure-volume relationships fell by 36% (p less than 0.001), and normalized end-systolic stress-volume relationships declined by 21% (p less than 0.005). The normalized end-systolic volume at 100 mm Hg end-systolic left ventricular pressure increased from 0.63 to 0.75 (p less than 0.05). Similar results were observed based on a nonlinear (quadratic) fit of the end-systolic pressure-volume data. In terms of energetics, the slopes of the stroke volume-end-diastolic volume and pressure-volume area-end-diastolic volume relationships fell significantly, indicating reduced external stroke work and mechanical energy at any given level of preload. Additionally, the efficiency of energy transfer from pressure-volume area to external pressure-volume work at matched end-diastolic volume was 25% lower (p = 0.006) at 3 months compared with the 1-week measurements. While overall effective arterial (or total vascular) elastance tended to decrease after a period of time, the effective ventriculovascular coupling ratio increased from 1.6 +/- 0.6 to 2.7 +/- 1.1 (p less than 0.005), indicating a greater degree of mismatch between the left ventricle and the total (forward and regurgitant) vascular load. Therefore the low pressure-volume overload of mitral regurgitation not only resulted in depressed left ventricular systolic mechanics but also was associated with deterioration of global left ventricular energetics and efficiency and exacerbated mismatch in coupling between the left ventricle and the systemic arterial bed and left atrium.     

Effects of left ventricular venting and distention during heterogenous distribution of cardioplegic solution

The effects of left ventricular venting and distention on myocardial protection during heterogenous distribution of cardioplegic solution remain undefined. This study was undertaken to determine if left ventricular venting enhances and distention impairs myocardial cooling and recovery of global and regional left ventricular function. Twenty-one pigs were placed on cardiopulmonary bypass and subjected to 80 minutes of ischemic arrest with the mid-left anterior descending artery occluded. Hearts were protected with multidose potassium (25 mEq/L) crystalloid cardioplegic solution supplemented with topical (4 degrees C) and systemic (28 degrees C) hypothermia. During arrest, the left ventricle was vented in seven pigs, seven pigs were not vented, and seven others had systemic pump blood infused into the left ventricle to maintain an end-diastolic pressure of 15 mm Hg. Parameters measured included left ventricular temperature, stroke work index, compliance (end-diastolic pressure-end-diastolic volume curves) and wall motion scores (two-dimensional echocardiography). Distended hearts had the lowest mean left ventricular temperature beyond the left anterior descending arterial occlusion (10.1 degrees +/- 1.8 degrees C distended [p less than 0.025 from vented and nonvented groups] versus 14.2 degrees +/- 0.7 degrees C vented versus 15.5 degrees +/- 1.2 degrees C nonvented), the highest postischemic stroke work index (0.78 +/- 0.09 gm-m/kg distended versus 0.62 +/- 0.07 gm-m/kg vented versus 0.66 +/- 0.07 gm-m/kg nonvented at end-diastolic pressure = 10 mm Hg), and the best wall motion scores (0.7 +/- 0.04 distended [p less than 0.025 from vented and nonvented groups] versus 5.5 +/- 1.80 vented versus 4.8 +/- 1.20 nonvented). Postischemic end-diastolic pressure-end-diastolic volume curves were unchanged from preischemic values in each group. We conclude that during heterogenous cardioplegic arrest, left ventricular venting offers no additional myocardial protection and may negate the beneficial effects of moderate (end-diastolic pressure = 15 mm Hg) left ventricular distention.     

Two-dimensional echocardiography in dogs. Variation of left ventricular mass, geometry, volume, and ejection fraction on cardiopulmonary bypass

Quantitative two-dimensional echocardiography was evaluated in 39 open-chest dogs placed on cardiopulmonary bypass. The correlation coefficient of left ventricular end-diastolic volume against postmortem pressure-volume curves was r = 0.89 to 0.93 (347 measurements in 15 dogs, 0 to 24 mm Hg). Ejection fraction was validated against roller pump flow and echo left ventricular end-diastolic volume (r = 0.83, n = 13). Left ventricular mass in vivo was compared with postmortem left ventricular mass (r = 0.81 in 21 early studies, r = 0.91 in 10 later studies with updated equipment) and was found to increase with ischemic injury as well as cardiopulmonary bypass with hemodilution. Left ventricular mass increased (p less than 0.001) from 119 +/- 5 (standard error of the mean) to 138 +/- 6 gm (n = 23) after 2 1/2 hours on cardiopulmonary bypass and moderate hemodilution. With the addition of ischemic arrest, left ventricular mass increased from 119 +/- 7 to 148 +/- 11 gm (p less than 0.01, n = 8), and myocardial water content increased by 2.0% +/- 0.4%, which accounted for at least 65% of the observed mass change. Mean left ventricular wall thickness increased from 13.8 to 15.5 mm (p = 0.02) after ischemia. Ventricular shape became more spherical with increasing left ventricular end-diastolic pressure. We conclude that two-dimensional echocardiography can be reliably used for accurate, serial measurements in physiological studies. The demonstrated variability in left ventricular mass is important, yet frequently ignored. Recognizing left ventricular mass changes may facilitate the detection of myocardial injury reflected as edema.     

Analysis of myocardial function in orthotopic cardiac allografts after prolonged storage in UW solution

The need for a better organ preservative solution in heart transplantation is clear. At the same time, newer techniques in the assessment of cardiac function in the laboratory have made accurate load-independent quantification of myocardial preservation possible. Therefore a study was undertaken to evaluate left ventricular function in transplanted hearts after 14 hours of preservation in the intracellular lactobionate solution. Nine dogs were instrumented with ultrasonic dimension transducers, to measure left ventricular epicardial volume, and with micromanometers, to measure left ventricular pressure. Left ventricular wall volumes were determined from epicardial echocardiograms. To define the extent of organ injury resulting from the transplant procedure and cardiopulmonary bypass alone, four other animals were instrumented in a similar fashion, and left ventricular function was assessed after standard cardioplegic arrest and transplantation. The transplant procedures were performed with a warm ischemic period of 0.75 +/- 0.2 hours. In all experiments, data were collected before graft harvest and 1 hour after separation from cardiopulmonary bypass. Standard cardioplegic arrest and 2.4 +/- 0.1 hours of ischemia resulted in a decrease in left ventricular ejection fraction from 0.43 +/- 0.04 to 0.27 +/- 0.1 (37%) (p less than 0.01), a decrease in the slope of the stroke work/end-diastolic volume relationship from 15.4 +/- 7.9 to 7.9 +/- 2.0 erg X 10(4) (49%; p less than 0.01), and a decrease in the myocardial power output from 19.7 +/- 10.9 to 5.9 +/- 1.9 (70%; p less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)     

Superiority of the University of Wisconsin solution over simple crystalloid for extended heart preservation. A study of left ventricular pressure-volume relationship.

To compare the effects of the University of Wisconsin solution with those of an extracellular crystalloid solution, Krebs-Ringer bicarbonate, as cardiac preservation media, we studied 35 adult dogs in an isolated heart preparation. Four groups of seven hearts were preserved in University of Wisconsin solution for 6 or 12 hours or in Krebs-Ringer bicarbonate solution for 6 or 12 hours. An additional group of seven hearts with no ischemia was used for a control group. In the four preservation groups, hearts were arrested by electrolyte solution (Normosol with potassium chloride, 20 mEq/L, added, 4 degrees C), flushed with 200 ml of the preservation solution, and then stored in the same solution at 1 degree to 2 degrees C. The hearts were mounted on an isolated heart preparation equipped with a computer-controlled servo-pump system that used a mock arterial system to modulate the aortic input impedance presented to the left ventricle. Left ventricular pressure-volume loops were measured on-line for 2 hours of reperfusion with autologous warm oxygenated blood. Elastance was derived from the end-systolic pressure-volume relationship, and diastolic compliance was derived from the end-diastolic pressure-volume relationship. The total left ventricular performance was assessed by the preload recruitable stroke work area, the slope, and its x-intercept, all of which derived from the stroke work (pressure-volume area)-end-diastolic volume relationship. Extended global ischemia had more deleterious effects on the end-diastolic than the end-systolic pressure-volume relationship. In confirmation with other studies, elastance did not accurately reflect the level of ventricular contractile dysfunction because of the significant amount of diastolic dysfunction. The preservation of myocardial systolic and diastolic functions, as demonstrated by the preload recruitable stroke work area and diastolic compliance, was better in the University of Wisconsin solution groups than in the Krebs-Ringer bicarbonate solution groups after 6 and 12 hours of preservation. In addition, 6 hours of preservation with University of Wisconsin solution maintained normal systolic and diastolic functions as compared with those of the control group. Preservation with University of Wisconsin solution prevented any myocardial edema formation; by contrast, this was significantly increased after 12 hours in Krebs-Ringer bicarbonate solution. Groups preserved with University of Wisconsin solution had less reperfusion injury as evidenced by the release of coronary sinus creatine kinase during reperfusion; they also had improved oxygen use during reperfusion.(ABSTRACT TRUNCATED AT 400 WORDS)     

Comparison of blood-based and asanguineous cardioplegic solutions administered at 4 degrees C. An ultrastructural morphometric study in the dog

Although several studies have shown better myocardial preservation with blood-based than asanguineous cardioplegic solutions at myocardial temperatures above 15 degrees C, one might suspect that blood would become unsafe at lower temperatures because of increased oxygen-hemoglobin affinity and viscosity. We compared myocardial preservation in dogs subjected to 6 hours of aortic crossclamping and treated with modified Roe's asanguineous cardioplegic solution at 4 degrees C (group CA), blood cardioplegic solution at 4 degrees C (CB), or blood cardioplegic solution at 27 degrees C (WB, four dogs per group). Myocardial preservation was assessed by triphenyltetrazolium staining of whole hearts, and by analysis of ultrastructure and morphometric analysis of mitochondria in myocardial biopsies from three sites in each heart (left ventricle subepicardium and subendocardium and right ventricle). Tetrazolium staining showed no difference in preservation among the three treatment groups (no necrosis in any heart). For two of the three biopsy sites (left ventricular subepicardium and right ventricle), ultrastructural and morphometric analyses demonstrated signs of more severe subcellular injury in group CA than in CB (p = 0.013 to 0.004), whereas equivalent preservation with all treatments was observed in the left ventricular endocardial site. Functional recovery also appeared to be equivalent between treatments, to the extent that all dogs were successfully weaned from bypass after 20 minutes of reperfusion. We conclude that the safety and effectiveness of blood cardioplegia is not compromised by infusion at 4 degrees C compared with 27 degrees C and that myocardial preservation is not improved by using asanguineous cardioplegia instead of blood cardioplegia at 4 degrees C.     

Prolonged preservation of the blood-perfused canine heart with glycolysis-promoting solution.

BACKGROUND: Prolonged ischemia and inadequate myocardial preservation remain significant perioperative risk factors in cardiac transplantation. Long-term preservation techniques that have been effective in small rodent hearts have not been as effective in larger animal models or in clinical studies. We developed a cardioplegia solution formulated to promote high-energy phosphate production from glycolysis and determined its efficacy in a blood perfused canine heart model subjected to 24 hours of ischemia. METHODS: Hearts harvested from adult dogs (n = 6 per group) were flushed with a histidine-buffered cardioplegia solution containing glucose or University of Wisconsin solution. The hearts were maintained at 4 degrees C for 24 hours then reperfused with autologous blood. After reperfusion, left ventricular pressures were measured with an intracavitary balloon at varying balloon volumes and compared with control nonischemic hearts. Predicted stroke volume and ejection fraction were calculated at an end-systolic pressure of 70 mm Hg and end-diastolic pressure of 15 mm Hg. RESULTS: Developed pressure was better preserved in the hearts that received histidine-buffered solution (93+/-9 versus 38+/-7 mm Hg, p<0.05), along with a higher end-diastolic volume at 15 mm Hg (31+/-3 versus 22+/-2 mL histidine-buffered versus University of Wisconsin solutions, respectively, p<0.05). Stroke volume and ejection fraction were also higher in the histidine group (17+/-2.5 versus 2.3+/-1.2 mL and 50%+/-3.5% versus 9% +/-4.5%, respectively) in the presence of dobutamine. CONCLUSIONS: The highly buffered glycolysis-promoting cardioplegia solution provided effective preservation of the blood perfused canine heart with superior recovery of pump performance after 24 hours of hypothermic ischemia compared with University of Wisconsin solution in this model.     

Superior myocardial protection with nicorandil cardioplegia.

OBJECTIVE: The ATP-sensitive potassium channel (K(ATP)) activator nicorandil used as cardioplegic agent may protect the left ventricle during cardiac arrest. Nicorandil in cold blood was compared with standard hyperkalemic blood and crystalloid cardioplegia. METHODS: Twenty-one pigs were randomly assigned to three groups: (1) cold hyperkalemic crystalloid (n=7); (2) cold hyperkalemic blood (n=7); and (3) nicorandil as cardioplegia in cold blood (n=7). Left ventricular mechanical performance, pressure-volume area (PVA) and myocardial oxygen consumption (MVO(2)) were measured before and at 1 and at 2 h after 60 min of cold global ischemia on cardiopulmonary bypass using intraventricular pressure-volume conductance catheters, coronary flow probes and O(2)-content difference. RESULTS: The slope (M(w)) of the stroke work end-diastolic volume relationship, the preload recriutable stroke work relationship, was unchanged after ischemia in the nicorandil group, but was reduced to averaged 62.5% (standard deviation 14) of baseline values in both hyperkalemic perfusions (P<0.05). The slope of the MVO(2)-PVA relationship was unchanged after nicorandil cardioplegia while the slope after hyperkalemic blood and crystalloid cardioplegia increased with 33% (P<0.02) and 52% (P<0.02) of baseline values, respectively. CONCLUSIONS: Nicorandil as sole cardioplegic agent in cold blood given intermittently preserves left ventricular contractility and myocardial energetics significantly better than traditional forms of cardioplegia after cardiac arrest.